Stringish to integral type conversion. Fix #44

conv: Fix overflow hanndling in readIntegral
format: Support text in the format string
2018-07-18 06:33:45 +02:00 · 2018-07-17 16:03:05 +02:00 · 2018-07-14 19:09:21 +02:00 · 2018-07-13 05:39:58 +02:00 · 2018-07-08 12:54:47 +02:00 · 2018-07-07 12:17:59 +02:00
90 changed files with 33587 additions and 10166 deletions
--- a/.editorconfig
+++ b/.editorconfig
@ -0,0 +1,9 @@
 root = true
 [*]
 end_of_line = lf
 insert_final_newline = true
 charset = utf-8
 indent_style = space
 indent_size = 4
 trim_trailing_whitespace = true
--- a/.gitignore
+++ b/.gitignore
@ -1,7 +1,21 @@
 # Binary
 *.[oa]
 *.exe
 *.lib
 # D
 .dub
 dub.selections.json
 __test__*__
 __test__*__.core
 /tanya-test-*
 /dub_platform_probe-*
 /docs/
 /docs.json
 /*.lst
 # Ninja build
 .ninja_*
--- a/.travis.yml
+++ b/.travis.yml
@ -1,16 +1,39 @@
 sudo: false
 os:
- - linux
+  - linux
  - osx
 language: d
 d:
- - dmd-2.072.1
+  - dmd-2.081.0
  - dmd-2.080.1
  - dmd-2.079.1
  - dmd-2.078.3
-env: 
+env:
- matrix:
+  matrix:
-  - ARCH=x86_64
+    - ARCH=x86_64
    - ARCH=x86
 addons:
  apt:
    packages:
      - gcc-multilib
 before_script:
  - if [ "`$DC --version | head -n 1 | grep 'v2.081.0'`" ]; then
      export UNITTEST="unittest-cov";
    fi
 script:
- - dub test --arch=$ARCH
+  - dub test -b ${UNITTEST:-unittest} --arch=$ARCH --compiler=$DC
  - if [ "$UNITTEST" ] && [ "$ARCH" = "x86_64" ] && [ "$TRAVIS_OS_NAME" = "linux" ];
    then
      dub fetch dscanner;
      dub run dscanner -- --styleCheck ./source/;
    fi
 after_success:
  - test "$UNITTEST" && bash <(curl -s https://codecov.io/bash)
--- a/CODE_OF_CONDUCT.md
+++ b/CODE_OF_CONDUCT.md
@ -0,0 +1,5 @@
 # Contributor Code of Conduct
 This project adheres to No Code of Conduct.  We are all adults.  We accept anyone's contributions.  Nothing else matters.
 For more information please visit the [No Code of Conduct](https://github.com/domgetter/NCoC) homepage.
--- a/CONTRIBUTING.md
+++ b/CONTRIBUTING.md
@ -0,0 +1,107 @@
 # Contributing
 Tanya is a project in active development, therefore any help is appreciated. Thank you for considering contributing
 to it, feel welcome.
 These guidelines describe ways to get started.
 ## Ways to get involved
 * **Reporting a problem**: [Report](https://github.com/caraus-ecms/tanya/issues) bugs and usage problems you
 encounter.
 * **Fixing issues**: [The bug tracker](https://github.com/caraus-ecms/tanya/issues) contains a list of issues you
 can work on.
 * **Documentation**: You can improve API documentation by correcting grammar errors, completing existing texts and
 writing new ones, or providing usage examples.
 * **Testing**: Test coverage is important for a library. Writing tests is not only helpful, but is also a great way
 to get a feel for how tanya works.
 * **Adding new features**: Tanya is a growing library. If you think some feature is missing, you can suggest
 and implement this.
 ## Opening an issue
 If you have found a bug, an error, have some question, or suggestion,
 [Open an issue](https://github.com/caraus-ecms/tanya/issues). I'll try to answer as soon as I can. There is also a
 list of open issues that mirror the current development process and progress. If you're looking for a challenge, just
 pick an issue you are interested in and start working on it. Fill free to comment on the issue to get more
 information.
 You can also look at the [milestones](https://github.com/Dlackware/gnome/milestones) to see what is planned for a
 specific release.
 ## Contribution process
 ### Creating a pull request
 I accept GitHub pull requests. Creating a pull request is like sending a patch with the suggested change.
 First you have to [fork](https://guides.github.com/activities/forking/) the repository. Clone your fork locally
 with `git clone` and create a new branch where you want to work. For example:
 ```shell
 git checkout -b bugfix-x
 ```
 Commit your changes to your fork:
 ```shell
 git commit -m "Fix X"
 git push -u origin bugfix-x
 ```
 After that if you visit your fork on GitHub, GitHub will suggest to create pull request. Just follow the steps
 described on GitHub to finish the process. See
 [Using Pull Requests](https://help.github.com/articles/about-pull-requests/) for more information.
 Please ensure that your fork is even with the upstream (original) repository. If not, you have to rebase your branch
 on upstream/master before submitting the pull request. See [Syncing a fork](https://help.github.com/articles/syncing-a-fork/) for a
 step-by-step guide.
 ### Fixing a bug
 Add a unit test that demonstrates the bug along with a short description or link to the original bug.
 ### Adding new features
 * Use Ddoc to document the feature.
 * Add some unit tests to prevent bugs.
 * [Documented D unit tests](https://dlang.org/spec/ddoc.html#using_ddoc_to_generate_examples) go into the documentation and can be used as an usage
 example. These tests should be readable and not complicated since they demonstrate how the feature is supposed to work.
 * More advanced tests should be put into a separate not documented unittest block.
 ### Writing unit tests
 ```d
 ///
 unittest
 {
    // A documented unit test has three slashes in front of it.
 }
 // Issue ##: https://github.com/caraus-ecms/tanya/issues/##.
 unittest
 {
    // Not documented unit test may still have a description.
 }
 ```
 ### Style guide
 Make sure your changes follow [The D Style](https://dlang.org/dstyle.html) (including
 [Additional Requirements for Phobos](https://dlang.org/dstyle.html#phobos)).
 You can also use [dscanner](https://github.com/dlang-community/D-Scanner) to test the new code against the
 most guidlines. The root of this repository contains
 [dscanner.ini](https://github.com/caraus-ecms/tanya/blob/master/dscanner.ini), configuration file with settings for an
 automatic style check. Just go to the top-level directory and issue (this assumes `dscanner` is installed in your
 system):
 ```shell
 dscanner --styleCheck source
 ```
 ## Questions and suggestions
 * [Open an issue](https://github.com/caraus-ecms/tanya/issues)
 * [Send an email](mailto:info@caraus.de)
--- a/README.md
+++ b/README.md
@ -1,68 +1,218 @@
 # Tanya
-[![Build Status](https://travis-ci.org/caraus-ecms/tanya.svg?branch=master)](https://travis-ci.org/caraus-ecms/tanya)
+[![Build Status](https://travis-ci.com/caraus-ecms/tanya.svg?branch=master)](https://travis-ci.com/caraus-ecms/tanya)
-[![Dub Version](https://img.shields.io/dub/v/tanya.svg)](https://code.dlang.org/packages/tanya)
+[![Build status](https://ci.appveyor.com/api/projects/status/djkmverdfsylc7ti/branch/master?svg=true)](https://ci.appveyor.com/project/belka-ew/tanya/branch/master)
 [![codecov](https://codecov.io/gh/caraus-ecms/tanya/branch/master/graph/badge.svg)](https://codecov.io/gh/caraus-ecms/tanya)
 [![Dub version](https://img.shields.io/dub/v/tanya.svg)](https://code.dlang.org/packages/tanya)
 [![Dub downloads](https://img.shields.io/dub/dt/tanya.svg)](https://code.dlang.org/packages/tanya)
 [![License](https://img.shields.io/badge/license-MPL_2.0-blue.svg)](https://raw.githubusercontent.com/caraus-ecms/tanya/master/LICENSE)
-Tanya is a general purpose library for D programming language that doesn't
+Tanya is a general purpose library for D programming language.
 rely on the Garbage Collector.
 Its aim is to simplify the manual memory management in D and to provide a
 guarantee with @nogc attribute that there are no hidden allocations on the
 Garbage Collector heap. Everything in the library is usable in @nogc code.
-Tanya extends Phobos functionality and provides alternative implementations for
+Tanya provides data structures and utilities to facilitate painless systems
-data structures and utilities that depend on the Garbage Collector in Phobos.
+programming in D.
 * [API Documentation](https://docs.caraus.io/tanya)
 * [Contribution guidelines](CONTRIBUTING.md)
 ## Overview
-Tanya consists of the following packages:
+Tanya consists of the following packages and (top-level) modules:
-* `async`: Event loop.
+* `algorithm`: Collection of generic algorithms.
-* `container`: Queue, Vector, Singly linked list.
+* `async`: Event loop (epoll, kqueue and IOCP).
-* `crypto`: Work in progress TLS implementation.
+* `container`: Queue, Array, Singly and doubly linked lists, Buffers, UTF-8
-* `math`: Multiple precision integer and a set of functions.
+string, Set, Hash table.
-* `memory`: Tools for manual memory management (allocator, reference counting, helper functions).
+* `conv`: This module provides functions for converting between different
-* `network`: URL-Parsing, sockets.
+types.
 * `encoding`: This package provides tools to work with text encodings.
 * `exception`: Common exceptions and errors.
 * `format`: Formatting and conversion functions.
 * `functional`: Functions that manipulate other functions and their argument
 lists.
 * `hash`: Hash algorithms.
 * `math`: Arbitrary precision integer and a set of functions.
 * `memory`: Tools for manual memory management (allocators, smart pointers).
 * `meta`: Template metaprogramming. This package contains utilities to acquire
 type information at compile-time, to transform from one type to another. It has
 also different algorithms for iterating, searching and modifying template
 arguments.
 * `net`: URL-Parsing, network programming.
 * `network`: Socket implementation. `network` is currently under rework.
 After finishing the new socket implementation will land in the `net` package and
 `network` will be deprecated.
 * `os`: Platform-independent interfaces to operating system functionality.
 * `range`: Generic functions and templates for D ranges.
 * `test`: Test suite for unittest-blocks.
 * `typecons`: Templates that allow to build new types based on the available
 ones.
 ### Current status
-The library is currently under development, but some parts of it can already be
+## NogcD
 used.
-Containers were newly reworked and the API won't change significantly, but will
+To achieve programming without the Garbage Collection tanya uses a subset of D:
-be only extended. The same is true for the `memory` package.
+NogcD.
-`network` and `async` packages should be reviewed in the future and the API may
+### Allocators
 change.
-`math` package contains an arbitrary precision integer implementation that has
+Memory management is done with allocators. Instead of using `new` to create an
-a stable API (that mostly consists of operator overloads), but still needs
+instance of a class, an allocator is used:
 testing and work on its performance.
-I'm currently mostly working on `crypto` that is not a complete cryptographic
+```d
-suite, but contains (will contain) algorithm implementations required by TLS.
+import tanya.memory;
-### Other properties
+class A
 {
    this(int arg)
    {
    }
 }
-* Tanya is a native D library (only D and Assembler are tolerated).
+A a = defaultAllocator.make!A(5);
-* It is important for me to document the code and attach at least a few unit
+defaultAllocator.dispose(a);
-tests where possible. So the documentation and usage examples can be found in
+```
 the source code.
-* Tanya is mostly tested on a 64-bit Linux and some features are
+As you can see, the user is responsible for deallocation, therefore `dispose`
-platform-dependant, but not because it is a Linux-only library. Therefore any
+is called at the end.
 help to bring better support for Windows and BSD systems would be accepted.
-* The library isn't thread-safe. Thread-safity should be added later.
+If you want to change the `defaultAllocator` to something different, you
 probably want to do it at the program's beginning. Or you can invoke another
 allocator directly. It is important to ensure that the object is destroyed
 using the same allocator that was used to allocate it.
-* I'm working with the latest dmd version, but will be looking to support other
+What if I get an allocated object from some function? The generic rule is: If
-D compilers and keep compatibility with the elder dmd versions in the future.
+you haven't requested the memory yourself (with `make`), you don't need to free
 it.
-## Contributing
+`tanya.memory.smartref` contains smart pointers, helpers that can take care of
 a proper deallocation in some cases for you.
-Since I'm mostly busy writing new code and implementing new features I would
+### Exceptions
 appreciate, if anyone uses the library. It would help me to improve the
 codebase and fix issues.
-Feel free to contact me if you have any questions.
+Since exceptions are normal classes in D, they are allocated and dellocated the
 same as described above, but:
 1. The caller is **always** responsible for destroying a caught exception.
 2. Exceptions are **always** allocated and should be always allocated with the
 `defaultAllocator`.
 ```d
 import tanya.memory;
 void functionThatThrows()
 {
    throw defaultAlocator.make!Exception("An error occurred");
 }
 try
 {
    functionThatThrows()
 }
 catch (Exception e)
 {
    defaultAllocator.dispose(e);
 }
 ```
 ### Built-in array operations and containers
 Arrays are commonly used in programming. D's built-in arrays often rely on the
 GC. It is inconvenient to change their size, reserve memory for future use and
 so on. Containers can help here. The following example demonstrates how
 `tanya.container.array.Array` can be used instead of `int[]`.
 ```d
 import tanya.container.array;
 Array!int arr;
 // Reserve memory if I know that my container will contain approximately 15
 // elements.
 arr.reserve(15);
 arr.insertBack(5); // Add one element.
 arr.length = 10; // New elements are initialized to 0.
 // Iterate over the first five elements.
 foreach (el; arr[0 .. 5])
 {
 }
 int i = arr[7]; // Access 8th element.
 ```
 There are more containers in the `tanya.container` package.
 ### Immutability
 Immutability doesn't play nice with manual memory management since the
 allocated storage should be initialized (mutated) and then released (mutated).
 `immutable` is used only for non-local immutable declarations (that are
 evaluated at compile time), static immutable data, strings (`immutable(char)[]`,
 `immutable(wchar)[]` and `immutable(dchar)[]`).
 ### Unsupported features
 The following features depend on GC and aren't supported:
 - `lazy` parameters (allocate a closure which is evaluated when then the
 parameter is used)
 - `synchronized` blocks
 ## Development
 ### Supported compilers
 | DMD     | GCC       |
 |:-------:|:---------:|
 | 2.081.1 | *master*  |
 | 2.080.1 |           |
 | 2.079.1 |           |
 | 2.078.3 |           |
 ### Release management
 Tanya is still under active development and it isn't possible to provide great
 backwards-compatibility at this stage. This won't change until 1.0.0. Almost
 every release contains new features or API changes alongside bug fixes. Thus:
 - Patch releases add new functionality and bug fixes in a backwards-compatible
 manner
 - Minor releases contain API breakages
 - Major release number is always the same: `0.x.x`
 Deprecated functionality is where possible marked as such before getting
 removed. It is left in the library for one release: If 0.8.1 deprecates some
 feature, it is removed in the next release: 0.9.0.
 ## Further characteristics
 - Tanya is a native D library
 - Tanya is cross-platform. The development happens on a 64-bit Linux, but it
 is being tested on Windows and FreeBSD as well
 - Tanya favours generic algorithms therefore there is no auto-decoding. Char
 arrays are handled as any other array type
 - The library isn't thread-safe yet
 - Complex numbers (`cfloat`, `cdouble`, `creal`, `ifloat`, `idouble`, `ireal`)
 aren't supported
 ## Feedback
 Any feedback about your experience with tanya would be greatly appreciated. Feel free to
 [contact me](mailto:info@caraus.de).
--- a/appveyor.yml
+++ b/appveyor.yml
@ -0,0 +1,66 @@
 platform: x64
 os: Visual Studio 2015
 environment:
  matrix:
    - DC: dmd
      DVersion: 2.081.1
      arch: x64
    - DC: dmd
      DVersion: 2.081.1
      arch: x86
    - DC: dmd
      DVersion: 2.080.1
      arch: x64
    - DC: dmd
      DVersion: 2.080.1
      arch: x86
    - DC: dmd
      DVersion: 2.079.1
      arch: x64
    - DC: dmd
      DVersion: 2.079.1
      arch: x86
    - DC: dmd
      DVersion: 2.078.3
      arch: x64
    - DC: dmd
      DVersion: 2.078.3
      arch: x86
 skip_tags: true
 install:
  - ps: function SetUpDCompiler
        {
          $env:toolchain = "msvc";
          $version = $env:DVersion;
          Invoke-WebRequest "http://downloads.dlang.org/releases/2.x/$($version)/dmd.$($version).windows.7z" -OutFile "c:\dmd.7z";
          echo "finished.";
          pushd c:\\;
          7z x dmd.7z > $null;
          popd;
        }
  - ps: SetUpDCompiler
 before_build:
  - ps: if($env:arch -eq "x86"){
          $env:compilersetupargs = "x86";
          $env:Darch = "x86";
        }
        elseif($env:arch -eq "x64"){
          $env:compilersetupargs = "amd64";
          $env:Darch = "x86_64";
        }
  - ps: $env:PATH += ";C:\dmd2\windows\bin;";
  - call "C:\Program Files (x86)\Microsoft Visual Studio 14.0\VC\vcvarsall" %compilersetupargs%
 build_script:
  - echo dummy build script - dont remove me
 test_script:
  - echo %Darch%
  - echo %PATH%
  - 'dub --version'
  - '%DC% --version'
  - dub test -b unittest --arch=%Darch% --compiler=%DC%
--- a/arch/build.ninja
+++ b/arch/build.ninja
@ -0,0 +1,14 @@
 rule gas
  command = gcc -c $in -o $out
 rule archive
  command = ar rcs $out $in
 build abs.o: gas x64/linux/math/abs.S
 build log.o: gas x64/linux/math/log.S
 build cmp.o: gas x64/linux/memory/cmp.S
 build fill.o: gas x64/linux/memory/fill.S
 build copy.o: gas x64/linux/memory/copy.S
 build syscall.o: gas x64/linux/syscall.S
 build tanya.a: archive syscall.o copy.o fill.o cmp.o log.o abs.o
--- a/arch/x64/linux/concurrency/thread.S
+++ b/arch/x64/linux/concurrency/thread.S
@ -0,0 +1,8 @@
 	.text
 	.globl thrd_current
 	.type thrd_current, @function
 thrd_current:
 	mov %fs:0, %rax
 	ret
--- a/arch/x64/linux/math/abs.S
+++ b/arch/x64/linux/math/abs.S
@ -0,0 +1,35 @@
 	.text
 // fabsf.
 	.globl _D5tanya4math8nbtheory4fabsFNaNbNiNffZf
 	.type _D5tanya4math8nbtheory4fabsFNaNbNiNffZf, @function
 _D5tanya4math8nbtheory4fabsFNaNbNiNffZf:
 	mov $0x7fffffff, %eax
 	movq %rax, %xmm1
 	andpd %xmm1, %xmm0
 	ret
 // fabs.
 	.globl _D5tanya4math8nbtheory4fabsFNaNbNiNfdZd
 	.type _D5tanya4math8nbtheory4fabsFNaNbNiNfdZd, @function
 _D5tanya4math8nbtheory4fabsFNaNbNiNfdZd:
 	mov $0x7fffffffffffffff, %rax
 	movq %rax, %xmm1
 	andpd %xmm1, %xmm0
 	ret
 // fabsl.
 	.globl _D5tanya4math8nbtheory4fabsFNaNbNiNfeZe
 	.type _D5tanya4math8nbtheory4fabsFNaNbNiNfeZe, @function
 // Load the parameter from the stack onto FP stack, execute 'fabs' instruction
 // The result is returned in ST0.
 _D5tanya4math8nbtheory4fabsFNaNbNiNfeZe:
 	fldt 0x8(%rsp)
 	fabs
 	ret
--- a/arch/x64/linux/math/log.S
+++ b/arch/x64/linux/math/log.S
@ -0,0 +1,48 @@
 	.text
 // logf.
 	.globl _D5tanya4math8nbtheory4logfFNaNbNiNffZf
 	.type _D5tanya4math8nbtheory4logfFNaNbNiNffZf, @function
 _D5tanya4math8nbtheory4logfFNaNbNiNffZf:
 	movss %xmm0, -4(%rsp) // Put the argument onto the stack
 	fldln2 // Put lb(e) onto the FPU stack
 	flds -4(%rsp) // Put a float onto the FPU stack
 	fyl2x // %st1 * lb(%st0)
 	 // The result is on the FPU stack, but returned in %xmm0
 	fstps -4(%rsp)
 	movss -4(%rsp), %xmm0
 	ret
 // log.
 	.globl _D5tanya4math8nbtheory3logFNaNbNiNfdZd
 	.type _D5tanya4math8nbtheory3logFNaNbNiNfdZd, @function
 _D5tanya4math8nbtheory3logFNaNbNiNfdZd:
 	movsd %xmm0, -8(%rsp) // Put the argument onto the stack
 	fldln2 // Put lb(e) onto the FPU stack
 	fldl -8(%rsp) // Put a double onto the FPU stack
 	fyl2x // %st1 * lb(%st0)
 	 // The result is on the FPU stack, but returned in %xmm0
 	fstpl -8(%rsp)
 	movsd -8(%rsp), %xmm0
 	ret
 // logl.
 	.globl _D5tanya4math8nbtheory4loglFNaNbNiNfeZe
 	.type _D5tanya4math8nbtheory4loglFNaNbNiNfeZe, @function
 _D5tanya4math8nbtheory4loglFNaNbNiNfeZe:
 	fldln2 // Put lb(e) onto the FPU stack
 	fldt 8(%rsp) // Put the argument onto the FPU stack
 	fyl2x // %st1 * lb(%st0)
 	ret
--- a/arch/x64/linux/memory/cmp.S
+++ b/arch/x64/linux/memory/cmp.S
@ -0,0 +1,68 @@
 	.text
 /*
 * cmpMemory.
 *
 * rdi - r1 length
 * rsi - r1 data.
 * rdx - r2 length.
 * rcx - r2 data.
 */
 	.globl _D5tanya6memory2op9cmpMemoryFNaNbNixAvxAvZi
 	.type _D5tanya6memory2op9cmpMemoryFNaNbNixAvxAvZi, @function
 _D5tanya6memory2op9cmpMemoryFNaNbNixAvxAvZi:
 		// Compare the lengths
 		cmp %rdx, %rdi
 		jl  less
 		jg  greater
 		mov %rcx, %rdi
 		// Check if we're aligned
 		cmp $0x08, %rdx
 		jc aligned_1
 		test $0x07, %edi
 		jz aligned_8
 	naligned:
 		cmpsb
 		jl less
 		jg greater
 		dec %rdx
 		test $0x07, %edi
 		jnz naligned
 	aligned_8:
 		mov %rdx,  %rcx
 		shr $0x03, %rcx
 		repe cmpsq
 		jl less
 		jg greater
 		and $0x07, %edx
 		jz equal
 	aligned_1: // Compare the remaining bytes
 		mov %rdx, %rcx
 		cmp $0x0, %rcx
 		repe cmpsb
 		jl less
 		jg greater
 	equal:
 		xor %rax, %rax // Return 0
 		jmp end
 	greater:
 		mov $0x01, %rax
 		jmp end
 	less:
 		mov $-0x01, %rax
 	end:
 		ret
--- a/arch/x64/linux/memory/copy.S
+++ b/arch/x64/linux/memory/copy.S
@ -0,0 +1,67 @@
 	.text
 /*
 * copyMemory.
 *
 * rdi - source length
 * rsi - source data.
 * rdx - target length.
 * rcx - target data.
 */
 	.globl _D5tanya6memory2op10copyMemoryFNaNbNixAvAvZv
 	.type _D5tanya6memory2op10copyMemoryFNaNbNixAvAvZv, @function
 _D5tanya6memory2op10copyMemoryFNaNbNixAvAvZv:
 		mov %rdi, %rdx
 		mov %rcx, %rdi
 		cmp  $0x08, %rdx
 		jc aligned_1
 		test $0x07, %edi
 		jz aligned_8
 	naligned:
 		movsb
 		dec  %rdx
 		test $0x07, %edi
 		jnz naligned
 	aligned_8:
 		mov %rdx,  %rcx
 		shr $0x03, %rcx
 		rep movsq
 		and $0x07, %edx
 		jz end
 	aligned_1:
 		// Write the remaining bytes
 		mov %rdx, %rcx
 		rep movsb
 	end:
 		ret
 /*
 * moveMemory.
 *
 * rdi - source length
 * rsi - source data.
 * rdx - target length.
 * rcx - target data.
 */
 	.globl _D5tanya6memory2op10moveMemoryFNaNbNixAvAvZv
 	.type _D5tanya6memory2op10moveMemoryFNaNbNixAvAvZv, @function
 _D5tanya6memory2op10moveMemoryFNaNbNixAvAvZv:
 		mov %rdi, %rdx
 		lea -1(%rdx, %rsi), %rsi
 		lea -1(%rdx, %rcx), %rdi
 		mov %rdx, %rcx
 		std // Set the direction flag
 		rep movsb
 		cld // Clear the direction flag
 		ret
--- a/arch/x64/linux/memory/fill.S
+++ b/arch/x64/linux/memory/fill.S
@ -0,0 +1,160 @@
 	.text
 /*
 * fillMemory.
 *
 * rdi - length.
 * rsi - pointer.
 * rdx - value filled with a byte.
 */
 	.globl _D5tanya6memory2op10fillMemoryFNaNbNiAvmZv
 	.type _D5tanya6memory2op10fillMemoryFNaNbNiAvmZv, @function
 _D5tanya6memory2op10fillMemoryFNaNbNiAvmZv:
 		// Check for zero length
 		test    %rdi, %rdi
 		jz end
 		mov     %rdi, %rax
 		mov     %rsi, %r8
 		movq    %rdx,  %xmm0
 		movlhps %xmm0, %xmm0
 		// Check if the pointer is aligned to a 16-byte boundary
 		and     $-0x10, %r8
 		// Compute the number of misaligned bytes
 		mov  %rsi, %r9
 		sub  %r8,  %r9
 		test %r9,  %r9
 		jz aligned
 		// Get the number of bytes to be written until we are aligned
 		mov $0x10, %rcx
 		sub %r9,   %rcx
 		mov %rsi,  %r8
 		// If the length is less than the number of misaligned bytes,
 		// write one byte at a time and exit
 		cmp %rax, %rcx
 		jg aligned_1
 	naligned:
 		mov %dl, (%r8) // Write a byte
 		// Advance the pointer. Decrease the total number of bytes
 		// and the misaligned ones
 		inc %r8
 		dec %rcx
 		dec %rax
 		// Checks if we are aligned
 		test %rcx, %rcx
 		jnz naligned
 	aligned:
 		// Checks if we're done writing bytes
 		test %rax, %rax
 		jz end
 		// Write 1 byte at a time
 		cmp $8, %rax
 		jl aligned_1
 		// Write 8 bytes at a time
 		cmp $16, %rax
 		jl aligned_8
 		// Write 16 bytes at a time
 		cmp $32, %rax
 		jl aligned_16
 		// Write 32 bytes at a time
 		cmp $64, %rax
 		jl aligned_32
 	aligned_64:
 		movdqa %xmm0, (%r8)
 		movdqa %xmm0, 16(%r8)
 		movdqa %xmm0, 32(%r8)
 		movdqa %xmm0, 48(%r8)
 		add $64, %r8
 		sub $64, %rax
 		cmp $64, %rax
 		jge aligned_64
 		// Checks if we're done writing bytes
 		test %rax, %rax
 		jz end
 		// Write 1 byte at a time
 		cmp $8, %rax
 		jl aligned_1
 		// Write 8 bytes at a time
 		cmp $16, %rax
 		jl aligned_8
 		// Write 16 bytes at a time
 		cmp $32, %rax
 		jl aligned_16
 	aligned_32:
 		movdqa %xmm0, (%r8)
 		movdqa %xmm0, 16(%r8)
 		add $32, %r8
 		sub $32, %rax
 		// Checks if we're done writing bytes
 		test %rax, %rax
 		jz end
 		// Write 1 byte at a time
 		cmp $8, %rax
 		jl aligned_1
 		// Write 8 bytes at a time
 		cmp $16, %rax
 		jl aligned_8
 	aligned_16:
 		movdqa %xmm0, (%r8)
 		add $16, %r8
 		sub $16, %rax
 		// Checks if we're done writing bytes
 		test %rax, %rax
 		jz end
 		// Write 1 byte at a time
 		cmp $8, %rax
 		jl aligned_1
 	aligned_8:
 		mov %rdx, (%r8)
 		add $8, %r8
 		sub $8, %rax
 		// Checks if we're done writing bytes
 		test %rax, %rax
 		jz end
 	aligned_1:
 		mov %dl, (%r8)
 		inc %r8
 		dec %rax
 		test %rax, %rax
 		jnz aligned_1
 	end:
 		ret
--- a/arch/x64/linux/syscall.S
+++ b/arch/x64/linux/syscall.S
@ -0,0 +1,52 @@
 /*
 The kernel uses the following registers:
 %rdi, %rsi, %rdx, %r8, %r9, %r10
 The number of the syscall is passed in %rax.
 A syscall clobbers:
 %rax, %rcx, %r11
 The returned value is placed in %rax.
 */
 	.text
 	.globl syscall1
 	.type syscall1, @function
 syscall1:
 	movq %rsi, %rax // Syscall number.
 	syscall
 	ret
 // 2 parameters.
 	.globl _D5tanya3sys5linux7syscall7syscallFNbNilllZl
 	.type _D5tanya3sys5linux7syscall7syscallFNbNilllZl, @function
 _D5tanya3sys5linux7syscall7syscallFNbNilllZl:
 	movq %rdx, %rax
 	syscall
 	ret
 // 6 parameters.
 	.globl _D5tanya3sys5linux7syscall7syscallFNbNilllllllZl
 	.type _D5tanya3sys5linux7syscall7syscallFNbNilllllllZl, @function
 _D5tanya3sys5linux7syscall7syscallFNbNilllllllZl:
 	pushq %rbp
 	movq %rsp, %rbp
 	movq 16(%rbp), %rax
 	mov %rcx, %r10
 	syscall
 	leave
 	ret
--- a/codecov.yml
+++ b/codecov.yml
@ -0,0 +1,3 @@
 ignore:
  - "source/tanya/async/event/iocp.d"
  - "source/tanya/async/iocp.d"
--- a/dscanner.ini
+++ b/dscanner.ini
@ -0,0 +1,81 @@
 ; Configure which static analysis checks are skip-unittest
 [analysis.config.StaticAnalysisConfig]
 ; Check variable, class, struct, interface, union, and function names against t
 ; he Phobos style guide
 style_check="disabled"
 ; Check for array literals that cause unnecessary allocation
 enum_array_literal_check="skip-unittest"
 ; Check for poor exception handling practices
 exception_check="skip-unittest"
 ; Check for use of the deprecated 'delete' keyword
 delete_check="skip-unittest"
 ; Check for use of the deprecated floating point operators
 float_operator_check="skip-unittest"
 ; Check number literals for readability
 number_style_check="disabled"
 ; Checks that opEquals, opCmp, toHash, and toString are either const, immutable
 ; , or inout.
 object_const_check="disabled"
 ; Checks for .. expressions where the left side is larger than the right.
 backwards_range_check="skip-unittest"
 ; Checks for if statements whose 'then' block is the same as the 'else' block
 if_else_same_check="skip-unittest"
 ; Checks for some problems with constructors
 constructor_check="skip-unittest"
 ; Checks for unused variables and function parameters
 unused_variable_check="skip-unittest"
 ; Checks for unused labels
 unused_label_check="skip-unittest"
 ; Checks for duplicate attributes
 duplicate_attribute="skip-unittest"
 ; Checks that opEquals and toHash are both defined or neither are defined
 opequals_tohash_check="disabled"
 ; Checks for subtraction from .length properties
 length_subtraction_check="disabled"
 ; Checks for methods or properties whose names conflict with built-in propertie
 ; s
 builtin_property_names_check="skip-unittest"
 ; Checks for confusing code in inline asm statements
 asm_style_check="skip-unittest"
 ; Checks for confusing logical operator precedence
 logical_precedence_check="skip-unittest"
 ; Checks for undocumented public declarations
 undocumented_declaration_check="disabled"
 ; Checks for poor placement of function attributes
 function_attribute_check="skip-unittest"
 ; Checks for use of the comma operator
 comma_expression_check="skip-unittest"
 ; Checks for local imports that are too broad
 local_import_check="disabled"
 ; Checks for variables that could be declared immutable
 could_be_immutable_check="disabled"
 ; Checks for redundant expressions in if statements
 redundant_if_check="skip-unittest"
 ; Checks for redundant parenthesis
 redundant_parens_check="skip-unittest"
 ; Checks for mismatched argument and parameter names
 mismatched_args_check="skip-unittest"
 ; Checks for labels with the same name as variables
 label_var_same_name_check="disabled"
 ; Checks for lines longer than 120 characters
 long_line_check="skip-unittest"
 ; Checks for assignment to auto-ref function parameters
 auto_ref_assignment_check="disabled"
 ; Checks for incorrect infinite range definitions
 incorrect_infinite_range_check="skip-unittest"
 ; Checks for asserts that are always true
 useless_assert_check="skip-unittest"
 ; Check for uses of the old-style alias syntax
 alias_syntax_check="disabled"
 ; Checks for else if that should be else static if
 static_if_else_check="skip-unittest"
 ; Check for unclear lambda syntax
 lambda_return_check="skip-unittest"
 ; Check for auto function without return statement
 auto_function_check="skip-unittest"
 ; Check for sortedness of imports
 imports_sortedness="skip-unittest"
 ; Check for explicitly annotated unittests
 explicitly_annotated_unittests="disabled"
 ; Check for useless usage of the final attribute
 final_attribute_check="skip-unittest"
--- a/dub.json
+++ b/dub.json
@ -1,17 +1,38 @@
 {
 	"name": "tanya",
-	"description": "D library with event loop",
+	"description": "@nogc library. Containers, networking, metaprogramming, memory management, utilities",
 	"license": "MPL-2.0",
-	"copyright": "(c) Eugene Wissner <info@caraus.de>",
+	"copyright": "© Eugene Wissner <info@caraus.de>",
 	"authors": [
 		"Eugene Wissner"
 	],
 	"targetType": "library",
 	"dependencies-linux": {
 		"mir-linux-kernel": "~>1.0.0"
 	},
 	"configurations": [
 		{
-			"name": "library"
+			"name": "library",
 			"targetType": "staticLibrary",
 			"versions": ["TanyaPhobos"]
 		},
 		{
 			"name": "dynamic",
 			"targetType": "dynamicLibrary",
 			"versions": ["TanyaPhobos"]
 		},
 		{
 			"name": "native",
 			"targetType": "library",
 			"platforms": ["linux-x86_64-gdc"],
 			"preBuildCommands": ["ninja -C arch"],
 			"lflags": ["arch/tanya.a"],
 			"versions": ["TanyaNative"]
 		}
-	]
+	],
 	"libs-windows": ["advapi32"]
 }
--- a/source/tanya/algorithm/comparison.d
+++ b/source/tanya/algorithm/comparison.d
@ -0,0 +1,333 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * Algorithms for comparing values.
 *
 * Copyright: Eugene Wissner 2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/algorithm/comparison.d,
 *                 tanya/algorithm/comparison.d)
 */
 module tanya.algorithm.comparison;
 import tanya.algorithm.mutation;
 import tanya.math : isNaN;
 import tanya.memory.op;
 import tanya.meta.metafunction;
 import tanya.meta.trait;
 import tanya.meta.transform;
 import tanya.range.array;
 import tanya.range.primitive;
 private ref inout(Args[0]) minMax(alias cmp, Args...)(ref inout Args args)
 {
    auto actual = ((ref arg) @trusted => &arg)(args[0]);
    foreach (i, arg; args[1 .. $])
    {
        static if (isFloatingPoint!(Args[0]))
        {
            if (isNaN(arg))
            {
                continue;
            }
            if (isNaN(*actual))
            {
                actual = ((ref arg) @trusted => &arg)(args[i + 1]);
                continue;
            }
        }
        if (cmp(arg, *actual))
        {
            actual = ((ref arg) @trusted => &arg)(args[i + 1]);
        }
    }
    return *actual;
 }
 private T moveIf(T)(ref T arg)
 {
    static if (hasElaborateCopyConstructor!T && isMutable!T)
    {
        return move(arg);
    }
    else
    {
        return arg;
    }
 }
 /**
 * Finds the smallest element in the argument list or a range.
 *
 * If a range is passed, $(D_PSYMBOL min) returns a range of the same type,
 * whose front element is the smallest in the range. If more than one element
 * fulfills this condition, the front of the returned range points to
 * the first one found.
 * If $(D_PARAM range) is empty, the original range is returned.
 *
 * If $(D_PARAM Args) are floating point numbers, $(B NaN) is not considered
 * for comparison. $(B NaN) is returned only if all arguments are $(B NaN)s.
 *
 * Params:
 *  Args  = Types of the arguments. All arguments should have the same type.
 *  Range = Forward range type.
 *  args  = Argument list.
 *  range = Forward range.
 *
 * Returns: The smallest element.
 */
 CommonType!Args min(Args...)(Args args)
 if (Args.length >= 2
 && isOrderingComparable!(Args[0])
 && allSameType!(Map!(Unqual, Args)))
 {
    return moveIf(minMax!((ref a, ref b) => a < b)(args));
 }
 /// ditto
 ref inout(Unqual!(Args[0])) min(Args...)(ref inout Args args)
 if (Args.length >= 2
 && isOrderingComparable!(Args[0])
 && allSameType!(Map!(Unqual, Args)))
 {
    return minMax!((ref a, ref b) => a < b)(args);
 }
@nogc nothrow pure @safe unittest
 {
    static assert(!is(typeof(min(1, 1UL))));
 }
@nogc nothrow pure @safe unittest
 {
    assert(min(5, 3) == 3);
    assert(min(4, 4) == 4);
    assert(min(5.2, 3.0) == 3.0);
    assert(min(5.2, double.nan) == 5.2);
    assert(min(double.nan, 3.0) == 3.0);
    assert(isNaN(min(double.nan, double.nan)));
 }
 /// ditto
 Range min(Range)(Range range)
 if (isForwardRange!Range && isOrderingComparable!(ElementType!Range))
 {
    if (range.empty)
    {
        return range;
    }
    auto actual = range.save;
    range.popFront();
    for (; !range.empty; range.popFront())
    {
        if (range.front < actual.front)
        {
            actual = range.save;
        }
    }
    return actual;
 }
 ///
@nogc nothrow pure @safe unittest
 {
    assert(min(1, 2) == 1);
    assert(min(3, 2) == 2);
    assert(min(3, 1, 2) == 1);
    int[4] range = [3, 1, 1, 2];
    auto minElement = min(range[]);
    assert(minElement.front == 1);
    assert(minElement.length == 3);
 }
@nogc nothrow pure @safe unittest
 {
    assert(min(cast(ubyte[]) []).empty);
 }
 /**
 * Finds the largest element in the argument list or a range.
 *
 * If a range is passed, $(D_PSYMBOL max) returns a range of the same type,
 * whose front element is the largest in the range. If more than one element
 * fulfills this condition, the front of the returned range points to
 * the first one found.
 * If $(D_PARAM range) is empty, the original range is returned.
 *
 * If $(D_PARAM Args) are floating point numbers, $(B NaN) is not considered
 * for comparison. $(B NaN) is returned only if all arguments are $(B NaN)s.
 *
 * Params:
 *  Args  = Types of the arguments. All arguments should have the same type.
 *  Range = Forward range type.
 *  args  = Argument list.
 *  range = Forward range.
 *
 * Returns: The largest element.
 */
 CommonType!Args max(Args...)(Args args)
 if (Args.length >= 2
 && isOrderingComparable!(Args[0])
 && allSameType!(Map!(Unqual, Args)))
 {
    return moveIf(minMax!((ref a, ref b) => a > b)(args));
 }
 /// ditto
 ref inout(Unqual!(Args[0])) max(Args...)(ref inout Args args)
 if (Args.length >= 2
 && isOrderingComparable!(Args[0])
 && allSameType!(Map!(Unqual, Args)))
 {
    return minMax!((ref a, ref b) => a > b)(args);
 }
@nogc nothrow pure @safe unittest
 {
    static assert(!is(typeof(max(1, 1UL))));
 }
@nogc nothrow pure @safe unittest
 {
    assert(max(5, 3) == 5);
    assert(max(4, 4) == 4);
    assert(max(5.2, 3.0) == 5.2);
    assert(max(5.2, double.nan) == 5.2);
    assert(max(double.nan, 3.0) == 3.0);
    assert(isNaN(max(double.nan, double.nan)));
 }
 /// ditto
 Range max(Range)(Range range)
 if (isForwardRange!Range && isOrderingComparable!(ElementType!Range))
 {
    if (range.empty)
    {
        return range;
    }
    auto actual = range.save;
    range.popFront();
    for (; !range.empty; range.popFront())
    {
        if (range.front > actual.front)
        {
            actual = range.save;
        }
    }
    return actual;
 }
 ///
@nogc nothrow pure @safe unittest
 {
    assert(max(1, 2) == 2);
    assert(max(3, 2) == 3);
    assert(max(1, 3, 2) == 3);
    int[4] range = [1, 5, 5, 2];
    auto maxElement = max(range[]);
    assert(maxElement.front == 5);
    assert(maxElement.length == 3);
 }
@nogc nothrow pure @safe unittest
 {
    assert(max(cast(ubyte[]) []).empty);
 }
 // min/max compare const and mutable structs.
@nogc nothrow pure @safe unittest
 {
    static struct S
    {
        int s;
        int opCmp(typeof(this) that) const @nogc nothrow pure @safe
        {
            return this.s - that.s;
        }
    }
    {
        const s1 = S(1);
        assert(min(s1, S(2)).s == 1);
        assert(max(s1, S(2)).s == 2);
    }
    {
        auto s2 = S(2), s3 = S(3);
        assert(min(s2, s3).s == 2);
        assert(max(s2, s3).s == 3);
    }
 }
 /**
 * Compares element-wise two ranges for equality.
 *
 * If the ranges have different lengths, they aren't equal.
 *
 * Params:
 *  R1 = First range type.
 *  R2 = Second range type.
 *  r1 = First range.
 *  r2 = Second range.
 *
 * Returns: $(D_KEYWORD true) if both ranges are equal, $(D_KEYWORD false)
 *          otherwise.
 */
 bool equal(R1, R2)(R1 r1, R2 r2)
 if (allSatisfy!(isInputRange, R1, R2) && is(typeof(r1.front == r2.front)))
 {
    static if (isDynamicArray!R1
            && is(R1 == R2)
            && __traits(isPOD, ElementType!R1))
    {
        return cmp(r1, r2) == 0;
    }
    else
    {
        static if (hasLength!R1 && hasLength!R2)
        {
            if (r1.length != r2.length)
            {
                return false;
            }
        }
        for (; !r1.empty && !r2.empty; r1.popFront(), r2.popFront())
        {
            if (r1.front != r2.front)
            {
                return false;
            }
        }
        static if (hasLength!R1 && hasLength!R2)
        {
            return true;
        }
        else
        {
            return r1.empty && r2.empty;
        }
    }
 }
 ///
@nogc nothrow pure @safe unittest
 {
    int[2] range1 = [1, 2];
    assert(equal(range1[], range1[]));
    int[3] range2 = [1, 2, 3];
    assert(!equal(range1[], range2[]));
 }
--- a/source/tanya/algorithm/mutation.d
+++ b/source/tanya/algorithm/mutation.d
@ -0,0 +1,275 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * Algorithms that modify its arguments.
 *
 * Copyright: Eugene Wissner 2017-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/algorithm/mutation.d,
 *                 tanya/algorithm/mutation.d)
 */
 module tanya.algorithm.mutation;
 import tanya.memory.op;
 import tanya.meta.trait;
 private void deinitialize(bool zero, T)(ref T value)
 {
    static if (is(T == U[S], U, size_t S))
    {
        foreach (ref e; value)
        {
            deinitialize!zero(e);
        }
    }
    else
    {
        static if (isNested!T)
        {
            // Don't override the context pointer.
            enum size_t size = T.sizeof - (void*).sizeof;
        }
        else
        {
            enum size_t size = T.sizeof;
        }
        static if (zero)
        {
            fill!0((cast(void*) &value)[0 .. size]);
        }
        else
        {
            copy(typeid(T).initializer()[0 .. size], (&value)[0 .. 1]);
        }
    }
 }
 /**
 * Moves $(D_PARAM source) into $(D_PARAM target) assuming that
 * $(D_PARAM target) isn't initialized.
 *
 * Moving the $(D_PARAM source) copies it into the $(D_PARAM target) and places
 * the $(D_PARAM source) into a valid but unspecified state, which means that
 * after moving $(D_PARAM source) can be destroyed or assigned a new value, but
 * accessing it yields an unspecified value. No postblits or destructors are
 * called. If the $(D_PARAM target) should be destroyed before, use
 * $(D_PSYMBOL move).
 *
 * $(D_PARAM source) and $(D_PARAM target) must be different objects.
 *
 * Params:
 *  T      = Object type.
 *  source = Source object.
 *  target = Target object.
 *
 * See_Also: $(D_PSYMBOL move),
 *           $(D_PSYMBOL hasElaborateCopyConstructor),
 *           $(D_PSYMBOL hasElaborateDestructor).
 *
 * Precondition: `&source !is &target`.
 */
 void moveEmplace(T)(ref T source, ref T target) @system
 in
 {
    assert(&source !is &target, "Source and target must be different");
 }
 do
 {
    static if (is(T == struct) || isStaticArray!T)
    {
        copy((&source)[0 .. 1], (&target)[0 .. 1]);
        static if (hasElaborateCopyConstructor!T || hasElaborateDestructor!T)
        {
            if (typeid(T).initializer().ptr is null)
            {
                deinitialize!true(source);
            }
            else
            {
                deinitialize!false(source);
            }
        }
    }
    else
    {
        target = source;
    }
 }
 ///
@nogc nothrow pure @system unittest
 {
    static struct S
    {
        int member = 5;
        this(this) @nogc nothrow pure @safe
        {
            assert(false);
        }
    }
    S source, target = void;
    moveEmplace(source, target);
    assert(target.member == 5);
    int x1 = 5, x2;
    moveEmplace(x1, x2);
    assert(x2 == 5);
 }
 // Is pure.
@nogc nothrow pure @system unittest
 {
    struct S
    {
        this(this)
        {
        }
    }
    S source, target = void;
    static assert(is(typeof({ moveEmplace(source, target); })));
 }
 // Moves nested.
@nogc nothrow pure @system unittest
 {
    struct Nested
    {
        void method() @nogc nothrow pure @safe
        {
        }
    }
    Nested source, target = void;
    moveEmplace(source, target);
    assert(source == target);
 }
 // Emplaces static arrays.
@nogc nothrow pure @system unittest
 {
    static struct S
    {
        size_t member;
        this(size_t i) @nogc nothrow pure @safe
        {
            this.member = i;
        }
        ~this() @nogc nothrow pure @safe
        {
        }
    }
    S[2] source = [ S(5), S(5) ], target = void;
    moveEmplace(source, target);
    assert(source[0].member == 0);
    assert(target[0].member == 5);
    assert(source[1].member == 0);
    assert(target[1].member == 5);
 }
 /**
 * Moves $(D_PARAM source) into $(D_PARAM target) assuming that
 * $(D_PARAM target) isn't initialized.
 *
 * Moving the $(D_PARAM source) copies it into the $(D_PARAM target) and places
 * the $(D_PARAM source) into a valid but unspecified state, which means that
 * after moving $(D_PARAM source) can be destroyed or assigned a new value, but
 * accessing it yields an unspecified value. $(D_PARAM target) is destroyed before
 * the new value is assigned. If $(D_PARAM target) isn't initialized and
 * therefore shouldn't be destroyed, $(D_PSYMBOL moveEmplace) can be used.
 *
 * If $(D_PARAM target) isn't specified, $(D_PSYMBOL move) returns the source
 * as rvalue without calling its copy constructor or destructor.
 *
 * $(D_PARAM source) and $(D_PARAM target) are the same object,
 * $(D_PSYMBOL move) does nothing.
 *
 * Params:
 *  T      = Object type.
 *  source = Source object.
 *  target = Target object.
 *
 * See_Also: $(D_PSYMBOL moveEmplace).
 */
 void move(T)(ref T source, ref T target)
 {
    if ((() @trusted => &source is &target)())
    {
        return;
    }
    static if (hasElaborateDestructor!T)
    {
        target.__xdtor();
    }
    (() @trusted => moveEmplace(source, target))();
 }
 /// ditto
 T move(T)(ref T source) @trusted
 {
    T target = void;
    moveEmplace(source, target);
    return target;
 }
 ///
@nogc nothrow pure @safe unittest
 {
    static struct S
    {
        int member = 5;
        this(this) @nogc nothrow pure @safe
        {
            assert(false);
        }
    }
    S source, target = void;
    move(source, target);
    assert(target.member == 5);
    assert(move(target).member == 5);
    int x1 = 5, x2;
    move(x1, x2);
    assert(x2 == 5);
    assert(move(x2) == 5);
 }
 // Moves if source is target.
@nogc nothrow pure @safe unittest
 {
    int x = 5;
    move(x, x);
    assert(x == 5);
 }
 /**
 * Exchanges the values of $(D_PARAM a) and $(D_PARAM b).
 *
 * $(D_PSYMBOL swap) moves the contents of $(D_PARAM a) and $(D_PARAM b)
 * without calling its postblits or destructors.
 *
 * Params:
 *  a = The first object.
 *  b = The second object.
 */
 void swap(T)(ref T a, ref T b) @trusted
 {
    T tmp = void;
    moveEmplace(a, tmp);
    moveEmplace(b, a);
    moveEmplace(tmp, b);
 }
 ///
@nogc nothrow pure @safe unittest
 {
    int a = 3, b = 5;
    swap(a, b);
    assert(a == 5);
    assert(b == 3);
 }
--- a/source/tanya/algorithm/package.d
+++ b/source/tanya/algorithm/package.d
@ -0,0 +1,18 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * Collection of generic algorithms.
 *
 * Copyright: Eugene Wissner 2017-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/algorithm/package.d,
 *                 tanya/algorithm/package.d)
 */
 module tanya.algorithm;
 public import tanya.algorithm.comparison;
 public import tanya.algorithm.mutation;
--- a/source/tanya/async/event/epoll.d
+++ b/source/tanya/async/event/epoll.d
@ -1,187 +1,187 @@
-/* This Source Code Form is subject to the terms of the Mozilla Public
+/* This Source Code Form is subject to the terms of the Mozilla Public
- * License, v. 2.0. If a copy of the MPL was not distributed with this
+ * License, v. 2.0. If a copy of the MPL was not distributed with this
- * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
+ * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
-
+
-/**
+/**
- * Copyright: Eugene Wissner 2016.
+ * Event loop implementation for Linux.
- * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
+ *
- *                  Mozilla Public License, v. 2.0).
+ * Copyright: Eugene Wissner 2016-2018.
- * Authors: $(LINK2 mailto:belka@caraus.de, Eugene Wissner)
+ * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
- */
+ *                  Mozilla Public License, v. 2.0).
-module tanya.async.event.epoll;
+ * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
-
+ * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/async/event/epoll.d,
-version (linux):
+ *                 tanya/async/event/epoll.d)
-
+ */
-public import core.sys.linux.epoll;
+module tanya.async.event.epoll;
-import tanya.async.protocol;
+
-import tanya.async.event.selector;
+version (D_Ddoc)
-import tanya.async.loop;
+{
-import tanya.async.transport;
+}
-import tanya.async.watcher;
+else version (linux):
-import tanya.memory;
+
-import tanya.memory.mmappool;
+import core.stdc.errno;
-import tanya.network.socket;
+public import core.sys.linux.epoll;
-import core.stdc.errno;
+import core.sys.posix.unistd;
-import core.sys.posix.unistd;
+import core.time;
-import core.time;
+import tanya.algorithm.comparison;
-import std.algorithm.comparison;
+import tanya.async.event.selector;
-
+import tanya.async.loop;
-extern (C) nothrow @nogc
+import tanya.async.protocol;
-{
+import tanya.async.transport;
-	int epoll_create1(int flags);
+import tanya.async.watcher;
-	int epoll_ctl (int epfd, int op, int fd, epoll_event *event);
+import tanya.container.array;
-	int epoll_wait (int epfd, epoll_event *events, int maxevents, int timeout);
+import tanya.memory;
-}
+import tanya.network.socket;
-
+
-class EpollLoop : SelectorLoop
+extern (C) nothrow @nogc
-{
+{
-	protected int fd;
+    int epoll_create1(int flags);
-	private epoll_event[] events;
+    int epoll_ctl (int epfd, int op, int fd, epoll_event *event);
-
+    int epoll_wait (int epfd, epoll_event *events, int maxevents, int timeout);
-	/**
+}
-	 * Initializes the loop.
+
-	 */
+final class EpollLoop : SelectorLoop
-	this() @nogc
+{
-	{
+    protected int fd;
-		if ((fd = epoll_create1(EPOLL_CLOEXEC)) < 0)
+    private Array!epoll_event events;
-		{
+
-			throw MmapPool.instance.make!BadLoopException("epoll initialization failed");
+    /**
-		}
+     * Initializes the loop.
-		super();
+     */
-		MmapPool.instance.resizeArray(events, maxEvents);
+    this() @nogc
-	}
+    {
-
+        if ((fd = epoll_create1(EPOLL_CLOEXEC)) < 0)
-	/**
+        {
-	 * Free loop internals.
+            throw defaultAllocator.make!BadLoopException("epoll initialization failed");
-	 */
+        }
-	~this() @nogc
+        super();
-	{
+        events = Array!epoll_event(maxEvents);
-		MmapPool.instance.dispose(events);
+    }
-		close(fd);
+
-	}
+    /**
-
+     * Frees loop internals.
-	/**
+     */
-	 * Should be called if the backend configuration changes.
+    ~this() @nogc
-	 *
+    {
-	 * Params:
+        close(fd);
-	 * 	watcher   = Watcher.
+    }
-	 * 	oldEvents = The events were already set.
+
-	 * 	events    = The events should be set.
+    /**
-	 *
+     * Should be called if the backend configuration changes.
-	 * Returns: $(D_KEYWORD true) if the operation was successful.
+     *
-	 */
+     * Params:
-	protected override bool reify(ConnectionWatcher watcher,
+     *  watcher   = Watcher.
-	                              EventMask oldEvents,
+     *  oldEvents = The events were already set.
-	                              EventMask events) @nogc
+     *  events    = The events should be set.
-	in
+     *
-	{
+     * Returns: $(D_KEYWORD true) if the operation was successful.
-		assert(watcher !is null);
+     */
-	}
+    protected override bool reify(SocketWatcher watcher,
-	body
+                                  EventMask oldEvents,
-	{
+                                  EventMask events) @nogc
-		int op = EPOLL_CTL_DEL;
+    {
-		epoll_event ev;
+        int op = EPOLL_CTL_DEL;
-
+        epoll_event ev;
-		if (events == oldEvents)
+
-		{
+        if (events == oldEvents)
-			return true;
+        {
-		}
+            return true;
-		if (events && oldEvents)
+        }
-		{
+        if (events && oldEvents)
-			op = EPOLL_CTL_MOD;
+        {
-		}
+            op = EPOLL_CTL_MOD;
-		else if (events && !oldEvents)
+        }
-		{
+        else if (events && !oldEvents)
-			op = EPOLL_CTL_ADD;
+        {
-		}
+            op = EPOLL_CTL_ADD;
-
+        }
-		ev.data.fd = watcher.socket.handle;
+
-		ev.events = (events & (Event.read | Event.accept) ? EPOLLIN | EPOLLPRI : 0)
+        ev.data.fd = watcher.socket.handle;
-				  | (events & Event.write ? EPOLLOUT : 0)
+        ev.events = (events & (Event.read | Event.accept) ? EPOLLIN | EPOLLPRI : 0)
-				  | EPOLLET;
+                  | (events & Event.write ? EPOLLOUT : 0)
-
+                  | EPOLLET;
-		return epoll_ctl(fd, op, watcher.socket.handle, &ev) == 0;
+
-	}
+        return epoll_ctl(fd, op, watcher.socket.handle, &ev) == 0;
-
+    }
-	/**
+
-	 * Does the actual polling.
+    /**
-	 */
+     * Does the actual polling.
-	protected override void poll() @nogc
+     */
-	{
+    protected override void poll() @nogc
-		// Don't block
+    {
-		immutable timeout = cast(immutable int) blockTime.total!"msecs";
+        // Don't block
-		auto eventCount = epoll_wait(fd, events.ptr, maxEvents, timeout);
+        immutable timeout = cast(immutable int) blockTime.total!"msecs";
-
+        auto eventCount = epoll_wait(fd, events.get().ptr, maxEvents, timeout);
-		if (eventCount < 0)
+
-		{
+        if (eventCount < 0)
-			if (errno != EINTR)
+        {
-			{
+            if (errno != EINTR)
-				throw defaultAllocator.make!BadLoopException();
+            {
-			}
+                throw defaultAllocator.make!BadLoopException();
-			return;
+            }
-		}
+            return;
-
+        }
-		for (auto i = 0; i < eventCount; ++i)
+
-		{
+        for (auto i = 0; i < eventCount; ++i)
-			auto io = cast(IOWatcher) connections[events[i].data.fd];
+        {
-
+            auto transport = cast(StreamTransport) connections[events[i].data.fd];
-			if (io is null)
+
-			{
+            if (transport is null)
-				acceptConnections(connections[events[i].data.fd]);
+            {
-			}
+                auto connection = cast(ConnectionWatcher) connections[events[i].data.fd];
-			else if (events[i].events & EPOLLERR)
+                assert(connection !is null);
-			{
+
-				kill(io, null);
+                acceptConnections(connection);
-			}
+            }
-			else if (events[i].events & (EPOLLIN | EPOLLPRI | EPOLLHUP))
+            else if (events[i].events & EPOLLERR)
-			{
+            {
-				auto transport = cast(SelectorStreamTransport) io.transport;
+                kill(transport);
-				assert(transport !is null);
+                continue;
-
+            }
-				SocketException exception;
+            else if (events[i].events & (EPOLLIN | EPOLLPRI | EPOLLHUP))
-				try
+            {
-				{
+                SocketException exception;
-					ptrdiff_t received;
+                try
-					do
+                {
-					{
+                    ptrdiff_t received;
-						received = transport.socket.receive(io.output[]);
+                    do
-						io.output += received;
+                    {
-					}
+                        received = transport.socket.receive(transport.output[]);
-					while (received);
+                        transport.output += received;
-				}
+                    }
-				catch (SocketException e)
+                    while (received);
-				{
+                }
-					exception = e;
+                catch (SocketException e)
-				}
+                {
-				if (transport.socket.disconnected)
+                    exception = e;
-				{
+                }
-					kill(io, exception);
+                if (transport.socket.disconnected)
-				}
+                {
-				else if (io.output.length)
+                    kill(transport, exception);
-				{
+                    continue;
-					swapPendings.insertBack(io);
+                }
-				}
+                else if (transport.output.length)
-			}
+                {
-			else if (events[i].events & EPOLLOUT)
+                    pendings.insertBack(transport);
-			{
+                }
-				auto transport = cast(SelectorStreamTransport) io.transport;
+            }
-				assert(transport !is null);
+            if (events[i].events & EPOLLOUT)
-
+            {
-				transport.writeReady = true;
+                transport.writeReady = true;
-				if (transport.input.length)
+                if (transport.input.length)
-				{
+                {
-					feed(transport);
+                    feed(transport);
-				}
+                }
-			}
+            }
-		}
+        }
-	}
+    }
-
+
-	/**
+    /**
-	 * Returns: The blocking time.
+     * Returns: The blocking time.
-	 */
+     */
-	override protected @property inout(Duration) blockTime()
+    override protected @property inout(Duration) blockTime()
-	inout @safe pure nothrow
+    inout @safe pure nothrow
-	{
+    {
-		return min(super.blockTime, 1.dur!"seconds");
+        return min(super.blockTime, 1.dur!"seconds");
-	}
+    }
-}
+}
--- a/source/tanya/async/event/iocp.d
+++ b/source/tanya/async/event/iocp.d
@ -3,289 +3,386 @@
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
- * Copyright: Eugene Wissner 2016.
+ * Event loop implementation for Windows.
 *
 * Copyright: Eugene Wissner 2016-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
- * Authors: $(LINK2 mailto:belka@caraus.de, Eugene Wissner)
+ * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/async/event/iocp.d,
 *                 tanya/async/event/iocp.d)
 */
 module tanya.async.event.iocp;
-version (Windows):
+version (D_Ddoc)
 {
 }
 else version (Windows):
-import tanya.container.buffer;
+import core.sys.windows.mswsock;
 import core.sys.windows.winsock2;
 import tanya.async.loop;
 import tanya.async.protocol;
 import tanya.async.transport;
 import tanya.async.watcher;
 import tanya.container.buffer;
 import tanya.memory;
 import tanya.memory.mmappool;
 import tanya.network.socket;
-import core.sys.windows.basetyps;
+import tanya.sys.windows.winbase;
 import core.sys.windows.mswsock;
 import core.sys.windows.winbase;
 import core.sys.windows.windef;
 import core.sys.windows.winsock2;
-class IOCPStreamTransport : StreamTransport
+/**
 * Transport for stream sockets.
 */
 final class StreamTransport : SocketWatcher, DuplexTransport, SocketTransport
 {
-	private OverlappedConnectedSocket socket_;
+    private SocketException exception;
-	private WriteBuffer!ubyte input;
+    private ReadBuffer!ubyte output;
-	/**
+    private WriteBuffer!ubyte input;
 	 * Creates new completion port transport.
 	 * Params:
 	 * 	socket = Socket.
 	 */
 	this(OverlappedConnectedSocket socket) @nogc
 	in
 	{
 		assert(socket !is null);
 	}
 	body
 	{
 		socket_ = socket;
 		input = WriteBuffer!ubyte(8192, MmapPool.instance);
 	}
-	@property inout(OverlappedConnectedSocket) socket()
+    private Protocol protocol_;
 	inout pure nothrow @safe @nogc
 	{
 		return socket_;
 	}
-	/**
+    private bool closing;
-	 * Write some data to the transport.
+
-	 *
+    /**
-	 * Params:
+     * Creates new completion port transport.
-	 * 	data = Data to send.
+     *
-	 */
+     * Params:
-	void write(ubyte[] data) @nogc
+     *  socket = Socket.
-	{
+     *
-		immutable empty = input.length == 0;
+     * Precondition: $(D_INLINECODE socket !is null)
-		input ~= data;
+     */
-		if (empty)
+    this(OverlappedConnectedSocket socket) @nogc
-		{
+    {
-			SocketState overlapped;
+        super(socket);
-			try
+        output = ReadBuffer!ubyte(8192, 1024);
-			{
+        input = WriteBuffer!ubyte(8192);
-				overlapped = MmapPool.instance.make!SocketState;
+        active = true;
-				socket.beginSend(input[], overlapped);
+    }
-			}
+
-			catch (SocketException e)
+    /**
-			{
+     * Returns: Socket.
-				MmapPool.instance.dispose(overlapped);
+     *
-				MmapPool.instance.dispose(e);
+     * Postcondition: $(D_INLINECODE socket !is null)
-			}
+     */
-		}
+    override @property OverlappedConnectedSocket socket() pure nothrow @safe @nogc
-	}
+    out (socket)
    {
        assert(socket !is null);
    }
    do
    {
        return cast(OverlappedConnectedSocket) socket_;
    }
    /**
     * Returns $(D_PARAM true) if the transport is closing or closed.
     */
    bool isClosing() const pure nothrow @safe @nogc
    {
        return closing;
    }
    /**
     * Close the transport.
     *
     * Buffered data will be flushed.  No more data will be received.
     */
    void close() pure nothrow @safe @nogc
    {
        closing = true;
    }
    /**
     * Write some data to the transport.
     *
     * Params:
     *  data = Data to send.
     */
    void write(ubyte[] data) @nogc
    {
        input ~= data;
    }
    /**
     * Returns: Application protocol.
     */
    @property Protocol protocol() pure nothrow @safe @nogc
    {
        return protocol_;
    }
    /**
     * Switches the protocol.
     *
     * The protocol is deallocated by the event loop.
     *
     * Params:
     *  protocol = Application protocol.
     *
     * Precondition: $(D_INLINECODE protocol !is null)
     */
    @property void protocol(Protocol protocol) pure nothrow @safe @nogc
    in
    {
        assert(protocol !is null);
    }
    do
    {
        protocol_ = protocol;
    }
    /**
     * Invokes the watcher callback.
     */
    override void invoke() @nogc
    {
        if (output.length)
        {
            immutable empty = input.length == 0;
            protocol.received(output[0 .. $]);
            output.clear();
            if (empty)
            {
                SocketState overlapped;
                try
                {
                    overlapped = defaultAllocator.make!SocketState;
                    socket.beginSend(input[], overlapped);
                }
                catch (SocketException e)
                {
                    defaultAllocator.dispose(overlapped);
                    defaultAllocator.dispose(e);
                }
            }
        }
        else
        {
            protocol.disconnected(exception);
            defaultAllocator.dispose(protocol_);
            defaultAllocator.dispose(exception);
            active = false;
        }
    }
 }
-class IOCPLoop : Loop
+final class IOCPLoop : Loop
 {
-	protected HANDLE completionPort;
+    protected HANDLE completionPort;
-	protected OVERLAPPED overlap;
+    protected OVERLAPPED overlap;
-	/**
+    /**
-	 * Initializes the loop.
+     * Initializes the loop.
-	 */
+     */
-	this() @nogc
+    this() @nogc
-	{
+    {
-		super();
+        super();
-		completionPort = CreateIoCompletionPort(INVALID_HANDLE_VALUE, NULL, 0, 0);
+        completionPort = CreateIoCompletionPort(INVALID_HANDLE_VALUE, null, 0, 0);
-		if (!completionPort)
+        if (!completionPort)
-		{
+        {
-			throw make!BadLoopException(defaultAllocator,
+            throw make!BadLoopException(defaultAllocator,
-			                            "Creating completion port failed");
+                                        "Creating completion port failed");
-		}
+        }
-	}
+    }
-	/**
+    /**
-	 * Should be called if the backend configuration changes.
+     * Should be called if the backend configuration changes.
-	 *
+     *
-	 * Params:
+     * Params:
-	 * 	watcher   = Watcher.
+     *  watcher   = Watcher.
-	 * 	oldEvents = The events were already set.
+     *  oldEvents = The events were already set.
-	 * 	events    = The events should be set.
+     *  events    = The events should be set.
-	 *
+     *
-	 * Returns: $(D_KEYWORD true) if the operation was successful.
+     * Returns: $(D_KEYWORD true) if the operation was successful.
-	 */
+     */
-	override protected bool reify(ConnectionWatcher watcher,
+    override protected bool reify(SocketWatcher watcher,
-								  EventMask oldEvents,
+                                  EventMask oldEvents,
-								  EventMask events) @nogc
+                                  EventMask events) @nogc
-	{
+    {
-		SocketState overlapped;
+        SocketState overlapped;
-		if (!(oldEvents & Event.accept) && (events & Event.accept))
+        if (!(oldEvents & Event.accept) && (events & Event.accept))
-		{
+        {
-			auto socket = cast(OverlappedStreamSocket) watcher.socket;
+            auto socket = cast(OverlappedStreamSocket) watcher.socket;
-			assert(socket !is null);
+            assert(socket !is null);
-			if (CreateIoCompletionPort(cast(HANDLE) socket.handle,
+            if (CreateIoCompletionPort(cast(HANDLE) socket.handle,
-									   completionPort,
+                                       completionPort,
-									   cast(ULONG_PTR) (cast(void*) watcher),
+                                       cast(size_t) (cast(void*) watcher),
-									   0) !is completionPort)
+                                       0) !is completionPort)
-			{
+            {
-				return false;
+                return false;
-			}
+            }
-			try
+            try
-			{
+            {
-				overlapped = MmapPool.instance.make!SocketState;
+                overlapped = defaultAllocator.make!SocketState;
-				socket.beginAccept(overlapped);
+                socket.beginAccept(overlapped);
-			}
+            }
-			catch (SocketException e)
+            catch (SocketException e)
-			{
+            {
-				MmapPool.instance.dispose(overlapped);
+                defaultAllocator.dispose(overlapped);
-				defaultAllocator.dispose(e);
+                defaultAllocator.dispose(e);
-				return false;
+                return false;
-			}
+            }
-		}
+        }
-		if (!(oldEvents & Event.read) && (events & Event.read)
+        if ((!(oldEvents & Event.read) && (events & Event.read))
-			|| !(oldEvents & Event.write) && (events & Event.write))
+            || (!(oldEvents & Event.write) && (events & Event.write)))
-		{
+        {
-			auto io = cast(IOWatcher) watcher;
+            auto transport = cast(StreamTransport) watcher;
-			assert(io !is null);
+            assert(transport !is null);
-			auto transport = cast(IOCPStreamTransport) io.transport;
+            if (CreateIoCompletionPort(cast(HANDLE) transport.socket.handle,
-			assert(transport !is null);
+                                       completionPort,
                                       cast(size_t) (cast(void*) watcher),
                                       0) !is completionPort)
            {
                return false;
            }
-			if (CreateIoCompletionPort(cast(HANDLE) transport.socket.handle,
+            // Begin to read
-									   completionPort,
+            if (!(oldEvents & Event.read) && (events & Event.read))
-									   cast(ULONG_PTR) (cast(void*) watcher),
+            {
-									   0) !is completionPort)
+                try
-			{
+                {
-				return false;
+                    overlapped = defaultAllocator.make!SocketState;
-			}
+                    transport.socket.beginReceive(transport.output[], overlapped);
                }
                catch (SocketException e)
                {
                    defaultAllocator.dispose(overlapped);
                    defaultAllocator.dispose(e);
                    return false;
                }
            }
        }
        return true;
    }
-			// Begin to read
+    private void kill(StreamTransport transport,
-			if (!(oldEvents & Event.read) && (events & Event.read))
+                      SocketException exception = null) @nogc
-			{
+    in
-				try
+    {
-				{
+        assert(transport !is null);
-					overlapped = MmapPool.instance.make!SocketState;
+    }
-					transport.socket.beginReceive(io.output[], overlapped);
+    do
-				}
+    {
-				catch (SocketException e)
+        transport.socket.shutdown();
-				{
+        defaultAllocator.dispose(transport.socket);
-					MmapPool.instance.dispose(overlapped);
+        transport.exception = exception;
-					defaultAllocator.dispose(e);
+        pendings.insertBack(transport);
-					return false;
+    }
 				}
 			}
 		}
 		return true;
 	}
-	/**
+    /**
-	 * Does the actual polling.
+     * Does the actual polling.
-	 */
+     */
-	override protected void poll() @nogc
+    override protected void poll() @nogc
-	{
+    {
-		DWORD lpNumberOfBytes;
+        DWORD lpNumberOfBytes;
-		ULONG_PTR key;
+        size_t key;
-		LPOVERLAPPED overlap;
+        OVERLAPPED* overlap;
-		immutable timeout = cast(immutable int) blockTime.total!"msecs";
+        immutable timeout = cast(immutable int) blockTime.total!"msecs";
-		auto result = GetQueuedCompletionStatus(completionPort,
+        auto result = GetQueuedCompletionStatus(completionPort,
-												&lpNumberOfBytes,
+                                                &lpNumberOfBytes,
-												&key,
+                                                &key,
-												&overlap,
+                                                &overlap,
-												timeout);
+                                                timeout);
-		if (result == FALSE && overlap == NULL)
+        if (result == FALSE && overlap is null)
-		{
+        {
-			return; // Timeout
+            return; // Timeout
-		}
+        }
-		auto overlapped = (cast(SocketState) ((cast(void*) overlap) - 8));
+        enum size_t offset = size_t.sizeof * 2;
-		assert(overlapped !is null);
+        auto overlapped = cast(SocketState) ((cast(void*) overlap) - offset);
-		scope (failure)
+        assert(overlapped !is null);
-		{
+        scope (failure)
-			MmapPool.instance.dispose(overlapped);
+        {
-		}
+            defaultAllocator.dispose(overlapped);
        }
-		switch (overlapped.event)
+        switch (overlapped.event)
-		{
+        {
-			case OverlappedSocketEvent.accept:
+            case OverlappedSocketEvent.accept:
-				auto connection = cast(ConnectionWatcher) (cast(void*) key);
+                auto connection = cast(ConnectionWatcher) (cast(void*) key);
-				assert(connection !is null);
+                assert(connection !is null);
-				auto listener = cast(OverlappedStreamSocket) connection.socket;
+                auto listener = cast(OverlappedStreamSocket) connection.socket;
-				assert(listener !is null);
+                assert(listener !is null);
-				auto socket = listener.endAccept(overlapped);
+                auto socket = listener.endAccept(overlapped);
-				auto transport = MmapPool.instance.make!IOCPStreamTransport(socket);
+                auto transport = defaultAllocator.make!StreamTransport(socket);
 				auto io = MmapPool.instance.make!IOWatcher(transport, connection.protocol);
-				connection.incoming.insertBack(io);
+                connection.incoming.insertBack(transport);
-				reify(io, EventMask(Event.none), EventMask(Event.read, Event.write));
+                reify(transport, EventMask(Event.none), EventMask(Event.read, Event.write));
-				swapPendings.insertBack(connection);
+                pendings.insertBack(connection);
-				listener.beginAccept(overlapped);
+                listener.beginAccept(overlapped);
-				break;
+                break;
-			case OverlappedSocketEvent.read:
+            case OverlappedSocketEvent.read:
-				auto io = cast(IOWatcher) (cast(void*) key);
+                auto transport = cast(StreamTransport) (cast(void*) key);
-				assert(io !is null);
+                assert(transport !is null);
 				if (!io.active)
 				{
 					MmapPool.instance.dispose(io);
 					MmapPool.instance.dispose(overlapped);
 					return;
 				}
-				auto transport = cast(IOCPStreamTransport) io.transport;
+                if (!transport.active)
-				assert(transport !is null);
+                {
                    defaultAllocator.dispose(transport);
                    defaultAllocator.dispose(overlapped);
                    return;
                }
-				int received;
+                int received;
-				SocketException exception;
+                SocketException exception;
-				try
+                try
-				{
+                {
-					received = transport.socket.endReceive(overlapped);
+                    received = transport.socket.endReceive(overlapped);
-				}
+                }
-				catch (SocketException e)
+                catch (SocketException e)
-				{
+                {
-					exception = e;
+                    exception = e;
-				}
+                }
-				if (transport.socket.disconnected)
+                if (transport.socket.disconnected)
-				{
+                {
-					// We want to get one last notification to destroy the watcher
+                    // We want to get one last notification to destroy the watcher.
-					transport.socket.beginReceive(io.output[], overlapped);
+                    transport.socket.beginReceive(transport.output[], overlapped);
-					kill(io, exception);
+                    kill(transport, exception);
-				}
+                }
-				else if (received > 0)
+                else if (received > 0)
-				{
+                {
-					immutable full = io.output.free == received;
+                    immutable full = transport.output.free == received;
-					io.output += received;
+                    transport.output += received;
-					// Receive was interrupted because the buffer is full. We have to continue
+                    // Receive was interrupted because the buffer is full. We have to continue.
-					if (full)
+                    if (full)
-					{
+                    {
-						transport.socket.beginReceive(io.output[], overlapped);
+                        transport.socket.beginReceive(transport.output[], overlapped);
-					}
+                    }
-					swapPendings.insertBack(io);
+                    pendings.insertBack(transport);
-				}
+                }
-				break;
+                break;
-			case OverlappedSocketEvent.write:
+            case OverlappedSocketEvent.write:
-				auto io = cast(IOWatcher) (cast(void*) key);
+                auto transport = cast(StreamTransport) (cast(void*) key);
-				assert(io !is null);
+                assert(transport !is null);
-				auto transport = cast(IOCPStreamTransport) io.transport;
+                transport.input += transport.socket.endSend(overlapped);
-				assert(transport !is null);
+                if (transport.input.length > 0)
-
+                {
-				transport.input += transport.socket.endSend(overlapped);
+                    transport.socket.beginSend(transport.input[], overlapped);
-				if (transport.input.length)
+                }
-				{
+                else
-					transport.socket.beginSend(transport.input[], overlapped);
+                {
-				}
+                    transport.socket.beginReceive(transport.output[], overlapped);
-				else
+                    if (transport.isClosing())
-				{
+                    {
-					transport.socket.beginReceive(io.output[], overlapped);
+                        kill(transport);
-				}
+                    }
-				break;
+                }
-			default:
+                break;
-				assert(false, "Unknown event");
+            default:
-		}
+                assert(false, "Unknown event");
-	}
+        }
    }
 }
--- a/source/tanya/async/event/kqueue.d
+++ b/source/tanya/async/event/kqueue.d
@ -2,99 +2,116 @@
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
-/**
+/*
- * Copyright: Eugene Wissner 2016.
+ * Event loop implementation for *BSD.
 *
 * Copyright: Eugene Wissner 2016-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/async/event/kqueue.d,
 *                 tanya/async/event/kqueue.d)
 */
 module tanya.async.event.kqueue;
-version (OSX)
+version (D_Ddoc)
 {
-	version = MacBSD;
+}
 else version (OSX)
 {
    version = MacBSD;
 }
 else version (iOS)
 {
-	version = MacBSD;
+    version = MacBSD;
 }
 else version (TVOS)
 {
-	version = MacBSD;
+    version = MacBSD;
 }
 else version (WatchOS)
 {
-	version = MacBSD;
+    version = MacBSD;
 }
 else version (FreeBSD)
 {
-	version = MacBSD;
+    version = MacBSD;
 }
 else version (OpenBSD)
 {
-	version = MacBSD;
+    version = MacBSD;
 }
 else version (DragonFlyBSD)
 {
-	version = MacBSD;
+    version = MacBSD;
 }
 version (MacBSD):
-import core.stdc.stdint;    // intptr_t, uintptr_t
+import core.stdc.errno;
 import core.sys.posix.time; // timespec
 import core.sys.posix.unistd;
 import core.time;
 import tanya.algorithm.comparison;
 import tanya.async.event.selector;
 import tanya.async.loop;
 import tanya.async.transport;
 import tanya.async.watcher;
 import tanya.container.array;
 import tanya.memory;
 import tanya.network.socket;
 void EV_SET(kevent_t* kevp, typeof(kevent_t.tupleof) args) pure nothrow @nogc
 {
-	*kevp = kevent_t(args);
+    *kevp = kevent_t(args);
 }
 enum : short
 {
-	EVFILT_READ     =  -1,
+    EVFILT_READ     =  -1,
-	EVFILT_WRITE    =  -2,
+    EVFILT_WRITE    =  -2,
-	EVFILT_AIO      =  -3, /* attached to aio requests */
+    EVFILT_AIO      =  -3, /* attached to aio requests */
-	EVFILT_VNODE    =  -4, /* attached to vnodes */
+    EVFILT_VNODE    =  -4, /* attached to vnodes */
-	EVFILT_PROC     =  -5, /* attached to struct proc */
+    EVFILT_PROC     =  -5, /* attached to struct proc */
-	EVFILT_SIGNAL   =  -6, /* attached to struct proc */
+    EVFILT_SIGNAL   =  -6, /* attached to struct proc */
-	EVFILT_TIMER    =  -7, /* timers */
+    EVFILT_TIMER    =  -7, /* timers */
-	EVFILT_MACHPORT =  -8, /* Mach portsets */
+    EVFILT_MACHPORT =  -8, /* Mach portsets */
-	EVFILT_FS       =  -9, /* filesystem events */
+    EVFILT_FS       =  -9, /* filesystem events */
-	EVFILT_USER     = -10, /* User events */
+    EVFILT_USER     = -10, /* User events */
-	EVFILT_VM       = -12, /* virtual memory events */
+    EVFILT_VM       = -12, /* virtual memory events */
-	EVFILT_SYSCOUNT =  11
+    EVFILT_SYSCOUNT =  11
 }
 struct kevent_t
 {
-	uintptr_t    ident; /* identifier for this event */
+    uintptr_t ident; // Identifier for this event
-	short       filter; /* filter for event */
+    short filter; // Filter for event
-	ushort       flags;
+    ushort flags;
-	uint        fflags;
+    uint fflags;
-	intptr_t      data;
+    intptr_t data;
-	void        *udata; /* opaque user data identifier */
+    void* udata; // Opaque user data identifier
 }
 enum
 {
-	/* actions */
+    /* actions */
-	EV_ADD      = 0x0001, /* add event to kq (implies enable) */
+    EV_ADD      = 0x0001, /* add event to kq (implies enable) */
-	EV_DELETE   = 0x0002, /* delete event from kq */
+    EV_DELETE   = 0x0002, /* delete event from kq */
-	EV_ENABLE   = 0x0004, /* enable event */
+    EV_ENABLE   = 0x0004, /* enable event */
-	EV_DISABLE  = 0x0008, /* disable event (not reported) */
+    EV_DISABLE  = 0x0008, /* disable event (not reported) */
-	/* flags */
+    /* flags */
-	EV_ONESHOT  = 0x0010, /* only report one occurrence */
+    EV_ONESHOT  = 0x0010, /* only report one occurrence */
-	EV_CLEAR    = 0x0020, /* clear event state after reporting */
+    EV_CLEAR    = 0x0020, /* clear event state after reporting */
-	EV_RECEIPT  = 0x0040, /* force EV_ERROR on success, data=0 */
+    EV_RECEIPT  = 0x0040, /* force EV_ERROR on success, data=0 */
-	EV_DISPATCH = 0x0080, /* disable event after reporting */
+    EV_DISPATCH = 0x0080, /* disable event after reporting */
-	EV_SYSFLAGS = 0xF000, /* reserved by system */
+    EV_SYSFLAGS = 0xF000, /* reserved by system */
-	EV_FLAG1    = 0x2000, /* filter-specific flag */
+    EV_FLAG1    = 0x2000, /* filter-specific flag */
-	/* returned values */
+    /* returned values */
-	EV_EOF      = 0x8000, /* EOF detected */
+    EV_EOF      = 0x8000, /* EOF detected */
-	EV_ERROR    = 0x4000, /* error, data contains errno */
+    EV_ERROR    = 0x4000, /* error, data contains errno */
 }
 extern(C) int kqueue() nothrow @nogc;
@ -102,225 +119,213 @@ extern(C) int kevent(int kq, const kevent_t *changelist, int nchanges,
                     kevent_t *eventlist, int nevents, const timespec *timeout)
                     nothrow @nogc;
-import tanya.async.event.selector;
+final class KqueueLoop : SelectorLoop
 import tanya.async.loop;
 import tanya.async.transport;
 import tanya.async.watcher;
 import tanya.memory;
 import tanya.memory.mmappool;
 import tanya.network.socket;
 import core.stdc.errno;
 import core.sys.posix.unistd;
 import core.sys.posix.sys.time;
 import core.time;
 import std.algorithm.comparison;
 class KqueueLoop : SelectorLoop
 {
-	protected int fd;
+    protected int fd;
-	private kevent_t[] events;
+    private Array!kevent_t events;
-	private kevent_t[] changes;
+    private Array!kevent_t changes;
-	private size_t changeCount;
+    private size_t changeCount;
-	/**
+    /**
-	 * Returns: Maximal event count can be got at a time
+     * Returns: Maximal event count can be got at a time
-	 *          (should be supported by the backend).
+     *          (should be supported by the backend).
-	 */
+     */
-	override protected @property inout(uint) maxEvents()
+    override protected @property uint maxEvents()
-	inout const pure nothrow @safe @nogc
+    const pure nothrow @safe @nogc
-	{
+    {
-		return cast(uint) events.length;
+        return cast(uint) events.length;
-	}
+    }
-	this() @nogc
+    this() @nogc
-	{
+    {
-		super();
+        super();
-		if ((fd = kqueue()) == -1)
+        if ((fd = kqueue()) == -1)
-		{
+        {
-			throw MmapPool.instance.make!BadLoopException("epoll initialization failed");
+            throw make!BadLoopException(defaultAllocator,
-		}
+                                        "kqueue initialization failed");
-		MmapPool.instance.resizeArray(events, 64);
+        }
-		MmapPool.instance.resizeArray(changes, 64);
+        events = Array!kevent_t(64);
-	}
+        changes = Array!kevent_t(64);
    }
-	/**
+    /**
-	 * Free loop internals.
+     * Frees loop internals.
-	 */
+     */
-	~this() @nogc
+    ~this() @nogc
-	{
+    {
-		MmapPool.instance.dispose(events);
+        close(fd);
-		MmapPool.instance.dispose(changes);
+    }
 		close(fd);
 	}
-	private void set(socket_t socket, short filter, ushort flags) @nogc
+    private void set(SocketType socket, short filter, ushort flags) @nogc
-	{
+    {
-		if (changes.length <= changeCount)
+        if (changes.length <= changeCount)
-		{
+        {
-			MmapPool.instance.resizeArray(changes, changeCount + maxEvents);
+            changes.length = changeCount + maxEvents;
-		}
+        }
-		EV_SET(&changes[changeCount],
+        EV_SET(&changes[changeCount],
-			   cast(ulong) socket,
+               cast(ulong) socket,
-			   filter,
+               filter,
-			   flags,
+               flags,
-			   0U,
+               0U,
-			   0L,
+               0,
-			   null);
+               null);
-		++changeCount;
+        ++changeCount;
-	}
+    }
-	/**
+    /**
-	 * Should be called if the backend configuration changes.
+     * Should be called if the backend configuration changes.
-	 *
+     *
-	 * Params:
+     * Params:
-	 * 	watcher   = Watcher.
+     * 	watcher   = Watcher.
-	 * 	oldEvents = The events were already set.
+     * 	oldEvents = The events were already set.
-	 * 	events    = The events should be set.
+     * 	events    = The events should be set.
-	 *
+     *
-	 * Returns: $(D_KEYWORD true) if the operation was successful.
+     * Returns: $(D_KEYWORD true) if the operation was successful.
-	 */
+     */
-	override protected bool reify(ConnectionWatcher watcher,
+    override protected bool reify(SocketWatcher watcher,
-	                              EventMask oldEvents,
+                                  EventMask oldEvents,
-	                              EventMask events) @nogc
+                                  EventMask events) @nogc
-	{
+    {
-		if (events != oldEvents)
+        if (events != oldEvents)
-		{
+        {
-			if (oldEvents & Event.read || oldEvents & Event.accept)
+            if (oldEvents & Event.read || oldEvents & Event.accept)
-			{
+            {
-				set(watcher.socket.handle, EVFILT_READ, EV_DELETE);
+                set(watcher.socket.handle, EVFILT_READ, EV_DELETE);
-			}
+            }
-			if (oldEvents & Event.write)
+            if (oldEvents & Event.write)
-			{
+            {
-				set(watcher.socket.handle, EVFILT_WRITE, EV_DELETE);
+                set(watcher.socket.handle, EVFILT_WRITE, EV_DELETE);
-			}
+            }
-		}
+        }
-		if (events & (Event.read | events & Event.accept))
+        if (events & (Event.read | events & Event.accept))
-		{
+        {
-			set(watcher.socket.handle, EVFILT_READ, EV_ADD | EV_ENABLE);
+            set(watcher.socket.handle, EVFILT_READ, EV_ADD | EV_ENABLE);
-		}
+        }
-		if (events & Event.write)
+        if (events & Event.write)
-		{
+        {
-			set(watcher.socket.handle, EVFILT_WRITE, EV_ADD | EV_DISPATCH);
+            set(watcher.socket.handle, EVFILT_WRITE, EV_ADD | EV_DISPATCH);
-		}
+        }
-		return true;
+        return true;
-	}
+    }
-	/**
+    /**
-	 * Does the actual polling.
+     * Does the actual polling.
-	 */
+     */
-	protected override void poll() @nogc
+    protected override void poll() @nogc
-	{
+    {
-		timespec ts;
+        timespec ts;
-		blockTime.split!("seconds", "nsecs")(ts.tv_sec, ts.tv_nsec);
+        blockTime.split!("seconds", "nsecs")(ts.tv_sec, ts.tv_nsec);
-		if (changeCount > maxEvents) 
+        if (changeCount > maxEvents)
-		{
+        {
-			MmapPool.instance.resizeArray(events, changes.length);
+            events.length = changes.length;
-		}
+        }
-		auto eventCount = kevent(fd, changes.ptr, cast(int) changeCount, events.ptr, maxEvents, &ts);
+        auto eventCount = kevent(fd,
-		changeCount = 0;
+                                 changes.get().ptr,
                                 cast(int) changeCount,
                                 events.get().ptr,
                                 maxEvents,
                                 &ts);
        changeCount = 0;
-		if (eventCount < 0)
+        if (eventCount < 0)
-		{
+        {
-			if (errno != EINTR)
+            if (errno != EINTR)
-			{
+            {
-				throw defaultAllocator.make!BadLoopException();
+                throw defaultAllocator.make!BadLoopException();
-			}
+            }
-			return;
+            return;
-		}
+        }
-		for (int i; i < eventCount; ++i)
+        for (int i; i < eventCount; ++i)
-		{
+        {
-			assert(connections.length > events[i].ident);
+            assert(connections.length > events[i].ident);
-			IOWatcher io = cast(IOWatcher) connections[events[i].ident];
+            auto transport = cast(StreamTransport) connections[events[i].ident];
-			// If it is a ConnectionWatcher. Accept connections.
+            // If it is a ConnectionWatcher. Accept connections.
-			if (io is null)
+            if (transport is null)
-			{
+            {
-				acceptConnections(connections[events[i].ident]);
+                auto connection = cast(ConnectionWatcher) connections[events[i].ident];
-			}
+                assert(connection !is null);
 			else if (events[i].flags & EV_ERROR)
 			{
 				kill(io, null);
 			}
 			else if (events[i].filter == EVFILT_READ)
 			{
 				auto transport = cast(SelectorStreamTransport) io.transport;
 				assert(transport !is null);
-				SocketException exception;
+                acceptConnections(connection);
-				try
+            }
-				{
+            else if (events[i].flags & EV_ERROR)
-					ptrdiff_t received;
+            {
-					do
+                kill(transport);
-					{
+            }
-						received = transport.socket.receive(io.output[]);
+            else if (events[i].filter == EVFILT_READ)
-						io.output += received;
+            {
-					}
+                SocketException exception;
-					while (received);
+                try
-				}
+                {
-				catch (SocketException e)
+                    ptrdiff_t received;
-				{
+                    do
-					exception = e;
+                    {
-				}
+                        received = transport.socket.receive(transport.output[]);
-				if (transport.socket.disconnected)
+                        transport.output += received;
-				{
+                    }
-					kill(io, exception);
+                    while (received);
-				}
+                }
-				else if (io.output.length)
+                catch (SocketException e)
-				{
+                {
-					swapPendings.insertBack(io);
+                    exception = e;
-				}
+                }
-			}
+                if (transport.socket.disconnected)
-			else if (events[i].filter == EVFILT_WRITE)
+                {
-			{
+                    kill(transport, exception);
-				auto transport = cast(SelectorStreamTransport) io.transport;
+                }
-				assert(transport !is null);
+                else if (transport.output.length)
                {
                    pendings.insertBack(transport);
                }
            }
            else if (events[i].filter == EVFILT_WRITE)
            {
                transport.writeReady = true;
                if (transport.input.length)
                {
                    feed(transport);
                }
            }
        }
    }
-				transport.writeReady = true;
+    /**
-				if (transport.input.length)
+     * Returns: The blocking time.
-				{
+     */
-					feed(transport);
+    override protected @property inout(Duration) blockTime()
-				}
+    inout @nogc @safe pure nothrow
-			}
+    {
-		}
+        return min(super.blockTime, 1.dur!"seconds");
-	}
+    }
-	/**
+    /**
-	 * Returns: The blocking time.
+     * If the transport couldn't send the data, the further sending should
-	 */
+     * be handled by the event loop.
-	override protected @property inout(Duration) blockTime()
+     *
-	inout @nogc @safe pure nothrow
+     * Params:
-	{
+     * 	transport = Transport.
-		return min(super.blockTime, 1.dur!"seconds");
+     * 	exception = Exception thrown on sending.
-	}
+     *
-
+     * Returns: $(D_KEYWORD true) if the operation could be successfully
-	/**
+     *          completed or scheduled, $(D_KEYWORD false) otherwise (the
-	 * If the transport couldn't send the data, the further sending should
+     *          transport will be destroyed then).
-	 * be handled by the event loop.
+     */
-	 *
+    protected override bool feed(StreamTransport transport,
-	 * Params:
+                                 SocketException exception = null) @nogc
-	 * 	transport = Transport.
+    {
-	 * 	exception = Exception thrown on sending.
+        if (!super.feed(transport, exception))
-	 *
+        {
-	 * Returns: $(D_KEYWORD true) if the operation could be successfully
+            return false;
-	 *          completed or scheduled, $(D_KEYWORD false) otherwise (the
+        }
-	 *          transport is be destroyed then).
+        if (!transport.writeReady)
-	 */
+        {
-	protected override bool feed(SelectorStreamTransport transport,
+            set(transport.socket.handle, EVFILT_WRITE, EV_DISPATCH);
-	                             SocketException exception = null) @nogc
+            return true;
-	{
+        }
-		if (!super.feed(transport, exception))
+        return false;
-		{
+    }
 			return false;
 		}
 		if (!transport.writeReady)
 		{
 			set(transport.socket.handle, EVFILT_WRITE, EV_DISPATCH);
 			return true;
 		}
 		return false;
 	}
 }
--- a/source/tanya/async/event/selector.d
+++ b/source/tanya/async/event/selector.d
@ -2,258 +2,404 @@
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
-/**
+/*
- * Copyright: Eugene Wissner 2016.
+ * This module contains base implementations for reactor event loops.
 *
 * Copyright: Eugene Wissner 2016-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
- * Authors: $(LINK2 mailto:belka@caraus.de, Eugene Wissner)
+ * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/async/event/selector.d,
 *                 tanya/async/event/selector.d)
 */
 module tanya.async.event.selector;
-version (Posix):
+version (D_Ddoc)
 {
 }
 else version (Posix):
 import tanya.async.loop;
 import tanya.async.protocol;
 import tanya.async.transport;
 import tanya.async.watcher;
 import tanya.container.array;
 import tanya.container.buffer;
 import tanya.memory;
 import tanya.memory.mmappool;
 import tanya.network.socket;
 import core.sys.posix.netinet.in_;
 import core.stdc.errno;
 /**
 * Transport for stream sockets.
 */
-class SelectorStreamTransport : StreamTransport
+package class StreamTransport : SocketWatcher, DuplexTransport, SocketTransport
 {
-	private ConnectedSocket socket_;
+    private SelectorLoop loop;
-	/// Input buffer.
+    private SocketException exception;
 	package WriteBuffer!ubyte input;
-	private SelectorLoop loop;
+    package ReadBuffer!ubyte output;
-	/// Received notification that the underlying socket is write-ready.
+    package WriteBuffer!ubyte input;
 	package bool writeReady;
-	/**
+    private Protocol protocol_;
 	 * Params:
 	 * 	loop     = Event loop.
 	 * 	socket   = Socket.
 	 */
 	this(SelectorLoop loop, ConnectedSocket socket) @nogc
 	{
 		socket_ = socket;
 		this.loop = loop;
 		input = WriteBuffer!ubyte(8192, MmapPool.instance);
 	}
-	/**
+    private bool closing;
 	 * Returns: Transport socket.
 	 */
 	inout(ConnectedSocket) socket() inout pure nothrow @safe @nogc
 	{
 		return socket_;
 	}
-	/**
+    /// Received notification that the underlying socket is write-ready.
-	 * Write some data to the transport.
+    package bool writeReady;
-	 *
+
-	 * Params:
+    /**
-	 * 	data = Data to send.
+     * Params:
-	 */
+     *  loop   = Event loop.
-	void write(ubyte[] data) @nogc
+     *  socket = Socket.
-	{
+     *
-		if (!data.length)
+     * Precondition: $(D_INLINECODE loop !is null && socket !is null)
-		{
+     */
-			return;
+    this(SelectorLoop loop, ConnectedSocket socket) @nogc
-		}
+    in 
-		// Try to write if the socket is write ready.
+    {
-		if (writeReady)
+        assert(loop !is null);
-		{
+    }
-			ptrdiff_t sent;
+    do
-			SocketException exception;
+    {
-			try
+        super(socket);
-			{
+        this.loop = loop;
-				sent = socket.send(data);
+        output = ReadBuffer!ubyte(8192, 1024);
-				if (sent == 0)
+        input = WriteBuffer!ubyte(8192);
-				{
+        active = true;
-					writeReady = false;
+    }
-				}
+
-			}
+    /**
-			catch (SocketException e)
+     * Returns: Socket.
-			{
+     *
-				writeReady = false;
+     * Postcondition: $(D_INLINECODE socket !is null)
-				exception = e;
+     */
-			}
+    override @property ConnectedSocket socket() pure nothrow @safe @nogc
-			if (sent < data.length)
+    out (socket)
-			{
+    {
-				input ~= data[sent..$];
+        assert(socket !is null);
-				loop.feed(this, exception);
+    }
-			}
+    do
-		}
+    {
-		else
+        return cast(ConnectedSocket) socket_;
-		{
+    }
-			input ~= data;
+
-		}
+    private @property void socket(ConnectedSocket socket)
-	}
+    pure nothrow @safe @nogc
    in
    {
        assert(socket !is null);
    }
    do
    {
        socket_ = socket;
    }
    /**
     * Returns: Application protocol.
     */
    @property Protocol protocol() pure nothrow @safe @nogc
    {
        return protocol_;
    }
    /**
     * Switches the protocol.
     *
     * The protocol is deallocated by the event loop.
     *
     * Params:
     *  protocol = Application protocol.
     *
     * Precondition: $(D_INLINECODE protocol !is null)
     */
    @property void protocol(Protocol protocol) pure nothrow @safe @nogc
    in
    {
        assert(protocol !is null);
    }
    do
    {
        protocol_ = protocol;
    }
    /**
     * Returns $(D_PARAM true) if the transport is closing or closed.
     */
    bool isClosing() const pure nothrow @safe @nogc
    {
        return closing;
    }
    /**
     * Close the transport.
     *
     * Buffered data will be flushed.  No more data will be received.
     */
    void close() @nogc
    {
        closing = true;
        loop.reify(this,
                   EventMask(Event.read, Event.write),
                   EventMask(Event.write));
    }
    /**
     * Invokes the watcher callback.
     */
    override void invoke() @nogc
    {
        if (output.length)
        {
            protocol.received(output[0 .. $]);
            output.clear();
            if (isClosing() && input.length == 0)
            {
                loop.kill(this);
            }
        }
        else
        {
            protocol.disconnected(exception);
            defaultAllocator.dispose(protocol_);
            defaultAllocator.dispose(exception);
            active = false;
        }
    }
    /**
     * Write some data to the transport.
     *
     * Params:
     *  data = Data to send.
     */
    void write(ubyte[] data) @nogc
    {
        if (!data.length)
        {
            return;
        }
        // Try to write if the socket is write ready.
        if (writeReady)
        {
            ptrdiff_t sent;
            SocketException exception;
            try
            {
                sent = socket.send(data);
                if (sent == 0)
                {
                    writeReady = false;
                }
            }
            catch (SocketException e)
            {
                writeReady = false;
                exception = e;
            }
            if (sent < data.length)
            {
                input ~= data[sent..$];
                loop.feed(this, exception);
            }
        }
        else
        {
            input ~= data;
        }
    }
 }
 abstract class SelectorLoop : Loop
 {
-	/// Pending connections.
+    /// Pending connections.
-	protected ConnectionWatcher[] connections;
+    protected Array!SocketWatcher connections;
-	this() @nogc
+    this() @nogc
-	{
+    {
-		super();
+        super();
-		MmapPool.instance.resizeArray(connections, maxEvents);
+        this.connections = Array!SocketWatcher(maxEvents);
-	}
+    }
-	~this() @nogc
+    ~this() @nogc
-	{
+    {
-		foreach (ref connection; connections)
+        foreach (ref connection; this.connections[])
-		{
+        {
-			// We want to free only IOWatchers. ConnectionWatcher are created by the
+            // We want to free only the transports. ConnectionWatcher are
-			// user and should be freed by himself.
+            // created by the user and should be freed by himself.
-			auto io = cast(IOWatcher) connection;
+            if (cast(StreamTransport) connection !is null)
-			if (io !is null)
+            {
-			{
+                defaultAllocator.dispose(connection);
-				MmapPool.instance.dispose(io);
+            }
-				connection = null;
+        }
-			}
+    }
 		}
 		MmapPool.instance.dispose(connections);
 	}
-	/**
+    /**
-	 * If the transport couldn't send the data, the further sending should
+     * Should be called if the backend configuration changes.
-	 * be handled by the event loop.
+     *
-	 *
+     * Params:
-	 * Params:
+     *  watcher   = Watcher.
-	 * 	transport = Transport.
+     *  oldEvents = The events were already set.
-	 * 	exception = Exception thrown on sending.
+     *  events    = The events should be set.
-	 *
+     *
-	 * Returns: $(D_KEYWORD true) if the operation could be successfully
+     * Returns: $(D_KEYWORD true) if the operation was successful.
-	 *          completed or scheduled, $(D_KEYWORD false) otherwise (the
+     */
-	 *          transport will be destroyed then).
+    override abstract protected bool reify(SocketWatcher watcher,
-	 */
+                                           EventMask oldEvents,
-	protected bool feed(SelectorStreamTransport transport,
+                                           EventMask events) @nogc;
 	                    SocketException exception = null) @nogc
 	{
 		while (transport.input.length && transport.writeReady)
 		{
 			try
 			{
 				ptrdiff_t sent = transport.socket.send(transport.input[]);
 				if (sent == 0)
 				{
 					transport.writeReady = false;
 				}
 				else
 				{
 					transport.input += sent;
 				}
 			}
 			catch (SocketException e)
 			{
 				exception = e;
 				transport.writeReady = false;
 			}
 		}
 		if (exception !is null)
 		{
 			auto watcher = cast(IOWatcher) connections[transport.socket.handle];
 			assert(watcher !is null);
-			kill(watcher, exception);
+    /**
-			return false;
+     * Kills the watcher and closes the connection.
-		}
+     *
-		return true;
+     * Params:
-	}
+     *  transport = Transport.
     *  exception = Occurred exception.
     */
    protected void kill(StreamTransport transport,
                        SocketException exception = null) @nogc
    in
    {
        assert(transport !is null);
    }
    do
    {
        transport.socket.shutdown();
        defaultAllocator.dispose(transport.socket);
        transport.exception = exception;
        pendings.insertBack(transport);
    }
-	/**
+    /**
-	 * Start watching.
+     * If the transport couldn't send the data, the further sending should
-	 *
+     * be handled by the event loop.
-	 * Params:
+     *
-	 * 	watcher = Watcher.
+     * Params:
-	 */
+     *  transport = Transport.
-	override void start(ConnectionWatcher watcher) @nogc
+     *  exception = Exception thrown on sending.
-	{
+     *
-		if (watcher.active)
+     * Returns: $(D_KEYWORD true) if the operation could be successfully
-		{
+     *          completed or scheduled, $(D_KEYWORD false) otherwise (the
-			return;
+     *          transport will be destroyed then).
-		}
+     */
    protected bool feed(StreamTransport transport,
                        SocketException exception = null) @nogc
    in
    {
        assert(transport !is null);
    }
    do
    {
        while (transport.input.length && transport.writeReady)
        {
            try
            {
                ptrdiff_t sent = transport.socket.send(transport.input[]);
                if (sent == 0)
                {
                    transport.writeReady = false;
                }
                else
                {
                    transport.input += sent;
                }
            }
            catch (SocketException e)
            {
                exception = e;
                transport.writeReady = false;
            }
        }
        if (exception !is null)
        {
            kill(transport, exception);
            return false;
        }
        if (transport.input.length == 0 && transport.isClosing())
        {
            kill(transport);
        }
        return true;
    }
-		if (connections.length <= watcher.socket)
+    /**
-		{
+     * Start watching.
-			MmapPool.instance.resizeArray(connections, watcher.socket.handle + maxEvents / 2);
+     *
-		}
+     * Params:
-		connections[watcher.socket.handle] = watcher;
+     *  watcher = Watcher.
     */
    override void start(ConnectionWatcher watcher) @nogc
    {
        if (watcher.active)
        {
            return;
        }
-		super.start(watcher);
+        if (connections.length <= watcher.socket)
-	}
+        {
            connections.length = watcher.socket.handle + maxEvents / 2;
        }
        connections[watcher.socket.handle] = watcher;
-	/**
+        super.start(watcher);
-	 * Accept incoming connections.
+    }
 	 *
 	 * Params:
 	 * 	connection = Connection watcher ready to accept.
 	 */
 	package void acceptConnections(ConnectionWatcher connection) @nogc
 	in
 	{
 		assert(connection !is null);
 	}
 	body
 	{
 		while (true)
 		{
 			ConnectedSocket client;
 			try
 			{
 				client = (cast(StreamSocket) connection.socket).accept();
 			}
 			catch (SocketException e)
 			{
 				defaultAllocator.dispose(e);
 				break;
 			}
 			if (client is null)
 			{
 				break;
 			}
-			IOWatcher io;
+    /**
-			auto transport = MmapPool.instance.make!SelectorStreamTransport(this, client);
+     * Accept incoming connections.
     *
     * Params:
     *  connection = Connection watcher ready to accept.
     */
    package void acceptConnections(ConnectionWatcher connection) @nogc
    in
    {
        assert(connection !is null);
    }
    do
    {
        while (true)
        {
            ConnectedSocket client;
            try
            {
                client = (cast(StreamSocket) connection.socket).accept();
            }
            catch (SocketException e)
            {
                defaultAllocator.dispose(e);
                break;
            }
            if (client is null)
            {
                break;
            }
-			if (connections.length > client.handle)
+            StreamTransport transport;
 			{
 				io = cast(IOWatcher) connections[client.handle];
 			}
 			else
 			{
 				MmapPool.instance.resizeArray(connections, client.handle + maxEvents / 2);
 			}
 			if (io is null)
 			{
 				io = MmapPool.instance.make!IOWatcher(transport,
 				                                      connection.protocol);
 				connections[client.handle] = io;
 			}
 			else
 			{
 				io(transport, connection.protocol);
 			}
-			reify(io, EventMask(Event.none), EventMask(Event.read, Event.write));
+            if (connections.length > client.handle)
-			connection.incoming.insertBack(io);
+            {
-		}
+                transport = cast(StreamTransport) connections[client.handle];
            }
            else
            {
                connections.length = client.handle + maxEvents / 2;
            }
            if (transport is null)
            {
                transport = defaultAllocator.make!StreamTransport(this, client);
                connections[client.handle] = transport;
            }
            else
            {
                transport.socket = client;
            }
-		if (!connection.incoming.empty)
+            reify(transport, EventMask(Event.none), EventMask(Event.read, Event.write));
-		{
+            connection.incoming.insertBack(transport);
-			swapPendings.insertBack(connection);
+        }
-		}
+
-	}
+        if (!connection.incoming.empty)
        {
            pendings.insertBack(connection);
        }
    }
 }
--- a/source/tanya/async/iocp.d
+++ b/source/tanya/async/iocp.d
@ -3,17 +3,41 @@
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
- * Copyright: Eugene Wissner 2016.
+ * This module provides API for Windows I/O Completion Ports.
 *
 * Note: Available only on Windows.
 *
 * Copyright: Eugene Wissner 2016-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
- * Authors: $(LINK2 mailto:belka@caraus.de, Eugene Wissner)
+ * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/async/iocp.d,
 *                 tanya/async/iocp.d)
 */
 module tanya.async.iocp;
-version (Windows):
+version (Windows)
 {
    version = WindowsDoc;
 }
 else version (D_Ddoc)
 {
    version = WindowsDoc;
    version (Windows)
    {
    }
    else
    {
        private struct OVERLAPPED
        {
        }
        private alias HANDLE = void*;
    }
 }
-import core.sys.windows.winbase;
+version (WindowsDoc):
-import core.sys.windows.windef;
+
 import tanya.sys.windows.winbase;
 /**
 * Provides an extendable representation of a Win32 $(D_PSYMBOL OVERLAPPED)
@ -21,12 +45,12 @@ import core.sys.windows.windef;
 */
 class State
 {
-	/// For internal use by Windows API.
+    /// For internal use by Windows API.
-	align(1) OVERLAPPED overlapped;
+    align(1) OVERLAPPED overlapped;
-	/// File/socket handle.
+    /// File/socket handle.
-	HANDLE handle;
+    HANDLE handle;
-	/// For keeping events or event masks.
+    /// For keeping events or event masks.
-	int event;
+    int event;
 }
--- a/source/tanya/async/loop.d
+++ b/source/tanya/async/loop.d
@ -3,10 +3,8 @@
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
- * Copyright: Eugene Wissner 2016.
+ * Interface for the event loop implementations and the default event loop
- * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
+ * chooser.
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:belka@caraus.de, Eugene Wissner)
 *
 * ---
 * import tanya.async;
@ -15,100 +13,132 @@
 *
 * class EchoProtocol : TransmissionControlProtocol
 * {
- * 	private DuplexTransport transport;
+ *     private DuplexTransport transport;
 *
- * 	void received(ubyte[] data) @nogc
+ *     void received(in ubyte[] data) @nogc
- * 	{
+ *     {
- * 		transport.write(data);
+ *         ubyte[512] buffer;
- * 	}
+ *         buffer[0 .. data.length] = data;
 *         transport.write(buffer[]);
 *     }
 *
- * 	void connected(DuplexTransport transport) @nogc
+ *     void connected(DuplexTransport transport) @nogc
- * 	{
+ *     {
- * 		this.transport = transport;
+ *         this.transport = transport;
- * 	}
+ *     }
 *
- * 	void disconnected(SocketException e = null) @nogc
+ *     void disconnected(SocketException e) @nogc
- * 	{
+ *     {
- * 	}
+ *     }
 * }
 *
 * void main()
 * {
- * 	auto address = defaultAllocator.make!InternetAddress("127.0.0.1", cast(ushort) 8192);
+ *     auto address = defaultAllocator.make!InternetAddress("127.0.0.1", cast(ushort) 8192);
 *
- * 	version (Windows)
+ *     version (Windows)
- * 	{
+ *     {
- * 		auto sock = defaultAllocator.make!OverlappedStreamSocket(AddressFamily.INET);
+ *         auto sock = defaultAllocator.make!OverlappedStreamSocket(AddressFamily.inet);
- * 	}
+ *     }
- * 	else
+ *     else
- * 	{
+ *     {
- * 		auto sock = defaultAllocator.make!StreamSocket(AddressFamily.INET);
+ *         auto sock = defaultAllocator.make!StreamSocket(AddressFamily.inet);
- * 		sock.blocking = false;
+ *         sock.blocking = false;
- * 	}
+ *     }
 *
- * 	sock.bind(address);
+ *     sock.bind(address);
- * 	sock.listen(5);
+ *     sock.listen(5);
 *
- * 	auto io = defaultAllocator.make!ConnectionWatcher(sock);
+ *     auto io = defaultAllocator.make!ConnectionWatcher(sock);
- * 	io.setProtocol!EchoProtocol;
+ *     io.setProtocol!EchoProtocol;
 *
- * 	defaultLoop.start(io);
+ *     defaultLoop.start(io);
- * 	defaultLoop.run();
+ *     defaultLoop.run();
 *
- * 	sock.shutdown();
+ *     sock.shutdown();
- * 	defaultAllocator.dispose(io);
+ *     defaultAllocator.dispose(io);
- * 	defaultAllocator.dispose(sock);
+ *     defaultAllocator.dispose(sock);
- * 	defaultAllocator.dispose(address);
+ *     defaultAllocator.dispose(address);
 * }
 * ---
 *
 * Copyright: Eugene Wissner 2016-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/async/loop.d,
 *                 tanya/async/loop.d)
 */
 module tanya.async.loop;
 import core.time;
 import std.algorithm.iteration;
 import std.algorithm.mutation;
 import std.typecons;
 import tanya.async.protocol;
 import tanya.async.transport;
 import tanya.async.watcher;
 import tanya.container.buffer;
-import tanya.container.queue;
+import tanya.container.list;
 import tanya.memory;
 import tanya.memory.mmappool;
 import tanya.network.socket;
 version (DisableBackends)
 {
 }
 else version (D_Ddoc)
 {
 }
 else version (linux)
 {
-	import tanya.async.event.epoll;
+    import tanya.async.event.epoll;
-	version = Epoll;
+    version = Epoll;
 }
 else version (Windows)
 {
-	import tanya.async.event.iocp;
+    import tanya.async.event.iocp;
-	version = IOCP;
+    version = IOCP;
 }
 else version (OSX)
 {
-	version = Kqueue;
+    version = Kqueue;
 }
 else version (iOS)
 {
-	version = Kqueue;
+    version = Kqueue;
 }
 else version (FreeBSD)
 {
-	version = Kqueue;
+    version = Kqueue;
 }
 else version (OpenBSD)
 {
-	version = Kqueue;
+    version = Kqueue;
 }
 else version (DragonFlyBSD)
 {
-	version = Kqueue;
+    version = Kqueue;
 }
 version (unittest)
 {
    final class TestLoop : Loop
    {
        override protected bool reify(SocketWatcher watcher,
                                      EventMask oldEvents,
                                      EventMask events) @nogc
        {
            return true;
        }
        override protected void poll() @nogc
        {
            assert(!this.done);
            unloop();
        }
        override protected @property uint maxEvents()
        const pure nothrow @safe @nogc
        {
            return 64U;
        }
    }
 }
 /**
@ -116,11 +146,11 @@ else version (DragonFlyBSD)
 */
 enum Event : uint
 {
-	none   = 0x00,       /// No events.
+    none   = 0x00,       /// No events.
-	read   = 0x01,       /// Non-blocking read call.
+    read   = 0x01,       /// Non-blocking read call.
-	write  = 0x02,       /// Non-blocking write call.
+    write  = 0x02,       /// Non-blocking write call.
-	accept = 0x04,       /// Connection made.
+    accept = 0x04,       /// Connection made.
-	error  = 0x80000000, /// Sent when an error occurs.
+    error  = 0x80000000, /// Sent when an error occurs.
 }
 alias EventMask = BitFlags!Event;
@ -130,172 +160,193 @@ alias EventMask = BitFlags!Event;
 */
 abstract class Loop
 {
-	/// Pending watchers.
+    private bool done = true;
 	protected Queue!Watcher* pendings;
-	/// Ditto.
+    /// Pending watchers.
-	protected Queue!Watcher* swapPendings;
+    protected DList!Watcher pendings;
-	/**
+    /**
-	 * Returns: Maximal event count can be got at a time
+     * Returns: Maximal event count can be got at a time
-	 *          (should be supported by the backend).
+     *          (should be supported by the backend).
-	 */
+     */
-	protected @property inout(uint) maxEvents()
+    protected @property uint maxEvents()
-	inout const pure nothrow @safe @nogc
+    const pure nothrow @safe @nogc
-	{
+    {
-		return 128U;
+        return 128U;
-	}
+    }
-	/**
+    @nogc @system unittest
-	 * Initializes the loop.
+    {
-	 */
+        auto loop = defaultAllocator.make!TestLoop;
-	this() @nogc
+        assert(loop.maxEvents == 64);
 	{
 		pendings = MmapPool.instance.make!(Queue!Watcher)(MmapPool.instance);
 		swapPendings = MmapPool.instance.make!(Queue!Watcher)(MmapPool.instance);
 	}
-	/**
+        defaultAllocator.dispose(loop);
-	 * Frees loop internals.
+    }
 	 */
 	~this() @nogc
 	{
 		foreach (w; *pendings)
 		{
 			MmapPool.instance.dispose(w);
 		}
 		MmapPool.instance.dispose(pendings);
-		foreach (w; *swapPendings)
+    /**
-		{
+     * Initializes the loop.
-			MmapPool.instance.dispose(w);
+     */
-		}
+    this() @nogc
-		MmapPool.instance.dispose(swapPendings);
+    {
-	}
+    }
-	/**
+    /**
-	 * Starts the loop.
+     * Frees loop internals.
-	 */
+     */
-	void run() @nogc
+    ~this() @nogc
-	{
+    {
-		done_ = false;
+        for (; !this.pendings.empty; this.pendings.removeFront())
-		do
+        {
-		{
+            defaultAllocator.dispose(this.pendings.front);
-			poll();
+        }
    }
-			// Invoke pendings
+    /**
-			swapPendings.each!((ref p) @nogc => p.invoke());
+     * Starts the loop.
     */
    void run() @nogc
    {
        this.done = false;
        do
        {
            poll();
-			swap(pendings, swapPendings);
+            // Invoke pendings
-		}
+            for (; !this.pendings.empty; this.pendings.removeFront())
-		while (!done_);
+            {
-	}
+                this.pendings.front.invoke();
            }
        }
        while (!this.done);
    }
-	/**
+    /**
-	 * Break out of the loop.
+     * Break out of the loop.
-	 */
+     */
-	void unloop() @safe pure nothrow @nogc
+    void unloop() @safe pure nothrow @nogc
-	{
+    {
-		done_ = true;
+        this.done = true;
-	}
+    }
-	/**
+    @nogc @system unittest
-	 * Start watching.
+    {
-	 *
+        auto loop = defaultAllocator.make!TestLoop;
-	 * Params:
+        assert(loop.done);
 	 * 	watcher = Watcher.
 	 */
 	void start(ConnectionWatcher watcher) @nogc
 	{
 		if (watcher.active)
 		{
 			return;
 		}
 		watcher.active = true;
 		reify(watcher, EventMask(Event.none), EventMask(Event.accept));
 	}
-	/**
+        loop.run();
-	 * Stop watching.
+        assert(loop.done);
 	 *
 	 * Params:
 	 * 	watcher = Watcher.
 	 */
 	void stop(ConnectionWatcher watcher) @nogc
 	{
 		if (!watcher.active)
 		{
 			return;
 		}
 		watcher.active = false;
-		reify(watcher, EventMask(Event.accept), EventMask(Event.none));
+        defaultAllocator.dispose(loop);
-	}
+    }
-	/**
+    @nogc @system unittest
-	 * Should be called if the backend configuration changes.
+    {
-	 *
+        auto loop = defaultAllocator.make!TestLoop;
-	 * Params:
+        auto watcher = defaultAllocator.make!DummyWatcher;
-	 * 	watcher   = Watcher.
+        loop.pendings.insertBack(watcher);
 	 * 	oldEvents = The events were already set.
 	 * 	events    = The events should be set.
 	 *
 	 * Returns: $(D_KEYWORD true) if the operation was successful.
 	 */
 	abstract protected bool reify(ConnectionWatcher watcher,
 								  EventMask oldEvents,
 								  EventMask events) @nogc;
-	/**
+        assert(!watcher.invoked);
-	 * Returns: The blocking time.
+        loop.run();
-	 */
+        assert(watcher.invoked);
 	protected @property inout(Duration) blockTime()
 	inout @safe pure nothrow @nogc
 	{
 		// Don't block if we have to do.
 		return swapPendings.empty ? blockTime_ : Duration.zero;
 	}
-	/**
+        defaultAllocator.dispose(loop);
-	 * Sets the blocking time for IO watchers.
+        defaultAllocator.dispose(watcher);
-	 *
+    }
 	 * Params:
 	 * 	blockTime = The blocking time. Cannot be larger than
 	 * 	            $(D_PSYMBOL maxBlockTime).
 	 */
 	protected @property void blockTime(in Duration blockTime) @safe pure nothrow @nogc
 	in
 	{
 		assert(blockTime <= 1.dur!"hours", "Too long to wait.");
 		assert(!blockTime.isNegative);
 	}
 	body
 	{
 		blockTime_ = blockTime;
 	}
-	/**
+    /**
-	 * Kills the watcher and closes the connection.
+     * Start watching.
-	 */
+     *
-	protected void kill(IOWatcher watcher, SocketException exception) @nogc
+     * Params:
-	{
+     *  watcher = Watcher.
-		watcher.socket.shutdown();
+     */
-		defaultAllocator.dispose(watcher.socket);
+    void start(ConnectionWatcher watcher) @nogc
-		MmapPool.instance.dispose(watcher.transport);
+    {
-		watcher.exception = exception;
+        if (watcher.active)
-		swapPendings.insertBack(watcher);
+        {
-	}
+            return;
        }
        watcher.active = true;
-	/**
+        reify(watcher, EventMask(Event.none), EventMask(Event.accept));
-	 * Does the actual polling.
+    }
 	 */
 	abstract protected void poll() @nogc;
-	/// Whether the event loop should be stopped.
+    /**
-	private bool done_;
+     * Stop watching.
     *
     * Params:
     *  watcher = Watcher.
     */
    void stop(ConnectionWatcher watcher) @nogc
    {
        if (!watcher.active)
        {
            return;
        }
        watcher.active = false;
-	/// Maximal block time.
+        reify(watcher, EventMask(Event.accept), EventMask(Event.none));
-	protected Duration blockTime_ = 1.dur!"minutes";
+    }
    /**
     * Should be called if the backend configuration changes.
     *
     * Params:
     *  watcher   = Watcher.
     *  oldEvents = The events were already set.
     *  events    = The events should be set.
     *
     * Returns: $(D_KEYWORD true) if the operation was successful.
     */
    abstract protected bool reify(SocketWatcher watcher,
                                  EventMask oldEvents,
                                  EventMask events) @nogc;
    /**
     * Returns: The blocking time.
     */
    protected @property inout(Duration) blockTime()
    inout @safe pure nothrow @nogc
    {
        // Don't block if we have to do.
        return pendings.empty ? blockTime_ : Duration.zero;
    }
    /**
     * Sets the blocking time for IO watchers.
     *
     * Params:
     *  blockTime = The blocking time. Cannot be larger than
     *              $(D_PSYMBOL maxBlockTime).
     */
    protected @property void blockTime(in Duration blockTime) @safe pure nothrow @nogc
    in
    {
        assert(blockTime <= 1.dur!"hours", "Too long to wait.");
        assert(!blockTime.isNegative);
    }
    do
    {
        blockTime_ = blockTime;
    }
    @nogc @system unittest
    {
        auto loop = defaultAllocator.make!TestLoop;
        assert(loop.blockTime == 1.dur!"minutes");
        loop.blockTime = 2.dur!"minutes";
        assert(loop.blockTime == 2.dur!"minutes");
        defaultAllocator.dispose(loop);
    }
    /**
     * Does the actual polling.
     */
    abstract protected void poll() @nogc;
    /// Maximal block time.
    protected Duration blockTime_ = 1.dur!"minutes";
 }
 /**
@ -303,17 +354,17 @@ abstract class Loop
 */
 class BadLoopException : Exception
 {
-	/**
+    /**
-	 * Params:
+     * Params:
-	 * 	file = The file where the exception occurred.
+     *  file = The file where the exception occurred.
-	 * 	line = The line number where the exception occurred.
+     *  line = The line number where the exception occurred.
-	 * 	next = The previous exception in the chain of exceptions, if any.
+     *  next = The previous exception in the chain of exceptions, if any.
-	 */
+     */
-	this(string file = __FILE__, size_t line = __LINE__, Throwable next = null)
+    this(string file = __FILE__, size_t line = __LINE__, Throwable next = null)
-	pure nothrow const @safe @nogc
+    pure nothrow const @safe @nogc
-	{
+    {
-		super("Event loop cannot be initialized.", file, line, next);
+        super("Event loop cannot be initialized.", file, line, next);
-	}
+    }
 }
 /**
@ -325,24 +376,24 @@ class BadLoopException : Exception
 */
@property Loop defaultLoop() @nogc
 {
-	if (defaultLoop_ !is null)
+    if (defaultLoop_ !is null)
-	{
+    {
-		return defaultLoop_;
+        return defaultLoop_;
-	}
+    }
-	version (Epoll)
+    version (Epoll)
-	{
+    {
-		defaultLoop_ = MmapPool.instance.make!EpollLoop;
+        defaultLoop_ = defaultAllocator.make!EpollLoop;
-	}
+    }
-	else version (IOCP)
+    else version (IOCP)
-	{
+    {
-		defaultLoop_ = MmapPool.instance.make!IOCPLoop;
+        defaultLoop_ = defaultAllocator.make!IOCPLoop;
-	}
+    }
-	else version (Kqueue)
+    else version (Kqueue)
-	{
+    {
-		import tanya.async.event.kqueue;
+        import tanya.async.event.kqueue;
-		defaultLoop_ = MmapPool.instance.make!KqueueLoop;
+        defaultLoop_ = defaultAllocator.make!KqueueLoop;
-	}
+    }
-	return defaultLoop_;
+    return defaultLoop_;
 }
 /**
@ -354,16 +405,29 @@ class BadLoopException : Exception
 * your implementation to this property.
 *
 * Params:
- * 	loop = The event loop.
+ *  loop = The event loop.
 */
@property void defaultLoop(Loop loop) @nogc
 in
 {
-	assert(loop !is null);
+    assert(loop !is null);
 }
-body
+do
 {
-	defaultLoop_ = loop;
+    defaultLoop_ = loop;
 }
 private Loop defaultLoop_;
@nogc @system unittest
 {
    auto oldLoop = defaultLoop_;
    auto loop = defaultAllocator.make!TestLoop;
    defaultLoop = loop;
    assert(defaultLoop_ is loop);
    assert(defaultLoop is loop);
    defaultLoop_ = oldLoop;
    defaultAllocator.dispose(loop);
 }
--- a/source/tanya/async/package.d
+++ b/source/tanya/async/package.d
@ -3,10 +3,14 @@
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
- * Copyright: Eugene Wissner 2016.
+ * This package provides asynchronous capabilities.
 *
 * Copyright: Eugene Wissner 2016-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
- * Authors: $(LINK2 mailto:belka@caraus.de, Eugene Wissner)
+ * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/async/package.d,
 *                 tanya/async/package.d)
 */
 module tanya.async;
--- a/source/tanya/async/protocol.d
+++ b/source/tanya/async/protocol.d
@ -3,43 +3,51 @@
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
- * Copyright: Eugene Wissner 2016.
+ * This module contains protocol which handle data in asynchronous
 * applications.
 *
 * When an event from the network arrives, a protocol method gets
 * called and can respond to the event.
 *
 * Copyright: Eugene Wissner 2016-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
- * Authors: $(LINK2 mailto:belka@caraus.de, Eugene Wissner)
+ * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/async/protocol.d,
 *                 tanya/async/protocol.d)
 */
 module tanya.async.protocol;
 import tanya.network.socket;
 import tanya.async.transport;
 import tanya.network.socket;
 /**
 * Common protocol interface.
 */
 interface Protocol
 {
-	/**
+    /**
-	 * Params:
+     * Params:
-	 * 	data = Read data.
+     *  data = Read data.
-	 */
+     */
-	void received(ubyte[] data) @nogc;
+    void received(in ubyte[] data) @nogc;
-	/**
+    /**
-	 * Called when a connection is made.
+     * Called when a connection is made.
-	 *
+     *
-	 * Params:
+     * Params:
-	 * 	transport = Protocol transport.
+     *  transport = Protocol transport.
-	 */
+     */
-	void connected(DuplexTransport transport) @nogc;
+    void connected(DuplexTransport transport) @nogc;
-	/**
+    /**
-	 * Called when a connection is lost.
+     * Called when a connection is lost.
-	 *
+     *
-	 * Params:
+     * Params:
-	 * 	exception = $(D_PSYMBOL Exception) if an error caused
+     *  exception = $(D_PSYMBOL Exception) if an error caused
-	 * 	            the disconnect, $(D_KEYWORD null) otherwise.
+     *              the disconnect, $(D_KEYWORD null) otherwise.
-	 */
+     */
-	void disconnected(SocketException exception = null) @nogc;
+    void disconnected(SocketException exception) @nogc;
 }
 /**
--- a/source/tanya/async/transport.d
+++ b/source/tanya/async/transport.d
@ -3,13 +3,19 @@
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
- * Copyright: Eugene Wissner 2016.
+ * This module contains transports which are responsible for data dilvery
 * between two parties of an asynchronous communication.
 *
 * Copyright: Eugene Wissner 2016-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
- * Authors: $(LINK2 mailto:belka@caraus.de, Eugene Wissner)
+ * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/async/transport.d,
 *                 tanya/async/transport.d)
 */
 module tanya.async.transport;
 import tanya.async.protocol;
 import tanya.network.socket;
 /**
@ -31,13 +37,13 @@ interface ReadTransport : Transport
 */
 interface WriteTransport : Transport
 {
-	/**
+    /**
-	 * Write some data to the transport.
+     * Write some data to the transport.
-	 *
+     *
-	 * Params:
+     * Params:
-	 * 	data = Data to send.
+     *  data = Data to send.
-	 */
+     */
-	void write(ubyte[] data) @nogc;
+    void write(ubyte[] data) @nogc;
 }
 /**
@ -45,6 +51,45 @@ interface WriteTransport : Transport
 */
 interface DuplexTransport : ReadTransport, WriteTransport
 {
    /**
     * Returns: Application protocol.
     *
     * Postcondition: $(D_INLINECODE protocol !is null)
     */
    @property Protocol protocol() pure nothrow @safe @nogc
    out (protocol)
    {
        assert(protocol !is null);
    }
    /**
     * Switches the protocol.
     *
     * The protocol is deallocated by the event loop.
     *
     * Params:
     *  protocol = Application protocol.
     *
     * Precondition: $(D_INLINECODE protocol !is null)
     */
    @property void protocol(Protocol protocol) pure nothrow @safe @nogc
    in
    {
        assert(protocol !is null);
    }
    /**
     * Returns $(D_PARAM true) if the transport is closing or closed.
     */
    bool isClosing() const pure nothrow @safe @nogc;
    /**
     * Close the transport.
     *
     * Buffered data will be flushed.  No more data will be received.
     */
    void close() @nogc;
 }
 /**
@ -52,12 +97,8 @@ interface DuplexTransport : ReadTransport, WriteTransport
 */
 interface SocketTransport : Transport
 {
-	@property inout(Socket) socket() inout pure nothrow @safe @nogc;
+    /**
-}
+     * Returns: Socket.
-
+     */
-/**
+    @property Socket socket() pure nothrow @safe @nogc;
 * Represents a connection-oriented socket transport.
 */
 package interface StreamTransport : DuplexTransport, SocketTransport
 {
 }
--- a/source/tanya/async/watcher.d
+++ b/source/tanya/async/watcher.d
@ -3,243 +3,128 @@
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
- * Copyright: Eugene Wissner 2016.
+ * Watchers register user's interest in some event.
 *
 * Copyright: Eugene Wissner 2016-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
- * Authors: $(LINK2 mailto:belka@caraus.de, Eugene Wissner)
+ * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/async/watcher.d,
 *                 tanya/async/watcher.d)
 */
 module tanya.async.watcher;
 import std.functional;
 import std.exception;
 import tanya.async.loop;
 import tanya.async.protocol;
 import tanya.async.transport;
 import tanya.container.buffer;
-import tanya.container.queue;
+import tanya.container.list;
 import tanya.memory;
 import tanya.memory.mmappool;
 import tanya.network.socket;
 version (Windows)
 {
 	import core.sys.windows.basetyps;
 	import core.sys.windows.mswsock;
 	import core.sys.windows.winbase;
 	import core.sys.windows.windef;
 	import core.sys.windows.winsock2;
 }
 /**
 * A watcher is an opaque structure that you allocate and register to record
 * your interest in some event. 
 */
 abstract class Watcher
 {
-	/// Whether the watcher is active.
+    /// Whether the watcher is active.
-	bool active;
+    bool active;
-	/**
+    /**
-	 * Invoke some action on event.
+     * Invoke some action on event.
-	 */
+     */
-	void invoke() @nogc;
+    void invoke() @nogc;
 }
-class ConnectionWatcher : Watcher
+version (unittest)
 {
-	/// Watched socket.
+    final class DummyWatcher : Watcher
-	private Socket socket_;
+    {
        bool invoked;
-	/// Protocol factory.
+        override void invoke() @nogc
-	protected Protocol delegate() @nogc protocolFactory;
+        {
-
+            this.invoked = true;
-	package Queue!IOWatcher incoming;
+        }
-
+    }
 	/**
 	 * Params:
 	 * 	socket = Socket.
 	 */
 	this(Socket socket) @nogc
 	{
 		socket_ = socket;
 	}
 	/// Ditto.
 	protected this() pure nothrow @safe @nogc
 	{
 	}
 	~this() @nogc
 	{
 		foreach (w; incoming)
 		{
 			MmapPool.instance.dispose(w);
 		}
 	}
 	/**
 	 * Params:
 	 * 	P = Protocol should be used.
 	 */
 	void setProtocol(P : Protocol)() @nogc
 	{
 		this.protocolFactory = () @nogc => cast(Protocol) MmapPool.instance.make!P;
 	}
 	/**
 	 * Returns: Socket.
 	 */
 	@property inout(Socket) socket() inout pure nothrow @nogc
 	{
 		return socket_;
 	}
 	/**
 	 * Returns: New protocol instance.
 	 */
 	@property Protocol protocol() @nogc
 	in
 	{
 		assert(protocolFactory !is null, "Protocol isn't set.");
 	}
 	body
 	{
 		return protocolFactory();
 	}
 	/**
 	 * Invokes new connection callback.
 	 */
 	override void invoke() @nogc
 	{
 		foreach (io; incoming)
 		{
 			io.protocol.connected(cast(DuplexTransport) io.transport);
 		}
 	}
 }
 /**
- * Contains a pending watcher with the invoked events or a transport can be
+ * Socket watcher.
 * read from.
 */
-class IOWatcher : ConnectionWatcher
+abstract class SocketWatcher : Watcher
 {
-	/// If an exception was thrown the transport should be already invalid.
+    /// Watched socket.
-	private union
+    protected Socket socket_;
 	{
 		StreamTransport transport_;
 		SocketException exception_;
 	}
-	private Protocol protocol_;
+    /**
     * Params:
     *  socket = Socket.
     *
     * Precondition: $(D_INLINECODE socket !is null)
     */
    this(Socket socket) pure nothrow @safe @nogc
    in
    {
        assert(socket !is null);
    }
    do
    {
        socket_ = socket;
    }
-	/**
+    /**
-	 * Returns: Underlying output buffer.
+     * Returns: Socket.
-	 */
+     */
-	package ReadBuffer!ubyte output;
+    @property Socket socket() pure nothrow @safe @nogc
-
+    {
-	/**
+        return socket_;
-	 * Params:
+    }
-	 * 	transport = Transport.
+}
-	 * 	protocol  = New instance of the application protocol.
+
-	 */
+/**
-	this(StreamTransport transport, Protocol protocol) @nogc
+ * Connection watcher.
-	in
+ */
-	{
+class ConnectionWatcher : SocketWatcher
-		assert(transport !is null);
+{
-		assert(protocol !is null);
+    /// Incoming connection queue.
-	}
+    DList!DuplexTransport incoming;
-	body
+
-	{
+    private Protocol delegate() @nogc protocolFactory;
-		super();
+
-		transport_ = transport;
+    /**
-		protocol_ = protocol;
+     * Params:
-		output = ReadBuffer!ubyte(8192, 1024, MmapPool.instance);
+     *  socket = Socket.
-		active = true;
+     */
-	}
+    this(Socket socket) @nogc
-
+    {
-	/**
+        super(socket);
-	 * Destroys the watcher.
+    }
-	 */
+
-	~this() @nogc
+    /**
-	{
+     * Params:
-		MmapPool.instance.dispose(protocol_);
+     *  P = Protocol should be used.
-	}
+     */
-
+    void setProtocol(P : Protocol)() @nogc
-	/**
+    {
-	 * Assigns a transport.
+        this.protocolFactory = () @nogc => cast(Protocol) defaultAllocator.make!P;
-	 *
+    }
-	 * Params:
+
-	 * 	transport = Transport.
+    /**
-	 * 	protocol  = Application protocol.
+     * Invokes new connection callback.
-	 *
+     */
-	 * Returns: $(D_KEYWORD this).
+    override void invoke() @nogc
-	 */
+    in
-	IOWatcher opCall(StreamTransport transport, Protocol protocol)
+    {
-	pure nothrow @nogc
+        assert(protocolFactory !is null, "Protocol isn't set.");
-	in
+    }
-	{
+    do
-		assert(transport !is null);
+    {
-		assert(protocol !is null);
+        for (; !this.incoming.empty; this.incoming.removeFront())
-	}
+        {
-	body
+            this.incoming.front.protocol = protocolFactory();
-	{
+            this.incoming.front.protocol.connected(this.incoming.front);
-		transport_ = transport;
+        }
-		protocol_ = protocol;
+    }
 		active = true;
 		return this;
 	}
 	/**
 	 * Returns: Transport used by this watcher.
 	 */
 	@property inout(StreamTransport) transport() inout pure nothrow @nogc
 	{
 		return transport_;
 	}
 	/**
 	 * Sets an exception occurred during a read/write operation.
 	 *
 	 * Params:
 	 * 	exception = Thrown exception.
 	 */
 	@property void exception(SocketException exception) pure nothrow @nogc
 	{
 		exception_ = exception;
 	}
 	/**
 	 * Returns: Application protocol.
 	 */
 	override @property Protocol protocol() pure nothrow @safe @nogc
 	{
 		return protocol_;
 	}
 	/**
 	 * Returns: Socket.
 	 */
 	override @property inout(Socket) socket() inout pure nothrow @nogc
 	{
 		return transport.socket;
 	}
 	/**
 	 * Invokes the watcher callback.
 	 */
 	override void invoke() @nogc
 	{
 		if (output.length)
 		{
 			protocol.received(output[0..$]);
 			output.clear();
 		}
 		else
 		{
 			protocol.disconnected(exception_);
 			active = false;
 		}
 	}
 }
--- a/source/tanya/container/array.d
+++ b/source/tanya/container/array.d
--- a/source/tanya/container/buffer.d
+++ b/source/tanya/container/buffer.d
--- a/source/tanya/container/entry.d
+++ b/source/tanya/container/entry.d
@ -5,41 +5,324 @@
 /*
 * Internal package used by containers that rely on entries/nodes.
 *
- * Copyright: Eugene Wissner 2016.
+ * Copyright: Eugene Wissner 2016-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
- */  
+ * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/container/entry.d,
 *                 tanya/container/entry.d)
 */
 module tanya.container.entry;
-version (unittest)
+import tanya.algorithm.mutation;
 import tanya.container.array;
 import tanya.memory.allocator;
 import tanya.meta.trait;
 import tanya.meta.transform;
 import tanya.typecons;
 package struct SEntry(T)
 {
-	package struct ConstEqualsStruct
+    // Item content.
-	{
+    T content;
 		int opEquals(typeof(this) that) const
 		{
 			return true;
 		}
 	}
-	package struct MutableEqualsStruct
+    // Next item.
-	{
+    SEntry* next;
 		int opEquals(typeof(this) that)
 		{
 			return true;
 		}
 	}
 	package struct NoEqualsStruct
 	{
 	}
 }
-package struct Entry(T)
+package struct DEntry(T)
 {
-	/// Item content.
+    // Item content.
-	T content;
+    T content;
-	/// Next item.
+    // Previous and next item.
-	Entry* next;
+    DEntry* next, prev;
 }
 package enum BucketStatus : byte
 {
    deleted = -1,
    empty = 0,
    used = 1,
 }
 package struct Bucket(K, V = void)
 {
    static if (is(V == void))
    {
        K key_;
    }
    else
    {
        alias KV = Tuple!(K, "key", V, "value");
        KV kv;
    }
    BucketStatus status = BucketStatus.empty;
    this(ref K key)
    {
        this.key = key;
    }
    @property void key(ref K key)
    {
        this.key() = key;
        this.status = BucketStatus.used;
    }
    @property ref inout(K) key() inout
    {
        static if (is(V == void))
        {
            return this.key_;
        }
        else
        {
            return this.kv.key;
        }
    }
    void moveKey(ref K key)
    {
        move(key, this.key());
        this.status = BucketStatus.used;
    }
    bool opEquals(T)(ref const T key) const
    {
        return this.status == BucketStatus.used && this.key == key;
    }
    bool opEquals(ref const(typeof(this)) that) const
    {
        return key == that.key && this.status == that.status;
    }
    void remove()
    {
        static if (hasElaborateDestructor!K)
        {
            destroy(key);
        }
        this.status = BucketStatus.deleted;
    }
 }
 // Possible sizes for the hash-based containers.
 package static immutable size_t[33] primes = [
    0, 3, 7, 13, 23, 37, 53, 97, 193, 389, 769, 1543, 3079, 6151, 12289,
    24593, 49157, 98317, 196613, 393241, 786433, 1572869, 3145739, 6291469,
    12582917, 25165843, 50331653, 100663319, 201326611, 402653189,
    805306457, 1610612741, 3221225473
 ];
 package struct HashArray(alias hasher, K, V = void)
 {
    alias Key = K;
    alias Value = V;
    alias Bucket = .Bucket!(Key, Value);
    alias Buckets = Array!Bucket;
    Buckets array;
    size_t lengthIndex;
    size_t length;
    this(shared Allocator allocator)
    in
    {
        assert(allocator !is null);
    }
    do
    {
        this.array = Buckets(allocator);
    }
    this(T)(ref T data, shared Allocator allocator)
    if (is(Unqual!T == HashArray))
    in
    {
        assert(allocator !is null);
    }
    do
    {
        this.array = Buckets(data.array, allocator);
        this.lengthIndex = data.lengthIndex;
        this.length = data.length;
    }
    // Move constructor
    void move(ref HashArray data, shared Allocator allocator)
    in
    {
        assert(allocator !is null);
    }
    do
    {
        this.array = Buckets(.move(data.array), allocator);
        this.lengthIndex = data.lengthIndex;
        this.length = data.length;
    }
    void swap(ref HashArray data)
    {
        .swap(this.array, data.array);
        .swap(this.lengthIndex, data.lengthIndex);
        .swap(this.length, data.length);
    }
    void opAssign(ref typeof(this) that)
    {
        this.array = that.array;
        this.lengthIndex = that.lengthIndex;
        this.length = that.length;
    }
    @property size_t bucketCount() const
    {
        return primes[this.lengthIndex];
    }
    /*
     * Returns bucket position for `hash`. `0` may mean the 0th position or an
     * empty `buckets` array.
     */
    size_t locateBucket(T)(ref const T key) const
    {
        return this.array.length == 0 ? 0 : hasher(key) % bucketCount;
    }
    /*
     * If the key doesn't already exists, returns an empty bucket the key can
     * be inserted in and adjusts the element count. Otherwise returns the
     * bucket containing the key.
     */
    ref Bucket insert(ref Key key)
    {
        const newLengthIndex = this.lengthIndex + 1;
        if (newLengthIndex != primes.length)
        {
            foreach (ref e; this.array[locateBucket(key) .. $])
            {
                if (e == key)
                {
                    return e;
                }
                else if (e.status != BucketStatus.used)
                {
                    ++this.length;
                    return e;
                }
            }
            this.rehashToSize(newLengthIndex);
        }
        foreach (ref e; this.array[locateBucket(key) .. $])
        {
            if (e == key)
            {
                return e;
            }
            else if (e.status != BucketStatus.used)
            {
                ++this.length;
                return e;
            }
        }
        this.array.length = this.array.length + 1;
        ++this.length;
        return this.array[$ - 1];
    }
    // Takes an index in the primes array.
    void rehashToSize(const size_t n)
    in
    {
        assert(n < primes.length);
    }
    do
    {
        auto storage = typeof(this.array)(primes[n], this.array.allocator);
        DataLoop: foreach (ref e1; this.array[])
        {
            if (e1.status == BucketStatus.used)
            {
                auto bucketPosition = hasher(e1.key) % primes[n];
                foreach (ref e2; storage[bucketPosition .. $])
                {
                    if (e2.status != BucketStatus.used) // Insert the key
                    {
                        .move(e1, e2);
                        continue DataLoop;
                    }
                }
                storage.insertBack(.move(e1));
            }
        }
        .move(storage, this.array);
        this.lengthIndex = n;
    }
    void rehash(const size_t n)
    {
        size_t lengthIndex;
        for (; lengthIndex < primes.length; ++lengthIndex)
        {
            if (primes[lengthIndex] >= n)
            {
                break;
            }
        }
        if (lengthIndex > this.lengthIndex)
        {
            this.rehashToSize(lengthIndex);
        }
    }
    @property size_t capacity() const
    {
        return this.array.length;
    }
    void clear()
    {
        this.array.clear();
        this.length = 0;
    }
    size_t remove(ref Key key)
    {
        foreach (ref e; this.array[locateBucket(key) .. $])
        {
            if (e == key) // Found.
            {
                e.remove();
                --this.length;
                return 1;
            }
            else if (e.status == BucketStatus.empty)
            {
                break;
            }
        }
        return 0;
    }
    bool opBinaryRight(string op : "in", T)(ref const T key) const
    {
        foreach (ref e; this.array[locateBucket(key) .. $])
        {
            if (e == key) // Found.
            {
                return true;
            }
            else if (e.status == BucketStatus.empty)
            {
                break;
            }
        }
        return false;
    }
 }
--- a/source/tanya/container/hashtable.d
+++ b/source/tanya/container/hashtable.d
--- a/source/tanya/container/list.d
+++ b/source/tanya/container/list.d
--- a/source/tanya/container/package.d
+++ b/source/tanya/container/package.d
@ -3,14 +3,20 @@
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
- * Copyright: Eugene Wissner 2016.
+ * Abstract data types whose instances are collections of other objects.
 *
 * Copyright: Eugene Wissner 2016-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
- */  
+ * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/container/package.d,
 *                 tanya/container/package.d)
 */
 module tanya.container;
 public import tanya.container.array;
 public import tanya.container.buffer;
 public import tanya.container.hashtable;
 public import tanya.container.list;
-public import tanya.container.vector;
+public import tanya.container.set;
-public import tanya.container.queue;
+public import tanya.container.string;
--- a/source/tanya/container/queue.d
+++ b/source/tanya/container/queue.d
@ -1,399 +0,0 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * Copyright: Eugene Wissner 2016.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 */  
 module tanya.container.queue;
 import tanya.container.entry;
 import std.traits;
 import tanya.memory;
 /**
 * FIFO queue.
 *
 * Params:
 * 	T = Content type.
 */
 struct Queue(T)
 {
 	/**
 	 * Removes all elements from the queue.
 	 */
 	~this()
 	{
 		clear();
 	}
 	/**
 	 * Removes all elements from the queue.
 	 */
 	void clear()
 	{
 		while (!empty)
 		{
 			popFront();
 		}
 	}
 	///
 	unittest
 	{
 		Queue!int q;
 		assert(q.empty);
 		q.insertBack(8);
 		q.insertBack(9);
 		q.clear();
 		assert(q.empty);
 	}
 	/**
 	 * Returns how many elements are in the queue. It iterates through the queue
 	 * to count the elements.
 	 *
 	 * Returns: How many elements are in the queue.
 	 */
 	size_t length() const
 	{
 		size_t len;
 		for (const(Entry!T)* i = first.next; i !is null; i = i.next)
 		{
 			++len;
 		}
 		return len;
 	}
 	///
 	unittest
 	{
 		Queue!int q;
 		assert(q.length == 0);
 		q.insertBack(5);
 		assert(q.length == 1);
 		q.insertBack(4);
 		assert(q.length == 2);
 		q.insertBack(9);
 		assert(q.length == 3);
 		q.popFront();
 		assert(q.length == 2);
 		q.popFront();
 		assert(q.length == 1);
 		q.popFront();
 		assert(q.length == 0);
 	}
 	version (D_Ddoc)
 	{
 		/**
 		 * Compares two queues. Checks if all elements of the both queues are equal.
 		 *
 		 * Returns: Whether $(D_KEYWORD this) and $(D_PARAM that) are equal.
 		 */
 		int opEquals(ref typeof(this) that);
 		/// Ditto.
 		int opEquals(typeof(this) that);
 	}
 	else static if (!hasMember!(T, "opEquals")
 	             || (functionAttributes!(T.opEquals) & FunctionAttribute.const_))
 	{
 		bool opEquals(in ref typeof(this) that) const
 		{
 			const(Entry!T)* i = first.next;
 			const(Entry!T)* j = that.first.next;
 			while (i !is null && j !is null)
 			{
 				if (i.content != j.content)
 				{
 					return false;
 				}
 				i = i.next;
 				j = j.next;
 			}
 			return i is null && j is null;
 		}
 		/// Ditto.
 		bool opEquals(in typeof(this) that) const
 		{
 			return opEquals(that);
 		}
 	}
 	else
 	{
 		/**
 		 * Compares two queues. Checks if all elements of the both queues are equal.
 		 *
 		 * Returns: How many elements are in the queue.
 		 */
 		bool opEquals(ref typeof(this) that)
 		{
 			Entry!T* i = first.next;
 			Entry!T* j = that.first.next;
 			while (i !is null && j !is null)
 			{
 				if (i.content != j.content)
 				{
 					return false;
 				}
 				i = i.next;
 				j = j.next;
 			}
 			return i is null && j is null;
 		}
 		/// Ditto.
 		bool opEquals(typeof(this) that)
 		{
 			return opEquals(that);
 		}
 	}
 	///
 	unittest
 	{
 		Queue!int q1, q2;
 		q1.insertBack(5);
 		q1.insertBack(4);
 		q2.insertBack(5);
 		assert(q1 != q2);
 		q2.insertBack(4);
 		assert(q1 == q2);
 		q2.popFront();
 		assert(q1 != q2);
 		q1.popFront();
 		assert(q1 == q2);
 		q1.popFront();
 		q2.popFront();
 		assert(q1 == q2);
 	}
 	private unittest
 	{
 		static assert(is(Queue!ConstEqualsStruct));
 		static assert(is(Queue!MutableEqualsStruct));
 		static assert(is(Queue!NoEqualsStruct));
 	}
 	/**
 	 * Returns: First element.
 	 */
 	@property ref inout(T) front() inout
 	in
 	{
 		assert(!empty);
 	}
 	body
 	{
 		return first.next.content;
 	}
 	/**
 	 * Inserts a new element.
 	 *
 	 * Params:
 	 * 	x = New element.
 	 */
 	void insertBack(ref T x)
 	{
 		auto temp = allocator.make!(Entry!T);
 		temp.content = x;
 		if (empty)
 		{
 			first.next = rear = temp;
 		}
 		else
 		{
 			rear.next = temp;
 			rear = rear.next;
 		}
 	}
 	/// Ditto.
 	void insertBack(T x)
 	{
 		insertBack(x);
 	}
 	/// Ditto.
 	alias insert = insertBack;
 	///
 	unittest
 	{
 		Queue!int q;
 		assert(q.empty);
 		q.insertBack(8);
 		assert(q.front == 8);
 		q.insertBack(9);
 		assert(q.front == 8);
 	}
 	/**
 	 * Returns: $(D_KEYWORD true) if the queue is empty.
 	 */
 	@property bool empty() const
 	{
 		return first.next is null;
 	}
 	///
 	unittest
 	{
 		Queue!int q;
 		int value = 7;
 		assert(q.empty);
 		q.insertBack(value);
 		assert(!q.empty);
 	}
 	/**
 	 * Move the position to the next element.
 	 */
 	void popFront()
 	in
 	{
 		assert(!empty);
 		assert(allocator !is null);
 	}
 	body
 	{
 		auto n = first.next.next;
 		dispose(allocator, first.next);
 		first.next = n;
 	}
 	///
 	unittest
 	{
 		Queue!int q;
 		q.insertBack(8);
 		q.insertBack(9);
 		assert(q.front == 8);
 		q.popFront();
 		assert(q.front == 9);
 	}
 	/**
 	 * $(D_KEYWORD foreach) iteration. The elements will be automatically
 	 * dequeued.
 	 *
 	 * Params:
 	 * 	dg = $(D_KEYWORD foreach) body.
 	 */
 	int opApply(scope int delegate(ref size_t i, ref T) @nogc dg)
 	{
 		int result;
 		for (size_t i = 0; !empty; ++i)
 		{
 			if ((result = dg(i, front)) != 0)
 			{
 				return result;
 			}
 			popFront();
 		}
 		return result;
 	}
 	/// Ditto.
 	int opApply(scope int delegate(ref T) @nogc dg)
 	{
 		int result;
 		while (!empty)
 		{
 			if ((result = dg(front)) != 0)
 			{
 				return result;
 			}
 			popFront();
 		}
 		return result;
 	}
 	///
 	unittest
 	{
 		Queue!int q;
 		size_t j;
 		q.insertBack(5);
 		q.insertBack(4);
 		q.insertBack(9);
 		foreach (i, e; q)
 		{
 			assert(i != 2 || e == 9);
 			assert(i != 1 || e == 4);
 			assert(i != 0 || e == 5);
 			++j;
 		}
 		assert(j == 3);
 		assert(q.empty);
 		j = 0;
 		q.insertBack(5);
 		q.insertBack(4);
 		q.insertBack(9);
 		foreach (e; q)
 		{
 			assert(j != 2 || e == 9);
 			assert(j != 1 || e == 4);
 			assert(j != 0 || e == 5);
 			++j;
 		}
 		assert(j == 3);
 		assert(q.empty);
 	}
 	/// The first element of the list.
 	private Entry!T first;
 	/// The last element of the list.
 	private Entry!T* rear;
 	mixin DefaultAllocator;
 }
 ///
 unittest
 {
 	Queue!int q;
 	q.insertBack(5);
 	assert(!q.empty);
 	q.insertBack(4);
 	assert(q.front == 5);
 	q.insertBack(9);
 	assert(q.front == 5);
 	q.popFront();
 	assert(q.front == 4);
 	foreach (i, ref e; q)
 	{
 		assert(i != 0 || e == 4);
 		assert(i != 1 || e == 9);
 	}
 	assert(q.empty);
 }
--- a/source/tanya/container/set.d
+++ b/source/tanya/container/set.d
@ -0,0 +1,769 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * This module implements a $(D_PSYMBOL Set) container that stores unique
 * values without any particular order.
 *
 * Copyright: Eugene Wissner 2017-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/container/set.d,
 *                 tanya/container/set.d)
 */
 module tanya.container.set;
 import tanya.container.array;
 import tanya.container.entry;
 import tanya.hash.lookup;
 import tanya.memory;
 import tanya.meta.trait;
 import tanya.meta.transform;
 import tanya.range.primitive;
 /**
 * Bidirectional range that iterates over the $(D_PSYMBOL Set)'s values.
 *
 * Params:
 *  T = Type of the internal hash storage.
 */
 struct Range(T)
 {
    private alias E = CopyConstness!(T, T.Key);
    static if (isMutable!T)
    {
        private alias DataRange = T.array.Range;
    }
    else
    {
        private alias DataRange = T.array.ConstRange;
    }
    private DataRange dataRange;
    @disable this();
    private this(DataRange dataRange)
    {
        while (!dataRange.empty && dataRange.front.status != BucketStatus.used)
        {
            dataRange.popFront();
        }
        while (!dataRange.empty && dataRange.back.status != BucketStatus.used)
        {
            dataRange.popBack();
        }
        this.dataRange = dataRange;
    }
    @property Range save()
    {
        return this;
    }
    @property bool empty() const
    {
        return this.dataRange.empty();
    }
    @property void popFront()
    in
    {
        assert(!empty);
        assert(this.dataRange.front.status == BucketStatus.used);
    }
    out
    {
        assert(empty || this.dataRange.back.status == BucketStatus.used);
    }
    do
    {
        do
        {
            this.dataRange.popFront();
        }
        while (!empty && dataRange.front.status != BucketStatus.used);
    }
    @property void popBack()
    in
    {
        assert(!empty);
        assert(this.dataRange.back.status == BucketStatus.used);
    }
    out
    {
        assert(empty || this.dataRange.back.status == BucketStatus.used);
    }
    do
    {
        do
        {
            this.dataRange.popBack();
        }
        while (!empty && dataRange.back.status != BucketStatus.used);
    }
    @property ref inout(E) front() inout
    in
    {
        assert(!empty);
        assert(this.dataRange.front.status == BucketStatus.used);
    }
    do
    {
        return this.dataRange.front.key;
    }
    @property ref inout(E) back() inout
    in
    {
        assert(!empty);
        assert(this.dataRange.back.status == BucketStatus.used);
    }
    do
    {
        return this.dataRange.back.key;
    }
    Range opIndex()
    {
        return typeof(return)(this.dataRange[]);
    }
    Range!(const T) opIndex() const
    {
        return typeof(return)(this.dataRange[]);
    }
 }
 /**
 * Set is a data structure that stores unique values without any particular
 * order.
 *
 * This $(D_PSYMBOL Set) is implemented using closed hashing. Hash collisions
 * are resolved with linear probing.
 *
 * $(D_PARAM T) should be hashable with $(D_PARAM hasher). $(D_PARAM hasher) is
 * a callable that accepts an argument of type $(D_PARAM T) and returns a hash
 * value for it ($(D_KEYWORD size_t)).
 *
 * Params:
 *  T      = Element type.
 *  hasher = Hash function for $(D_PARAM T).
 */
 struct Set(T, alias hasher = hash)
 if (is(typeof(hasher(T.init)) == size_t))
 {
    private alias HashArray = .HashArray!(hasher, T);
    private alias Buckets = HashArray.Buckets;
    private HashArray data;
    /// The range types for $(D_PSYMBOL Set).
    alias Range = .Range!HashArray;
    /// ditto
    alias ConstRange = .Range!(const HashArray);
    invariant
    {
        assert(this.data.lengthIndex < primes.length);
        assert(this.data.array.length == 0
            || this.data.array.length == primes[this.data.lengthIndex]);
    }
    /**
     * Constructor.
     *
     * Params:
     *  n         = Minimum number of buckets.
     *  allocator = Allocator.
     *
     * Precondition: $(D_INLINECODE allocator !is null).
     */
    this(size_t n, shared Allocator allocator = defaultAllocator)
    in
    {
        assert(allocator !is null);
    }
    do
    {
        this(allocator);
        this.data.rehash(n);
    }
    ///
    @nogc nothrow pure @safe unittest
    {
        auto set = Set!int(5);
        assert(set.capacity == 7);
    }
    /// ditto
    this(shared Allocator allocator)
    in
    {
        assert(allocator !is null);
    }
    do
    {
        this.data = HashArray(allocator);
    }
    /**
     * Initializes this $(D_PARAM Set) from another one.
     *
     * If $(D_PARAM init) is passed by reference, it will be copied.
     * If $(D_PARAM init) is passed by value, it will be moved.
     *
     * Params:
     *  S         = Source set type.
     *  init      = Source set.
     *  allocator = Allocator.
     *
     * Precondition: $(D_INLINECODE allocator !is null).
     */
    this(S)(ref S init, shared Allocator allocator = defaultAllocator)
    if (is(Unqual!S == Set))
    in
    {
        assert(allocator !is null);
    }
    do
    {
        this.data = HashArray(init.data, allocator);
    }
    /// ditto
    this(S)(S init, shared Allocator allocator = defaultAllocator)
    if (is(S == Set))
    in
    {
        assert(allocator !is null);
    }
    do
    {
        this.data.move(init.data, allocator);
    }
    /**
     * Initializes the set from a forward range.
     *
     * Params:
     *  R         = Range type.
     *  range     = Forward range.
     *  allocator = Allocator.
     *
     * Precondition: $(D_INLINECODE allocator !is null).
     */
    this(R)(R range, shared Allocator allocator = defaultAllocator)
    if (isForwardRange!R && isImplicitlyConvertible!(ElementType!R, T))
    in
    {
        assert(allocator !is null);
    }
    do
    {
        insert(range);
    }
    ///
    @nogc nothrow pure @safe unittest
    {
        int[2] range = [1, 2];
        Set!int set = Set!int(range[]);
        assert(1 in set);
        assert(2 in set);
    }
    /**
     * Initializes the set from a static array.
     *
     * Params:
     *  n         = Array size.
     *  array     = Static array.
     *  allocator = Allocator.
     *
     * Precondition: $(D_INLINECODE allocator !is null).
     */
    this(size_t n)(T[n] array, shared Allocator allocator = defaultAllocator)
    in
    {
        assert(allocator !is null);
    }
    do
    {
        insert(array[]);
    }
    ///
    @nogc nothrow pure @safe unittest
    {
        Set!int set = Set!int([1, 2]);
        assert(1 in set);
        assert(2 in set);
    }
    /**
     * Assigns another set.
     *
     * If $(D_PARAM that) is passed by reference, it will be copied.
     * If $(D_PARAM that) is passed by value, it will be moved.
     *
     * Params:
     *  S    = Content type.
     *  that = The value should be assigned.
     *
     * Returns: $(D_KEYWORD this).
     */
    ref typeof(this) opAssign(S)(ref S that)
    if (is(Unqual!S == Set))
    {
        this.data = that.data;
        return this;
    }
    /// ditto
    ref typeof(this) opAssign(S)(S that) @trusted
    if (is(S == Set))
    {
        this.data.swap(that.data);
        return this;
    }
    /**
     * Returns: Used allocator.
     *
     * Postcondition: $(D_INLINECODE allocator !is null)
     */
    @property shared(Allocator) allocator() const
    out (allocator)
    {
        assert(allocator !is null);
    }
    do
    {
        return this.data.array.allocator;
    }
    /**
     * Maximum amount of elements this $(D_PSYMBOL Set) can hold without
     * resizing and rehashing. Note that it doesn't mean that the
     * $(D_PSYMBOL Set) will hold $(I exactly) $(D_PSYMBOL capacity) elements.
     * $(D_PSYMBOL capacity) tells the size of the container under a best-case
     * distribution of elements.
     *
     * Returns: $(D_PSYMBOL Set) capacity.
     */
    @property size_t capacity() const
    {
        return this.data.capacity;
    }
    ///
    @nogc nothrow pure @safe unittest
    {
        Set!int set;
        assert(set.capacity == 0);
        set.insert(8);
        assert(set.capacity == 3);
    }
    /**
     * Iterates over the $(D_PSYMBOL Set) and counts the elements.
     *
     * Returns: Count of elements within the $(D_PSYMBOL Set).
     */
    @property size_t length() const
    {
        return this.data.length;
    }
    ///
    @nogc nothrow pure @safe unittest
    {
        Set!int set;
        assert(set.length == 0);
        set.insert(8);
        assert(set.length == 1);
    }
    /**
     * Tells whether the container contains any elements.
     *
     * Returns: Whether the container is empty.
     */
    @property bool empty() const
    {
        return length == 0;
    }
    ///
    @nogc nothrow pure @safe unittest
    {
        Set!int set;
        assert(set.empty);
        set.insert(5);
        assert(!set.empty);
    }
    /**
     * Removes all elements.
     */
    void clear()
    {
        this.data.clear();
    }
    ///
    @nogc nothrow pure @safe unittest
    {
        Set!int set;
        set.insert(5);
        assert(!set.empty);
        set.clear();
        assert(set.empty);
    }
    /**
     * Returns current bucket count in the container.
     *
     * Bucket count equals to the number of the elements can be saved in the
     * container in the best case scenario for key distribution, i.d. every key
     * has a unique hash value. In a worse case the bucket count can be less
     * than the number of elements stored in the container.
     *
     * Returns: Current bucket count.
     *
     * See_Also: $(D_PSYMBOL rehash).
     */
    @property size_t bucketCount() const
    {
        return this.data.bucketCount;
    }
    /// The maximum number of buckets the container can have.
    enum size_t maxBucketCount = primes[$ - 1];
    /**
     * Inserts a new element.
     *
     * Params:
     *  value = Element value.
     *
     * Returns: Amount of new elements inserted.
     */
    size_t insert(ref T value)
    {
        auto e = ((ref v) @trusted => &this.data.insert(v))(value);
        if (e.status != BucketStatus.used)
        {
            e.moveKey(value);
            return 1;
        }
        return 0;
    }
    size_t insert(T value)
    {
        auto e = ((ref v) @trusted => &this.data.insert(v))(value);
        if (e.status != BucketStatus.used)
        {
            e.key = value;
            return 1;
        }
        return 0;
    }
    ///
    @nogc nothrow pure @safe unittest
    {
        Set!int set;
        assert(8 !in set);
        assert(set.insert(8) == 1);
        assert(set.length == 1);
        assert(8 in set);
        assert(set.insert(8) == 0);
        assert(set.length == 1);
        assert(8 in set);
        assert(set.remove(8));
        assert(set.insert(8) == 1);
    }
    /**
     * Inserts the value from a forward range into the set.
     *
     * Params:
     *  R     = Range type.
     *  range = Forward range.
     *
     * Returns: The number of new elements inserted.
     */
    size_t insert(R)(R range)
    if (isForwardRange!R && isImplicitlyConvertible!(ElementType!R, T))
    {
        size_t count;
        foreach (e; range)
        {
            count += insert(e);
        }
        return count;
    }
    ///
    @nogc nothrow pure @safe unittest
    {
        Set!int set;
        int[3] range = [2, 1, 2];
        assert(set.insert(range[]) == 2);
        assert(1 in set);
        assert(2 in set);
    }
    /**
     * Removes an element.
     *
     * Params:
     *  value = Element value.
     *
     * Returns: Number of elements removed, which is in the container with
     *          unique values `1` if an element existed, and `0` otherwise.
     */
    size_t remove(T value)
    {
        return this.data.remove(value);
    }
    ///
    @nogc nothrow pure @safe unittest
    {
        Set!int set;
        set.insert(8);
        assert(8 in set);
        assert(set.remove(8) == 1);
        assert(set.remove(8) == 0);
        assert(8 !in set);
    }
    /**
     * $(D_KEYWORD in) operator.
     *
     * Params:
     *  U     = Type comparable with the element type, used for the lookup.
     *  value = Element to be searched for.
     *
     * Returns: $(D_KEYWORD true) if the given element exists in the container,
     *          $(D_KEYWORD false) otherwise.
     */
    bool opBinaryRight(string op : "in", U)(auto ref const U value) const
    if (ifTestable!(U, a => T.init == a))
    {
        return value in this.data;
    }
    ///
    @nogc nothrow pure @safe unittest
    {
        Set!int set;
        assert(5 !in set);
        set.insert(5);
        assert(5 in set);
        assert(8 !in set);
    }
    /**
     * Sets the number of buckets in the container to at least $(D_PARAM n)
     * and rearranges all the elements according to their hash values.
     *
     * If $(D_PARAM n) is greater than the current $(D_PSYMBOL bucketCount)
     * and lower than or equal to $(D_PSYMBOL maxBucketCount), a rehash is
     * forced.
     *
     * If $(D_PARAM n) is greater than $(D_PSYMBOL maxBucketCount),
     * $(D_PSYMBOL maxBucketCount) is used instead as a new number of buckets.
     *
     * If $(D_PARAM n) is less than or equal to the current
     * $(D_PSYMBOL bucketCount), the function may have no effect.
     *
     * Rehashing is automatically performed whenever the container needs space
     * to insert new elements.
     *
     * Params:
     *  n = Minimum number of buckets.
     */
    void rehash(size_t n)
    {
        this.data.rehash(n);
    }
    /**
     * Returns a bidirectional range over the container.
     *
     * Returns: A bidirectional range that iterates over the container.
     */
    Range opIndex()
    {
        return typeof(return)(this.data.array[]);
    }
    /// ditto
    ConstRange opIndex() const
    {
        return typeof(return)(this.data.array[]);
    }
    ///
    @nogc nothrow pure @safe unittest
    {
        Set!int set;
        assert(set[].empty);
        set.insert(8);
        assert(!set[].empty);
        assert(set[].front == 8);
        assert(set[].back == 8);
    }
 }
 // Basic insertion logic.
@nogc nothrow pure @safe unittest
 {
    Set!int set;
    assert(set.insert(5) == 1);
    assert(5 in set);
    assert(set.data.array.length == 3);
    assert(set.insert(5) == 0);
    assert(5 in set);
    assert(set.data.array.length == 3);
    assert(set.insert(9) == 1);
    assert(9 in set);
    assert(5 in set);
    assert(set.data.array.length == 3);
    assert(set.insert(7) == 1);
    assert(set.insert(8) == 1);
    assert(8 in set);
    assert(5 in set);
    assert(9 in set);
    assert(7 in set);
    assert(set.data.array.length == 7);
    assert(set.insert(16) == 1);
    assert(16 in set);
    assert(set.data.array.length == 7);
 }
 // Static checks.
@nogc nothrow pure @safe unittest
 {
    import tanya.range.primitive;
    static assert(isBidirectionalRange!(Set!int.ConstRange));
    static assert(isBidirectionalRange!(Set!int.Range));
    static assert(!isInfinite!(Set!int.Range));
    static assert(!hasLength!(Set!int.Range));
    static assert(is(Set!uint));
    static assert(is(Set!long));
    static assert(is(Set!ulong));
    static assert(is(Set!short));
    static assert(is(Set!ushort));
    static assert(is(Set!bool));
 }
@nogc nothrow pure @safe unittest
 {
    const Set!int set;
    assert(set[].empty);
 }
@nogc nothrow pure @safe unittest
 {
    Set!int set;
    set.insert(8);
    auto r1 = set[];
    auto r2 = r1.save();
    r1.popFront();
    assert(r1.empty);
    r2.popBack();
    assert(r2.empty);
 }
 // Initial capacity is 0.
@nogc nothrow pure @safe unittest
 {
    auto set = Set!int(defaultAllocator);
    assert(set.capacity == 0);
 }
 // Capacity is set to a prime.
@nogc nothrow pure @safe unittest
 {
    auto set = Set!int(8);
    assert(set.capacity == 13);
 }
 // Constructs by reference
@nogc nothrow pure @safe unittest
 {
    auto set1 = Set!int(7);
    auto set2 = Set!int(set1);
    assert(set1.length == set2.length);
    assert(set1.capacity == set2.capacity);
 }
 // Constructs by value
@nogc nothrow pure @safe unittest
 {
    auto set = Set!int(Set!int(7));
    assert(set.capacity == 7);
 }
 // Assigns by reference
@nogc nothrow pure @safe unittest
 {
    auto set1 = Set!int(7);
    Set!int set2;
    set1 = set2;
    assert(set1.length == set2.length);
    assert(set1.capacity == set2.capacity);
 }
 // Assigns by value
@nogc nothrow pure @safe unittest
 {
    Set!int set;
    set = Set!int(7);
    assert(set.capacity == 7);
 }
 // Postblit copies
@nogc nothrow pure @safe unittest
 {
    auto set = Set!int(7);
    void testFunc(Set!int set)
    {
        assert(set.capacity == 7);
    }
    testFunc(set);
 }
--- a/source/tanya/container/string.d
+++ b/source/tanya/container/string.d
--- a/source/tanya/container/vector.d
+++ b/source/tanya/container/vector.d
@ -1,995 +0,0 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * Copyright: Eugene Wissner 2016.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 */  
 module tanya.container.vector;
 import core.exception;
 import std.algorithm.comparison;
 import std.range.primitives;
 import std.traits;
 public import tanya.enums : IL;
 import tanya.memory;
 version (unittest)
 {
 	struct TestA
 	{
 		~this() @nogc
 		{
 		}
 	}
 }
 /**
 * One dimensional array.
 *
 * Params:
 * 	T = Content type.
 */
 template Vector(T)
 {
 	/**
 	 * Defines the container's primary range.
 	 */
 	struct Range(V)
 	{
 		private alias E = typeof(data.vector[0]);
 		private V* data;
 		private @property ref inout(V) outer() inout return
 		{
 			return *data;
 		}
 		private size_t start, end;
 		invariant
 		{
 			assert(start <= end);
 		}
 		private this(ref inout V data, in size_t a, in size_t b) inout
 		in
 		{
 			assert(a <= b);
 			assert(b <= data.length);
 		}
 		body
 		{
 			this.data = &data;
 			start = a;
 			end = b;
 		}
 		@property Range save()
 		{
 			return this;
 		}
 		@property bool empty() inout const
 		{
 			return start == end;
 		}
 		@property size_t length() inout const
 		{
 			return end - start;
 		}
 		alias opDollar = length;
 		@property ref inout(E) front() inout
 		{
 			return outer[start];
 		}
 		@property ref inout(E) back() inout
 		{
 			return outer[end - 1];
 		}
 		void popFront()
 		in
 		{
 			assert(!empty);
 		}
 		body
 		{
 			++start;
 		}
 		void popBack()
 		in
 		{
 			assert(!empty);
 		}
 		body
 		{
 			--end;
 		}
 		ref inout(E) opIndex(in size_t i) inout
 		{
 			return outer[start + i];
 		}
 		Range opIndex()
 		{
 			return typeof(return)(outer, start, end);
 		}
 		Range opSlice(in size_t i, in size_t j)
 		in
 		{
 			assert(i <= j);
 			assert(start + j <= end);
 		}
 		body
 		{
 			return typeof(return)(outer, start + i, start + j);
 		}
 		static if (isMutable!V)
 		{
 			Range opIndexAssign(T value)
 			{
 				return outer[start .. end] = value;
 			}
 			Range opSliceAssign(T value, in size_t i, in size_t j)
 			{
 				return outer[start + i .. start + j] = value;
 			}
 			Range opSliceAssign(Range value, in size_t i, in size_t j)
 			{
 				return outer[start + i .. start + j] = value;
 			}
 			Range opSliceAssign(T[] value, in size_t i, in size_t j)
 			{
 				return outer[start + i .. start + j] = value;
 			}
 		}
 	}
 	struct Vector
 	{
 		private size_t length_;
 		invariant
 		{
 			assert(length_ <= vector.length);
 		}
 		/// Internal representation.
 		private T[] vector;
 		/**
 		 * Creates a new $(D_PSYMBOL Vector).
 		 *
 		 * Params:
 		 * 	U         = Type of the static array with the initial elements.
 		 * 	params    = Values to initialize the array with. Use $(D_PSYMBOL IL)
 		 * 	            to generate a list.
 		 * 	allocator = Allocator.
 		 */
 		this(U)(U init, shared Allocator allocator = defaultAllocator)
 			if (isStaticArray!U)
 		in
 		{
 			assert(allocator !is null);
 			static assert(init.length > 0);
 		}
 		body
 		{
 			this(allocator);
 			allocator.resize!(T, false)(vector, init.length);
 			vector[0 .. $] = init[0 .. $];
 			length_ = init.length;
 		}
 		/// Ditto.
 		this(U)(U init, shared Allocator allocator = defaultAllocator) const
 			if (isStaticArray!U)
 		in
 		{
 			assert(allocator !is null);
 			static assert(init.length > 0);
 		}
 		body
 		{
 			allocator_ = cast(const shared Allocator) allocator;
 			T[] buf;
 			allocator.resize!(T, false)(buf, init.length);
 			buf[0 .. $] = init[0 .. $];
 			vector = cast(const(T[])) buf;
 			length_ = init.length;
 		}
 		/// Ditto.
 		this(U)(U init, shared Allocator allocator = defaultAllocator) immutable
 			if (isStaticArray!U)
 		in
 		{
 			assert(allocator !is null);
 			static assert(init.length > 0);
 		}
 		body
 		{
 			allocator_ = cast(immutable Allocator) allocator;
 			T[] buf;
 			allocator.resize!(T, false)(buf, init.length);
 			buf[0 .. $] = init[0 .. $];
 			vector = cast(immutable(T[])) buf;
 			length_ = init.length;
 		}
 		/// Ditto.
 		this(shared Allocator allocator)
 		in
 		{
 			assert(allocator !is null);
 		}
 		body
 		{
 			allocator_ = allocator;
 		}
 		///
 		unittest
 		{
 			auto v = Vector!int(IL(3, 8, 2));
 			assert(v.capacity == 3);
 			assert(v.length == 3);
 			assert(v[0] == 3 && v[1] == 8 && v[2] == 2);
 		}
 		/**
 		 * Destroys this $(D_PSYMBOL Vector).
 		 */
 		~this()
 		{
 			allocator.dispose(vector);
 		}
 		/**
 		 * Removes all elements.
 		 */
 		void clear()
 		{
 			length = 0;
 		}
 		///
 		unittest
 		{
 			auto v = Vector!int(IL(18, 20, 15));
 			v.clear();
 			assert(v.length == 0);
 			assert(v.capacity == 3);
 		}
 		/**
 		 * Returns: How many elements the vector can contain without reallocating.
 		 */
 		@property size_t capacity() inout const
 		{
 			return vector.length;
 		}
 		/**
 		 * Returns: Vector length.
 		 */
 		@property size_t length() inout const
 		{
 			return length_;
 		}
 		/// Ditto.
 		alias opDollar = length;
 		/**
 		 * Expands/shrinks the vector.
 		 *
 		 * Params:
 		 * 	len = New length.
 		 */
 		@property void length(in size_t len)
 		{
 			if (len > length)
 			{
 				reserve(len);
 				vector[length .. len] = T.init;
 			}
 			else if (len < length)
 			{
 				static if (hasElaborateDestructor!T)
 				{
 					foreach (ref e; vector[len - 1 .. length_])
 					{
 						destroy(e);
 					}
 				}
 			}
 			else
 			{
 				return;
 			}
 			length_ = len;
 		}
 		///
 		unittest
 		{
 			Vector!int v;
 			v.length = 5;
 			assert(v.length == 5);
 			assert(v.capacity == 5);
 			v.length = 7;
 			assert(v.length == 7);
 			assert(v.capacity == 7);
 			assert(v[$ - 1] == 0);
 			v[$ - 1] = 3;
 			assert(v[$ - 1] == 3);
 			v.length = 0;
 			assert(v.length == 0);
 			assert(v.capacity == 7);
 		}
 		/**
 		 * Reserves space for $(D_PARAM size) elements.
 		 *
 		 * Params:
 		 * 	size = Desired size.
 		 */
 		void reserve(in size_t size) @trusted
 		{
 			if (vector.length < size)
 			{
 				void[] buf = vector;
 				allocator.reallocate(buf, size * T.sizeof);
 				vector = cast(T[]) buf;
 			}
 		}
 		///
 		unittest
 		{
 			Vector!int v;
 			assert(v.capacity == 0);
 			assert(v.length == 0);
 			v.reserve(3);
 			assert(v.capacity == 3);
 			assert(v.length == 0);
 		}
 		/**
 		 * Requests the vector to reduce its capacity to fit the $(D_PARAM size).
 		 *
 		 * The request is non-binding. The vector won't become smaller than the
 		 * $(D_PARAM length).
 		 *
 		 * Params:
 		 * 	size = Desired size.
 		 */
 		void shrink(in size_t size) @trusted
 		{
 			auto n = max(length, size);
 			void[] buf = vector;
 			allocator.reallocate(buf, n * T.sizeof);
 			vector = cast(T[]) buf;
 		}
 		///
 		unittest
 		{
 			Vector!int v;
 			assert(v.capacity == 0);
 			assert(v.length == 0);
 			v.reserve(5);
 			v.insertBack(1);
 			v.insertBack(3);
 			assert(v.capacity == 5);
 			assert(v.length == 2);
 			v.shrink(4);
 			assert(v.capacity == 4);
 			assert(v.length == 2);
 			v.shrink(1);
 			assert(v.capacity == 2);
 			assert(v.length == 2);
 		}
 		/**
 		 * Returns: $(D_KEYWORD true) if the vector is empty.
 		 */
 		@property bool empty() inout const
 		{
 			return length == 0;
 		}
 		/**
 		 * Removes $(D_PARAM howMany) elements from the vector.
 		 *
 		 * This method doesn't fail if it could not remove $(D_PARAM howMany)
 		 * elements. Instead, if $(D_PARAM howMany) is greater than the vector
 		 * length, all elements are removed.
 		 *
 		 * Params:
 		 * 	howMany = How many elements should be removed.
 		 *
 		 * Returns: The number of elements removed
 		 */
 		size_t removeBack(in size_t howMany = 1)
 		{
 			immutable toRemove = min(howMany, length);
 			length = length - toRemove;
 			return toRemove;
 		}
 		/// Ditto.
 		alias remove = removeBack;
 		///
 		unittest
 		{
 			auto v = Vector!int(IL(5, 18, 17));
 			assert(v.removeBack(0) == 0);
 			assert(v.removeBack(2) == 2);
 			assert(v.removeBack(3) == 1);
 			assert(v.removeBack(3) == 0);
 		}
 		/**
 		 * Inserts the $(D_PARAM el) into the vector.
 		 *
 		 * Returns: The number of elements inserted.
 		 */
 		size_t insertBack(T el)
 		{
 			reserve(length + 1);
 			vector[length] = el;
 			++length_;
 			return 1;
 		}
 		/// Ditto.
 		size_t insertBack(Range!Vector el)
 		{
 			immutable newLength = length + el.length;
 			reserve(newLength);
 			vector[length .. newLength] = el.outer.vector[el.start .. el.end];
 			length_ = newLength;
 			return el.length;
 		}
 		/// Ditto.
 		size_t insertBack(R)(R el)
 			if (isInputRange!R && isImplicitlyConvertible!(ElementType!R, T))
 		{
 			immutable rLen = walkLength(el);
 			reserve(length + rLen);
 			while (!el.empty)
 			{
 				vector[length_] = el.front;
 				el.popFront();
 				length_++;
 			}
 			return rLen;
 		}
 		/// Ditto.
 		alias insert = insertBack;
 		///
 		unittest
 		{
 			struct TestRange
 			{
 				int counter = 6;
 				int front()
 				{
 					return counter;
 				}
 				void popFront()
 				{
 					counter -= 2;
 				}
 				bool empty()
 				{
 					return counter == 0;
 				}
 			}
 			Vector!int v1;
 			assert(v1.insertBack(5) == 1);
 			assert(v1.length == 1);
 			assert(v1.capacity == 1);
 			assert(v1.back == 5);
 			assert(v1.insertBack(TestRange()) == 3);
 			assert(v1.length == 4);
 			assert(v1.capacity == 4);
 			assert(v1[0] == 5 && v1[1] == 6 && v1[2] == 4 && v1[3] == 2);
 			auto v2 = Vector!int(IL(34, 234));
 			assert(v1.insertBack(v2[]) == 2);
 			assert(v1.length == 6);
 			assert(v1.capacity == 6);
 			assert(v1[4] == 34 && v1[5] == 234);
 		}
 		/**
 		 * Assigns a value to the element with the index $(D_PARAM pos).
 		 *
 		 * Params:
 		 * 	value = Value.
 		 * 	pos   = Position.
 		 *
 		 * Returns: Assigned value.
 		 *
 		 * Precondition: $(D_INLINECODE length > pos)
 		 */
 		T opIndexAssign(T value, in size_t pos)
 		in
 		{
 			assert(length > pos);
 		}
 		body
 		{
 			return vector[pos] = value;
 		}
 		/// Ditto.
 		Range!Vector opIndexAssign(T value)
 		{
 			vector[0 .. $] = value;
 			return opIndex();
 		}
 		///
 		unittest
 		{
 			auto v1 = Vector!int(IL(12, 1, 7));
 			v1[] = 3;
 			assert(v1[0] == 3);
 			assert(v1[1] == 3);
 			assert(v1[2] == 3);
 		}
 		/**
 		 * Params:
 		 * 	pos = Index.
 		 *
 		 * Returns: The value at a specified index.
 		 *
 		 * Precondition: $(D_INLINECODE length > pos)
 		 */
 		ref inout(T) opIndex(in size_t pos) inout
 		in
 		{
 			assert(length > pos);
 		}
 		body
 		{
 			return vector[pos];
 		}
 		/**
 		 * Returns: Random access range that iterates over elements of the vector, in
 		 *          forward order.
 		 */
 		Range!Vector opIndex()
 		{
 			return typeof(return)(this, 0, length);
 		}
 		/// Ditto.
 		Range!(const Vector) opIndex() const
 		{
 			return typeof(return)(this, 0, length);
 		}
 		/// Ditto.
 		Range!(immutable Vector) opIndex() immutable
 		{
 			return typeof(return)(this, 0, length);
 		}
 		///
 		unittest
 		{
 			const v1 = Vector!int(IL(6, 123, 34, 5));
 			assert(v1[0] == 6);
 			assert(v1[1] == 123);
 			assert(v1[2] == 34);
 			assert(v1[3] == 5);
 			static assert(is(typeof(v1[0]) == const(int)));
 			static assert(is(typeof(v1[])));
 			auto v2 = immutable Vector!int(IL(6, 123, 34, 5));
 			static assert(is(typeof(v2[0]) == immutable(int)));
 			static assert(is(typeof(v2[])));
 		}
 		/**
 		 * Comparison for equality.
 		 *
 		 * Params:
 		 * 	o = The vector to compare with.
 		 *
 		 * Returns: $(D_KEYWORD true) if the vectors are equal, $(D_KEYWORD false)
 		 *          otherwise.
 		 */
 		bool opEquals(typeof(this) v) const
 		{
 			return opEquals(v);
 		}
 		/// Ditto.
 		bool opEquals(ref typeof(this) v) const
 		{
 			return vector == v.vector;
 		}
 		///
 		unittest
 		{
 			Vector!int v1, v2;
 			assert(v1 == v2);
 			v1.length = 1;
 			v2.length = 2;
 			assert(v1 != v2);
 			v1.length = 2;
 			v1[0] = v2[0] = 2;
 			v1[1] = 3;
 			v2[1] = 4;
 			assert(v1 != v2);
 			v2[1] = 3;
 			assert(v1 == v2);
 		}
 		/**
 		 * $(D_KEYWORD foreach) iteration.
 		 *
 		 * Params:
 		 * 	dg = $(D_KEYWORD foreach) body.
 		 */
 		int opApply(scope int delegate(ref T) dg)
 		{
 			int result;
 			foreach (e; vector)
 			{
 				if ((result = dg(e)) != 0)
 				{
 					return result;
 				}
 			}
 			return result;
 		}
 		/// Ditto.
 		int opApply(scope int delegate(ref size_t i, ref T) dg)
 		{
 			int result;
 			foreach (i, e; vector)
 			{
 				if ((result = dg(i, e)) != 0)
 				{
 					return result;
 				}
 			}
 			return result;
 		}
 		/// Ditto.
 		int opApplyReverse(scope int delegate(ref T) dg)
 		{
 			int result;
 			foreach_reverse (e; vector)
 			{
 				if ((result = dg(e)) != 0)
 				{
 					return result;
 				}
 			}
 			return result;
 		}
 		/// Ditto.
 		int opApplyReverse(scope int delegate(ref size_t i, ref T) dg)
 		{
 			int result;
 			foreach_reverse (i, e; vector)
 			{
 				if ((result = dg(i, e)) != 0)
 				{
 					return result;
 				}
 			}
 			return result;
 		}
 		///
 		unittest
 		{
 			auto v = Vector!int(IL(5, 15, 8));
 			size_t i;
 			foreach (j, ref e; v)
 			{
 				i = j;
 			}
 			assert(i == 2);
 			foreach (j, e; v)
 			{
 				assert(j != 0 || e == 5);
 				assert(j != 1 || e == 15);
 				assert(j != 2 || e == 8);
 			}
 		}
 		///
 		unittest
 		{
 			auto v = Vector!int(IL(5, 15, 8));
 			size_t i;
 			foreach_reverse (j, ref e; v)
 			{
 				i = j;
 			}
 			assert(i == 0);
 			foreach_reverse (j, e; v)
 			{
 				assert(j != 2 || e == 8);
 				assert(j != 1 || e == 15);
 				assert(j != 0 || e == 5);
 			}
 		}
 		/**
 		 * Returns: The first element.
 		 *
 		 * Precondition: $(D_INLINECODE length > 0)
 		 */
 		@property ref inout(T) front() inout
 		in
 		{
 			assert(!empty);
 		}
 		body
 		{
 			return vector[0];
 		}
 		///
 		unittest
 		{
 			auto v = Vector!int(IL(5));
 			assert(v.front == 5);
 			v.length = 2;
 			v[1] = 15;
 			assert(v.front == 5);
 		}
 		/**
 		 * Returns: The last element.
 		 *
 		 * Precondition: $(D_INLINECODE length > 0)
 		 */
 		@property ref inout(T) back() inout
 		in
 		{
 			assert(!empty);
 		}
 		body
 		{
 			return vector[length_ - 1];
 		}
 		///
 		unittest
 		{
 			auto v = Vector!int(IL(5));
 			assert(v.back == 5);
 			v.length = 2;
 			v[1] = 15;
 			assert(v.back == 15);
 		}
 		/**
 		 * Params:
 		 * 	i = Slice start.
 		 * 	j = Slice end.
 		 *
 		 * Returns: A range that iterates over elements of the container from
 		 *          index $(D_PARAM i) up to (excluding) index $(D_PARAM j).
 		 *
 		 * Precondition: $(D_INLINECODE i <= j && j <= length)
 		 */
 		Range!Vector opSlice(in size_t i, in size_t j)
 		in
 		{
 			assert(i <= j);
 			assert(j <= length);
 		}
 		body
 		{
 			return typeof(return)(this, i, j);
 		}
 		/**
 		 * Slicing assignment.
 		 *
 		 * Params:
 		 * 	value = New value.
 		 * 	i     = Slice start.
 		 * 	j     = Slice end.
 		 *
 		 * Returns: Assigned value.
 		 *
 		 * Precondition: $(D_INLINECODE i <= j && j <= length);
 		 *               The lenghts of the ranges and slices match.
 		 */
 		Range!Vector opSliceAssign(T value, in size_t i, in size_t j)
 		in
 		{
 			assert(i <= j);
 			assert(j <= length);
 		}
 		body
 		{
 			vector[i .. j] = value;
 			return opSlice(i, j);
 		}
 		/// Ditto.
 		Range!Vector opSliceAssign(Range!Vector value, in size_t i, in size_t j)
 		in
 		{
 			assert(j - i == value.length);
 		}
 		body
 		{
 			vector[i .. j] = value.outer.vector[value.start .. value.end];
 			return opSlice(i, j);
 		}
 		/// Ditto.
 		Range!Vector opSliceAssign(T[] value, in size_t i, in size_t j)
 		in
 		{
 			assert(j - i == value.length);
 		}
 		body
 		{
 			vector[i .. j] = value;
 			return opSlice(i, j);
 		}
 		///
 		unittest
 		{
 			auto v1 = Vector!int(IL(3, 3, 3));
 			auto v2 = Vector!int(IL(1, 2));
 			v1[0 .. 2] = 286;
 			assert(v1[0] == 286);
 			assert(v1[1] == 286);
 			assert(v1[2] == 3);
 			v2[0 .. $] = v1[1 .. 3];
 			assert(v2[0] == 286);
 			assert(v2[1] == 3);
 		}
 		mixin DefaultAllocator;
 	}
 }
 ///
 unittest
 {
 	auto v = Vector!int(IL(5, 15, 8));
 	assert(v.front == 5);
 	assert(v[1] == 15);
 	assert(v.back == 8);
 }
 private @nogc unittest
 {
 	// Test the destructor can be called at the end of the scope.
 	auto a = Vector!A();
 	// Test that structs can be members of the vector.
 	static assert(is(typeof(Vector!TestA())));
 	static assert(is(typeof(immutable Vector!TestA(IL(TestA())))));
 	static assert(is(typeof(const Vector!TestA(IL(TestA())))));
 }
 private @nogc unittest
 {
 	const v1 = Vector!int();
 	const Vector!int v2;
 	const v3 = Vector!int(IL(1, 5, 8));
 	static assert(is(typeof(v3.vector) == const(int[])));
 	static assert(is(typeof(v3.vector[0]) == const(int)));
 	immutable v4 = immutable Vector!int();
 	immutable v5 = immutable Vector!int(IL(2, 5, 8));
 	static assert(is(typeof(v4.vector) == immutable(int[])));
 	static assert(is(typeof(v4.vector[0]) == immutable(int)));
 }
 private @nogc unittest
 {
 	// Test that immutable/const vectors return usable ranges.
 	auto v = immutable Vector!int(IL(1, 2, 4));
 	auto r = v[];
 	assert(r.back == 4);
 	r.popBack();
 	assert(r.back == 2);
 	r.popBack();
 	assert(r.back == 1);
 	r.popBack();
 }
 private @nogc unittest
 {
 	Vector!int v1;
 	const Vector!int v2;
 	auto r1 = v1[];
 	auto r2 = v1[];
 	assert(r1.length == 0);
 	assert(r2.empty);
 	assert(r1 == r2);
 }
--- a/source/tanya/conv.d
+++ b/source/tanya/conv.d
--- a/source/tanya/crypto/bit.d
+++ b/source/tanya/crypto/bit.d
@ -1,510 +0,0 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * Copyright: Eugene Wissner 2016.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:belka@caraus.de, Eugene Wissner)
 */
 module tanya.crypto.bit;
 /**
 * Wrapper that allows bit manipulation on $(D_KEYWORD ubyte[]) array.
 */
 struct BitVector
 {
    protected ubyte[] vector;
    /**
     * Params:
     *     array = Array should be manipulated on.
     */
    this(inout(ubyte[]) array) inout pure nothrow @safe @nogc
    in
    {
        assert(array.length <= size_t.max / 8);
        assert(array !is null);
    }
    body
    {
        vector = array;
    }
    ///
    unittest
    {
        ubyte[5] array1 = [234, 3, 252, 10, 18];
        ubyte[3] array2 = [65, 13, 173];
        auto bits = BitVector(array1);
        assert(bits[] is array1);
        assert(bits[] !is array2);
        bits = BitVector(array2);
        assert(bits[] is array2);
    }
    /**
     * Returns: Number of bits in the vector.
     */
    @property inout(size_t) length() inout const pure nothrow @safe @nogc
    {
        return vector.length * 8;
    }
    /// Ditto.
    inout(size_t) opDollar() inout const pure nothrow @safe @nogc
    {
        return vector.length * 8;
    }
    ///
    unittest
    {
        // [01000001, 00001101, 10101101]
        ubyte[3] arr = [65, 13, 173];
        auto bits = BitVector(arr);
        assert(bits.length == 24);
    }
    /**
     * Params:
     *     bit = Bit position.
     *
     * Returns: $(D_KEYWORD true) if the bit on position $(D_PARAM bit) is set,
     *          $(D_KEYWORD false) if not set.
     */
    inout(bool) opIndex(size_t bit) inout const pure nothrow @safe @nogc
    in
    {
        assert(bit / 8 <= vector.length);
    }
    body
    {
        return (vector[bit / 8] & (0x80 >> (bit % 8))) != 0;
    }
    ///
    unittest
    {
        // [01000001, 00001101, 10101101]
        ubyte[3] arr = [65, 13, 173];
        auto bits = BitVector(arr);
        assert(!bits[0]);
        assert(bits[1]);
        assert(bits[7]);
        assert(!bits[8]);
        assert(!bits[11]);
        assert(bits[12]);
        assert(bits[20]);
        assert(bits[23]);
    }
    /**
     * Returns: Underlying array.
     */
    inout(ubyte[]) opIndex() inout pure nothrow @safe @nogc
    {
        return vector;
    }
    ///
    unittest
    {
        // [01000001, 00001101, 10101101]
        ubyte[3] arr = [65, 13, 173];
        auto bits = BitVector(arr);
        assert(bits[] is arr);
    }
    /**
     * Params:
     *     value = $(D_KEYWORD true) if the bit should be set,
     *             $(D_KEYWORD false) if cleared.
     *     bit   = Bit position.
     *
     * Returns: $(D_PSYMBOL this).
     */
    bool opIndexAssign(bool value, size_t bit) pure nothrow @safe @nogc
    in
    {
        assert(bit / 8 <= vector.length);
    }
    body
    {
        if (value)
        {
            vector[bit / 8] |= (0x80 >> (bit % 8));
        }
        else
        {
            vector[bit / 8] &= ~(0x80 >> (bit % 8));
        }
        return value;
    }
    ///
    unittest
    {
        // [01000001, 00001101, 10101101]
        ubyte[3] arr = [65, 13, 173];
        auto bits = BitVector(arr);
        bits[5] = bits[6] = true;
        assert(bits[][0] == 71);
        bits[14] = true;
        bits[15] = false;
        assert(bits[][1] == 14);
        bits[16] = bits[23] = false;
        assert(bits[][2] == 44);
    }
    /**
     * Copies bits from $(D_PARAM vector) into this $(D_PSYMBOL BitVector).
     *
     * The array that should be assigned, can be smaller (but not larger) than
     * the underlying array of this $(D_PSYMBOL BitVector), leading zeros will
     * be added in this case to the left.
     *
     * Params:
     *     vector = $(D_KEYWORD ubyte[]) array not larger than
     *              `$(D_PSYMBOL length) / 8`.
     *
     * Returns: $(D_KEYWORD this).
     */
    BitVector opAssign(ubyte[] vector) pure nothrow @safe @nogc
    in
    {
        assert(vector.length <= this.vector.length);
    }
    body
    {
        immutable delta = this.vector.length - vector.length;
        if (delta > 0)
        {
            this.vector[0..delta] = 0;
        }
        this.vector[delta..$] = vector[0..$];
        return this;
    }
    ///
    unittest
    {
        ubyte[5] array1 = [234, 3, 252, 10, 18];
        ubyte[3] array2 = [65, 13, 173];
        auto bits = BitVector(array1);
        bits = array2;
        assert(bits[][0] == 0);
        assert(bits[][1] == 0);
        assert(bits[][2] == 65);
        assert(bits[][3] == 13);
        assert(bits[][4] == 173);
        bits = array2[0..2];
        assert(bits[][0] == 0);
        assert(bits[][1] == 0);
        assert(bits[][2] == 0);
        assert(bits[][3] == 65);
        assert(bits[][4] == 13);
    }
    /**
     * Support for bitwise operations.
     *
     * Params:
     *     that = Another bit vector.
     *
     * Returns: $(D_KEYWORD this).
     */
    BitVector opOpAssign(string op)(BitVector that) pure nothrow @safe @nogc
        if ((op == "^") || (op == "|") || (op == "&"))
    {
        return opOpAssign(op)(that.vector);
    }
    /// Ditto.
    BitVector opOpAssign(string op)(ubyte[] that) pure nothrow @safe @nogc
        if ((op == "^") || (op == "|") || (op == "&"))
    in
    {
        assert(that.length <= vector.length);
    }
    body
    {
        for (int i = cast(int) vector.length - 1; i >= 0; --i)
        {
            mixin("vector[i] " ~  op ~ "= " ~ "that[i];");
        }
        immutable delta = vector.length - that.length;
        if (delta)
        {
            static if (op == "&")
            {
                vector[0..delta] = 0;
            }
        }
        return this;
    }
    ///
    unittest
    {
        // [01000001, 00001101, 10101101]
        ubyte[3] array1 = [65, 13, 173];
        ubyte[3] array2 = [0b01010010, 0b10111110, 0b10111110];
        auto bits = BitVector(array1);
        bits |= array2;
        assert(bits[][0] == 0b01010011);
        assert(bits[][1] == 0b10111111);
        assert(bits[][2] == 0b10111111);
        bits &= array2;
        assert(bits[][0] == array2[0]);
        assert(bits[][1] == array2[1]);
        assert(bits[][2] == array2[2]);
        bits ^= array2;
        assert(bits[][0] == 0);
        assert(bits[][1] == 0);
        assert(bits[][2] == 0);
    }
    /**
     * Support for shift operations.
     *
     * Params:
     *     n = Number of bits.
     *
     * Returns: $(D_KEYWORD this).
     */
    BitVector opOpAssign(string op)(in size_t n) pure nothrow @safe @nogc
        if ((op == "<<") || (op == ">>"))
    {
        if (n >= length)
        {
            vector[0..$] = 0;
        }
        else if (n != 0)
        {
            immutable bit = n % 8, step = n / 8;
            immutable delta = 8 - bit;
            size_t i, j;
            static if (op == "<<")
            {
                for (j = step; j < vector.length - 1; ++i)
                {
                    vector[i] = cast(ubyte)((vector[j] << bit)
                              | vector[++j] >> delta);
                }
                vector[i] = cast(ubyte)(vector[j] << bit);
                vector[$ - step ..$] = 0;
            }
            else static if (op == ">>")
            {
                for (i = vector.length - 1, j = i - step; j > 0; --i)
                {
                    vector[i] = cast(ubyte)((vector[j] >> bit)
                              | vector[--j] << delta);
                }
                vector[i] = cast(ubyte)(vector[j] >> bit);
                vector[0..step] = 0;
            }
        }
        return this;
    }
    ///
    nothrow @safe @nogc unittest
    {
        ubyte[4] arr = [0b10111110, 0b11110010, 0b01010010, 0b01010011];
        auto bits = BitVector(arr);
        bits <<= 0;
        assert(bits[][0] == 0b10111110 && bits[][1] == 0b11110010
            && bits[][2] == 0b01010010 && bits[][3] == 0b01010011);
        bits <<= 2;
        assert(bits[][0] == 0b11111011 && bits[][1] == 0b11001001
            && bits[][2] == 0b01001001 && bits[][3] == 0b01001100);
        bits <<= 4;
        assert(bits[][0] == 0b10111100 && bits[][1] == 0b10010100
            && bits[][2] == 0b10010100 && bits[][3] == 0b11000000);
        bits <<= 8;
        assert(bits[][0] == 0b10010100 && bits[][1] == 0b10010100
            && bits[][2] == 0b11000000 && bits[][3] == 0b00000000);
        bits <<= 7;
        assert(bits[][0] == 0b01001010 && bits[][1] == 0b01100000
            && bits[][2] == 0b00000000 && bits[][3] == 0b00000000);
        bits <<= 25;
        assert(bits[][0] == 0b00000000 && bits[][1] == 0b00000000
            && bits[][2] == 0b00000000 && bits[][3] == 0b00000000);
        arr = [0b00110011, 0b11001100, 0b11111111, 0b01010101];
        bits <<= 24;
        assert(bits[][0] == 0b01010101 && bits[][1] == 0b00000000
            && bits[][2] == 0b00000000 && bits[][3] == 0b00000000);
        arr[1] = 0b11001100;
        arr[2] = 0b11111111;
        arr[3] = 0b01010101;
        bits <<= 12;
        assert(bits[][0] == 0b11001111 && bits[][1] == 0b11110101
            && bits[][2] == 0b01010000 && bits[][3] == 0b00000000);
        bits <<= 100;
        assert(bits[][0] == 0b00000000 && bits[][1] == 0b00000000
            && bits[][2] == 0b00000000 && bits[][3] == 0b00000000);
        arr = [0b10111110, 0b11110010, 0b01010010, 0b01010011];
        bits >>= 0;
        assert(bits[][0] == 0b10111110 && bits[][1] == 0b11110010
            && bits[][2] == 0b01010010 && bits[][3] == 0b01010011);
        bits >>= 2;
        assert(bits[][0] == 0b00101111 && bits[][1] == 0b10111100
            && bits[][2] == 0b10010100 && bits[][3] == 0b10010100);
        bits >>= 4;
        assert(bits[][0] == 0b00000010 && bits[][1] == 0b11111011
            && bits[][2] == 0b11001001 && bits[][3] == 0b01001001);
        bits >>= 8;
        assert(bits[][0] == 0b00000000 && bits[][1] == 0b00000010
            && bits[][2] == 0b11111011 && bits[][3] == 0b11001001);
        bits >>= 7;
        assert(bits[][0] == 0b00000000 && bits[][1] == 0b00000000
            && bits[][2] == 0b00000101 && bits[][3] == 0b11110111);
        bits >>= 25;
        assert(bits[][0] == 0b00000000 && bits[][1] == 0b00000000
            && bits[][2] == 0b00000000 && bits[][3] == 0b00000000);
        arr = [0b00110011, 0b11001100, 0b11111111, 0b01010101];
        bits >>= 24;
        assert(bits[][0] == 0b00000000 && bits[][1] == 0b00000000
            && bits[][2] == 0b00000000 && bits[][3] == 0b00110011);
        arr[1] = 0b11001100;
        arr[2] = 0b11111111;
        arr[3] = 0b01010101;
        bits >>= 12;
        assert(bits[][0] == 0b00000000 && bits[][1] == 0b00000000
            && bits[][2] == 0b00001100 && bits[][3] == 0b11001111);
        bits >>= 100;
        assert(bits[][0] == 0b00000000 && bits[][1] == 0b00000000
            && bits[][2] == 0b00000000 && bits[][3] == 0b00000000);
    }
    /**
     * Negates all bits.
     *
     * Returns: $(D_KEYWORD this).
     */
    BitVector opUnary(string op)() pure nothrow @safe @nogc
        if (op == "~")
    {
        foreach (ref b; vector)
        {
            b = ~b;
        }
        return this;
    }
    ///
    unittest
    {
        // [01000001, 00001101, 10101101]
        ubyte[3] arr = [65, 13, 173];
        auto bits = BitVector(arr);
        ~bits;
        assert(bits[][0] == 0b10111110);
        assert(bits[][1] == 0b11110010);
        assert(bits[][2] == 0b01010010);
    }
    /**
     * Iterates through all bits.
     *
     * Params:
     *     dg = $(D_KEYWORD foreach) delegate.
     *
     * Returns: By $(D_PARAM dg) returned value.
     */
    int opApply(int delegate(size_t, bool) dg)
    {
        int result;
        foreach (i, ref v; vector)
        {
            foreach (c; 0..8)
            {
                result = dg(i * 8 + c, (v & (0x80 >> c)) != 0);
                if (result)
                {
                    return result;
                }
            }
        }
        return result;
    }
    /// Ditto.
    int opApply(int delegate(bool) dg)
    {
        int result;
        foreach (ref v; vector)
        {
            foreach (c; 0..8)
            {
                result = dg((v & (0x80 >> c)) != 0);
                if (result)
                {
                    return result;
                }
            }
        }
        return result;
    }
    ///
    unittest
    {
        ubyte[2] arr = [0b01000001, 0b00001101];
        auto bits = BitVector(arr);
        size_t c;
        foreach (i, v; bits)
        {
            assert(i == c);
            if (i == 1 || i == 7 || i == 15 || i == 13 || i == 12)
            {
                assert(v);
            }
            else
            {
                assert(!v);
            }
            ++c;
        }
        assert(c == 16);
    }
 }
--- a/source/tanya/crypto/des.d
+++ b/source/tanya/crypto/des.d
@ -1,607 +0,0 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * Copyright: Eugene Wissner 2016.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:belka@caraus.de, Eugene Wissner)
 */
 module tanya.crypto.des;
 import tanya.crypto.bit;
 import tanya.crypto.symmetric;
 /// Initial permutation table.
 private immutable ubyte[64] ipTable = [58, 50, 42, 34, 26, 18, 10, 2,
                                       60, 52, 44, 36, 28, 20, 12, 4,
                                       62, 54, 46, 38, 30, 22, 14, 6,
                                       64, 56, 48, 40, 32, 24, 16, 8,
                                       57, 49, 41, 33, 25, 17, 9,  1,
                                       59, 51, 43, 35, 27, 19, 11, 3,
                                       61, 53, 45, 37, 29, 21, 13, 5,
                                       63, 55, 47, 39, 31, 23, 15, 7];
 /// Final permutation table.
 private immutable ubyte[64] fpTable = [40, 8, 48, 16, 56, 24, 64, 32,
                                       39, 7, 47, 15, 55, 23, 63, 31,
                                       38, 6, 46, 14, 54, 22, 62, 30,
                                       37, 5, 45, 13, 53, 21, 61, 29,
                                       36, 4, 44, 12, 52, 20, 60, 28,
                                       35, 3, 43, 11, 51, 19, 59, 27,
                                       34, 2, 42, 10, 50, 18, 58, 26,
                                       33, 1, 41, 9,  49, 17, 57, 25];
 /// Key permutation table 1.
 private immutable ubyte[64] pc1Table = [57, 49, 41, 33, 25, 17, 9, 1,
                                        58, 50, 42, 34, 26, 18, 10, 2,
                                        59, 51, 43, 35, 27, 19, 11, 3,
                                        60, 52, 44, 36, 63, 55, 47, 39,
                                        31, 23, 15, 7,  62, 54, 46, 38,
                                        30, 22, 14, 6,  61, 53, 45, 37,
                                        29, 21, 13, 5,  28, 20, 12, 4];
 /// Key permutation table 2.
 private immutable ubyte[48] pc2Table = [14, 17, 11, 24, 1,  5,  3,  28,
                                        15, 6,  21, 10, 23, 19, 12, 4,
                                        26, 8,  16, 7,  27, 20, 13, 2,
                                        41, 52, 31, 37, 47, 55, 30, 40,
                                        51, 45, 33, 48, 44, 49, 39, 56,
                                        34, 53, 46, 42, 50, 36, 29, 32];
 /// Expansion table.
 private immutable ubyte[48] expansionTable = [32, 1,  2,  3,  4,  5,  4,  5,
                                              6,  7,  8,  9,  8,  9,  10, 11,
                                              12, 13, 12, 13, 14, 15, 16, 17,
                                              16, 17, 18, 19, 20, 21, 20, 21,
                                              22, 23, 24, 25, 24, 25, 26, 27,
                                              28, 29, 28, 29, 30, 31, 32, 1];
 /// Final input block permutation.
 private immutable ubyte[32] pTable = [16, 7,  20, 21, 29, 12, 28, 17,
                                      1,  15, 23, 26, 5,  18, 31, 10,
                                      2,  8,  24, 14, 32, 27, 3,  9,
                                      19, 13, 30, 6,  22, 11, 4, 25];
 /// The (in)famous S-boxes.
 private immutable ubyte[64][8] sBox = [[
                                         14, 0,  4,  15, 13, 7,  1,  4,  2, 14,  15, 2, 11, 13, 8,  1,
                                         3,  10, 10, 6,  6,  12, 12, 11, 5,  9,  9,  5, 0,  3,  7,  8,
                                         4,  15, 1,  12, 14, 8,  8,  2,  13, 4,  6,  9, 2,  1,  11, 7,
                                         15, 5,  12, 11, 9,  3,  7,  14, 3,  10, 10, 0, 5,  6,  0,  13,
                                      ],[
                                         15, 3,  1,  13, 8,  4,  14, 7,  6,  15, 11, 2,  3,  8,  4,  14,
                                         9,  12, 7,  0,  2,  1,  13, 10, 12, 6,  0,  9,  5,  11, 10, 5,
                                         0,  13, 14, 8,  7,  10, 11, 1,  10, 3,  4,  15, 13, 4,  1,  2,
                                         5,  11, 8,  6,  12, 7,  6,  12, 9,  0,  3,  5,  2,  14, 15, 9,
                                      ],[
                                         10, 13, 0,  7,  9,  0,  14, 9,  6,  3,  3,  4,  15, 6,  5,  10,
                                         1,  2,  13, 8,  12, 5,  7,  14, 11, 12, 4,  11, 2,  15, 8,  1,
                                         13, 1,  6,  10, 4,  13, 9,  0,  8,  6,  15, 9,  3,  8,  0,  7,
                                         11, 4,  1,  15, 2,  14, 12, 3,  5,  11, 10, 5,  14, 2,  7,  12,
                                      ],[
                                         7,  13, 13, 8,  14, 11, 3,  5,  0,  6,  6,  15, 9,  0,  10, 3,
                                         1,  4,  2,  7,  8,  2,  5,  12, 11, 1,  12, 10, 4,  14, 15, 9,
                                         10, 3,  6,  15, 9,  0,  0,  6,  12, 10, 11, 1,  7,  13, 13, 8,
                                         15, 9,  1,  4,  3,  5,  14, 11, 5,  12, 2,  7,  8,  2,  4,  14,
                                      ],[
                                         2,  14, 12, 11, 4,  2,  1,  12, 7,  4,  10, 7,  11, 13, 6,  1,
                                         8,  5,  5,  0,  3,  15, 15, 10, 13, 3,  0,  9,  14, 8,  9,  6,
                                         4,  11, 2,  8,  1,  12, 11, 7,  10, 1,  13, 14, 7,  2,  8,  13,
                                         15, 6,  9,  15, 12, 0,  5,  9,  6,  10, 3,  4,  0,  5,  14, 3,
                                      ],[
                                         12, 10, 1,  15, 10, 4,  15, 2,  9,  7,  2,  12, 6,  9,  8,  5,
                                         0,  6,  13, 1,  3,  13, 4,  14, 14, 0,  7,  11, 5,  3,  11, 8,
                                         9,  4,  14, 3,  15, 2,  5,  12, 2,  9,  8,  5,  12, 15, 3,  10,
                                         7,  11, 0,  14, 4,  1,  10, 7,  1,  6,  13, 0,  11, 8,  6,  13,
                                      ],[
                                         4,  13, 11, 0,  2,  11, 14, 7,  15, 4,  0,  9,  8,  1,  13, 10,
                                         3,  14, 12, 3,  9,  5,  7,  12, 5,  2,  10, 15, 6,  8,  1,  6,
                                         1,  6,  4,  11, 11, 13, 13, 8,  12, 1,  3,  4,  7,  10, 14, 7,
                                         10, 9,  15, 5,  6,  0,  8,  15, 0,  14, 5,  2,  9,  3,  2,  12,
                                      ],[
                                         13, 1,  2,  15, 8,  13, 4,  8,  6,  10, 15, 3,  11, 7,  1,  4,
                                         10, 12, 9,  5,  3,  6,  14, 11, 5,  0,  0,  14, 12, 9,  7,  2,
                                         7,  2,  11, 1,  4,  14, 1,  7,  9,  4,  12, 10, 14, 8,  2,  13,
                                         0,  15, 6,  12, 10, 9,  13, 0,  15, 3,  3,  5,  5,  6,  8,  11,
                                      ]];
 /**
 * Data Encryption Standard.
 *
 * Params:
 *     L = Number of keys.
 */
 class DES(ushort L = 1) : BlockCipher
    if (L == 1)
 {
    mixin FixedBlockSize!8;
    mixin KeyLength!8;
    private enum expansionBlockSize = 6;
    private enum pc1KeyLength = 7;
    private enum subkeyLength = 6;
    private ubyte[] key_;
    /**
     * Params:
     *     key = Key.
     */
    @property void key(ubyte[] key) pure nothrow @safe @nogc
    in
    {
        assert(key.length >= minKeyLength);
        assert(key.length <= maxKeyLength);
    }
    body
    {
        key_ = key;
    }
    /**
     * Encrypts a block.
     *
     * Params:
     *    plain  = Plain text, input.
     *    cipher = Cipher text, output.
     */
    void encrypt(in ubyte[] plain, ubyte[] cipher)
    nothrow
    in
    {
        assert(plain.length == blockSize);
        assert(cipher.length == blockSize);
    }
    body
    {
        operateBlock!(Direction.encryption)(plain, cipher);
    }
    /**
     * Decrypts a block.
     *
     * Params:
     *    cipher = Cipher text, input.
     *    plain  = Plain text, output.
     */
    void decrypt(in ubyte[] cipher, ubyte[] plain)
    nothrow
    in
    {
        assert(plain.length == blockSize);
        assert(cipher.length == blockSize);
    }
    body
    {
        operateBlock!(Direction.decryption)(cipher, plain);
    }
    private void operateBlock(Direction D)(in ubyte[] source, ref ubyte[] target)
    {
        ubyte[blockSize_] ipBlock;
        ubyte[expansionBlockSize] expansionBlock;
        ubyte[4] substitutionBlock;
        ubyte[4] pBoxTarget;
        ubyte[pc1KeyLength] pc1Key;
        ubyte[subkeyLength] subkey;
        // Initial permutation
        permute(source, ipBlock, ipTable, blockSize);
        // Key schedule computation
        permute(key_, pc1Key, pc1Table, pc1KeyLength);
        // Feistel function
        for (ubyte round; round < 16; ++round)
        {
            auto bitVector = BitVector(expansionBlock);
            /* Expansion. This permutation only looks at the first 4 bytes (32
               bits of ipBlock); 16 of these are repeated in expansion table.*/
            permute(BitVector(ipBlock[4..$]), bitVector, expansionTable, 6);
            // Key mixing
            static if (D == Direction.encryption)
            {
                rotateLeft(pc1Key);
                if (!(round <= 1 || round == 8 || round == 15))
                {
                    // Rotate twice.
                    rotateLeft(pc1Key);
                }
            }
            permute(pc1Key, subkey, pc2Table, subkeyLength);
            static if (D == Direction.decryption)
            {
                rotateRight(pc1Key);
                if (!(round >= 14 || round == 7 || round == 0))
                {
                    // Rotate twice.
                    rotateRight(pc1Key);
                }
            }
            bitVector ^= subkey;
            // Substitution; copy from updated expansion block to ciphertext block
            substitutionBlock[0] = cast(ubyte) (sBox[0][(expansionBlock[0] & 0xfc ) >> 2] << 4);
            substitutionBlock[0] |= sBox[1][(expansionBlock[0] & 0x03) << 4 | (expansionBlock[1] & 0xf0) >> 4];
            substitutionBlock[1] = cast(ubyte) (sBox[2][(expansionBlock[1] & 0x0f) << 2 | (expansionBlock[2] & 0xc0) >> 6] << 4);
            substitutionBlock[1] |= sBox[3][(expansionBlock[2] & 0x3f)];
            substitutionBlock[2] = cast(ubyte) (sBox[4][(expansionBlock[3] & 0xfc) >> 2 ] << 4);
            substitutionBlock[2] |= sBox[5][(expansionBlock[3] & 0x03) << 4 | (expansionBlock[4] & 0xf0) >> 4];
            substitutionBlock[3] = cast(ubyte) (sBox[6][(expansionBlock[4] & 0x0F) << 2 | (expansionBlock[5] & 0xc0) >> 6] << 4);
            substitutionBlock[3] |= sBox[7][(expansionBlock[5] & 0x3f)];
            // Permutation
            bitVector = BitVector(substitutionBlock);
            permute(bitVector, pBoxTarget, pTable, blockSize / 2);
            // Swap the halves.
            substitutionBlock = ipBlock[0..4];
            ipBlock[0..4] = ipBlock[4..$];
            bitVector ^= pBoxTarget;
            ipBlock[4..$] = substitutionBlock;
        }
        substitutionBlock = ipBlock[0..4];
        ipBlock[0..4] = ipBlock[4..$];
        ipBlock[4..$] = substitutionBlock;
        // Final permutaion (undo initial permuation).
        permute(ipBlock, target, fpTable, blockSize);
    }
    /**
     * Performs the left rotation operation on the key.
     *
     * Params:
     *     key = The key to rotate.
     */
    private void rotateLeft(ref ubyte[7] key) const pure nothrow @safe @nogc
    {
        immutable carryLeft = (key[0] & 0x80) >> 3;
        key[0] = cast(ubyte) ((key[0] << 1) | ((key[1] & 0x80) >> 7));
        key[1] = cast(ubyte) ((key[1] << 1) | ((key[2] & 0x80) >> 7));
        key[2] = cast(ubyte) ((key[2] << 1) | ((key[3] & 0x80) >> 7));
        immutable carryRight = (key[3] & 0x08) >> 3;
        key[3] = cast(ubyte) ((((key[3] << 1) | ((key[4] & 0x80) >> 7)) & ~0x10) | carryLeft);
        key[4] = cast(ubyte) ((key[4] << 1) | ((key[5] & 0x80) >> 7));
        key[5] = cast(ubyte) ((key[5] << 1) | ((key[6] & 0x80) >> 7));
        key[6] = cast(ubyte) ((key[6] << 1) | carryRight);
    }
    /**
     * Performs the right rotation operation on the key.
     *
     * Params:
     *     key = The key to rotate.
     */
    private void rotateRight(ref ubyte[7] key) const pure nothrow @safe @nogc
    {
        immutable carryRight = (key[6] & 0x01) << 3;
        key[6] = cast(ubyte) ((key[6] >> 1) | ((key[5] & 0x01) << 7));
        key[5] = cast(ubyte) ((key[5] >> 1) | ((key[4] & 0x01) << 7));
        key[4] = cast(ubyte) ((key[4] >> 1) | ((key[3] & 0x01) << 7));
        immutable carryLeft = (key[3] & 0x10) << 3;
        key[3] = cast(ubyte) ((((key[3] >> 1) | ((key[2] & 0x01) << 7)) & ~0x08) | carryRight);
        key[2] = cast(ubyte) ((key[2] >> 1) | ((key[1] & 0x01) << 7));
        key[1] = cast(ubyte) ((key[1] >> 1) | ((key[0] & 0x01) << 7));
        key[0] = cast(ubyte) ((key[0] >> 1) | carryLeft);
    }
    private void permute(in ubyte[] source, ubyte[] target, immutable(ubyte[]) permuteTable, size_t length)
    const pure nothrow @safe @nogc
    {
        const sourceVector = const BitVector(source);
        auto targetVector = BitVector(target);
        permute(sourceVector, targetVector, permuteTable, length);
    }
    private void permute(in BitVector source, ubyte[] target, immutable(ubyte[]) permuteTable, size_t length)
    const pure nothrow @safe @nogc
    {
        auto targetVector = BitVector(target);
        permute(source, targetVector, permuteTable, length);
    }
    private void permute(in BitVector source, ref BitVector target, immutable(ubyte[]) permuteTable, size_t length)
    const pure nothrow @safe @nogc
    {
        for (uint i; i < length * 8; ++i)
        {
            target[i] = source[permuteTable[i] - 1];
        }
    }
 }
 version (unittest)
 {
    import std.typecons;
    /* Test vectors for DES. Source:
       "Validating the Correctness of Hardware 
       Implementations of the NBS Data Encryption Standard"
       NBS Special Publication 500-20, 1980. Appendix B */
    // Initial and reverse Permutation and Expansion tests. Encrypt.
    ubyte[8][64] desTestVectors1 = [
        [0x95, 0xf8, 0xa5, 0xe5, 0xdd, 0x31, 0xd9, 0x00],
        [0xdd, 0x7f, 0x12, 0x1c, 0xa5, 0x01, 0x56, 0x19],
        [0x2e, 0x86, 0x53, 0x10, 0x4f, 0x38, 0x34, 0xea],
        [0x4b, 0xd3, 0x88, 0xff, 0x6c, 0xd8, 0x1d, 0x4f],
        [0x20, 0xb9, 0xe7, 0x67, 0xb2, 0xfb, 0x14, 0x56],
        [0x55, 0x57, 0x93, 0x80, 0xd7, 0x71, 0x38, 0xef],
        [0x6c, 0xc5, 0xde, 0xfa, 0xaf, 0x04, 0x51, 0x2f],
        [0x0d, 0x9f, 0x27, 0x9b, 0xa5, 0xd8, 0x72, 0x60],
        [0xd9, 0x03, 0x1b, 0x02, 0x71, 0xbd, 0x5a, 0x0a],
        [0x42, 0x42, 0x50, 0xb3, 0x7c, 0x3d, 0xd9, 0x51],
        [0xb8, 0x06, 0x1b, 0x7e, 0xcd, 0x9a, 0x21, 0xe5],
        [0xf1, 0x5d, 0x0f, 0x28, 0x6b, 0x65, 0xbd, 0x28],
        [0xad, 0xd0, 0xcc, 0x8d, 0x6e, 0x5d, 0xeb, 0xa1],
        [0xe6, 0xd5, 0xf8, 0x27, 0x52, 0xad, 0x63, 0xd1],
        [0xec, 0xbf, 0xe3, 0xbd, 0x3f, 0x59, 0x1a, 0x5e],
        [0xf3, 0x56, 0x83, 0x43, 0x79, 0xd1, 0x65, 0xcd],
        [0x2b, 0x9f, 0x98, 0x2f, 0x20, 0x03, 0x7f, 0xa9],
        [0x88, 0x9d, 0xe0, 0x68, 0xa1, 0x6f, 0x0b, 0xe6],
        [0xe1, 0x9e, 0x27, 0x5d, 0x84, 0x6a, 0x12, 0x98],
        [0x32, 0x9a, 0x8e, 0xd5, 0x23, 0xd7, 0x1a, 0xec],
        [0xe7, 0xfc, 0xe2, 0x25, 0x57, 0xd2, 0x3c, 0x97],
        [0x12, 0xa9, 0xf5, 0x81, 0x7f, 0xf2, 0xd6, 0x5d],
        [0xa4, 0x84, 0xc3, 0xad, 0x38, 0xdc, 0x9c, 0x19],
        [0xfb, 0xe0, 0x0a, 0x8a, 0x1e, 0xf8, 0xad, 0x72],
        [0x75, 0x0d, 0x07, 0x94, 0x07, 0x52, 0x13, 0x63],
        [0x64, 0xfe, 0xed, 0x9c, 0x72, 0x4c, 0x2f, 0xaf],
        [0xf0, 0x2b, 0x26, 0x3b, 0x32, 0x8e, 0x2b, 0x60],
        [0x9d, 0x64, 0x55, 0x5a, 0x9a, 0x10, 0xb8, 0x52],
        [0xd1, 0x06, 0xff, 0x0b, 0xed, 0x52, 0x55, 0xd7],
        [0xe1, 0x65, 0x2c, 0x6b, 0x13, 0x8c, 0x64, 0xa5],
        [0xe4, 0x28, 0x58, 0x11, 0x86, 0xec, 0x8f, 0x46],
        [0xae, 0xb5, 0xf5, 0xed, 0xe2, 0x2d, 0x1a, 0x36],
        [0xe9, 0x43, 0xd7, 0x56, 0x8a, 0xec, 0x0c, 0x5c],
        [0xdf, 0x98, 0xc8, 0x27, 0x6f, 0x54, 0xb0, 0x4b],
        [0xb1, 0x60, 0xe4, 0x68, 0x0f, 0x6c, 0x69, 0x6f],
        [0xfa, 0x07, 0x52, 0xb0, 0x7d, 0x9c, 0x4a, 0xb8],
        [0xca, 0x3a, 0x2b, 0x03, 0x6d, 0xbc, 0x85, 0x02],
        [0x5e, 0x09, 0x05, 0x51, 0x7b, 0xb5, 0x9b, 0xcf],
        [0x81, 0x4e, 0xeb, 0x3b, 0x91, 0xd9, 0x07, 0x26],
        [0x4d, 0x49, 0xdb, 0x15, 0x32, 0x91, 0x9c, 0x9f],
        [0x25, 0xeb, 0x5f, 0xc3, 0xf8, 0xcf, 0x06, 0x21],
        [0xab, 0x6a, 0x20, 0xc0, 0x62, 0x0d, 0x1c, 0x6f],
        [0x79, 0xe9, 0x0d, 0xbc, 0x98, 0xf9, 0x2c, 0xca],
        [0x86, 0x6e, 0xce, 0xdd, 0x80, 0x72, 0xbb, 0x0e],
        [0x8b, 0x54, 0x53, 0x6f, 0x2f, 0x3e, 0x64, 0xa8],
        [0xea, 0x51, 0xd3, 0x97, 0x55, 0x95, 0xb8, 0x6b],
        [0xca, 0xff, 0xc6, 0xac, 0x45, 0x42, 0xde, 0x31],
        [0x8d, 0xd4, 0x5a, 0x2d, 0xdf, 0x90, 0x79, 0x6c],
        [0x10, 0x29, 0xd5, 0x5e, 0x88, 0x0e, 0xc2, 0xd0],
        [0x5d, 0x86, 0xcb, 0x23, 0x63, 0x9d, 0xbe, 0xa9],
        [0x1d, 0x1c, 0xa8, 0x53, 0xae, 0x7c, 0x0c, 0x5f],
        [0xce, 0x33, 0x23, 0x29, 0x24, 0x8f, 0x32, 0x28],
        [0x84, 0x05, 0xd1, 0xab, 0xe2, 0x4f, 0xb9, 0x42],
        [0xe6, 0x43, 0xd7, 0x80, 0x90, 0xca, 0x42, 0x07],
        [0x48, 0x22, 0x1b, 0x99, 0x37, 0x74, 0x8a, 0x23],
        [0xdd, 0x7c, 0x0b, 0xbd, 0x61, 0xfa, 0xfd, 0x54],
        [0x2f, 0xbc, 0x29, 0x1a, 0x57, 0x0d, 0xb5, 0xc4],
        [0xe0, 0x7c, 0x30, 0xd7, 0xe4, 0xe2, 0x6e, 0x12],
        [0x09, 0x53, 0xe2, 0x25, 0x8e, 0x8e, 0x90, 0xa1],
        [0x5b, 0x71, 0x1b, 0xc4, 0xce, 0xeb, 0xf2, 0xee],
        [0xcc, 0x08, 0x3f, 0x1e, 0x6d, 0x9e, 0x85, 0xf6],
        [0xd2, 0xfd, 0x88, 0x67, 0xd5, 0x0d, 0x2d, 0xfe],
        [0x06, 0xe7, 0xea, 0x22, 0xce, 0x92, 0x70, 0x8f],
        [0x16, 0x6b, 0x40, 0xb4, 0x4a, 0xba, 0x4b, 0xd6],
    ];
    // Key Permutation test. Encrypt.
    // Test of right-shifts. Decrypt.
    ubyte[8][56] desTestVectors2 = [
        [0x95, 0xa8, 0xd7, 0x28, 0x13, 0xda, 0xa9, 0x4d],
        [0x0e, 0xec, 0x14, 0x87, 0xdd, 0x8c, 0x26, 0xd5],
        [0x7a, 0xd1, 0x6f, 0xfb, 0x79, 0xc4, 0x59, 0x26],
        [0xd3, 0x74, 0x62, 0x94, 0xca, 0x6a, 0x6c, 0xf3],
        [0x80, 0x9f, 0x5f, 0x87, 0x3c, 0x1f, 0xd7, 0x61],
        [0xc0, 0x2f, 0xaf, 0xfe, 0xc9, 0x89, 0xd1, 0xfc],
        [0x46, 0x15, 0xaa, 0x1d, 0x33, 0xe7, 0x2f, 0x10],
        [0x20, 0x55, 0x12, 0x33, 0x50, 0xc0, 0x08, 0x58],
        [0xdf, 0x3b, 0x99, 0xd6, 0x57, 0x73, 0x97, 0xc8],
        [0x31, 0xfe, 0x17, 0x36, 0x9b, 0x52, 0x88, 0xc9],
        [0xdf, 0xdd, 0x3c, 0xc6, 0x4d, 0xae, 0x16, 0x42],
        [0x17, 0x8c, 0x83, 0xce, 0x2b, 0x39, 0x9d, 0x94],
        [0x50, 0xf6, 0x36, 0x32, 0x4a, 0x9b, 0x7f, 0x80],
        [0xa8, 0x46, 0x8e, 0xe3, 0xbc, 0x18, 0xf0, 0x6d],
        [0xa2, 0xdc, 0x9e, 0x92, 0xfd, 0x3c, 0xde, 0x92],
        [0xca, 0xc0, 0x9f, 0x79, 0x7d, 0x03, 0x12, 0x87],
        [0x90, 0xba, 0x68, 0x0b, 0x22, 0xae, 0xb5, 0x25],
        [0xce, 0x7a, 0x24, 0xf3, 0x50, 0xe2, 0x80, 0xb6],
        [0x88, 0x2b, 0xff, 0x0a, 0xa0, 0x1a, 0x0b, 0x87],
        [0x25, 0x61, 0x02, 0x88, 0x92, 0x45, 0x11, 0xc2],
        [0xc7, 0x15, 0x16, 0xc2, 0x9c, 0x75, 0xd1, 0x70],
        [0x51, 0x99, 0xc2, 0x9a, 0x52, 0xc9, 0xf0, 0x59],
        [0xc2, 0x2f, 0x0a, 0x29, 0x4a, 0x71, 0xf2, 0x9f],
        [0xee, 0x37, 0x14, 0x83, 0x71, 0x4c, 0x02, 0xea],
        [0xa8, 0x1f, 0xbd, 0x44, 0x8f, 0x9e, 0x52, 0x2f],
        [0x4f, 0x64, 0x4c, 0x92, 0xe1, 0x92, 0xdf, 0xed],
        [0x1a, 0xfa, 0x9a, 0x66, 0xa6, 0xdf, 0x92, 0xae],
        [0xb3, 0xc1, 0xcc, 0x71, 0x5c, 0xb8, 0x79, 0xd8],
        [0x19, 0xd0, 0x32, 0xe6, 0x4a, 0xb0, 0xbd, 0x8b],
        [0x3c, 0xfa, 0xa7, 0xa7, 0xdc, 0x87, 0x20, 0xdc],
        [0xb7, 0x26, 0x5f, 0x7f, 0x44, 0x7a, 0xc6, 0xf3],
        [0x9d, 0xb7, 0x3b, 0x3c, 0x0d, 0x16, 0x3f, 0x54],
        [0x81, 0x81, 0xb6, 0x5b, 0xab, 0xf4, 0xa9, 0x75],
        [0x93, 0xc9, 0xb6, 0x40, 0x42, 0xea, 0xa2, 0x40],
        [0x55, 0x70, 0x53, 0x08, 0x29, 0x70, 0x55, 0x92],
        [0x86, 0x38, 0x80, 0x9e, 0x87, 0x87, 0x87, 0xa0],
        [0x41, 0xb9, 0xa7, 0x9a, 0xf7, 0x9a, 0xc2, 0x08],
        [0x7a, 0x9b, 0xe4, 0x2f, 0x20, 0x09, 0xa8, 0x92],
        [0x29, 0x03, 0x8d, 0x56, 0xba, 0x6d, 0x27, 0x45],
        [0x54, 0x95, 0xc6, 0xab, 0xf1, 0xe5, 0xdf, 0x51],
        [0xae, 0x13, 0xdb, 0xd5, 0x61, 0x48, 0x89, 0x33],
        [0x02, 0x4d, 0x1f, 0xfa, 0x89, 0x04, 0xe3, 0x89],
        [0xd1, 0x39, 0x97, 0x12, 0xf9, 0x9b, 0xf0, 0x2e],
        [0x14, 0xc1, 0xd7, 0xc1, 0xcf, 0xfe, 0xc7, 0x9e],
        [0x1d, 0xe5, 0x27, 0x9d, 0xae, 0x3b, 0xed, 0x6f],
        [0xe9, 0x41, 0xa3, 0x3f, 0x85, 0x50, 0x13, 0x03],
        [0xda, 0x99, 0xdb, 0xbc, 0x9a, 0x03, 0xf3, 0x79],
        [0xb7, 0xfc, 0x92, 0xf9, 0x1d, 0x8e, 0x92, 0xe9],
        [0xae, 0x8e, 0x5c, 0xaa, 0x3c, 0xa0, 0x4e, 0x85],
        [0x9c, 0xc6, 0x2d, 0xf4, 0x3b, 0x6e, 0xed, 0x74],
        [0xd8, 0x63, 0xdb, 0xb5, 0xc5, 0x9a, 0x91, 0xa0],
        [0xa1, 0xab, 0x21, 0x90, 0x54, 0x5b, 0x91, 0xd7],
        [0x08, 0x75, 0x04, 0x1e, 0x64, 0xc5, 0x70, 0xf7],
        [0x5a, 0x59, 0x45, 0x28, 0xbe, 0xbe, 0xf1, 0xcc],
        [0xfc, 0xdb, 0x32, 0x91, 0xde, 0x21, 0xf0, 0xc0],
        [0x86, 0x9e, 0xfd, 0x7f, 0x9f, 0x26, 0x5a, 0x09],
    ];
    // Data permutation test. Encrypt.
    ubyte[8][2][32] desTestVectors3 = [
        [[0x10, 0x46, 0x91, 0x34, 0x89, 0x98, 0x01, 0x31], [0x88, 0xd5, 0x5e, 0x54, 0xf5, 0x4c, 0x97, 0xb4]],
        [[0x10, 0x07, 0x10, 0x34, 0x89, 0x98, 0x80, 0x20], [0x0c, 0x0c, 0xc0, 0x0c, 0x83, 0xea, 0x48, 0xfd]],
        [[0x10, 0x07, 0x10, 0x34, 0xc8, 0x98, 0x01, 0x20], [0x83, 0xbc, 0x8e, 0xf3, 0xa6, 0x57, 0x01, 0x83]],
        [[0x10, 0x46, 0x10, 0x34, 0x89, 0x98, 0x80, 0x20], [0xdf, 0x72, 0x5d, 0xca, 0xd9, 0x4e, 0xa2, 0xe9]],
        [[0x10, 0x86, 0x91, 0x15, 0x19, 0x19, 0x01, 0x01], [0xe6, 0x52, 0xb5, 0x3b, 0x55, 0x0b, 0xe8, 0xb0]],
        [[0x10, 0x86, 0x91, 0x15, 0x19, 0x58, 0x01, 0x01], [0xaf, 0x52, 0x71, 0x20, 0xc4, 0x85, 0xcb, 0xb0]],
        [[0x51, 0x07, 0xb0, 0x15, 0x19, 0x58, 0x01, 0x01], [0x0f, 0x04, 0xce, 0x39, 0x3d, 0xb9, 0x26, 0xd5]],
        [[0x10, 0x07, 0xb0, 0x15, 0x19, 0x19, 0x01, 0x01], [0xc9, 0xf0, 0x0f, 0xfc, 0x74, 0x07, 0x90, 0x67]],
        [[0x31, 0x07, 0x91, 0x54, 0x98, 0x08, 0x01, 0x01], [0x7c, 0xfd, 0x82, 0xa5, 0x93, 0x25, 0x2b, 0x4e]],
        [[0x31, 0x07, 0x91, 0x94, 0x98, 0x08, 0x01, 0x01], [0xcb, 0x49, 0xa2, 0xf9, 0xe9, 0x13, 0x63, 0xe3]],
        [[0x10, 0x07, 0x91, 0x15, 0xb9, 0x08, 0x01, 0x40], [0x00, 0xb5, 0x88, 0xbe, 0x70, 0xd2, 0x3f, 0x56]],
        [[0x31, 0x07, 0x91, 0x15, 0x98, 0x08, 0x01, 0x40], [0x40, 0x6a, 0x9a, 0x6a, 0xb4, 0x33, 0x99, 0xae]],
        [[0x10, 0x07, 0xd0, 0x15, 0x89, 0x98, 0x01, 0x01], [0x6c, 0xb7, 0x73, 0x61, 0x1d, 0xca, 0x9a, 0xda]],
        [[0x91, 0x07, 0x91, 0x15, 0x89, 0x98, 0x01, 0x01], [0x67, 0xfd, 0x21, 0xc1, 0x7d, 0xbb, 0x5d, 0x70]],
        [[0x91, 0x07, 0xd0, 0x15, 0x89, 0x19, 0x01, 0x01], [0x95, 0x92, 0xcb, 0x41, 0x10, 0x43, 0x07, 0x87]],
        [[0x10, 0x07, 0xd0, 0x15, 0x98, 0x98, 0x01, 0x20], [0xa6, 0xb7, 0xff, 0x68, 0xa3, 0x18, 0xdd, 0xd3]],
        [[0x10, 0x07, 0x94, 0x04, 0x98, 0x19, 0x01, 0x01], [0x4d, 0x10, 0x21, 0x96, 0xc9, 0x14, 0xca, 0x16]],
        [[0x01, 0x07, 0x91, 0x04, 0x91, 0x19, 0x04, 0x01], [0x2d, 0xfa, 0x9f, 0x45, 0x73, 0x59, 0x49, 0x65]],
        [[0x01, 0x07, 0x91, 0x04, 0x91, 0x19, 0x01, 0x01], [0xb4, 0x66, 0x04, 0x81, 0x6c, 0x0e, 0x07, 0x74]],
        [[0x01, 0x07, 0x94, 0x04, 0x91, 0x19, 0x04, 0x01], [0x6e, 0x7e, 0x62, 0x21, 0xa4, 0xf3, 0x4e, 0x87]],
        [[0x19, 0x07, 0x92, 0x10, 0x98, 0x1a, 0x01, 0x01], [0xaa, 0x85, 0xe7, 0x46, 0x43, 0x23, 0x31, 0x99]],
        [[0x10, 0x07, 0x91, 0x19, 0x98, 0x19, 0x08, 0x01], [0x2e, 0x5a, 0x19, 0xdb, 0x4d, 0x19, 0x62, 0xd6]],
        [[0x10, 0x07, 0x91, 0x19, 0x98, 0x1a, 0x08, 0x01], [0x23, 0xa8, 0x66, 0xa8, 0x09, 0xd3, 0x08, 0x94]],
        [[0x10, 0x07, 0x92, 0x10, 0x98, 0x19, 0x01, 0x01], [0xd8, 0x12, 0xd9, 0x61, 0xf0, 0x17, 0xd3, 0x20]],
        [[0x10, 0x07, 0x91, 0x15, 0x98, 0x19, 0x01, 0x0b], [0x05, 0x56, 0x05, 0x81, 0x6e, 0x58, 0x60, 0x8f]],
        [[0x10, 0x04, 0x80, 0x15, 0x98, 0x19, 0x01, 0x01], [0xab, 0xd8, 0x8e, 0x8b, 0x1b, 0x77, 0x16, 0xf1]],
        [[0x10, 0x04, 0x80, 0x15, 0x98, 0x19, 0x01, 0x02], [0x53, 0x7a, 0xc9, 0x5b, 0xe6, 0x9d, 0xa1, 0xe1]],
        [[0x10, 0x04, 0x80, 0x15, 0x98, 0x19, 0x01, 0x08], [0xae, 0xd0, 0xf6, 0xae, 0x3c, 0x25, 0xcd, 0xd8]],
        [[0x10, 0x02, 0x91, 0x14, 0x98, 0x10, 0x01, 0x04], [0xb3, 0xe3, 0x5a, 0x5e, 0xe5, 0x3e, 0x7b, 0x8d]],
        [[0x10, 0x02, 0x91, 0x15, 0x98, 0x19, 0x01, 0x04], [0x61, 0xc7, 0x9c, 0x71, 0x92, 0x1a, 0x2e, 0xf8]],
        [[0x10, 0x02, 0x91, 0x15, 0x98, 0x10, 0x02, 0x01], [0xe2, 0xf5, 0x72, 0x8f, 0x09, 0x95, 0x01, 0x3c]],
        [[0x10, 0x02, 0x91, 0x16, 0x98, 0x10, 0x01, 0x01], [0x1a, 0xea, 0xc3, 0x9a, 0x61, 0xf0, 0xa4, 0x64]],
    ];
    // S-Box test. Encrypt.
    ubyte[8][3][19] desTestVectors4 = [
        [[0x7c, 0xa1, 0x10, 0x45, 0x4a, 0x1a, 0x6e, 0x57], [0x01, 0xa1, 0xd6, 0xd0, 0x39, 0x77, 0x67, 0x42],
        [0x69, 0x0f, 0x5b, 0x0d, 0x9a, 0x26, 0x93, 0x9b]],
        [[0x01, 0x31, 0xd9, 0x61, 0x9d, 0xc1, 0x37, 0x6e], [0x5c, 0xd5, 0x4c, 0xa8, 0x3d, 0xef, 0x57, 0xda],
        [0x7a, 0x38, 0x9d, 0x10, 0x35, 0x4b, 0xd2, 0x71]],
        [[0x07, 0xa1, 0x13, 0x3e, 0x4a, 0x0b, 0x26, 0x86], [0x02, 0x48, 0xd4, 0x38, 0x06, 0xf6, 0x71, 0x72],
        [0x86, 0x8e, 0xbb, 0x51, 0xca, 0xb4, 0x59, 0x9a]],
        [[0x38, 0x49, 0x67, 0x4c, 0x26, 0x02, 0x31, 0x9e], [0x51, 0x45, 0x4b, 0x58, 0x2d, 0xdf, 0x44, 0x0a],
        [0x71, 0x78, 0x87, 0x6e, 0x01, 0xf1, 0x9b, 0x2a]],
        [[0x04, 0xb9, 0x15, 0xba, 0x43, 0xfe, 0xb5, 0xb6], [0x42, 0xfd, 0x44, 0x30, 0x59, 0x57, 0x7f, 0xa2],
        [0xaf, 0x37, 0xfb, 0x42, 0x1f, 0x8c, 0x40, 0x95]],
        [[0x01, 0x13, 0xb9, 0x70, 0xfd, 0x34, 0xf2, 0xce], [0x05, 0x9b, 0x5e, 0x08, 0x51, 0xcf, 0x14, 0x3a],
        [0x86, 0xa5, 0x60, 0xf1, 0x0e, 0xc6, 0xd8, 0x5b]],
        [[0x01, 0x70, 0xf1, 0x75, 0x46, 0x8f, 0xb5, 0xe6], [0x07, 0x56, 0xd8, 0xe0, 0x77, 0x47, 0x61, 0xd2],
        [0x0c, 0xd3, 0xda, 0x02, 0x00, 0x21, 0xdc, 0x09]],
        [[0x43, 0x29, 0x7f, 0xad, 0x38, 0xe3, 0x73, 0xfe], [0x76, 0x25, 0x14, 0xb8, 0x29, 0xbf, 0x48, 0x6a],
        [0xea, 0x67, 0x6b, 0x2c, 0xb7, 0xdb, 0x2b, 0x7a]],
        [[0x07, 0xa7, 0x13, 0x70, 0x45, 0xda, 0x2a, 0x16], [0x3b, 0xdd, 0x11, 0x90, 0x49, 0x37, 0x28, 0x02],
        [0xdf, 0xd6, 0x4a, 0x81, 0x5c, 0xaf, 0x1a, 0x0f]],
        [[0x04, 0x68, 0x91, 0x04, 0xc2, 0xfd, 0x3b, 0x2f], [0x26, 0x95, 0x5f, 0x68, 0x35, 0xaf, 0x60, 0x9a],
        [0x5c, 0x51, 0x3c, 0x9c, 0x48, 0x86, 0xc0, 0x88]],
        [[0x37, 0xd0, 0x6b, 0xb5, 0x16, 0xcb, 0x75, 0x46], [0x16, 0x4d, 0x5e, 0x40, 0x4f, 0x27, 0x52, 0x32],
        [0x0a, 0x2a, 0xee, 0xae, 0x3f, 0xf4, 0xab, 0x77]],
        [[0x1f, 0x08, 0x26, 0x0d, 0x1a, 0xc2, 0x46, 0x5e], [0x6b, 0x05, 0x6e, 0x18, 0x75, 0x9f, 0x5c, 0xca],
        [0xef, 0x1b, 0xf0, 0x3e, 0x5d, 0xfa, 0x57, 0x5a]],
        [[0x58, 0x40, 0x23, 0x64, 0x1a, 0xba, 0x61, 0x76], [0x00, 0x4b, 0xd6, 0xef, 0x09, 0x17, 0x60, 0x62],
        [0x88, 0xbf, 0x0d, 0xb6, 0xd7, 0x0d, 0xee, 0x56]],
        [[0x02, 0x58, 0x16, 0x16, 0x46, 0x29, 0xb0, 0x07], [0x48, 0x0d, 0x39, 0x00, 0x6e, 0xe7, 0x62, 0xf2],
        [0xa1, 0xf9, 0x91, 0x55, 0x41, 0x02, 0x0b, 0x56]],
        [[0x49, 0x79, 0x3e, 0xbc, 0x79, 0xb3, 0x25, 0x8f], [0x43, 0x75, 0x40, 0xc8, 0x69, 0x8f, 0x3c, 0xfa],
        [0x6f, 0xbf, 0x1c, 0xaf, 0xcf, 0xfd, 0x05, 0x56]],
        [[0x4f, 0xb0, 0x5e, 0x15, 0x15, 0xab, 0x73, 0xa7], [0x07, 0x2d, 0x43, 0xa0, 0x77, 0x07, 0x52, 0x92],
        [0x2f, 0x22, 0xe4, 0x9b, 0xab, 0x7c, 0xa1, 0xac]],
        [[0x49, 0xe9, 0x5d, 0x6d, 0x4c, 0xa2, 0x29, 0xbf], [0x02, 0xfe, 0x55, 0x77, 0x81, 0x17, 0xf1, 0x2a],
        [0x5a, 0x6b, 0x61, 0x2c, 0xc2, 0x6c, 0xce, 0x4a]],
        [[0x01, 0x83, 0x10, 0xdc, 0x40, 0x9b, 0x26, 0xd6], [0x1d, 0x9d, 0x5c, 0x50, 0x18, 0xf7, 0x28, 0xc2],
        [0x5f, 0x4c, 0x03, 0x8e, 0xd1, 0x2b, 0x2e, 0x41]],
        [[0x1c, 0x58, 0x7f, 0x1c, 0x13, 0x92, 0x4f, 0xef], [0x30, 0x55, 0x32, 0x28, 0x6d, 0x6f, 0x29, 0x5a],
        [0x63, 0xfa, 0xc0, 0xd0, 0x34, 0xd9, 0xf7, 0x93]],
    ];
 }
 ///
 unittest
 {
    auto des = scoped!(DES!1);
    ubyte[8] key = [0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01];
    ubyte[8] plain = [0x80, 0, 0, 0, 0, 0, 0, 0];
    ubyte[8] cipher;
    des.key = key;
    foreach (ubyte i; 0..64)
    {
        if (i != 0)
        {
            plain[i / 8] = i % 8 ? plain[i / 8] >> 1 : 0x80;
            if (i % 8 == 0)
            {
                plain[i / 8 - 1] = 0;
            }
        }
        // Initial Permutation and Expansion test.
        des.encrypt(plain, cipher);
        assert(cipher == desTestVectors1[i]);
        // Inverse Permutation and Expansion test.
        des.encrypt(cipher, cipher);
        assert(cipher == plain);
    }
    plain[0..$] = 0;
    foreach (ubyte i; 0..56)
    {
        key[i / 7] = i % 7 ? key[i / 7] >> 1 : 0x80;
        if (i % 7 == 0 && i != 0)
        {
            key[i / 7 - 1] = 0x01;
        }
        des.key = key;
        // Initial Permutation and Expansion test.
        des.encrypt(plain, cipher);
        assert(cipher == desTestVectors2[i]);
        // Test of right-shifts in Decryption.
        des.decrypt(desTestVectors2[i], cipher);
        assert(cipher == plain);
    }
    // Data permutation test.
    plain[0..$] = 0;
    foreach (i; desTestVectors3)
    {
        des.key = i[0];
        des.encrypt(plain, cipher);
        assert(cipher == i[1]);
    }
    // S-Box test.
    foreach (i; desTestVectors4)
    {
        des.key = i[0];
        des.encrypt(i[1], cipher);
        assert(cipher == i[2]);
    }
 }
--- a/source/tanya/crypto/mode.d
+++ b/source/tanya/crypto/mode.d
@ -1,279 +0,0 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * Block cipher modes of operation.
 *
 * Copyright: Eugene Wissner 2016.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:belka@caraus.de, Eugene Wissner)
 */
 module tanya.crypto.mode;
 import tanya.memory;
 import std.algorithm.iteration;
 import std.typecons;
 /**
 * Supported padding mode.
 *
 * See_Also:
 * 	$(D_PSYMBOL pad)
 */
 enum PaddingMode
 {
 	zero,
 	pkcs7,
 	ansiX923,
 }
 /**
 * Params:
 * 	input     = Sequence that should be padded.
 * 	mode      = Padding mode.
 * 	blockSize = Block size.
 * 	allocator = Allocator was used to allocate $(D_PARAM input).
 *
 * Returns: The function modifies the initial array and returns it.
 *
 * See_Also:
 * 	$(D_PSYMBOL PaddingMode)
 */
 ubyte[] pad(ref ubyte[] input,
            in PaddingMode mode,
            in ushort blockSize,
            shared Allocator allocator = defaultAllocator)
 in
 {
 	assert(blockSize > 0 && blockSize <= 256);
 	assert(blockSize % 64 == 0);
 	assert(input.length > 0);
 }
 body
 {
 	immutable rest = cast(ubyte) input.length % blockSize;
 	immutable size_t lastBlock = input.length - (rest > 0 ? rest : blockSize);
 	immutable needed = cast(ubyte) (rest > 0 ? blockSize - rest : 0);
 	final switch (mode) with (PaddingMode)
 	{
 		case zero:
 			allocator.resizeArray(input, input.length + needed);
 			break;
 		case pkcs7:
 			if (needed)
 			{
 				allocator.resizeArray(input, input.length + needed);
 				input[input.length - needed ..$].each!((ref e) => e = needed);
 			}
 			else
 			{
 				allocator.resizeArray(input, input.length + blockSize);
 			}
 			break;
 		case ansiX923:
 			allocator.resizeArray(input, input.length + (needed ? needed : blockSize));
 			input[$ - 1] = needed;
 			break;
 	}
 	return input;
 }
 ///
 unittest
 {
 	{ // Zeros
 		auto input = defaultAllocator.makeArray!ubyte(50);
 		pad(input, PaddingMode.zero, 64);
 		assert(input.length == 64);
 		pad(input, PaddingMode.zero, 64);
 		assert(input.length == 64);
 		assert(input[63] == 0);
 		defaultAllocator.dispose(input);
 	}
 	{ // PKCS#7
 		auto input = defaultAllocator.makeArray!ubyte(50);
 		for (ubyte i; i < 40; ++i)
 		{
 			input[i] = i;
 		}
 		pad(input, PaddingMode.pkcs7, 64);
 		assert(input.length == 64);
 		for (ubyte i; i < 64; ++i)
 		{
 			if (i >= 40 && i < 50)
 			{
 				assert(input[i] == 0);
 			}
 			else if (i >= 50)
 			{
 				assert(input[i] == 14);
 			}
 			else
 			{
 				assert(input[i] == i);
 			}
 		}
 		pad(input, PaddingMode.pkcs7, 64);
 		assert(input.length == 128);
 		for (ubyte i; i < 128; ++i)
 		{
 			if (i >= 64 || (i >= 40 && i < 50))
 			{
 				assert(input[i] == 0);
 			}
 			else if (i >= 50 && i < 64)
 			{
 				assert(input[i] == 14);
 			}
 			else
 			{
 				assert(input[i] == i);
 			}
 		}
 		defaultAllocator.dispose(input);
 	}
 	{ // ANSI X.923
 		auto input = defaultAllocator.makeArray!ubyte(50);
 		for (ubyte i; i < 40; ++i)
 		{
 			input[i] = i;
 		}
 		pad(input, PaddingMode.ansiX923, 64);
 		assert(input.length == 64);
 		for (ubyte i; i < 64; ++i)
 		{
 			if (i < 40)
 			{
 				assert(input[i] == i);
 			}
 			else if (i == 63)
 			{
 				assert(input[i] == 14);
 			}
 			else
 			{
 				assert(input[i] == 0);
 			}
 		}
 		pad(input, PaddingMode.pkcs7, 64);
 		assert(input.length == 128);
 		for (ubyte i = 0; i < 128; ++i)
 		{
 			if (i < 40)
 			{
 				assert(input[i] == i);
 			}
 			else if (i == 63)
 			{
 				assert(input[i] == 14);
 			}
 			else
 			{
 				assert(input[i] == 0);
 			}
 		}
 		defaultAllocator.dispose(input);
 	}
 }
 /**
 * Params:
 * 	input     = Sequence that should be padded.
 * 	mode      = Padding mode.
 * 	blockSize = Block size.
 * 	allocator = Allocator was used to allocate $(D_PARAM input).
 *
 * Returns: The function modifies the initial array and returns it.
 *
 * See_Also:
 * 	$(D_PSYMBOL pad)
 */
 ref ubyte[] unpad(ref ubyte[] input,
                  in PaddingMode mode,
                  in ushort blockSize,
                  shared Allocator allocator = defaultAllocator)
 in
 {
 	assert(input.length != 0);
 	assert(input.length % 64 == 0);
 }
 body
 {
 	final switch (mode) with (PaddingMode)
 	{
 		case zero:
 			break;
 		case pkcs7:
 		case ansiX923:
 			immutable last = input[$ - 1];
 			allocator.resizeArray(input, input.length - (last ? last : blockSize));
 			break;
 	}
 	return input;
 }
 ///
 unittest
 {
 	{ // Zeros
 		auto input = defaultAllocator.makeArray!ubyte(50);
 		auto inputDup = defaultAllocator.makeArray!ubyte(50);
 		pad(input, PaddingMode.zero, 64);
 		pad(inputDup, PaddingMode.zero, 64);
 		unpad(input, PaddingMode.zero, 64);
 		assert(input == inputDup);
 		defaultAllocator.dispose(input);
 		defaultAllocator.dispose(inputDup);
 	}
 	{ // PKCS#7
 		auto input = defaultAllocator.makeArray!ubyte(50);
 		auto inputDup = defaultAllocator.makeArray!ubyte(50);
 		for (ubyte i; i < 40; ++i)
 		{
 			input[i] = i;
 			inputDup[i] = i;
 		}
 		pad(input, PaddingMode.pkcs7, 64);
 		unpad(input, PaddingMode.pkcs7, 64);
 		assert(input == inputDup);
 		defaultAllocator.dispose(input);
 		defaultAllocator.dispose(inputDup);
 	}
 	{ // ANSI X.923
 		auto input = defaultAllocator.makeArray!ubyte(50);
 		auto inputDup = defaultAllocator.makeArray!ubyte(50);
 		for (ubyte i; i < 40; ++i)
 		{
 			input[i] = i;
 			inputDup[i] = i;
 		}
 		pad(input, PaddingMode.pkcs7, 64);
 		unpad(input, PaddingMode.pkcs7, 64);
 		assert(input == inputDup);
 		defaultAllocator.dispose(input);
 		defaultAllocator.dispose(inputDup);
 	}
 }
--- a/source/tanya/crypto/symmetric.d
+++ b/source/tanya/crypto/symmetric.d
@ -1,177 +0,0 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * Interfaces for implementing secret key algorithms.
 *
 * Copyright: Eugene Wissner 2016.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:belka@caraus.de, Eugene Wissner)
 */
 module tanya.crypto.symmetric;
 /**
 * Implemented by secret key algorithms.
 */
 interface SymmetricCipher
 {
    /**
     * Returns: Key length.
     */
    @property inout(uint) keyLength() inout const pure nothrow @safe @nogc;
    /**
     * Returns: Minimum key length.
     */
    @property inout(uint) minKeyLength() inout const pure nothrow @safe @nogc;
    /**
     * Returns: Maximum key length.
     */
    @property inout(uint) maxKeyLength() inout const pure nothrow @safe @nogc;
    /// Cipher direction.
    protected enum Direction : ushort
    {
        encryption,
        decryption,
    }
    /**
     * Params:
     *     key = Key.
     */
    @property void key(ubyte[] key) pure nothrow @safe @nogc
    in
    {
        assert(key.length >= minKeyLength);
        assert(key.length <= maxKeyLength);
    }
 }
 /**
 * Implemented by block ciphers.
 */
 interface BlockCipher : SymmetricCipher
 {
    /**
     * Returns: Block size.
     */
    @property inout(uint) blockSize() inout const pure nothrow @safe @nogc;
    /**
     * Encrypts a block.
     *
     * Params:
     *    plain  = Plain text, input.
     *    cipher = Cipher text, output.
     */
    void encrypt(in ubyte[] plain, ubyte[] cipher)
    in
    {
        assert(plain.length == blockSize);
        assert(cipher.length == blockSize);
    }
    /**
     * Decrypts a block.
     *
     * Params:
     *    cipher = Cipher text, input.
     *    plain  = Plain text, output.
     */
    void decrypt(in ubyte[] cipher, ubyte[] plain)
    in
    {
        assert(plain.length == blockSize);
        assert(cipher.length == blockSize);
    }
 }
 /**
 * Mixed in by algorithms with fixed block size.
 *
 * Params:
 *     N = Block size.
 */
 mixin template FixedBlockSize(uint N)
    if (N != 0)
 {
    private enum uint blockSize_ = N;
    /**
     * Returns: Fixed block size.
     */
    final @property inout(uint) blockSize() inout const pure nothrow @safe @nogc
    {
        return blockSize_;
    }
 }
 /**
 * Mixed in by symmetric algorithms.
 * If $(D_PARAM Min) equals $(D_PARAM Max) fixed key length is assumed.
 *
 * Params:
 *     Min = Minimum key length.
 *     Max = Maximum key length.
 */
 mixin template KeyLength(uint Min, uint Max = Min)
    if (Min != 0 && Max != 0)
 {
    static if (Min == Max)
    {
        private enum uint keyLength_ = Min;
        /**
         * Returns: Key length.
         */
        final @property inout(uint) keyLength() inout const pure nothrow @safe @nogc
        {
            return keyLength_;
        }
        /**
         * Returns: Minimum key length.
         */
        final @property inout(uint) minKeyLength() inout const pure nothrow @safe @nogc
        {
            return keyLength_;
        }
        /**
         * Returns: Maximum key length.
         */
        final @property inout(uint) maxKeyLength() inout const pure nothrow @safe @nogc
        {
            return keyLength_;
        }
    }
    else static if (Min < Max)
    {
        private enum uint minKeyLength_ = Min;
        private enum uint maxKeyLength_ = Max;
        /**
         * Returns: Minimum key length.
         */
        final @property inout(uint) minKeyLength() inout const pure nothrow @safe @nogc
        {
            return minKeyLength_;
        }
        /**
         * Returns: Maximum key length.
         */
        final @property inout(uint) maxKeyLength() inout const pure nothrow @safe @nogc
        {
            return maxKeyLength_;
        }
    }
    else
    {
        static assert(false, "Max should be larger or equal to Min");
    }
 }
--- a/source/tanya/encoding/ascii.d
+++ b/source/tanya/encoding/ascii.d
@ -0,0 +1,501 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * Functions operating on ASCII characters.
 *
 * ASCII is $(B A)merican $(B S)tandard $(B C)ode for $(B I)nformation
 * $(B I)nterchange.
 *
 * Copyright: Eugene Wissner 2017-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/encoding/ascii.d,
 *                 tanya/encoding/ascii.d)
 */
 module tanya.encoding.ascii;
 import tanya.meta.trait;
 immutable string fullHexDigits = "0123456789ABCDEFabcdef"; /// 0..9A..Fa..f.
 immutable string hexDigits = "0123456789ABCDEF"; /// 0..9A..F.
 immutable string lowerHexDigits = "0123456789abcdef"; /// 0..9a..f.
 immutable string digits = "0123456789"; /// 0..9.
 immutable string octalDigits = "01234567"; /// 0..7.
 /// A..Za..z.
 immutable string letters = "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz";
 immutable string uppercase = "ABCDEFGHIJKLMNOPQRSTUVWXYZ"; /// A..Z.
 immutable string lowercase = "abcdefghijklmnopqrstuvwxyz"; /// a..z.
 /**
 * Whitespace, Horizontal Tab (HT), Line Feed (LF), Carriage Return (CR),
 * Vertical Tab (VT) or Form Feed (FF).
 */
 immutable string whitespace = "\t\n\v\f\r ";
 /// Letter case specifier.
 enum LetterCase : bool
 {
    upper, /// Uppercase.
    lower, /// Lowercase.
 }
 /**
 * Checks for an uppecase alphabetic character.
 *
 * Params:
 *  C = Some character type.
 *  c = Some character.
 *
 * Returns: $(D_KEYWORD true) if $(D_PARAM c) is an uppercase alphabetic
 *          character, $(D_KEYWORD false) otherwise.
 */
 bool isUpper(C)(C c)
 if (isSomeChar!C)
 {
    return (c >= 'A') && (c <= 'Z');
 }
 ///
@nogc nothrow pure @safe unittest
 {
    assert(isUpper('A'));
    assert(isUpper('Z'));
    assert(isUpper('L'));
    assert(!isUpper('a'));
    assert(!isUpper('!'));
 }
 /**
 * Checks for a lowercase alphabetic character.
 *
 * Params:
 *  C = Some character type.
 *  c = Some character.
 *
 * Returns: $(D_KEYWORD true) if $(D_PARAM c) is a lowercase alphabetic
 *          character, $(D_KEYWORD false) otherwise.
 */
 bool isLower(C)(C c)
 if (isSomeChar!C)
 {
    return (c >= 'a') && (c <= 'z');
 }
 ///
@nogc nothrow pure @safe unittest
 {
    assert(isLower('a'));
    assert(isLower('z'));
    assert(isLower('l'));
    assert(!isLower('A'));
    assert(!isLower('!'));
 }
 /**
 * Checks for an alphabetic character (upper- or lowercase).
 *
 * Params:
 *  C = Some character type.
 *  c = Some character.
 *
 * Returns: $(D_KEYWORD true) if $(D_PARAM c) is an alphabetic character,
 *          $(D_KEYWORD false) otherwise.
 */
 bool isAlpha(C)(C c)
 if (isSomeChar!C)
 {
    return isUpper(c) || isLower(c);
 }
 ///
@nogc nothrow pure @safe unittest
 {
    assert(isAlpha('A'));
    assert(isAlpha('Z'));
    assert(isAlpha('L'));
    assert(isAlpha('a'));
    assert(isAlpha('z'));
    assert(isAlpha('l'));
    assert(!isAlpha('!'));
 }
 /**
 * Checks for a digit.
 *
 * Params:
 *  C = Some character type.
 *  c = Some character.
 *
 * Returns: $(D_KEYWORD true) if $(D_PARAM c) is a digit,
 *          $(D_KEYWORD false) otherwise.
 */
 bool isDigit(C)(C c)
 if (isSomeChar!C)
 {
    return (c >= '0') && (c <= '9');
 }
 ///
@nogc nothrow pure @safe unittest
 {
    assert(isDigit('0'));
    assert(isDigit('1'));
    assert(isDigit('2'));
    assert(isDigit('3'));
    assert(isDigit('4'));
    assert(isDigit('5'));
    assert(isDigit('6'));
    assert(isDigit('7'));
    assert(isDigit('8'));
    assert(isDigit('9'));
    assert(!isDigit('a'));
    assert(!isDigit('!'));
 }
 /**
 * Checks for an alphabetic character (upper- or lowercase) or a digit.
 *
 * Params:
 *  C = Some character type.
 *  c = Some character.
 *
 * Returns: $(D_KEYWORD true) if $(D_PARAM c) is an alphabetic character or a
 *          digit, $(D_KEYWORD false) otherwise.
 */
 bool isAlphaNum(C)(C c)
 if (isSomeChar!C)
 {
    return isAlpha(c) || isDigit(c);
 }
 ///
@nogc nothrow pure @safe unittest
 {
    assert(isAlphaNum('0'));
    assert(isAlphaNum('1'));
    assert(isAlphaNum('9'));
    assert(isAlphaNum('A'));
    assert(isAlphaNum('Z'));
    assert(isAlphaNum('L'));
    assert(isAlphaNum('a'));
    assert(isAlphaNum('z'));
    assert(isAlphaNum('l'));
    assert(!isAlphaNum('!'));
 }
 /**
 * Checks for a 7-bit ASCII character.
 *
 * Params:
 *  C = Some character type.
 *  c = Some character.
 *
 * Returns: $(D_KEYWORD true) if $(D_PARAM c) is an ASCII character,
 *          $(D_KEYWORD false) otherwise.
 */
 bool isASCII(C)(C c)
 if (isSomeChar!C)
 {
    return c < 128;
 }
 ///
@nogc nothrow pure @safe unittest
 {
    assert(isASCII('0'));
    assert(isASCII('L'));
    assert(isASCII('l'));
    assert(isASCII('!'));
    assert(!isASCII('©'));
    assert(!isASCII('§'));
    assert(!isASCII(char.init)); // 0xFF
    assert(!isASCII(wchar.init)); // 0xFFFF
    assert(!isASCII(dchar.init)); // 0xFFFF
 }
 /**
 * Checks for a control character.
 *
 * Control characters are non-printable characters. Their ASCII codes are those
 * between 0x00 (NUL) and 0x1f (US), and 0x7f (DEL).
 *
 * Params:
 *  C = Some character type.
 *  c = Some character.
 *
 * Returns: $(D_KEYWORD true) if $(D_PARAM c) is a control character,
 *          $(D_KEYWORD false) otherwise.
 *
 * See_Also: $(D_PSYMBOL isPrintable),  $(D_PSYMBOL isGraphical).
 */
 bool isControl(C)(C c)
 if (isSomeChar!C)
 {
    return (c <= 0x1f) || (c == 0x7f);
 }
 ///
@nogc nothrow pure @safe unittest
 {
    assert(isControl('\t'));
    assert(isControl('\0'));
    assert(isControl('\u007f'));
    assert(!isControl(' '));
    assert(!isControl('a'));
    assert(!isControl(char.init)); // 0xFF
    assert(!isControl(wchar.init)); // 0xFFFF
 }
 /**
 * Checks for a whitespace character.
 *
 * Whitespace characters are:
 *
 * $(UL
 *  $(LI Whitespace)
 *  $(LI Horizontal Tab (HT))
 *  $(LI Line Feed (LF))
 *  $(LI Carriage Return (CR))
 *  $(LI Vertical Tab (VT))
 *  $(LI Form Feed (FF))
 * )
 *
 * Params:
 *  C = Some character type.
 *  c = Some character.
 *
 * Returns: $(D_KEYWORD true) if $(D_PARAM c) is a whitespace character,
 *          $(D_KEYWORD false) otherwise.
 *
 * See_Also: $(D_PSYMBOL whitespace).
 */
 bool isWhite(C)(C c)
 if (isSomeChar!C)
 {
    return ((c >= 0x09) && (c <= 0x0d)) || (c == 0x20);
 }
 ///
@nogc nothrow pure @safe unittest
 {
    assert(isWhite('\t'));
    assert(isWhite('\n'));
    assert(isWhite('\v'));
    assert(isWhite('\f'));
    assert(isWhite('\r'));
    assert(isWhite(' '));
 }
 /**
 * Checks for a graphical character.
 *
 * Graphical characters are printable characters but whitespace characters.
 *
 * Params:
 *  C = Some character type.
 *  c = Some character.
 *
 * Returns: $(D_KEYWORD true) if $(D_PARAM c) is a control character,
 *          $(D_KEYWORD false) otherwise.
 *
 * See_Also: $(D_PSYMBOL isControl), $(D_PSYMBOL isWhite).
 */
 bool isGraphical(C)(C c)
 if (isSomeChar!C)
 {
    return (c > 0x20) && (c < 0x7f);
 }
 ///
@nogc nothrow pure @safe unittest
 {
    assert(isGraphical('a'));
    assert(isGraphical('0'));
    assert(!isGraphical('\u007f'));
    assert(!isGraphical('§'));
    assert(!isGraphical('\n'));
    assert(!isGraphical(' '));
 }
 /**
 * Checks for a printable character.
 *
 * This is the opposite of a control character.
 *
 * Params:
 *  C = Some character type.
 *  c = Some character.
 *
 * Returns: $(D_KEYWORD true) if $(D_PARAM c) is a control character,
 *          $(D_KEYWORD false) otherwise.
 *
 * See_Also: $(D_PSYMBOL isControl).
 */
 bool isPrintable(C)(C c)
 if (isSomeChar!C)
 {
    return (c >= 0x20) && (c < 0x7f);
 }
 ///
@nogc nothrow pure @safe unittest
 {
    assert(isPrintable('a'));
    assert(isPrintable('0'));
    assert(!isPrintable('\u007f'));
    assert(!isPrintable('§'));
    assert(!isPrintable('\n'));
    assert(isPrintable(' '));
 }
 /**
 * Checks for a hexadecimal digit.
 *
 * Params:
 *  C = Some character type.
 *  c = Some character.
 *
 * Returns: $(D_KEYWORD true) if $(D_PARAM c) is a hexadecimal digit,
 *          $(D_KEYWORD false) otherwise.
 */
 bool isHexDigit(C)(C c)
 if (isSomeChar!C)
 {
    return ((c >= '0') && (c <= '9'))
        || ((c >= 'a') && (c <= 'f'))
        || ((c >= 'A') && (c <= 'F'));
 }
 ///
@nogc nothrow pure @safe unittest
 {
    assert(isHexDigit('0'));
    assert(isHexDigit('1'));
    assert(isHexDigit('8'));
    assert(isHexDigit('9'));
    assert(isHexDigit('A'));
    assert(isHexDigit('F'));
    assert(!isHexDigit('G'));
    assert(isHexDigit('a'));
    assert(isHexDigit('f'));
    assert(!isHexDigit('g'));
 }
 /**
 * Checks for an octal character.
 *
 * Params:
 *  C = Some character type.
 *  c = Some character.
 *
 * Returns: $(D_KEYWORD true) if $(D_PARAM c) is an octal character,
 *          $(D_KEYWORD false) otherwise.
 */
 bool isOctalDigit(C)(C c)
 if (isSomeChar!C)
 {
    return (c >= '0') && (c <= '7');
 }
 ///
@nogc nothrow pure @safe unittest
 {
    assert(isOctalDigit('0'));
    assert(isOctalDigit('1'));
    assert(isOctalDigit('2'));
    assert(isOctalDigit('3'));
    assert(isOctalDigit('4'));
    assert(isOctalDigit('5'));
    assert(isOctalDigit('6'));
    assert(isOctalDigit('7'));
    assert(!isOctalDigit('8'));
 }
 /**
 * Checks for a octal character.
 *
 * Params:
 *  C = Some character type.
 *  c = Some character.
 *
 * Returns: $(D_KEYWORD true) if $(D_PARAM c) is a octal character,
 *          $(D_KEYWORD false) otherwise.
 */
 bool isPunctuation(C)(C c)
 if (isSomeChar!C)
 {
    return ((c >= 0x21) && (c <= 0x2f))
        || ((c >= 0x3a) && (c <= 0x40))
        || ((c >= 0x5b) && (c <= 0x60))
        || ((c >= 0x7b) && (c <= 0x7e));
 }
 ///
@nogc nothrow pure @safe unittest
 {
    assert(isPunctuation('!'));
    assert(isPunctuation(':'));
    assert(isPunctuation('\\'));
    assert(isPunctuation('|'));
    assert(!isPunctuation('0'));
    assert(!isPunctuation(' '));
 }
 /**
 * Converts $(D_PARAM c) to uppercase.
 *
 * If $(D_PARAM c) is not a lowercase character, $(D_PARAM c) is returned
 * unchanged.
 *
 * Params:
 *  C = Some character type.
 *  c = Some character.
 *
 * Returns: The lowercase of $(D_PARAM c) if available, just $(D_PARAM c)
 *          otherwise.
 */
 C toUpper(C)(C c)
 if (isSomeChar!C)
 {
    return isLower(c) ? (cast(C) (c - 32)) : c;
 }
 ///
@nogc nothrow pure @safe unittest
 {
    assert(toUpper('a') == 'A');
    assert(toUpper('A') == 'A');
    assert(toUpper('!') == '!');
 }
 /**
 * Converts $(D_PARAM c) to lowercase.
 *
 * If $(D_PARAM c) is not an uppercase character, $(D_PARAM c) is returned
 * unchanged.
 *
 * Params:
 *  C = Some character type.
 *  c = Some character.
 *
 * Returns: The uppercase of $(D_PARAM c) if available, just $(D_PARAM c)
 *          otherwise.
 */
 C toLower(C)(C c)
 if (isSomeChar!C)
 {
    return isUpper(c) ? (cast(C) (c + 32)) : c;
 }
 ///
@nogc nothrow pure @safe unittest
 {
    assert(toLower('A') == 'a');
    assert(toLower('a') == 'a');
    assert(toLower('!') == '!');
 }
--- a/source/tanya/encoding/package.d
+++ b/source/tanya/encoding/package.d
@ -0,0 +1,17 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * This package provides tools to work with text encodings.
 *
 * Copyright: Eugene Wissner 2017-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/encoding/package.d,
 *                 tanya/encoding/package.d)
 */
 module tanya.encoding;
 public import tanya.encoding.ascii;
--- a/source/tanya/enums.d
+++ b/source/tanya/enums.d
@ -1,49 +0,0 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * Generic enum templates.
 *
 * Copyright: Eugene Wissner 2016.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:belka@caraus.de, Eugene Wissner)
 */
 module tanya.enums;
 import std.traits;
 /**
 * Initializer list.
 *
 * Generates a static array with elements from $(D_PARAM args). All elements
 * should have the same type. It can be used in constructors which accept a
 * list of the elements of the same type in the situations where variadic
 * functions and templates can't be used.
 *
 * Params:
 * 	Args = Argument type.
 * 	args = Arguments.
 */
 enum IL(Args...)(Args args)
 	if (Args.length > 0)
 {
 	alias BaseType = typeof(args[0]);
 	BaseType[args.length] result;
 	foreach (i, a; args)
 	{
 		static assert(isImplicitlyConvertible!(typeof(a), BaseType));
 		result[i] = a;
 	}
 	return result;
 }
 ///
 unittest
 {
 	static assert(IL(1, 5, 8).length == 3);
 	static assert(IL(1, 5, 8).sizeof == 3 * int.sizeof);
 }
--- a/source/tanya/exception.d
+++ b/source/tanya/exception.d
@ -0,0 +1,66 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * Common exceptions and errors.
 *
 * Copyright: Eugene Wissner 2017-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/exception.d,
 *                 tanya/exception.d)
 */
 module tanya.exception;
 import tanya.conv;
 import tanya.memory;
 /**
 * Error thrown if memory allocation fails.
 */
 final class OutOfMemoryError : Error
 {
    /**
     * Constructs new error.
     *
     * Params:
     *  msg  = The message for the exception.
     *  file = The file where the exception occurred.
     *  line = The line number where the exception occurred.
     *  next = The previous exception in the chain of exceptions, if any.
     */
    this(string msg = "Out of memory",
         string file = __FILE__,
         size_t line = __LINE__,
         Throwable next = null) @nogc nothrow pure @safe
    {
        super(msg, file, line, next);
    }
    /// ditto
    this(string msg,
         Throwable next,
         string file = __FILE__,
         size_t line = __LINE__) @nogc nothrow pure @safe
    {
        super(msg, file, line, next);
    }
 }
 /**
 * Allocates $(D_PSYMBOL OutOfMemoryError) in a static storage and throws it.
 *
 * Params:
 *  msg = Custom error message.
 *
 * Throws: $(D_PSYMBOL OutOfMemoryError).
 */
 void onOutOfMemoryError(string msg = "Out of memory")
@nogc nothrow pure @trusted
 {
    static ubyte[stateSize!OutOfMemoryError] memory;
    alias PureType = OutOfMemoryError function(string) @nogc nothrow pure;
    throw (cast(PureType) () => emplace!OutOfMemoryError(memory))(msg);
 }
--- a/source/tanya/format.d
+++ b/source/tanya/format.d
--- a/source/tanya/functional.d
+++ b/source/tanya/functional.d
@ -0,0 +1,71 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * Functions that manipulate other functions and their argument lists.
 *
 * Copyright: Eugene Wissner 2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/functional.d,
 *                 tanya/functional.d)
 */
 module tanya.functional;
 import tanya.algorithm.mutation;
 import tanya.meta.metafunction;
 private template forwardOne(alias arg)
 {
    static if (__traits(isRef, arg) || __traits(isOut, arg))
    {
        alias forwardOne = arg;
    }
    else
    {
        @property auto forwardOne()
        {
            return move(arg);
        }
    }
 }
 /**
 * Forwards its argument list preserving $(D_KEYWORD ref) and $(D_KEYWORD out)
 * storage classes.
 *
 * $(D_PSYMBOL forward) accepts a list of variables or literals. It returns an
 * argument list of the same length that can be for example passed to a
 * function accepting the arguments of this type.
 *
 * Params:
 *  args = Argument list.
 *
 * Returns: $(D_PARAM args) with their original storage classes.
 */
 template forward(args...)
 {
    static if (args.length == 1)
    {
        alias forward = forwardOne!(args[0]);
    }
    else
    {
        alias forward = Map!(forwardOne, args);
    }
 }
 ///
@nogc nothrow pure @safe unittest
 {
    static assert(is(typeof((int i) { int v = forward!i; })));
    static assert(is(typeof((ref int i) { int v = forward!i; })));
    static assert(is(typeof({
        void f(int i, ref int j, out int k)
        {
            f(forward!(i, j, k));
        }
    })));
 }
--- a/source/tanya/hash/lookup.d
+++ b/source/tanya/hash/lookup.d
@ -0,0 +1,623 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * Non-cryptographic, lookup hash functions.
 *
 * Copyright: Eugene Wissner 2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/hash/lookup.d,
 *                 tanya/hash/lookup.d)
 */
 module tanya.hash.lookup;
 import tanya.meta.trait;
 import tanya.range.primitive;
 private struct FNV
 {
    static if (size_t.sizeof == 4)
    {
        enum uint offsetBasis = 2166136261;
        enum uint prime = 16777619;
    }
    else static if (size_t.sizeof == 8)
    {
        enum ulong offsetBasis = 14695981039346656037UL;
        enum ulong prime = 1099511628211UL;
    }
    else
    {
        static assert(false, "FNV requires at least 32-bit hash length");
    }
    size_t hash = offsetBasis;
    void opCall(T)(auto ref T key)
    {
        static if (is(typeof(key.toHash()) == size_t))
        {
            opCall(key.toHash()); // Combine user-defined hashes
        }
        else static if (isScalarType!T || isPointer!T)
        {
            (() @trusted => add((cast(const ubyte*) &key)[0 .. T.sizeof]))();
        }
        else static if (isArray!T && isScalarType!(ElementType!T))
        {
            add(cast(const ubyte[]) key);
        }
        else static if (is(T == typeof(null)))
        {
            add(key);
        }
        else static if (isInputRange!T && !isInfinite!T)
        {
            foreach (e; key)
            {
                opCall(e);
            }
        }
        else
        {
            static assert(false, "Hash function is not available");
        }
    }
    void add(const ubyte[] key) @nogc nothrow pure @safe
    {
        foreach (c; key)
        {
            this.hash = (this.hash ^ c) * prime;
        }
    }
 }
 /**
 * Takes an argument of an arbitrary type $(D_PARAM T) and calculates the hash
 * value.
 *
 * Hash calculation is supported for all scalar types. Aggregate types, like
 * $(D_KEYWORD struct)s, should implement `toHash`-function:
 * ---
 * size_t toHash() const
 * {
 *  return hash;
 * }
 * ---
 *
 * For scalar types FNV-1a (Fowler-Noll-Vo) hash function is used internally.
 * If the type provides a `toHash`-function, only `toHash()` is called and its
 * result is returned.
 *
 * This function also accepts input ranges that contain hashable elements.
 * Individual values are combined then and the resulting hash is returned.
 *
 * Params:
 *  T   = Hashable type.
 *  key = Hashable value.
 *
 * Returns: Calculated hash value.
 *
 * See_Also: $(LINK http://www.isthe.com/chongo/tech/comp/fnv/).
 */
 size_t hash(T)(auto ref T key)
 {
    static if (is(typeof(key.toHash()) == size_t))
    {
        return key.toHash();
    }
    else
    {
        FNV fnv;
        fnv(key);
        return fnv.hash;
    }
 }
 version (unittest)
 {
    enum string r10(string x) = x ~ x ~ x ~ x ~ x ~ x ~ x ~ x ~ x ~ x;
    enum string r100(string x) = r10!x ~ r10!x ~ r10!x ~ r10!x ~ r10!x
                               ~ r10!x ~ r10!x ~ r10!x ~ r10!x ~ r10!x;
    enum string r500(string x) = r100!x ~ r100!x ~ r100!x ~ r100!x ~ r100!x;
    private static struct ToHash
    {
        size_t toHash() const @nogc nothrow pure @safe
        {
            return 0;
        }
    }
    private static struct HashRange
    {
        string fo = "fo";
        @property ubyte front() const @nogc nothrow pure @safe
        {
            return this.fo[0];
        }
        void popFront() @nogc nothrow pure @safe
        {
            this.fo = this.fo[1 .. $];
        }
        @property bool empty() const @nogc nothrow pure @safe
        {
            return this.fo.length == 0;
        }
    }
    private static struct ToHashRange
    {
        bool empty_;
        @property ToHash front() const @nogc nothrow pure @safe
        {
            return ToHash();
        }
        void popFront() @nogc nothrow pure @safe
        {
            this.empty_ = true;
        }
         @property bool empty() const @nogc nothrow pure @safe
         {
             return this.empty_;
         }
    }
 }
 // Tests that work for any hash size
@nogc nothrow pure @safe unittest
 {
    assert(hash(null) == FNV.offsetBasis);
    assert(hash(ToHash()) == 0U);
 }
 static if (size_t.sizeof == 4) @nogc nothrow pure @safe unittest
 {
    assert(hash('a') == 0xe40c292cU);
    assert(hash(HashRange()) == 0x6222e842U);
    assert(hash(ToHashRange()) == 1268118805U);
 }
 static if (size_t.sizeof == 8) @nogc nothrow pure @safe unittest
 {
    assert(hash('a') == 0xaf63dc4c8601ec8cUL);
    assert(hash(HashRange()) == 0x08985907b541d342UL);
    assert(hash(ToHashRange()) == 12161962213042174405UL);
 }
 static if (size_t.sizeof == 4) @nogc nothrow pure @system unittest
 {
    assert(hash(cast(void*) 0x6e6f6863) == 0xac297727U);
 }
 static if (size_t.sizeof == 8) @nogc nothrow pure @system unittest
 {
    assert(hash(cast(void*) 0x77206f676e6f6863) == 0xd1edd10b507344d0UL);
 }
 /*
 * These are official FNV-1a test vectors and they are in the public domain.
 */
 // FNV-1a 32 bit test vectors
 static if (size_t.sizeof == 4) @nogc nothrow pure @safe unittest
 {
    assert(hash("") == 0x811c9dc5U);
    assert(hash("a") == 0xe40c292cU);
    assert(hash("b") == 0xe70c2de5U);
    assert(hash("c") == 0xe60c2c52U);
    assert(hash("d") == 0xe10c2473U);
    assert(hash("e") == 0xe00c22e0U);
    assert(hash("f") == 0xe30c2799U);
    assert(hash("fo") == 0x6222e842U);
    assert(hash("foo") == 0xa9f37ed7U);
    assert(hash("foob") == 0x3f5076efU);
    assert(hash("fooba") == 0x39aaa18aU);
    assert(hash("foobar") == 0xbf9cf968U);
    assert(hash("\0") == 0x050c5d1fU);
    assert(hash("a\0") == 0x2b24d044U);
    assert(hash("b\0") == 0x9d2c3f7fU);
    assert(hash("c\0") == 0x7729c516U);
    assert(hash("d\0") == 0xb91d6109U);
    assert(hash("e\0") == 0x931ae6a0U);
    assert(hash("f\0") == 0x052255dbU);
    assert(hash("fo\0") == 0xbef39fe6U);
    assert(hash("foo\0") == 0x6150ac75U);
    assert(hash("foob\0") == 0x9aab3a3dU);
    assert(hash("fooba\0") == 0x519c4c3eU);
    assert(hash("foobar\0") == 0x0c1c9eb8U);
    assert(hash("ch") == 0x5f299f4eU);
    assert(hash("cho") == 0xef8580f3U);
    assert(hash("chon") == 0xac297727U);
    assert(hash("chong") == 0x4546b9c0U);
    assert(hash("chongo") == 0xbd564e7dU);
    assert(hash("chongo ") == 0x6bdd5c67U);
    assert(hash("chongo w") == 0xdd77ed30U);
    assert(hash("chongo wa") == 0xf4ca9683U);
    assert(hash("chongo was") == 0x4aeb9bd0U);
    assert(hash("chongo was ") == 0xe0e67ad0U);
    assert(hash("chongo was h") == 0xc2d32fa8U);
    assert(hash("chongo was he") == 0x7f743fb7U);
    assert(hash("chongo was her") == 0x6900631fU);
    assert(hash("chongo was here") == 0xc59c990eU);
    assert(hash("chongo was here!") == 0x448524fdU);
    assert(hash("chongo was here!\n") == 0xd49930d5U);
    assert(hash("ch\0") == 0x1c85c7caU);
    assert(hash("cho\0") == 0x0229fe89U);
    assert(hash("chon\0") == 0x2c469265U);
    assert(hash("chong\0") == 0xce566940U);
    assert(hash("chongo\0") == 0x8bdd8ec7U);
    assert(hash("chongo \0") == 0x34787625U);
    assert(hash("chongo w\0") == 0xd3ca6290U);
    assert(hash("chongo wa\0") == 0xddeaf039U);
    assert(hash("chongo was\0") == 0xc0e64870U);
    assert(hash("chongo was \0") == 0xdad35570U);
    assert(hash("chongo was h\0") == 0x5a740578U);
    assert(hash("chongo was he\0") == 0x5b004d15U);
    assert(hash("chongo was her\0") == 0x6a9c09cdU);
    assert(hash("chongo was here\0") == 0x2384f10aU);
    assert(hash("chongo was here!\0") == 0xda993a47U);
    assert(hash("chongo was here!\n\0") == 0x8227df4fU);
    assert(hash("cu") == 0x4c298165U);
    assert(hash("cur") == 0xfc563735U);
    assert(hash("curd") == 0x8cb91483U);
    assert(hash("curds") == 0x775bf5d0U);
    assert(hash("curds ") == 0xd5c428d0U);
    assert(hash("curds a") == 0x34cc0ea3U);
    assert(hash("curds an") == 0xea3b4cb7U);
    assert(hash("curds and") == 0x8e59f029U);
    assert(hash("curds and ") == 0x2094de2bU);
    assert(hash("curds and w") == 0xa65a0ad4U);
    assert(hash("curds and wh") == 0x9bbee5f4U);
    assert(hash("curds and whe") == 0xbe836343U);
    assert(hash("curds and whey") == 0x22d5344eU);
    assert(hash("curds and whey\n") == 0x19a1470cU);
    assert(hash("cu\0") == 0x4a56b1ffU);
    assert(hash("cur\0") == 0x70b8e86fU);
    assert(hash("curd\0") == 0x0a5b4a39U);
    assert(hash("curds\0") == 0xb5c3f670U);
    assert(hash("curds \0") == 0x53cc3f70U);
    assert(hash("curds a\0") == 0xc03b0a99U);
    assert(hash("curds an\0") == 0x7259c415U);
    assert(hash("curds and\0") == 0x4095108bU);
    assert(hash("curds and \0") == 0x7559bdb1U);
    assert(hash("curds and w\0") == 0xb3bf0bbcU);
    assert(hash("curds and wh\0") == 0x2183ff1cU);
    assert(hash("curds and whe\0") == 0x2bd54279U);
    assert(hash("curds and whey\0") == 0x23a156caU);
    assert(hash("curds and whey\n\0") == 0x64e2d7e4U);
    assert(hash("hi") == 0x683af69aU);
    assert(hash("hi\0") == 0xaed2346eU);
    assert(hash("hello") == 0x4f9f2cabU);
    assert(hash("hello\0") == 0x02935131U);
    assert(hash("\xff\x00\x00\x01") == 0xc48fb86dU);
    assert(hash("\x01\x00\x00\xff") == 0x2269f369U);
    assert(hash("\xff\x00\x00\x02") == 0xc18fb3b4U);
    assert(hash("\x02\x00\x00\xff") == 0x50ef1236U);
    assert(hash("\xff\x00\x00\x03") == 0xc28fb547U);
    assert(hash("\x03\x00\x00\xff") == 0x96c3bf47U);
    assert(hash("\xff\x00\x00\x04") == 0xbf8fb08eU);
    assert(hash("\x04\x00\x00\xff") == 0xf3e4d49cU);
    assert(hash("\x40\x51\x4e\x44") == 0x32179058U);
    assert(hash("\x44\x4e\x51\x40") == 0x280bfee6U);
    assert(hash("\x40\x51\x4e\x4a") == 0x30178d32U);
    assert(hash("\x4a\x4e\x51\x40") == 0x21addaf8U);
    assert(hash("\x40\x51\x4e\x54") == 0x4217a988U);
    assert(hash("\x54\x4e\x51\x40") == 0x772633d6U);
    assert(hash("127.0.0.1") == 0x08a3d11eU);
    assert(hash("127.0.0.1\0") == 0xb7e2323aU);
    assert(hash("127.0.0.2") == 0x07a3cf8bU);
    assert(hash("127.0.0.2\0") == 0x91dfb7d1U);
    assert(hash("127.0.0.3") == 0x06a3cdf8U);
    assert(hash("127.0.0.3\0") == 0x6bdd3d68U);
    assert(hash("64.81.78.68") == 0x1d5636a7U);
    assert(hash("64.81.78.68\0") == 0xd5b808e5U);
    assert(hash("64.81.78.74") == 0x1353e852U);
    assert(hash("64.81.78.74\0") == 0xbf16b916U);
    assert(hash("64.81.78.84") == 0xa55b89edU);
    assert(hash("64.81.78.84\0") == 0x3c1a2017U);
    assert(hash("feedface") == 0x0588b13cU);
    assert(hash("feedface\0") == 0xf22f0174U);
    assert(hash("feedfacedaffdeed") == 0xe83641e1U);
    assert(hash("feedfacedaffdeed\0") == 0x6e69b533U);
    assert(hash("feedfacedeadbeef") == 0xf1760448U);
    assert(hash("feedfacedeadbeef\0") == 0x64c8bd58U);
    assert(hash("line 1\nline 2\nline 3") == 0x97b4ea23U);
    assert(hash("chongo <Landon Curt Noll> /\\../\\") == 0x9a4e92e6U);
    assert(hash("chongo <Landon Curt Noll> /\\../\\\0") == 0xcfb14012U);
    assert(hash("chongo (Landon Curt Noll) /\\../\\") == 0xf01b2511U);
    assert(hash("chongo (Landon Curt Noll) /\\../\\\0") == 0x0bbb59c3U);
    assert(hash("http://antwrp.gsfc.nasa.gov/apod/astropix.html") == 0xce524afaU);
    assert(hash("http://en.wikipedia.org/wiki/Fowler_Noll_Vo_hash") == 0xdd16ef45U);
    assert(hash("http://epod.usra.edu/") == 0x60648bb3U);
    assert(hash("http://exoplanet.eu/") == 0x7fa4bcfcU);
    assert(hash("http://hvo.wr.usgs.gov/cam3/") == 0x5053ae17U);
    assert(hash("http://hvo.wr.usgs.gov/cams/HMcam/") == 0xc9302890U);
    assert(hash("http://hvo.wr.usgs.gov/kilauea/update/deformation.html") == 0x956ded32U);
    assert(hash("http://hvo.wr.usgs.gov/kilauea/update/images.html") == 0x9136db84U);
    assert(hash("http://hvo.wr.usgs.gov/kilauea/update/maps.html") == 0xdf9d3323U);
    assert(hash("http://hvo.wr.usgs.gov/volcanowatch/current_issue.html") == 0x32bb6cd0U);
    assert(hash("http://neo.jpl.nasa.gov/risk/") == 0xc8f8385bU);
    assert(hash("http://norvig.com/21-days.html") == 0xeb08bfbaU);
    assert(hash("http://primes.utm.edu/curios/home.php") == 0x62cc8e3dU);
    assert(hash("http://slashdot.org/") == 0xc3e20f5cU);
    assert(hash("http://tux.wr.usgs.gov/Maps/155.25-19.5.html") == 0x39e97f17U);
    assert(hash("http://volcano.wr.usgs.gov/kilaueastatus.php") == 0x7837b203U);
    assert(hash("http://www.avo.alaska.edu/activity/Redoubt.php") == 0x319e877bU);
    assert(hash("http://www.dilbert.com/fast/") == 0xd3e63f89U);
    assert(hash("http://www.fourmilab.ch/gravitation/orbits/") == 0x29b50b38U);
    assert(hash("http://www.fpoa.net/") == 0x5ed678b8U);
    assert(hash("http://www.ioccc.org/index.html") == 0xb0d5b793U);
    assert(hash("http://www.isthe.com/cgi-bin/number.cgi") == 0x52450be5U);
    assert(hash("http://www.isthe.com/chongo/bio.html") == 0xfa72d767U);
    assert(hash("http://www.isthe.com/chongo/index.html") == 0x95066709U);
    assert(hash("http://www.isthe.com/chongo/src/calc/lucas-calc") == 0x7f52e123U);
    assert(hash("http://www.isthe.com/chongo/tech/astro/venus2004.html") == 0x76966481U);
    assert(hash("http://www.isthe.com/chongo/tech/astro/vita.html") == 0x063258b0U);
    assert(hash("http://www.isthe.com/chongo/tech/comp/c/expert.html") == 0x2ded6e8aU);
    assert(hash("http://www.isthe.com/chongo/tech/comp/calc/index.html") == 0xb07d7c52U);
    assert(hash("http://www.isthe.com/chongo/tech/comp/fnv/index.html") == 0xd0c71b71U);
    assert(hash("http://www.isthe.com/chongo/tech/math/number/howhigh.html") == 0xf684f1bdU);
    assert(hash("http://www.isthe.com/chongo/tech/math/number/number.html") == 0x868ecfa8U);
    assert(hash("http://www.isthe.com/chongo/tech/math/prime/mersenne.html") == 0xf794f684U);
    assert(hash("http://www.isthe.com/chongo/tech/math/prime/mersenne.html#largest") == 0xd19701c3U);
    assert(hash("http://www.lavarnd.org/cgi-bin/corpspeak.cgi") == 0x346e171eU);
    assert(hash("http://www.lavarnd.org/cgi-bin/haiku.cgi") == 0x91f8f676U);
    assert(hash("http://www.lavarnd.org/cgi-bin/rand-none.cgi") == 0x0bf58848U);
    assert(hash("http://www.lavarnd.org/cgi-bin/randdist.cgi") == 0x6317b6d1U);
    assert(hash("http://www.lavarnd.org/index.html") == 0xafad4c54U);
    assert(hash("http://www.lavarnd.org/what/nist-test.html") == 0x0f25681eU);
    assert(hash("http://www.macosxhints.com/") == 0x91b18d49U);
    assert(hash("http://www.mellis.com/") == 0x7d61c12eU);
    assert(hash("http://www.nature.nps.gov/air/webcams/parks/havoso2alert/havoalert.cfm") == 0x5147d25cU);
    assert(hash("http://www.nature.nps.gov/air/webcams/parks/havoso2alert/timelines_24.cfm") == 0x9a8b6805U);
    assert(hash("http://www.paulnoll.com/") == 0x4cd2a447U);
    assert(hash("http://www.pepysdiary.com/") == 0x1e549b14U);
    assert(hash("http://www.sciencenews.org/index/home/activity/view") == 0x2fe1b574U);
    assert(hash("http://www.skyandtelescope.com/") == 0xcf0cd31eU);
    assert(hash("http://www.sput.nl/~rob/sirius.html") == 0x6c471669U);
    assert(hash("http://www.systemexperts.com/") == 0x0e5eef1eU);
    assert(hash("http://www.tq-international.com/phpBB3/index.php") == 0x2bed3602U);
    assert(hash("http://www.travelquesttours.com/index.htm") == 0xb26249e0U);
    assert(hash("http://www.wunderground.com/global/stations/89606.html") == 0x2c9b86a4U);
    assert(hash(r10!"21701") == 0xe415e2bbU);
    assert(hash(r10!"M21701") == 0x18a98d1dU);
    assert(hash(r10!"2^21701-1") == 0xb7df8b7bU);
    assert(hash(r10!"\x54\xc5") == 0x241e9075U);
    assert(hash(r10!"\xc5\x54") == 0x063f70ddU);
    assert(hash(r10!"23209") == 0x0295aed9U);
    assert(hash(r10!"M23209") == 0x56a7f781U);
    assert(hash(r10!"2^23209-1") == 0x253bc645U);
    assert(hash(r10!"\x5a\xa9") == 0x46610921U);
    assert(hash(r10!"\xa9\x5a") == 0x7c1577f9U);
    assert(hash(r10!"391581216093") == 0x512b2851U);
    assert(hash(r10!"391581*2^216093-1") == 0x76823999U);
    assert(hash(r10!"\x05\xf9\x9d\x03\x4c\x81") == 0xc0586935U);
    assert(hash(r10!"FEDCBA9876543210") == 0xf3415c85U);
    assert(hash(r10!"\xfe\xdc\xba\x98\x76\x54\x32\x10") == 0x0ae4ff65U);
    assert(hash(r10!"EFCDAB8967452301") == 0x58b79725U);
    assert(hash(r10!"\xef\xcd\xab\x89\x67\x45\x23\x01") == 0xdea43aa5U);
    assert(hash(r10!"0123456789ABCDEF") == 0x2bb3be35U);
    assert(hash(r10!"\x01\x23\x45\x67\x89\xab\xcd\xef") == 0xea777a45U);
    assert(hash(r10!"1032547698BADCFE") == 0x8f21c305U);
    assert(hash(r10!"\x10\x32\x54\x76\x98\xba\xdc\xfe") == 0x5c9d0865U);
    assert(hash(r500!"\x00") == 0xfa823dd5U);
    assert(hash(r500!"\x07") == 0x21a27271U);
    assert(hash(r500!"~") == 0x83c5c6d5U);
    assert(hash(r500!"\x7f") == 0x813b0881U);
 }
 // FNV-1a 64 bit test vectors
 static if (size_t.sizeof == 8) @nogc nothrow pure @safe unittest
 {
    assert(hash("") == 0xcbf29ce484222325UL);
    assert(hash("a") == 0xaf63dc4c8601ec8cUL);
    assert(hash("b") == 0xaf63df4c8601f1a5UL);
    assert(hash("c") == 0xaf63de4c8601eff2UL);
    assert(hash("d") == 0xaf63d94c8601e773UL);
    assert(hash("e") == 0xaf63d84c8601e5c0UL);
    assert(hash("f") == 0xaf63db4c8601ead9UL);
    assert(hash("fo") == 0x08985907b541d342UL);
    assert(hash("foo") == 0xdcb27518fed9d577UL);
    assert(hash("foob") == 0xdd120e790c2512afUL);
    assert(hash("fooba") == 0xcac165afa2fef40aUL);
    assert(hash("foobar") == 0x85944171f73967e8UL);
    assert(hash("\0") == 0xaf63bd4c8601b7dfUL);
    assert(hash("a\0") == 0x089be207b544f1e4UL);
    assert(hash("b\0") == 0x08a61407b54d9b5fUL);
    assert(hash("c\0") == 0x08a2ae07b54ab836UL);
    assert(hash("d\0") == 0x0891b007b53c4869UL);
    assert(hash("e\0") == 0x088e4a07b5396540UL);
    assert(hash("f\0") == 0x08987c07b5420ebbUL);
    assert(hash("fo\0") == 0xdcb28a18fed9f926UL);
    assert(hash("foo\0") == 0xdd1270790c25b935UL);
    assert(hash("foob\0") == 0xcac146afa2febf5dUL);
    assert(hash("fooba\0") == 0x8593d371f738acfeUL);
    assert(hash("foobar\0") == 0x34531ca7168b8f38UL);
    assert(hash("ch") == 0x08a25607b54a22aeUL);
    assert(hash("cho") == 0xf5faf0190cf90df3UL);
    assert(hash("chon") == 0xf27397910b3221c7UL);
    assert(hash("chong") == 0x2c8c2b76062f22e0UL);
    assert(hash("chongo") == 0xe150688c8217b8fdUL);
    assert(hash("chongo ") == 0xf35a83c10e4f1f87UL);
    assert(hash("chongo w") == 0xd1edd10b507344d0UL);
    assert(hash("chongo wa") == 0x2a5ee739b3ddb8c3UL);
    assert(hash("chongo was") == 0xdcfb970ca1c0d310UL);
    assert(hash("chongo was ") == 0x4054da76daa6da90UL);
    assert(hash("chongo was h") == 0xf70a2ff589861368UL);
    assert(hash("chongo was he") == 0x4c628b38aed25f17UL);
    assert(hash("chongo was her") == 0x9dd1f6510f78189fUL);
    assert(hash("chongo was here") == 0xa3de85bd491270ceUL);
    assert(hash("chongo was here!") == 0x858e2fa32a55e61dUL);
    assert(hash("chongo was here!\n") == 0x46810940eff5f915UL);
    assert(hash("ch\0") == 0xf5fadd190cf8edaaUL);
    assert(hash("cho\0") == 0xf273ed910b32b3e9UL);
    assert(hash("chon\0") == 0x2c8c5276062f6525UL);
    assert(hash("chong\0") == 0xe150b98c821842a0UL);
    assert(hash("chongo\0") == 0xf35aa3c10e4f55e7UL);
    assert(hash("chongo \0") == 0xd1ed680b50729265UL);
    assert(hash("chongo w\0") == 0x2a5f0639b3dded70UL);
    assert(hash("chongo wa\0") == 0xdcfbaa0ca1c0f359UL);
    assert(hash("chongo was\0") == 0x4054ba76daa6a430UL);
    assert(hash("chongo was \0") == 0xf709c7f5898562b0UL);
    assert(hash("chongo was h\0") == 0x4c62e638aed2f9b8UL);
    assert(hash("chongo was he\0") == 0x9dd1a8510f779415UL);
    assert(hash("chongo was her\0") == 0xa3de2abd4911d62dUL);
    assert(hash("chongo was here\0") == 0x858e0ea32a55ae0aUL);
    assert(hash("chongo was here!\0") == 0x46810f40eff60347UL);
    assert(hash("chongo was here!\n\0") == 0xc33bce57bef63eafUL);
    assert(hash("cu") == 0x08a24307b54a0265UL);
    assert(hash("cur") == 0xf5b9fd190cc18d15UL);
    assert(hash("curd") == 0x4c968290ace35703UL);
    assert(hash("curds") == 0x07174bd5c64d9350UL);
    assert(hash("curds ") == 0x5a294c3ff5d18750UL);
    assert(hash("curds a") == 0x05b3c1aeb308b843UL);
    assert(hash("curds an") == 0xb92a48da37d0f477UL);
    assert(hash("curds and") == 0x73cdddccd80ebc49UL);
    assert(hash("curds and ") == 0xd58c4c13210a266bUL);
    assert(hash("curds and w") == 0xe78b6081243ec194UL);
    assert(hash("curds and wh") == 0xb096f77096a39f34UL);
    assert(hash("curds and whe") == 0xb425c54ff807b6a3UL);
    assert(hash("curds and whey") == 0x23e520e2751bb46eUL);
    assert(hash("curds and whey\n") == 0x1a0b44ccfe1385ecUL);
    assert(hash("cu\0") == 0xf5ba4b190cc2119fUL);
    assert(hash("cur\0") == 0x4c962690ace2baafUL);
    assert(hash("curd\0") == 0x0716ded5c64cda19UL);
    assert(hash("curds\0") == 0x5a292c3ff5d150f0UL);
    assert(hash("curds \0") == 0x05b3e0aeb308ecf0UL);
    assert(hash("curds a\0") == 0xb92a5eda37d119d9UL);
    assert(hash("curds an\0") == 0x73ce41ccd80f6635UL);
    assert(hash("curds and\0") == 0xd58c2c132109f00bUL);
    assert(hash("curds and \0") == 0xe78baf81243f47d1UL);
    assert(hash("curds and w\0") == 0xb0968f7096a2ee7cUL);
    assert(hash("curds and wh\0") == 0xb425a84ff807855cUL);
    assert(hash("curds and whe\0") == 0x23e4e9e2751b56f9UL);
    assert(hash("curds and whey\0") == 0x1a0b4eccfe1396eaUL);
    assert(hash("curds and whey\n\0") == 0x54abd453bb2c9004UL);
    assert(hash("hi") == 0x08ba5f07b55ec3daUL);
    assert(hash("hi\0") == 0x337354193006cb6eUL);
    assert(hash("hello") == 0xa430d84680aabd0bUL);
    assert(hash("hello\0") == 0xa9bc8acca21f39b1UL);
    assert(hash("\xff\x00\x00\x01") == 0x6961196491cc682dUL);
    assert(hash("\x01\x00\x00\xff") == 0xad2bb1774799dfe9UL);
    assert(hash("\xff\x00\x00\x02") == 0x6961166491cc6314UL);
    assert(hash("\x02\x00\x00\xff") == 0x8d1bb3904a3b1236UL);
    assert(hash("\xff\x00\x00\x03") == 0x6961176491cc64c7UL);
    assert(hash("\x03\x00\x00\xff") == 0xed205d87f40434c7UL);
    assert(hash("\xff\x00\x00\x04") == 0x6961146491cc5faeUL);
    assert(hash("\x04\x00\x00\xff") == 0xcd3baf5e44f8ad9cUL);
    assert(hash("\x40\x51\x4e\x44") == 0xe3b36596127cd6d8UL);
    assert(hash("\x44\x4e\x51\x40") == 0xf77f1072c8e8a646UL);
    assert(hash("\x40\x51\x4e\x4a") == 0xe3b36396127cd372UL);
    assert(hash("\x4a\x4e\x51\x40") == 0x6067dce9932ad458UL);
    assert(hash("\x40\x51\x4e\x54") == 0xe3b37596127cf208UL);
    assert(hash("\x54\x4e\x51\x40") == 0x4b7b10fa9fe83936UL);
    assert(hash("127.0.0.1") == 0xaabafe7104d914beUL);
    assert(hash("127.0.0.1\0") == 0xf4d3180b3cde3edaUL);
    assert(hash("127.0.0.2") == 0xaabafd7104d9130bUL);
    assert(hash("127.0.0.2\0") == 0xf4cfb20b3cdb5bb1UL);
    assert(hash("127.0.0.3") == 0xaabafc7104d91158UL);
    assert(hash("127.0.0.3\0") == 0xf4cc4c0b3cd87888UL);
    assert(hash("64.81.78.68") == 0xe729bac5d2a8d3a7UL);
    assert(hash("64.81.78.68\0") == 0x74bc0524f4dfa4c5UL);
    assert(hash("64.81.78.74") == 0xe72630c5d2a5b352UL);
    assert(hash("64.81.78.74\0") == 0x6b983224ef8fb456UL);
    assert(hash("64.81.78.84") == 0xe73042c5d2ae266dUL);
    assert(hash("64.81.78.84\0") == 0x8527e324fdeb4b37UL);
    assert(hash("feedface") == 0x0a83c86fee952abcUL);
    assert(hash("feedface\0") == 0x7318523267779d74UL);
    assert(hash("feedfacedaffdeed") == 0x3e66d3d56b8caca1UL);
    assert(hash("feedfacedaffdeed\0") == 0x956694a5c0095593UL);
    assert(hash("feedfacedeadbeef") == 0xcac54572bb1a6fc8UL);
    assert(hash("feedfacedeadbeef\0") == 0xa7a4c9f3edebf0d8UL);
    assert(hash("line 1\nline 2\nline 3") == 0x7829851fac17b143UL);
    assert(hash("chongo <Landon Curt Noll> /\\../\\") == 0x2c8f4c9af81bcf06UL);
    assert(hash("chongo <Landon Curt Noll> /\\../\\\0") == 0xd34e31539740c732UL);
    assert(hash("chongo (Landon Curt Noll) /\\../\\") == 0x3605a2ac253d2db1UL);
    assert(hash("chongo (Landon Curt Noll) /\\../\\\0") == 0x08c11b8346f4a3c3UL);
    assert(hash("http://antwrp.gsfc.nasa.gov/apod/astropix.html") == 0x6be396289ce8a6daUL);
    assert(hash("http://en.wikipedia.org/wiki/Fowler_Noll_Vo_hash") == 0xd9b957fb7fe794c5UL);
    assert(hash("http://epod.usra.edu/") == 0x05be33da04560a93UL);
    assert(hash("http://exoplanet.eu/") == 0x0957f1577ba9747cUL);
    assert(hash("http://hvo.wr.usgs.gov/cam3/") == 0xda2cc3acc24fba57UL);
    assert(hash("http://hvo.wr.usgs.gov/cams/HMcam/") == 0x74136f185b29e7f0UL);
    assert(hash("http://hvo.wr.usgs.gov/kilauea/update/deformation.html") == 0xb2f2b4590edb93b2UL);
    assert(hash("http://hvo.wr.usgs.gov/kilauea/update/images.html") == 0xb3608fce8b86ae04UL);
    assert(hash("http://hvo.wr.usgs.gov/kilauea/update/maps.html") == 0x4a3a865079359063UL);
    assert(hash("http://hvo.wr.usgs.gov/volcanowatch/current_issue.html") == 0x5b3a7ef496880a50UL);
    assert(hash("http://neo.jpl.nasa.gov/risk/") == 0x48fae3163854c23bUL);
    assert(hash("http://norvig.com/21-days.html") == 0x07aaa640476e0b9aUL);
    assert(hash("http://primes.utm.edu/curios/home.php") == 0x2f653656383a687dUL);
    assert(hash("http://slashdot.org/") == 0xa1031f8e7599d79cUL);
    assert(hash("http://tux.wr.usgs.gov/Maps/155.25-19.5.html") == 0xa31908178ff92477UL);
    assert(hash("http://volcano.wr.usgs.gov/kilaueastatus.php") == 0x097edf3c14c3fb83UL);
    assert(hash("http://www.avo.alaska.edu/activity/Redoubt.php") == 0xb51ca83feaa0971bUL);
    assert(hash("http://www.dilbert.com/fast/") == 0xdd3c0d96d784f2e9UL);
    assert(hash("http://www.fourmilab.ch/gravitation/orbits/") == 0x86cd26a9ea767d78UL);
    assert(hash("http://www.fpoa.net/") == 0xe6b215ff54a30c18UL);
    assert(hash("http://www.ioccc.org/index.html") == 0xec5b06a1c5531093UL);
    assert(hash("http://www.isthe.com/cgi-bin/number.cgi") == 0x45665a929f9ec5e5UL);
    assert(hash("http://www.isthe.com/chongo/bio.html") == 0x8c7609b4a9f10907UL);
    assert(hash("http://www.isthe.com/chongo/index.html") == 0x89aac3a491f0d729UL);
    assert(hash("http://www.isthe.com/chongo/src/calc/lucas-calc") == 0x32ce6b26e0f4a403UL);
    assert(hash("http://www.isthe.com/chongo/tech/astro/venus2004.html") == 0x614ab44e02b53e01UL);
    assert(hash("http://www.isthe.com/chongo/tech/astro/vita.html") == 0xfa6472eb6eef3290UL);
    assert(hash("http://www.isthe.com/chongo/tech/comp/c/expert.html") == 0x9e5d75eb1948eb6aUL);
    assert(hash("http://www.isthe.com/chongo/tech/comp/calc/index.html") == 0xb6d12ad4a8671852UL);
    assert(hash("http://www.isthe.com/chongo/tech/comp/fnv/index.html") == 0x88826f56eba07af1UL);
    assert(hash("http://www.isthe.com/chongo/tech/math/number/howhigh.html") == 0x44535bf2645bc0fdUL);
    assert(hash("http://www.isthe.com/chongo/tech/math/number/number.html") == 0x169388ffc21e3728UL);
    assert(hash("http://www.isthe.com/chongo/tech/math/prime/mersenne.html") == 0xf68aac9e396d8224UL);
    assert(hash("http://www.isthe.com/chongo/tech/math/prime/mersenne.html#largest") == 0x8e87d7e7472b3883UL);
    assert(hash("http://www.lavarnd.org/cgi-bin/corpspeak.cgi") == 0x295c26caa8b423deUL);
    assert(hash("http://www.lavarnd.org/cgi-bin/haiku.cgi") == 0x322c814292e72176UL);
    assert(hash("http://www.lavarnd.org/cgi-bin/rand-none.cgi") == 0x8a06550eb8af7268UL);
    assert(hash("http://www.lavarnd.org/cgi-bin/randdist.cgi") == 0xef86d60e661bcf71UL);
    assert(hash("http://www.lavarnd.org/index.html") == 0x9e5426c87f30ee54UL);
    assert(hash("http://www.lavarnd.org/what/nist-test.html") == 0xf1ea8aa826fd047eUL);
    assert(hash("http://www.macosxhints.com/") == 0x0babaf9a642cb769UL);
    assert(hash("http://www.mellis.com/") == 0x4b3341d4068d012eUL);
    assert(hash("http://www.nature.nps.gov/air/webcams/parks/havoso2alert/havoalert.cfm") == 0xd15605cbc30a335cUL);
    assert(hash("http://www.nature.nps.gov/air/webcams/parks/havoso2alert/timelines_24.cfm") == 0x5b21060aed8412e5UL);
    assert(hash("http://www.paulnoll.com/") == 0x45e2cda1ce6f4227UL);
    assert(hash("http://www.pepysdiary.com/") == 0x50ae3745033ad7d4UL);
    assert(hash("http://www.sciencenews.org/index/home/activity/view") == 0xaa4588ced46bf414UL);
    assert(hash("http://www.skyandtelescope.com/") == 0xc1b0056c4a95467eUL);
    assert(hash("http://www.sput.nl/~rob/sirius.html") == 0x56576a71de8b4089UL);
    assert(hash("http://www.systemexperts.com/") == 0xbf20965fa6dc927eUL);
    assert(hash("http://www.tq-international.com/phpBB3/index.php") == 0x569f8383c2040882UL);
    assert(hash("http://www.travelquesttours.com/index.htm") == 0xe1e772fba08feca0UL);
    assert(hash("http://www.wunderground.com/global/stations/89606.html") == 0x4ced94af97138ac4UL);
    assert(hash(r10!"21701") == 0xc4112ffb337a82fbUL);
    assert(hash(r10!"M21701") == 0xd64a4fd41de38b7dUL);
    assert(hash(r10!"2^21701-1") == 0x4cfc32329edebcbbUL);
    assert(hash(r10!"\x54\xc5") == 0x0803564445050395UL);
    assert(hash(r10!"\xc5\x54") == 0xaa1574ecf4642ffdUL);
    assert(hash(r10!"23209") == 0x694bc4e54cc315f9UL);
    assert(hash(r10!"M23209") == 0xa3d7cb273b011721UL);
    assert(hash(r10!"2^23209-1") == 0x577c2f8b6115bfa5UL);
    assert(hash(r10!"\x5a\xa9") == 0xb7ec8c1a769fb4c1UL);
    assert(hash(r10!"\xa9\x5a") == 0x5d5cfce63359ab19UL);
    assert(hash(r10!"391581216093") == 0x33b96c3cd65b5f71UL);
    assert(hash(r10!"391581*2^216093-1") == 0xd845097780602bb9UL);
    assert(hash(r10!"\x05\xf9\x9d\x03\x4c\x81") == 0x84d47645d02da3d5UL);
    assert(hash(r10!"FEDCBA9876543210") == 0x83544f33b58773a5UL);
    assert(hash(r10!"\xfe\xdc\xba\x98\x76\x54\x32\x10") == 0x9175cbb2160836c5UL);
    assert(hash(r10!"EFCDAB8967452301") == 0xc71b3bc175e72bc5UL);
    assert(hash(r10!"\xef\xcd\xab\x89\x67\x45\x23\x01") == 0x636806ac222ec985UL);
    assert(hash(r10!"0123456789ABCDEF") == 0xb6ef0e6950f52ed5UL);
    assert(hash(r10!"\x01\x23\x45\x67\x89\xab\xcd\xef") == 0xead3d8a0f3dfdaa5UL);
    assert(hash(r10!"1032547698BADCFE") == 0x922908fe9a861ba5UL);
    assert(hash(r10!"\x10\x32\x54\x76\x98\xba\xdc\xfe") == 0x6d4821de275fd5c5UL);
    assert(hash(r500!"\x00") == 0x1fe3fce62bd816b5UL);
    assert(hash(r500!"\x07") == 0xc23e9fccd6f70591UL);
    assert(hash(r500!"~") == 0xc1af12bdfe16b5b5UL);
    assert(hash(r500!"\x7f") == 0x39e9f18f2f85e221UL);
 }
--- a/source/tanya/crypto/package.d
+++ b/source/tanya/crypto/package.d
@ -3,14 +3,13 @@
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
- * Copyright: Eugene Wissner 2016.
+ * Copyright: Eugene Wissner 2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
- * Authors: $(LINK2 mailto:belka@caraus.de, Eugene Wissner)
+ * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/hash/package.d,
 *                 tanya/hash/package.d)
 */
-module tanya.crypto;
+module tanya.hash;
-public import tanya.crypto.bit;
+public import tanya.hash.lookup;
 public import tanya.crypto.des;
 public import tanya.crypto.mode;
 public import tanya.crypto.symmetric;
--- a/source/tanya/math/mp.d
+++ b/source/tanya/math/mp.d
--- a/source/tanya/math/nbtheory.d
+++ b/source/tanya/math/nbtheory.d
@ -0,0 +1,167 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * Number theory.
 *
 * Copyright: Eugene Wissner 2017-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/math/nbtheory.d,
 *                 tanya/math/nbtheory.d)
 */
 module tanya.math.nbtheory;
 import tanya.math.mp;
 import tanya.meta.trait;
 import tanya.meta.transform;
 version (TanyaNative)
 {
    private extern float fabs(float) @nogc nothrow pure @safe;
    private extern double fabs(double) @nogc nothrow pure @safe;
    private extern real fabs(real) @nogc nothrow pure @safe;
    private extern double log(double) @nogc nothrow pure @safe;
    private extern float logf(float) @nogc nothrow pure @safe;
    private extern real logl(real) @nogc nothrow pure @safe;
 }
 else
 {
    import core.math : fabs;
    import std.math : log;
 }
 /**
 * Calculates the absolute value of a number.
 *
 * Params:
 *  T = Argument type.
 *  x = Argument.
 *
 * Returns: Absolute value of $(D_PARAM x).
 */
 Unqual!T abs(T)(T x)
 if (isIntegral!T)
 {
    static if (isSigned!T)
    {
        return x >= 0 ? x : -x;
    }
    else
    {
        return x;
    }
 }
 ///
@nogc nothrow pure @safe unittest
 {
    int i = -1;
    assert(i.abs == 1);
    static assert(is(typeof(i.abs) == int));
    uint u = 1;
    assert(u.abs == 1);
    static assert(is(typeof(u.abs) == uint));
 }
 /// ditto
 Unqual!T abs(T)(T x)
 if (isFloatingPoint!T)
 {
    return fabs(x);
 }
 ///
@nogc nothrow pure @safe unittest
 {
    float f = -1.64;
    assert(f.abs == 1.64F);
    static assert(is(typeof(f.abs) == float));
    double d = -1.64;
    assert(d.abs == 1.64);
    static assert(is(typeof(d.abs) == double));
    real r = -1.64;
    assert(r.abs == 1.64L);
    static assert(is(typeof(r.abs) == real));
 }
 /// ditto
 T abs(T : Integer)(const auto ref T x)
 {
    auto result = Integer(x, x.allocator);
    result.sign = Sign.positive;
    return result;
 }
 /// ditto
 T abs(T : Integer)(T x)
 {
    x.sign = Sign.positive;
    return x;
 }
 version (D_Ddoc)
 {
    /**
     * Calculates natural logarithm of $(D_PARAM x).
     *
     * Params:
     *  T = Argument type.
     *  x = Argument.
     *
     * Returns: Natural logarithm of $(D_PARAM x).
     */
    Unqual!T ln(T)(T x)
    if (isFloatingPoint!T);
 }
 else version (TanyaNative)
 {
    Unqual!T ln(T)(T x) @nogc nothrow pure @safe
    if (isFloatingPoint!T)
    {
        static if (is(Unqual!T == float))
        {
            return logf(x);
        }
        else static if (is(Unqual!T == double))
        {
            return log(x);
        }
        else
        {
            return logl(x);
        }
    }
 }
 else
 {
    Unqual!T ln(T)(T x)
    if (isFloatingPoint!T)
    {
        return log(x);
    }
 }
 ///
@nogc nothrow pure @safe unittest
 {
    import tanya.math;
    assert(isNaN(ln(-7.389f)));
    assert(isNaN(ln(-7.389)));
    assert(isNaN(ln(-7.389L)));
    assert(isInfinity(ln(0.0f)));
    assert(isInfinity(ln(0.0)));
    assert(isInfinity(ln(0.0L)));
    assert(ln(1.0f) == 0.0f);
    assert(ln(1.0) == 0.0);
    assert(ln(1.0L) == 0.0L);
 }
--- a/source/tanya/math/package.d
+++ b/source/tanya/math/package.d
@ -3,20 +3,562 @@
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
- * Copyright: Eugene Wissner 2016.
+ * This package provides mathematical functions.
 *
 * The $(D_PSYMBOL tanya.math) package itself provides only representation
 * functions for built-in types, such as functions that provide information
 * about internal representation of floating-point numbers and low-level
 * operatons on these. Actual mathematical functions and additional types can
 * be found in its submodules. $(D_PSYMBOL tanya.math) doesn't import any
 * submodules publically, they should be imported explicitly.
 *
 * Copyright: Eugene Wissner 2016-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
- * Authors: $(LINK2 mailto:belka@caraus.de, Eugene Wissner)
+ * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
- */  
+ * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/math/package.d,
 *                 tanya/math/package.d)
 */
 module tanya.math;
-import std.traits;
+import tanya.algorithm.mutation;
-public import tanya.math.mp;
+import tanya.math.mp;
-public import tanya.math.random;
+import tanya.math.nbtheory;
 import tanya.meta.trait;
 import tanya.meta.transform;
-version (unittest)
+/// Floating-point number precisions according to IEEE-754.
 enum IEEEPrecision : ubyte
 {
-	import std.algorithm.iteration;
+    single = 4, /// Single precision: 64-bit.
    double_ = 8, /// Single precision: 64-bit.
    doubleExtended = 10, /// Double extended precision: 80-bit.
 }
 /**
 * Tests the precision of floating-point type $(D_PARAM F).
 *
 * For $(D_KEYWORD float) $(D_PSYMBOL ieeePrecision) always evaluates to
 * $(D_INLINECODE IEEEPrecision.single); for $(D_KEYWORD double) - to
 * $(D_INLINECODE IEEEPrecision.double). It returns different values only
 * for $(D_KEYWORD real), since $(D_KEYWORD real) is a platform-dependent type.
 *
 * If $(D_PARAM F) is a $(D_KEYWORD real) and the target platform isn't
 * currently supported, static assertion error will be raised (you can use
 * $(D_INLINECODE is(typeof(ieeePrecision!F))) for testing the platform support
 * without a compilation error).
 *
 * Params:
 *  F = Type to be tested.
 *
 * Returns: Precision according to IEEE-754.
 *
 * See_Also: $(D_PSYMBOL IEEEPrecision).
 */
 template ieeePrecision(F)
 if (isFloatingPoint!F)
 {
    static if (F.sizeof == float.sizeof)
    {
        enum IEEEPrecision ieeePrecision = IEEEPrecision.single;
    }
    else static if (F.sizeof == double.sizeof)
    {
        enum IEEEPrecision ieeePrecision = IEEEPrecision.double_;
    }
    else version (X86)
    {
        enum IEEEPrecision ieeePrecision = IEEEPrecision.doubleExtended;
    }
    else version (X86_64)
    {
        enum IEEEPrecision ieeePrecision = IEEEPrecision.doubleExtended;
    }
    else
    {
        static assert(false, "Unsupported IEEE 754 floating point precision");
    }
 }
 ///
@nogc nothrow pure @safe unittest
 {
    static assert(ieeePrecision!float == IEEEPrecision.single);
    static assert(ieeePrecision!double == IEEEPrecision.double_);
 }
 package(tanya) union FloatBits(F)
 {
    Unqual!F floating;
    static if (ieeePrecision!F == IEEEPrecision.single)
    {
        uint integral;
        enum uint expMask = 0x7f800000;
    }
    else static if (ieeePrecision!F == IEEEPrecision.double_)
    {
        ulong integral;
        enum ulong expMask = 0x7ff0000000000000;
    }
    else static if (ieeePrecision!F == IEEEPrecision.doubleExtended)
    {
        struct // Little-endian.
        {
            ulong mantissa;
            ushort exp;
        }
        enum ulong mantissaMask = 0x7fffffffffffffff;
        enum uint expMask = 0x7fff;
    }
    else
    {
        static assert(false, "Unsupported IEEE 754 floating point precision");
    }
 }
 /**
 * Floating-point number classifications.
 */
 enum FloatingPointClass : ubyte
 {
    /**
     * Not a Number.
     *
     * See_Also: $(D_PSYMBOL isNaN).
     */
    nan,
    /// Zero.
    zero,
    /**
     * Infinity.
     *
     * See_Also: $(D_PSYMBOL isInfinity).
     */
    infinite,
    /**
     * Denormalized number.
     *
     * See_Also: $(D_PSYMBOL isSubnormal).
     */
    subnormal,
    /**
     * Normalized number.
     *
     * See_Also: $(D_PSYMBOL isNormal).
     */
    normal,
 }
 /**
 * Returns whether $(D_PARAM x) is a NaN, zero, infinity, subnormal or
 * normalized number.
 *
 * This function doesn't distinguish between negative and positive infinity,
 * negative and positive NaN or negative and positive zero.
 *
 * Params:
 *  F = Type of the floating point number.
 *  x = Floating point number.
 *
 * Returns: Classification of $(D_PARAM x).
 */
 FloatingPointClass classify(F)(F x)
 if (isFloatingPoint!F)
 {
    if (x == 0)
    {
        return FloatingPointClass.zero;
    }
    FloatBits!F bits;
    bits.floating = abs(x);
    static if (ieeePrecision!F == IEEEPrecision.single)
    {
        if (bits.integral > bits.expMask)
        {
            return FloatingPointClass.nan;
        }
        else if (bits.integral == bits.expMask)
        {
            return FloatingPointClass.infinite;
        }
        else if (bits.integral < (1 << 23))
        {
            return FloatingPointClass.subnormal;
        }
    }
    else static if (ieeePrecision!F == IEEEPrecision.double_)
    {
        if (bits.integral > bits.expMask)
        {
            return FloatingPointClass.nan;
        }
        else if (bits.integral == bits.expMask)
        {
            return FloatingPointClass.infinite;
        }
        else if (bits.integral < (1L << 52))
        {
            return FloatingPointClass.subnormal;
        }
    }
    else static if (ieeePrecision!F == IEEEPrecision.doubleExtended)
    {
        if (bits.exp == bits.expMask)
        {
            if ((bits.mantissa & bits.mantissaMask) == 0)
            {
                return FloatingPointClass.infinite;
            }
            else
            {
                return FloatingPointClass.nan;
            }
        }
        else if (bits.exp == 0)
        {
            return FloatingPointClass.subnormal;
        }
        else if (bits.mantissa < (1L << 63)) // "Unnormal".
        {
            return FloatingPointClass.nan;
        }
    }
    return FloatingPointClass.normal;
 }
 ///
@nogc nothrow pure @safe unittest
 {
    assert(classify(0.0) == FloatingPointClass.zero);
    assert(classify(double.nan) == FloatingPointClass.nan);
    assert(classify(double.infinity) == FloatingPointClass.infinite);
    assert(classify(-double.infinity) == FloatingPointClass.infinite);
    assert(classify(1.4) == FloatingPointClass.normal);
    assert(classify(1.11254e-307 / 10) == FloatingPointClass.subnormal);
    assert(classify(0.0f) == FloatingPointClass.zero);
    assert(classify(float.nan) == FloatingPointClass.nan);
    assert(classify(float.infinity) == FloatingPointClass.infinite);
    assert(classify(-float.infinity) == FloatingPointClass.infinite);
    assert(classify(0.3) == FloatingPointClass.normal);
    assert(classify(5.87747e-38f / 10) == FloatingPointClass.subnormal);
    assert(classify(0.0L) == FloatingPointClass.zero);
    assert(classify(real.nan) == FloatingPointClass.nan);
    assert(classify(real.infinity) == FloatingPointClass.infinite);
    assert(classify(-real.infinity) == FloatingPointClass.infinite);
 }
@nogc nothrow pure @safe unittest
 {
    static if (ieeePrecision!float == IEEEPrecision.doubleExtended)
    {
        assert(classify(1.68105e-10) == FloatingPointClass.normal);
        assert(classify(1.68105e-4932L) == FloatingPointClass.subnormal);
        // Emulate unnormals, because they aren't generated anymore since i386
        FloatBits!real unnormal;
        unnormal.exp = 0x123;
        unnormal.mantissa = 0x1;
        assert(classify(unnormal) == FloatingPointClass.subnormal);
    }
 }
 /**
 * Determines whether $(D_PARAM x) is a finite number.
 *
 * Params:
 *  F = Type of the floating point number.
 *  x = Floating point number.
 *
 * Returns: $(D_KEYWORD true) if $(D_PARAM x) is a finite number,
 *          $(D_KEYWORD false) otherwise.
 *
 * See_Also: $(D_PSYMBOL isInfinity).
 */
 bool isFinite(F)(F x)
 if (isFloatingPoint!F)
 {
    FloatBits!F bits;
    static if (ieeePrecision!F == IEEEPrecision.single
            || ieeePrecision!F == IEEEPrecision.double_)
    {
        bits.floating = x;
        bits.integral &= bits.expMask;
        return bits.integral != bits.expMask;
    }
    else static if (ieeePrecision!F == IEEEPrecision.doubleExtended)
    {
        bits.floating = abs(x);
        return (bits.exp != bits.expMask)
            && (bits.exp == 0 || bits.mantissa >= (1L << 63));
    }
 }
 ///
@nogc nothrow pure @safe unittest
 {
    assert(!isFinite(float.infinity));
    assert(!isFinite(-double.infinity));
    assert(isFinite(0.0));
    assert(!isFinite(float.nan));
    assert(isFinite(5.87747e-38f / 10));
    assert(isFinite(1.11254e-307 / 10));
    assert(isFinite(0.5));
 }
 /**
 * Determines whether $(D_PARAM x) is $(B n)ot $(B a) $(B n)umber (NaN).
 *
 * Params:
 *  F = Type of the floating point number.
 *  x = Floating point number.
 *
 * Returns: $(D_KEYWORD true) if $(D_PARAM x) is not a number,
 *          $(D_KEYWORD false) otherwise.
 */
 bool isNaN(F)(F x)
 if (isFloatingPoint!F)
 {
    FloatBits!F bits;
    bits.floating = abs(x);
    static if (ieeePrecision!F == IEEEPrecision.single
            || ieeePrecision!F == IEEEPrecision.double_)
    {
        return bits.integral > bits.expMask;
    }
    else static if (ieeePrecision!F == IEEEPrecision.doubleExtended)
    {
        const maskedMantissa = bits.mantissa & bits.mantissaMask;
        if ((bits.exp == bits.expMask && maskedMantissa != 0)
         || ((bits.exp != 0) && (bits.mantissa < (1L << 63))))
        {
            return true;
        }
        return false;
    }
 }
 ///
@nogc nothrow pure @safe unittest
 {
    assert(isNaN(float.init));
    assert(isNaN(double.init));
    assert(isNaN(real.init));
 }
 /**
 * Determines whether $(D_PARAM x) is a positive or negative infinity.
 *
 * Params:
 *  F = Type of the floating point number.
 *  x = Floating point number.
 *
 * Returns: $(D_KEYWORD true) if $(D_PARAM x) is infinity, $(D_KEYWORD false)
 *          otherwise.
 *
 * See_Also: $(D_PSYMBOL isFinite).
 */
 bool isInfinity(F)(F x)
 if (isFloatingPoint!F)
 {
    FloatBits!F bits;
    bits.floating = abs(x);
    static if (ieeePrecision!F == IEEEPrecision.single
            || ieeePrecision!F == IEEEPrecision.double_)
    {
        return bits.integral == bits.expMask;
    }
    else static if (ieeePrecision!F == IEEEPrecision.doubleExtended)
    {
        return (bits.exp == bits.expMask)
            && ((bits.mantissa & bits.mantissaMask) == 0);
    }
 }
 ///
@nogc nothrow pure @safe unittest
 {
    assert(isInfinity(float.infinity));
    assert(isInfinity(-float.infinity));
    assert(isInfinity(double.infinity));
    assert(isInfinity(-double.infinity));
    assert(isInfinity(real.infinity));
    assert(isInfinity(-real.infinity));
 }
 /**
 * Determines whether $(D_PARAM x) is a denormilized number or not.
 *
 * Denormalized number is a number between `0` and `1` that cannot be
 * represented as
 *
 * <pre>
 * m*2<sup>e</sup>
 * </pre>
 *
 * where $(I m) is the mantissa and $(I e) is an exponent that fits into the
 * exponent field of the type $(D_PARAM F).
 *
 * `0` is neither normalized nor denormalized.
 *
 * Params:
 *  F = Type of the floating point number.
 *  x = Floating point number.
 *
 * Returns: $(D_KEYWORD true) if $(D_PARAM x) is a denormilized number,
 *          $(D_KEYWORD false) otherwise.
 *
 * See_Also: $(D_PSYMBOL isNormal).
 */
 bool isSubnormal(F)(F x)
 if (isFloatingPoint!F)
 {
    FloatBits!F bits;
    bits.floating = abs(x);
    static if (ieeePrecision!F == IEEEPrecision.single)
    {
        return bits.integral < (1 << 23) && bits.integral > 0;
    }
    else static if (ieeePrecision!F == IEEEPrecision.double_)
    {
        return bits.integral < (1L << 52) && bits.integral > 0;
    }
    else static if (ieeePrecision!F == IEEEPrecision.doubleExtended)
    {
        return bits.exp == 0 && bits.mantissa != 0;
    }
 }
 ///
@nogc nothrow pure @safe unittest
 {
    assert(!isSubnormal(0.0f));
    assert(!isSubnormal(float.nan));
    assert(!isSubnormal(float.infinity));
    assert(!isSubnormal(0.3f));
    assert(isSubnormal(5.87747e-38f / 10));
    assert(!isSubnormal(0.0));
    assert(!isSubnormal(double.nan));
    assert(!isSubnormal(double.infinity));
    assert(!isSubnormal(1.4));
    assert(isSubnormal(1.11254e-307 / 10));
    assert(!isSubnormal(0.0L));
    assert(!isSubnormal(real.nan));
    assert(!isSubnormal(real.infinity));
 }
 /**
 * Determines whether $(D_PARAM x) is a normilized number or not.
 *
 * Normalized number is a number that can be represented as
 *
 * <pre>
 * m*2<sup>e</sup>
 * </pre>
 *
 * where $(I m) is the mantissa and $(I e) is an exponent that fits into the
 * exponent field of the type $(D_PARAM F).
 *
 * `0` is neither normalized nor denormalized.
 *
 * Params:
 *  F = Type of the floating point number.
 *  x = Floating point number.
 *
 * Returns: $(D_KEYWORD true) if $(D_PARAM x) is a normilized number,
 *          $(D_KEYWORD false) otherwise.
 *
 * See_Also: $(D_PSYMBOL isSubnormal).
 */
 bool isNormal(F)(F x)
 if (isFloatingPoint!F)
 {
    static if (ieeePrecision!F == IEEEPrecision.single
            || ieeePrecision!F == IEEEPrecision.double_)
    {
        FloatBits!F bits;
        bits.floating = x;
        bits.integral &= bits.expMask;
        return bits.integral != 0 && bits.integral != bits.expMask;
    }
    else static if (ieeePrecision!F == IEEEPrecision.doubleExtended)
    {
        return classify(x) == FloatingPointClass.normal;
    }
 }
 ///
@nogc nothrow pure @safe unittest
 {
    assert(!isNormal(0.0f));
    assert(!isNormal(float.nan));
    assert(!isNormal(float.infinity));
    assert(isNormal(0.3f));
    assert(!isNormal(5.87747e-38f / 10));
    assert(!isNormal(0.0));
    assert(!isNormal(double.nan));
    assert(!isNormal(double.infinity));
    assert(isNormal(1.4));
    assert(!isNormal(1.11254e-307 / 10));
    assert(!isNormal(0.0L));
    assert(!isNormal(real.nan));
    assert(!isNormal(real.infinity));
 }
 /**
 * Determines whether the sign bit of $(D_PARAM x) is set or not.
 *
 * If the sign bit, $(D_PARAM x) is a negative number, otherwise positive.
 *
 * Params:
 *  F = Type of the floating point number.
 *  x = Floating point number.
 *
 * Returns: $(D_KEYWORD true) if the sign bit of $(D_PARAM x) is set,
 *          $(D_KEYWORD false) otherwise.
 */
 bool signBit(F)(F x)
 if (isFloatingPoint!F)
 {
    FloatBits!F bits;
    bits.floating = x;
    static if (ieeePrecision!F == IEEEPrecision.single)
    {
        return (bits.integral & (1 << 31)) != 0;
    }
    else static if (ieeePrecision!F == IEEEPrecision.double_)
    {
        return (bits.integral & (1L << 63)) != 0;
    }
    else static if (ieeePrecision!F == IEEEPrecision.doubleExtended)
    {
        return (bits.exp & (1 << 15)) != 0;
    }
 }
 ///
@nogc nothrow pure @safe unittest
 {
    assert(signBit(-1.0f));
    assert(!signBit(1.0f));
    assert(signBit(-1.0));
    assert(!signBit(1.0));
    assert(signBit(-1.0L));
    assert(!signBit(1.0L));
 }
 /**
@ -26,12 +568,12 @@ version (unittest)
 * is used to allocate the result.
 *
 * Params:
- * 	I = Base type.
+ *  I = Base type.
- * 	G = Exponent type.
+ *  G = Exponent type.
- * 	H = Divisor type:
+ *  H = Divisor type:
- * 	x = Base.
+ *  x = Base.
- * 	y = Exponent.
+ *  y = Exponent.
- * 	z = Divisor.
+ *  z = Divisor.
 *
 * Returns: Reminder of the division of $(D_PARAM x) to the power $(D_PARAM y)
 *          by $(D_PARAM z).
@ -39,134 +581,161 @@ version (unittest)
 * Precondition: $(D_INLINECODE z > 0)
 */
 H pow(I, G, H)(in auto ref I x, in auto ref G y, in auto ref H z)
-	if (isIntegral!I && isIntegral!G && isIntegral!H)
+if (isIntegral!I && isIntegral!G && isIntegral!H)
 in
 {
-	assert(z > 0, "Division by zero.");
+    assert(z > 0, "Division by zero.");
 }
-body
+do
 {
-	G mask = G.max / 2 + 1;
+    G mask = G.max / 2 + 1;
-	H result;
+    H result;
-	if (y == 0)
+    if (y == 0)
-	{
+    {
-		return 1 % z;
+        return 1 % z;
-	}
+    }
-	else if (y == 1)
+    else if (y == 1)
-	{
+    {
-		return x % z;
+        return x % z;
-	}
+    }
-	do
+    do
-	{
+    {
-		immutable bit = y & mask;
+        immutable bit = y & mask;
-		if (!result && bit)
+        if (!result && bit)
-		{
+        {
-			result = x;
+            result = x;
-			continue;
+            continue;
-		}
+        }
-		result *= result;
+        result *= result;
-		if (bit)
+        if (bit)
-		{
+        {
-			result *= x;
+            result *= x;
-		}
+        }
-		result %= z;
+        result %= z;
-	}
+    }
-	while (mask >>= 1);
+    while (mask >>= 1);
-	return result;
+    return result;
 }
-/// Ditto.
+/// ditto
-I pow(I)(in auto ref I x, in auto ref I y, in auto ref I z)
+I pow(I)(const auto ref I x, const auto ref I y, const auto ref I z)
-	if (is(I == Integer))
+if (is(I == Integer))
 in
 {
-	assert(z.length > 0, "Division by zero.");
+    assert(z.length > 0, "Division by zero.");
 }
-body
+do
 {
-	size_t i = y.length;
+    size_t i;
-	auto tmp2 = Integer(x.allocator), tmp1 = Integer(x, x.allocator);
+    auto tmp1 = Integer(x, x.allocator);
-	Integer result = Integer(x.allocator);
+    auto result = Integer(x.allocator);
-	if (x.length == 0 && i != 0)
+    if (x.size == 0 && y.size != 0)
-	{
+    {
-		i = 0;
+        i = y.size;
-	}
+    }
-	else
+    else
-	{
+    {
-		result = 1;
+        result = 1;
-	}
+    }
-	while (i)
+    while (i < y.size)
-	{
+    {
-		--i;
+        for (uint mask = 0x01; mask != 0x10000000; mask <<= 1)
-		for (ubyte mask = 0x01; mask; mask <<= 1)
+        {
-		{
+            if (y.rep[i] & mask)
-			if (y.rep[i] & mask)
+            {
-			{
+                result *= tmp1;
-				result *= tmp1;
+                result %= z;
-				result %= z;
+            }
-			}
+            auto tmp2 = tmp1;
-			tmp2 = tmp1;
+            tmp1 *= tmp2;
-			tmp1 *= tmp2;
+            tmp1 %= z;
-			tmp1 %= z;
+        }
-		}
+        ++i;
-	}
+    }
-	return result;
+    return result;
 }
 ///
-pure nothrow @safe @nogc unittest
+@nogc nothrow pure @safe unittest
 {
-	assert(pow(3, 5, 7) == 5);
+    assert(pow(3, 5, 7) == 5);
-	assert(pow(2, 2, 1) == 0);
+    assert(pow(2, 2, 1) == 0);
-	assert(pow(3, 3, 3) == 0);
+    assert(pow(3, 3, 3) == 0);
-	assert(pow(7, 4, 2) == 1);
+    assert(pow(7, 4, 2) == 1);
-	assert(pow(53, 0, 2) == 1);
+    assert(pow(53, 0, 2) == 1);
-	assert(pow(53, 1, 3) == 2);
+    assert(pow(53, 1, 3) == 2);
-	assert(pow(53, 2, 5) == 4);
+    assert(pow(53, 2, 5) == 4);
-	assert(pow(0, 0, 5) == 1);
+    assert(pow(0, 0, 5) == 1);
-	assert(pow(0, 5, 5) == 0);
+    assert(pow(0, 5, 5) == 0);
 }
 ///
-unittest
+@nogc nothrow pure @safe unittest
 {
-	assert(cast(long) pow(Integer(3), Integer(5), Integer(7)) == 5);
+    assert(pow(Integer(3), Integer(5), Integer(7)) == 5);
-	assert(cast(long) pow(Integer(2), Integer(2), Integer(1)) == 0);
+    assert(pow(Integer(2), Integer(2), Integer(1)) == 0);
-	assert(cast(long) pow(Integer(3), Integer(3), Integer(3)) == 0);
+    assert(pow(Integer(3), Integer(3), Integer(3)) == 0);
-	assert(cast(long) pow(Integer(7), Integer(4), Integer(2)) == 1);
+    assert(pow(Integer(7), Integer(4), Integer(2)) == 1);
-	assert(cast(long) pow(Integer(53), Integer(0), Integer(2)) == 1);
+    assert(pow(Integer(53), Integer(0), Integer(2)) == 1);
-	assert(cast(long) pow(Integer(53), Integer(1), Integer(3)) == 2);
+    assert(pow(Integer(53), Integer(1), Integer(3)) == 2);
-	assert(cast(long) pow(Integer(53), Integer(2), Integer(5)) == 4);
+    assert(pow(Integer(53), Integer(2), Integer(5)) == 4);
-	assert(cast(long) pow(Integer(0), Integer(0), Integer(5)) == 1);
+    assert(pow(Integer(0), Integer(0), Integer(5)) == 1);
-	assert(cast(long) pow(Integer(0), Integer(5), Integer(5)) == 0);
+    assert(pow(Integer(0), Integer(5), Integer(5)) == 0);
 }
 /**
 * Checks if $(D_PARAM x) is a prime.
 *
 * Params:
- * 	x = The number should be checked.
+ *  x = The number should be checked.
 *
 * Returns: $(D_KEYWORD true) if $(D_PARAM x) is a prime number,
 *          $(D_KEYWORD false) otherwise.
 */
-bool isPseudoprime(ulong x) nothrow pure @safe @nogc
+bool isPseudoprime(ulong x) @nogc nothrow pure @safe
 {
-	return pow(2, x - 1, x) == 1;
+    return pow(2, x - 1, x) == 1;
 }
 ///
-unittest
+@nogc nothrow pure @safe unittest
 {
-	uint[30] known = [74623, 74653, 74687, 74699, 74707, 74713, 74717, 74719,
+    assert(74623.isPseudoprime);
-	                  74843, 74747, 74759, 74761, 74771, 74779, 74797, 74821,
+    assert(104729.isPseudoprime);
-	                  74827, 9973, 104729, 15485867, 49979693, 104395303,
+    assert(15485867.isPseudoprime);
-	                  593441861, 104729, 15485867, 49979693, 104395303,
+    assert(!15485868.isPseudoprime);
-	                  593441861, 899809363, 982451653];
+}
-
+
-	known.each!((ref x) => assert(isPseudoprime(x)));
+@nogc nothrow pure @safe unittest
 {
    assert(74653.isPseudoprime);
    assert(74687.isPseudoprime);
    assert(74699.isPseudoprime);
    assert(74707.isPseudoprime);
    assert(74713.isPseudoprime);
    assert(74717.isPseudoprime);
    assert(74719.isPseudoprime);
    assert(74747.isPseudoprime);
    assert(74759.isPseudoprime);
    assert(74761.isPseudoprime);
    assert(74771.isPseudoprime);
    assert(74779.isPseudoprime);
    assert(74797.isPseudoprime);
    assert(74821.isPseudoprime);
    assert(74827.isPseudoprime);
    assert(9973.isPseudoprime);
    assert(49979693.isPseudoprime);
    assert(104395303.isPseudoprime);
    assert(593441861.isPseudoprime);
    assert(104729.isPseudoprime);
    assert(15485867.isPseudoprime);
    assert(49979693.isPseudoprime);
    assert(104395303.isPseudoprime);
    assert(593441861.isPseudoprime);
    assert(899809363.isPseudoprime);
    assert(982451653.isPseudoprime);
 }
--- a/source/tanya/math/random.d
+++ b/source/tanya/math/random.d
@ -5,11 +5,13 @@
 /**
 * Random number generator.
 *
- * Copyright: Eugene Wissner 2016.
+ * Copyright: Eugene Wissner 2016-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
- * Authors: $(LINK2 mailto:belka@caraus.de, Eugene Wissner)
+ * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
- */  
+ * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/math/random.d,
 *                 tanya/math/random.d)
 */
 module tanya.math.random;
 import std.digest.sha;
@ -27,20 +29,20 @@ enum maxGather = 128;
 */
 class EntropyException : Exception
 {
-	/**
+    /**
-	 * Params:
+     * Params:
-	 * 	msg  = Message to output.
+     *  msg  = Message to output.
-	 * 	file = The file where the exception occurred.
+     *  file = The file where the exception occurred.
-	 * 	line = The line number where the exception occurred.
+     *  line = The line number where the exception occurred.
-	 * 	next = The previous exception in the chain of exceptions, if any.
+     *  next = The previous exception in the chain of exceptions, if any.
-	 */
+     */
-	this(string msg,
+    this(string msg,
-	     string file = __FILE__,
+         string file = __FILE__,
-	     size_t line = __LINE__,
+         size_t line = __LINE__,
-	     Throwable next = null) pure @safe nothrow const @nogc
+         Throwable next = null) pure @safe nothrow const @nogc
-	{
+    {
-		super(msg, file, line, next);
+        super(msg, file, line, next);
-	}
+    }
 }
 /**
@ -48,103 +50,302 @@ class EntropyException : Exception
 */
 abstract class EntropySource
 {
-	/// Amount of already generated entropy.
+    /// Amount of already generated entropy.
-	protected ushort size_;
+    protected ushort size_;
-	/**
+    /**
-	 * Returns: Minimum bytes required from the entropy source.
+     * Returns: Minimum bytes required from the entropy source.
-	 */
+     */
-	@property immutable(ubyte) threshold() const @safe pure nothrow;
+    @property ubyte threshold() const pure nothrow @safe @nogc;
-	/**
+    /**
-	 * Returns: Whether this entropy source is strong.
+     * Returns: Whether this entropy source is strong.
-	 */
+     */
-	@property immutable(bool) strong() const @safe pure nothrow;
+    @property bool strong() const pure nothrow @safe @nogc;
-	/**
+    /**
-	 * Returns: Amount of already generated entropy.
+     * Returns: Amount of already generated entropy.
-	 */
+     */
-	@property ushort size() const @safe pure nothrow
+    @property ushort size() const pure nothrow @safe @nogc
-	{
+    {
-		return size_;
+        return size_;
-	}
+    }
-	/**
+    /**
-	 * Params:
+     * Params:
-	 * 	size = Amount of already generated entropy. Cannot be smaller than the
+     *  size = Amount of already generated entropy. Cannot be smaller than the
-	 * 	       already set value.
+     *         already set value.
-	 */
+     */
-	@property void size(ushort size) @safe pure nothrow
+    @property void size(ushort size) pure nothrow @safe @nogc
-	{
+    {
-		size_ = size;
+        size_ = size;
-	}
+    }
-	/**
+    /**
-	 * Poll the entropy source.
+     * Poll the entropy source.
-	 *
+     *
-	 * Params:
+     * Params:
-	 * 	output = Buffer to save the generate random sequence (the method will
+     *  output = Buffer to save the generate random sequence (the method will
-	 * 	         to fill the buffer).
+     *           to fill the buffer).
-	 *
+     *
-	 * Returns: Number of bytes that were copied to the $(D_PARAM output)
+     * Returns: Number of bytes that were copied to the $(D_PARAM output)
-	 *          or $(D_PSYMBOL Nullable!ubyte.init) on error.
+     *          or $(D_PSYMBOL Nullable!ubyte.init) on error.
-	 */
+     */
-	Nullable!ubyte poll(out ubyte[maxGather] output);
+    Nullable!ubyte poll(out ubyte[maxGather] output) @nogc;
 }
 version (CRuntime_Bionic)
 {
    version = SecureARC4Random;
 }
 else version (OSX)
 {
    version = SecureARC4Random;
 }
 else version (OpenBSD)
 {
    version = SecureARC4Random;
 }
 else version (NetBSD)
 {
    version = SecureARC4Random;
 }
 else version (Solaris)
 {
    version = SecureARC4Random;
 }
 version (linux)
 {
-	extern (C) long syscall(long number, ...) nothrow;
+    import core.stdc.config : c_long;
    extern (C) c_long syscall(c_long number, ...) nothrow @system @nogc;
-	/**
+    /**
-	 * Uses getrandom system call.
+     * Uses getrandom system call.
-	 */
+     */
-	class PlatformEntropySource : EntropySource
+    class PlatformEntropySource : EntropySource
-	{
+    {
-		/**
+        /**
-		 * Returns: Minimum bytes required from the entropy source.
+         * Returns: Minimum bytes required from the entropy source.
-		 */
+         */
-		override @property immutable(ubyte) threshold() const @safe pure nothrow
+        override @property ubyte threshold() const pure nothrow @safe @nogc
-		{
+        {
-			return 32;
+            return 32;
-		}
+        }
-		/**
+        /**
-		 * Returns: Whether this entropy source is strong.
+         * Returns: Whether this entropy source is strong.
-		 */
+         */
-		override @property immutable(bool) strong() const @safe pure nothrow
+        override @property bool strong() const pure nothrow @safe @nogc
-		{
+        {
-			return true;
+            return true;
-		}
+        }
-		/**
+        /**
-		 * Poll the entropy source.
+         * Poll the entropy source.
-		 *
+         *
-		 * Params:
+         * Params:
-		 * 	output = Buffer to save the generate random sequence (the method will
+         *  output = Buffer to save the generate random sequence (the method will
-		 * 	         to fill the buffer).
+         *           to fill the buffer).
-		 *
+         *
-		 * Returns: Number of bytes that were copied to the $(D_PARAM output)
+         * Returns: Number of bytes that were copied to the $(D_PARAM output)
-		 *          or $(D_PSYMBOL Nullable!ubyte.init) on error.
+         *          or $(D_PSYMBOL Nullable!ubyte.init) on error.
-		 */
+         */
-		override Nullable!ubyte poll(out ubyte[maxGather] output) nothrow
+        override Nullable!ubyte poll(out ubyte[maxGather] output) nothrow @nogc
-		out (length)
+        out (length)
-		{
+        {
-			assert(length <= maxGather);
+            assert(length <= maxGather);
-		}
+        }
-		body
+        do
-		{
+        {
-			// int getrandom(void *buf, size_t buflen, unsigned int flags);
+            // int getrandom(void *buf, size_t buflen, unsigned int flags);
-			auto length = syscall(318, output.ptr, output.length, 0);
+            import mir.linux._asm.unistd : NR_getrandom;
-			Nullable!ubyte ret;
+            auto length = syscall(NR_getrandom, output.ptr, output.length, 0);
            Nullable!ubyte ret;
-			if (length >= 0)
+            if (length >= 0)
-			{
+            {
-				ret = cast(ubyte) length;
+                ret = cast(ubyte) length;
-			}
+            }
-			return ret;
+            return ret;
-		}
+        }
-	}
+    }
    @nogc @system unittest
    {
        auto entropy = defaultAllocator.make!Entropy();
        ubyte[blockSize] output;
        output = entropy.random;
        defaultAllocator.dispose(entropy);
    }
 }
 else version (SecureARC4Random)
 {
    private extern (C) void arc4random_buf(scope void* buf, size_t nbytes) nothrow @nogc @system;
    /**
     * Uses arc4random_buf.
     */
    class PlatformEntropySource : EntropySource
    {
        /**
         * Returns: Minimum bytes required from the entropy source.
         */
        override @property ubyte threshold() const pure nothrow @safe @nogc
        {
            return 32;
        }
        /**
         * Returns: Whether this entropy source is strong.
         */
        override @property bool strong() const pure nothrow @safe @nogc
        {
            return true;
        }
        /**
         * Poll the entropy source.
         *
         * Params:
         *  output = Buffer to save the generate random sequence (the method will
         *           to fill the buffer).
         *
         * Returns: Number of bytes that were copied to the $(D_PARAM output)
         *          or $(D_PSYMBOL Nullable!ubyte.init) on error.
         */
        override Nullable!ubyte poll(out ubyte[maxGather] output) nothrow @nogc @safe
        {
            (() @trusted => arc4random_buf(output.ptr, output.length))();
            return Nullable!ubyte(cast(ubyte) (output.length));
        }
    }
    @nogc @system unittest
    {
        auto entropy = defaultAllocator.make!Entropy();
        ubyte[blockSize] output;
        output = entropy.random;
        defaultAllocator.dispose(entropy);
    }
 }
 else version (Windows)
 {
    import core.sys.windows.basetsd : ULONG_PTR;
    import core.sys.windows.winbase : GetLastError;
    import core.sys.windows.wincrypt;
    import core.sys.windows.windef : BOOL, DWORD, PBYTE;
    import core.sys.windows.winerror : NTE_BAD_KEYSET;
    import core.sys.windows.winnt : LPCSTR, LPCWSTR;
    private extern(Windows) @nogc nothrow
    {
        BOOL CryptGenRandom(HCRYPTPROV, DWORD, PBYTE);
        BOOL CryptAcquireContextA(HCRYPTPROV*, LPCSTR, LPCSTR, DWORD, DWORD);
        BOOL CryptAcquireContextW(HCRYPTPROV*, LPCWSTR, LPCWSTR, DWORD, DWORD);
        BOOL CryptReleaseContext(HCRYPTPROV, ULONG_PTR);
    }
    private bool initCryptGenRandom(scope ref HCRYPTPROV hProvider) @nogc nothrow @trusted
    {
        // https://msdn.microsoft.com/en-us/library/windows/desktop/aa379886(v=vs.85).aspx
        // For performance reasons, we recommend that you set the pszContainer
        // parameter to NULL and the dwFlags parameter to CRYPT_VERIFYCONTEXT
        // in all situations where you do not require a persisted key.
        // CRYPT_SILENT is intended for use with applications for which the UI cannot be displayed by the CSP.
        if (!CryptAcquireContextW(&hProvider, null, null, PROV_RSA_FULL, CRYPT_VERIFYCONTEXT | CRYPT_SILENT))
        {
            if (GetLastError() == NTE_BAD_KEYSET)
            {
                // Attempt to create default container
                if (!CryptAcquireContextA(&hProvider, null, null, PROV_RSA_FULL, CRYPT_NEWKEYSET | CRYPT_SILENT))
                    return false;
            }
            else
            {
                return false;
            }
        }
        return true;
    }
    class PlatformEntropySource : EntropySource
    {
        private HCRYPTPROV hProvider;
        /**
         * Uses CryptGenRandom.
         */
        this() @nogc
        {
            if (!initCryptGenRandom(hProvider))
            {
                throw defaultAllocator.make!EntropyException("CryptAcquireContextW failed.");
            }
            assert(hProvider > 0, "hProvider not properly initialized.");
        }
        ~this() @nogc nothrow @safe
        {
            if (hProvider > 0)
            {
                (() @trusted => CryptReleaseContext(hProvider, 0))();
            }
        }
        /**
         * Returns: Minimum bytes required from the entropy source.
         */
        override @property ubyte threshold() const pure nothrow @safe @nogc
        {
            return 32;
        }
        /**
         * Returns: Whether this entropy source is strong.
         */
        override @property bool strong() const pure nothrow @safe @nogc
        {
            return true;
        }
        /**
         * Poll the entropy source.
         *
         * Params:
         *  output = Buffer to save the generate random sequence (the method will
         *           to fill the buffer).
         *
         * Returns: Number of bytes that were copied to the $(D_PARAM output)
         *          or $(D_PSYMBOL Nullable!ubyte.init) on error.
         */
        override Nullable!ubyte poll(out ubyte[maxGather] output) @nogc nothrow @safe
        in
        {
            assert(hProvider > 0, "hProvider not properly initialized.");
        }
        do
        {
            Nullable!ubyte ret;
            if ((() @trusted => CryptGenRandom(hProvider, output.length, cast(PBYTE) output.ptr))())
            {
                ret = cast(ubyte) (output.length);
            }
            return ret;
        }
    }
    @nogc @system unittest
    {
        auto entropy = defaultAllocator.make!Entropy();
        ubyte[blockSize] output;
        output = entropy.random;
        defaultAllocator.dispose(entropy);
    }
 }
 /**
@ -156,165 +357,165 @@ version (linux)
 *
 * output = entropy.random;
 *
- * defaultAllocator.finalize(entropy);
+ * defaultAllocator.dispose(entropy);
 * ---
 */
 class Entropy
 {
-	/// Entropy sources.
+    /// Entropy sources.
-	protected EntropySource[] sources;
+    protected EntropySource[] sources;
-	private ubyte sourceCount_;
+    private ubyte sourceCount_;
-	private shared Allocator allocator;
+    /// Entropy accumulator.
    protected SHA!(maxGather * 8, 512) accumulator;
-	/// Entropy accumulator.
+    /**
-	protected SHA!(maxGather * 8, 512) accumulator;
+     * Params:
     *  maxSources = Maximum amount of entropy sources can be set.
     *  allocator  = Allocator to allocate entropy sources available on the
     *               system.
     */
    this(const size_t maxSources = 20,
         shared Allocator allocator = defaultAllocator) @nogc
    in
    {
        assert(maxSources > 0 && maxSources <= ubyte.max);
        assert(allocator !is null);
    }
    do
    {
        allocator.resize(sources, maxSources);
-	/**
+        static if (is(PlatformEntropySource))
-	 * Params:
+        {
-	 *  maxSources = Maximum amount of entropy sources can be set.
+            this ~= allocator.make!PlatformEntropySource;
-	 * 	allocator  = Allocator to allocate entropy sources available on the
+        }
-	 * 	             system.
+    }
 	 */
 	this(size_t maxSources = 20, shared Allocator allocator = defaultAllocator)
 	in
 	{
 		assert(maxSources > 0 && maxSources <= ubyte.max);
 		assert(allocator !is null);
 	}
 	body
 	{
 		allocator.resizeArray(sources, maxSources);
-		version (linux)
+    /**
-		{
+     * Returns: Amount of the registered entropy sources.
-			this ~= allocator.make!PlatformEntropySource;
+     */
-		}
+    @property ubyte sourceCount() const pure nothrow @safe @nogc
-	}
+    {
        return sourceCount_;
    }
-	/**
+    /**
-	 * Returns: Amount of the registered entropy sources.
+     * Add an entropy source.
-	 */
+     *
-	@property ubyte sourceCount() const @safe pure nothrow
+     * Params:
-	{
+     *  source = Entropy source.
-		return sourceCount_;
+     *
-	}
+     * Returns: $(D_PSYMBOL this).
     *
     * See_Also:
     *  $(D_PSYMBOL EntropySource)
     */
    Entropy opOpAssign(string op)(EntropySource source)
    pure nothrow @safe @nogc
    if (op == "~")
    in
    {
        assert(sourceCount_ <= sources.length);
    }
    do
    {
        sources[sourceCount_++] = source;
        return this;
    }
-	/**
+    /**
-	 * Add an entropy source.
+     * Returns: Generated random sequence.
-	 *
+     *
-	 * Params:
+     * Throws: $(D_PSYMBOL EntropyException) if no strong entropy source was
-	 * 	source = Entropy source.
+     *         registered or it failed.
-	 *
+     */
-	 * Returns: $(D_PSYMBOL this).
+    @property ubyte[blockSize] random() @nogc
-	 *
+    in
-	 * See_Also:
+    {
-	 * 	$(D_PSYMBOL EntropySource)
+        assert(sourceCount_ > 0, "No entropy sources defined.");
-	 */
+    }
-	Entropy opOpAssign(string Op)(EntropySource source) @safe pure nothrow
+    do
-		if (Op == "~")
+    {
-	in
+        bool haveStrong;
-	{
+        ushort done;
-		assert(sourceCount_ <= sources.length);
+        ubyte[blockSize] output;
 	}
 	body
 	{
 		sources[sourceCount_++] = source;
 		return this;
 	}
-	/**
+        do
-	 * Returns: Generated random sequence.
+        {
-	 *
+            ubyte[maxGather] buffer;
 	 * Throws: $(D_PSYMBOL EntropyException) if no strong entropy source was
 	 *         registered or it failed.
 	 */
 	@property ubyte[blockSize] random()
 	in
 	{
 		assert(sourceCount_ > 0, "No entropy sources defined.");
 	}
 	body
 	{
 		bool haveStrong;
 		ushort done;
 		ubyte[blockSize] output;
-		do
+            // Run through our entropy sources
-		{
+            for (ubyte i; i < sourceCount; ++i)
-			ubyte[maxGather] buffer;
+            {
                auto outputLength = sources[i].poll(buffer);
-			// Run through our entropy sources
+                if (!outputLength.isNull)
-			for (ubyte i; i < sourceCount; ++i)
+                {
-			{
+                    if (outputLength > 0)
-				auto outputLength = sources[i].poll(buffer);
+                    {
                        update(i, buffer, outputLength);
                        sources[i].size = cast(ushort) (sources[i].size + outputLength);
                    }
                    if (sources[i].size < sources[i].threshold)
                    {
                        continue;
                    }
                    else if (sources[i].strong)
                    {
                        haveStrong = true;
                    }
                }
                done = 257;
            }
        }
        while (++done < 256);
-				if (!outputLength.isNull)
+        if (!haveStrong)
-				{
+        {
-					if (outputLength > 0)
+            throw defaultAllocator.make!EntropyException("No strong entropy source defined.");
-					{
+        }
 						update(i, buffer, outputLength);
 						sources[i].size = cast(ushort) (sources[i].size + outputLength);
 					}
 					if (sources[i].size < sources[i].threshold)
 					{
 						continue;
 					}
 					else if (sources[i].strong)
 					{
 						haveStrong = true;
 					}
 				}
 				done = 257;
 			}
 		}
 		while (++done < 256);
-		if (!haveStrong)
+        output = accumulator.finish();
 		{
 			throw allocator.make!EntropyException("No strong entropy source defined.");
 		}
-		output = accumulator.finish();
+        // Reset accumulator and counters and recycle existing entropy
        accumulator.start();
-		// Reset accumulator and counters and recycle existing entropy
+        // Perform second SHA-512 on entropy
-		accumulator.start();
+        output = sha512Of(output);
-		// Perform second SHA-512 on entropy
+        for (ubyte i; i < sourceCount; ++i)
-		output = sha512Of(output);
+        {
            sources[i].size = 0;
        }
        return output;
    }
-		for (ubyte i = 0; i < sourceCount; ++i)
+    /**
-		{
+     * Update entropy accumulator.
-			sources[i].size = 0;
+     *
-		}
+     * Params:
-		return output;
+     *  sourceId = Entropy source index in $(D_PSYMBOL sources).
-	}
+     *  data     = Data got from the entropy source.
     *  length   = Length of the received data.
     */
    protected void update(in ubyte sourceId,
                          ref ubyte[maxGather] data,
                          ubyte length) pure nothrow @safe @nogc
    {
        ubyte[2] header;
-	/**
+        if (length > blockSize)
-	 * Update entropy accumulator.
+        {
-	 *
+            data[0 .. 64] = sha512Of(data);
-	 * Params:
+            length = blockSize;
-	 * 	sourceId = Entropy source index in $(D_PSYMBOL sources).
+        }
 	 * 	data     = Data got from the entropy source.
 	 * 	length   = Length of the received data.
 	 */
 	protected void update(in ubyte sourceId,
 	                      ref ubyte[maxGather] data,
 	                      ubyte length) @safe pure nothrow
 	{
 		ubyte[2] header;
-		if (length > blockSize)
+        header[0] = sourceId;
-		{
+        header[1] = length;
 			data[0..64] = sha512Of(data);
 			length = blockSize;
 		}
-		header[0] = sourceId;
+        accumulator.put(header);
-		header[1] = length;
+        accumulator.put(data[0 .. length]);
-
+    }
 		accumulator.put(header);
 		accumulator.put(data[0..length]);
 	}
 }
--- a/source/tanya/memory/allocator.d
+++ b/source/tanya/memory/allocator.d
@ -3,10 +3,17 @@
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
- * Copyright: Eugene Wissner 2016.
+ * This module contains the interface for implementing custom allocators.
 *
 * Allocators are classes encapsulating memory allocation strategy. This allows
 * to decouple memory management from the algorithms and the data. 
 *
 * Copyright: Eugene Wissner 2016-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/memory/allocator.d,
 *                 tanya/memory/allocator.d)
 */
 module tanya.memory.allocator;
@ -15,102 +22,60 @@ module tanya.memory.allocator;
 */
 interface Allocator
 {
-	/**
+    /**
-	 * Returns: Alignment.
+     * Returns: Alignment offered.
-	 */
+     */
-	@property uint alignment() const shared pure nothrow @safe @nogc;
+    @property uint alignment() const shared pure nothrow @safe @nogc;
-	/**
+    /**
-	 * Allocates $(D_PARAM size) bytes of memory.
+     * Allocates $(D_PARAM size) bytes of memory.
-	 *
+     *
-	 * Params:
+     * Params:
-	 * 	size = Amount of memory to allocate.
+     *  size = Amount of memory to allocate.
-	 *
+     *
-	 * Returns: Pointer to the new allocated memory.
+     * Returns: Pointer to the new allocated memory.
-	 */
+     */
-	void[] allocate(size_t size) shared nothrow @nogc;
+    void[] allocate(size_t size) shared pure nothrow @nogc;
-	/**
+    /**
-	 * Deallocates a memory block.
+     * Deallocates a memory block.
-	 *
+     *
-	 * Params:
+     * Params:
-	 * 	p = A pointer to the memory block to be freed.
+     *  p = A pointer to the memory block to be freed.
-	 *
+     *
-	 * Returns: Whether the deallocation was successful.
+     * Returns: Whether the deallocation was successful.
-	 */
+     */
-	bool deallocate(void[] p) shared nothrow @nogc;
+    bool deallocate(void[] p) shared pure nothrow @nogc;
-	/**
+    /**
-	 * Increases or decreases the size of a memory block.
+     * Increases or decreases the size of a memory block.
-	 *
+     *
-	 * Params:
+     * Params:
-	 * 	p    = A pointer to the memory block.
+     *  p    = A pointer to the memory block.
-	 * 	size = Size of the reallocated block.
+     *  size = Size of the reallocated block.
-	 *
+     *
-	 * Returns: Pointer to the allocated memory.
+     * Returns: Pointer to the allocated memory.
-	 */
+     */
-	bool reallocate(ref void[] p, size_t size) shared nothrow @nogc;
+    bool reallocate(ref void[] p, size_t size) shared pure nothrow @nogc;
    /**
     * Reallocates a memory block in place if possible or returns
     * $(D_KEYWORD false). This function cannot be used to allocate or
     * deallocate memory, so if $(D_PARAM p) is $(D_KEYWORD null) or
     * $(D_PARAM size) is `0`, it should return $(D_KEYWORD false).
     *
     * Params:
     *  p    = A pointer to the memory block.
     *  size = Size of the reallocated block.
     *
     * Returns: $(D_KEYWORD true) if successful, $(D_KEYWORD false) otherwise.
     */
    bool reallocateInPlace(ref void[] p, size_t size)
    shared pure nothrow @nogc;
 }
-/**
+package template GetPureInstance(T : Allocator)
 * The mixin generates common methods for classes and structs using
 * allocators. It provides a protected member, constructor and a read-only property,
 * that checks if an allocator was already set and sets it to the default
 * one, if not (useful for structs which don't have a default constructor).
 */
 mixin template DefaultAllocator()
 {
-	/// Allocator.
+    alias GetPureInstance = shared(T) function()
-	protected shared Allocator allocator_;
+                            pure nothrow @nogc;
 	/**
 	 * Params:
 	 * 	allocator = The allocator should be used.
 	 */
 	this(shared Allocator allocator)
 	in
 	{
 		assert(allocator !is null);
 	}
 	body
 	{
 		this.allocator_ = allocator;
 	}
 	/**
 	 * This property checks if the allocator was set in the constructor
 	 * and sets it to the default one, if not.
 	 *
 	 * Returns: Used allocator.
 	 *
 	 * Postcondition: $(D_INLINECODE allocator_ !is null)
 	 */
 	protected @property shared(Allocator) allocator() nothrow @safe @nogc
 	out (allocator)
 	{
 		assert(allocator !is null);
 	}
 	body
 	{
 		if (allocator_ is null)
 		{
 			allocator_ = defaultAllocator;
 		}
 		return allocator_;
 	}
 	/// Ditto.
 	@property shared(Allocator) allocator() const nothrow @trusted @nogc
 	out (allocator)
 	{
 		assert(allocator !is null);
 	}
 	body
 	{
 		if (allocator_ is null)
 		{
 			return defaultAllocator;
 		}
 		return cast(shared Allocator) allocator_;
 	}
 }
--- a/source/tanya/memory/mallocator.d
+++ b/source/tanya/memory/mallocator.d
@ -0,0 +1,232 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * Allocator based on $(D_PSYMBOL malloc), $(D_PSYMBOL realloc) and $(D_PSYMBOL free).
 *
 * Copyright: Eugene Wissner 2017-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/memory/mallocator.d,
 *                 tanya/memory/mallocator.d)
 */
 module tanya.memory.mallocator;
 version (TanyaNative)
 {
 }
 else:
 import core.stdc.stdlib;
 import tanya.memory.allocator;
 /**
 * Wrapper for $(D_PSYMBOL malloc)/$(D_PSYMBOL realloc)/$(D_PSYMBOL free) from
 * the C standard library.
 */
 final class Mallocator : Allocator
 {
    private alias MallocType = extern (C) void* function(size_t)
                               @nogc nothrow pure @system;
    private alias FreeType = extern (C) void function(void*)
                             @nogc nothrow pure @system;
    private alias ReallocType = extern (C) void* function(void*, size_t)
                                @nogc nothrow pure @system;
    /**
     * Allocates $(D_PARAM size) bytes of memory.
     *
     * Params:
     *  size = Amount of memory to allocate.
     *
     * Returns: The pointer to the new allocated memory.
     */
    void[] allocate(size_t size) @nogc nothrow pure shared @system
    {
        if (size == 0)
        {
            return null;
        }
        auto p = (cast(MallocType) &malloc)(size + psize);
        return p is null ? null : p[psize .. psize + size];
    }
    ///
    @nogc nothrow pure @system unittest
    {
        auto p = Mallocator.instance.allocate(20);
        assert(p.length == 20);
        Mallocator.instance.deallocate(p);
        p = Mallocator.instance.allocate(0);
        assert(p.length == 0);
    }
    /**
     * Deallocates a memory block.
     *
     * Params:
     *  p = A pointer to the memory block to be freed.
     *
     * Returns: Whether the deallocation was successful.
     */
    bool deallocate(void[] p) @nogc nothrow pure shared @system
    {
        if (p !is null)
        {
            (cast(FreeType) &free)(p.ptr - psize);
        }
        return true;
    }
    ///
    @nogc nothrow pure @system unittest
    {
        void[] p;
        assert(Mallocator.instance.deallocate(p));
        p = Mallocator.instance.allocate(10);
        assert(Mallocator.instance.deallocate(p));
    }
    /**
     * Reallocating in place isn't supported.
     *
     * Params:
     *  p    = A pointer to the memory block.
     *  size = Size of the reallocated block.
     *
     * Returns: $(D_KEYWORD false).
     */
    bool reallocateInPlace(ref void[] p, size_t size)
    @nogc nothrow pure shared @system
    {
        cast(void) size;
        return false;
    }
    ///
    @nogc nothrow pure @system unittest
    {
        void[] p;
        assert(!Mallocator.instance.reallocateInPlace(p, 8));
    }
    /**
     * Increases or decreases the size of a memory block.
     *
     * Params:
     *  p    = A pointer to the memory block.
     *  size = Size of the reallocated block.
     *
     * Returns: Whether the reallocation was successful.
     */
    bool reallocate(ref void[] p, size_t size)
    @nogc nothrow pure shared @system
    {
        if (size == 0)
        {
            if (deallocate(p))
            {
                p = null;
                return true;
            }
        }
        else if (p is null)
        {
            p = allocate(size);
            return p is null ? false : true;
        }
        else
        {
            auto r = (cast(ReallocType) &realloc)(p.ptr - psize, size + psize);
            if (r !is null)
            {
                p = r[psize .. psize + size];
                return true;
            }
        }
        return false;
    }
    ///
    @nogc nothrow pure @system unittest
    {
        void[] p;
        assert(Mallocator.instance.reallocate(p, 20));
        assert(p.length == 20);
        assert(Mallocator.instance.reallocate(p, 30));
        assert(p.length == 30);
        assert(Mallocator.instance.reallocate(p, 10));
        assert(p.length == 10);
        assert(Mallocator.instance.reallocate(p, 0));
        assert(p is null);
    }
    // Fails with false
    @nogc nothrow pure @system unittest
    {
        void[] p = Mallocator.instance.allocate(20);
        void[] oldP = p;
        assert(!Mallocator.instance.reallocate(p, size_t.max - Mallocator.psize * 2));
        assert(oldP is p);
        Mallocator.instance.deallocate(p);
    }
    /**
     * Returns: The alignment offered.
     */
    @property uint alignment() const @nogc nothrow pure @safe shared
    {
        return (void*).alignof;
    }
    private nothrow @nogc unittest
    {
        assert(Mallocator.instance.alignment == (void*).alignof);
    }
    static private shared(Mallocator) instantiate() @nogc nothrow @system
    {
        if (instance_ is null)
        {
            const size = __traits(classInstanceSize, Mallocator) + psize;
            void* p = malloc(size);
            if (p !is null)
            {
                p[psize .. size] = typeid(Mallocator).initializer[];
                instance_ = cast(shared Mallocator) p[psize .. size].ptr;
            }
        }
        return instance_;
    }
    /**
     * Static allocator instance and initializer.
     *
     * Returns: The global $(D_PSYMBOL Allocator) instance.
     */
    static @property shared(Mallocator) instance() @nogc nothrow pure @system
    {
        return (cast(GetPureInstance!Mallocator) &instantiate)();
    }
    ///
    @nogc nothrow pure @system unittest
    {
        assert(instance is instance);
    }
    private enum ushort psize = 8;
    private shared static Mallocator instance_;
 }
--- a/source/tanya/memory/mmappool.d
+++ b/source/tanya/memory/mmappool.d
--- a/source/tanya/memory/op.d
+++ b/source/tanya/memory/op.d
@ -0,0 +1,375 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * Set of operations on memory blocks.
 *
 * Copyright: Eugene Wissner 2017-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/memory/op.d,
 *                 tanya/memory/op.d)
 */
 module tanya.memory.op;
 version (TanyaNative)
 {
    extern private void fillMemory(void[], size_t) pure nothrow @system @nogc;
    extern private void copyMemory(const void[], void[])
    pure nothrow @system @nogc;
    extern private void moveMemory(const void[], void[])
    pure nothrow @system @nogc;
    extern private int cmpMemory(const void[], const void[])
    pure nothrow @system @nogc;
 }
 else
 {
    import core.stdc.string;
 }
 version (TanyaNative)
 {
    @nogc nothrow pure @system unittest
    {
        ubyte[2] buffer = 1;
        fillMemory(buffer[1 .. $], 0);
        assert(buffer[0] == 1 && buffer[1] == 0);
    }
    @nogc nothrow pure @safe unittest
    {
        assert(cmp(null, null) == 0);
    }
 }
 private enum alignMask = size_t.sizeof - 1;
 /**
 * Copies $(D_PARAM source) into $(D_PARAM target).
 *
 * $(D_PARAM source) and $(D_PARAM target) shall not overlap so that
 * $(D_PARAM source) points ahead of $(D_PARAM target).
 *
 * $(D_PARAM target) shall have enough space for $(D_INLINECODE source.length)
 * elements.
 *
 * Params:
 *  source = Memory to copy from.
 *  target = Destination memory.
 *
 * See_Also: $(D_PSYMBOL copyBackward).
 *
 * Precondition: $(D_INLINECODE source.length <= target.length).
 */
 void copy(const void[] source, void[] target) @nogc nothrow pure @trusted
 in
 {
    assert(source.length <= target.length);
    assert(source.length == 0 || source.ptr !is null);
    assert(target.length == 0 || target.ptr !is null);
 }
 do
 {
    version (TanyaNative)
    {
        copyMemory(source, target);
    }
    else
    {
        memcpy(target.ptr, source.ptr, source.length);
    }
 }
 ///
@nogc nothrow pure @safe unittest
 {
    ubyte[9] source = [1, 2, 3, 4, 5, 6, 7, 8, 9];
    ubyte[9] target;
    source.copy(target);
    assert(cmp(source, target) == 0);
 }
@nogc nothrow pure @safe unittest
 {
    {
        ubyte[0] source, target;
        source.copy(target);
    }
    {
        ubyte[1] source = [1];
        ubyte[1] target;
        source.copy(target);
        assert(target[0] == 1);
    }
    {
        ubyte[8] source = [1, 2, 3, 4, 5, 6, 7, 8];
        ubyte[8] target;
        source.copy(target);
        assert(cmp(source, target) == 0);
    }
 }
 /*
 * size_t value each of which bytes is set to `Byte`.
 */
 private template filledBytes(ubyte Byte, ubyte I = 0)
 {
    static if (I == size_t.sizeof)
    {
        enum size_t filledBytes = Byte;
    }
    else
    {
        enum size_t filledBytes = (filledBytes!(Byte, I + 1) << 8) | Byte;
    }
 }
 /**
 * Fills $(D_PARAM memory) with the single byte $(D_PARAM c).
 *
 * Param:
 *  c      = The value to fill $(D_PARAM memory) with.
 *  memory = Memory block.
 */
 void fill(ubyte c = 0)(void[] memory) @trusted
 in
 {
    assert(memory.length == 0 || memory.ptr !is null);
 }
 do
 {
    version (TanyaNative)
    {
        fillMemory(memory, filledBytes!c);
    }
    else
    {
        memset(memory.ptr, c, memory.length);
    }
 }
 ///
@nogc nothrow pure @safe unittest
 {
    ubyte[9] memory = [1, 2, 3, 4, 5, 6, 7, 8, 9];
    memory.fill!0();
    foreach (ubyte v; memory)
    {
        assert(v == 0);
    }
 }
 /**
 * Copies starting from the end of $(D_PARAM source) into the end of
 * $(D_PARAM target).
 *
 * $(D_PSYMBOL copyBackward) copies the elements in reverse order, but the
 * order of elements in the $(D_PARAM target) is exactly the same as in the
 * $(D_PARAM source).
 *
 * $(D_PARAM source) and $(D_PARAM target) shall not overlap so that
 * $(D_PARAM target) points ahead of $(D_PARAM source).
 *
 * $(D_PARAM target) shall have enough space for $(D_INLINECODE source.length)
 * elements.
 *
 * Params:
 *  source = Memory to copy from.
 *  target = Destination memory.
 *
 * See_Also: $(D_PSYMBOL copy).
 *
 * Precondition: $(D_INLINECODE source.length <= target.length).
 */
 void copyBackward(const void[] source, void[] target) @nogc nothrow pure @trusted
 in
 {
    assert(source.length <= target.length);
    assert(source.length == 0 || source.ptr !is null);
    assert(target.length == 0 || target.ptr !is null);
 }
 do
 {
    version (TanyaNative)
    {
        moveMemory(source, target);
    }
    else
    {
        memmove(target.ptr, source.ptr, source.length);
    }
 }
 ///
@nogc nothrow pure @safe unittest
 {
    ubyte[6] mem = [ 'a', 'a', 'b', 'b', 'c', 'c' ];
    ubyte[6] expected = [ 'a', 'a', 'a', 'a', 'b', 'b' ];
    copyBackward(mem[0 .. 4], mem[2 .. $]);
    assert(cmp(expected, mem) == 0);
 }
@nogc nothrow pure @safe unittest
 {
    ubyte[9] r1 = [ 'a', 'b', 'c', 'd', 'e', 'f', 'g', 'h', 'i' ];
    ubyte[9] r2;
    copyBackward(r1, r2);
    assert(cmp(r1, r2) == 0);
 }
 /**
 * Compares two memory areas $(D_PARAM r1) and $(D_PARAM r2).
 *
 * $(D_PSYMBOL cmp) returns a positive integer if
 * $(D_INLINECODE r1.length > r2.length) or the first `n` compared bytes of
 * $(D_PARAM r1) found to be greater than the first `n` bytes of $(D_PARAM r2),
 *
 * $(D_PSYMBOL cmp) returns a negative integer if
 * $(D_INLINECODE r2.length > r1.length) or the first `n` compared bytes of
 * $(D_PARAM r1) found to be less than the first `n` bytes of $(D_PARAM r2),
 *
 * `0` is returned otherwise.
 *
 * Returns: Positive integer if $(D_INLINECODE r1 > r2),
 *          negative integer if $(D_INLINECODE r2 > r1),
 *          `0` if $(D_INLINECODE r1 == r2).
 */
 int cmp(const void[] r1, const void[] r2) @nogc nothrow pure @trusted
 in
 {
    assert(r1.length == 0 || r1.ptr !is null);
    assert(r2.length == 0 || r2.ptr !is null);
 }
 do
 {
    version (TanyaNative)
    {
        return cmpMemory(r1, r2);
    }
    else
    {
        if (r1.length > r2.length)
        {
            return 1;
        }
        return r1.length < r2.length ? -1 : memcmp(r1.ptr, r2.ptr, r1.length);
    }
 }
 ///
@nogc nothrow pure @safe unittest
 {
    ubyte[4] r1 = [ 'a', 'b', 'c', 'd' ];
    ubyte[3] r2 = [ 'c', 'a', 'b' ];
    assert(cmp(r1[0 .. 3], r2[]) < 0);
    assert(cmp(r2[], r1[0 .. 3]) > 0);
    assert(cmp(r1, r2) > 0);
    assert(cmp(r2, r1) < 0);
 }
@nogc nothrow pure @safe unittest
 {
    ubyte[16] r1 = [
        'a', 'b', 'c', 'd', 'e', 'f', 'g', 'h',
        'i', 'j', 'k', 'l', 'm', 'n', 'o', 'p',
    ];
    ubyte[16] r2 = [
        'a', 'b', 'c', 'd', 'e', 'f', 'g', 'h',
        'i', 'j', 'k', 'l', 'm', 'n', 'o', 'p',
    ];
    assert(cmp(r1, r2) == 0);
    assert(cmp(r1[1 .. $], r2[1 .. $]) == 0);
    assert(cmp(r1[0 .. $ - 1], r2[0 .. $ - 1]) == 0);
    assert(cmp(r1[0 .. 8], r2[0 .. 8]) == 0);
 }
 /**
 * Finds the first occurrence of $(D_PARAM needle) in $(D_PARAM haystack) if
 * any.
 *
 * Params:
 *  haystack = Memory block.
 *  needle   = A byte.
 *
 * Returns: The subrange of $(D_PARAM haystack) whose first element is the
 *          first occurrence of $(D_PARAM needle). If $(D_PARAM needle)
 *          couldn't be found, an empty `inout void[]` is returned.
 */
 inout(void[]) find(return inout void[] haystack, const ubyte needle)
@nogc nothrow pure @trusted
 in
 {
    assert(haystack.length == 0 || haystack.ptr !is null);
 }
 do
 {
    auto length = haystack.length;
    const size_t needleWord = size_t.max * needle;
    enum size_t highBits = filledBytes!(0x01, 0);
    enum size_t mask = filledBytes!(0x80, 0);
    // Align
    auto bytes = cast(inout(ubyte)*) haystack;
    while (length > 0 && ((cast(size_t) bytes) & 3) != 0)
    {
        if (*bytes == needle)
        {
            return bytes[0 .. length];
        }
        bytes++;
        length--;
    }
    // Check if some of the words has the needle
    auto words = cast(inout(size_t)*) bytes;
    while (length >= size_t.sizeof)
    {
        if (((*words ^ needleWord) - highBits) & (~*words) & mask)
        {
            break;
        }
        words++;
        length -= size_t.sizeof;
    }
    // Find the exact needle position in the word
    bytes = cast(inout(ubyte)*) words;
    while (length > 0)
    {
        if (*bytes == needle)
        {
            return bytes[0 .. length];
        }
        bytes++;
        length--;
    }
    return haystack[$ .. $];
 }
 ///
@nogc nothrow pure @safe unittest
 {
    const ubyte[9] haystack = ['a', 'b', 'c', 'd', 'e', 'f', 'b', 'g', 'h'];
    assert(find(haystack, 'a') == haystack[]);
    assert(find(haystack, 'b') == haystack[1 .. $]);
    assert(find(haystack, 'c') == haystack[2 .. $]);
    assert(find(haystack, 'd') == haystack[3 .. $]);
    assert(find(haystack, 'e') == haystack[4 .. $]);
    assert(find(haystack, 'f') == haystack[5 .. $]);
    assert(find(haystack, 'h') == haystack[8 .. $]);
    assert(find(haystack, 'i').length == 0);
    assert(find(null, 'a').length == 0);
 }
--- a/source/tanya/memory/package.d
+++ b/source/tanya/memory/package.d
@ -3,140 +3,352 @@
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
- * Copyright: Eugene Wissner 2016.
+ * Dynamic memory management.
 *
 * Copyright: Eugene Wissner 2016-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/memory/package.d,
 *                 tanya/memory/package.d)
 */
 module tanya.memory;
-import core.exception;
+import std.algorithm.mutation;
-public import std.experimental.allocator : make, makeArray;
+import tanya.conv;
-import std.traits;
+import tanya.exception;
 public import tanya.memory.allocator;
-public import tanya.memory.types;
+import tanya.meta.trait;
 import tanya.range.primitive;
 /**
 * The mixin generates common methods for classes and structs using
 * allocators. It provides a protected member, constructor and a read-only property,
 * that checks if an allocator was already set and sets it to the default
 * one, if not (useful for structs which don't have a default constructor).
 */
 mixin template DefaultAllocator()
 {
    /// Allocator.
    protected shared Allocator allocator_;
    /**
     * Params:
     *  allocator = The allocator should be used.
     *
     * Precondition: $(D_INLINECODE allocator_ !is null)
     */
    this(shared Allocator allocator) @nogc nothrow pure @safe
    in
    {
        assert(allocator !is null);
    }
    do
    {
        this.allocator_ = allocator;
    }
    /**
     * This property checks if the allocator was set in the constructor
     * and sets it to the default one, if not.
     *
     * Returns: Used allocator.
     *
     * Postcondition: $(D_INLINECODE allocator !is null)
     */
    @property shared(Allocator) allocator() @nogc nothrow pure @safe
    out (allocator)
    {
        assert(allocator !is null);
    }
    do
    {
        if (allocator_ is null)
        {
            allocator_ = defaultAllocator;
        }
        return allocator_;
    }
    /// ditto
    @property shared(Allocator) allocator() const @nogc nothrow pure @trusted
    out (allocator)
    {
        assert(allocator !is null);
    }
    do
    {
        if (allocator_ is null)
        {
            return defaultAllocator;
        }
        return cast(shared Allocator) allocator_;
    }
 }
 // From druntime
-private extern (C) void _d_monitordelete(Object h, bool det) nothrow @nogc;
+extern (C)
 private void _d_monitordelete(Object h, bool det) @nogc nothrow pure;
 shared Allocator allocator;
-shared static this() nothrow @trusted @nogc
+private shared(Allocator) getAllocatorInstance() @nogc nothrow
 {
-	import tanya.memory.mmappool;
+    if (allocator is null)
-	allocator = MmapPool.instance;
+    {
        version (TanyaNative)
        {
            import tanya.memory.mmappool;
            defaultAllocator = MmapPool.instance;
        }
        else
        {
            import tanya.memory.mallocator;
            defaultAllocator = Mallocator.instance;
        }
    }
    return allocator;
 }
-@property ref shared(Allocator) defaultAllocator() nothrow @safe @nogc
+/**
 * Returns: Default allocator.
 *
 * Postcondition: $(D_INLINECODE allocator !is null).
 */
@property shared(Allocator) defaultAllocator() @nogc nothrow pure @trusted
 out (allocator)
 {
-	return allocator;
+    assert(allocator !is null);
 }
 do
 {
    return (cast(GetPureInstance!Allocator) &getAllocatorInstance)();
 }
-@property void defaultAllocator(shared(Allocator) allocator) nothrow @safe @nogc
+/**
 * Sets the default allocator.
 *
 * Params:
 *  allocator = $(D_PSYMBOL Allocator) instance.
 *
 * Precondition: $(D_INLINECODE allocator !is null).
 */
@property void defaultAllocator(shared(Allocator) allocator) @nogc nothrow @safe
 in
 {
-	.allocator = allocator;
+    assert(allocator !is null);
 }
 do
 {
    .allocator = allocator;
 }
 /**
 * Returns the size in bytes of the state that needs to be allocated to hold an
 * object of type $(D_PARAM T).
 *
 * There is a difference between the `.sizeof`-property and
 * $(D_PSYMBOL stateSize) if $(D_PARAM T) is a class or an interface.
 * `T.sizeof` is constant on the given architecture then and is the same as
 * `size_t.sizeof` and `ptrdiff_t.sizeof`. This is because classes and
 * interfaces are reference types and `.sizeof` returns the size of the
 * reference which is the same as the size of a pointer. $(D_PSYMBOL stateSize)
 * returns the size of the instance itself.
 *
 * The size of a dynamic array is `size_t.sizeof * 2` since a dynamic array
 * stores its length and a data pointer. The size of the static arrays is
 * calculated differently since they are value types. It is the array length
 * multiplied by the element size.
 *
 * `stateSize!void` is `1` since $(D_KEYWORD void) is mostly used as a synonym
 * for $(D_KEYWORD byte)/$(D_KEYWORD ubyte) in `void*`.
 *
 * Params:
- * 	T = Object type.
+ *  T = Object type.
 *
 * Returns: Size of an instance of type $(D_PARAM T).
 */
 template stateSize(T)
 {
-	static if (is(T == class) || is(T == interface))
+    static if (isPolymorphicType!T)
-	{
+    {
-		enum stateSize = __traits(classInstanceSize, T);
+        enum size_t stateSize = __traits(classInstanceSize, T);
-	}
+    }
-	else
+    else
-	{
+    {
-		enum stateSize = T.sizeof;
+        enum size_t stateSize = T.sizeof;
-	}
+    }
 }
 ///
@nogc nothrow pure @safe unittest
 {
    static assert(stateSize!int == 4);
    static assert(stateSize!bool == 1);
    static assert(stateSize!(int[]) == (size_t.sizeof * 2));
    static assert(stateSize!(short[3]) == 6);
    static struct Empty
    {
    }
    static assert(stateSize!Empty == 1);
    static assert(stateSize!void == 1);
 }
 /**
 * Params:
- * 	size      = Raw size.
+ *  size      = Raw size.
- * 	alignment = Alignment.
+ *  alignment = Alignment.
 *
 * Returns: Aligned size.
 */
-size_t alignedSize(in size_t size, in size_t alignment = 8) pure nothrow @safe @nogc
+size_t alignedSize(const size_t size, const size_t alignment = 8)
 pure nothrow @safe @nogc
 {
-	return (size - 1) / alignment * alignment + alignment;
+    return (size - 1) / alignment * alignment + alignment;
 }
-/**
+/*
 * Internal function used to create, resize or destroy a dynamic array. It
- * throws $(D_PSYMBOL OutOfMemoryError) if $(D_PARAM Throws) is set. The new
+ * may throw $(D_PSYMBOL OutOfMemoryError). The new
- * allocated part of the array is initialized only if $(D_PARAM Init) 
+ * allocated part of the array isn't initialized. This function can be trusted
- * is set. This function can be trusted only in the data structures that
+ * only in the data structures that can ensure that the array is
- * can ensure that the array is allocated/rellocated/deallocated with the
+ * allocated/rellocated/deallocated with the same allocator.
 * same allocator.
 *
 * Params:
- * 	T         = Element type of the array being created.
+ *  T         = Element type of the array being created.
- *      Init      = If should be initialized.
+ *  allocator = The allocator used for getting memory.
- *      Throws    = If $(D_PSYMBOL OutOfMemoryError) should be throwsn.
+ *  array     = A reference to the array being changed.
- * 	allocator = The allocator used for getting memory.
+ *  length    = New array length.
 * 	array     = A reference to the array being changed.
 * 	length    = New array length.
 *
- * Returns: $(D_KEYWORD true) upon success, $(D_KEYWORD false) if memory could
+ * Returns: $(D_PARAM array).
 *          not be reallocated. In the latter
 */
-package(tanya) bool resize(T,
+package(tanya) T[] resize(T)(shared Allocator allocator,
-                           bool Init = true,
+                             auto ref T[] array,
-                           bool Throws = true)
+                             const size_t length) @trusted
                          (shared Allocator allocator,
                           ref T[] array,
                           in size_t length) @trusted
 {
-	void[] buf = array;
+    if (length == 0)
-	static if (Init)
+    {
-	{
+        if (allocator.deallocate(array))
-		immutable oldLength = array.length;
+        {
-	}
+            return null;
-	if (!allocator.reallocate(buf, length * T.sizeof))
+        }
-	{
+        else
-		static if (Throws)
+        {
-		{
+            onOutOfMemoryError();
-			onOutOfMemoryError;
+        }
-		}
+    }
 		return false;
 	}
 	// Casting from void[] is unsafe, but we know we cast to the original type.
 	array = cast(T[]) buf;
-	static if (Init)
+    void[] buf = array;
-	{
+    if (!allocator.reallocate(buf, length * T.sizeof))
-		if (oldLength < length)
+    {
-		{
+        onOutOfMemoryError();
-			array[oldLength .. $] = T.init;
+    }
-		}
+    // Casting from void[] is unsafe, but we know we cast to the original type.
-	}
+    array = cast(T[]) buf;
-	return true;
+
    return array;
 }
 package(tanya) alias resizeArray = resize;
-///
+@nogc nothrow pure @safe unittest
 unittest
 {
-	int[] p;
+    int[] p;
-	defaultAllocator.resizeArray(p, 20);
+    p = defaultAllocator.resize(p, 20);
-	assert(p.length == 20);
+    assert(p.length == 20);
-	defaultAllocator.resizeArray(p, 30);
+    p = defaultAllocator.resize(p, 30);
-	assert(p.length == 30);
+    assert(p.length == 30);
-	defaultAllocator.resizeArray(p, 10);
+    p = defaultAllocator.resize(p, 10);
-	assert(p.length == 10);
+    assert(p.length == 10);
-	defaultAllocator.resizeArray(p, 0);
+    p = defaultAllocator.resize(p, 0);
-	assert(p is null);
+    assert(p is null);
 }
 /*
 * Destroys the object.
 * Returns the memory should be freed.
 */
 package(tanya) void[] finalize(T)(ref T* p)
 {
    if (p is null)
    {
        return null;
    }
    static if (hasElaborateDestructor!T)
    {
        destroy(*p);
    }
    return (cast(void*) p)[0 .. T.sizeof];
 }
 package(tanya) void[] finalize(T)(ref T p)
 if (isPolymorphicType!T)
 {
    if (p is null)
    {
        return null;
    }
    static if (is(T == interface))
    {
        version(Windows)
        {
            import core.sys.windows.unknwn : IUnknown;
            static assert(!is(T : IUnknown), "COM interfaces can't be destroyed in "
                                           ~ __PRETTY_FUNCTION__);
        }
        auto ob = cast(Object) p;
    }
    else
    {
        alias ob = p;
    }
    auto ptr = cast(void*) ob;
    auto support = ptr[0 .. typeid(ob).initializer.length];
    auto ppv = cast(void**) ptr;
    if (!*ppv)
    {
        return null;
    }
    auto pc = cast(ClassInfo*) *ppv;
    scope (exit)
    {
        *ppv = null;
    }
    auto c = *pc;
    do
    {
        // Assume the destructor is @nogc. Leave it nothrow since the destructor
        // shouldn't throw and if it does, it is an error anyway.
        if (c.destructor)
        {
            alias DtorType = void function(Object) pure nothrow @safe @nogc;
            (cast(DtorType) c.destructor)(ob);
        }
    }
    while ((c = c.base) !is null);
    if (ppv[1]) // if monitor is not null
    {
        _d_monitordelete(cast(Object) ptr, true);
    }
    return support;
 }
 package(tanya) void[] finalize(T)(ref T[] p)
 {
    static if (hasElaborateDestructor!(typeof(p[0])))
    {
        foreach (ref e; p)
        {
            destroy(e);
        }
    }
    return p;
 }
 /**
@ -145,90 +357,158 @@ unittest
 * allocator.
 *
 * Params:
- * 	T         = Type of $(D_PARAM p).
+ *  T         = Type of $(D_PARAM p).
- * 	allocator = Allocator the $(D_PARAM p) was allocated with.
+ *  allocator = Allocator the $(D_PARAM p) was allocated with.
- * 	p         = Object or array to be destroyed.
+ *  p         = Object or array to be destroyed.
 */
 void dispose(T)(shared Allocator allocator, auto ref T* p)
 {
 	static if (hasElaborateDestructor!T)
 	{
 		destroy(*p);
 	}
 	() @trusted { allocator.deallocate((cast(void*) p)[0 .. T.sizeof]); }();
 	p = null;
 }
 /// Ditto.
 void dispose(T)(shared Allocator allocator, auto ref T p)
 	if (is(T == class) || is(T == interface))
 {
-	if (p is null)
+    () @trusted { allocator.deallocate(finalize(p)); }();
-	{
+    p = null;
 		return;
 	}
 	static if (is(T == interface))
 	{
 		version(Windows)
 		{
 			import core.sys.windows.unknwn : IUnknown;
 			static assert(!is(T: IUnknown), "COM interfaces can't be destroyed in "
 										 ~ __PRETTY_FUNCTION__);
 		}
 		auto ob = cast(Object) p;
 	}
 	else
 	{
 		alias ob = p;
 	}
 	auto ptr = cast(void *) ob;
 	auto support = ptr[0 .. typeid(ob).initializer.length];
 	scope (success)
 	{
 		() @trusted { allocator.deallocate(support); }();
 		p = null;
 	}
 	auto ppv = cast(void**) ptr;
 	if (!*ppv)
 	{
 		return;
 	}
 	auto pc = cast(ClassInfo*) *ppv;
 	scope (exit)
 	{
 		*ppv = null;
 	}
 	auto c = *pc;
 	do
 	{
 		// Assume the destructor is @nogc. Leave it nothrow since the destructor
 		// shouldn't throw and if it does, it is an error anyway.
 		if (c.destructor)
 		{
 			(cast(void function (Object) nothrow @safe @nogc) c.destructor)(ob);
 		}
 	}
 	while ((c = c.base) !is null);
 	if (ppv[1]) // if monitor is not null
 	{
 		_d_monitordelete(cast(Object) ptr, true);
 	}
 }
-/// Ditto.
+@nogc nothrow pure @system unittest
 void dispose(T)(shared Allocator allocator, auto ref T[] array)
 {
-	static if (hasElaborateDestructor!(typeof(array[0])))
+    static struct S
-	{
+    {
-	foreach (ref e; array)
+        ~this() @nogc nothrow pure @safe
-	{
+        {
-	    destroy(e);
+        }
-	}
+    }
-	}
+    auto p = cast(S[]) defaultAllocator.allocate(S.sizeof);
-	() @trusted { allocator.deallocate(array); }();
+
-	array = null;
+    defaultAllocator.dispose(p);
 }
 // Works with interfaces.
@nogc nothrow pure @safe unittest
 {
    interface I
    {
    }
    class C : I
    {
    }
    auto c = defaultAllocator.make!C();
    I i = c;
    defaultAllocator.dispose(i);
    defaultAllocator.dispose(i);
 }
 /**
 * Constructs a new class instance of type $(D_PARAM T) using $(D_PARAM args)
 * as the parameter list for the constructor of $(D_PARAM T).
 *
 * Params:
 *  T         = Class type.
 *  A         = Types of the arguments to the constructor of $(D_PARAM T).
 *  allocator = Allocator.
 *  args      = Constructor arguments of $(D_PARAM T).
 *
 * Returns: Newly created $(D_PSYMBOL T).
 *
 * Precondition: $(D_INLINECODE allocator !is null)
 */
 T make(T, A...)(shared Allocator allocator, auto ref A args)
 if (is(T == class))
 in
 {
    assert(allocator !is null);
 }
 do
 {
    auto mem = (() @trusted => allocator.allocate(stateSize!T))();
    if (mem is null)
    {
        onOutOfMemoryError();
    }
    scope (failure)
    {
        () @trusted { allocator.deallocate(mem); }();
    }
    return emplace!T(mem[0 .. stateSize!T], args);
 }
 /**
 * Constructs a value object of type $(D_PARAM T) using $(D_PARAM args)
 * as the parameter list for the constructor of $(D_PARAM T) and returns a
 * pointer to the new object.
 *
 * Params:
 *  T         = Object type.
 *  A         = Types of the arguments to the constructor of $(D_PARAM T).
 *  allocator = Allocator.
 *  args      = Constructor arguments of $(D_PARAM T).
 *
 * Returns: Pointer to the created object.
 *
 * Precondition: $(D_INLINECODE allocator !is null)
 */
 T* make(T, A...)(shared Allocator allocator, auto ref A args)
 if (!is(T == interface)
 && !is(T == class)
 && !isAssociativeArray!T
 && !isArray!T)
 in
 {
    assert(allocator !is null);
 }
 do
 {
    auto mem = (() @trusted => allocator.allocate(stateSize!T))();
    if (mem is null)
    {
        onOutOfMemoryError();
    }
    scope (failure)
    {
        () @trusted { allocator.deallocate(mem); }();
    }
    return emplace!T(mem[0 .. stateSize!T], args);
 }
 ///
@nogc nothrow pure @safe unittest
 {
    int* i = defaultAllocator.make!int(5);
    assert(*i == 5);
    defaultAllocator.dispose(i);
 }
 /**
 * Constructs a new array with $(D_PARAM n) elements.
 *
 * Params:
 *  T         = Array type.
 *  allocator = Allocator.
 *  n         = Array size.
 *
 * Returns: Newly created array.
 *
 * Precondition: $(D_INLINECODE allocator !is null
 *                           && n <= size_t.max / ElementType!T.sizeof)
 */
 T make(T)(shared Allocator allocator, const size_t n)
 if (isArray!T)
 in
 {
    assert(allocator !is null);
    assert(n <= size_t.max / ElementType!T.sizeof);
 }
 do
 {
    auto ret = allocator.resize!(ElementType!T)(null, n);
    ret.uninitializedFill(ElementType!T.init);
    return ret;
 }
 ///
@nogc nothrow pure @safe unittest
 {
    int[] i = defaultAllocator.make!(int[])(2);
    assert(i.length == 2);
    assert(i[0] == int.init && i[1] == int.init);
    defaultAllocator.dispose(i);
 }
--- a/source/tanya/memory/smartref.d
+++ b/source/tanya/memory/smartref.d
@ -0,0 +1,923 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * Smart pointers.
 *
 * A smart pointer is an object that wraps a raw pointer or a reference
 * (class, dynamic array) to manage its lifetime.
 *
 * This module provides two kinds of lifetime management strategies:
 * $(UL
 *  $(LI Reference counting)
 *  $(LI Unique ownership)
 * )
 *
 * Copyright: Eugene Wissner 2016-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/memory/smartref.d,
 *                 tanya/memory/smartref.d)
 */
 module tanya.memory.smartref;
 import tanya.algorithm.comparison;
 import tanya.algorithm.mutation;
 import tanya.conv;
 import tanya.exception;
 import tanya.memory;
 import tanya.meta.trait;
 import tanya.range.primitive;
 private template Payload(T)
 {
    static if (isPolymorphicType!T || isArray!T)
    {
        alias Payload = T;
    }
    else
    {
        alias Payload = T*;
    }
 }
 private final class RefCountedStore(T)
 {
    T payload;
    size_t counter = 1;
    size_t opUnary(string op)()
    if (op == "--" || op == "++")
    in
    {
        assert(this.counter > 0);
    }
    do
    {
        mixin("return " ~ op ~ "counter;");
    }
    int opCmp(const size_t counter)
    {
        if (this.counter > counter)
        {
            return 1;
        }
        else if (this.counter < counter)
        {
            return -1;
        }
        else
        {
            return 0;
        }
    }
 }
 private void separateDeleter(T)(RefCountedStore!T storage,
                                shared Allocator allocator)
 {
    allocator.dispose(storage.payload);
    allocator.dispose(storage);
 }
 private void unifiedDeleter(T)(RefCountedStore!T storage,
                               shared Allocator allocator)
 {
    auto ptr1 = finalize(storage);
    auto ptr2 = finalize(storage.payload);
    allocator.deallocate(ptr1.ptr[0 .. ptr1.length + ptr2.length]);
 }
 /**
 * Reference-counted object containing a $(D_PARAM T) value as payload.
 * $(D_PSYMBOL RefCounted) keeps track of all references of an object, and
 * when the reference count goes down to zero, frees the underlying store.
 *
 * Params:
 *  T = Type of the reference-counted value.
 */
 struct RefCounted(T)
 {
    private alias Storage = RefCountedStore!(Payload!T);
    private Storage storage;
    private void function(Storage storage,
                          shared Allocator allocator) @nogc deleter;
    invariant
    {
        assert(this.storage is null || this.allocator_ !is null);
        assert(this.storage is null || this.deleter !is null);
    }
    /**
     * Takes ownership over $(D_PARAM value), setting the counter to 1.
     * $(D_PARAM value) may be a pointer, an object or a dynamic array.
     *
     * Params:
     *  value     = Value whose ownership is taken over.
     *  allocator = Allocator used to destroy the $(D_PARAM value) and to
     *              allocate/deallocate internal storage.
     *
     * Precondition: $(D_INLINECODE allocator !is null)
     */
    this(Payload!T value, shared Allocator allocator = defaultAllocator)
    {
        this(allocator);
        this.storage = allocator.make!Storage();
        this.deleter = &separateDeleter!(Payload!T);
        this.storage.payload = value;
    }
    /// ditto
    this(shared Allocator allocator)
    in
    {
        assert(allocator !is null);
    }
    do
    {
        this.allocator_ = allocator;
    }
    /**
     * Increases the reference counter by one.
     */
    this(this)
    {
        if (count != 0)
        {
            ++this.storage;
        }
    }
    /**
     * Decreases the reference counter by one.
     *
     * If the counter reaches 0, destroys the owned object.
     */
    ~this()
    {
        if (this.storage !is null && !(this.storage > 0 && --this.storage))
        {
            deleter(this.storage, allocator);
        }
    }
    /**
     * Takes ownership over $(D_PARAM rhs). Initializes this
     * $(D_PSYMBOL RefCounted) if needed.
     *
     * If it is the last reference of the previously owned object,
     * it will be destroyed.
     *
     * To reset $(D_PSYMBOL RefCounted) assign $(D_KEYWORD null).
     *
     * If the allocator wasn't set before, $(D_PSYMBOL defaultAllocator) will
     * be used. If you need a different allocator, create a new
     * $(D_PSYMBOL RefCounted) and assign it.
     *
     * Params:
     *  rhs = New object.
     *
     * Returns: $(D_KEYWORD this).
     */
    ref typeof(this) opAssign(Payload!T rhs)
    {
        if (this.storage is null)
        {
            this.storage = allocator.make!Storage();
            this.deleter = &separateDeleter!(Payload!T);
        }
        else if (this.storage > 1)
        {
            --this.storage;
            this.storage = allocator.make!Storage();
            this.deleter = &separateDeleter!(Payload!T);
        }
        else
        {
            finalize(this.storage.payload);
            this.storage.payload = Payload!T.init;
        }
        this.storage.payload = rhs;
        return this;
    }
    /// ditto
    ref typeof(this) opAssign(typeof(null))
    {
        if (this.storage is null)
        {
            return this;
        }
        else if (this.storage > 1)
        {
            --this.storage;
        }
        else
        {
            deleter(this.storage, allocator);
        }
        this.storage = null;
        return this;
    }
    /// ditto
    ref typeof(this) opAssign(typeof(this) rhs)
    {
        swap(this.allocator_, rhs.allocator_);
        swap(this.storage, rhs.storage);
        swap(this.deleter, rhs.deleter);
        return this;
    }
    /**
     * Returns: Reference to the owned object.
     *
     * Precondition: $(D_INLINECODE cound > 0).
     */
    inout(Payload!T) get() inout
    in
    {
        assert(count > 0, "Attempted to access an uninitialized reference");
    }
    do
    {
        return this.storage.payload;
    }
    version (D_Ddoc)
    {
        /**
         * Dereferences the pointer. It is defined only for pointers, not for
         * reference types like classes, that can be accessed directly.
         *
         * Params:
         *  op = Operation.
         *
         * Returns: Reference to the pointed value.
         */
        ref inout(T) opUnary(string op)() inout
        if (op == "*");
    }
    else static if (isPointer!(Payload!T))
    {
        ref inout(T) opUnary(string op)() inout
        if (op == "*")
        {
            return *this.storage.payload;
        }
    }
    /**
     * Returns: Whether this $(D_PSYMBOL RefCounted) already has an internal
     *          storage.
     */
    @property bool isInitialized() const
    {
        return this.storage !is null;
    }
    /**
     * Returns: The number of $(D_PSYMBOL RefCounted) instances that share
     *          ownership over the same pointer (including $(D_KEYWORD this)).
     *          If this $(D_PSYMBOL RefCounted) isn't initialized, returns `0`.
     */
    @property size_t count() const
    {
        return this.storage is null ? 0 : this.storage.counter;
    }
    mixin DefaultAllocator;
    alias get this;
 }
 ///
@nogc @system unittest
 {
    auto rc = RefCounted!int(defaultAllocator.make!int(5), defaultAllocator);
    auto val = rc.get();
    *val = 8;
    assert(*rc.storage.payload == 8);
    val = null;
    assert(rc.storage.payload !is null);
    assert(*rc.storage.payload == 8);
    *rc = 9;
    assert(*rc.storage.payload == 9);
 }
@nogc @system unittest
 {
    auto rc = defaultAllocator.refCounted!int(5);
    rc = defaultAllocator.make!int(7);
    assert(*rc == 7);
 }
@nogc @system unittest
 {
    RefCounted!int rc;
    assert(!rc.isInitialized);
    rc = null;
    assert(!rc.isInitialized);
 }
@nogc @system unittest
 {
    auto rc = defaultAllocator.refCounted!int(5);
    void func(RefCounted!int param) @nogc
    {
        assert(param.count == 2);
        param = defaultAllocator.make!int(7);
        assert(param.count == 1);
        assert(*param == 7);
    }
    func(rc);
    assert(rc.count == 1);
    assert(*rc == 5);
 }
@nogc @system unittest
 {
    RefCounted!int rc;
    void func(RefCounted!int param) @nogc
    {
        assert(param.count == 0);
        param = defaultAllocator.make!int(7);
        assert(param.count == 1);
        assert(*param == 7);
    }
    func(rc);
    assert(rc.count == 0);
 }
@nogc @system unittest
 {
    RefCounted!int rc1, rc2;
    static assert(is(typeof(rc1 = rc2)));
 }
 version (unittest)
 {
    private class A
    {
        uint *destroyed;
        this(ref uint destroyed) @nogc
        {
            this.destroyed = &destroyed;
        }
        ~this() @nogc
        {
            ++(*destroyed);
        }
    }
    private struct B
    {
        int prop;
        @disable this();
        this(int param1) @nogc
        {
            prop = param1;
        }
    }
 }
@nogc @system unittest
 {
    uint destroyed;
    auto a = defaultAllocator.make!A(destroyed);
    assert(destroyed == 0);
    {
        auto rc = RefCounted!A(a, defaultAllocator);
        assert(rc.count == 1);
        void func(RefCounted!A rc) @nogc @system
        {
            assert(rc.count == 2);
        }
        func(rc);
        assert(rc.count == 1);
    }
    assert(destroyed == 1);
    RefCounted!int rc;
    assert(rc.count == 0);
    rc = defaultAllocator.make!int(8);
    assert(rc.count == 1);
 }
@nogc @system unittest
 {
    auto rc = RefCounted!int(defaultAllocator);
    assert(!rc.isInitialized);
    assert(rc.allocator is defaultAllocator);
 }
@nogc @system unittest
 {
    auto rc = defaultAllocator.refCounted!int(5);
    assert(rc.count == 1);
    void func(RefCounted!int rc) @nogc
    {
        assert(rc.count == 2);
        rc = null;
        assert(!rc.isInitialized);
        assert(rc.count == 0);
    }
    assert(rc.count == 1);
    func(rc);
    assert(rc.count == 1);
    rc = null;
    assert(!rc.isInitialized);
    assert(rc.count == 0);
 }
@nogc @system unittest
 {
    auto rc = defaultAllocator.refCounted!int(5);
    assert(*rc == 5);
    void func(RefCounted!int rc) @nogc
    {
        assert(rc.count == 2);
        rc = defaultAllocator.refCounted!int(4);
        assert(*rc == 4);
        assert(rc.count == 1);
    }
    func(rc);
    assert(*rc == 5);
 }
@nogc nothrow pure @safe unittest
 {
    static assert(is(typeof(RefCounted!int.storage.payload) == int*));
    static assert(is(typeof(RefCounted!A.storage.payload) == A));
    static assert(is(RefCounted!B));
    static assert(is(RefCounted!A));
 }
 /**
 * Constructs a new object of type $(D_PARAM T) and wraps it in a
 * $(D_PSYMBOL RefCounted) using $(D_PARAM args) as the parameter list for
 * the constructor of $(D_PARAM T).
 *
 * This function is more efficient than the using of $(D_PSYMBOL RefCounted)
 * directly, since it allocates only ones (the internal storage and the
 * object).
 *
 * Params:
 *  T         = Type of the constructed object.
 *  A         = Types of the arguments to the constructor of $(D_PARAM T).
 *  allocator = Allocator.
 *  args      = Constructor arguments of $(D_PARAM T).
 *
 * Returns: Newly created $(D_PSYMBOL RefCounted!T).
 *
 * Precondition: $(D_INLINECODE allocator !is null)
 */
 RefCounted!T refCounted(T, A...)(shared Allocator allocator, auto ref A args)
 if (!is(T == interface) && !isAbstractClass!T
 && !isAssociativeArray!T && !isArray!T)
 in
 {
    assert(allocator !is null);
 }
 do
 {
    auto rc = typeof(return)(allocator);
    const storageSize = alignedSize(stateSize!(RefCounted!T.Storage));
    const size = alignedSize(stateSize!T + storageSize);
    auto mem = (() @trusted => allocator.allocate(size))();
    if (mem is null)
    {
        onOutOfMemoryError();
    }
    scope (failure)
    {
        () @trusted { allocator.deallocate(mem); }();
    }
    rc.storage = emplace!(RefCounted!T.Storage)(mem[0 .. storageSize]);
    rc.storage.payload = emplace!T(mem[storageSize .. $], args);
    rc.deleter = &unifiedDeleter!(Payload!T);
    return rc;
 }
 /**
 * Constructs a new array with $(D_PARAM size) elements and wraps it in a
 * $(D_PSYMBOL RefCounted).
 *
 * Params:
 *  T         = Array type.
 *  size      = Array size.
 *  allocator = Allocator.
 *
 * Returns: Newly created $(D_PSYMBOL RefCounted!T).
 *
 * Precondition: $(D_INLINECODE allocator !is null
 *                           && size <= size_t.max / ElementType!T.sizeof)
 */
 RefCounted!T refCounted(T)(shared Allocator allocator, const size_t size)
@trusted
 if (isArray!T)
 in
 {
    assert(allocator !is null);
    assert(size <= size_t.max / ElementType!T.sizeof);
 }
 do
 {
    return RefCounted!T(allocator.make!T(size), allocator);
 }
 ///
@nogc @system unittest
 {
    auto rc = defaultAllocator.refCounted!int(5);
    assert(rc.count == 1);
    void func(RefCounted!int param) @nogc
    {
        if (param.count == 2)
        {
            func(param);
        }
        else
        {
            assert(param.count == 3);
        }
    }
    func(rc);
    assert(rc.count == 1);
 }
@nogc @system unittest
 {
    struct E
    {
    }
    auto b = defaultAllocator.refCounted!B(15);
    static assert(is(typeof(b.storage.payload) == B*));
    static assert(is(typeof(b.prop) == int));
    static assert(!is(typeof(defaultAllocator.refCounted!B())));
    static assert(is(typeof(defaultAllocator.refCounted!E())));
    static assert(!is(typeof(defaultAllocator.refCounted!E(5))));
    {
        auto rc = defaultAllocator.refCounted!B(3);
        assert(rc.get().prop == 3);
    }
    {
        auto rc = defaultAllocator.refCounted!E();
        assert(rc.count);
    }
 }
@nogc @system unittest
 {
    auto rc = defaultAllocator.refCounted!(int[])(5);
    assert(rc.length == 5);
 }
@nogc @system unittest
 {
    auto p1 = defaultAllocator.make!int(5);
    auto p2 = p1;
    auto rc = RefCounted!int(p1, defaultAllocator);
    assert(rc.get() is p2);
 }
@nogc @system unittest
 {
    static bool destroyed;
    static struct F
    {
        ~this() @nogc nothrow @safe
        {
            destroyed = true;
        }
    }
    {
        auto rc = defaultAllocator.refCounted!F();
    }
    assert(destroyed);
 }
 /**
 * $(D_PSYMBOL Unique) stores an object that gets destroyed at the end of its scope.
 *
 * Params:
 *  T = Value type.
 */
 struct Unique(T)
 {
    private Payload!T payload;
    invariant
    {
        assert(payload is null || allocator_ !is null);
    }
    /**
     * Takes ownership over $(D_PARAM value), setting the counter to 1.
     * $(D_PARAM value) may be a pointer, an object or a dynamic array.
     *
     * Params:
     *  value     = Value whose ownership is taken over.
     *  allocator = Allocator used to destroy the $(D_PARAM value) and to
     *              allocate/deallocate internal storage.
     *
     * Precondition: $(D_INLINECODE allocator !is null)
     */
    this(Payload!T value, shared Allocator allocator = defaultAllocator)
    {
        this(allocator);
        this.payload = value;
    }
    /// ditto
    this(shared Allocator allocator)
    in
    {
        assert(allocator !is null);
    }
    do
    {
        this.allocator_ = allocator;
    }
    /**
     * $(D_PSYMBOL Unique) is noncopyable.
     */
    @disable this(this);
    /**
     * Destroys the owned object.
     */
    ~this()
    {
        allocator.dispose(this.payload);
    }
    /**
     * Initialized this $(D_PARAM Unique) and takes ownership over
     * $(D_PARAM rhs).
     *
     * To reset $(D_PSYMBOL Unique) assign $(D_KEYWORD null).
     *
     * If the allocator wasn't set before, $(D_PSYMBOL defaultAllocator) will
     * be used. If you need a different allocator, create a new
     * $(D_PSYMBOL Unique) and assign it.
     *
     * Params:
     *  rhs = New object.
     *
     * Returns: $(D_KEYWORD this).
     */
    ref typeof(this) opAssign(Payload!T rhs)
    {
        allocator.dispose(this.payload);
        this.payload = rhs;
        return this;
    }
    /// ditto
    ref typeof(this) opAssign(typeof(null))
    {
        allocator.dispose(this.payload);
        return this;
    }
    /// ditto
    ref typeof(this) opAssign(typeof(this) rhs)
    {
        swap(this.allocator_, rhs.allocator_);
        swap(this.payload, rhs.payload);
        return this;
    }
    ///
    @nogc nothrow pure @system unittest
    {
        auto rc = defaultAllocator.unique!int(5);
        rc = defaultAllocator.make!int(7);
        assert(*rc == 7);
    }
    /**
     * Returns: Reference to the owned object.
     */
    inout(Payload!T) get() inout
    {
        return this.payload;
    }
    version (D_Ddoc)
    {
        /**
         * Dereferences the pointer. It is defined only for pointers, not for
         * reference types like classes, that can be accessed directly.
         *
         * Params:
         *  op = Operation.
         *
         * Returns: Reference to the pointed value.
         */
        ref inout(T) opUnary(string op)() inout
        if (op == "*");
    }
    else static if (isPointer!(Payload!T))
    {
        ref inout(T) opUnary(string op)() inout
        if (op == "*")
        {
            return *this.payload;
        }
    }
    /**
     * Returns: Whether this $(D_PSYMBOL Unique) holds some value.
     */
    @property bool isInitialized() const
    {
        return this.payload !is null;
    }
    ///
    @nogc nothrow pure @system unittest
    {
        Unique!int u;
        assert(!u.isInitialized);
    }
    /**
     * Sets the internal pointer to $(D_KEYWORD). The allocator isn't changed.
     *
     * Returns: Reference to the owned object.
     */
    Payload!T release()
    {
        auto payload = this.payload;
        this.payload = null;
        return payload;
    }
    ///
    @nogc nothrow pure @system unittest
    {
        auto u = defaultAllocator.unique!int(5);
        assert(u.isInitialized);
        auto i = u.release();
        assert(*i == 5);
        assert(!u.isInitialized);
    }
    mixin DefaultAllocator;
    alias get this;
 }
 ///
@nogc nothrow pure @system unittest
 {
    auto p = defaultAllocator.make!int(5);
    auto s = Unique!int(p, defaultAllocator);
    assert(*s == 5);
 }
 ///
@nogc nothrow @system unittest
 {
    static bool destroyed;
    static struct F
    {
        ~this() @nogc nothrow @safe
        {
            destroyed = true;
        }
    }
    {
        auto s = Unique!F(defaultAllocator.make!F(), defaultAllocator);
    }
    assert(destroyed);
 }
 /**
 * Constructs a new object of type $(D_PARAM T) and wraps it in a
 * $(D_PSYMBOL Unique) using $(D_PARAM args) as the parameter list for
 * the constructor of $(D_PARAM T).
 *
 * Params:
 *  T         = Type of the constructed object.
 *  A         = Types of the arguments to the constructor of $(D_PARAM T).
 *  allocator = Allocator.
 *  args      = Constructor arguments of $(D_PARAM T).
 *
 * Returns: Newly created $(D_PSYMBOL Unique!T).
 *
 * Precondition: $(D_INLINECODE allocator !is null)
 */
 Unique!T unique(T, A...)(shared Allocator allocator, auto ref A args)
 if (!is(T == interface) && !isAbstractClass!T
 && !isAssociativeArray!T && !isArray!T)
 in
 {
    assert(allocator !is null);
 }
 do
 {
    auto payload = allocator.make!(T, A)(args);
    return Unique!T(payload, allocator);
 }
 /**
 * Constructs a new array with $(D_PARAM size) elements and wraps it in a
 * $(D_PSYMBOL Unique).
 *
 * Params:
 *  T         = Array type.
 *  size      = Array size.
 *  allocator = Allocator.
 *
 * Returns: Newly created $(D_PSYMBOL Unique!T).
 *
 * Precondition: $(D_INLINECODE allocator !is null
 *                           && size <= size_t.max / ElementType!T.sizeof)
 */
 Unique!T unique(T)(shared Allocator allocator, const size_t size)
@trusted
 if (isArray!T)
 in
 {
    assert(allocator !is null);
    assert(size <= size_t.max / ElementType!T.sizeof);
 }
 do
 {
    auto payload = allocator.resize!(ElementType!T)(null, size);
    return Unique!T(payload, allocator);
 }
@nogc nothrow pure @safe unittest
 {
    static assert(is(typeof(defaultAllocator.unique!B(5))));
    static assert(is(typeof(defaultAllocator.unique!(int[])(5))));
 }
@nogc nothrow pure @system unittest
 {
    auto s = defaultAllocator.unique!int(5);
    assert(*s == 5);
    s = null;
    assert(s is null);
 }
@nogc nothrow pure @system unittest
 {
    auto s = defaultAllocator.unique!int(5);
    assert(*s == 5);
    s = defaultAllocator.unique!int(4);
    assert(*s == 4);
 }
@nogc nothrow pure @system unittest
 {
    auto p1 = defaultAllocator.make!int(5);
    auto p2 = p1;
    auto rc = Unique!int(p1, defaultAllocator);
    assert(rc.get() is p2);
 }
@nogc nothrow pure @system unittest
 {
    auto rc = Unique!int(defaultAllocator);
    assert(rc.allocator is defaultAllocator);
 }
--- a/source/tanya/memory/types.d
+++ b/source/tanya/memory/types.d
@ -1,457 +0,0 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * Copyright: Eugene Wissner 2016.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:belka@caraus.de, Eugene Wissner)
 */
 module tanya.memory.types;
 import core.exception;
 import std.algorithm.comparison;
 import std.algorithm.mutation;
 import std.conv;
 import std.traits;
 import tanya.memory;
 /**
 * Reference-counted object containing a $(D_PARAM T) value as payload.
 * $(D_PSYMBOL RefCounted) keeps track of all references of an object, and
 * when the reference count goes down to zero, frees the underlying store.
 *
 * Params:
 * 	T = Type of the reference-counted value.
 */
 struct RefCounted(T)
 {
 	static if (is(T == class) || is(T == interface))
 	{
 		private alias Payload = T;
 	}
 	else
 	{
 		private alias Payload = T*;
 	}
 	private class Storage
 	{
 		private Payload payload;
 		private size_t counter = 1;
 		private final size_t opUnary(string op)() pure nothrow @safe @nogc
 			if (op == "--" || op == "++")
 		in
 		{
 			assert(counter > 0);
 		}
 		body
 		{
 			mixin("return " ~ op ~ "counter;");
 		}
 		private final int opCmp(size_t counter) const pure nothrow @safe @nogc
 		{
 			if (this.counter > counter)
 			{
 				return 1;
 			}
 			else if (this.counter < counter)
 			{
 				return -1;
 			}
 			else
 			{
 				return 0;
 			}
 		}
 		private final int opEquals(size_t counter) const pure nothrow @safe @nogc
 		{
 			return this.counter == counter;
 		}
 	}
 	private final class RefCountedStorage : Storage
 	{
 		private shared Allocator allocator;
 		this(shared Allocator allocator) pure nothrow @safe @nogc
 		in
 		{
 			assert(allocator !is null);
 		}
 		body
 		{
 			this.allocator = allocator;
 		}
 		~this() nothrow @nogc
 		{
 			allocator.dispose(payload);
 		}
 	}
 	private Storage storage;
 	invariant
 	{
 		assert(storage is null || allocator_ !is null);
 	}
 	/**
 	 * Takes ownership over $(D_PARAM value), setting the counter to 1.
 	 * $(D_PARAM value) may be a pointer, an object or a dynamic array.
 	 *
 	 * Params:
 	 * 	value     = Value whose ownership is taken over.
 	 * 	allocator = Allocator used to destroy the $(D_PARAM value) and to
 	 * 	            allocate/deallocate internal storage.
 	 *
 	 * Precondition: $(D_INLINECODE allocator !is null)
 	 */
 	this(Payload value, shared Allocator allocator = defaultAllocator)
 	{
 		this(allocator);
 		storage = allocator.make!RefCountedStorage(allocator);
 		move(value, storage.payload);
 	}
 	/// Ditto.
 	this(shared Allocator allocator)
 	in
 	{
 		assert(allocator !is null);
 	}
 	body
 	{
 		this.allocator_ = allocator;
 	}
 	/**
 	 * Increases the reference counter by one.
 	 */
 	this(this)
 	{
 		if (count != 0)
 		{
 			++storage;
 		}
 	}
 	/**
 	 * Decreases the reference counter by one.
 	 *
 	 * If the counter reaches 0, destroys the owned object.
 	 */
 	~this()
 	{
 		if (storage !is null && !(storage.counter && --storage))
 		{
 			allocator_.dispose(storage);
 		}
 	}
 	/**
 	 * Takes ownership over $(D_PARAM rhs). Initializes this
 	 * $(D_PSYMBOL RefCounted) if needed.
 	 *
 	 * If it is the last reference of the previously owned object,
 	 * it will be destroyed.
 	 *
 	 * To reset the $(D_PSYMBOL RefCounted) assign $(D_KEYWORD null).
 	 *
 	 * If the allocator wasn't set before, $(D_PSYMBOL defaultAllocator) will
 	 * be used. If you need a different allocator, create a new
 	 * $(D_PSYMBOL RefCounted) and assign it.
 	 *
 	 * Params:
 	 * 	rhs = $(D_KEYWORD this).
 	 */
 	ref typeof(this) opAssign(Payload rhs)
 	{
 		if (storage is null)
 		{
 			storage = allocator.make!RefCountedStorage(allocator);
 		}
 		else if (storage > 1)
 		{
 			--storage;
 			storage = allocator.make!RefCountedStorage(allocator);
 		}
 		else if (cast(RefCountedStorage) storage is null)
 		{
 			// Created with refCounted. Always destroyed togethter with the pointer.
 			assert(storage.counter != 0);
 			allocator.dispose(storage);
 			storage = allocator.make!RefCountedStorage(allocator);
 		}
 		else
 		{
 			allocator.dispose(storage.payload);
 		}
 		move(rhs, storage.payload);
 		return this;
 	}
 	/// Ditto.
 	ref typeof(this) opAssign(typeof(null))
 	{
 		if (storage is null)
 		{
 			return this;
 		}
 		else if (storage > 1)
 		{
 			--storage;
 			storage = null;
 		}
 		else if (cast(RefCountedStorage) storage is null)
 		{
 			// Created with refCounted. Always destroyed togethter with the pointer.
 			assert(storage.counter != 0);
 			allocator.dispose(storage);
 			return this;
 		}
 		else
 		{
 			allocator.dispose(storage.payload);
 		}
 		return this;
 	}
 	/// Ditto.
 	ref typeof(this) opAssign(typeof(this) rhs)
 	{
 		swap(allocator_, rhs.allocator_);
 		swap(storage, rhs.storage);
 		return this;
 	}
 	/**
 	 * Returns: Reference to the owned object.
 	 */
 	inout(Payload) get() inout pure nothrow @safe @nogc
 	in
 	{
 		assert(count > 0, "Attempted to access an uninitialized reference.");
 	}
 	body
 	{
 		return storage.payload;
 	}
 	static if (isPointer!Payload)
 	{
 		/**
 		 * Params:
 		 * 	op = Operation. 
 		 *
 		 * Dereferences the pointer. It is defined only for pointers, not for
 		 * reference types like classes, that can be accessed directly.
 		 *
 		 * Returns: Reference to the pointed value.
 		 */
 		ref T opUnary(string op)()
 			if (op == "*")
 		{
 			return *storage.payload;
 		}
 	}
 	/**
 	 * Returns: Whether this $(D_PSYMBOL RefCounted) already has an internal 
 	 *          storage.
 	 */
 	@property bool isInitialized() const
 	{
 		return storage !is null;
 	}
 	/**
 	 * Returns: The number of $(D_PSYMBOL RefCounted) instances that share
 	 *          ownership over the same pointer (including $(D_KEYWORD this)).
 	 *          If this $(D_PSYMBOL RefCounted) isn't initialized, returns `0`.
 	 */
 	@property size_t count() const
 	{
 		return storage is null ? 0 : storage.counter;
 	}
 	mixin DefaultAllocator;
 	alias get this;
 }
 ///
 unittest
 {
 	auto rc = RefCounted!int(defaultAllocator.make!int(5), defaultAllocator);
 	auto val = rc.get;
 	*val = 8;
 	assert(*rc.storage.payload == 8);
 	val = null;
 	assert(rc.storage.payload !is null);
 	assert(*rc.storage.payload == 8);
 	*rc = 9;
 	assert(*rc.storage.payload == 9);
 }
 version (unittest)
 {
 	class A
 	{
 		uint *destroyed;
 		this(ref uint destroyed) @nogc
 		{
 			this.destroyed = &destroyed;
 		}
 		~this() @nogc
 		{
 			++(*destroyed);
 		}
 	}
 	struct B
 	{
 		int prop;
 		@disable this();
 		this(int param1) @nogc
 		{
 			prop = param1;
 		}
 	}
 }
 private unittest
 {
 	uint destroyed;
 	auto a = defaultAllocator.make!A(destroyed);
 	assert(destroyed == 0);
 	{
 		auto rc = RefCounted!A(a, defaultAllocator);
 		assert(rc.count == 1);
 		void func(RefCounted!A rc)
 		{
 			assert(rc.count == 2);
 		}
 		func(rc);
 		assert(rc.count == 1);
 	}
 	assert(destroyed == 1);
 	RefCounted!int rc;
 	assert(rc.count == 0);
 	rc = defaultAllocator.make!int(8);
 	assert(rc.count == 1);
 }
 private unittest
 {
 	static assert(is(typeof(RefCounted!int.storage.payload) == int*));
 	static assert(is(typeof(RefCounted!A.storage.payload) == A));
 	static assert(is(RefCounted!B));
 	static assert(is(RefCounted!A));
 }
 /**
 * Constructs a new object of type $(D_PARAM T) and wraps it in a
 * $(D_PSYMBOL RefCounted) using $(D_PARAM args) as the parameter list for
 * the constructor of $(D_PARAM T).
 *
 * This function is more efficient than the using of $(D_PSYMBOL RefCounted)
 * directly, since it allocates only ones (the internal storage and the
 * object).
 *
 * Params:
 * 	T    = Type of the constructed object.
 * 	A    = Types of the arguments to the constructor of $(D_PARAM T).
 * 	args = Constructor arguments of $(D_PARAM T).
 * 
 * Returns: Newly created $(D_PSYMBOL RefCounted!T).
 */
 RefCounted!T refCounted(T, A...)(shared Allocator allocator, auto ref A args)
 	if (!is(T == interface) && !isAbstractClass!T
         && !isArray!T && !isAssociativeArray!T)
 {
 	auto rc = typeof(return)(allocator);
 	immutable storageSize = alignedSize(stateSize!(RefCounted!T.Storage));
 	immutable size = alignedSize(stateSize!T + storageSize);
 	auto mem = (() @trusted => allocator.allocate(size))();
 	if (mem is null)
 	{
 		onOutOfMemoryError();
 	}
 	scope (failure)
 	{
 		() @trusted { allocator.deallocate(mem); }();
 	}
 	rc.storage = emplace!(RefCounted!T.Storage)(mem[0 .. storageSize]);
 	static if (is(T == class))
 	{
 		rc.storage.payload = emplace!T(mem[storageSize .. $], args);
 	}
 	else
 	{
 		auto ptr = (() @trusted => (cast(T*) mem[storageSize .. $].ptr))();
 		rc.storage.payload = emplace!T(ptr, args);
 	}
 	return rc;
 }
 ///
 unittest
 {
 	auto rc = defaultAllocator.refCounted!int(5);
 	assert(rc.count == 1);
 	void func(RefCounted!int param)
 	{
 		if (param.count == 2)
 		{
 			func(param);
 		}
 		else
 		{
 			assert(param.count == 3);
 		}
 	}
 	func(rc);
 	assert(rc.count == 1);
 }
 private @nogc unittest
 {
 	struct E
 	{
 	}
 	auto b = defaultAllocator.refCounted!B(15);
 	static assert(is(typeof(b.storage.payload) == B*));
 	static assert(is(typeof(b.prop) == int));
 	static assert(!is(typeof(defaultAllocator.refCounted!B())));
 	static assert(is(typeof(defaultAllocator.refCounted!E())));
 	static assert(!is(typeof(defaultAllocator.refCounted!E(5))));
 	{
 		auto rc = defaultAllocator.refCounted!B(3);
 		assert(rc.get.prop == 3);
 	}
 	{
 		auto rc = defaultAllocator.refCounted!E();
 		assert(rc.count);
 	}
 }
--- a/source/tanya/meta/metafunction.d
+++ b/source/tanya/meta/metafunction.d
--- a/source/tanya/meta/package.d
+++ b/source/tanya/meta/package.d
@ -0,0 +1,23 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * Template metaprogramming.
 *
 * This package contains utilities to acquire type information at compile-time,
 * to transform from one type to another. It has also different algorithms for
 * iterating, searching and modifying template arguments.
 *
 * Copyright: Eugene Wissner 2017-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/meta/package.d,
 *                 tanya/meta/package.d)
 */
 module tanya.meta;
 public import tanya.meta.metafunction;
 public import tanya.meta.trait;
 public import tanya.meta.transform;
--- a/source/tanya/meta/trait.d
+++ b/source/tanya/meta/trait.d
--- a/source/tanya/meta/transform.d
+++ b/source/tanya/meta/transform.d
@ -0,0 +1,981 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * Type transformations.
 *
 * Templates in this module can be used to modify type qualifiers or transform
 * types. They take some type as argument and return a different type after
 * perfoming the specified transformation.
 *
 * Copyright: Eugene Wissner 2017-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/meta/transform.d,
 *                 tanya/meta/transform.d)
 */
 module tanya.meta.transform;
 import tanya.meta.metafunction;
 import tanya.meta.trait;
 /**
 * Removes any type qualifiers from $(D_PARAM T).
 *
 * Removed qualifiers are:
 * $(UL
 *  $(LI const)
 *  $(LI immutable)
 *  $(LI inout)
 *  $(LI shared)
 * )
 * and combinations of these.
 *
 * If the type $(D_PARAM T) doesn't have any qualifieres,
 * $(D_INLINECODE Unqual!T) becomes an alias for $(D_PARAM T).
 *
 * Params:
 *  T = A type.
 *
 * Returns: $(D_PARAM T) without any type qualifiers.
 */
 template Unqual(T)
 {
    static if (is(T U == const U)
            || is(T U == immutable U)
            || is(T U == inout U)
            || is(T U == inout const U)
            || is(T U == shared U)
            || is(T U == shared const U)
            || is(T U == shared inout U)
            || is(T U == shared inout const U))
    {
        alias Unqual = U;
    }
    else
    {
        alias Unqual = T;
    }
 }
 ///
@nogc nothrow pure @safe unittest
 {
    static assert(is(Unqual!bool == bool));
    static assert(is(Unqual!(immutable bool) == bool));
    static assert(is(Unqual!(inout bool) == bool));
    static assert(is(Unqual!(inout const bool) == bool));
    static assert(is(Unqual!(shared bool) == bool));
    static assert(is(Unqual!(shared const bool) == bool));
    static assert(is(Unqual!(shared inout const bool) == bool));
 }
 /**
 * If $(D_PARAM T) is an $(D_KEYWORD enum), $(D_INLINECODE OriginalType!T)
 * evaluates to the most base type of that $(D_KEYWORD enum) and to
 * $(D_PARAM T) otherwise.
 *
 * Params:
 *  T = A type.
 *
 * Returns: Base type of the $(D_KEYWORD enum) $(D_PARAM T) or $(D_PARAM T)
 *          itself.
 */
 template OriginalType(T)
 {
    static if (is(T U == enum))
    {
        alias OriginalType = OriginalType!U;
    }
    else
    {
        alias OriginalType = T;
    }
 }
 ///
@nogc nothrow pure @safe unittest
 {
    enum E1 : const(int)
    {
        n = 0,
    }
    enum E2 : bool
    {
        t = true,
    }
    enum E3 : E2
    {
        t = E2.t,
    }
    enum E4 : const(E2)
    {
        t = E2.t,
    }
    static assert(is(OriginalType!E1 == const int));
    static assert(is(OriginalType!E2 == bool));
    static assert(is(OriginalType!E3 == bool));
    static assert(is(OriginalType!E4 == bool));
    static assert(is(OriginalType!(const E4) == bool));
 }
 /**
 * Copies constness of $(D_PARAM From) to $(D_PARAM To).
 *
 * The following type qualifiers affect the constness and hence are copied:
 * $(UL
 *  $(LI const)
 *  $(LI immutable)
 *  $(LI inout)
 *  $(LI inout const)
 * )
 *
 * Params:
 *  From = Source type.
 *  To   = Target type.
 *
 * Returns: $(D_PARAM To) with the constness of $(D_PARAM From).
 *
 * See_Also: $(D_PSYMBOL CopyTypeQualifiers).
 */
 template CopyConstness(From, To)
 {
    static if (is(From T == immutable T))
    {
        alias CopyConstness = immutable To;
    }
    else static if (is(From T == const T) || is(From T == shared const T))
    {
        alias CopyConstness = const To;
    }
    else static if (is(From T == inout T) || is(From T == shared inout T))
    {
        alias CopyConstness = inout To;
    }
    else static if (is(From T == inout const T)
                 || is(From T == shared inout const T))
    {
        alias CopyConstness = inout const To;
    }
    else
    {
        alias CopyConstness = To;
    }
 }
 ///
@nogc nothrow pure @safe unittest
 {
    static assert(is(CopyConstness!(int, char) == char));
    static assert(is(CopyConstness!(const int, char) == const char));
    static assert(is(CopyConstness!(immutable int, char) == immutable char));
    static assert(is(CopyConstness!(inout int, char) == inout char));
    static assert(is(CopyConstness!(inout const int, char) == inout const char));
    static assert(is(CopyConstness!(shared int, char) == char));
    static assert(is(CopyConstness!(shared const int, char) == const char));
    static assert(is(CopyConstness!(shared inout int, char) == inout char));
    static assert(is(CopyConstness!(shared inout const int, char) == inout const char));
    static assert(is(CopyConstness!(const int, shared char) == shared const char));
    static assert(is(CopyConstness!(const int, immutable char) == immutable char));
    static assert(is(CopyConstness!(immutable int, const char) == immutable char));
 }
 /**
 * Copies type qualifiers of $(D_PARAM From) to $(D_PARAM To).
 *
 * Type qualifiers copied are:
 * $(UL
 *  $(LI const)
 *  $(LI immutable)
 *  $(LI inout)
 *  $(LI shared)
 * )
 * and combinations of these.
 *
 * Params:
 *  From = Source type.
 *  To   = Target type.
 *
 * Returns: $(D_PARAM To) with the type qualifiers of $(D_PARAM From).
 *
 * See_Also: $(D_PSYMBOL CopyConstness).
 */
 template CopyTypeQualifiers(From, To)
 {
    static if (is(From T == immutable T))
    {
        alias CopyTypeQualifiers = immutable To;
    }
    else static if (is(From T == const T))
    {
        alias CopyTypeQualifiers = const To;
    }
    else static if (is(From T == shared T))
    {
        alias CopyTypeQualifiers = shared To;
    }
    else static if (is(From T == shared const T))
    {
        alias CopyTypeQualifiers = shared const To;
    }
    else static if (is(From T == inout T))
    {
        alias CopyTypeQualifiers = inout To;
    }
    else static if (is(From T == shared inout T))
    {
        alias CopyTypeQualifiers = shared inout To;
    }
    else static if (is(From T == inout const T))
    {
        alias CopyTypeQualifiers = inout const To;
    }
    else static if (is(From T == shared inout const T))
    {
        alias CopyTypeQualifiers = shared inout const To;
    }
    else
    {
        alias CopyTypeQualifiers = To;
    }
 }
 ///
@nogc nothrow pure @safe unittest
 {
    static assert(is(CopyTypeQualifiers!(int, char) == char));
    static assert(is(CopyTypeQualifiers!(const int, char) == const char));
    static assert(is(CopyTypeQualifiers!(immutable int, char) == immutable char));
    static assert(is(CopyTypeQualifiers!(inout int, char) == inout char));
    static assert(is(CopyTypeQualifiers!(inout const int, char) == inout const char));
    static assert(is(CopyTypeQualifiers!(shared int, char) == shared char));
    static assert(is(CopyTypeQualifiers!(shared const int, char) == shared const char));
    static assert(is(CopyTypeQualifiers!(shared inout int, char) == shared inout char));
    static assert(is(CopyTypeQualifiers!(shared inout const int, char) == shared inout const char));
 }
 /**
 * Evaluates to the unsigned counterpart of the integral type $(D_PARAM T) preserving all type qualifiers.
 * If $(D_PARAM T) is already unsigned, $(D_INLINECODE Unsigned!T) aliases $(D_PARAM T).
 *
 * Params:
 *  T = A type.
 *
 * Returns: Unsigned counterpart of $(D_PARAM T).
 *
 * See_Also: $(D_PSYMBOL isSigned).
 */
 template Unsigned(T)
 if (isIntegral!T)
 {
    alias UnqualedType = Unqual!(OriginalType!T);
    static if (is(UnqualedType == byte))
    {
        alias Unsigned = CopyTypeQualifiers!(T, ubyte);
    }
    else static if (is(UnqualedType == short))
    {
        alias Unsigned = CopyTypeQualifiers!(T, ushort);
    }
    else static if (is(UnqualedType == int))
    {
        alias Unsigned = CopyTypeQualifiers!(T, uint);
    }
    else static if (is(UnqualedType == long))
    {
        alias Unsigned = CopyTypeQualifiers!(T, ulong);
    }
    else
    {
        alias Unsigned = T;
    }
 }
 ///
@nogc nothrow pure @safe unittest
 {
    static assert(is(Unsigned!byte == ubyte));
    static assert(is(Unsigned!short == ushort));
    static assert(is(Unsigned!int == uint));
    static assert(is(Unsigned!long == ulong));
    static assert(is(Unsigned!(const byte) == const ubyte));
    static assert(is(Unsigned!(shared byte) == shared ubyte));
    static assert(is(Unsigned!(shared const byte) == shared const ubyte));
    static assert(!is(Unsigned!float));
    static assert(is(Unsigned!ubyte == ubyte));
 }
 /**
 * Evaluates to the signed counterpart of the integral type $(D_PARAM T) preserving all type qualifiers.
 * If $(D_PARAM T) is already signed, $(D_INLINECODE Signed!T) aliases $(D_PARAM T).
 *
 * Params:
 *  T = A type.
 *
 * Returns: Signed counterpart of $(D_PARAM T).
 *
 * See_Also: $(D_PSYMBOL isUnsigned).
 */
 template Signed(T)
 if (isIntegral!T)
 {
    alias UnqualedType = Unqual!(OriginalType!T);
    static if (is(UnqualedType == ubyte))
    {
        alias Signed = CopyTypeQualifiers!(T, byte);
    }
    else static if (is(UnqualedType == ushort))
    {
        alias Signed = CopyTypeQualifiers!(T, short);
    }
    else static if (is(UnqualedType == uint))
    {
        alias Signed = CopyTypeQualifiers!(T, int);
    }
    else static if (is(UnqualedType == ulong))
    {
        alias Signed = CopyTypeQualifiers!(T, long);
    }
    else
    {
        alias Signed = T;
    }
 }
 ///
@nogc nothrow pure @safe unittest
 {
    static assert(is(Signed!ubyte == byte));
    static assert(is(Signed!ushort == short));
    static assert(is(Signed!uint == int));
    static assert(is(Signed!ulong == long));
    static assert(is(Signed!(const ubyte) == const byte));
    static assert(is(Signed!(shared ubyte) == shared byte));
    static assert(is(Signed!(shared const ubyte) == shared const byte));
    static assert(!is(Signed!float));
    static assert(is(Signed!byte == byte));
 }
 /**
 * Retrieves the target type `U` of a pointer `U*`.
 *
 * Params:
 *  T = Pointer type.
 *
 * Returns: Pointer target type.
 */
 template PointerTarget(T)
 {
    static if (is(T U : U*))
    {
        alias PointerTarget = U;
    }
    else
    {
        static assert(T.stringof ~ " isn't a pointer type");
    }
 }
 ///
@nogc nothrow pure @safe unittest
 {
    static assert(is(PointerTarget!(bool*) == bool));
    static assert(is(PointerTarget!(const bool*) == const bool));
    static assert(is(PointerTarget!(const shared bool*) == const shared bool));
    static assert(!is(PointerTarget!bool));
 }
 /**
 * Params:
 *  T = The type of the associative array.
 *
 * Returns: The key type of the associative array $(D_PARAM T).
 */
 template KeyType(T)
 {
    static if (is(T V : V[K], K))
    {
        alias KeyType = K;
    }
    else
    {
        static assert(false, T.stringof ~ " isn't an associative array");
    }
 }
 ///
@nogc nothrow pure @safe unittest
 {
    static assert(is(KeyType!(int[string]) == string));
    static assert(!is(KeyType!(int[15])));
 }
 /**
 * Params:
 *  T = The type of the associative array.
 *
 * Returns: The value type of the associative array $(D_PARAM T).
 */
 template ValueType(T)
 {
    static if (is(T V : V[K], K))
    {
        alias ValueType = V;
    }
    else
    {
        static assert(false, T.stringof ~ " isn't an associative array");
    }
 }
 ///
@nogc nothrow pure @safe unittest
 {
    static assert(is(ValueType!(int[string]) == int));
    static assert(!is(ValueType!(int[15])));
 }
 /**
 * Params:
 *  T = Scalar type.
 *
 * Returns: The type $(D_PARAM T) will promote to.
 *
 * See_Also: $(LINK2 https://dlang.org/spec/type.html#integer-promotions,
 *                   Integer Promotions).
 */
 template Promoted(T)
 if (isScalarType!T)
 {
    alias Promoted = CopyTypeQualifiers!(T, typeof(T.init + T.init));
 }
 ///
@nogc nothrow pure @safe unittest
 {
    static assert(is(Promoted!bool == int));
    static assert(is(Promoted!byte == int));
    static assert(is(Promoted!ubyte == int));
    static assert(is(Promoted!short == int));
    static assert(is(Promoted!ushort == int));
    static assert(is(Promoted!char == int));
    static assert(is(Promoted!wchar == int));
    static assert(is(Promoted!dchar == uint));
    static assert(is(Promoted!(const bool) == const int));
    static assert(is(Promoted!(shared bool) == shared int));
 }
 /**
 * Adds $(D_KEYWORD inout) qualifier to the type $(D_PARAM T).
 *
 * Params:
 *  T = A type.
 *
 * Returns: $(D_INLINECODE inout(T)).
 */
 alias InoutOf(T) = inout(T);
 ///
@nogc nothrow pure @safe unittest
 {
    static assert(is(InoutOf!int == inout int));
 }
 /**
 * Adds $(D_KEYWORD inout) qualifier to the type $(D_PARAM T).
 *
 * Params:
 *  T = A type.
 *
 * Returns: $(D_INLINECODE inout(T)).
 */
 alias ConstOf(T) = const(T);
 ///
@nogc nothrow pure @safe unittest
 {
    static assert(is(ConstOf!int == const int));
 }
 /**
 * Adds $(D_KEYWORD inout) qualifier to the type $(D_PARAM T).
 *
 * Params:
 *  T = A type.
 *
 * Returns: $(D_INLINECODE inout(T)).
 */
 alias SharedOf(T) = shared(T);
 ///
@nogc nothrow pure @safe unittest
 {
    static assert(is(SharedOf!int == shared int));
 }
 /**
 * Adds $(D_KEYWORD inout) qualifier to the type $(D_PARAM T).
 *
 * Params:
 *  T = A type.
 *
 * Returns: $(D_INLINECODE inout(T)).
 */
 alias SharedInoutOf(T) = shared(inout T);
 ///
@nogc nothrow pure @safe unittest
 {
    static assert(is(SharedInoutOf!int == shared inout int));
 }
 /**
 * Adds $(D_KEYWORD shared const) qualifier to the type $(D_PARAM T).
 *
 * Params:
 *  T = A type.
 *
 * Returns: $(D_INLINECODE shared(const T)).
 */
 alias SharedConstOf(T) = shared(const T);
 ///
@nogc nothrow pure @safe unittest
 {
    static assert(is(SharedConstOf!int == shared const int));
 }
 /**
 * Adds $(D_KEYWORD immutable) qualifier to the type $(D_PARAM T).
 *
 * Params:
 *  T = A type.
 *
 * Returns: $(D_INLINECODE immutable(T)).
 */
 alias ImmutableOf(T) = immutable(T);
 ///
@nogc nothrow pure @safe unittest
 {
    static assert(is(ImmutableOf!int == immutable int));
 }
 /**
 * Adds $(D_KEYWORD inout const) qualifier to the type $(D_PARAM T).
 *
 * Params:
 *  T = A type.
 *
 * Returns: $(D_INLINECODE inout(const T)).
 */
 alias InoutConstOf(T) = inout(const T);
 ///
@nogc nothrow pure @safe unittest
 {
    static assert(is(InoutConstOf!int == inout const int));
 }
 /**
 * Adds $(D_KEYWORD shared inout const) qualifier to the type $(D_PARAM T).
 *
 * Params:
 *  T = A type.
 *
 * Returns: $(D_INLINECODE shared(inout const T)).
 */
 alias SharedInoutConstOf(T) = shared(inout const T);
 ///
@nogc nothrow pure @safe unittest
 {
    static assert(is(SharedInoutConstOf!int == shared inout const int));
 }
 /**
 * Returns a template with one argument which applies all qualifiers of
 * $(D_PARAM T) on its argument if instantiated.
 *
 * Params:
 *  T = A type.
 *
 * Returns: $(D_INLINECODE shared(inout const T)).
 */
 template QualifierOf(T)
 {
    static if (is(T U == const U))
    {
        alias QualifierOf = ConstOf;
    }
    else static if (is(T U == immutable U))
    {
        alias QualifierOf = ImmutableOf;
    }
    else static if (is(T U == inout U))
    {
        alias QualifierOf = InoutOf;
    }
    else static if (is(T U == inout const U))
    {
        alias QualifierOf = InoutConstOf;
    }
    else static if (is(T U == shared U))
    {
        alias QualifierOf = SharedOf;
    }
    else static if (is(T U == shared const U))
    {
        alias QualifierOf = SharedConstOf;
    }
    else static if (is(T U == shared inout U))
    {
        alias QualifierOf = SharedInoutOf;
    }
    else static if (is(T U == shared inout const U))
    {
        alias QualifierOf = SharedInoutConstOf;
    }
    else
    {
        alias QualifierOf(T) = T;
    }
 }
 ///
@nogc nothrow pure @safe unittest
 {
    alias MutableOf = QualifierOf!int;
    static assert(is(MutableOf!uint == uint));
    alias ConstOf = QualifierOf!(const int);
    static assert(is(ConstOf!uint == const uint));
    alias InoutOf = QualifierOf!(inout int);
    static assert(is(InoutOf!uint == inout uint));
    alias InoutConstOf = QualifierOf!(inout const int);
    static assert(is(InoutConstOf!uint == inout const uint));
    alias ImmutableOf = QualifierOf!(immutable int);
    static assert(is(ImmutableOf!uint == immutable uint));
    alias SharedOf = QualifierOf!(shared int);
    static assert(is(SharedOf!uint == shared uint));
    alias SharedConstOf = QualifierOf!(shared const int);
    static assert(is(SharedConstOf!uint == shared const uint));
    alias SharedInoutOf = QualifierOf!(shared inout int);
    static assert(is(SharedInoutOf!uint == shared inout uint));
    alias SharedInoutConstOf = QualifierOf!(shared inout const int);
    static assert(is(SharedInoutConstOf!uint == shared inout const uint));
 }
 /**
 * Determines the type of $(D_PARAM T). If $(D_PARAM T) is already a type,
 * $(D_PSYMBOL TypeOf) aliases itself to $(D_PARAM T).
 *
 * $(D_PSYMBOL TypeOf) evaluates to $(D_KEYWORD void) for template arguments.
 *
 * The symbols that don't have a type and aren't types cannot be used as
 * arguments to $(D_PSYMBOL TypeOf).
 *
 * Params:
 *  T = Expression, type or template.
 *
 * Returns: The type of $(D_PARAM T).
 */
 alias TypeOf(T) = T;
 /// ditto
 template TypeOf(alias T)
 if (isExpressions!T || __traits(isTemplate, T))
 {
    alias TypeOf = typeof(T);
 }
 ///
@nogc nothrow pure @safe unittest
 {
    struct S(T)
    {
    }
    static assert(is(TypeOf!S == void));
    static assert(is(TypeOf!int == int));
    static assert(is(TypeOf!true == bool));
    static assert(!is(TypeOf!(tanya.meta)));
 }
 // e.g. returns int for int**.
 private template FinalPointerTarget(T)
 {
    static if (isPointer!T)
    {
        alias FinalPointerTarget = FinalPointerTarget!(PointerTarget!T);
    }
    else
    {
        alias FinalPointerTarget = T;
    }
 }
 // Returns true if T1 is void* and T2 is some pointer.
 private template voidAndPointer(T1, T2)
 {
    enum bool voidAndPointer = is(Unqual!(PointerTarget!T1) == void)
                            && isPointer!T2;
 }
 // Type returned by the ternary operator.
 private alias TernaryType(T, U) = typeof(true ? T.init : U.init);
 /**
 * Determines the type all $(D_PARAM Args) can be implicitly converted to.
 *
 * $(OL
 *  $(LI If one of the arguments is $(D_KEYWORD void), the common type is
 *       $(D_KEYWORD void).)
 *  $(LI The common type of integers with the same sign is the type with a
 *       larger size. Signed and unsigned integers don't have a common type.
 *       Type qualifiers are only preserved if all arguments are the same
 *       type.)
 *  $(LI The common type of floating point numbers is the type with more
 *       precision. Type qualifiers are only preserved if all arguments are
 *       the same type.)
 *  $(LI The common type of polymorphic objects is the next, more generic type
 *       both objects inherit from, e.g. $(D_PSYMBOL Object).)
 *  $(LI `void*` is concerned as a common type of pointers only if one of the
 *       arguments is a void pointer.)
 *  $(LI Other types have a common type only if their pointers have a common
 *       type. It means that for example $(D_KEYWORD bool) and $(D_KEYWORD int)
         don't have a common type. If the types fullfill this condition, the
         common type is determined with the ternary operator, i.e.
         `typeof(true ? T1.init : T2.init)` is evaluated.)
 * )
 *
 * If $(D_PARAM Args) don't have a common type, $(D_PSYMBOL CommonType) is
 * $(D_KEYWORD void).
 *
 * Params:
 *  Args = Type list.
 *
 * Returns: Common type for $(D_PARAM Args) or $(D_KEYWORD void) if
 *          $(D_PARAM Args) don't have a common type.
 */
 template CommonType(Args...)
 if (allSatisfy!(isType, Args))
 {
    static if (Args.length == 0
            || is(Unqual!(Args[0]) == void)
            || is(Unqual!(Args[1]) == void))
    {
        alias CommonType = void;
    }
    else static if (Args.length == 1)
    {
        alias CommonType = Args[0];
    }
    else
    {
        private alias Pair = Args[0 .. 2];
        private enum bool sameSigned = allSatisfy!(isIntegral, Pair)
                                    && isSigned!(Args[0]) == isSigned!(Args[1]);
        static if (is(Args[0] == Args[1]))
        {
            alias CommonType = CommonType!(Args[0], Args[2 .. $]);
        }
        else static if (sameSigned || allSatisfy!(isFloatingPoint, Pair))
        {
            alias CommonType = CommonType!(Unqual!(Largest!Pair),
                                           Args[2 .. $]);
        }
        else static if (voidAndPointer!Pair
                     || voidAndPointer!(Args[1], Args[0]))
        {
            // Workaround for https://issues.dlang.org/show_bug.cgi?id=15557.
            // Determine the qualifiers returned by the ternary operator as if
            // both pointers were int*. Then copy the qualifiers to void*.
            alias P1 = CopyTypeQualifiers!(FinalPointerTarget!(Args[0]), int)*;
            alias P2 = CopyTypeQualifiers!(FinalPointerTarget!(Args[1]), int)*;
            static if (is(TernaryType!(P1, P2) U))
            {
                alias CommonType = CopyTypeQualifiers!(PointerTarget!U, void)*;
            }
            else
            {
                alias CommonType = void;
            }
        }
        else static if ((isPointer!(Args[0]) || isPolymorphicType!(Args[0]))
                     && is(TernaryType!Pair U))
        {
            alias CommonType = CommonType!(U, Args[2 .. $]);
        }
        else static if (is(TernaryType!(Args[0]*, Args[1]*)))
        {
            alias CommonType = CommonType!(TernaryType!Pair, Args[2 .. $]);
        }
        else
        {
            alias CommonType = void;
        }
    }
 }
 ///
@nogc nothrow pure @safe unittest
 {
    static assert(is(CommonType!(int, int, int) == int));
    static assert(is(CommonType!(ubyte, ushort, uint) == uint));
    static assert(is(CommonType!(int, uint) == void));
    static assert(is(CommonType!(int, const int) == int));
    static assert(is(CommonType!(const int, const int) == const int));
    static assert(is(CommonType!(int[], const(int)[]) == const(int)[]));
    static assert(is(CommonType!(string, char[]) == const(char)[]));
    class A
    {
    }
    static assert(is(CommonType!(const A, Object) == const Object));
 }
@nogc nothrow pure @safe unittest
 {
    static assert(is(CommonType!(void*, int*) == void*));
    static assert(is(CommonType!(void*, const(int)*) == const(void)*));
    static assert(is(CommonType!(void*, const(void)*) == const(void)*));
    static assert(is(CommonType!(int*, void*) == void*));
    static assert(is(CommonType!(const(int)*, void*) == const(void)*));
    static assert(is(CommonType!(const(void)*, void*) == const(void)*));
    static assert(is(CommonType!() == void));
    static assert(is(CommonType!(int*, const(int)*) == const(int)*));
    static assert(is(CommonType!(int**, const(int)**) == const(int*)*));
    static assert(is(CommonType!(float, double) == double));
    static assert(is(CommonType!(float, int) == void));
    static assert(is(CommonType!(bool, const bool) == bool));
    static assert(is(CommonType!(int, bool) == void));
    static assert(is(CommonType!(int, void) == void));
    static assert(is(CommonType!(Object, void*) == void));
    class A
    {
    }
    static assert(is(CommonType!(A, Object) == Object));
    static assert(is(CommonType!(const(A)*, Object*) == const(Object)*));
    static assert(is(CommonType!(A, typeof(null)) == A));
    class B : A
    {
    }
    class C : A
    {
    }
    static assert(is(CommonType!(B, C) == A));
    static struct S
    {
        int opCast(T : int)()
        {
            return 1;
        }
    }
    static assert(is(CommonType!(S, int) == void));
    static assert(is(CommonType!(const S, S) == const S));
 }
 /**
 * Finds the type with the smallest size in the $(D_PARAM Args) list. If
 * several types have the same type, the leftmost is returned.
 *
 * Params:
 *  Args = Type list.
 *
 * Returns: The smallest type.
 *
 * See_Also: $(D_PSYMBOL Largest).
 */
 template Smallest(Args...)
 if (Args.length >= 1)
 {
    static assert(is(Args[0]), T.stringof ~ " doesn't have .sizeof property");
    static if (Args.length == 1)
    {
        alias Smallest = Args[0];
    }
    else static if (Smallest!(Args[1 .. $]).sizeof < Args[0].sizeof)
    {
        alias Smallest = Smallest!(Args[1 .. $]);
    }
    else
    {
        alias Smallest = Args[0];
    }
 }
 ///
@nogc nothrow pure @safe unittest
 {
    static assert(is(Smallest!(int, ushort, uint, short) == ushort));
    static assert(is(Smallest!(short) == short));
    static assert(is(Smallest!(ubyte[8], ubyte[5]) == ubyte[5]));
    static assert(!is(Smallest!(short, 5)));
 }
 /**
 * Finds the type with the largest size in the $(D_PARAM Args) list. If several
 * types have the same type, the leftmost is returned.
 *
 * Params:
 *  Args = Type list.
 *
 * Returns: The largest type.
 *
 * See_Also: $(D_PSYMBOL Smallest).
 */
 template Largest(Args...)
 if (Args.length >= 1)
 {
    static assert(is(Args[0]), T.stringof ~ " doesn't have .sizeof property");
    static if (Args.length == 1)
    {
        alias Largest = Args[0];
    }
    else static if (Largest!(Args[1 .. $]).sizeof > Args[0].sizeof)
    {
        alias Largest = Largest!(Args[1 .. $]);
    }
    else
    {
        alias Largest = Args[0];
    }
 }
 ///
@nogc nothrow pure @safe unittest
 {
    static assert(is(Largest!(int, short, uint) == int));
    static assert(is(Largest!(short) == short));
    static assert(is(Largest!(ubyte[8], ubyte[5]) == ubyte[8]));
    static assert(!is(Largest!(short, 5)));
 }
--- a/source/tanya/net/inet.d
+++ b/source/tanya/net/inet.d
@ -0,0 +1,245 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * Internet utilities.
 *
 * Copyright: Eugene Wissner 2016-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/net/inet.d,
 *                 tanya/net/inet.d)
 */
 module tanya.net.inet;
 import tanya.meta.trait;
 import tanya.meta.transform;
 import tanya.range.primitive;
 /**
 * Represents an unsigned integer as an $(D_KEYWORD ubyte) range.
 *
 * The range is bidirectional. The byte order is always big-endian.
 *
 * It can accept any unsigned integral type but the value should fit
 * in $(D_PARAM L) bytes.
 *
 * Params:
 *  L = Desired range length.
 */
 struct NetworkOrder(uint L)
 if (L > ubyte.sizeof && L <= ulong.sizeof)
 {
    static if (L > uint.sizeof)
    {
        private alias StorageType = ulong;
    }
    else static if (L > ushort.sizeof)
    {
        private alias StorageType = uint;
    }
    else static if (L > ubyte.sizeof)
    {
        private alias StorageType = ushort;
    }
    else
    {
        private alias StorageType = ubyte;
    }
    private StorageType value;
    private size_t size = L;
    invariant
    {
        assert(this.size <= L);
    }
    /**
     * Constructs a new range.
     *
     * $(D_PARAM T) can be any unsigned type but $(D_PARAM value) cannot be
     * larger than the maximum can be stored in $(D_PARAM L) bytes. Otherwise
     * an assertion failure will be caused.
     *
     * Params:
     *  T      = Value type.
     *  value  = The value should be represented by this range.
     *
     * Precondition: $(D_INLINECODE value <= (2 ^^ (L * 8)) - 1).
     */
    this(T)(T value)
    if (isUnsigned!T)
    in
    {
        assert(value <= (2 ^^ (L * 8)) - 1);
    }
    do
    {
        this.value = value & StorageType.max;
    }
    /**
     * Returns: LSB.
     *
     * Precondition: $(D_INLINECODE length > 0).
     */
    @property ubyte back() const
    in
    {
        assert(this.length > 0);
    }
    do
    {
        return this.value & 0xff;
    }
    /**
     * Returns: MSB.
     *
     * Precondition: $(D_INLINECODE length > 0).
     */
    @property ubyte front() const
    in
    {
        assert(this.length > 0);
    }
    do
    {
        return (this.value >> ((this.length - 1) * 8)) & 0xff;
    }
    /**
     * Eliminates the LSB.
     *
     * Precondition: $(D_INLINECODE length > 0).
     */
    void popBack()
    in
    {
        assert(this.length > 0);
    }
    do
    {
        this.value >>= 8;
        --this.size;
    }
    /**
     * Eliminates the MSB.
     *
     * Precondition: $(D_INLINECODE length > 0).
     */
    void popFront()
    in
    {
        assert(this.length > 0);
    }
    do
    {
        this.value &= StorageType.max >> ((StorageType.sizeof - this.length) * 8);
        --this.size;
    }
    /**
     * Returns: Copy of this range.
     */
    typeof(this) save() const
    {
        return this;
    }
    /**
     * Returns: Whether the range is empty.
     */
    @property bool empty() const
    {
        return this.length == 0;
    }
    /**
     * Returns: Byte length.
     */
    @property size_t length() const
    {
        return this.size;
    }
 }
 ///
@nogc nothrow pure @safe unittest
 {
    auto networkOrder = NetworkOrder!3(0xae34e2u);
    assert(!networkOrder.empty);
    assert(networkOrder.front == 0xae);
    networkOrder.popFront();
    assert(networkOrder.length == 2);
    assert(networkOrder.front == 0x34);
    assert(networkOrder.back == 0xe2);
    networkOrder.popBack();
    assert(networkOrder.length == 1);
    assert(networkOrder.front == 0x34);
    assert(networkOrder.front == 0x34);
    networkOrder.popFront();
    assert(networkOrder.empty);
 }
 // Static tests
@nogc nothrow pure @safe unittest
 {
    static assert(isBidirectionalRange!(NetworkOrder!4));
    static assert(isBidirectionalRange!(NetworkOrder!8));
    static assert(!is(NetworkOrder!9));
    static assert(!is(NetworkOrder!1));
 }
 /**
 * Converts the $(D_KEYWORD ubyte) input range $(D_PARAM range) to
 * $(D_PARAM T).
 *
 * The byte order of $(D_PARAM r) is assumed to be big-endian. The length
 * cannot be larger than $(D_INLINECODE T.sizeof). Otherwise an assertion
 * failure will be caused.
 *
 * Params:
 *  T     = Desired return type.
 *  R     = Range type.
 *  range = Input range.
 *
 * Returns: Integral representation of $(D_PARAM range) with the host byte
 *          order.
 */
 T toHostOrder(T = size_t, R)(R range)
 if (isInputRange!R
 && !isInfinite!R
 && is(Unqual!(ElementType!R) == ubyte)
 && isUnsigned!T)
 {
    T ret;
    ushort pos = T.sizeof * 8;
    for (; !range.empty && range.front == 0; pos -= 8, range.popFront())
    {
    }
    for (; !range.empty; range.popFront())
    {
        assert(pos != 0);
        pos -= 8;
        ret |= (cast(T) range.front) << pos;
    }
    return ret >> pos;
 }
 ///
@nogc nothrow pure @safe unittest
 {
    const value = 0xae34e2u;
    auto networkOrder = NetworkOrder!4(value);
    assert(networkOrder.toHostOrder() == value);
 }
--- a/source/tanya/net/package.d
+++ b/source/tanya/net/package.d
@ -0,0 +1,18 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * Network programming.
 *
 * Copyright: Eugene Wissner 2017-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/net/package.d,
 *                 tanya/net/package.d)
 */
 module tanya.net;
 public import tanya.net.inet;
 public import tanya.net.uri;
--- a/source/tanya/net/uri.d
+++ b/source/tanya/net/uri.d
@ -0,0 +1,500 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * URL parser.
 *
 * Copyright: Eugene Wissner 2017-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/net/uri.d,
 *                 tanya/net/uri.d)
 */
 module tanya.net.uri;
 import tanya.conv;
 import tanya.encoding.ascii;
 import tanya.memory;
 version (unittest)
 {
    import tanya.test.assertion;
 }
 /**
 * Thrown if an invalid URI was specified.
 */
 final class URIException : Exception
 {
    /**
     * Params:
     *  msg  = The message for the exception.
     *  file = The file where the exception occurred.
     *  line = The line number where the exception occurred.
     *  next = The previous exception in the chain of exceptions, if any.
     */
    this(string msg,
         string file = __FILE__,
         size_t line = __LINE__,
         Throwable next = null) @nogc nothrow pure @safe
    {
        super(msg, file, line, next);
    }
 }
 /**
 * A Unique Resource Locator.
 */
 struct URL
 {
    /// The URL scheme.
    const(char)[] scheme;
    /// The username.
    const(char)[] user;
    /// The password.
    const(char)[] pass;
    /// The hostname.
    const(char)[] host;
    /// The port number.
    ushort port;
    /// The path.
    const(char)[] path;
    /// The query string.
    const(char)[] query;
    /// The anchor.
    const(char)[] fragment;
    /**
     * Attempts to parse an URL from a string.
     * Output string data (scheme, user, etc.) are just slices of input string
     * (i.e., no memory allocation and copying).
     *
     * Params:
     *  source = The string containing the URL.
     *
     * Throws: $(D_PSYMBOL URIException) if the URL is malformed.
     */
    this(const char[] source) @nogc pure
    {
        ptrdiff_t pos = -1, endPos = source.length, start;
        foreach (i, ref c; source)
        {
            if (pos == -1 && c == ':')
            {
                pos = i;
            }
            if (endPos == source.length && (c == '?' || c == '#'))
            {
                endPos = i;
            }
        }
        // Check if the colon is a part of the scheme or the port and parse
        // the appropriate part.
        if (source.length > 1 && source[0] == '/' && source[1] == '/')
        {
            // Relative scheme.
            start = 2;
        }
        else if (pos > 0)
        {
            // Validate scheme:
            // [ toLower(alpha) | digit | "+" | "-" | "." ]
            foreach (ref c; source[0 .. pos])
            {
                if (!c.isAlphaNum && c != '+' && c != '-' && c != '.')
                {
                    goto ParsePath;
                }
            }
            if (source.length == pos + 1) // only "scheme:" is available.
            {
                this.scheme = source[0 .. $ - 1];
                return;
            }
            else if (source.length > pos + 1 && source[pos + 1] == '/')
            {
                this.scheme = source[0 .. pos];
                if (source.length > pos + 2 && source[pos + 2] == '/')
                {
                    start = pos + 3;
                    if (source.length <= start)
                    {
                        // Only "scheme://" is available.
                        return;
                    }
                    if (this.scheme == "file" && source[start] == '/')
                    {
                        // Windows drive letters.
                        if (source.length - start > 2
                         && source[start + 2] == ':')
                        {
                            ++start;
                        }
                        goto ParsePath;
                    }
                }
                else
                {
                    start = pos + 1;
                    goto ParsePath;
                }
            }
            else if (!parsePort(source[pos .. $]))
            {
                // Schemas like mailto: and zlib: may not have any slash after
                // them.
                this.scheme = source[0 .. pos];
                start = pos + 1;
                goto ParsePath;
            }
        }
        else if (pos == 0 && parsePort(source[pos .. $]))
        {
            // An URL shouldn't begin with a port number.
            throw defaultAllocator.make!URIException("URL begins with port");
        }
        else
        {
            goto ParsePath;
        }
        // Parse host.
        pos = -1;
        for (ptrdiff_t i = start; i < source.length; ++i)
        {
            if (source[i] == '@')
            {
                pos = i;
            }
            else if (source[i] == '/')
            {
                endPos = i;
                break;
            }
        }
        // Check for login and password.
        if (pos != -1)
        {
            // *( unreserved / pct-encoded / sub-delims / ":" )
            foreach (i, c; source[start .. pos])
            {
                if (c == ':')
                {
                    if (this.user is null)
                    {
                        this.user = source[start .. start + i];
                        this.pass = source[start + i + 1 .. pos]; 
                    }
                }
                else if (!c.isAlpha() &&
                         !c.isDigit() &&
                         c != '!' &&
                         c != ';' &&
                         c != '=' &&
                         c != '_' &&
                         c != '~' &&
                         !(c >= '$' && c <= '.'))
                {
                    this.scheme = this.user = this.pass = null;
                    throw make!URIException(defaultAllocator,
                                            "Restricted characters in user information");
                }
            }
            if (this.user is null)
            {
                this.user = source[start .. pos];
            }
            start = ++pos;
        }
        pos = endPos;
        if (endPos <= 1 || source[start] != '[' || source[endPos - 1] != ']')
        {
            // Short circuit portscan.
            // IPv6 embedded address.
            for (ptrdiff_t i = endPos - 1; i >= start; --i)
            {
                if (source[i] == ':')
                {
                    pos = i;
                    if  (this.port == 0 && !parsePort(source[i .. endPos]))
                    {
                        this.scheme = this.user = this.pass = null;
                        throw defaultAllocator.make!URIException("Invalid port");
                    }
                    break;
                }
            }
        }
        // Check if we have a valid host, if we don't reject the string as URL.
        if (pos <= start)
        {
            this.scheme = this.user = this.pass = null;
            throw defaultAllocator.make!URIException("Invalid host");
        }
        this.host = source[start .. pos];
        if (endPos == source.length)
        {
            return;
        }
        start = endPos;
    ParsePath:
        endPos = source.length;
        pos = -1;
        foreach (i, ref c; source[start .. $])
        {
            if (c == '?' && pos == -1)
            {
                pos = start + i;
            }
            else if (c == '#')
            {
                endPos = start + i;
                break;
            }
        }
        if (pos == -1)
        {
            pos = endPos;
        }
        if (pos > start)
        {
            this.path = source[start .. pos];
        }
        if (endPos >= ++pos)
        {
            this.query = source[pos .. endPos];
        }
        if (++endPos <= source.length)
        {
            this.fragment = source[endPos .. $];
        }
    }
    /*
     * Attempts to parse and set the port.
     *
     * Params:
     *  port = String beginning with a colon followed by the port number and
     *         an optional path (query string and/or fragment), like:
     *         `:12345/some_path` or `:12345`.
     *
     * Returns: Whether the port could be found.
     */
    private bool parsePort(const(char)[] port) @nogc nothrow pure @safe
    {
        auto unparsed = port[1 .. $];
        auto parsed = readIntegral!ushort(unparsed);
        if (unparsed.length == 0 || unparsed[0] == '/')
        {
            this.port = parsed;
            return true;
        }
        return false;
    }
 }
 ///
@nogc pure @system unittest
 {
    auto u = URL("example.org");
    assert(u.path == "example.org"); 
    u = URL("relative/path");
    assert(u.path == "relative/path"); 
    // Host and scheme
    u = URL("https://example.org");
    assert(u.scheme == "https");
    assert(u.host == "example.org");
    assert(u.path is null);
    assert(u.port == 0);
    assert(u.fragment is null);
    // With user and port and path
    u = URL("https://hilary:putnam@example.org:443/foo/bar");
    assert(u.scheme == "https");
    assert(u.host == "example.org");
    assert(u.path == "/foo/bar");
    assert(u.port == 443);
    assert(u.user == "hilary");
    assert(u.pass == "putnam");
    assert(u.fragment is null);
    // With query string
    u = URL("https://example.org/?login=true");
    assert(u.scheme == "https");
    assert(u.host == "example.org");
    assert(u.path == "/");
    assert(u.query == "login=true");
    assert(u.fragment is null);
    // With query string and fragment
    u = URL("https://example.org/?login=false#label");
    assert(u.scheme == "https");
    assert(u.host == "example.org");
    assert(u.path == "/");
    assert(u.query == "login=false");
    assert(u.fragment == "label");
    u = URL("redis://root:password@localhost:2201/path?query=value#fragment");
    assert(u.scheme == "redis");
    assert(u.user == "root");
    assert(u.pass == "password");
    assert(u.host == "localhost");
    assert(u.port == 2201);
    assert(u.path == "/path");
    assert(u.query == "query=value");
    assert(u.fragment == "fragment");
 }
@nogc pure @system unittest
 {
    auto u = URL("127.0.0.1");
    assert(u.path == "127.0.0.1");
    u = URL("http://127.0.0.1");
    assert(u.scheme == "http");
    assert(u.host == "127.0.0.1");
    u = URL("http://127.0.0.1:9000");
    assert(u.scheme == "http");
    assert(u.host == "127.0.0.1");
    assert(u.port == 9000);
    u = URL("127.0.0.1:80");
    assert(u.host == "127.0.0.1");
    assert(u.port == 80);
    assert(u.path is null);
    u = URL("//example.net");
    assert(u.host == "example.net");
    assert(u.scheme is null);
    u = URL("//example.net?q=before:after");
    assert(u.host == "example.net");
    assert(u.query == "q=before:after");
    u = URL("localhost:8080");
    assert(u.host == "localhost");
    assert(u.port == 8080);
    assert(u.path is null);
    u = URL("ftp:");
    assert(u.scheme == "ftp");
    u = URL("file:///C:\\Users");
    assert(u.scheme == "file");
    assert(u.path == "C:\\Users");
    u = URL("localhost:66000");
    assert(u.scheme == "localhost");
    assert(u.path == "66000");
    u = URL("file:///home/");
    assert(u.scheme == "file");
    assert(u.path == "/home/");
    u = URL("file:///home/?q=asdf");
    assert(u.scheme == "file");
    assert(u.path == "/home/");
    assert(u.query == "q=asdf");
    u = URL("http://secret@example.org");
    assert(u.scheme == "http");
    assert(u.host == "example.org");
    assert(u.user == "secret");
    u = URL("h_tp://:80");
    assert(u.path == "h_tp://:80");
    assert(u.port == 0);
    u = URL("zlib:/home/user/file.gz");
    assert(u.scheme == "zlib");
    assert(u.path == "/home/user/file.gz");
    u = URL("h_tp:asdf");
    assert(u.path == "h_tp:asdf");
 }
@nogc pure @system unittest
 {
    assertThrown!URIException(() => URL("http://:80"));
    assertThrown!URIException(() => URL(":80"));
    assertThrown!URIException(() => URL("http://u1:p1@u2:p2@example.org"));
    assertThrown!URIException(() => URL("http://blah.com:port"));
    assertThrown!URIException(() => URL("http://blah.com:66000"));
 }
@nogc pure @system unittest
 {
    auto u = URL("ftp://");
    assert(u.scheme == "ftp");
 }
 /**
 * Attempts to parse an URL from a string and returns the specified component
 * of the URL or $(D_PSYMBOL URL) if no component is specified.
 *
 * Params:
 *  T      = "scheme", "host", "port", "user", "pass", "path", "query",
 *           "fragment".
 *  source = The string containing the URL.
 *
 * Returns: Requested URL component.
 */
 auto parseURL(string T)(const char[] source)
 if (T == "scheme"
 || T == "host"
 || T == "user"
 || T == "pass"
 || T == "path"
 || T == "query"
 || T == "fragment"
 || T == "port")
 {
    auto ret = URL(source);
    return mixin("ret." ~ T);
 }
 /// ditto
 URL parseURL(const char[] source) @nogc pure
 {
    return URL(source);
 }
 ///
@nogc pure @system unittest
 {
    auto u = parseURL("http://example.org:5326");
    assert(u.scheme == parseURL!"scheme"("http://example.org:5326"));
    assert(u.host == parseURL!"host"("http://example.org:5326"));
    assert(u.user == parseURL!"user"("http://example.org:5326"));
    assert(u.pass == parseURL!"pass"("http://example.org:5326"));
    assert(u.path == parseURL!"path"("http://example.org:5326"));
    assert(u.query == parseURL!"query"("http://example.org:5326"));
    assert(u.fragment == parseURL!"fragment"("http://example.org:5326"));
    assert(u.port == parseURL!"port"("http://example.org:5326"));
 }
--- a/source/tanya/network/package.d
+++ b/source/tanya/network/package.d
@ -0,0 +1,17 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * Network programming.
 *
 * Copyright: Eugene Wissner 2016-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/network/package.d,
 *                 tanya/network/package.d)
 */
 module tanya.network;
 public import tanya.network.socket;
--- a/source/tanya/network/socket.d
+++ b/source/tanya/network/socket.d
--- a/source/tanya/network/url.d
+++ b/source/tanya/network/url.d
--- a/source/tanya/os/error.d
+++ b/source/tanya/os/error.d
@ -0,0 +1,419 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * This module provides a portable way of using operating system error codes.
 *
 * Copyright: Eugene Wissner 2017-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/os/error.d,
 *                 tanya/os/error.d)
 */
 module tanya.os.error;
 import tanya.meta.trait;
 // Socket API error.
 private template SAError(int posix, int wsa = posix)
 {
    version (Windows)
    {
        enum SAError = 10000 + wsa;
    }
    else
    {
        alias SAError = posix;
    }
 }
 // Error for Windows and Posix separately.
 private template NativeError(int posix, int win)
 {
    version (Windows)
    {
        alias NativeError = win;
    }
    else
    {
        alias NativeError = posix;
    }
 }
 version (Windows)
 {
    private enum eProtocolError = -71;
 }
 else version (OpenBSD)
 {
    private enum eProtocolError = -71;
 }
 else
 {
    private enum eProtocolError = 71;
 }
 /**
 * System error code.
 */
 struct ErrorCode
 {
    /**
     * Error code numbers.
     */
    enum ErrorNo : int
    {
        /// The operation completed successfully.
        success                   = 0,
        /// Operation not permitted.
        noPermission              = NativeError!(1, 5),
        /// Interrupted system call.
        interrupted               = SAError!4,
        /// Bad file descriptor.
        badDescriptor             = SAError!9,
        /// An operation on a non-blocking socket would block.
        wouldBlock                = SAError!(11, 35),
        /// Out of memory.
        noMemory                  = NativeError!(12, 14),
        /// Access denied.
        accessDenied              = SAError!13,
        /// An invalid pointer address detected.
        fault                     = SAError!14,
        /// No such device.
        noSuchDevice              = NativeError!(19, 20),
        /// An invalid argument was supplied.
        invalidArgument           = SAError!22,
        /// The limit on the number of open file descriptors.
        tooManyDescriptors        = NativeError!(23, 331),
        /// The limit on the number of open file descriptors.
        noDescriptors             = SAError!24,
        /// Broken pipe.
        brokenPipe                = NativeError!(32, 109),
        /// The name was too long.
        nameTooLong               = SAError!(36, 63),
        /// A socket operation was attempted on a non-socket.
        notSocket                 = SAError!(88, 38),
        /// Protocol error.
        protocolError             = eProtocolError,
        /// Message too long.
        messageTooLong            = SAError!(90, 40),
        /// Wrong protocol type for socket.
        wrongProtocolType         = SAError!(91, 41),
        /// Protocol not available.
        noProtocolOption          = SAError!(92, 42),
        /// The protocol is not implemented or has not been configured.
        protocolNotSupported      = SAError!(93, 43),
        /// The support for the specified socket type does not exist in this
        /// address family.
        socketNotSupported        = SAError!(94, 44),
        /// The address family is no supported by the protocol family.
        operationNotSupported     = SAError!(95, 45),
        /// Address family specified is not supported.
        addressFamilyNotSupported = SAError!(97, 47),
        /// Address already in use.
        addressInUse              = SAError!(98, 48),
        /// The network is not available.
        networkDown               = SAError!(100, 50),
        /// No route to host.
        networkUnreachable        = SAError!(101, 51),
        /// Network dropped connection because of reset.
        networkReset              = SAError!(102, 52),
        /// The connection has been aborted.
        connectionAborted         = SAError!(103, 53),
        /// Connection reset by peer.
        connectionReset           = SAError!(104, 54),
        /// No free buffer space is available for a socket operation.
        noBufferSpace             = SAError!(105, 55),
        /// Transport endpoint is already connected.
        alreadyConnected          = SAError!(106, 56),
        /// Transport endpoint is not connected.
        notConnected              = SAError!(107, 57),
        /// Cannot send after transport endpoint shutdown.
        shutdown                  = SAError!(108, 58),
        /// The connection attempt timed out, or the connected host has failed
        /// to respond.
        timedOut                  = SAError!(110, 60),
        /// Connection refused.
        connectionRefused         = SAError!(111, 61),
        /// Host is down.
        hostDown                  = SAError!(112, 64),
        /// No route to host.
        hostUnreachable           = SAError!(113, 65),
        /// Operation already in progress.
        alreadyStarted            = SAError!(114, 37),
        /// Operation now in progress.
        inProgress                = SAError!(115, 36),
        /// Operation cancelled.
        cancelled                 = SAError!(125, 103),
    }
    /**
     * Error descriptions.
     */
    private enum ErrorStr : string
    {
        success                   = "The operation completed successfully",
        noPermission              = "Operation not permitted",
        interrupted               = "Interrupted system call",
        badDescriptor             = "Bad file descriptor",
        wouldBlock                = "An operation on a non-blocking socket would block",
        noMemory                  = "Out of memory",
        accessDenied              = "Access denied",
        fault                     = "An invalid pointer address detected",
        noSuchDevice              = "No such device",
        invalidArgument           = "An invalid argument was supplied",
        tooManyDescriptors        = "The limit on the number of open file descriptors",
        noDescriptors             = "The limit on the number of open file descriptors",
        brokenPipe                = "Broken pipe",
        nameTooLong               = "The name was too long",
        notSocket                 = "A socket operation was attempted on a non-socket",
        protocolError             = "Protocol error",
        messageTooLong            = "Message too long",
        wrongProtocolType         = "Wrong protocol type for socket",
        noProtocolOption          = "Protocol not available",
        protocolNotSupported      = "The protocol is not implemented or has not been configured",
        socketNotSupported        = "Socket type not supported",
        operationNotSupported     = "The address family is no supported by the protocol family",
        addressFamilyNotSupported = "Address family specified is not supported",
        addressInUse              = "Address already in use",
        networkDown               = "The network is not available",
        networkUnreachable        = "No route to host",
        networkReset              = "Network dropped connection because of reset",
        connectionAborted         = "The connection has been aborted",
        connectionReset           = "Connection reset by peer",
        noBufferSpace             = "No free buffer space is available for a socket operation",
        alreadyConnected          = "Transport endpoint is already connected",
        notConnected              = "Transport endpoint is not connected",
        shutdown                  = "Cannot send after transport endpoint shutdown",
        timedOut                  = "Operation timed out",
        connectionRefused         = "Connection refused",
        hostDown                  = "Host is down",
        hostUnreachable           = "No route to host",
        alreadyStarted            = "Operation already in progress",
        inProgress                = "Operation now in progress",
        cancelled                 = "Operation cancelled",
    }
    /**
     * Constructor.
     *
     * Params:
     *  value = Numeric error code.
     */
    this(const ErrorNo value) @nogc nothrow pure @safe
    {
        this.value_ = value;
    }
    ///
    @nogc nothrow pure @safe unittest
    {
        ErrorCode ec;
        assert(ec == ErrorCode.success);
        ec = ErrorCode.fault;
        assert(ec == ErrorCode.fault);
    }
    /**
     * Resets this $(D_PSYMBOL ErrorCode) to default
     * ($(D_PSYMBOL ErrorCode.success)).
     */
    void reset() @nogc nothrow pure @safe
    {
        this.value_ = ErrorNo.success;
    }
    ///
    @nogc nothrow pure @safe unittest
    {
        auto ec = ErrorCode(ErrorCode.fault);
        assert(ec == ErrorCode.fault);
        ec.reset();
        assert(ec == ErrorCode.success);
    }
    /**
     * Returns: Numeric error code.
     */
    ErrorNo opCast(T : ErrorNo)() const
    {
        return this.value_;
    }
    /// ditto
    ErrorNo opCast(T : int)() const
    {
        return this.value_;
    }
    ///
    @nogc nothrow pure @safe unittest
    {
        ErrorCode ec = ErrorCode.fault;
        auto errorNo = cast(ErrorCode.ErrorNo) ec;
        assert(errorNo == ErrorCode.fault);
        static assert(is(typeof(cast(int) ec)));
    }
    /**
     * Assigns another error code or error code number.
     *
     * Params:
     *  that = Numeric error code.
     *
     * Returns: $(D_KEYWORD this).
     */
    ref ErrorCode opAssign(const ErrorNo that) @nogc nothrow pure @safe
    {
        this.value_ = that;
        return this;
    }
    /// ditto
    ref ErrorCode opAssign(const ErrorCode that) @nogc nothrow pure @safe
    {
        this.value_ = that.value_;
        return this;
    }
    ///
    @nogc nothrow pure @safe unittest
    {
        ErrorCode ec;
        assert(ec == ErrorCode.success);
        ec = ErrorCode.fault;
        assert(ec == ErrorCode.fault);
    }
    ///
    @nogc nothrow pure @safe unittest
    {
        auto ec1 = ErrorCode(ErrorCode.fault);
        ErrorCode ec2;
        assert(ec2 == ErrorCode.success);
        ec2 = ec1;
        assert(ec1 == ec2);
    }
    /**
     * Equality with another error code or error code number.
     *
     * Params:
     *  that = Numeric error code.
     *
     * Returns: Whether $(D_KEYWORD this) and $(D_PARAM that) are equal.
     */
    bool opEquals(const ErrorNo that) const @nogc nothrow pure @safe
    {
        return this.value_ == that;
    }
    /// ditto
    bool opEquals(const ErrorCode that) const @nogc nothrow pure @safe
    {
        return this.value_ == that.value_;
    }
    ///
    @nogc nothrow pure @safe unittest
    {
        ErrorCode ec1 = ErrorCode.fault;
        ErrorCode ec2 = ErrorCode.accessDenied;
        assert(ec1 != ec2);
        assert(ec1 != ErrorCode.accessDenied);
        assert(ErrorCode.fault != ec2);
    }
    ///
    @nogc nothrow pure @safe unittest
    {
        ErrorCode ec1 = ErrorCode.fault;
        ErrorCode ec2 = ErrorCode.fault;
        assert(ec1 == ec2);
        assert(ec1 == ErrorCode.fault);
        assert(ErrorCode.fault == ec2);
    }
    /**
     * Returns string describing the error number. If a description for a
     * specific error number is not available, returns $(D_KEYWORD null).
     *
     * Returns: String describing the error number.
     */
    string toString() const @nogc nothrow pure @safe
    {
        foreach (e; __traits(allMembers, ErrorNo))
        {
            if (__traits(getMember, ErrorNo, e) == this.value_)
            {
                return __traits(getMember, ErrorStr, e);
            }
        }
        return null;
    }
    ///
    @nogc nothrow pure @safe unittest
    {
        ErrorCode ec = ErrorCode.fault;
        assert(ec.toString() == "An invalid pointer address detected");
    }
    @nogc nothrow pure @safe unittest
    {
        ErrorCode ec = cast(ErrorCode.ErrorNo) -1;
        assert(ec.toString() is null);
    }
    private ErrorNo value_ = ErrorNo.success;
    alias ErrorNo this;
 }
--- a/source/tanya/os/package.d
+++ b/source/tanya/os/package.d
@ -0,0 +1,18 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * This package provides platform-independent interfaces to operating system
 * functionality.
 *
 * Copyright: Eugene Wissner 2017-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/os/package.d,
 *                 tanya/os/package.d)
 */
 module tanya.os;
 public import tanya.os.error;
--- a/source/tanya/range/adapter.d
+++ b/source/tanya/range/adapter.d
@ -0,0 +1,375 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * Range adapters.
 *
 * A range adapter wraps another range and modifies the way, how the original
 * range is iterated, or the order in which its elements are accessed.
 *
 * All adapters are lazy algorithms, they request the next element of the
 * adapted range on demand.
 *
 * Copyright: Eugene Wissner 2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/range/adapter.d,
 *                 tanya/range/adapter.d)
 */
 module tanya.range.adapter;
 import tanya.algorithm.mutation;
 import tanya.math;
 import tanya.range.primitive;
 private mixin template Take(R, bool exactly)
 {
    private R source;
    size_t length_;
    @disable this();
    private this(R source, size_t length)
    {
        this.source = source;
        static if (!exactly && hasLength!R)
        {
            this.length_ = min(source.length, length);
        }
        else
        {
            this.length_ = length;
        }
    }
    @property auto ref front()
    in
    {
        assert(!empty);
    }
    do
    {
        return this.source.front;
    }
    void popFront()
    in
    {
        assert(!empty);
    }
    do
    {
        this.source.popFront();
        --this.length_;
    }
    @property bool empty()
    {
        static if (exactly || isInfinite!R)
        {
            return length == 0;
        }
        else
        {
            return length == 0 || this.source.empty;
        }
    }
    @property size_t length()
    {
        return this.length_;
    }
    static if (hasAssignableElements!R)
    {
        @property void front(ref ElementType!R value)
        in
        {
            assert(!empty);
        }
        do
        {
            this.source.front = value;
        }
        @property void front(ElementType!R value)
        in
        {
            assert(!empty);
        }
        do
        {
            this.source.front = move(value);
        }
    }
    static if (isForwardRange!R)
    {
        typeof(this) save()
        {
            return typeof(this)(this.source.save(), length);
        }
    }
    static if (isRandomAccessRange!R)
    {
        @property auto ref back()
        in
        {
            assert(!empty);
        }
        do
        {
            return this.source[this.length - 1];
        }
        void popBack()
        in
        {
            assert(!empty);
        }
        do
        {
            --this.length_;
        }
        auto ref opIndex(size_t i)
        in
        {
            assert(i < length);
        }
        do
        {
            return this.source[i];
        }
        static if (hasAssignableElements!R)
        {
            @property void back(ref ElementType!R value)
            in
            {
                assert(!empty);
            }
            do
            {
                this.source[length - 1] = value;
            }
            @property void back(ElementType!R value)
            in
            {
                assert(!empty);
            }
            do
            {
                this.source[length - 1] = move(value);
            }
            void opIndexAssign(ref ElementType!R value, size_t i)
            in
            {
                assert(i < length);
            }
            do
            {
                this.source[i] = value;
            }
            void opIndexAssign(ElementType!R value, size_t i)
            in
            {
                assert(i < length);
            }
            do
            {
                this.source[i] = move(value);
            }
        }
    }
    static if (hasSlicing!R)
    {
        auto opSlice(size_t i, size_t j)
        in
        {
            assert(i <= j);
            assert(j <= length);
        }
        do
        {
            return take(this.source[i .. j], length);
        }
    }
 }
 /**
 * Takes $(D_PARAM n) elements from $(D_PARAM range).
 *
 * If $(D_PARAM range) doesn't have $(D_PARAM n) elements, the resulting range
 * spans all elements of $(D_PARAM range).
 *
 * $(D_PSYMBOL take) is particulary useful with infinite ranges. You can take
 ` $(B n) elements from such range and pass the result to an algorithm which
 * expects a finit range.
 *
 * Params:
 *  R     = Type of the adapted range.
 *  range = The range to take the elements from.
 *  n     = The number of elements to take.
 *
 * Returns: A range containing maximum $(D_PARAM n) first elements of
 *          $(D_PARAM range).
 *
 * See_Also: $(D_PSYMBOL takeExactly).
 */
 auto take(R)(R range, size_t n)
 if (isInputRange!R)
 {
    struct Take
    {
        mixin .Take!(R, false);
    }
    return Take(range, n);
 }
 ///
@nogc nothrow pure @safe unittest
 {
    static struct InfiniteRange
    {
        private size_t front_ = 1;
        enum bool empty = false;
        @property size_t front() @nogc nothrow pure @safe
        {
            return this.front_;
        }
        @property void front(size_t i) @nogc nothrow pure @safe
        {
            this.front_ = i;
        }
        void popFront() @nogc nothrow pure @safe
        {
            ++this.front_;
        }
        size_t opIndex(size_t i) @nogc nothrow pure @safe
        {
            return this.front_ + i;
        }
        void opIndexAssign(size_t value, size_t i) @nogc nothrow pure @safe
        {
            this.front = i + value;
        }
        InfiniteRange save() @nogc nothrow pure @safe
        {
            return this;
        }
    }
    auto t = InfiniteRange().take(3);
    assert(t.length == 3);
    assert(t.front == 1);
    assert(t.back == 3);
    t.popFront();
    assert(t.front == 2);
    assert(t.back == 3);
    t.popBack();
    assert(t.front == 2);
    assert(t.back == 2);
    t.popFront();
    assert(t.empty);
 }
 /**
 * Takes exactly $(D_PARAM n) elements from $(D_PARAM range).
 *
 * $(D_PARAM range) must have at least $(D_PARAM n) elements.
 *
 * $(D_PSYMBOL takeExactly) is particulary useful with infinite ranges. You can
 ` take $(B n) elements from such range and pass the result to an algorithm
 * which expects a finit range.
 *
 * Params:
 *  R     = Type of the adapted range.
 *  range = The range to take the elements from.
 *  n     = The number of elements to take.
 *
 * Returns: A range containing $(D_PARAM n) first elements of $(D_PARAM range).
 *
 * See_Also: $(D_PSYMBOL take).
 */
 auto takeExactly(R)(R range, size_t n)
 if (isInputRange!R)
 {
    struct TakeExactly
    {
        mixin Take!(R, true);
    }
    return TakeExactly(range, n);
 }
 ///
@nogc nothrow pure @safe unittest
 {
    static struct InfiniteRange
    {
        private size_t front_ = 1;
        enum bool empty = false;
        @property size_t front() @nogc nothrow pure @safe
        {
            return this.front_;
        }
        @property void front(size_t i) @nogc nothrow pure @safe
        {
            this.front_ = i;
        }
        void popFront() @nogc nothrow pure @safe
        {
            ++this.front_;
        }
        size_t opIndex(size_t i) @nogc nothrow pure @safe
        {
            return this.front_ + i;
        }
        void opIndexAssign(size_t value, size_t i) @nogc nothrow pure @safe
        {
            this.front = i + value;
        }
        InfiniteRange save() @nogc nothrow pure @safe
        {
            return this;
        }
    }
    auto t = InfiniteRange().takeExactly(3);
    assert(t.length == 3);
    assert(t.front == 1);
    assert(t.back == 3);
    t.popFront();
    assert(t.front == 2);
    assert(t.back == 3);
    t.popBack();
    assert(t.front == 2);
    assert(t.back == 2);
    t.popFront();
    assert(t.empty);
 }
--- a/source/tanya/range/array.d
+++ b/source/tanya/range/array.d
@ -0,0 +1,220 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * $(D_PSYMBOL tanya.range.array) implements range primitives for built-in arrays.
 *
 * This module is a submodule of
 * $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/range/package.d, tanya.range).
 *
 * After importing of
 * $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/range/array.d, tanya/range/array.d)
 * built-in arrays can act as bidirectional ranges. For that to work the module
 * defines a set of functions that accept a built-in array of any type as their
 * first argument, so thanks to UFCS (Uniform Function Call Syntax) they can be
 * called as if they were array member functions. For example the arrays the
 * `.length`-property, but no `.empty` property. So here can be find the
 * $(D_PSYMBOL empty) function. Since $(D_INLINECODE empty(array)) and
 * $(D_INLINECODE array.empty) are equal for the arrays, arrays get a faked
 * property `empty`.
 *
 * The functions in this module don't change array elements or its underlying
 * storage, but some functions alter the slice. Each array maintains a pointer
 * to its data and the length and there can be several pointers which point to
 * the same data. Array pointer can be advanced and the length can be reduced
 * without changing the underlying storage. So slices offer the possibility to
 * have multiple views into the same array, point to different positions inside
 * it.
 *
 * Strings ($(D_INLINECODE char[]), (D_INLINECODE wchar[]) and
 * (D_INLINECODE dchar[])) are treated as any other normal array, they aren't
 * auto-decoded.
 *
 * Copyright: Eugene Wissner 2017-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/range/array.d,
 *                 tanya/range/array.d)
 */
 module tanya.range.array;
 /**
 * Returns the first element of the $(D_PARAM array).
 *
 * The element is returned by reference, so $(D_PSYMBOL front) can be also used
 * to change the first element of $(D_PARAM array) if it is mutable.
 *
 * Params:
 *  T     = Element type of $(D_PARAM array).
 *  array = Built-in array.
 *
 * Returns: First element.
 *
 * Precondition: $(D_INLINECODE array.length > 0).
 */
@property ref T front(T)(T[] array)
 in
 {
    assert(array.length > 0);
 }
 do
 {
    return array[0];
 }
 ///
@nogc nothrow pure @safe unittest
 {
    string s = "Wenn die Wunde nicht mehr wehtut, schmerzt die Narbe";
    static assert(is(typeof(s.front) == immutable char));
    assert(s.front == 'W');
    wstring w = "Волны несутся, гремя и сверкая";
    static assert(is(typeof(w.front) == immutable wchar));
    assert(w.front == 'В');
    dstring d = "Для писателя память - это почти все";
    static assert(is(typeof(d.front) == immutable dchar));
    assert(d.front == 'Д');
 }
 /**
 * Returns the last element of the $(D_PARAM array).
 *
 * The element is returned by reference, so $(D_PSYMBOL back) can be also used
 * to change the last element of $(D_PARAM array) if it is mutable.
 *
 * Params:
 *  T     = Element type of $(D_PARAM array).
 *  array = Built-in array.
 *
 * Returns: Last element.
 *
 * Precondition: $(D_INLINECODE array.length > 0).
 */
@property ref T back(T)(T[] array)
 in
 {
    assert(array.length > 0);
 }
 do
 {
    return array[$ - 1];
 }
 ///
@nogc nothrow pure @safe unittest
 {
    string s = "Brecht";
    static assert(is(typeof(s.back) == immutable char));
    assert(s.back == 't');
    wstring w = "Тютчев";
    static assert(is(typeof(w.back) == immutable wchar));
    assert(w.back == 'в');
    dstring d = "Паустовский";
    static assert(is(typeof(d.back) == immutable dchar));
    assert(d.back == 'й');
 }
 /**
 * $(D_PSYMBOL popFront) and $(D_PSYMBOL popBack) advance the $(D_PARAM array)
 * and remove one element from its back, respectively.
 *
 * $(D_PSYMBOL popFront) and $(D_PSYMBOL popBack) don't alter the array
 * storage, they only narrow the view into the array.
 *
 * Params:
 *  T     = Element type of $(D_PARAM array).
 *  array = Built-in array.
 *
 * Precondition: $(D_INLINECODE array.length > 0).
 */
 void popFront(T)(ref T[] array)
 in
 {
    assert(array.length > 0);
 }
 do
 {
    array = array[1 .. $];
 }
 /// ditto
 void popBack(T)(ref T[] array)
 in
 {
    assert(array.length > 0);
 }
 do
 {
    array = array[0 .. $ - 1];
 }
 ///
@nogc nothrow pure @safe unittest
 {
    wstring array = "Der finstere Ozean der Metaphysik. Nietzsche";
    array.popFront();
    assert(array.length == 43);
    assert(array.front == 'e');
    array.popBack();
    assert(array.length == 42);
    assert(array.back == 'h');
 }
 /**
 * Tests whether $(D_PARAM array) is empty.
 *
 * Params:
 *  T     = Element type of $(D_PARAM array).
 *  array = Built-in array.
 *
 * Returns: $(D_KEYWORD true) if $(D_PARAM array) has no elements,
 *          $(D_KEYWORD false) otherwise.
 */
@property bool empty(T)(const T[] array)
 {
    return array.length == 0;
 }
 ///
@nogc nothrow pure @safe unittest
 {
    int[1] array;
    assert(!array.empty);
    assert(array[1 .. 1].empty);
 }
 /**
 * Returns a copy of the slice $(D_PARAM array).
 *
 * $(D_PSYMBOL save) doesn't copy the array itself, but only the data pointer
 * and the length.
 *
 * Params:
 *  T     = Element type of $(D_PARAM array).
 *  array = Built-in array.
 *
 * Returns: A copy of the slice $(D_PARAM array).
 */
@property T[] save(T)(T[] array)
 {
    return array;
 }
 ///
@nogc nothrow pure @safe unittest
 {
    ubyte[8] array;
    auto slice = array.save;
    assert(slice.length == array.length);
    slice.popFront();
    assert(slice.length < array.length);
 }
--- a/source/tanya/range/package.d
+++ b/source/tanya/range/package.d
@ -0,0 +1,20 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * This package contains generic functions and templates to be used with D
 * ranges.
 *
 * Copyright: Eugene Wissner 2017-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/range/package.d,
 *                 tanya/range/package.d)
 */
 module tanya.range;
 public import tanya.range.adapter;
 public import tanya.range.array;
 public import tanya.range.primitive;
--- a/source/tanya/range/primitive.d
+++ b/source/tanya/range/primitive.d
--- a/source/tanya/sys/linux/syscall.d
+++ b/source/tanya/sys/linux/syscall.d
@ -0,0 +1,47 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /*
 * Copyright: Eugene Wissner 2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/sys/linux/syscall.d,
 *                 tanya/sys/linux/syscall.d)
 */
 module tanya.sys.linux.syscall;
 version (TanyaNative):
 extern ptrdiff_t syscall(ptrdiff_t, ptrdiff_t, ptrdiff_t)
@nogc nothrow @system;
 extern ptrdiff_t syscall(ptrdiff_t,
                         ptrdiff_t,
                         ptrdiff_t,
                         ptrdiff_t,
                         ptrdiff_t,
                         ptrdiff_t,
                         ptrdiff_t) @nogc nothrow @system;
 // Same syscalls as above but pure.
 private template getOverloadMangling(size_t n)
 {
    enum string getOverloadMangling = __traits(getOverloads,
                                               tanya.sys.linux.syscall,
                                               "syscall")[n].mangleof;
 }
 pragma(mangle, getOverloadMangling!0)
 extern ptrdiff_t syscall_(ptrdiff_t, ptrdiff_t, ptrdiff_t)
@nogc nothrow pure @system;
 pragma(mangle, getOverloadMangling!1)
 extern ptrdiff_t syscall_(ptrdiff_t,
                          ptrdiff_t,
                          ptrdiff_t,
                          ptrdiff_t,
                          ptrdiff_t,
                          ptrdiff_t,
                          ptrdiff_t) @nogc nothrow pure @system;
--- a/source/tanya/sys/posix/mman.d
+++ b/source/tanya/sys/posix/mman.d
@ -0,0 +1,31 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /*
 * Copyright: Eugene Wissner 2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/sys/posix/mman.d,
 *                 tanya/sys/posix/mman.d)
 */
 module tanya.sys.posix.mman;
 version (TanyaNative):
 enum
 {
    PROT_EXEC = 0x4, // Page can be executed.
    PROT_NONE = 0x0, // Page cannot be accessed.
    PROT_READ = 0x1, // Page can be read.
    PROT_WRITE = 0x2, // Page can be written.
 }
 enum
 {
    MAP_FIXED = 0x10, // Interpret addr exactly.
    MAP_PRIVATE = 0x02, // Changes are private.
    MAP_SHARED = 0x01, // Share changes.
    MAP_ANONYMOUS = 0x20, // Don't use a file.
 }
--- a/source/tanya/sys/windows/def.d
+++ b/source/tanya/sys/windows/def.d
@ -0,0 +1,61 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * Base type definitions and aliases.
 *
 * This module doesn't provide aliases for all types used by Windows, but only
 * for types that can vary on different platforms. For example there is no
 * need to define `INT32` alias for D, since $(D_KEYWORD int) is always a
 * 32-bit signed integer. But `int` and its Windows alias `INT` is not the
 * same on all platforms in C, so its size can be something differen than
 * 32 bit, therefore an $(D_PSYMBOL INT) alias is available in this module.
 * $(D_PARAM TCHAR) can be a $(D_KEYWORD char) if Unicode isn't supported or
 * $(D_KEYWORD wchar) if Unicode is supported, so $(D_PSYMBOL TCHAR) is
 * defined here.
 * Also aliases for specific types like $(D_PSYMBOL SOCKET) are defined here.
 *
 * Copyright: Eugene Wissner 2017-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/sys/windows/def.d,
 *                 tanya/sys/windows/def.d)
 */
 module tanya.sys.windows.def;
 version (Windows):
 alias BYTE = ubyte;
 alias TBYTE = wchar; // If Unicode, otherwise char.
 alias CHAR = char; // Signed or unsigned char.
 alias TCHAR = wchar; // If Unicode, otherwise char.
 alias SHORT = short;
 alias USHORT = ushort;
 alias WORD = ushort;
 alias INT = int;
 alias UINT = uint;
 alias LONG = int;
 alias ULONG = uint;
 alias DWORD = uint;
 alias LONGLONG = long; // Or double.
 alias ULONGLONG = ulong; // Or double.
 alias DWORDLONG = ulong;
 alias FLOAT = float;
 alias BOOL = int;
 alias BOOLEAN = BYTE;
 alias HANDLE = void*;
 enum HANDLE INVALID_HANDLE_VALUE = cast(HANDLE) -1;
 enum TRUE = 1;
 enum FALSE = 0;
 align(1) struct GUID
 {
    uint Data1;
    ushort Data2;
    ushort Data3;
    char[8] Data4;
 }
--- a/source/tanya/sys/windows/package.d
+++ b/source/tanya/sys/windows/package.d
@ -0,0 +1,19 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * Copyright: Eugene Wissner 2017-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/sys/windows/package.d,
 *                 tanya/sys/windows/package.d)
 */
 module tanya.sys.windows;
 version (Windows):
 public import tanya.sys.windows.def;
 public import tanya.sys.windows.winbase;
 public import tanya.sys.windows.winsock2;
--- a/source/tanya/sys/windows/winbase.d
+++ b/source/tanya/sys/windows/winbase.d
@ -0,0 +1,55 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * Definitions from winbase.h.
 *
 * Copyright: Eugene Wissner 2017-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/sys/windows/winbase.d,
 *                 tanya/sys/windows/winbase.d)
 */
 module tanya.sys.windows.winbase;
 version (Windows):
 public import tanya.sys.windows.def;
 struct OVERLAPPED
 {
    size_t Internal;
    size_t InternalHigh;
    union
    {
        struct
        {
            DWORD Offset;
            DWORD OffsetHigh;
        }
        void* Pointer;
    }
    HANDLE hEvent;
 }
 extern(Windows)
 HANDLE CreateIoCompletionPort(HANDLE FileHandle,
                              HANDLE ExistingCompletionPort,
                              size_t CompletionKey,
                              DWORD NumberOfConcurrentThreads)
 nothrow @system @nogc;
 extern(Windows)
 BOOL GetQueuedCompletionStatus(HANDLE CompletionPort,
                               DWORD* lpNumberOfBytes,
                               size_t* lpCompletionKey,
                               OVERLAPPED** lpOverlapped,
                               DWORD dwMilliseconds) nothrow @system @nogc;
 extern(Windows)
 BOOL GetOverlappedResult(HANDLE hFile,
                         OVERLAPPED* lpOverlapped,
                         DWORD* lpNumberOfBytesTransferred,
                         BOOL bWait) nothrow @system @nogc;
--- a/source/tanya/sys/windows/winsock2.d
+++ b/source/tanya/sys/windows/winsock2.d
@ -0,0 +1,219 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * Definitions from winsock2.h, ws2def.h and MSWSock.h.
 *
 * Copyright: Eugene Wissner 2017-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/sys/windows/winsock2.d,
 *                 tanya/sys/windows/winsock2.d)
 */
 module tanya.sys.windows.winsock2;
 version (Windows):
 public import tanya.sys.windows.def;
 public import tanya.sys.windows.winbase;
 alias SOCKET = size_t;
 enum SOCKET INVALID_SOCKET = ~0;
 enum SOCKET_ERROR = -1;
 enum
 {
    IOC_UNIX     = 0x00000000,
    IOC_WS2      = 0x08000000,
    IOC_PROTOCOL = 0x10000000,
    IOC_VOID     = 0x20000000,         // No parameters.
    IOC_OUT      = 0x40000000,         // Copy parameters back.
    IOC_IN       = 0x80000000,         // Copy parameters into.
    IOC_VENDOR   = 0x18000000,
    IOC_WSK      = (IOC_WS2 | 0x07000000), // _WIN32_WINNT >= 0x0600.
    IOC_INOUT    = (IOC_IN | IOC_OUT), // Copy parameter into and get back.
 }
 template _WSAIO(int x, int y)
 {
    enum _WSAIO = IOC_VOID | x | y;
 }
 template _WSAIOR(int x, int y)
 {
    enum _WSAIOR = IOC_OUT | x | y;
 }
 template _WSAIOW(int x, int y)
 {
    enum _WSAIOW = IOC_IN | x | y;
 }
 template _WSAIORW(int x, int y)
 {
    enum _WSAIORW = IOC_INOUT | x | y;
 }
 alias SIO_ASSOCIATE_HANDLE               = _WSAIOW!(IOC_WS2, 1);
 alias SIO_ENABLE_CIRCULAR_QUEUEING       = _WSAIO!(IOC_WS2, 2);
 alias SIO_FIND_ROUTE                     = _WSAIOR!(IOC_WS2, 3);
 alias SIO_FLUSH                          = _WSAIO!(IOC_WS2, 4);
 alias SIO_GET_BROADCAST_ADDRESS          = _WSAIOR!(IOC_WS2, 5);
 alias SIO_GET_EXTENSION_FUNCTION_POINTER = _WSAIORW!(IOC_WS2, 6);
 alias SIO_GET_QOS                        = _WSAIORW!(IOC_WS2, 7);
 alias SIO_GET_GROUP_QOS                  = _WSAIORW!(IOC_WS2, 8);
 alias SIO_MULTIPOINT_LOOPBACK            = _WSAIOW!(IOC_WS2, 9);
 alias SIO_MULTICAST_SCOPE                = _WSAIOW!(IOC_WS2, 10);
 alias SIO_SET_QOS                        = _WSAIOW!(IOC_WS2, 11);
 alias SIO_SET_GROUP_QOS                  = _WSAIOW!(IOC_WS2, 12);
 alias SIO_TRANSLATE_HANDLE               = _WSAIORW!(IOC_WS2, 13);
 alias SIO_ROUTING_INTERFACE_QUERY        = _WSAIORW!(IOC_WS2, 20);
 alias SIO_ROUTING_INTERFACE_CHANGE       = _WSAIOW!(IOC_WS2, 21);
 alias SIO_ADDRESS_LIST_QUERY             = _WSAIOR!(IOC_WS2, 22);
 alias SIO_ADDRESS_LIST_CHANGE            = _WSAIO!(IOC_WS2, 23);
 alias SIO_QUERY_TARGET_PNP_HANDLE        = _WSAIOR!(IOC_WS2, 24);
 alias SIO_NSP_NOTIFY_CHANGE              = _WSAIOW!(IOC_WS2, 25);
 alias GROUP = uint;
 enum
 {
    WSA_FLAG_OVERLAPPED = 0x01,
    WSA_FLAG_MULTIPOINT_C_ROOT = 0x02,
    WSA_FLAG_MULTIPOINT_C_LEAF = 0x04,
    WSA_FLAG_MULTIPOINT_D_ROOT = 0x08,
    WSA_FLAG_MULTIPOINT_D_LEAF = 0x10,
    WSA_FLAG_ACCESS_SYSTEM_SECURITY = 0x40,
    WSA_FLAG_NO_HANDLE_INHERIT = 0x80,
    WSA_FLAG_REGISTERED_IO = 0x100,
 }
 enum MAX_PROTOCOL_CHAIN = 7;
 enum BASE_PROTOCOL = 1;
 enum LAYERED_PROTOCOL = 0;
 enum WSAPROTOCOL_LEN = 255;
 struct WSAPROTOCOLCHAIN
 {
    int ChainLen;
    DWORD[MAX_PROTOCOL_CHAIN] ChainEntries;
 }
 struct WSABUF
 {
    ULONG len;
    CHAR* buf;
 }
 struct WSAPROTOCOL_INFO
 {
    DWORD                      dwServiceFlags1;
    DWORD                      dwServiceFlags2;
    DWORD                      dwServiceFlags3;
    DWORD                      dwServiceFlags4;
    DWORD                      dwProviderFlags;
    GUID                       ProviderId;
    DWORD                      dwCatalogEntryId;
    WSAPROTOCOLCHAIN           ProtocolChain;
    int                        iVersion;
    int                        iAddressFamily;
    int                        iMaxSockAddr;
    int                        iMinSockAddr;
    int                        iSocketType;
    int                        iProtocol;
    int                        iProtocolMaxOffset;
    int                        iNetworkByteOrder;
    int                        iSecurityScheme;
    DWORD                      dwMessageSize;
    DWORD                      dwProviderReserved;
    TCHAR[WSAPROTOCOL_LEN + 1] szProtocol;
 }
 const GUID WSAID_GETACCEPTEXSOCKADDRS = {
    0xb5367df2, 0xcbac, 0x11cf,
    [0x95, 0xca, 0x00, 0x80, 0x5f, 0x48, 0xa1, 0x92],
 };
 const GUID WSAID_ACCEPTEX = {
    0xb5367df1, 0xcbac, 0x11cf,
    [0x95, 0xca, 0x00, 0x80, 0x5f, 0x48, 0xa1, 0x92],
 };
 alias LPWSAOVERLAPPED_COMPLETION_ROUTINE = void function(DWORD dwError,
                                                         DWORD cbTransferred,
                                                         OVERLAPPED* lpOverlapped,
                                                         DWORD dwFlags) nothrow @nogc;
 extern(Windows)
 SOCKET WSASocket(int af,
                 int type,
                 int protocol,
                 WSAPROTOCOL_INFO* lpProtocolInfo,
                 GROUP g,
                 DWORD dwFlags) nothrow @system @nogc;
 extern(Windows)
 int WSARecv(SOCKET s,
            WSABUF* lpBuffers,
            DWORD dwBufferCount,
            DWORD* lpNumberOfBytesRecvd,
            DWORD* lpFlags,
            OVERLAPPED* lpOverlapped,
            LPWSAOVERLAPPED_COMPLETION_ROUTINE lpCompletionRoutine)
 nothrow @system @nogc;
 extern(Windows)
 int WSASend(SOCKET s,
            WSABUF* lpBuffers,
            DWORD dwBufferCount,
            DWORD* lpNumberOfBytesRecvd,
            DWORD lpFlags,
            OVERLAPPED* lpOverlapped,
            LPWSAOVERLAPPED_COMPLETION_ROUTINE lpCompletionRoutine)
 nothrow @system @nogc;
 extern(Windows)
 int WSAIoctl(SOCKET s,
             uint dwIoControlCode,
             void* lpvInBuffer,
             uint cbInBuffer,
             void* lpvOutBuffer,
             uint cbOutBuffer,
             uint* lpcbBytesReturned,
             OVERLAPPED* lpOverlapped,
             LPWSAOVERLAPPED_COMPLETION_ROUTINE lpCompletionRoutine)             
 nothrow @system @nogc;
 alias ADDRESS_FAMILY = USHORT;
 struct SOCKADDR
 {
    ADDRESS_FAMILY sa_family;           // Address family.
    CHAR[14] sa_data;                   // Up to 14 bytes of direct address.
 }
 alias LPFN_GETACCEPTEXSOCKADDRS = void function(void*,
                                                DWORD,
                                                DWORD,
                                                DWORD,
                                                SOCKADDR**,
                                                INT*,
                                                SOCKADDR**,
                                                INT*) nothrow @nogc;
 alias LPFN_ACCEPTEX = extern(Windows) BOOL function(SOCKET,
                                                    SOCKET,
                                                    void*,
                                                    DWORD,
                                                    DWORD,
                                                    DWORD,
                                                    DWORD*,
                                                    OVERLAPPED*) @nogc nothrow;
 enum
 {
    SO_MAXDG = 0x7009,
    SO_MAXPATHDG = 0x700A,
    SO_UPDATE_ACCEPT_CONTEXT = 0x700B,
    SO_CONNECT_TIME = 0x700C,
    SO_UPDATE_CONNECT_CONTEXT = 0x7010,
 }
--- a/source/tanya/test/assertion.d
+++ b/source/tanya/test/assertion.d
@ -0,0 +1,105 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * Additional assertions.
 *
 * This module provides functions that assert whether a given expression
 * satisfies some complex condition, that can't be tested with
 * $(D_KEYWORD assert) in a single line. Internally all the functions
 * just evaluate the expression and call $(D_KEYWORD assert).
 *
 * The functions can cause segmentation fault if the module is compiled
 * in production mode and the condition fails.
 *
 * Copyright: Eugene Wissner 2017-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/test/assertion.d,
 *                 tanya/test/assertion.d)
 */
 module tanya.test.assertion;
 import tanya.memory;
 import tanya.meta.trait;
 /**
 * Asserts whether the function $(D_PARAM expr) throws an exception of type
 * $(D_PARAM E). If it does, the exception is catched and properly destroyed.
 * If it doesn't, an assertion error is thrown. If the exception doesn't match
 * $(D_PARAM E) type, it isn't catched and escapes.
 *
 * Params:
 *  E    = Expected exception type.
 *  T    = Throwing function type.
 *  Args = Argument types of the throwing function.
 *  expr = Throwing function.
 *  args = Arguments for $(D_PARAM expr).
 */
 void assertThrown(E : Exception, T, Args...)(T expr, auto ref Args args)
 if (isSomeFunction!T)
 {
    try
    {
        cast(void) expr(args);
        assert(false, "Expected exception not thrown");
    }
    catch (E exception)
    {
        defaultAllocator.dispose(exception);
    }
 }
 ///
@nogc nothrow pure @safe unittest
 {
    // If you want to test that an expression throws, you can wrap it into an
    // arrow function.
    static struct CtorThrows
    {
        this(int i) @nogc pure @safe
        {
            throw defaultAllocator.make!Exception();
        }
    }
    assertThrown!Exception(() => CtorThrows(8));
 }
 /**
 * Asserts that the function $(D_PARAM expr) doesn't throw.
 *
 * If it does, the thrown exception is catched, properly destroyed and an
 * assertion error is thrown instead.
 *
 * Params:
 *  T    = Tested function type.
 *  Args = Argument types of $(D_PARAM expr).
 *  expr = Tested function.
 *  args = Arguments for $(D_PARAM expr).
 */
 void assertNotThrown(T, Args...)(T expr, auto ref Args args)
 if (isSomeFunction!T)
 {
    try
    {
        cast(void) expr(args);
    }
    catch (Exception exception)
    {
        defaultAllocator.dispose(exception);
        assert(false, "Unexpected exception thrown");
    }
 }
 ///
@nogc nothrow pure @safe unittest
 {
    // If you want to test that an expression doesn't throw, you can wrap it
    // into an arrow function.
    static struct S
    {
    }
    assertNotThrown(() => S());
 }
--- a/source/tanya/test/package.d
+++ b/source/tanya/test/package.d
@ -0,0 +1,17 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * Test suite for $(D_KEYWORD unittest)-blocks.
 *
 * Copyright: Eugene Wissner 2017-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/test/package.d,
 *                 tanya/test/package.d)
 */
 module tanya.test;
 public import tanya.test.assertion;
--- a/source/tanya/typecons.d
+++ b/source/tanya/typecons.d
@ -0,0 +1,454 @@
 /* This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
 /**
 * Type constructors.
 *
 * This module contains templates that allow to build new types from the
 * available ones.
 *
 * Copyright: Eugene Wissner 2017-2018.
 * License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
 *                  Mozilla Public License, v. 2.0).
 * Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
 * Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/typecons.d,
 *                 tanya/typecons.d)
 */
 module tanya.typecons;
 import tanya.algorithm.mutation;
 import tanya.format;
 import tanya.meta.metafunction : AliasSeq, AliasTuple = Tuple, Map;
 import tanya.meta.trait;
 /**
 * $(D_PSYMBOL Tuple) can store two or more heterogeneous objects.
 *
 * The objects can by accessed by index as `obj[0]` and `obj[1]` or by optional
 * names (e.g. `obj.first`).
 *
 * $(D_PARAM Specs) contains a list of object types and names. First
 * comes the object type, then an optional string containing the name.
 * If you want the object be accessible only by its index (`0` or `1`),
 * just skip the name.
 *
 * Params:
 *  Specs = Field types and names.
 */
 template Tuple(Specs...)
 {
    template parseSpecs(size_t fieldCount, Specs...)
    {
        static if (Specs.length == 0)
        {
            alias parseSpecs = AliasSeq!();
        }
        else static if (is(Specs[0]) && fieldCount < 2)
        {
            static if (is(typeof(Specs[1]) == string))
            {
                alias parseSpecs
                    = AliasSeq!(AliasTuple!(Specs[0], Specs[1]),
                                parseSpecs!(fieldCount + 1, Specs[2 .. $]));
            }
            else
            {
                alias parseSpecs
                    = AliasSeq!(AliasTuple!(Specs[0]),
                                parseSpecs!(fieldCount + 1, Specs[1 .. $]));
            }
        }
        else
        {
            static assert(false, "Invalid argument: " ~ Specs[0].stringof);
        }
    }
    alias ChooseType(alias T) = T.Seq[0];
    alias ParsedSpecs = parseSpecs!(0, Specs);
    static assert(ParsedSpecs.length > 1, "Invalid argument count");
    private string formatAliases(size_t n, Specs...)()
    {
        static if (Specs.length == 0)
        {
            return "";
        }
        else
        {
            string fieldAlias;
            static if (Specs[0].length == 2)
            {
                char[21] buffer;
                fieldAlias = "alias " ~ Specs[0][1] ~ " = expand["
                           ~ integral2String(n, buffer).idup ~ "];";
            }
            return fieldAlias ~ formatAliases!(n + 1, Specs[1 .. $])();
        }
    }
    struct Tuple
    {
        /// Field types.
        alias Types = Map!(ChooseType, ParsedSpecs);
        // Create field aliases.
        mixin(formatAliases!(0, ParsedSpecs[0 .. $])());
        /// Represents the values of the $(D_PSYMBOL Tuple) as a list of values.
        Types expand;
        alias expand this;
    }
 }
 ///
@nogc nothrow pure @safe unittest
 {
    auto pair = Tuple!(int, "first", string, "second")(1, "second");
    assert(pair.first == 1);
    assert(pair[0] == 1);
    assert(pair.second == "second");
    assert(pair[1] == "second");
 }
@nogc nothrow pure @safe unittest
 {
    static assert(is(Tuple!(int, int)));
    static assert(!is(Tuple!(int, 5)));
    static assert(is(Tuple!(int, "first", int)));
    static assert(is(Tuple!(int, "first", int, "second")));
    static assert(is(Tuple!(int, "first", int)));
    static assert(is(Tuple!(int, int, "second")));
    static assert(!is(Tuple!("first", int, "second", int)));
    static assert(!is(Tuple!(int, int, int)));
    static assert(!is(Tuple!(int, "first")));
    static assert(!is(Tuple!(int, double, char)));
    static assert(!is(Tuple!(int, "first", double, "second", char, "third")));
 }
 /**
 * $(D_PSYMBOL Option) is a type that contains an optional value.
 *
 * Params:
 *  T = Type of the encapsulated value.
 */
 struct Option(T)
 {
    private bool isNothing_ = true;
    private T value = void;
    /**
     * Constructs a new option with $(D_PARAM value).
     *
     * Params:
     *  value = Encapsulated value.
     */
    this()(ref T value)
    {
        this.value = value;
        this.isNothing_ = false;
    }
    /// ditto
    this()(T value) @trusted
    {
        moveEmplace(value, this.value);
        this.isNothing_ = false;
    }
    /**
     * Tells if the option is just a value or nothing.
     *
     * Returns: $(D_KEYWORD true) if this $(D_PSYMBOL Option) contains a nothing,
     *          $(D_KEYWORD false) if it contains a value.
     */
    @property bool isNothing() const
    {
        return this.isNothing_;
    }
    /**
     * Returns the encapsulated value.
     *
     * Returns: Value encapsulated in this $(D_PSYMBOL Option).
     *
     * See_Also: $(D_PSYMBOL or).
     *
     * Precondition: `!isNothing`.
     */
    @property ref inout(T) get() inout
    in
    {
        assert(!isNothing, "Option is nothing");
    }
    do
    {
        return this.value;
    }
    /**
     * Returns the encapsulated value if available or a default value
     * otherwise.
     *
     * Note that the contained value can be returned by reference only if the
     * default value is passed by reference as well.
     *
     * Params:
     *  U            = Type of the default value.
     *  defaultValue = Default value.
     *
     * Returns: The value of this $(D_PSYMBOL Option) if available,
     *          $(D_PARAM defaultValue) otherwise.
     *
     * See_Also: $(D_PSYMBOL isNothing), $(D_PSYMBOL get).
     */
    @property U or(U)(U defaultValue) inout
    if (is(U == T) && isCopyable!T)
    {
        return isNothing ? defaultValue : this.value;
    }
    /// ditto
    @property ref inout(T) or(ref inout(T) defaultValue) inout
    {
        return isNothing ? defaultValue : this.value;
    }
    /**
     * Casts this $(D_PSYMBOL Option) to $(D_KEYWORD bool).
     *
     * An $(D_PSYMBOL Option) is $(D_KEYWORD true) if it contains a value,
     * ($D_KEYWORD false) if it contains nothing.
     *
     * Returns: $(D_KEYWORD true) if this $(D_PSYMBOL Option) contains a value,
     *          ($D_KEYWORD false) if it contains nothing.
     */
    bool opCast(U : bool)()
    {
        return !isNothing;
    }
    /**
     * Compares this $(D_PSYMBOL Option) with $(D_PARAM that).
     *
     * If both objects are options of the same type and they don't contain a
     * value, they are considered equal. If only one of them contains a value,
     * they aren't equal. Otherwise, the encapsulated values are compared for
     * equality.
     *
     * If $(D_PARAM U) is a type comparable with the type encapsulated by this
     * $(D_PSYMBOL Option), the value of this $(D_PSYMBOL Option) is compared
     * with $(D_PARAM that), this $(D_PSYMBOL Option) must have a value then.
     *
     * Params:
     *  U    = Type of the object to compare with.
     *  that = Object to compare with.
     *
     * Returns: $(D_KEYWORD true) if this $(D_PSYMBOL Option) and
     *          $(D_PARAM that) are equal, $(D_KEYWORD false) if not.
     *
     * Precondition: `!isNothing` if $(D_PARAM U) is equality comparable with
     *               $(D_PARAM T).
     */
    bool opEquals(U)(auto ref const U that) const
    if (is(U == Option))
    {
        if (!isNothing && !that.isNothing)
        {
            return this.value == that.value;
        }
        return isNothing == that.isNothing;
    }
    /// ditto
    bool opEquals(U)(auto ref const U that) const
    if (ifTestable!(U, a => a == T.init) && !is(U == Option))
    in
    {
        assert(!isNothing);
    }
    do
    {
        return get == that;
    }
    /**
     * Resets this $(D_PSYMBOL Option) and destroys the contained value.
     *
     * $(D_PSYMBOL reset) can be safely called on an $(D_PSYMBOL Option) that
     * doesn't contain any value.
     */
    void reset()
    {
        static if (hasElaborateDestructor!T)
        {
            destroy(this.value);
        }
        this.isNothing_ = true;
    }
    /**
     * Assigns a new value.
     *
     * Params:
     *  U    = Type of the new value.
     *  that = New value.
     *
     * Returns: $(D_KEYWORD this).
     */
    ref typeof(this) opAssign(U)(ref U that)
    if (is(U : T) && !is(U == Option))
    {
        this.value = that;
        this.isNothing_ = false;
        return this;
    }
    /// ditto
    ref typeof(this) opAssign(U)(U that)
    if (is(U == T))
    {
        move(that, this.value);
        this.isNothing_ = false;
        return this;
    }
    /// ditto
    ref typeof(this) opAssign(U)(ref U that)
    if (is(U == Option))
    {
        this.value = that;
        this.isNothing_ = that.isNothing;
        return this;
    }
    /// ditto
    ref typeof(this) opAssign(U)(U that)
    if (is(U == Option))
    {
        move(that.value, this.value);
        this.isNothing_ = that.isNothing_;
        return this;
    }
    alias get this;
 }
 ///
@nogc nothrow pure @safe unittest
 {
    Option!int option;
    assert(option.isNothing);
    assert(option.or(8) == 8);
    option = 5;
    assert(!option.isNothing);
    assert(option.get == 5);
    assert(option.or(8) == 5);
    option.reset();
    assert(option.isNothing);
 }
 // Assigns a new value
@nogc nothrow pure @safe unittest
 {
    {
        Option!int option = 5;
        option = 8;
        assert(!option.isNothing);
        assert(option == 8);
    }
    {
        Option!int option;
        const int newValue = 8;
        assert(option.isNothing);
        option = newValue;
        assert(!option.isNothing);
        assert(option == newValue);
    }
    {
        Option!int option1;
        Option!int option2 = 5;
        assert(option1.isNothing);
        option1 = option2;
        assert(!option1.isNothing);
        assert(option1.get == 5);
    }
 }
 // Constructs with a value passed by reference
@nogc nothrow pure @safe unittest
 {
    int i = 5;
    assert(Option!int(i).get == 5);
 }
 // Moving
@nogc nothrow pure @safe unittest
 {
    static struct NotCopyable
    {
        @disable this(this);
    }
    static assert(is(typeof(Option!NotCopyable(NotCopyable()))));
    // The value cannot be returned by reference because the default value
    // isn't passed by reference
    static assert(!is(typeof(Option!DisabledPostblit().or(NotCopyable()))));
    {
        NotCopyable notCopyable;
        static assert(is(typeof(Option!NotCopyable().or(notCopyable))));
    }
    {
        Option!NotCopyable option;
        assert(option.isNothing);
        option = NotCopyable();
        assert(!option.isNothing);
    }
    {
        Option!NotCopyable option;
        assert(option.isNothing);
        option = Option!NotCopyable(NotCopyable());
        assert(!option.isNothing);
    }
 }
 // Cast to bool is done before touching the encapsulated value
@nogc nothrow pure @safe unittest
 {
    assert(Option!bool(false));
 }
 // Option can be const
@nogc nothrow pure @safe unittest
 {
    assert((const Option!int(5)).get == 5);
    assert((const Option!int()).or(5) == 5);
 }
 // Equality
@nogc nothrow pure @safe unittest
 {
    assert(Option!int() == Option!int());
    assert(Option!int(0) != Option!int());
    assert(Option!int(5) == Option!int(5));
    assert(Option!int(5) == 5);
    assert(Option!int(5) == cast(ubyte) 5);
 }
 // Returns default value
@nogc nothrow pure @safe unittest
 {
    {
        int i = 5;
        assert(((ref e) => e)(Option!int().or(i)) == 5);
    }
 }