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49 Commits
v0.8.1 ... v0.10.0

Author SHA1 Message Date
Eugen Wissner
f51e9405c9 Update socket documentation 2018-06-20 07:59:37 +02:00
Eugen Wissner
de15281ccb Tuple with more than two fields 
Fix #41.
 2018-06-19 05:44:15 +02:00
Eugen Wissner
a86b6690f0 Implement auto-decoding free equal comparison 
Fix #39.
 2018-06-12 20:19:06 +02:00
Eugen Wissner
15f7994187 Add takeExactly 
Fix #43.
 2018-06-10 19:03:26 +02:00
Eugen Wissner
37b0afe290 take: Remove moveFront, moveBack, moveAt 2018-06-10 14:46:40 +02:00
Eugen Wissner
cd9960db2a Add take range adapter 2018-06-10 14:46:40 +02:00
Eugen Wissner
7357503c5a Update 2.080 series to 2.080.1 2018-06-09 05:05:30 +02:00
Eugen Wissner
173ae115ee readIntegral: Support base between 2 and 36 2018-06-08 21:05:35 +02:00
Eugen Wissner
7561b964d3 Make intToString -> readString more generic 
Make readString work with any char range and unsigned integral type.
 2018-06-07 07:23:39 +02:00
Eugen Wissner
c663703221 container.list: Remove deprecated list length property 2018-06-01 14:13:27 +02:00
Eugen Wissner
58af2fd89b encoding.ascii: Make static const data immutable 2018-05-31 18:43:35 +02:00
Eugen Wissner
52ec88bd04 async: Annotate system tests 2018-05-31 18:43:21 +02:00
Eugen Wissner
bfe0748a63 Insert a range into the hash table and set 2018-05-30 18:50:52 +02:00
Eugen Wissner
61814d5383 Make an independent function for converting port string 2018-05-23 05:10:44 +02:00
Eugen Wissner
c268696ee9 HashTable/Set: Add proper assignment 2018-05-20 21:58:15 +02:00
Eugen Wissner
9efbc9d5e0 Make Array postblit safe if possible 2018-05-18 07:43:18 +02:00
Eugen Wissner
c511b97b1b container.Set and HashTable: Fix constructors 2018-05-17 05:31:14 +02:00
Eugen Wissner
385ec19e2f hash.lookup: Reformat the docs 2018-05-17 05:30:49 +02:00
Eugen Wissner
205d7a080e Add KeyValue alias for value tuple 2018-05-14 21:55:49 +02:00
Eugen Wissner
d545d6900e Make HashTable Range return Pair 2018-05-14 19:23:22 +02:00
Eugene Wissner
3ed46117d1 Port Set ranges for HashTable 2018-05-14 19:23:22 +02:00
Eugene Wissner
00dbb224f7 Move length tracking to HashArray 2018-05-14 19:23:22 +02:00
Eugene Wissner
9cf1b6f491 Use HashArray as internal storage 2018-05-14 19:23:22 +02:00
Eugene Wissner
bdce5cda6a Add HashTable container 2018-05-14 19:23:22 +02:00
Eugen Wissner
faf952b30e Rename Pair to Tuple 2018-05-12 06:11:24 +02:00
Eugen Wissner
53620cdddf Improve preconditions for the container.Set 2018-05-11 05:43:14 +02:00
Eugen Wissner
41a8e32351 Switch to travis-ci.com 2018-05-10 06:13:38 +02:00
Eugen Wissner
2ec750ca05 Fix math.nbtheory linkage to asm 
Don't use extern for templated functions. If the function argument is
const, it gets a different mangling. So define a private function for
each floatint point length and call it from template.
 2018-05-08 18:07:42 +02:00
Eugen Wissner
6ed2992862 Remove unused variables 2018-05-06 07:03:11 +02:00
Eugen Wissner
5c8c0ce4d8 Add dmd 2.080.0 support 2018-05-05 05:22:04 +02:00
Eugene Wissner
cd1a38f402 Move Smallest and Largest to meta.transform 
Smallest and Largest choose the smallest or largest (according to
.sizeof property) type in the list of types. These templates get a list
of types and produce a type, so they are transformations.
 2018-05-02 15:50:28 +02:00
Eugene Wissner
4f6ce116bc Add documented tests for Set.empty and Set.clear() 2018-05-01 15:56:07 +02:00
Eugene Wissner
c4424e7e01 Track hash Set length 
Can be used later to rehash the hash table if it is full up to some
percentage.
 2018-04-30 12:51:35 +02:00
Eugene Wissner
18d54b4b18 HashArray as an internal store for hash containers 2018-04-29 09:12:48 +02:00
Eugene Wissner
36646aa2c4 container.Set: Rewrite arch dependent tests 2018-04-28 18:07:41 +02:00
Eugene Wissner
702d1b02e0 Make allocator getter public 2018-04-28 17:57:07 +02:00
Eugene Wissner
8733b93ca0 container.Set: Support customizable hasher 2018-04-28 17:49:49 +02:00
Eugene Wissner
55c36d22a0 Make isType public 2018-04-27 11:32:41 +02:00
Eugene Wissner
6e2852000b Deprecate math.min/max in favour of tanya.algorithm 2018-04-27 11:32:22 +02:00
Eugene Wissner
c0f9e5be10 Replace std min/max. Fix #35 2018-04-26 10:23:06 +02:00
Eugene Wissner
3468d6ea00 Accept/return as inout in min/max 2018-04-26 08:06:06 +02:00
Eugene Wissner
ed5fa91e64 Merge remote-tracking branch 'origin/master' into feature/min_max 2018-04-25 15:13:03 +02:00
Eugene Wissner
2185a70ac8 Fix #33 2018-04-25 13:09:34 +02:00
Eugene Wissner
b94da1f58a Replace SocketError with ErrorCode.ErrorNo 2018-04-25 12:59:38 +02:00
Eugen Wissner
3f9b500e20 Add CommonType 2018-04-24 15:45:47 +02:00
Eugen Wissner
86053de8c9 Add min/max algorithms 2018-04-22 12:08:33 +02:00
Eugen Wissner
e8222123e6 Use syscall instead of mmap and munmap 2018-04-22 08:07:20 +02:00
Eugen Wissner
5cac28c093 Add new comparison traits 
- allSameType
- isEqualityComparable
- isOrderingComparable
 2018-04-21 06:38:32 +02:00
Eugen Wissner
5e40424f7d net.inet: Replace CTFE-pow with pow operator 2018-04-20 15:15:00 +02:00
55 changed files with 3464 additions and 1172 deletions
Expand all files Collapse all files

3
.travis.yml
View File

@ -7,6 +7,7 @@ os:
language: d
d:
- dmd-2.080.1
- dmd-2.079.1
- dmd-2.078.3
- dmd-2.077.1
@ -22,7 +23,7 @@ addons:
- gcc-multilib
before_script:
- if [ "`$DC --version | head -n 1 | grep 'v2.079.1'`" ]; then
- if [ "`$DC --version | head -n 1 | grep 'v2.080.1'`" ]; then
export UNITTEST="unittest-cov";
fi

15
README.md
View File

@ -1,6 +1,6 @@
# 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)
[![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)
@ -26,7 +26,7 @@ Tanya consists of the following packages and (top-level) modules:
* `algorithm`: Collection of generic algorithms.
* `async`: Event loop (epoll, kqueue and IOCP).
* `container`: Queue, Array, Singly and doubly linked lists, Buffers, UTF-8
string, Hash table.
string, Set, Hash table.
* `conv`: This module provides functions for converting between different
types.
* `encoding`: This package provides tools to work with text encodings.
@ -172,18 +172,11 @@ parameter is used)
| DMD | GCC |
|:-------:|:---------:|
| 2.079.1 | *master* |
| 2.080.1 | *master* |
| 2.079.1 | |
| 2.078.3 | |
| 2.077.1 | |
### Current status
Following modules are under development:
| Feature | Branch | Build status |
|------------|:---------:|-----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------|
| Hash table | bitvector | [![bitvector](https://travis-ci.org/caraus-ecms/tanya.svg?branch=bitvector)](https://travis-ci.org/caraus-ecms/tanya) [![bitvector](https://ci.appveyor.com/api/projects/status/djkmverdfsylc7ti/branch/bitvector?svg=true)](https://ci.appveyor.com/project/belka-ew/tanya/branch/bitvector) |
### Release management
Tanya is still under active development and it isn't possible to provide great

6
appveyor.yml
View File

@ -3,6 +3,12 @@ os: Visual Studio 2015
environment:
matrix:
- DC: dmd
DVersion: 2.080.1
arch: x64
- DC: dmd
DVersion: 2.080.1
arch: x86
- DC: dmd
DVersion: 2.079.1
arch: x64

18
arch/x64/linux/math/abs.S
View File

@ -2,10 +2,10 @@
// fabsf.
.globl _D5tanya4math8nbtheory10__T3absTfZ3absFNaNbNiNffZf
.type _D5tanya4math8nbtheory10__T3absTfZ3absFNaNbNiNffZf, @function
.globl _D5tanya4math8nbtheory4fabsFNaNbNiNffZf
.type _D5tanya4math8nbtheory4fabsFNaNbNiNffZf, @function
_D5tanya4math8nbtheory10__T3absTfZ3absFNaNbNiNffZf:
_D5tanya4math8nbtheory4fabsFNaNbNiNffZf:
mov $0x7fffffff, %eax
movq %rax, %xmm1
andpd %xmm1, %xmm0
@ -13,10 +13,10 @@ _D5tanya4math8nbtheory10__T3absTfZ3absFNaNbNiNffZf:
// fabs.
.globl _D5tanya4math8nbtheory10__T3absTdZ3absFNaNbNiNfdZd
.type _D5tanya4math8nbtheory10__T3absTdZ3absFNaNbNiNfdZd, @function
.globl _D5tanya4math8nbtheory4fabsFNaNbNiNfdZd
.type _D5tanya4math8nbtheory4fabsFNaNbNiNfdZd, @function
_D5tanya4math8nbtheory10__T3absTdZ3absFNaNbNiNfdZd:
_D5tanya4math8nbtheory4fabsFNaNbNiNfdZd:
mov $0x7fffffffffffffff, %rax
movq %rax, %xmm1
andpd %xmm1, %xmm0
@ -24,12 +24,12 @@ _D5tanya4math8nbtheory10__T3absTdZ3absFNaNbNiNfdZd:
// fabsl.
.globl _D5tanya4math8nbtheory10__T3absTeZ3absFNaNbNiNfeZe
.type _D5tanya4math8nbtheory10__T3absTeZ3absFNaNbNiNfeZe, @function
.globl _D5tanya4math8nbtheory4fabsFNaNbNiNfeZe
.type _D5tanya4math8nbtheory4fabsFNaNbNiNfeZe, @function
// Load the parameter from the stack onto FP stack, execute 'fabs' instruction
// The result is returned in ST0.
_D5tanya4math8nbtheory10__T3absTeZ3absFNaNbNiNfeZe:
_D5tanya4math8nbtheory4fabsFNaNbNiNfeZe:
fldt 0x8(%rsp)
fabs
ret

40
arch/x64/linux/math/log.S
View File

@ -1,22 +1,29 @@
.text
// logl.
.globl _D5tanya4math8nbtheory9__T2lnTeZ2lnFNaNbNiNfeZe
.type _D5tanya4math8nbtheory9__T2lnTeZ2lnFNaNbNiNfeZe, @function
// logf.
.globl _D5tanya4math8nbtheory4logfFNaNbNiNffZf
.type _D5tanya4math8nbtheory4logfFNaNbNiNffZf, @function
_D5tanya4math8nbtheory4logfFNaNbNiNffZf:
movss %xmm0, -4(%rsp) // Put the argument onto the stack
_D5tanya4math8nbtheory9__T2lnTeZ2lnFNaNbNiNfeZe:
fldln2 // Put lb(e) onto the FPU stack
fldt 8(%rsp) // Put the argument 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 _D5tanya4math8nbtheory9__T2lnTdZ2lnFNaNbNiNfdZd
.type _D5tanya4math8nbtheory9__T2lnTdZ2lnFNaNbNiNfdZd, @function
.globl _D5tanya4math8nbtheory3logFNaNbNiNfdZd
.type _D5tanya4math8nbtheory3logFNaNbNiNfdZd, @function
_D5tanya4math8nbtheory9__T2lnTdZ2lnFNaNbNiNfdZd:
_D5tanya4math8nbtheory3logFNaNbNiNfdZd:
movsd %xmm0, -8(%rsp) // Put the argument onto the stack
fldln2 // Put lb(e) onto the FPU stack
@ -30,19 +37,12 @@ _D5tanya4math8nbtheory9__T2lnTdZ2lnFNaNbNiNfdZd:
ret
// logf.
.globl _D5tanya4math8nbtheory9__T2lnTfZ2lnFNaNbNiNffZf
.type _D5tanya4math8nbtheory9__T2lnTfZ2lnFNaNbNiNffZf, @function
_D5tanya4math8nbtheory9__T2lnTfZ2lnFNaNbNiNffZf:
movss %xmm0, -4(%rsp) // Put the argument onto the stack
// logl.
.globl _D5tanya4math8nbtheory4loglFNaNbNiNfeZe
.type _D5tanya4math8nbtheory4loglFNaNbNiNfeZe, @function
_D5tanya4math8nbtheory4loglFNaNbNiNfeZe:
fldln2 // Put lb(e) onto the FPU stack
flds -4(%rsp) // Put a float onto the FPU stack
fldt 8(%rsp) // Put the argument 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

1
arch/x64/linux/memory/cmp.S
View File

@ -47,6 +47,7 @@ _D5tanya6memory2op9cmpMemoryFNaNbNixAvxAvZi:
aligned_1: // Compare the remaining bytes
mov %rdx, %rcx
cmp $0x0, %rcx
repe cmpsb
jl less

41
arch/x64/linux/syscall.S
View File

@ -22,44 +22,31 @@ syscall1:
ret
.globl syscall2
.type syscall2, @function
// 2 parameters.
.globl _D5tanya3sys5linux7syscall7syscallFNbNilllZl
.type _D5tanya3sys5linux7syscall7syscallFNbNilllZl, @function
syscall2:
// Store registers.
movq %rdi, %r8
movq %rdx, %rax // Syscall number.
// Syscall arguments.
movq %rsi, %rdi
movq %r8, %rsi
_D5tanya3sys5linux7syscall7syscallFNbNilllZl:
movq %rdx, %rax
syscall
// Restore registers.
movq %rdi, %rsi
movq %r8, %rdi
ret
.globl syscall3
.type syscall3, @function
// 6 parameters.
.globl _D5tanya3sys5linux7syscall7syscallFNbNilllllllZl
.type _D5tanya3sys5linux7syscall7syscallFNbNilllllllZl, @function
syscall3:
// Store registers.
movq %rdi, %r8
_D5tanya3sys5linux7syscall7syscallFNbNilllllllZl:
pushq %rbp
movq %rsp, %rbp
movq %rcx, %rax // Syscall number.
movq 16(%rbp), %rax
// Syscall arguments.
movq %rdx, %rdi
movq %r8, %rdx
mov %rcx, %r10
syscall
// Restore registers.
movq %r8, %rdi
leave
ret

2
dscanner.ini
View File

@ -23,7 +23,7 @@ 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="disabled"
unused_variable_check="skip-unittest"
; Checks for unused labels
unused_label_check="skip-unittest"
; Checks for duplicate attributes

333
source/tanya/algorithm/comparison.d Normal file
View File

@ -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[]));
}

1
source/tanya/algorithm/package.d
View File

@ -14,4 +14,5 @@
*/
module tanya.algorithm;
public import tanya.algorithm.comparison;
public import tanya.algorithm.mutation;

374
source/tanya/async/event/epoll.d
View File

@ -1,187 +1,187 @@
/* 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/. */
/**
* Event loop implementation for Linux.
*
* 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/epoll.d,
* tanya/async/event/epoll.d)
*/
module tanya.async.event.epoll;
version (D_Ddoc)
{
}
else version (linux):
import core.stdc.errno;
public import core.sys.linux.epoll;
import core.sys.posix.unistd;
import core.time;
import std.algorithm.comparison;
import tanya.async.event.selector;
import tanya.async.loop;
import tanya.async.protocol;
import tanya.async.transport;
import tanya.async.watcher;
import tanya.container.array;
import tanya.memory;
import tanya.network.socket;
extern (C) nothrow @nogc
{
int epoll_create1(int flags);
int epoll_ctl (int epfd, int op, int fd, epoll_event *event);
int epoll_wait (int epfd, epoll_event *events, int maxevents, int timeout);
}
final class EpollLoop : SelectorLoop
{
protected int fd;
private Array!epoll_event events;
/**
* Initializes the loop.
*/
this() @nogc
{
if ((fd = epoll_create1(EPOLL_CLOEXEC)) < 0)
{
throw defaultAllocator.make!BadLoopException("epoll initialization failed");
}
super();
events = Array!epoll_event(maxEvents);
}
/**
* Frees loop internals.
*/
~this() @nogc
{
close(fd);
}
/**
* 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.
*/
protected override bool reify(SocketWatcher watcher,
EventMask oldEvents,
EventMask events) @nogc
{
int op = EPOLL_CTL_DEL;
epoll_event ev;
if (events == oldEvents)
{
return true;
}
if (events && oldEvents)
{
op = EPOLL_CTL_MOD;
}
else if (events && !oldEvents)
{
op = EPOLL_CTL_ADD;
}
ev.data.fd = watcher.socket.handle;
ev.events = (events & (Event.read | Event.accept) ? EPOLLIN | EPOLLPRI : 0)
| (events & Event.write ? EPOLLOUT : 0)
| EPOLLET;
return epoll_ctl(fd, op, watcher.socket.handle, &ev) == 0;
}
/**
* Does the actual polling.
*/
protected override void poll() @nogc
{
// Don't block
immutable timeout = cast(immutable int) blockTime.total!"msecs";
auto eventCount = epoll_wait(fd, events.get().ptr, maxEvents, timeout);
if (eventCount < 0)
{
if (errno != EINTR)
{
throw defaultAllocator.make!BadLoopException();
}
return;
}
for (auto i = 0; i < eventCount; ++i)
{
auto transport = cast(StreamTransport) connections[events[i].data.fd];
if (transport is null)
{
auto connection = cast(ConnectionWatcher) connections[events[i].data.fd];
assert(connection !is null);
acceptConnections(connection);
}
else if (events[i].events & EPOLLERR)
{
kill(transport);
continue;
}
else if (events[i].events & (EPOLLIN | EPOLLPRI | EPOLLHUP))
{
SocketException exception;
try
{
ptrdiff_t received;
do
{
received = transport.socket.receive(transport.output[]);
transport.output += received;
}
while (received);
}
catch (SocketException e)
{
exception = e;
}
if (transport.socket.disconnected)
{
kill(transport, exception);
continue;
}
else if (transport.output.length)
{
pendings.insertBack(transport);
}
}
if (events[i].events & EPOLLOUT)
{
transport.writeReady = true;
if (transport.input.length)
{
feed(transport);
}
}
}
}
/**
* Returns: The blocking time.
*/
override protected @property inout(Duration) blockTime()
inout @safe pure nothrow
{
return min(super.blockTime, 1.dur!"seconds");
}
}
/* 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/. */
/**
* Event loop implementation for Linux.
*
* 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/epoll.d,
* tanya/async/event/epoll.d)
*/
module tanya.async.event.epoll;
version (D_Ddoc)
{
}
else version (linux):
import core.stdc.errno;
public import core.sys.linux.epoll;
import core.sys.posix.unistd;
import core.time;
import tanya.algorithm.comparison;
import tanya.async.event.selector;
import tanya.async.loop;
import tanya.async.protocol;
import tanya.async.transport;
import tanya.async.watcher;
import tanya.container.array;
import tanya.memory;
import tanya.network.socket;
extern (C) nothrow @nogc
{
int epoll_create1(int flags);
int epoll_ctl (int epfd, int op, int fd, epoll_event *event);
int epoll_wait (int epfd, epoll_event *events, int maxevents, int timeout);
}
final class EpollLoop : SelectorLoop
{
protected int fd;
private Array!epoll_event events;
/**
* Initializes the loop.
*/
this() @nogc
{
if ((fd = epoll_create1(EPOLL_CLOEXEC)) < 0)
{
throw defaultAllocator.make!BadLoopException("epoll initialization failed");
}
super();
events = Array!epoll_event(maxEvents);
}
/**
* Frees loop internals.
*/
~this() @nogc
{
close(fd);
}
/**
* 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.
*/
protected override bool reify(SocketWatcher watcher,
EventMask oldEvents,
EventMask events) @nogc
{
int op = EPOLL_CTL_DEL;
epoll_event ev;
if (events == oldEvents)
{
return true;
}
if (events && oldEvents)
{
op = EPOLL_CTL_MOD;
}
else if (events && !oldEvents)
{
op = EPOLL_CTL_ADD;
}
ev.data.fd = watcher.socket.handle;
ev.events = (events & (Event.read | Event.accept) ? EPOLLIN | EPOLLPRI : 0)
| (events & Event.write ? EPOLLOUT : 0)
| EPOLLET;
return epoll_ctl(fd, op, watcher.socket.handle, &ev) == 0;
}
/**
* Does the actual polling.
*/
protected override void poll() @nogc
{
// Don't block
immutable timeout = cast(immutable int) blockTime.total!"msecs";
auto eventCount = epoll_wait(fd, events.get().ptr, maxEvents, timeout);
if (eventCount < 0)
{
if (errno != EINTR)
{
throw defaultAllocator.make!BadLoopException();
}
return;
}
for (auto i = 0; i < eventCount; ++i)
{
auto transport = cast(StreamTransport) connections[events[i].data.fd];
if (transport is null)
{
auto connection = cast(ConnectionWatcher) connections[events[i].data.fd];
assert(connection !is null);
acceptConnections(connection);
}
else if (events[i].events & EPOLLERR)
{
kill(transport);
continue;
}
else if (events[i].events & (EPOLLIN | EPOLLPRI | EPOLLHUP))
{
SocketException exception;
try
{
ptrdiff_t received;
do
{
received = transport.socket.receive(transport.output[]);
transport.output += received;
}
while (received);
}
catch (SocketException e)
{
exception = e;
}
if (transport.socket.disconnected)
{
kill(transport, exception);
continue;
}
else if (transport.output.length)
{
pendings.insertBack(transport);
}
}
if (events[i].events & EPOLLOUT)
{
transport.writeReady = true;
if (transport.input.length)
{
feed(transport);
}
}
}
}
/**
* Returns: The blocking time.
*/
override protected @property inout(Duration) blockTime()
inout @safe pure nothrow
{
return min(super.blockTime, 1.dur!"seconds");
}
}

4
source/tanya/async/event/kqueue.d
View File

@ -52,7 +52,7 @@ import core.stdc.errno;
import core.sys.posix.time; // timespec
import core.sys.posix.unistd;
import core.time;
import std.algorithm.comparison;
import tanya.algorithm.comparison;
import tanya.async.event.selector;
import tanya.async.loop;
import tanya.async.transport;
@ -217,7 +217,7 @@ final class KqueueLoop : SelectorLoop
timespec ts;
blockTime.split!("seconds", "nsecs")(ts.tv_sec, ts.tv_nsec);
if (changeCount > maxEvents)
if (changeCount > maxEvents)
{
events.length = changes.length;
}

76
source/tanya/async/loop.d
View File

@ -13,50 +13,52 @@
*
* class EchoProtocol : TransmissionControlProtocol
* {
* private DuplexTransport transport;
* private DuplexTransport transport;
*
* void received(in ubyte[] data) @nogc
* {
* transport.write(data);
* }
* void received(in ubyte[] data) @nogc
* {
* ubyte[512] buffer;
* buffer[0 .. data.length] = data;
* transport.write(buffer[]);
* }
*
* void connected(DuplexTransport transport) @nogc
* {
* this.transport = transport;
* }
* void connected(DuplexTransport transport) @nogc
* {
* this.transport = transport;
* }
*
* void disconnected(SocketException e) @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)
* {
* auto sock = defaultAllocator.make!OverlappedStreamSocket(AddressFamily.inet);
* }
* else
* {
* auto sock = defaultAllocator.make!StreamSocket(AddressFamily.inet);
* sock.blocking = false;
* }
* version (Windows)
* {
* auto sock = defaultAllocator.make!OverlappedStreamSocket(AddressFamily.inet);
* }
* else
* {
* auto sock = defaultAllocator.make!StreamSocket(AddressFamily.inet);
* sock.blocking = false;
* }
*
* sock.bind(address);
* sock.listen(5);
* sock.bind(address);
* sock.listen(5);
*
* auto io = defaultAllocator.make!ConnectionWatcher(sock);
* io.setProtocol!EchoProtocol;
* auto io = defaultAllocator.make!ConnectionWatcher(sock);
* io.setProtocol!EchoProtocol;
*
* defaultLoop.start(io);
* defaultLoop.run();
* defaultLoop.start(io);
* defaultLoop.run();
*
* sock.shutdown();
* defaultAllocator.dispose(io);
* defaultAllocator.dispose(sock);
* defaultAllocator.dispose(address);
* sock.shutdown();
* defaultAllocator.dispose(io);
* defaultAllocator.dispose(sock);
* defaultAllocator.dispose(address);
* }
* ---
*
@ -173,7 +175,7 @@ abstract class Loop
return 128U;
}
private unittest
@nogc @system unittest
{
auto loop = defaultAllocator.make!TestLoop;
assert(loop.maxEvents == 64);
@ -226,7 +228,7 @@ abstract class Loop
this.done = true;
}
private unittest
@nogc @system unittest
{
auto loop = defaultAllocator.make!TestLoop;
assert(loop.done);
@ -237,7 +239,7 @@ abstract class Loop
defaultAllocator.dispose(loop);
}
private unittest
@nogc @system unittest
{
auto loop = defaultAllocator.make!TestLoop;
auto watcher = defaultAllocator.make!DummyWatcher;
@ -327,7 +329,7 @@ abstract class Loop
blockTime_ = blockTime;
}
private unittest
@nogc @system unittest
{
auto loop = defaultAllocator.make!TestLoop;
assert(loop.blockTime == 1.dur!"minutes");
@ -417,7 +419,7 @@ do
private Loop defaultLoop_;
private unittest
@nogc @system unittest
{
auto oldLoop = defaultLoop_;
auto loop = defaultAllocator.make!TestLoop;

135
source/tanya/container/array.d
View File

@ -15,13 +15,13 @@
module tanya.container.array;
import core.checkedint;
import std.algorithm.comparison;
import std.algorithm.mutation : bringToFront,
copy,
fill,
initializeAll,
uninitializedFill;
import std.meta;
import tanya.algorithm.comparison;
import tanya.algorithm.mutation;
import tanya.exception;
import tanya.memory;
@ -122,7 +122,7 @@ struct Range(A)
--this.end;
}
ref inout(E) opIndex(const size_t i) inout @trusted
ref inout(E) opIndex(size_t i) inout @trusted
in
{
assert(i < length);
@ -142,7 +142,7 @@ struct Range(A)
return typeof(return)(*this.container, this.begin, this.end);
}
Range opSlice(const size_t i, const size_t j) @trusted
Range opSlice(size_t i, size_t j) @trusted
in
{
assert(i <= j);
@ -153,7 +153,7 @@ struct Range(A)
return typeof(return)(*this.container, this.begin + i, this.begin + j);
}
A.ConstRange opSlice(const size_t i, const size_t j) const @trusted
A.ConstRange opSlice(size_t i, size_t j) const @trusted
in
{
assert(i <= j);
@ -217,9 +217,9 @@ struct Array(T)
* allocator = Allocator.
*/
this(R)(R init, shared Allocator allocator = defaultAllocator)
if (!isInfinite!R
&& isInputRange!R
&& isImplicitlyConvertible!(ElementType!R, T))
if (!isInfinite!R
&& isInputRange!R
&& isImplicitlyConvertible!(ElementType!R, T))
{
this(allocator);
insertBack(init);
@ -243,7 +243,7 @@ struct Array(T)
* allocator = Allocator.
*/
this(R)(ref R init, shared Allocator allocator = defaultAllocator)
if (is(Unqual!R == Array))
if (is(Unqual!R == Array))
{
this(allocator);
insertBack(init[]);
@ -251,7 +251,7 @@ struct Array(T)
/// ditto
this(R)(R init, shared Allocator allocator = defaultAllocator) @trusted
if (is(R == Array))
if (is(R == Array))
{
this(allocator);
if (allocator is init.allocator)
@ -299,16 +299,16 @@ struct Array(T)
* init = Initial value to fill the array with.
* allocator = Allocator.
*/
this(const size_t len, T init, shared Allocator allocator = defaultAllocator) @trusted
this(size_t len, T init, shared Allocator allocator = defaultAllocator)
{
this(allocator);
reserve(len);
uninitializedFill(this.data[0 .. len], init);
uninitializedFill(slice(len), init);
length_ = len;
}
/// ditto
this(const size_t len, shared Allocator allocator = defaultAllocator)
this(size_t len, shared Allocator allocator = defaultAllocator)
{
this(allocator);
length = len;
@ -348,10 +348,10 @@ struct Array(T)
/**
* Destroys this $(D_PSYMBOL Array).
*/
~this() @trusted
~this()
{
clear();
allocator.deallocate(this.data[0 .. capacity]);
(() @trusted => allocator.deallocate(slice(capacity)))();
}
/**
@ -359,7 +359,7 @@ struct Array(T)
*/
this(this)
{
auto buf = this.data[0 .. this.length_];
auto buf = slice(this.length);
this.length_ = capacity_ = 0;
this.data = null;
insertBack(buf);
@ -417,7 +417,7 @@ struct Array(T)
* Params:
* len = New length.
*/
@property void length(const size_t len) @trusted
@property void length(size_t len) @trusted
{
if (len == length)
{
@ -474,7 +474,7 @@ struct Array(T)
* Params:
* size = Desired size.
*/
void reserve(const size_t size) @trusted
void reserve(size_t size) @trusted
{
if (capacity_ >= size)
{
@ -531,14 +531,14 @@ struct Array(T)
* Params:
* size = Desired size.
*/
void shrink(const size_t size) @trusted
void shrink(size_t size) @trusted
{
if (capacity <= size)
{
return;
}
const n = max(length, size);
void[] buf = this.data[0 .. this.capacity_];
void[] buf = slice(this.capacity_);
if (allocator.reallocateInPlace(buf, n * T.sizeof))
{
this.capacity_ = n;
@ -596,7 +596,7 @@ struct Array(T)
*
* Returns: The number of elements removed
*/
size_t removeBack(const size_t howMany)
size_t removeBack(size_t howMany)
out (removed)
{
assert(removed <= howMany);
@ -621,7 +621,17 @@ struct Array(T)
assert(v.removeBack(3) == 0);
}
private @property inout(T)* end() inout
private inout(T)[] slice(size_t length) inout @trusted
in
{
assert(length <= capacity);
}
do
{
return this.data[0 .. length];
}
private @property inout(T)* end() inout @trusted
{
return this.data + this.length_;
}
@ -637,22 +647,24 @@ struct Array(T)
*
* Precondition: $(D_PARAM r) refers to a region of $(D_KEYWORD this).
*/
Range remove(Range r) @trusted
Range remove(Range r)
in
{
assert(r.container is &this);
assert(r.begin >= this.data);
assert(r.end <= this.data + length);
assert(r.end <= end);
}
do
{
auto target = r.begin;
for (auto source = r.end; source != end; ++source, ++target)
auto source = r.end;
while (source !is end)
{
move(*source, *target);
((ref s, ref t) @trusted {++s; ++t;})(source, target);
}
length = length - r.length;
return Range(this, r.begin, this.data + length);
return Range(this, r.begin, end);
}
///
@ -677,7 +689,7 @@ struct Array(T)
}
private void moveBack(R)(ref R el) @trusted
if (isImplicitlyConvertible!(R, T))
if (isImplicitlyConvertible!(R, T))
{
reserve(this.length + 1);
moveEmplace(el, *end);
@ -694,20 +706,20 @@ struct Array(T)
* Returns: The number of elements inserted.
*/
size_t insertBack(R)(R el)
if (isImplicitlyConvertible!(R, T))
if (isImplicitlyConvertible!(R, T))
{
moveBack(el);
return 1;
}
/// ditto
size_t insertBack(R)(ref R el) @trusted
if (isImplicitlyConvertible!(R, T))
size_t insertBack(R)(ref R el)
if (isImplicitlyConvertible!(R, T))
{
this.length = this.length + 1;
length = length + 1;
scope (failure)
{
this.length = this.length - 1;
length = length - 1;
}
opIndex(this.length - 1) = el;
return 1;
@ -715,9 +727,9 @@ struct Array(T)
/// ditto
size_t insertBack(R)(R el)
if (!isInfinite!R
&& isInputRange!R
&& isImplicitlyConvertible!(ElementType!R, T))
if (!isInfinite!R
&& isInputRange!R
&& isImplicitlyConvertible!(ElementType!R, T))
{
static if (hasLength!R)
{
@ -794,9 +806,9 @@ struct Array(T)
* Precondition: $(D_PARAM r) refers to a region of $(D_KEYWORD this).
*/
size_t insertAfter(R)(Range r, R el)
if (!isInfinite!R
&& isInputRange!R
&& isImplicitlyConvertible!(ElementType!R, T))
if (!isInfinite!R
&& isInputRange!R
&& isImplicitlyConvertible!(ElementType!R, T))
in
{
assert(r.container is &this);
@ -827,7 +839,7 @@ struct Array(T)
/// ditto
size_t insertAfter(R)(Range r, auto ref R el)
if (isImplicitlyConvertible!(R, T))
if (isImplicitlyConvertible!(R, T))
in
{
assert(r.container is &this);
@ -854,9 +866,9 @@ struct Array(T)
/// ditto
size_t insertBefore(R)(Range r, R el)
if (!isInfinite!R
&& isInputRange!R
&& isImplicitlyConvertible!(ElementType!R, T))
if (!isInfinite!R
&& isInputRange!R
&& isImplicitlyConvertible!(ElementType!R, T))
in
{
assert(r.container is &this);
@ -883,7 +895,7 @@ struct Array(T)
/// ditto
size_t insertBefore(R)(Range r, auto ref R el)
if (isImplicitlyConvertible!(R, T))
if (isImplicitlyConvertible!(R, T))
in
{
assert(r.container is &this);
@ -992,7 +1004,7 @@ struct Array(T)
*
* Precondition: $(D_INLINECODE length > pos).
*/
ref T opIndexAssign(E : T)(auto ref E value, const size_t pos)
ref T opIndexAssign(E : T)(auto ref E value, size_t pos)
{
return opIndex(pos) = value;
}
@ -1057,7 +1069,7 @@ struct Array(T)
*
* Precondition: $(D_INLINECODE length > pos).
*/
ref inout(T) opIndex(const size_t pos) inout @trusted
ref inout(T) opIndex(size_t pos) inout @trusted
in
{
assert(length > pos);
@ -1132,7 +1144,7 @@ struct Array(T)
* $(D_KEYWORD false) otherwise.
*/
bool opEquals(R)(R that) const
if (is(R == Range) || is(R == ConstRange))
if (is(R == Range) || is(R == ConstRange))
{
return equal(opIndex(), that);
}
@ -1221,7 +1233,7 @@ struct Array(T)
*
* Precondition: $(D_INLINECODE i <= j && j <= length).
*/
Range opSlice(const size_t i, const size_t j) @trusted
Range opSlice(size_t i, size_t j) @trusted
in
{
assert(i <= j);
@ -1233,7 +1245,7 @@ struct Array(T)
}
/// ditto
ConstRange opSlice(const size_t i, const size_t j) const @trusted
ConstRange opSlice(size_t i, size_t j) const @trusted
in
{
assert(i <= j);
@ -1294,7 +1306,7 @@ struct Array(T)
* Precondition: $(D_INLINECODE i <= j && j <= length
* && value.length == j - i)
*/
Range opSliceAssign(size_t R)(T[R] value, const size_t i, const size_t j)
Range opSliceAssign(size_t R)(T[R] value, size_t i, size_t j)
@trusted
in
{
@ -1308,7 +1320,7 @@ struct Array(T)
}
/// ditto
Range opSliceAssign(R : T)(auto ref R value, const size_t i, const size_t j)
Range opSliceAssign(R : T)(auto ref R value, size_t i, size_t j)
@trusted
in
{
@ -1322,7 +1334,7 @@ struct Array(T)
}
/// ditto
Range opSliceAssign(Range value, const size_t i, const size_t j) @trusted
Range opSliceAssign(Range value, size_t i, size_t j) @trusted
in
{
assert(i <= j);
@ -1401,14 +1413,14 @@ struct Array(T)
* Returns: $(D_KEYWORD this).
*/
ref typeof(this) opAssign(R)(ref R that)
if (is(Unqual!R == Array))
if (is(Unqual!R == Array))
{
return this = that[];
}
/// ditto
ref typeof(this) opAssign(R)(R that) @trusted
if (is(R == Array))
ref typeof(this) opAssign(R)(R that)
if (is(R == Array))
{
swap(this.data, that.data);
swap(this.length_, that.length_);
@ -1427,9 +1439,9 @@ struct Array(T)
* Returns: $(D_KEYWORD this).
*/
ref typeof(this) opAssign(R)(R that)
if (!isInfinite!R
&& isInputRange!R
&& isImplicitlyConvertible!(ElementType!R, T))
if (!isInfinite!R
&& isInputRange!R
&& isImplicitlyConvertible!(ElementType!R, T))
{
length = 0;
insertBack(that);
@ -1669,3 +1681,14 @@ struct Array(T)
Array!int v1;
v1 = Array!int([5, 15, 8]);
}
// Postblit is safe
@nogc nothrow pure @safe unittest
{
auto array = Array!int(3);
void func(Array!int arg)
{
assert(arg.capacity == 3);
}
func(array);
}

181
source/tanya/container/buffer.d
View File

@ -20,7 +20,6 @@ import tanya.meta.trait;
version (unittest)
{
private int fillBuffer(ubyte[] buffer,
in size_t size,
int start = 0,
int end = 10) @nogc pure nothrow
in
@ -52,7 +51,7 @@ version (unittest)
* T = Buffer type.
*/
struct ReadBuffer(T = ubyte)
if (isScalarType!T)
if (isScalarType!T)
{
/// Internal buffer.
private T[] buffer_;
@ -67,16 +66,16 @@ struct ReadBuffer(T = ubyte)
private size_t ring;
/// Available space.
private immutable size_t minAvailable = 1024;
private size_t minAvailable = 1024;
/// Size by which the buffer will grow.
private immutable size_t blockSize = 8192;
private size_t blockSize = 8192;
invariant
{
assert(length_ <= buffer_.length);
assert(blockSize > 0);
assert(minAvailable > 0);
assert(this.length_ <= this.buffer_.length);
assert(this.blockSize > 0);
assert(this.minAvailable > 0);
}
/**
@ -90,14 +89,14 @@ struct ReadBuffer(T = ubyte)
* $(D_PSYMBOL free) < $(D_PARAM minAvailable)).
* allocator = Allocator.
*/
this(in size_t size,
in size_t minAvailable = 1024,
this(size_t size,
size_t minAvailable = 1024,
shared Allocator allocator = defaultAllocator) @trusted
{
this(allocator);
this.minAvailable = minAvailable;
this.blockSize = size;
buffer_ = cast(T[]) allocator_.allocate(size * T.sizeof);
this.buffer_ = cast(T[]) allocator_.allocate(size * T.sizeof);
}
/// ditto
@ -116,7 +115,7 @@ struct ReadBuffer(T = ubyte)
*/
~this() @trusted
{
allocator.deallocate(buffer_);
allocator.deallocate(this.buffer_);
}
///
@ -132,7 +131,7 @@ struct ReadBuffer(T = ubyte)
*/
@property size_t capacity() const
{
return buffer_.length;
return this.buffer_.length;
}
/**
@ -140,7 +139,7 @@ struct ReadBuffer(T = ubyte)
*/
@property size_t length() const
{
return length_ - start;
return this.length_ - start;
}
/// ditto
@ -153,7 +152,7 @@ struct ReadBuffer(T = ubyte)
*/
void clear()
{
start = length_ = ring;
start = this.length_ = ring;
}
/**
@ -165,7 +164,7 @@ struct ReadBuffer(T = ubyte)
}
///
@nogc nothrow pure unittest
@nogc nothrow pure @system unittest
{
ReadBuffer!ubyte b;
size_t numberRead;
@ -173,7 +172,7 @@ struct ReadBuffer(T = ubyte)
assert(b.free == 0);
// Fills the buffer with values 0..10
numberRead = fillBuffer(b[], b.free, 0, 10);
numberRead = fillBuffer(b[], 0, 10);
b += numberRead;
assert(b.free == b.blockSize - numberRead);
b.clear();
@ -188,23 +187,23 @@ struct ReadBuffer(T = ubyte)
*
* Returns: $(D_KEYWORD this).
*/
ref ReadBuffer opOpAssign(string op)(in size_t length)
ref ReadBuffer opOpAssign(string op)(size_t length)
if (op == "+")
{
length_ += length;
this.length_ += length;
ring = start;
return this;
}
///
@nogc nothrow pure unittest
@nogc nothrow pure @system unittest
{
ReadBuffer!ubyte b;
size_t numberRead;
ubyte[] result;
// Fills the buffer with values 0..10
numberRead = fillBuffer(b[], b.free, 0, 10);
numberRead = fillBuffer(b[], 0, 10);
b += numberRead;
result = b[0 .. $];
@ -214,10 +213,10 @@ struct ReadBuffer(T = ubyte)
b.clear();
// It shouldn't overwrite, but append another 5 bytes to the buffer
numberRead = fillBuffer(b[], b.free, 0, 10);
numberRead = fillBuffer(b[], 0, 10);
b += numberRead;
numberRead = fillBuffer(b[], b.free, 20, 25);
numberRead = fillBuffer(b[], 20, 25);
b += numberRead;
result = b[0..$];
@ -235,9 +234,9 @@ struct ReadBuffer(T = ubyte)
*
* Returns: Array between $(D_PARAM start) and $(D_PARAM end).
*/
T[] opSlice(in size_t start, in size_t end)
T[] opSlice(size_t start, size_t end)
{
return buffer_[this.start + start .. this.start + end];
return this.buffer_[this.start + start .. this.start + end];
}
/**
@ -251,35 +250,36 @@ struct ReadBuffer(T = ubyte)
{
if (start > 0)
{
auto ret = buffer_[0 .. start];
auto ret = this.buffer_[0 .. start];
ring = 0;
return ret;
}
else
{
if (capacity - length < minAvailable)
if (capacity - length < this.minAvailable)
{
void[] buf = buffer_;
immutable cap = capacity;
void[] buf = this.buffer_;
const cap = capacity;
() @trusted {
allocator.reallocate(buf, (cap + blockSize) * T.sizeof);
buffer_ = cast(T[]) buf;
allocator.reallocate(buf,
(cap + this.blockSize) * T.sizeof);
this.buffer_ = cast(T[]) buf;
}();
}
ring = length_;
return buffer_[length_ .. $];
ring = this.length_;
return this.buffer_[this.length_ .. $];
}
}
///
@nogc nothrow pure unittest
@nogc nothrow pure @system unittest
{
ReadBuffer!ubyte b;
size_t numberRead;
ubyte[] result;
// Fills the buffer with values 0..10
numberRead = fillBuffer(b[], b.free, 0, 10);
numberRead = fillBuffer(b[], 0, 10);
b += numberRead;
assert(b.length == 10);
@ -311,7 +311,7 @@ struct ReadBuffer(T = ubyte)
* T = Buffer type.
*/
struct WriteBuffer(T = ubyte)
if (isScalarType!T)
if (isScalarType!T)
{
/// Internal buffer.
private T[] buffer_;
@ -323,16 +323,16 @@ struct WriteBuffer(T = ubyte)
private size_t ring;
/// Size by which the buffer will grow.
private immutable size_t blockSize;
private const size_t blockSize;
/// The position of the free area in the buffer.
private size_t position;
invariant
{
assert(blockSize > 0);
assert(this.blockSize > 0);
// Position can refer to an element outside the buffer if the buffer is full.
assert(position <= buffer_.length);
assert(this.position <= this.buffer_.length);
}
/**
@ -343,7 +343,7 @@ struct WriteBuffer(T = ubyte)
*
* Precondition: $(D_INLINECODE size > 0 && allocator !is null)
*/
this(in size_t size, shared Allocator allocator = defaultAllocator) @trusted
this(size_t size, shared Allocator allocator = defaultAllocator) @trusted
in
{
assert(size > 0);
@ -351,10 +351,10 @@ struct WriteBuffer(T = ubyte)
}
do
{
blockSize = size;
this.blockSize = size;
ring = size - 1;
allocator_ = allocator;
buffer_ = cast(T[]) allocator_.allocate(size * T.sizeof);
this.buffer_ = cast(T[]) allocator_.allocate(size * T.sizeof);
}
@disable this();
@ -364,7 +364,7 @@ struct WriteBuffer(T = ubyte)
*/
~this()
{
allocator.deallocate(buffer_);
allocator.deallocate(this.buffer_);
}
/**
@ -372,7 +372,7 @@ struct WriteBuffer(T = ubyte)
*/
@property size_t capacity() const
{
return buffer_.length;
return this.buffer_.length;
}
/**
@ -385,13 +385,13 @@ struct WriteBuffer(T = ubyte)
*/
@property size_t length() const
{
if (position > ring || position < start) // Buffer overflowed
if (this.position > ring || this.position < start) // Buffer overflowed
{
return ring - start + 1;
}
else
{
return position - start;
return this.position - start;
}
}
@ -399,7 +399,7 @@ struct WriteBuffer(T = ubyte)
alias opDollar = length;
///
@nogc nothrow pure unittest
@nogc nothrow pure @system unittest
{
auto b = WriteBuffer!ubyte(4);
ubyte[3] buf = [48, 23, 255];
@ -434,61 +434,62 @@ struct WriteBuffer(T = ubyte)
* Params:
* buffer = Buffer chunk got with $(D_PSYMBOL opIndex).
*/
ref WriteBuffer opOpAssign(string op)(in T[] buffer)
ref WriteBuffer opOpAssign(string op)(const T[] buffer)
if (op == "~")
{
size_t end, start;
if (position >= this.start && position <= ring)
if (this.position >= this.start && this.position <= ring)
{
auto afterRing = ring + 1;
end = position + buffer.length;
end = this.position + buffer.length;
if (end > afterRing)
{
end = afterRing;
}
start = end - position;
buffer_[position .. end] = buffer[0 .. start];
start = end - this.position;
this.buffer_[this.position .. end] = buffer[0 .. start];
if (end == afterRing)
{
position = this.start == 0 ? afterRing : 0;
this.position = this.start == 0 ? afterRing : 0;
}
else
{
position = end;
this.position = end;
}
}
// Check if we have some free space at the beginning
if (start < buffer.length && position < this.start)
if (start < buffer.length && this.position < this.start)
{
end = position + buffer.length - start;
end = this.position + buffer.length - start;
if (end > this.start)
{
end = this.start;
}
auto areaEnd = end - position + start;
buffer_[position .. end] = buffer[start .. areaEnd];
position = end == this.start ? ring + 1 : end - position;
auto areaEnd = end - this.position + start;
this.buffer_[this.position .. end] = buffer[start .. areaEnd];
this.position = end == this.start ? ring + 1 : end - this.position;
start = areaEnd;
}
// And if we still haven't found any place, save the rest in the overflow area
if (start < buffer.length)
{
end = position + buffer.length - start;
end = this.position + buffer.length - start;
if (end > capacity)
{
auto newSize = (end / blockSize * blockSize + blockSize) * T.sizeof;
const newSize = end / this.blockSize * this.blockSize
+ this.blockSize;
() @trusted {
void[] buf = buffer_;
allocator.reallocate(buf, newSize);
buffer_ = cast(T[]) buf;
void[] buf = this.buffer_;
allocator.reallocate(buf, newSize * T.sizeof);
this.buffer_ = cast(T[]) buf;
}();
}
buffer_[position .. end] = buffer[start .. $];
position = end;
this.buffer_[this.position .. end] = buffer[start .. $];
this.position = end;
if (this.start == 0)
{
ring = capacity - 1;
@ -507,7 +508,7 @@ struct WriteBuffer(T = ubyte)
*
* Returns: $(D_KEYWORD this).
*/
ref WriteBuffer opOpAssign(string op)(in size_t length)
ref WriteBuffer opOpAssign(string op)(size_t length)
if (op == "+")
in
{
@ -522,42 +523,42 @@ struct WriteBuffer(T = ubyte)
{
return this;
}
else if (position <= afterRing)
else if (this.position <= afterRing)
{
start += length;
if (start > 0 && position == afterRing)
if (start > 0 && this.position == afterRing)
{
position = oldStart;
this.position = oldStart;
}
}
else
{
auto overflow = position - afterRing;
auto overflow = this.position - afterRing;
if (overflow > length)
{
immutable afterLength = afterRing + length;
buffer_[start .. start + length] = buffer_[afterRing .. afterLength];
buffer_[afterRing .. afterLength] = buffer_[afterLength .. position];
position -= length;
const afterLength = afterRing + length;
this.buffer_[start .. start + length] = this.buffer_[afterRing .. afterLength];
this.buffer_[afterRing .. afterLength] = this.buffer_[afterLength .. this.position];
this.position -= length;
}
else if (overflow == length)
{
buffer_[start .. start + overflow] = buffer_[afterRing .. position];
position -= overflow;
this.buffer_[start .. start + overflow] = this.buffer_[afterRing .. this.position];
this.position -= overflow;
}
else
{
buffer_[start .. start + overflow] = buffer_[afterRing .. position];
position = overflow;
this.buffer_[start .. start + overflow] = this.buffer_[afterRing .. this.position];
this.position = overflow;
}
start += length;
if (start == position)
if (start == this.position)
{
if (position != afterRing)
if (this.position != afterRing)
{
position = 0;
this.position = 0;
}
start = 0;
ring = capacity - 1;
@ -571,7 +572,7 @@ struct WriteBuffer(T = ubyte)
}
///
@nogc nothrow pure unittest
@nogc nothrow pure @system unittest
{
auto b = WriteBuffer!ubyte(6);
ubyte[6] buf = [23, 23, 255, 128, 127, 9];
@ -597,22 +598,20 @@ struct WriteBuffer(T = ubyte)
*
* Returns: A chunk of data buffer.
*/
T[] opSlice(in size_t start, in size_t end)
T[] opSlice(size_t start, size_t end)
{
immutable internStart = this.start + start;
if (position > ring || position < start) // Buffer overflowed
if (this.position > ring || this.position < start) // Buffer overflowed
{
return buffer_[this.start .. ring + 1 - length + end];
return this.buffer_[this.start .. ring + 1 - length + end];
}
else
{
return buffer_[this.start .. this.start + end];
return this.buffer_[this.start .. this.start + end];
}
}
///
@nogc nothrow pure unittest
@nogc nothrow pure @system unittest
{
auto b = WriteBuffer!ubyte(6);
ubyte[6] buf = [23, 23, 255, 128, 127, 9];
@ -655,7 +654,7 @@ struct WriteBuffer(T = ubyte)
static assert(is(typeof(WriteBuffer!int(5))));
}
@nogc nothrow pure unittest
@nogc nothrow pure @system unittest
{
auto b = WriteBuffer!ubyte(4);
ubyte[3] buf = [48, 23, 255];
@ -677,7 +676,7 @@ struct WriteBuffer(T = ubyte)
&& b.buffer_[2] == 48 && b.buffer_[3] == 23 && b.buffer_[4] == 255);
}
@nogc nothrow pure unittest
@nogc nothrow pure @system unittest
{
auto b = WriteBuffer!ubyte(2);
ubyte[3] buf = [48, 23, 255];

275
source/tanya/container/entry.d
View File

@ -14,7 +14,11 @@
*/
module tanya.container.entry;
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)
@ -35,17 +39,6 @@ package struct DEntry(T)
DEntry* next, prev;
}
package struct HashEntry(K, V)
{
this(ref K key, ref V value)
{
this.pair = Pair!(K, V)(key, value);
}
Pair!(K, V) pair;
HashEntry* next;
}
package enum BucketStatus : byte
{
deleted = -1,
@ -53,56 +46,260 @@ package enum BucketStatus : byte
used = 1,
}
package struct Bucket(T)
package struct Bucket(K, V = void)
{
@property void content(ref T content)
static if (is(V == void))
{
this.content_ = content;
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(T) content() inout
@property ref inout(K) key() inout
{
return this.content_;
}
bool opEquals(ref T content)
{
if (this.status == BucketStatus.used && this.content == content)
static if (is(V == void))
{
return true;
return this.key_;
}
return false;
}
bool opEquals(ref const T content) const
{
if (this.status == BucketStatus.used && this.content == content)
else
{
return true;
return this.kv.key;
}
return false;
}
bool opEquals(ref typeof(this) that)
bool opEquals(ref inout(K) key) inout
{
return this.content == that.content && this.status == that.status;
return this.status == BucketStatus.used && this.key == key;
}
bool opEquals(ref typeof(this) that) const
bool opEquals(ref inout(typeof(this)) that) inout
{
return this.content == that.content && this.status == that.status;
return key == that.key && this.status == that.status;
}
void remove()
{
static if (hasElaborateDestructor!T)
static if (hasElaborateDestructor!K)
{
destroy(this.content);
destroy(key);
}
this.status = BucketStatus.deleted;
}
T content_;
BucketStatus status = BucketStatus.empty;
}
// 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;
}
/*
* Returns bucket position for `hash`. `0` may mean the 0th position or an
* empty `buckets` array.
*/
size_t locateBucket(ref const Key key) const
{
return this.array.length == 0
? 0
: hasher(key) % primes[this.lengthIndex];
}
/*
* Inserts a key into an empty or deleted bucket. If the key is
* already in there, does nothing. Returns the bucket with the key.
*/
ref Bucket insert(ref Key key)
{
while ((this.lengthIndex + 1) != primes.length)
{
foreach (ref e; this.array[locateBucket(key) .. $])
{
if (e == key)
{
return e;
}
else if (e.status != BucketStatus.used)
{
++this.length;
return e;
}
}
if (this.rehashToSize(this.lengthIndex + 1))
{
++this.lengthIndex;
}
}
this.array.insertBack(Bucket(key));
return this.array[$ - 1];
}
// Takes an index in the primes array.
bool 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
{
e2 = e1;
continue DataLoop;
}
}
return false; // Rehashing failed.
}
}
.move(storage, this.array);
return true;
}
void rehash(const size_t n)
{
size_t lengthIndex;
for (; lengthIndex < primes.length; ++lengthIndex)
{
if (primes[lengthIndex] >= n)
{
break;
}
}
if (this.rehashToSize(lengthIndex))
{
this.lengthIndex = 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")(ref inout(Key) key) inout
{
foreach (ref e; this.array[locateBucket(key) .. $])
{
if (e == key) // Found.
{
return true;
}
else if (e.status == BucketStatus.empty)
{
break;
}
}
return false;
}
}

775
source/tanya/container/hashtable.d Normal file
View File

@ -0,0 +1,775 @@
/* 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/. */
/**
* Hash table.
*
* 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/container/hashtable.d,
* tanya/container/hashtable.d)
*/
module tanya.container.hashtable;
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 whose element type is a tuple of a key and the
* respective value.
*
* Params:
* T = Type of the internal hash storage.
*/
struct Range(T)
{
private alias KV = CopyConstness!(T, T.Bucket.KV);
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(KV) front() inout
in
{
assert(!empty);
assert(this.dataRange.front.status == BucketStatus.used);
}
do
{
return this.dataRange.front.kv;
}
@property ref inout(KV) back() inout
in
{
assert(!empty);
assert(this.dataRange.back.status == BucketStatus.used);
}
do
{
return this.dataRange.back.kv;
}
Range opIndex()
{
return typeof(return)(this.dataRange[]);
}
Range!(const T) opIndex() const
{
return typeof(return)(this.dataRange[]);
}
}
/**
* Hash table is a data structure that stores pairs of keys and values without
* any particular order.
*
* This $(D_PSYMBOL HashTable) is implemented using closed hashing. Hash
* collisions are resolved with linear probing.
*
* $(D_PARAM Key) should be hashable with $(D_PARAM hasher). $(D_PARAM hasher)
* is a callable that accepts an argument of type $(D_PARAM Key) and returns a
* hash value for it ($(D_KEYWORD size_t)).
*
* Params:
* Key = Key type.
* Value = Value type.
* hasher = Hash function for $(D_PARAM Key).
*/
struct HashTable(Key, Value, alias hasher = hash)
if (is(typeof(hasher(Key.init)) == size_t))
{
private alias HashArray = .HashArray!(hasher, Key, Value);
private alias Buckets = HashArray.Buckets;
private HashArray data;
/// Type of the key-value pair stored in the hash table.
alias KeyValue = HashArray.Bucket.KV;
/// The range types for $(D_PSYMBOL HashTable).
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 hashTable = HashTable!(string, int)(5);
assert(hashTable.capacity == 7);
}
/// ditto
this(shared Allocator allocator)
in
{
assert(allocator !is null);
}
do
{
this.data = HashArray(allocator);
}
/**
* Initializes this $(D_PARAM HashTable) 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 == HashTable))
in
{
assert(allocator !is null);
}
do
{
this.data = HashArray(init.data, allocator);
}
/// ditto
this(S)(S init, shared Allocator allocator = defaultAllocator)
if (is(S == HashTable))
in
{
assert(allocator !is null);
}
do
{
this.data.move(init.data, allocator);
}
/**
* Constructs the hash table 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 && is(ElementType!R == KeyValue))
in
{
assert(allocator !is null);
}
do
{
this(allocator);
insert(range);
}
///
@nogc nothrow pure @safe unittest
{
alias KeyValue = HashTable!(string, int).KeyValue;
KeyValue[2] range = [KeyValue("one", 1), KeyValue("two", 2)];
auto hashTable = HashTable!(string, int)(range[]);
assert(hashTable["one"] == 1);
assert(hashTable["two"] == 2);
}
/**
* Initializes the hash table from a static array.
*
* Params:
* n = Array size.
* array = Static array.
* allocator = Allocator.
*
* Precondition: $(D_INLINECODE allocator !is null).
*/
this(size_t n)(KeyValue[n] array,
shared Allocator allocator = defaultAllocator)
in
{
assert(allocator !is null);
}
do
{
insert(array[]);
}
///
@nogc nothrow pure @safe unittest
{
alias KeyValue = HashTable!(string, int).KeyValue;
auto hashTable = HashTable!(string, int)([KeyValue("one", 1), KeyValue("two", 2)]);
assert(hashTable["one"] == 1);
assert(hashTable["two"] == 2);
}
/**
* Assigns another hash table.
*
* 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 == HashTable))
{
this.data = that.data;
return this;
}
/// ditto
ref typeof(this) opAssign(S)(S that) @trusted
if (is(S == HashTable))
{
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 HashTable) 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: $(D_PSYMBOL HashTable) capacity.
*/
@property size_t capacity() const
{
return this.data.capacity;
}
///
@nogc nothrow pure @safe unittest
{
HashTable!(string, int) hashTable;
assert(hashTable.capacity == 0);
hashTable["eight"] = 8;
assert(hashTable.capacity == 3);
}
/**
* Returns the number of elements in the container.
*
* Returns: The number of elements in the container.
*/
@property size_t length() const
{
return this.data.length;
}
///
@nogc nothrow pure @safe unittest
{
HashTable!(string, int) hashTable;
assert(hashTable.length == 0);
hashTable["eight"] = 8;
assert(hashTable.length == 1);
}
/**
* Tells whether the container contains any elements.
*
* Returns: Whether the container is empty.
*/
@property bool empty() const
{
return length == 0;
}
///
@nogc nothrow pure @safe unittest
{
HashTable!(string, int) hashTable;
assert(hashTable.empty);
hashTable["five"] = 5;
assert(!hashTable.empty);
}
/**
* Removes all elements.
*/
void clear()
{
this.data.clear();
}
///
@nogc nothrow pure @safe unittest
{
HashTable!(string, int) hashTable;
hashTable["five"] = 5;
assert(!hashTable.empty);
hashTable.clear();
assert(hashTable.empty);
}
/// The maximum number of buckets the container can have.
enum size_t maxBucketCount = primes[$ - 1];
/**
* Inserts a new value at $(D_PARAM key) or reassigns the element if
* $(D_PARAM key) already exists in the hash table.
*
* Params:
* key = The key to insert the value at.
* value = The value to be inserted.
*
* Returns: Just inserted element.
*/
ref Value opIndexAssign(Value value, Key key)
{
auto e = ((ref v) @trusted => &this.data.insert(v))(key);
if (e.status != BucketStatus.used)
{
e.key = key;
}
return e.kv.value = value;
}
///
@nogc nothrow pure @safe unittest
{
HashTable!(string, int) hashTable;
assert("Pachycephalosaurus" !in hashTable);
hashTable["Pachycephalosaurus"] = 6;
assert(hashTable.length == 1);
assert("Pachycephalosaurus" in hashTable);
hashTable["Pachycephalosaurus"] = 6;
assert(hashTable.length == 1);
assert("Pachycephalosaurus" in hashTable);
}
/**
* Inserts a new element in the hash table.
*
* If the element with the same key was already in the table, it reassigns
* it with the new value, but $(D_PSYMBOL insert) returns `0`. Otherwise
* `1` is returned.
*
* Params:
* keyValue = Key/value pair.
*
* Returns: The number of the inserted elements with a unique key.
*/
size_t insert(KeyValue keyValue)
{
auto e = ((ref v) @trusted => &this.data.insert(v))(keyValue.key);
size_t inserted;
if (e.status != BucketStatus.used)
{
e.key = keyValue.key;
inserted = 1;
}
e.kv.value = keyValue.value;
return inserted;
}
///
@nogc nothrow pure @safe unittest
{
HashTable!(string, int) hashTable;
assert(hashTable.insert(hashTable.KeyValue("number", 1)) == 1);
assert(hashTable["number"] == 1);
assert(hashTable.insert(hashTable.KeyValue("number", 2)) == 0);
assert(hashTable["number"] == 2);
}
/**
* Inserts a forward range of key/value pairs into the hash table.
*
* If some of the elements in the $(D_PARAM range) have the same key, they
* are reassigned but are not counted as inserted elements. So the value
* returned by this function will be less than the range length.
*
* Params:
* R = Range type.
* range = Forward range.
*
* Returns: The number of the inserted elements with a unique key.
*/
size_t insert(R)(R range)
if (isForwardRange!R && is(ElementType!R == KeyValue))
{
size_t count;
foreach (e; range)
{
count += insert(e);
}
return count;
}
///
@nogc nothrow pure @safe unittest
{
HashTable!(string, int) hashTable;
hashTable.KeyValue[2] range = [
hashTable.KeyValue("one", 1),
hashTable.KeyValue("two", 2),
];
assert(hashTable.insert(range[]) == 2);
assert(hashTable["one"] == 1);
assert(hashTable["two"] == 2);
}
/**
* Find the element with the key $(D_PARAM key).
*
* Params:
* key = The key to be find.
*
* Returns: The value associated with $(D_PARAM key).
*
* Precondition: Element with $(D_PARAM key) is in this hash table.
*/
ref Value opIndex(Key key)
{
const code = this.data.locateBucket(key);
for (auto range = this.data.array[code .. $]; !range.empty; range.popFront())
{
if (key == range.front.key)
{
return range.front.kv.value;
}
}
assert(false, "Range violation");
}
///
@nogc nothrow pure @safe unittest
{
HashTable!(string, int) hashTable;
hashTable["Triceratops"] = 7;
assert(hashTable["Triceratops"] == 7);
}
/**
* Removes the element with the key $(D_PARAM key).
*
* The method returns the number of elements removed. Since
* the hash table contains only unique keys, $(D_PARAM remove) always
* returns `1` if an element with the $(D_PARAM key) was found, `0`
* otherwise.
*
* Params:
* key = The key to be removed.
*
* Returns: Number of the removed elements.
*/
size_t remove(Key key)
{
return this.data.remove(key);
}
///
@nogc nothrow pure @safe unittest
{
HashTable!(string, int) hashTable;
hashTable["Euoplocephalus"] = 6;
assert("Euoplocephalus" in hashTable);
assert(hashTable.remove("Euoplocephalus") == 1);
assert(hashTable.remove("Euoplocephalus") == 0);
assert("Euoplocephalus" !in hashTable);
}
/**
* Looks for $(D_PARAM key) in this hash table.
*
* Params:
* key = The key to look for.
*
* Returns: $(D_KEYWORD true) if $(D_PARAM key) exists in the hash table,
* $(D_KEYWORD false) otherwise.
*/
bool opBinaryRight(string op : "in")(auto ref inout(Key) key) inout
{
return key in this.data;
}
///
@nogc nothrow pure @safe unittest
{
HashTable!(string, int) hashTable;
assert("Shantungosaurus" !in hashTable);
hashTable["Shantungosaurus"] = 15;
assert("Shantungosaurus" in hashTable);
assert("Ceratopsia" !in hashTable);
}
/**
* 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 capacity)
* 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 equal to the current $(D_PSYMBOL capacity), rehashing
* is forced without resizing the container.
*
* If $(D_PARAM n) is lower than the current $(D_PSYMBOL capacity), 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 whose element type is a tuple of a key and
* the respective value.
*
* 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
{
HashTable!(string, int) hashTable;
assert(hashTable[].empty);
hashTable["Iguanodon"] = 9;
assert(!hashTable[].empty);
assert(hashTable[].front == hashTable.KeyValue("Iguanodon", 9));
assert(hashTable[].back == hashTable.KeyValue("Iguanodon", 9));
}
}
@nogc nothrow pure @safe unittest
{
auto dinos = HashTable!(string, int)(17);
assert(dinos.empty);
dinos["Ornithominus"] = 4;
dinos["Tyrannosaurus"] = 12;
dinos["Deinonychus"] = 3;
dinos["Stegosaurus"] = 6;
dinos["Brachiosaurus"] = 25;
assert(dinos.length == 5);
assert(dinos["Ornithominus"] == 4);
assert(dinos["Stegosaurus"] == 6);
assert(dinos["Deinonychus"] == 3);
assert(dinos["Tyrannosaurus"] == 12);
assert(dinos["Brachiosaurus"] == 25);
dinos.clear();
assert(dinos.empty);
}
@nogc nothrow pure @safe unittest
{
import tanya.range.primitive : isForwardRange;
static assert(is(HashTable!(string, int) a));
static assert(is(const HashTable!(string, int)));
static assert(isForwardRange!(HashTable!(string, int).Range));
}
// Constructs by reference
@nogc nothrow pure @safe unittest
{
auto hashTable1 = HashTable!(string, int)(7);
auto hashTable2 = HashTable!(string, int)(hashTable1);
assert(hashTable1.length == hashTable2.length);
assert(hashTable1.capacity == hashTable2.capacity);
}
// Constructs by value
@nogc nothrow pure @safe unittest
{
auto hashTable = HashTable!(string, int)(HashTable!(string, int)(7));
assert(hashTable.capacity == 7);
}
// Assigns by reference
@nogc nothrow pure @safe unittest
{
auto hashTable1 = HashTable!(string, int)(7);
HashTable!(string, int) hashTable2;
hashTable1 = hashTable2;
assert(hashTable1.length == hashTable2.length);
assert(hashTable1.capacity == hashTable2.capacity);
}
// Assigns by value
@nogc nothrow pure @safe unittest
{
HashTable!(string, int) hashTable;
hashTable = HashTable!(string, int)(7);
assert(hashTable.capacity == 7);
}
// Postblit copies
@nogc nothrow pure @safe unittest
{
auto hashTable = HashTable!(string, int)(7);
void testFunc(HashTable!(string, int) hashTable)
{
assert(hashTable.capacity == 7);
}
testFunc(hashTable);
}

26
source/tanya/container/list.d
View File

@ -15,8 +15,8 @@
*/
module tanya.container.list;
import std.algorithm.comparison;
import std.algorithm.searching;
import tanya.algorithm.comparison;
import tanya.algorithm.mutation;
import tanya.container.entry;
import tanya.memory;
@ -177,7 +177,6 @@ struct SList(T)
@nogc nothrow pure @safe unittest
{
auto l = SList!int(2, 3);
assert(l.length == 2);
assert(l.front == 3);
}
@ -191,7 +190,6 @@ struct SList(T)
@nogc nothrow pure @safe unittest
{
auto l = SList!int(2);
assert(l.length == 2);
assert(l.front == 0);
}
@ -431,7 +429,6 @@ struct SList(T)
assert(l2.front == 25);
l2.insertFront(l1[]);
assert(l2.length == 5);
assert(l2.front == 9);
}
@ -565,12 +562,6 @@ struct SList(T)
assert(l1 == l2);
}
deprecated
@property size_t length() const
{
return count(this[]);
}
/**
* Comparison for equality.
*
@ -582,7 +573,7 @@ struct SList(T)
*/
bool opEquals()(auto ref typeof(this) that) inout
{
return equal(this[], that[]);
return equal(opIndex(), that[]);
}
///
@ -707,7 +698,7 @@ struct SList(T)
auto outOfScopeList = typeof(this)(allocator);
outOfScopeList.head = *r.head;
*r.head = null;
return r;
}
@ -1153,7 +1144,6 @@ struct DList(T)
@nogc nothrow pure @safe unittest
{
auto l = DList!int(2, 3);
assert(l.length == 2);
assert(l.front == 3);
assert(l.back == 3);
}
@ -1168,7 +1158,6 @@ struct DList(T)
@nogc nothrow pure @safe unittest
{
auto l = DList!int(2);
assert(l.length == 2);
assert(l.front == 0);
}
@ -1479,7 +1468,6 @@ struct DList(T)
assert(l2.back == 15);
l2.insertFront(l1[]);
assert(l2.length == 5);
assert(l2.front == 9);
assert(l2.back == 15);
}
@ -1599,7 +1587,6 @@ struct DList(T)
assert(l2.back == 15);
l2.insertBack(l1[]);
assert(l2.length == 5);
assert(l2.back == 9);
}
@ -1854,12 +1841,6 @@ struct DList(T)
return insertAfter!(T[])(r, el[]);
}
deprecated
@property size_t length() const
{
return count(this[]);
}
/**
* Comparison for equality.
*
@ -2353,7 +2334,6 @@ struct DList(T)
l.insertAfter(l[], 234);
assert(l.front == 234);
assert(l.back == 234);
assert(l.length == 1);
}
@nogc nothrow pure @safe unittest

4
source/tanya/container/package.d
View File

@ -16,6 +16,7 @@ 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.set;
public import tanya.container.string;
@ -24,6 +25,7 @@ public import tanya.container.string;
* Thrown if $(D_PSYMBOL Set) cannot insert a new element because the container
* is full.
*/
deprecated
class HashContainerFullException : Exception
{
/**
@ -36,7 +38,7 @@ class HashContainerFullException : Exception
this(string msg,
string file = __FILE__,
size_t line = __LINE__,
Throwable next = null) @nogc @safe pure nothrow
Throwable next = null) @nogc nothrow pure @safe
{
super(msg, file, line, next);
}

590
source/tanya/container/set.d
View File

@ -16,27 +16,30 @@
module tanya.container.set;
import tanya.algorithm.mutation;
import tanya.container;
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:
* E = Element type.
* T = Type of the internal hash storage.
*/
struct Range(E)
struct Range(T)
{
static if (isMutable!E)
private alias E = CopyConstness!(T, T.Key);
static if (isMutable!T)
{
private alias DataRange = Array!(Bucket!(Unqual!E)).Range;
private alias DataRange = T.array.Range;
}
else
{
private alias DataRange = Array!(Bucket!(Unqual!E)).ConstRange;
private alias DataRange = T.array.ConstRange;
}
private DataRange dataRange;
@ -68,63 +71,61 @@ struct Range(E)
@property void popFront()
in
{
assert(!this.dataRange.empty);
assert(!empty);
assert(this.dataRange.front.status == BucketStatus.used);
}
out
{
assert(this.dataRange.empty
|| this.dataRange.back.status == BucketStatus.used);
assert(empty || this.dataRange.back.status == BucketStatus.used);
}
do
{
do
{
dataRange.popFront();
this.dataRange.popFront();
}
while (!dataRange.empty && dataRange.front.status != BucketStatus.used);
while (!empty && dataRange.front.status != BucketStatus.used);
}
@property void popBack()
in
{
assert(!this.dataRange.empty);
assert(!empty);
assert(this.dataRange.back.status == BucketStatus.used);
}
out
{
assert(this.dataRange.empty
|| this.dataRange.back.status == BucketStatus.used);
assert(empty || this.dataRange.back.status == BucketStatus.used);
}
do
{
do
{
dataRange.popBack();
this.dataRange.popBack();
}
while (!dataRange.empty && dataRange.back.status != BucketStatus.used);
while (!empty && dataRange.back.status != BucketStatus.used);
}
@property ref inout(E) front() inout
in
{
assert(!this.dataRange.empty);
assert(!empty);
assert(this.dataRange.front.status == BucketStatus.used);
}
do
{
return dataRange.front.content;
return this.dataRange.front.key;
}
@property ref inout(E) back() inout
in
{
assert(!this.dataRange.empty);
assert(!empty);
assert(this.dataRange.back.status == BucketStatus.used);
}
do
{
return dataRange.back.content;
return this.dataRange.back.key;
}
Range opIndex()
@ -132,7 +133,7 @@ struct Range(E)
return typeof(return)(this.dataRange[]);
}
Range!(const E) opIndex() const
Range!(const T) opIndex() const
{
return typeof(return)(this.dataRange[]);
}
@ -145,25 +146,33 @@ struct Range(E)
* This $(D_PSYMBOL Set) is implemented using closed hashing. Hash collisions
* are resolved with linear probing.
*
* Currently works only with integral types.
* $(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.
* T = Element type.
* hasher = Hash function for $(D_PARAM T).
*/
struct Set(T)
if (isIntegral!T || is(Unqual!T == bool))
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!T;
alias Range = .Range!HashArray;
/// ditto
alias ConstRange = .Range!(const T);
alias ConstRange = .Range!(const HashArray);
invariant
{
assert(this.lengthIndex < primes.length);
assert(this.data.length == 0
|| this.data.length == primes[this.lengthIndex]);
assert(this.data.lengthIndex < primes.length);
assert(this.data.array.length == 0
|| this.data.array.length == primes[this.data.lengthIndex]);
}
/**
@ -175,7 +184,7 @@ struct Set(T)
*
* Precondition: $(D_INLINECODE allocator !is null).
*/
this(const size_t n, shared Allocator allocator = defaultAllocator)
this(size_t n, shared Allocator allocator = defaultAllocator)
in
{
assert(allocator !is null);
@ -183,7 +192,14 @@ struct Set(T)
do
{
this(allocator);
rehash(n);
this.data.rehash(n);
}
///
@nogc nothrow pure @safe unittest
{
auto set = Set!int(5);
assert(set.capacity == 7);
}
/// ditto
@ -194,20 +210,7 @@ struct Set(T)
}
do
{
this.data = typeof(this.data)(allocator);
}
///
unittest
{
{
auto set = Set!int(defaultAllocator);
assert(set.capacity == 0);
}
{
auto set = Set!int(8);
assert(set.capacity == 13);
}
this.data = HashArray(allocator);
}
/**
@ -220,30 +223,90 @@ struct Set(T)
* 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))
if (is(Unqual!S == Set))
in
{
assert(allocator !is null);
}
do
{
this.data = typeof(this.data)(init.data, allocator);
this.data = HashArray(init.data, allocator);
}
/// ditto
this(S)(S init, shared Allocator allocator = defaultAllocator)
if (is(S == Set))
if (is(S == Set))
in
{
assert(allocator !is null);
}
do
{
this.data = typeof(this.data)(move(init.data), allocator);
this.lengthIndex = init.lengthIndex;
init.lengthIndex = 0;
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);
}
/**
@ -259,19 +322,17 @@ struct Set(T)
* Returns: $(D_KEYWORD this).
*/
ref typeof(this) opAssign(S)(ref S that)
if (is(Unqual!S == Set))
if (is(Unqual!S == Set))
{
this.data = that.data;
this.lengthIndex = that.lengthIndex;
return this;
}
/// ditto
ref typeof(this) opAssign(S)(S that) @trusted
if (is(S == Set))
if (is(S == Set))
{
swap(this.data, that.data);
swap(this.lengthIndex, that.lengthIndex);
this.data.swap(that.data);
return this;
}
@ -287,7 +348,7 @@ struct Set(T)
}
do
{
return cast(shared Allocator) this.data.allocator;
return this.data.array.allocator;
}
/**
@ -301,11 +362,11 @@ struct Set(T)
*/
@property size_t capacity() const
{
return this.data.length;
return this.data.capacity;
}
///
unittest
@nogc nothrow pure @safe unittest
{
Set!int set;
assert(set.capacity == 0);
@ -321,19 +382,11 @@ struct Set(T)
*/
@property size_t length() const
{
size_t count;
foreach (ref e; this.data[])
{
if (e.status == BucketStatus.used)
{
++count;
}
}
return count;
return this.data.length;
}
///
unittest
@nogc nothrow pure @safe unittest
{
Set!int set;
assert(set.length == 0);
@ -342,81 +395,46 @@ struct Set(T)
assert(set.length == 1);
}
private static const size_t[41] primes = [
3, 7, 13, 23, 29, 37, 53, 71, 97, 131, 163, 193, 239, 293, 389, 521,
769, 919, 1103, 1327, 1543, 2333, 3079, 4861, 6151, 12289, 24593,
49157, 98317, 196613, 393241, 786433, 1572869, 3145739, 6291469,
12582917, 25165843, 139022417, 282312799, 573292817, 1164186217,
];
/**
* Tells whether the container contains any elements.
*
* Returns: Whether the container is empty.
*/
@property bool empty() const
{
return length == 0;
}
///
@nogc nothrow pure @safe unittest
{
Set!int set;
assert(set.empty);
set.insert(5);
assert(!set.empty);
}
/**
* Removes all elements.
*/
void clear()
{
this.data.clear();
}
///
@nogc nothrow pure @safe unittest
{
Set!int set;
set.insert(5);
assert(!set.empty);
set.clear();
assert(set.empty);
}
/// The maximum number of buckets the container can have.
enum size_t maxBucketCount = primes[$ - 1];
static private size_t calculateHash(U)(ref const U value)
if (is(U == Unqual!T))
{
static if (isIntegral!T || isSomeChar!T || is(T == bool))
{
return (cast(size_t) value);
}
else
{
static assert(false);
}
}
static private size_t locateBucket(ref const DataType buckets,
const size_t hash)
in
{
assert(buckets.length > 0);
}
do
{
return hash % buckets.length;
}
/*
* Returns bucket position for `hash`. `0` may mean the 0th position or an
* empty `buckets` array.
*/
private size_t locateBucket(const size_t hash) const
{
return this.data.length == 0 ? 0 : locateBucket(this.data, hash);
}
private enum InsertStatus : byte
{
found = -1,
failed = 0,
added = 1,
}
/*
* Inserts the value in an empty or deleted bucket. If the value is
* already in there, does nothing and returns InsertStatus.found. If the
* hash array is full returns InsertStatus.failed. Otherwise,
* InsertStatus.added is returned.
*/
private InsertStatus insertInUnusedBucket(ref T value)
{
auto bucketPosition = locateBucket(this.data, calculateHash(value));
foreach (ref e; this.data[bucketPosition .. $])
{
if (e == value) // Already in the set.
{
return InsertStatus.found;
}
else if (e.status != BucketStatus.used) // Insert the value.
{
e.content = value;
return InsertStatus.added;
}
}
return InsertStatus.failed;
}
/**
* Inserts a new element.
*
@ -424,31 +442,20 @@ struct Set(T)
* value = Element value.
*
* Returns: Amount of new elements inserted.
*
* Throws: $(D_PSYMBOL HashContainerFullException) if the insertion failed.
*/
size_t insert(T value)
{
if (this.data.length == 0)
auto e = ((ref v) @trusted => &this.data.insert(v))(value);
if (e.status != BucketStatus.used)
{
this.data = DataType(primes[0], allocator);
e.key = value;
return 1;
}
InsertStatus status = insertInUnusedBucket(value);
for (; !status; status = insertInUnusedBucket(value))
{
if (this.primes.length == (this.lengthIndex + 1))
{
throw make!HashContainerFullException(defaultAllocator,
"Set is full");
}
rehashToSize(this.lengthIndex + 1);
}
return status == InsertStatus.added;
return 0;
}
///
unittest
@nogc nothrow pure @safe unittest
{
Set!int set;
assert(8 !in set);
@ -465,6 +472,38 @@ struct Set(T)
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.
*
@ -476,31 +515,16 @@ struct Set(T)
*/
size_t remove(T value)
{
auto bucketPosition = locateBucket(calculateHash(value));
foreach (ref e; this.data[bucketPosition .. $])
{
if (e == value) // Found.
{
e.remove();
return 1;
}
else if (e.status == BucketStatus.empty)
{
break;
}
}
return 0;
return this.data.remove(value);
}
///
@nogc unittest
@nogc nothrow pure @safe unittest
{
Set!int set;
assert(8 !in set);
set.insert(8);
assert(8 in set);
assert(8 in set);
assert(set.remove(8) == 1);
assert(set.remove(8) == 0);
assert(8 !in set);
@ -515,25 +539,13 @@ struct Set(T)
* Returns: $(D_KEYWORD true) if the given element exists in the container,
* $(D_KEYWORD false) otherwise.
*/
bool opBinaryRight(string op : "in")(auto ref const T value) const
bool opBinaryRight(string op : "in")(auto ref inout(T) value) inout
{
auto bucketPosition = locateBucket(calculateHash(value));
foreach (ref e; this.data[bucketPosition .. $])
{
if (e == value) // Found.
{
return true;
}
else if (e.status == BucketStatus.empty)
{
break;
}
}
return false;
return value in this.data;
}
///
@nogc unittest
@nogc nothrow pure @safe unittest
{
Set!int set;
@ -566,62 +578,29 @@ struct Set(T)
* Params:
* n = Minimum number of buckets.
*/
void rehash(const size_t n)
void rehash(size_t n)
{
size_t lengthIndex;
for (; lengthIndex < primes.length; ++lengthIndex)
{
if (primes[lengthIndex] >= n)
{
break;
}
}
rehashToSize(lengthIndex);
}
// Takes an index in the primes array.
private void rehashToSize(const size_t n)
{
auto storage = DataType(primes[n], allocator);
DataLoop: foreach (ref e1; this.data[])
{
if (e1.status == BucketStatus.used)
{
auto bucketPosition = locateBucket(storage,
calculateHash(e1.content));
foreach (ref e2; storage[bucketPosition .. $])
{
if (e2.status != BucketStatus.used) // Insert the value.
{
e2.content = e1.content;
continue DataLoop;
}
}
return; // Rehashing failed.
}
}
move(storage, this.data);
this.lengthIndex = n;
this.data.rehash(n);
}
/**
* Returns: A bidirectional range that iterates over the $(D_PSYMBOL Set)'s
* elements.
* Returns a bidirectional range over the container.
*
* Returns: A bidirectional range that iterates over the container.
*/
Range opIndex()
{
return typeof(return)(this.data[]);
return typeof(return)(this.data.array[]);
}
/// ditto
ConstRange opIndex() const
{
return typeof(return)(this.data[]);
return typeof(return)(this.data.array[]);
}
///
@nogc unittest
@nogc nothrow pure @safe unittest
{
Set!int set;
assert(set[].empty);
@ -630,77 +609,42 @@ struct Set(T)
assert(!set[].empty);
assert(set[].front == 8);
assert(set[].back == 8);
set.remove(8);
assert(set[].empty);
}
private @nogc unittest
{
const Set!int set;
assert(set[].empty);
}
private @nogc unittest
{
Set!int set;
set.insert(8);
auto r1 = set[];
auto r2 = r1.save();
r1.popFront();
assert(r1.empty);
r2.popBack();
assert(r2.empty);
}
private alias DataType = Array!(Bucket!T);
private DataType data;
private size_t lengthIndex;
}
// Basic insertion logic.
private @nogc unittest
@nogc nothrow pure @safe unittest
{
Set!int set;
assert(set.insert(5) == 1);
assert(set.data[0].status == BucketStatus.empty);
assert(set.data[1].status == BucketStatus.empty);
assert(set.data[2].content == 5 && set.data[2].status == BucketStatus.used);
assert(set.data.length == 3);
assert(5 in set);
assert(set.data.array.length == 3);
assert(set.insert(5) == 0);
assert(set.data[0].status == BucketStatus.empty);
assert(set.data[1].status == BucketStatus.empty);
assert(set.data[2].content == 5 && set.data[2].status == BucketStatus.used);
assert(set.data.length == 3);
assert(5 in set);
assert(set.data.array.length == 3);
assert(set.insert(9) == 1);
assert(set.data[0].content == 9 && set.data[0].status == BucketStatus.used);
assert(set.data[1].status == BucketStatus.empty);
assert(set.data[2].content == 5 && set.data[2].status == BucketStatus.used);
assert(set.data.length == 3);
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(set.data[0].content == 7);
assert(set.data[1].content == 8);
assert(set.data[2].content == 9);
assert(set.data[3].status == BucketStatus.empty);
assert(set.data[5].content == 5);
assert(set.data.length == 7);
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(set.data[2].content == 9);
assert(set.data[3].content == 16);
assert(set.data[4].status == BucketStatus.empty);
assert(16 in set);
assert(set.data.array.length == 7);
}
// Static checks.
private unittest
@nogc nothrow pure @safe unittest
{
import tanya.range.primitive;
@ -717,3 +661,83 @@ private unittest
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);
}

3
source/tanya/container/string.d
View File

@ -26,9 +26,10 @@
*/
module tanya.container.string;
import std.algorithm.comparison;
import std.algorithm.comparison : cmp;
import std.algorithm.mutation : bringToFront, copy;
import std.algorithm.searching;
import tanya.algorithm.comparison;
import tanya.algorithm.mutation;
import tanya.memory;
import tanya.meta.trait;

148
source/tanya/conv.d
View File

@ -5,7 +5,7 @@
/**
* This module provides functions for converting between different types.
*
* Copyright: Eugene Wissner 2017.
* 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)
@ -20,6 +20,8 @@ import tanya.memory;
import tanya.memory.op;
import tanya.meta.trait;
import tanya.meta.transform;
import tanya.range.array;
import tanya.range.primitive;
version (unittest)
{
@ -264,6 +266,150 @@ final class ConvException : Exception
}
}
/*
* Converts a string $(D_PARAM range) into an integral value of type
* $(D_PARAM T) in $(D_PARAM base).
*
* The convertion stops when $(D_PARAM range) is empty of if the next character
* cannot be converted because it is not a digit (with respect to the
* $(D_PARAM base)) or if the reading the next character would cause integer
* overflow. The function returns the value converted so far then. The front
* element of the $(D_PARAM range) points to the first character cannot be
* converted or $(D_PARAM range) is empty if the whole string could be
* converted.
*
* Base must be between 2 and 36 inclursive. Default base is 10.
*
* The function doesn't handle the sign (+ or -) or number prefixes (like 0x).
*/
package T readIntegral(T, R)(ref R range, ubyte base = 10)
if (isForwardRange!R
&& isSomeChar!(ElementType!R)
&& isIntegral!T
&& isUnsigned!T)
in
{
assert(base >= 2);
assert(base <= 36);
}
do
{
T boundary = cast(T) (T.max / base);
if (range.empty)
{
return T.init;
}
T n;
while (n <= boundary)
{
int digit;
if (range.front >= 'a')
{
digit = range.front - 'W';
}
else if (range.front >= 'A')
{
digit = range.front - '7';
}
else if (range.front >= '0')
{
digit = range.front - '0';
}
else
{
return n;
}
if (digit >= base)
{
return n;
}
n = cast(T) (n * base + digit);
range.popFront();
if (range.empty)
{
return n;
}
}
if (range.length > 1)
{
return n;
}
int digit = range.front - '0';
if (n > cast(T) ((T.max - digit) / base))
{
return n;
}
n = cast(T) (n * base + digit);
return n;
}
// reads ubyte.max
@nogc nothrow pure @safe unittest
{
string number = "255";
assert(readIntegral!ubyte(number) == 255);
assert(number.empty);
}
// detects integer overflow
@nogc nothrow pure @safe unittest
{
string number = "500";
readIntegral!ubyte(number);
assert(number.front == '0');
assert(number.length == 1);
}
// stops on a non-digit
@nogc nothrow pure @safe unittest
{
string number = "10-";
readIntegral!ubyte(number);
assert(number.front == '-');
}
// returns false if the number string is empty
@nogc nothrow pure @safe unittest
{
string number = "";
readIntegral!ubyte(number);
assert(number.empty);
}
@nogc nothrow pure @safe unittest
{
string number = "29";
assert(readIntegral!ubyte(number) == 29);
assert(number.empty);
}
@nogc nothrow pure @safe unittest
{
string number = "25467";
readIntegral!ubyte(number);
assert(number.front == '6');
}
// Converts lower case hexadecimals
@nogc nothrow pure @safe unittest
{
string number = "a";
assert(readIntegral!ubyte(number, 16) == 10);
assert(number.empty);
}
// Converts upper case hexadecimals
@nogc nothrow pure @safe unittest
{
string number = "FF";
assert(readIntegral!ubyte(number, 16) == 255);
assert(number.empty);
}
/**
* If the source type $(D_PARAM From) and the target type $(D_PARAM To) are
* equal, does nothing. If $(D_PARAM From) can be implicitly converted to

54
source/tanya/encoding/ascii.d
View File

@ -8,7 +8,7 @@
* ASCII is $(B A)merican $(B S)tandard $(B C)ode for $(B I)nformation
* $(B I)nterchange.
*
* Copyright: Eugene Wissner 2017.
* 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)
@ -19,23 +19,23 @@ module tanya.encoding.ascii;
import tanya.meta.trait;
const string fullHexDigits = "0123456789ABCDEFabcdef"; /// 0..9A..Fa..f.
const string hexDigits = "0123456789ABCDEF"; /// 0..9A..F.
const string lowerHexDigits = "0123456789abcdef"; /// 0..9a..f.
const string digits = "0123456789"; /// 0..9.
const string octalDigits = "01234567"; /// 0..7.
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.
const string letters = "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz";
immutable string letters = "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz";
const string uppercase = "ABCDEFGHIJKLMNOPQRSTUVWXYZ"; /// A..Z.
const string lowercase = "abcdefghijklmnopqrstuvwxyz"; /// a..z.
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).
*/
const string whitespace = "\t\n\v\f\r ";
immutable string whitespace = "\t\n\v\f\r ";
/// Letter case specifier.
enum LetterCase : bool
@ -61,7 +61,7 @@ if (isSomeChar!C)
}
///
pure nothrow @safe @nogc unittest
@nogc nothrow pure @safe unittest
{
assert(isUpper('A'));
assert(isUpper('Z'));
@ -87,7 +87,7 @@ if (isSomeChar!C)
}
///
pure nothrow @safe @nogc unittest
@nogc nothrow pure @safe unittest
{
assert(isLower('a'));
assert(isLower('z'));
@ -113,7 +113,7 @@ if (isSomeChar!C)
}
///
pure nothrow @safe @nogc unittest
@nogc nothrow pure @safe unittest
{
assert(isAlpha('A'));
assert(isAlpha('Z'));
@ -141,7 +141,7 @@ if (isSomeChar!C)
}
///
pure nothrow @safe @nogc unittest
@nogc nothrow pure @safe unittest
{
assert(isDigit('0'));
assert(isDigit('1'));
@ -174,7 +174,7 @@ if (isSomeChar!C)
}
///
pure nothrow @safe @nogc unittest
@nogc nothrow pure @safe unittest
{
assert(isAlphaNum('0'));
assert(isAlphaNum('1'));
@ -205,7 +205,7 @@ if (isSomeChar!C)
}
///
pure nothrow @safe @nogc unittest
@nogc nothrow pure @safe unittest
{
assert(isASCII('0'));
assert(isASCII('L'));
@ -240,7 +240,7 @@ if (isSomeChar!C)
}
///
pure nothrow @safe @nogc unittest
@nogc nothrow pure @safe unittest
{
assert(isControl('\t'));
assert(isControl('\0'));
@ -281,7 +281,7 @@ if (isSomeChar!C)
}
///
pure nothrow @safe @nogc unittest
@nogc nothrow pure @safe unittest
{
assert(isWhite('\t'));
assert(isWhite('\n'));
@ -312,7 +312,7 @@ if (isSomeChar!C)
}
///
pure nothrow @safe @nogc unittest
@nogc nothrow pure @safe unittest
{
assert(isGraphical('a'));
assert(isGraphical('0'));
@ -343,7 +343,7 @@ if (isSomeChar!C)
}
///
pure nothrow @safe @nogc unittest
@nogc nothrow pure @safe unittest
{
assert(isPrintable('a'));
assert(isPrintable('0'));
@ -372,7 +372,7 @@ if (isSomeChar!C)
}
///
pure nothrow @safe @nogc unittest
@nogc nothrow pure @safe unittest
{
assert(isHexDigit('0'));
assert(isHexDigit('1'));
@ -403,7 +403,7 @@ if (isSomeChar!C)
}
///
pure nothrow @safe @nogc unittest
@nogc nothrow pure @safe unittest
{
assert(isOctalDigit('0'));
assert(isOctalDigit('1'));
@ -436,7 +436,7 @@ if (isSomeChar!C)
}
///
pure nothrow @safe @nogc unittest
@nogc nothrow pure @safe unittest
{
assert(isPunctuation('!'));
assert(isPunctuation(':'));
@ -459,14 +459,14 @@ pure nothrow @safe @nogc unittest
* Returns: The lowercase of $(D_PARAM c) if available, just $(D_PARAM c)
* otherwise.
*/
C toUpper(C)(const C c)
C toUpper(C)(C c)
if (isSomeChar!C)
{
return isLower(c) ? (cast(C) (c - 32)) : c;
}
///
pure nothrow @safe @nogc unittest
@nogc nothrow pure @safe unittest
{
assert(toUpper('a') == 'A');
assert(toUpper('A') == 'A');
@ -486,14 +486,14 @@ pure nothrow @safe @nogc unittest
* Returns: The uppercase of $(D_PARAM c) if available, just $(D_PARAM c)
* otherwise.
*/
C toLower(C)(const C c)
C toLower(C)(C c)
if (isSomeChar!C)
{
return isUpper(c) ? (cast(C) (c + 32)) : c;
}
///
pure nothrow @safe @nogc unittest
@nogc nothrow pure @safe unittest
{
assert(toLower('A') == 'a');
assert(toLower('a') == 'a');

2
source/tanya/encoding/package.d
View File

@ -5,7 +5,7 @@
/**
* This package provides tools to work with text encodings.
*
* Copyright: Eugene Wissner 2017.
* 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)

2
source/tanya/exception.d
View File

@ -5,7 +5,7 @@
/**
* Common exceptions and errors.
*
* Copyright: Eugene Wissner 2017.
* 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)

5
source/tanya/format.d
View File

@ -3,9 +3,10 @@
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
/**
* This package contains formatting and conversion functions.
* This package doesn't yet contain public symbols. Refer to
* $(D_PSYMBOL tanya.conv) for basic formatting and conversion functionality.
*
* Copyright: Eugene Wissner 2017.
* 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)

13
source/tanya/hash/lookup.d
View File

@ -77,10 +77,11 @@ private struct FNV
}
/**
* Takes an a argument of an arbitrary type $(D_PARAM T) and calculates the hash value.
* 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:
* $(D_KEYWORD struct)s, should implement `toHash`-function:
* ---
* size_t toHash() const
* {
@ -96,7 +97,7 @@ private struct FNV
* Individual values are combined then and the resulting hash is returned.
*
* Params:
* T = Hashable type.
* T = Hashable type.
* key = Hashable value.
*
* Returns: Calculated hash value.
@ -124,7 +125,7 @@ version (unittest)
~ 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 struct ToHash
private static struct ToHash
{
size_t toHash() const @nogc nothrow pure @safe
{
@ -132,7 +133,7 @@ version (unittest)
}
}
private struct HashRange
private static struct HashRange
{
string fo = "fo";
@ -152,7 +153,7 @@ version (unittest)
}
}
private struct ToHashRange
private static struct ToHashRange
{
bool empty_;

5
source/tanya/math/mp.d
View File

@ -14,9 +14,10 @@
*/
module tanya.math.mp;
import std.algorithm.comparison;
import std.algorithm.comparison : cmp;
import std.algorithm.mutation : copy, fill, reverse;
import std.range;
import tanya.algorithm.comparison;
import tanya.algorithm.mutation;
import tanya.container.array;
import tanya.encoding.ascii;
@ -1256,7 +1257,7 @@ struct Integer
for (size_t i; i < this.size; ++i)
{
const limit = min(factor.size, digits - i);
const limit = min(cast(size_t) factor.size, digits - i);
word carry;
auto k = i;

53
source/tanya/math/nbtheory.d
View File

@ -16,9 +16,17 @@ 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
{
@ -35,7 +43,7 @@ else
*
* Returns: Absolute value of $(D_PARAM x).
*/
T abs(T)(T x)
Unqual!T abs(T)(T x)
if (isIntegral!T)
{
static if (isSigned!T)
@ -60,24 +68,11 @@ if (isIntegral!T)
static assert(is(typeof(u.abs) == uint));
}
version (D_Ddoc)
/// ditto
Unqual!T abs(T)(T x)
if (isFloatingPoint!T)
{
/// ditto
T abs(T)(T x)
if (isFloatingPoint!T);
}
else version (TanyaNative)
{
extern T abs(T)(T number) @nogc nothrow pure @safe
if (isFloatingPoint!T);
}
else
{
T abs(T)(T x)
if (isFloatingPoint!T)
{
return fabs(cast(real) x);
}
return fabs(x);
}
///
@ -122,17 +117,31 @@ version (D_Ddoc)
*
* Returns: Natural logarithm of $(D_PARAM x).
*/
T ln(T)(T x)
Unqual!T ln(T)(T x)
if (isFloatingPoint!T);
}
else version (TanyaNative)
{
extern T ln(T)(T x) @nogc nothrow pure @safe
if (isFloatingPoint!T);
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
{
T ln(T)(T x)
Unqual!T ln(T)(T x)
if (isFloatingPoint!T)
{
return log(x);

82
source/tanya/math/package.d
View File

@ -38,7 +38,7 @@ enum IEEEPrecision : ubyte
/**
* Tests the precision of floating-point type $(D_PARAM F).
*
* For $(D_KEYWORD float), $(D_PSYMBOL ieeePrecision) always evaluates to
* 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.
@ -89,7 +89,7 @@ if (isFloatingPoint!F)
private union FloatBits(F)
{
F floating;
Unqual!F floating;
static if (ieeePrecision!F == IEEEPrecision.single)
{
uint integral;
@ -396,7 +396,7 @@ if (isFloatingPoint!F)
/**
* 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
*
@ -459,7 +459,7 @@ if (isFloatingPoint!F)
/**
* Determines whether $(D_PARAM x) is a normilized number or not.
*
* Normalized number is a number that can be represented as
*
* <pre>
@ -632,7 +632,6 @@ do
size_t i;
auto tmp1 = Integer(x, x.allocator);
auto result = Integer(x.allocator);
bool firstBit;
if (x.size == 0 && y.size != 0)
{
@ -741,32 +740,14 @@ bool isPseudoprime(ulong x) @nogc nothrow pure @safe
assert(982451653.isPseudoprime);
}
/**
* Determines minimum of two numbers.
*
* Params:
* x = First number.
* y = Second number.
*
* Returns: $(D_PARAM x) if $(D_PARAM x) is smaller than $(D_PSYMBOL y),
* $(D_PARAM y) otherwise.
*
* See_Also: $(D_PSYMBOL max).
*/
deprecated("Use tanya.algorithm.comparison.min instead")
T min(T)(T x, T y)
if (isIntegral!T)
{
return x < y ? x : y;
}
///
@nogc nothrow pure @safe unittest
{
assert(min(5, 3) == 3);
assert(min(4, 4) == 4);
}
/// ditto
deprecated("Use tanya.algorithm.comparison.min instead")
T min(T)(T x, T y)
if (isFloatingPoint!T)
{
@ -781,62 +762,33 @@ if (isFloatingPoint!T)
return x < y ? x : y;
}
///
@nogc nothrow pure @safe unittest
{
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
deprecated("Use tanya.algorithm.comparison.min instead")
ref T min(T)(ref T x, ref T y)
if (is(Unqual!T == Integer))
{
return x < y ? x : y;
}
/// ditto
deprecated("Use tanya.algorithm.comparison.min instead")
T min(T)(T x, T y)
if (is(T == Integer))
{
return x < y ? move(x) : move(y);
}
///
@nogc nothrow pure @safe unittest
{
assert(min(Integer(5), Integer(3)) == 3);
}
/**
* Determines maximum of two numbers.
*
* Params:
* x = First number.
* y = Second number.
*
* Returns: $(D_PARAM x) if $(D_PARAM x) is larger than $(D_PSYMBOL y),
* $(D_PARAM y) otherwise.
*
* See_Also: $(D_PSYMBOL min).
*/
deprecated("Use tanya.algorithm.comparison.max instead")
T max(T)(T x, T y)
if (isIntegral!T)
{
return x > y ? x : y;
}
///
@nogc nothrow pure @safe unittest
{
assert(max(5, 3) == 5);
assert(max(4, 4) == 4);
}
/// ditto
deprecated("Use tanya.algorithm.comparison.max instead")
T max(T)(T x, T y)
if (isFloatingPoint!T)
{
@ -851,24 +803,14 @@ if (isFloatingPoint!T)
return x > y ? x : y;
}
///
@nogc nothrow pure @safe unittest
{
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
deprecated("Use tanya.algorithm.comparison.max instead")
ref T max(T)(ref T x, ref T y)
if (is(Unqual!T == Integer))
{
return x > y ? x : y;
}
/// ditto
deprecated("Use tanya.algorithm.comparison.max instead")
T max(T)(T x, T y)
if (is(T == Integer))
{

6
source/tanya/memory/allocator.d
View File

@ -35,7 +35,7 @@ interface Allocator
*
* Returns: Pointer to the new allocated memory.
*/
void[] allocate(const size_t size) shared pure nothrow @nogc;
void[] allocate(size_t size) shared pure nothrow @nogc;
/**
* Deallocates a memory block.
@ -56,7 +56,7 @@ interface Allocator
*
* Returns: Pointer to the allocated memory.
*/
bool reallocate(ref void[] p, const size_t size) shared pure nothrow @nogc;
bool reallocate(ref void[] p, size_t size) shared pure nothrow @nogc;
/**
* Reallocates a memory block in place if possible or returns
@ -70,7 +70,7 @@ interface Allocator
*
* Returns: $(D_KEYWORD true) if successful, $(D_KEYWORD false) otherwise.
*/
bool reallocateInPlace(ref void[] p, const size_t size)
bool reallocateInPlace(ref void[] p, size_t size)
shared pure nothrow @nogc;
}

38
source/tanya/memory/mallocator.d
View File

@ -29,11 +29,11 @@ import tanya.memory.allocator;
final class Mallocator : Allocator
{
private alias MallocType = extern (C) void* function(size_t)
pure nothrow @system @nogc;
@nogc nothrow pure @system;
private alias FreeType = extern (C) void function(void*)
pure nothrow @system @nogc;
@nogc nothrow pure @system;
private alias ReallocType = extern (C) void* function(void*, size_t)
pure nothrow @system @nogc;
@nogc nothrow pure @system;
/**
* Allocates $(D_PARAM size) bytes of memory.
@ -43,7 +43,7 @@ final class Mallocator : Allocator
*
* Returns: The pointer to the new allocated memory.
*/
void[] allocate(const size_t size) shared pure nothrow @nogc
void[] allocate(size_t size) @nogc nothrow pure shared @system
{
if (size == 0)
{
@ -55,7 +55,7 @@ final class Mallocator : Allocator
}
///
@nogc nothrow unittest
@nogc nothrow pure @system unittest
{
auto p = Mallocator.instance.allocate(20);
assert(p.length == 20);
@ -73,7 +73,7 @@ final class Mallocator : Allocator
*
* Returns: Whether the deallocation was successful.
*/
bool deallocate(void[] p) shared pure nothrow @nogc
bool deallocate(void[] p) @nogc nothrow pure shared @system
{
if (p !is null)
{
@ -83,7 +83,7 @@ final class Mallocator : Allocator
}
///
@nogc nothrow unittest
@nogc nothrow pure @system unittest
{
void[] p;
assert(Mallocator.instance.deallocate(p));
@ -101,14 +101,15 @@ final class Mallocator : Allocator
*
* Returns: $(D_KEYWORD false).
*/
bool reallocateInPlace(ref void[] p, const size_t size)
shared pure nothrow @nogc
bool reallocateInPlace(ref void[] p, size_t size)
@nogc nothrow pure shared @system
{
cast(void) size;
return false;
}
///
@nogc nothrow unittest
@nogc nothrow pure @system unittest
{
void[] p;
assert(!Mallocator.instance.reallocateInPlace(p, 8));
@ -123,7 +124,8 @@ final class Mallocator : Allocator
*
* Returns: Whether the reallocation was successful.
*/
bool reallocate(ref void[] p, const size_t size) shared pure nothrow @nogc
bool reallocate(ref void[] p, size_t size)
@nogc nothrow pure shared @system
{
if (size == 0)
{
@ -152,7 +154,7 @@ final class Mallocator : Allocator
}
///
@nogc nothrow unittest
@nogc nothrow pure @system unittest
{
void[] p;
@ -169,8 +171,8 @@ final class Mallocator : Allocator
assert(p is null);
}
// Fails with false.
private @nogc nothrow unittest
// Fails with false
@nogc nothrow pure @system unittest
{
void[] p = Mallocator.instance.allocate(20);
void[] oldP = p;
@ -182,7 +184,7 @@ final class Mallocator : Allocator
/**
* Returns: The alignment offered.
*/
@property uint alignment() shared const pure nothrow @safe @nogc
@property uint alignment() const @nogc nothrow pure @safe shared
{
return (void*).alignof;
}
@ -192,7 +194,7 @@ final class Mallocator : Allocator
assert(Mallocator.instance.alignment == (void*).alignof);
}
static private shared(Mallocator) instantiate() nothrow @nogc
static private shared(Mallocator) instantiate() @nogc nothrow @system
{
if (instance_ is null)
{
@ -213,13 +215,13 @@ final class Mallocator : Allocator
*
* Returns: The global $(D_PSYMBOL Allocator) instance.
*/
static @property shared(Mallocator) instance() pure nothrow @nogc
static @property shared(Mallocator) instance() @nogc nothrow pure @system
{
return (cast(GetPureInstance!Mallocator) &instantiate)();
}
///
@nogc nothrow unittest
@nogc nothrow pure @system unittest
{
assert(instance is instance);
}

131
source/tanya/memory/mmappool.d
View File

@ -14,45 +14,32 @@
*/
module tanya.memory.mmappool;
import std.algorithm.comparison;
import tanya.memory.allocator;
import tanya.memory.op;
version (TanyaNative):
import core.sys.posix.sys.mman : MAP_ANON,
MAP_FAILED,
MAP_PRIVATE,
PROT_READ,
PROT_WRITE;
import core.sys.posix.unistd;
import mir.linux._asm.unistd;
import tanya.algorithm.comparison;
import tanya.memory.allocator;
import tanya.memory.op;
import tanya.os.error;
import tanya.sys.linux.syscall;
import tanya.sys.posix.mman;
extern(C)
private void* mmap(void* addr,
size_t len,
int prot,
int flags,
int fd,
off_t offset) pure nothrow @system @nogc;
extern(C)
private int munmap(void* addr, size_t len) pure nothrow @system @nogc;
private void* mapMemory(const size_t len) pure nothrow @system @nogc
private void* mapMemory(const size_t length) @nogc nothrow pure @system
{
void* p = mmap(null,
len,
PROT_READ | PROT_WRITE,
MAP_PRIVATE | MAP_ANON,
-1,
0);
return p is MAP_FAILED ? null : p;
auto p = syscall_(0,
length,
PROT_READ | PROT_WRITE,
MAP_PRIVATE | MAP_ANONYMOUS,
-1,
0,
NR_mmap);
return p == -ErrorCode.noMemory ? null : cast(void*) p;
}
private bool unmapMemory(shared void* addr, const size_t len)
pure nothrow @system @nogc
private bool unmapMemory(shared void* addr, const size_t length)
@nogc nothrow pure @system
{
return munmap(cast(void*) addr, len) == 0;
return syscall_(cast(ptrdiff_t) addr, length, NR_munmap) == 0;
}
/*
@ -83,7 +70,7 @@ final class MmapPool : Allocator
{
version (none)
{
pure nothrow @nogc invariant
@nogc nothrow pure @system invariant
{
for (auto r = &head; *r !is null; r = &((*r).next))
{
@ -107,7 +94,7 @@ final class MmapPool : Allocator
*
* Returns: Pointer to the new allocated memory.
*/
void[] allocate(const size_t size) shared pure nothrow @nogc
void[] allocate(size_t size) @nogc nothrow pure shared @system
{
if (size == 0)
{
@ -128,7 +115,7 @@ final class MmapPool : Allocator
return data is null ? null : data[0 .. size];
}
@nogc nothrow pure unittest
@nogc nothrow pure @system unittest
{
auto p = MmapPool.instance.allocate(20);
assert(p);
@ -138,15 +125,14 @@ final class MmapPool : Allocator
assert(p.length == 0);
}
// Issue 245: https://issues.caraus.io/issues/245.
@nogc nothrow pure unittest
@nogc nothrow pure @system unittest
{
// allocate() check.
size_t tooMuchMemory = size_t.max
- MmapPool.alignment_
- BlockEntry.sizeof * 2
- RegionEntry.sizeof
- MmapPool.instance.pageSize;
- pageSize;
assert(MmapPool.instance.allocate(tooMuchMemory) is null);
assert(MmapPool.instance.allocate(size_t.max) is null);
@ -165,7 +151,8 @@ final class MmapPool : Allocator
*
* Returns: Data the block points to or $(D_KEYWORD null).
*/
private void* findBlock(const ref size_t size) shared pure nothrow @nogc
private void* findBlock(const ref size_t size)
@nogc nothrow pure shared @system
{
Block block1;
RegionLoop: for (auto r = head; r !is null; r = r.next)
@ -207,7 +194,7 @@ final class MmapPool : Allocator
}
// Merge block with the next one.
private void mergeNext(Block block) shared const pure nothrow @safe @nogc
private void mergeNext(Block block) const @nogc nothrow pure @safe shared
{
block.size = block.size + BlockEntry.sizeof + block.next.size;
if (block.next.next !is null)
@ -225,7 +212,7 @@ final class MmapPool : Allocator
*
* Returns: Whether the deallocation was successful.
*/
bool deallocate(void[] p) shared pure nothrow @nogc
bool deallocate(void[] p) @nogc nothrow pure shared @system
{
if (p.ptr is null)
{
@ -271,7 +258,7 @@ final class MmapPool : Allocator
return true;
}
@nogc nothrow pure unittest
@nogc nothrow pure @system unittest
{
auto p = MmapPool.instance.allocate(20);
@ -290,8 +277,8 @@ final class MmapPool : Allocator
*
* Returns: $(D_KEYWORD true) if successful, $(D_KEYWORD false) otherwise.
*/
bool reallocateInPlace(ref void[] p, const size_t size)
shared pure nothrow @nogc
bool reallocateInPlace(ref void[] p, size_t size)
@nogc nothrow pure shared @system
{
if (p is null || size == 0)
{
@ -354,7 +341,7 @@ final class MmapPool : Allocator
return true;
}
@nogc nothrow pure unittest
@nogc nothrow pure @system unittest
{
void[] p;
assert(!MmapPool.instance.reallocateInPlace(p, 5));
@ -387,7 +374,8 @@ final class MmapPool : Allocator
*
* Returns: Whether the reallocation was successful.
*/
bool reallocate(ref void[] p, const size_t size) shared pure nothrow @nogc
bool reallocate(ref void[] p, size_t size)
@nogc nothrow pure shared @system
{
if (size == 0)
{
@ -419,7 +407,7 @@ final class MmapPool : Allocator
return true;
}
@nogc nothrow pure unittest
@nogc nothrow pure @system unittest
{
void[] p;
MmapPool.instance.reallocate(p, 10 * int.sizeof);
@ -447,28 +435,20 @@ final class MmapPool : Allocator
MmapPool.instance.deallocate(p);
}
static private shared(MmapPool) instantiate() nothrow @nogc
static private shared(MmapPool) instantiate() @nogc nothrow @system
{
if (instance_ is null)
{
// Get system dependend page size.
size_t pageSize = sysconf(_SC_PAGE_SIZE);
if (pageSize < 65536)
{
pageSize = pageSize * 65536 / pageSize;
}
const instanceSize = addAlignment(__traits(classInstanceSize,
MmapPool));
Region head; // Will become soon our region list head
void* data = initializeRegion(instanceSize, head, pageSize);
void* data = initializeRegion(instanceSize, head);
if (data !is null)
{
copy(typeid(MmapPool).initializer, data[0 .. instanceSize]);
instance_ = cast(shared MmapPool) data;
instance_.head = head;
instance_.pageSize = pageSize;
}
}
return instance_;
@ -479,12 +459,12 @@ final class MmapPool : Allocator
*
* Returns: Global $(D_PSYMBOL MmapPool) instance.
*/
static @property shared(MmapPool) instance() pure nothrow @nogc
static @property shared(MmapPool) instance() @nogc nothrow pure @system
{
return (cast(GetPureInstance!MmapPool) &instantiate)();
}
@nogc nothrow pure unittest
@nogc nothrow pure @system unittest
{
assert(instance is instance);
}
@ -498,12 +478,10 @@ final class MmapPool : Allocator
*
* Returns: A pointer to the data.
*/
private static void* initializeRegion(const size_t size,
ref Region head,
const size_t pageSize)
pure nothrow @nogc
private static void* initializeRegion(const size_t size, ref Region head)
@nogc nothrow pure @system
{
const regionSize = calculateRegionSize(size, pageSize);
const regionSize = calculateRegionSize(size);
if (regionSize < size)
{
return null;
@ -550,9 +528,10 @@ final class MmapPool : Allocator
return data;
}
private void* initializeRegion(const size_t size) shared pure nothrow @nogc
private void* initializeRegion(const size_t size)
@nogc nothrow pure shared @system
{
return initializeRegion(size, this.head, this.pageSize);
return initializeRegion(size, this.head);
}
/*
@ -561,21 +540,19 @@ final class MmapPool : Allocator
*
* Returns: Aligned size of $(D_PARAM x).
*/
private static size_t addAlignment(const size_t x) pure nothrow @safe @nogc
private static size_t addAlignment(const size_t x) @nogc nothrow pure @safe
{
return (x - 1) / alignment_ * alignment_ + alignment_;
}
/*
* Params:
* x = Required space.
* pageSize = Page size.
* x = Required space.
*
* Returns: Minimum region size (a multiple of $(D_PSYMBOL pageSize)).
*/
private static size_t calculateRegionSize(ref const size_t x,
ref const size_t pageSize)
pure nothrow @safe @nogc
private static size_t calculateRegionSize(ref const size_t x)
@nogc nothrow pure @safe
{
return (x + RegionEntry.sizeof + BlockEntry.sizeof * 2)
/ pageSize * pageSize + pageSize;
@ -584,12 +561,12 @@ final class MmapPool : Allocator
/*
* Returns: Alignment offered.
*/
@property uint alignment() shared const pure nothrow @safe @nogc
@property uint alignment() const @nogc nothrow pure @safe shared
{
return alignment_;
}
@nogc nothrow pure unittest
@nogc nothrow pure @system unittest
{
assert(MmapPool.instance.alignment == MmapPool.alignment_);
}
@ -597,7 +574,9 @@ final class MmapPool : Allocator
private enum uint alignment_ = 8;
private shared static MmapPool instance_;
private shared size_t pageSize;
// Page size.
enum size_t pageSize = 65536;
private shared struct RegionEntry
{
@ -622,7 +601,7 @@ final class MmapPool : Allocator
// A lot of allocations/deallocations, but it is the minimum caused a
// segmentation fault because MmapPool reallocateInPlace moves a block wrong.
@nogc nothrow pure unittest
@nogc nothrow pure @system unittest
{
auto a = MmapPool.instance.allocate(16);
auto d = MmapPool.instance.allocate(16);

5
source/tanya/memory/op.d
View File

@ -40,6 +40,11 @@ version (TanyaNative)
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;

24
source/tanya/memory/package.d
View File

@ -38,7 +38,7 @@ mixin template DefaultAllocator()
*
* Precondition: $(D_INLINECODE allocator_ !is null)
*/
this(shared Allocator allocator) pure nothrow @safe @nogc
this(shared Allocator allocator) @nogc nothrow pure @safe
in
{
assert(allocator !is null);
@ -56,7 +56,7 @@ mixin template DefaultAllocator()
*
* Postcondition: $(D_INLINECODE allocator !is null)
*/
protected @property shared(Allocator) allocator() pure nothrow @safe @nogc
@property shared(Allocator) allocator() @nogc nothrow pure @safe
out (allocator)
{
assert(allocator !is null);
@ -71,7 +71,7 @@ mixin template DefaultAllocator()
}
/// ditto
@property shared(Allocator) allocator() const pure nothrow @trusted @nogc
@property shared(Allocator) allocator() const @nogc nothrow pure @trusted
out (allocator)
{
assert(allocator !is null);
@ -88,11 +88,11 @@ mixin template DefaultAllocator()
// From druntime
extern (C)
private void _d_monitordelete(Object h, bool det) pure nothrow @nogc;
private void _d_monitordelete(Object h, bool det) @nogc nothrow pure;
shared Allocator allocator;
private shared(Allocator) getAllocatorInstance() nothrow @nogc
private shared(Allocator) getAllocatorInstance() @nogc nothrow
{
if (allocator is null)
{
@ -115,7 +115,7 @@ private shared(Allocator) getAllocatorInstance() nothrow @nogc
*
* Postcondition: $(D_INLINECODE allocator !is null).
*/
@property shared(Allocator) defaultAllocator() pure nothrow @trusted @nogc
@property shared(Allocator) defaultAllocator() @nogc nothrow pure @trusted
out (allocator)
{
assert(allocator !is null);
@ -133,7 +133,7 @@ do
*
* Precondition: $(D_INLINECODE allocator !is null).
*/
@property void defaultAllocator(shared(Allocator) allocator) nothrow @safe @nogc
@property void defaultAllocator(shared(Allocator) allocator) @nogc nothrow @safe
in
{
assert(allocator !is null);
@ -185,8 +185,8 @@ template stateSize(T)
{
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 assert(stateSize!(int[]) == (size_t.sizeof * 2));
static assert(stateSize!(short[3]) == 6);
static struct Empty
{
@ -285,7 +285,7 @@ package(tanya) void[] finalize(T)(ref T* p)
}
package(tanya) void[] finalize(T)(ref T p)
if (is(T == class) || is(T == interface))
if (isPolymorphicType!T)
{
if (p is null)
{
@ -405,7 +405,7 @@ void dispose(T)(shared Allocator allocator, auto ref T p)
* 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)
@ -441,7 +441,7 @@ do
* 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)

12
source/tanya/memory/smartref.d
View File

@ -23,7 +23,7 @@
*/
module tanya.memory.smartref;
import std.algorithm.comparison;
import tanya.algorithm.comparison;
import tanya.algorithm.mutation;
import tanya.conv;
import tanya.exception;
@ -259,7 +259,7 @@ struct RefCounted(T)
* reference types like classes, that can be accessed directly.
*
* Params:
* op = Operation.
* op = Operation.
*
* Returns: Reference to the pointed value.
*/
@ -276,7 +276,7 @@ struct RefCounted(T)
}
/**
* Returns: Whether this $(D_PSYMBOL RefCounted) already has an internal
* Returns: Whether this $(D_PSYMBOL RefCounted) already has an internal
* storage.
*/
@property bool isInitialized() const
@ -489,7 +489,7 @@ version (unittest)
* 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)
@ -743,7 +743,7 @@ struct Unique(T)
* reference types like classes, that can be accessed directly.
*
* Params:
* op = Operation.
* op = Operation.
*
* Returns: Reference to the pointed value.
*/
@ -837,7 +837,7 @@ struct Unique(T)
* 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)

156
source/tanya/meta/trait.d
View File

@ -70,17 +70,7 @@ enum bool isWideString(T) = is(T : const dchar[]) && !isStaticArray!T;
static assert(!isWideString!(dchar[10]));
}
/**
* 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).
*/
deprecated("Use tanya.meta.transform.Smallest instead")
template Smallest(Args...)
if (Args.length >= 1)
{
@ -100,15 +90,6 @@ if (Args.length >= 1)
}
}
///
@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)));
}
/**
* Determines whether $(D_PARAM T) is a complex type.
*
@ -185,6 +166,9 @@ enum bool isPolymorphicType(T) = is(T == class) || is(T == interface);
}
/**
* Determines whether the type $(D_PARAM T) has a static method
* named $(D_PARAM member).
*
* Params:
* T = Aggregate type.
* member = Symbol name.
@ -944,17 +928,7 @@ template mostNegative(T)
static assert(mostNegative!cfloat == -cfloat.max);
}
/**
* 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).
*/
deprecated("Use tanya.meta.transform.Largest instead")
template Largest(Args...)
if (Args.length >= 1)
{
@ -974,15 +948,6 @@ if (Args.length >= 1)
}
}
///
@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)));
}
/**
* Determines whether the type $(D_PARAM T) is copyable.
*
@ -1076,8 +1041,19 @@ enum bool isAbstractClass(T) = __traits(isAbstractClass, T);
static assert(!isAbstractClass!E);
}
private enum bool isType(alias T) = is(T);
private enum bool isType(T) = true;
/**
* Checks whether $(D_PARAM T) is a type, same as `is(T)` does.
*
* Params:
* T = A symbol.
*
* Returns: $(D_KEYWORD true) if $(D_PARAM T) is a type, $(D_KEYWORD false)
* otherwise.
*/
enum bool isType(alias T) = is(T);
/// ditto
enum bool isType(T) = true;
/**
* Determines whether $(D_PARAM Args) contains only types.
@ -3012,3 +2988,99 @@ template Fields(T)
static assert(is(Fields!short == AliasSeq!short));
}
/**
* Determines whether all $(D_PARAM Types) are the same.
*
* If $(D_PARAM Types) is empty, returns $(D_KEYWORD true).
*
* Params:
* Types = Type sequence.
*
* Returns: $(D_KEYWORD true) if all $(D_PARAM Types) are the same,
* $(D_KEYWORD false) otherwise.
*/
template allSameType(Types...)
{
static if (Types.length == 0)
{
enum bool allSameType = true;
}
else
{
private enum bool sameType(T) = is(T == Types[0]);
enum bool allSameType = allSatisfy!(sameType, Types[1 .. $]);
}
}
///
@nogc nothrow pure @safe unittest
{
static assert(allSameType!());
static assert(allSameType!int);
static assert(allSameType!(int, int, int));
static assert(!allSameType!(int, uint, int));
static assert(!allSameType!(int, uint, short));
}
/**
* Determines whether values of type $(D_PARAM T) can be compared for equality,
* i.e. using `==` or `!=` binary operators.
*
* Params:
* T = Type to test.
*
* Returns: $(D_KEYWORD true) if $(D_PARAM T) can be compared for equality,
* $(D_KEYWORD false) otherwise.
*/
enum bool isEqualityComparable(T) = ifTestable!(T, a => a == a);
///
@nogc nothrow pure @safe unittest
{
static assert(isEqualityComparable!int);
}
/**
* Determines whether values of type $(D_PARAM T) can be compared for ordering,
* i.e. using `>`, `>=`, `<` or `<=` binary operators.
*
* Params:
* T = Type to test.
*
* Returns: $(D_KEYWORD true) if $(D_PARAM T) can be compared for ordering,
* $(D_KEYWORD false) otherwise.
*/
enum bool isOrderingComparable(T) = ifTestable!(T, a => a > a);
///
@nogc nothrow pure @safe unittest
{
static assert(isOrderingComparable!int);
}
@nogc nothrow pure @safe unittest
{
static struct DisabledOpEquals
{
@disable bool opEquals(typeof(this)) @nogc nothrow pure @safe;
int opCmp(typeof(this)) @nogc nothrow pure @safe
{
return 0;
}
}
static assert(!isEqualityComparable!DisabledOpEquals);
static assert(isOrderingComparable!DisabledOpEquals);
static struct OpEquals
{
bool opEquals(typeof(this)) @nogc nothrow pure @safe
{
return true;
}
}
static assert(isEqualityComparable!OpEquals);
static assert(!isOrderingComparable!OpEquals);
}

262
source/tanya/meta/transform.d
View File

@ -18,6 +18,7 @@
*/
module tanya.meta.transform;
import tanya.meta.metafunction;
import tanya.meta.trait;
/**
@ -717,3 +718,264 @@ if (isExpressions!T || __traits(isTemplate, T))
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)));
}

21
source/tanya/net/inet.d
View File

@ -14,7 +14,6 @@
*/
module tanya.net.inet;
import std.math;
import tanya.meta.trait;
import tanya.meta.transform;
import tanya.range.primitive;
@ -31,7 +30,7 @@ import tanya.range.primitive;
* L = Desired range length.
*/
struct NetworkOrder(uint L)
if (L > ubyte.sizeof && L <= ulong.sizeof)
if (L > ubyte.sizeof && L <= ulong.sizeof)
{
static if (L > uint.sizeof)
{
@ -53,7 +52,7 @@ struct NetworkOrder(uint L)
private StorageType value;
private size_t size = L;
const pure nothrow @safe @nogc invariant
invariant
{
assert(this.size <= L);
}
@ -69,13 +68,13 @@ struct NetworkOrder(uint L)
* T = Value type.
* value = The value should be represented by this range.
*
* Precondition: $(D_INLINECODE value <= 2 ^^ (length * 8) - 1).
* Precondition: $(D_INLINECODE value <= (2 ^^ (L * 8)) - 1).
*/
this(T)(const T value)
if (isUnsigned!T)
this(T)(T value)
if (isUnsigned!T)
in
{
assert(value <= pow(2, L * 8) - 1);
assert(value <= (2 ^^ (L * 8)) - 1);
}
do
{
@ -216,10 +215,10 @@ struct NetworkOrder(uint L)
* order.
*/
T toHostOrder(T = size_t, R)(R range)
if (isInputRange!R
&& !isInfinite!R
&& is(Unqual!(ElementType!R) == ubyte)
&& isUnsigned!T)
if (isInputRange!R
&& !isInfinite!R
&& is(Unqual!(ElementType!R) == ubyte)
&& isUnsigned!T)
{
T ret;
ushort pos = T.sizeof * 8;

36
source/tanya/net/uri.d
View File

@ -14,6 +14,7 @@
*/
module tanya.net.uri;
import tanya.conv;
import tanya.encoding.ascii;
import tanya.memory;
@ -37,7 +38,7 @@ final class URIException : Exception
this(string msg,
string file = __FILE__,
size_t line = __LINE__,
Throwable next = null) @nogc @safe pure nothrow
Throwable next = null) @nogc nothrow pure @safe
{
super(msg, file, line, next);
}
@ -82,7 +83,7 @@ struct URL
*
* Throws: $(D_PSYMBOL URIException) if the URL is malformed.
*/
this(const char[] source) pure @nogc
this(const char[] source) @nogc pure
{
ptrdiff_t pos = -1, endPos = source.length, start;
@ -152,16 +153,13 @@ struct URL
goto ParsePath;
}
}
else
else if (!parsePort(source[pos .. $]))
{
// Schemas like mailto: and zlib: may not have any slash after
// them.
if (!parsePort(source[pos .. $]))
{
this.scheme = source[0 .. pos];
start = pos + 1;
goto ParsePath;
}
this.scheme = source[0 .. pos];
start = pos + 1;
goto ParsePath;
}
}
else if (pos == 0 && parsePort(source[pos .. $]))
@ -305,23 +303,13 @@ struct URL
*
* Returns: Whether the port could be found.
*/
private bool parsePort(const char[] port) pure nothrow @safe @nogc
private bool parsePort(const(char)[] port) @nogc nothrow pure @safe
{
ptrdiff_t i = 1;
float lPort = 0;
for (; i < port.length && port[i].isDigit() && i <= 6; ++i)
auto unparsed = port[1 .. $];
auto parsed = readIntegral!ushort(unparsed);
if (unparsed.length == 0 || unparsed[0] == '/')
{
lPort += (port[i] - '0') / cast(float) (10 ^^ (i - 1));
}
if (i != 1 && (i == port.length || port[i] == '/'))
{
lPort *= 10 ^^ (i - 2);
if (lPort > ushort.max)
{
return false;
}
this.port = cast(ushort) lPort;
this.port = parsed;
return true;
}
return false;

2
source/tanya/network/package.d
View File

@ -5,7 +5,7 @@
/**
* Network programming.
*
* Copyright: Eugene Wissner 2016-2017.
* 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)

65
source/tanya/network/socket.d
View File

@ -5,7 +5,43 @@
/**
* Low-level socket programming.
*
* Copyright: Eugene Wissner 2016-2017.
* Current API supports only server-side TCP communication.
*
* Here is an example of a cross-platform blocking server:
*
* ---
* import std.stdio;
* import tanya.memory;
* import tanya.network;
*
* void main()
* {
* auto socket = defaultAllocator.make!StreamSocket(AddressFamily.inet);
* auto address = defaultAllocator.make!InternetAddress("127.0.0.1",
* cast(ushort) 8192);
*
* socket.setOption(SocketOptionLevel.SOCKET, SocketOption.REUSEADDR, true);
* socket.blocking = true;
* socket.bind(address);
* socket.listen(5);
*
* auto client = socket.accept();
* client.send(cast(const(ubyte)[]) "Test\n");
*
* ubyte[100] buf;
* auto response = client.receive(buf[]);
*
* writeln(cast(const(char)[]) buf[0 .. response]);
*
* defaultAllocator.dispose(client);
* defaultAllocator.dispose(socket);
* }
* ---
*
* For an example of an asynchronous server refer to the documentation of the
* $(D_PSYMBOL tanya.async.loop) module.
*
* 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)
@ -16,11 +52,12 @@ module tanya.network.socket;
import core.stdc.errno;
import core.time;
import std.algorithm.comparison;
public import std.socket : SocketOption, SocketOptionLevel;
import std.traits;
import std.typecons;
import tanya.algorithm.comparison;
import tanya.memory;
import tanya.os.error;
/// Value returned by socket operations on error.
enum int socketError = -1;
@ -44,10 +81,8 @@ version (Posix)
}
else version (Windows)
{
import core.sys.windows.winbase : ERROR_IO_INCOMPLETE,
ERROR_IO_PENDING,
GetModuleHandle,
GetProcAddress;
import core.sys.windows.winbase;
import core.sys.windows.winerror;
import core.sys.windows.winsock2 : accept,
addrinfo,
bind,
@ -68,6 +103,7 @@ else version (Windows)
send,
setsockopt,
shutdown,
SO_TYPE,
SOCKADDR,
sockaddr,
sockaddr_in,
@ -76,7 +112,6 @@ else version (Windows)
socket,
socklen_t,
SOL_SOCKET,
SO_TYPE,
WSAGetLastError;
import tanya.async.iocp;
import tanya.sys.windows.def;
@ -581,9 +616,7 @@ enum AddressFamily : int
inet6 = 10, /// IP version 6.
}
/**
* Error codes for $(D_PSYMBOL Socket).
*/
deprecated("Use tanya.os.error.ErrorCode.ErrorNo instead")
enum SocketError : int
{
/// Unknown error.
@ -621,7 +654,7 @@ enum SocketError : int
*/
class SocketException : Exception
{
const SocketError error = SocketError.unknown;
const ErrorCode.ErrorNo error = ErrorCode.ErrorNo.success;
/**
* Params:
@ -637,7 +670,7 @@ class SocketException : Exception
{
super(msg, file, line, next);
foreach (member; EnumMembers!SocketError)
foreach (member; EnumMembers!(ErrorCode.ErrorNo))
{
if (member == lastError)
{
@ -647,24 +680,24 @@ class SocketException : Exception
}
if (lastError == ENOMEM)
{
error = SocketError.noBufferSpaceAvailable;
error = ErrorCode.ErrorNo.noBufferSpace;
}
else if (lastError == EMFILE)
{
error = SocketError.tooManyOpenSockets;
error = ErrorCode.ErrorNo.tooManyDescriptors;
}
else version (linux)
{
if (lastError == ENOSR)
{
error = SocketError.networkDown;
error = ErrorCode.ErrorNo.networkDown;
}
}
else version (Posix)
{
if (lastError == EPROTO)
{
error = SocketError.networkDown;
error = ErrorCode.ErrorNo.networkDown;
}
}
}

2
source/tanya/os/package.d
View File

@ -6,7 +6,7 @@
* This package provides platform-independent interfaces to operating system
* functionality.
*
* Copyright: Eugene Wissner 2017.
* 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)

375
source/tanya/range/adapter.d Normal file
View File

@ -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);
}

1
source/tanya/range/package.d
View File

@ -15,5 +15,6 @@
*/
module tanya.range;
public import tanya.range.adapter;
public import tanya.range.array;
public import tanya.range.primitive;

47
source/tanya/sys/linux/syscall.d Normal file
View File

@ -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;

31
source/tanya/sys/posix/mman.d Normal file
View File

@ -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.
}

4
source/tanya/sys/windows/def.d
View File

@ -16,7 +16,7 @@
* defined here.
* Also aliases for specific types like $(D_PSYMBOL SOCKET) are defined here.
*
* Copyright: Eugene Wissner 2017.
* 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)
@ -58,4 +58,4 @@ align(1) struct GUID
ushort Data2;
ushort Data3;
char[8] Data4;
}
}

7
source/tanya/sys/windows/error.d
View File

@ -3,13 +3,14 @@
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
/**
* Copyright: Eugene Wissner 2017.
* 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/error.d,
* tanya/sys/windows/error.d)
*/
deprecated("Use core.sys.windows.winerror instead")
module tanya.sys.windows.error;
version (Windows):
@ -77,7 +78,7 @@ enum
WSA_E_NO_MORE = WSABASEERR + 110,
WSA_E_CANCELLED = WSABASEERR + 111,
WSAEREFUSED = WSABASEERR + 112,
WSAHOST_NOT_FOUND = WSABASEERR + 1001,
WSATRY_AGAIN = WSABASEERR + 1002,
WSANO_RECOVERY = WSABASEERR + 1003,
@ -111,4 +112,4 @@ enum
WSA_QOS_ESDMODEOBJ = WSABASEERR + 1029,
WSA_QOS_ESHAPERATEOBJ = WSABASEERR + 1030,
WSA_QOS_RESERVED_PETYPE = WSABASEERR + 1031,
}
}

4
source/tanya/sys/windows/package.d
View File

@ -3,7 +3,7 @@
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
/**
* Copyright: Eugene Wissner 2017.
* 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)
@ -17,4 +17,4 @@ version (Windows):
public import tanya.sys.windows.def;
public import tanya.sys.windows.error;
public import tanya.sys.windows.winbase;
public import tanya.sys.windows.winsock2;
public import tanya.sys.windows.winsock2;

4
source/tanya/sys/windows/winbase.d
View File

@ -5,7 +5,7 @@
/**
* Definitions from winbase.h.
*
* Copyright: Eugene Wissner 2017.
* 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)
@ -52,4 +52,4 @@ extern(Windows)
BOOL GetOverlappedResult(HANDLE hFile,
OVERLAPPED* lpOverlapped,
DWORD* lpNumberOfBytesTransferred,
BOOL bWait) nothrow @system @nogc;
BOOL bWait) nothrow @system @nogc;

4
source/tanya/sys/windows/winsock2.d
View File

@ -5,7 +5,7 @@
/**
* Definitions from winsock2.h, ws2def.h and MSWSock.h.
*
* Copyright: Eugene Wissner 2017.
* 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)
@ -216,4 +216,4 @@ enum
SO_UPDATE_ACCEPT_CONTEXT = 0x700B,
SO_CONNECT_TIME = 0x700C,
SO_UPDATE_CONNECT_CONTEXT = 0x7010,
}
}

2
source/tanya/test/assertion.d
View File

@ -13,7 +13,7 @@
* The functions can cause segmentation fault if the module is compiled
* in production mode and the condition fails.
*
* Copyright: Eugene Wissner 2017.
* 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)

2
source/tanya/test/package.d
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@ -5,7 +5,7 @@
/**
* Test suite for $(D_KEYWORD unittest)-blocks.
*
* Copyright: Eugene Wissner 2017.
* 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)

128
source/tanya/typecons.d
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@ -17,23 +17,10 @@
*/
module tanya.typecons;
import tanya.meta.metafunction;
import tanya.format;
import tanya.meta.metafunction : AliasSeq, AliasTuple = Tuple, Map;
/**
* $(D_PSYMBOL Pair) can store two heterogeneous objects.
*
* The objects can by accessed by index as $(D_INLINECODE obj[0]) and
* $(D_INLINECODE obj[1]) or by optional names (e.g.
* $(D_INLINECODE 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.
*/
deprecated("Use tanya.typecons.Tuple instead")
template Pair(Specs...)
{
template parseSpecs(size_t fieldCount, Specs...)
@ -47,13 +34,13 @@ template Pair(Specs...)
static if (is(typeof(Specs[1]) == string))
{
alias parseSpecs
= AliasSeq!(Tuple!(Specs[0], Specs[1]),
= AliasSeq!(AliasTuple!(Specs[0], Specs[1]),
parseSpecs!(fieldCount + 1, Specs[2 .. $]));
}
else
{
alias parseSpecs
= AliasSeq!(Tuple!(Specs[0]),
= AliasSeq!(AliasTuple!(Specs[0]),
parseSpecs!(fieldCount + 1, Specs[1 .. $]));
}
}
@ -90,10 +77,92 @@ template Pair(Specs...)
}
}
/**
* $(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 = Pair!(int, "first", string, "second")(1, "second");
auto pair = Tuple!(int, "first", string, "second")(1, "second");
assert(pair.first == 1);
assert(pair[0] == 1);
assert(pair.second == "second");
@ -102,16 +171,19 @@ template Pair(Specs...)
@nogc nothrow pure @safe unittest
{
static assert(is(Pair!(int, int)));
static assert(!is(Pair!(int, 5)));
static assert(is(Tuple!(int, int)));
static assert(!is(Tuple!(int, 5)));
static assert(is(Pair!(int, "first", int)));
static assert(is(Pair!(int, "first", int, "second")));
static assert(is(Pair!(int, "first", int)));
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(Pair!(int, int, "second")));
static assert(!is(Pair!("first", int, "second", int)));
static assert(!is(Pair!(int, int, 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(Pair!(int, "first")));
static assert(!is(Tuple!(int, "first")));
static assert(!is(Tuple!(int, double, char)));
static assert(!is(Tuple!(int, "first", double, "second", char, "third")));
}