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22 Commits
v0.7.3 ... v0.7.4

Author SHA1 Message Date
Eugen Wissner
a576c36d02 Replace memcpy/memmove with copy/copyBackward 2017-09-30 08:15:02 +02:00
Eugen Wissner
1056a2984e Fix #303 
Allocation schema is displayed incorrectly in HTML.
Add pre-tag for the schema.
 2017-09-27 17:56:15 +02:00
Eugen Wissner
faebf3e4d5 Fix #304 
Replace inline assembly with GAS.
 2017-09-26 08:26:12 +02:00
Eugen Wissner
20e7df386b Ignore dub_platform_probe- files 2017-09-25 07:51:03 +02:00
Eugen Wissner
15d9cda755 Add info about supporting GDC 2017-09-24 18:08:47 +02:00
Eugen Wissner
ee48c25328 Replace "Ditto." with "ditto" 
ddox doesn't recognize "Ditto.".
 2017-09-22 04:08:50 +02:00
Eugen Wissner
4612d5eb6d Add tanya.encoding.ascii 2017-09-21 06:57:49 +02:00
Eugen Wissner
8d3a4860e6 Add memory.op.find for looking for a byte in a memory block 2017-09-20 08:31:54 +02:00
Eugene Wissner
3df6c83376 Move formatting development to the io branch 2017-09-19 15:10:24 +02:00
Eugen Wissner
7445d42ad4 Add thrd_current for x86-64 linux 2017-09-19 06:16:43 +02:00
Eugen Wissner
14f91b6942 Don't import math submodules publically 2017-09-18 12:28:13 +02:00
Eugen Wissner
be551e9349 Add docs and tests for fp classificators 2017-09-18 11:31:37 +02:00
Eugen Wissner
586d12b6c7 Classificators for double extended floating point numbers 2017-09-17 10:30:12 +02:00
Eugen Wissner
27146f7e0c Add tanya.math.fp 2017-09-16 22:35:31 +02:00
Eugene Wissner
9b54017840 Move all windows specific definitions from network.socket to the sys-package 2017-09-15 10:58:23 +02:00
Eugene Wissner
aabb6334be Import extern windows fill/copy memory functions 2017-09-14 18:49:13 +02:00
Eugene Wissner
ce425b9ce5 Move simple socket definitions to sys.windows 2017-09-14 07:31:26 +02:00
Eugen Wissner
3e9ca359da math: Add floating point support to abs 2017-09-13 06:43:49 +02:00
Eugen Wissner
3705cf387e Add syscalls to x86-64 linux 2017-09-12 06:23:28 +02:00
Eugen Wissner
edc3296083 Drop support for dmd 2.073.2, remove deprecations 2017-09-12 06:07:16 +02:00
Eugen Wissner
e8143bd0cc Fix template constraints style in tanya.math 2017-09-11 06:48:47 +02:00
Eugen Wissner
3eb8618c32 Add range.primitive 2017-09-10 10:35:05 +02:00
48 changed files with 3487 additions and 2932 deletions
Expand all files Collapse all files

4
.gitignore vendored
View File

@ -7,8 +7,12 @@
__test__*__
__test__*__.core
/tanya-test-*
/dub_platform_probe-*
/docs/
/docs.json
/*.lst
# Ninja build
.ninja_*

1
.travis.yml
View File

@ -10,7 +10,6 @@ d:
- dmd-2.076.0
- dmd-2.075.1
- dmd-2.074.1
- dmd-2.073.2
env:
matrix:

12
README.md
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@ -27,6 +27,7 @@ Tanya consists of the following packages and (top-level) modules:
* `async`: Event loop (epoll, kqueue and IOCP).
* `container`: Queue, Array, Singly and doubly linked lists, Buffers, UTF-8
string, Hash set.
* `encoding`: This package provides tools to work with text encodings.
* `format`: Formatting and conversion functions.
* `math`: Arbitrary precision integer and a set of functions.
* `memory`: Tools for manual memory management (allocators, smart pointers).
@ -142,12 +143,11 @@ There are more containers in the `tanya.container` package.
### Supported compilers
| dmd |
|:-------:|
| 2.076.0 |
| 2.075.1 |
| 2.074.1 |
| 2.073.2 |
| DMD | GCC |
|:-------:|:--------------:|
| 2.076.0 | *gdc-5* branch |
| 2.075.1 | |
| 2.074.1 | |
### Current status

6
appveyor.yml
View File

@ -21,12 +21,6 @@ environment:
- DC: dmd
DVersion: 2.074.1
arch: x86
- DC: dmd
DVersion: 2.073.2
arch: x64
- DC: dmd
DVersion: 2.073.2
arch: x86
skip_tags: true

13
arch/build.ninja Normal file
View File

@ -0,0 +1,13 @@
rule gas
command = gcc -c $in -o $out
rule archive
command = ar rcs $out $in
build abs.o: gas x64/linux/math/abs.S
build cmp.o: gas x64/linux/memory/cmp.S
build fill.o: gas x64/linux/memory/fill.S
build copy.o: gas x64/linux/memory/copy.S
build syscall.o: gas x64/linux/syscall.S
build tanya.a: archive syscall.o copy.o fill.o cmp.o abs.o

8
arch/x64/linux/concurrency/thread.S Normal file
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@ -0,0 +1,8 @@
.text
.globl thrd_current
.type thrd_current, @function
thrd_current:
mov %fs:0, %rax
ret

35
arch/x64/linux/math/abs.S Normal file
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@ -0,0 +1,35 @@
.text
// fabsf.
.globl _D5tanya4math8nbtheory10__T3absTfZ3absFNaNbNiNffZf
.type _D5tanya4math8nbtheory10__T3absTfZ3absFNaNbNiNffZf, @function
_D5tanya4math8nbtheory10__T3absTfZ3absFNaNbNiNffZf:
mov $0x7fffffff, %eax
movq %rax, %xmm1
andpd %xmm1, %xmm0
ret
// fabs.
.globl _D5tanya4math8nbtheory10__T3absTdZ3absFNaNbNiNfdZd
.type _D5tanya4math8nbtheory10__T3absTdZ3absFNaNbNiNfdZd, @function
_D5tanya4math8nbtheory10__T3absTdZ3absFNaNbNiNfdZd:
mov $0x7fffffffffffffff, %rax
movq %rax, %xmm1
andpd %xmm1, %xmm0
ret
// fabsl.
.globl _D5tanya4math8nbtheory10__T3absTeZ3absFNaNbNiNfeZe
.type _D5tanya4math8nbtheory10__T3absTeZ3absFNaNbNiNfeZe, @function
// Load the parameter from the stack onto FP stack, execute 'fabs' instruction
// The result is returned in ST0.
_D5tanya4math8nbtheory10__T3absTeZ3absFNaNbNiNfeZe:
fldt 0x8(%rsp)
fabs
ret

67
arch/x64/linux/memory/cmp.S Normal file
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@ -0,0 +1,67 @@
.text
/*
* cmpMemory.
*
* rdi - r1 length
* rsi - r1 data.
* rdx - r2 length.
* rcx - r2 data.
*/
.globl _D5tanya6memory2op9cmpMemoryFNaNbNixAvxAvZi
.type _D5tanya6memory2op9cmpMemoryFNaNbNixAvxAvZi, @function
_D5tanya6memory2op9cmpMemoryFNaNbNixAvxAvZi:
// Compare the lengths
cmp %rdx, %rdi
jl less
jg greater
mov %rcx, %rdi
// Check if we're aligned
cmp $0x08, %rdx
jc aligned_1
test $0x07, %edi
jz aligned_8
naligned:
cmpsb
jl less
jg greater
dec %rdx
test $0x07, %edi
jnz naligned
aligned_8:
mov %rdx, %rcx
shr $0x03, %rcx
repe cmpsq
jl less
jg greater
and $0x07, %edx
jz equal
aligned_1: // Compare the remaining bytes
mov %rdx, %rcx
repe cmpsb
jl less
jg greater
equal:
xor %rax, %rax // Return 0
jmp end
greater:
mov $0x01, %rax
jmp end
less:
mov $-0x01, %rax
end:
ret

67
arch/x64/linux/memory/copy.S Normal file
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@ -0,0 +1,67 @@
.text
/*
* copyMemory.
*
* rdi - source length
* rsi - source data.
* rdx - target length.
* rcx - target data.
*/
.globl _D5tanya6memory2op10copyMemoryFNaNbNixAvAvZv
.type _D5tanya6memory2op10copyMemoryFNaNbNixAvAvZv, @function
_D5tanya6memory2op10copyMemoryFNaNbNixAvAvZv:
mov %rdi, %rdx
mov %rcx, %rdi
cmp $0x08, %rdx
jc aligned_1
test $0x07, %edi
jz aligned_8
naligned:
movsb
dec %rdx
test $0x07, %edi
jnz naligned
aligned_8:
mov %rdx, %rcx
shr $0x03, %rcx
rep movsq
and $0x07, %edx
jz end
aligned_1:
// Write the remaining bytes
mov %rdx, %rcx
rep movsb
end:
ret
/*
* moveMemory.
*
* rdi - source length
* rsi - source data.
* rdx - target length.
* rcx - target data.
*/
.globl _D5tanya6memory2op10moveMemoryFNaNbNixAvAvZv
.type _D5tanya6memory2op10moveMemoryFNaNbNixAvAvZv, @function
_D5tanya6memory2op10moveMemoryFNaNbNixAvAvZv:
mov %rdi, %rdx
lea -1(%rdx, %rsi), %rsi
lea -1(%rdx, %rcx), %rdi
mov %rdx, %rcx
std // Set the direction flag
rep movsb
cld // Clear the direction flag
ret

155
arch/x64/linux/memory/fill.S Normal file
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@ -0,0 +1,155 @@
.text
/*
* fillMemory.
*
* rdi - length.
* rsi - pointer.
* rdx - value filled with a byte.
*/
.globl _D5tanya6memory2op10fillMemoryFNaNbNiAvmZv
.type _D5tanya6memory2op10fillMemoryFNaNbNiAvmZv, @function
_D5tanya6memory2op10fillMemoryFNaNbNiAvmZv:
// Check for zero length
test %rdi, %rdi
jz end
mov %rdi, %rax
mov %rsi, %r8
movq %rdx, %xmm0
movlhps %xmm0, %xmm0
// Check if the pointer is aligned to a 16-byte boundary
and $-0x10, %r8
// Compute the number of misaligned bytes
mov %rsi, %r9
sub %r8, %r9
test %r9, %r9
jz aligned
// Get the number of bytes to be written until we are aligned
mov $0x10, %rcx
sub %r9, %rcx
mov %rsi, %r8
naligned:
mov %dl, (%r8) // Write a byte
// Advance the pointer. Decrease the total number of bytes
// and the misaligned ones
inc %r8
dec %rcx
dec %rax
// Checks if we are aligned
test %rcx, %rcx
jnz naligned
aligned:
// Checks if we're done writing bytes
test %rax, %rax
jz end
// Write 1 byte at a time
cmp $8, %rax
jl aligned_1
// Write 8 bytes at a time
cmp $16, %rax
jl aligned_8
// Write 16 bytes at a time
cmp $32, %rax
jl aligned_16
// Write 32 bytes at a time
cmp $64, %rax
jl aligned_32
aligned_64:
movdqa %xmm0, (%r8)
movdqa %xmm0, 16(%r8)
movdqa %xmm0, 32(%r8)
movdqa %xmm0, 48(%r8)
add $64, %r8
sub $64, %rax
cmp $64, %rax
jge aligned_64
// Checks if we're done writing bytes
test %rax, %rax
jz end
// Write 1 byte at a time
cmp $8, %rax
jl aligned_1
// Write 8 bytes at a time
cmp $16, %rax
jl aligned_8
// Write 16 bytes at a time
cmp $32, %rax
jl aligned_16
aligned_32:
movdqa %xmm0, (%r8)
movdqa %xmm0, 16(%r8)
add $32, %r8
sub $32, %rax
// Checks if we're done writing bytes
test %rax, %rax
jz end
// Write 1 byte at a time
cmp $8, %rax
jl aligned_1
// Write 8 bytes at a time
cmp $16, %rax
jl aligned_8
aligned_16:
movdqa %xmm0, (%r8)
add $16, %r8
sub $16, %rax
// Checks if we're done writing bytes
test %rax, %rax
jz end
// Write 1 byte at a time
cmp $8, %rax
jl aligned_1
aligned_8:
mov %rdx, (%r8)
add $8, %r8
sub $8, %rax
// Checks if we're done writing bytes
test %rax, %rax
jz end
aligned_1:
mov %dl, (%r8)
inc %r8
dec %rax
test %rax, %rax
jnz aligned_1
end:
ret

65
arch/x64/linux/syscall.S Normal file
View File

@ -0,0 +1,65 @@
/*
The kernel uses the following registers:
%rdi, %rsi, %rdx, %r8, %r9, %r10
The number of the syscall is passed in %rax.
A syscall clobbers:
%rax, %rcx, %r11
The returned value is placed in %rax.
*/
.text
.globl syscall1
.type syscall1, @function
syscall1:
movq %rsi, %rax // Syscall number.
syscall
ret
.globl syscall2
.type syscall2, @function
syscall2:
// Store registers.
movq %rdi, %r8
movq %rdx, %rax // Syscall number.
// Syscall arguments.
movq %rsi, %rdi
movq %r8, %rsi
syscall
// Restore registers.
movq %rdi, %rsi
movq %r8, %rdi
ret
.globl syscall3
.type syscall3, @function
syscall3:
// Store registers.
movq %rdi, %r8
movq %rcx, %rax // Syscall number.
// Syscall arguments.
movq %rdx, %rdi
movq %r8, %rdx
syscall
// Restore registers.
movq %r8, %rdi
ret

5
dub.json
View File

@ -18,7 +18,10 @@
{
"name": "native",
"targetType": "library",
"platforms": ["linux-x86_64"]
"platforms": ["linux-x86_64-gdc"],
"preBuildCommands": ["ninja -C arch"],
"lflags": ["arch/tanya.a"],
"versions": ["TanyaNative"]
}
]
}

16
source/tanya/async/event/iocp.d
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@ -27,10 +27,8 @@ import tanya.async.watcher;
import tanya.memory;
import tanya.memory.mmappool;
import tanya.network.socket;
import core.sys.windows.basetyps;
import tanya.sys.windows.winbase;
import core.sys.windows.mswsock;
import core.sys.windows.winbase;
import core.sys.windows.windef;
import core.sys.windows.winsock2;
/**
@ -185,7 +183,7 @@ final class IOCPLoop : Loop
{
super();
completionPort = CreateIoCompletionPort(INVALID_HANDLE_VALUE, NULL, 0, 0);
completionPort = CreateIoCompletionPort(INVALID_HANDLE_VALUE, null, 0, 0);
if (!completionPort)
{
throw make!BadLoopException(defaultAllocator,
@ -215,7 +213,7 @@ final class IOCPLoop : Loop
if (CreateIoCompletionPort(cast(HANDLE) socket.handle,
completionPort,
cast(ULONG_PTR) (cast(void*) watcher),
cast(size_t) (cast(void*) watcher),
0) !is completionPort)
{
return false;
@ -241,7 +239,7 @@ final class IOCPLoop : Loop
if (CreateIoCompletionPort(cast(HANDLE) transport.socket.handle,
completionPort,
cast(ULONG_PTR) (cast(void*) watcher),
cast(size_t) (cast(void*) watcher),
0) !is completionPort)
{
return false;
@ -286,8 +284,8 @@ final class IOCPLoop : Loop
override protected void poll() @nogc
{
DWORD lpNumberOfBytes;
ULONG_PTR key;
LPOVERLAPPED overlap;
size_t key;
OVERLAPPED* overlap;
immutable timeout = cast(immutable int) blockTime.total!"msecs";
auto result = GetQueuedCompletionStatus(completionPort,
@ -295,7 +293,7 @@ final class IOCPLoop : Loop
&key,
&overlap,
timeout);
if (result == FALSE && overlap == NULL)
if (result == FALSE && overlap is null)
{
return; // Timeout
}

3
source/tanya/async/iocp.d
View File

@ -37,8 +37,7 @@ else version (D_Ddoc)
version (WindowsDoc):
import core.sys.windows.winbase;
import core.sys.windows.windef;
import tanya.sys.windows.winbase;
/**
* Provides an extendable representation of a Win32 $(D_PSYMBOL OVERLAPPED)

48
source/tanya/container/array.d
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@ -19,11 +19,11 @@ import core.exception;
import std.algorithm.comparison;
import std.algorithm.mutation;
import std.conv;
import std.range.primitives;
import std.meta;
import tanya.memory;
import tanya.meta.trait;
import tanya.meta.transform;
import tanya.range.primitive;
/**
* Random-access range for the $(D_PSYMBOL Array).
@ -177,7 +177,7 @@ struct Array(T)
/// The range types for $(D_PSYMBOL Array).
alias Range = .Range!Array;
/// Ditto.
/// ditto
alias ConstRange = .Range!(const Array);
private size_t length_;
@ -245,7 +245,7 @@ struct Array(T)
insertBack(init[]);
}
/// Ditto.
/// ditto
this(R)(R init, shared Allocator allocator = defaultAllocator) @trusted
if (is(R == Array))
{
@ -313,14 +313,14 @@ struct Array(T)
length_ = len;
}
/// Ditto.
/// ditto
this(const size_t len, shared Allocator allocator = defaultAllocator)
{
this(allocator);
length = len;
}
/// Ditto.
/// ditto
this(shared Allocator allocator)
in
{
@ -416,7 +416,7 @@ struct Array(T)
return length_;
}
/// Ditto.
/// ditto
size_t opDollar() const
{
return length;
@ -704,7 +704,7 @@ struct Array(T)
return 1;
}
/// Ditto.
/// ditto
size_t insertBack(R)(ref R el) @trusted
if (isImplicitlyConvertible!(R, T))
{
@ -714,7 +714,7 @@ struct Array(T)
return 1;
}
/// Ditto.
/// ditto
size_t insertBack(R)(R el)
if (!isInfinite!R
&& isInputRange!R
@ -732,13 +732,13 @@ struct Array(T)
return retLength;
}
/// Ditto.
/// ditto
size_t insertBack(size_t R)(T[R] el)
{
return insertBack!(T[])(el[]);
}
/// Ditto.
/// ditto
alias insert = insertBack;
///
@ -813,7 +813,7 @@ struct Array(T)
return inserted;
}
/// Ditto.
/// ditto
size_t insertAfter(size_t R)(Range r, T[R] el)
in
{
@ -826,7 +826,7 @@ struct Array(T)
return insertAfter!(T[])(r, el[]);
}
/// Ditto.
/// ditto
size_t insertAfter(R)(Range r, auto ref R el)
if (isImplicitlyConvertible!(R, T))
in
@ -853,7 +853,7 @@ struct Array(T)
return 1;
}
/// Ditto.
/// ditto
size_t insertBefore(R)(Range r, R el)
if (!isInfinite!R
&& isInputRange!R
@ -869,7 +869,7 @@ struct Array(T)
return insertAfter(Range(this, this.data, r.begin), el);
}
/// Ditto.
/// ditto
size_t insertBefore(size_t R)(Range r, T[R] el)
in
{
@ -882,7 +882,7 @@ struct Array(T)
return insertBefore!(T[])(r, el[]);
}
/// Ditto.
/// ditto
size_t insertBefore(R)(Range r, auto ref R el)
if (isImplicitlyConvertible!(R, T))
in
@ -998,7 +998,7 @@ struct Array(T)
return opIndex(pos) = value;
}
/// Ditto.
/// ditto
Range opIndexAssign(E : T)(auto ref E value)
{
return opSliceAssign(value, 0, length);
@ -1028,7 +1028,7 @@ struct Array(T)
return opSliceAssign!R(value, 0, length);
}
/// Ditto.
/// ditto
Range opIndexAssign(Range value)
{
return opSliceAssign(value, 0, length);
@ -1077,7 +1077,7 @@ struct Array(T)
return typeof(return)(this, this.data, this.data + length);
}
/// Ditto.
/// ditto
ConstRange opIndex() const @trusted
{
return typeof(return)(this, this.data, this.data + length);
@ -1110,13 +1110,13 @@ struct Array(T)
return equal(this.data[0 .. length], that.data[0 .. that.length]);
}
/// Ditto.
/// ditto
bool opEquals()(auto ref const typeof(this) that) const @trusted
{
return equal(this.data[0 .. length], that.data[0 .. that.length]);
}
/// Ditto.
/// ditto
bool opEquals(Range that)
{
return equal(opIndex(), that);
@ -1233,7 +1233,7 @@ struct Array(T)
return typeof(return)(this, this.data + i, this.data + j);
}
/// Ditto.
/// ditto
ConstRange opSlice(const size_t i, const size_t j) const @trusted
in
{
@ -1317,7 +1317,7 @@ struct Array(T)
return opSlice(i, j);
}
/// Ditto.
/// ditto
Range opSliceAssign(R : T)(auto ref R value, const size_t i, const size_t j)
@trusted
in
@ -1331,7 +1331,7 @@ struct Array(T)
return opSlice(i, j);
}
/// Ditto.
/// ditto
Range opSliceAssign(Range value, const size_t i, const size_t j) @trusted
in
{
@ -1416,7 +1416,7 @@ struct Array(T)
return this = that[];
}
/// Ditto.
/// ditto
ref typeof(this) opAssign(R)(R that) @trusted
if (is(R == Array))
{

6
source/tanya/container/buffer.d
View File

@ -100,7 +100,7 @@ struct ReadBuffer(T = ubyte)
buffer_ = cast(T[]) allocator_.allocate(size * T.sizeof);
}
/// Ditto.
/// ditto
this(shared Allocator allocator)
in
{
@ -143,7 +143,7 @@ struct ReadBuffer(T = ubyte)
return length_ - start;
}
/// Ditto.
/// ditto
alias opDollar = length;
/**
@ -395,7 +395,7 @@ struct WriteBuffer(T = ubyte)
}
}
/// Ditto.
/// ditto
alias opDollar = length;
///

65
source/tanya/container/list.d
View File

@ -17,10 +17,11 @@ module tanya.container.list;
import std.algorithm.comparison;
import std.algorithm.mutation;
import std.algorithm.searching;
import std.range.primitives;
import tanya.container.entry;
import tanya.memory;
import tanya.meta.trait;
import tanya.range.array;
import tanya.range.primitive;
/**
* Forward range for the $(D_PSYMBOL SList).
@ -99,7 +100,7 @@ struct SList(T)
/// The range types for $(D_PSYMBOL SList).
alias Range = SRange!SList;
/// Ditto.
/// ditto
alias ConstRange = SRange!(const SList);
private alias Entry = SEntry!T;
@ -183,7 +184,7 @@ struct SList(T)
assert(l.empty);
}
/// Ditto.
/// ditto
this(const size_t len, shared Allocator allocator = defaultAllocator)
{
this(len, T.init, allocator);
@ -197,7 +198,7 @@ struct SList(T)
assert(l.front == 0);
}
/// Ditto.
/// ditto
this(shared Allocator allocator)
in
{
@ -231,7 +232,7 @@ struct SList(T)
this(init[], allocator);
}
/// Ditto.
/// ditto
this(R)(R init, shared Allocator allocator = defaultAllocator) @trusted
if (is(R == SList))
{
@ -355,7 +356,7 @@ struct SList(T)
return moveEntry(this.head, el);
}
/// Ditto.
/// ditto
size_t insertFront(R)(ref R el) @trusted
if (isImplicitlyConvertible!(R, T))
{
@ -377,7 +378,7 @@ struct SList(T)
assert(l.front == 8);
}
/// Ditto.
/// ditto
size_t insertFront(R)(R el) @trusted
if (!isInfinite!R
&& isInputRange!R
@ -407,13 +408,13 @@ struct SList(T)
return retLength;
}
/// Ditto.
/// ditto
size_t insertFront(size_t R)(T[R] el)
{
return insertFront!(T[])(el[]);
}
/// Ditto.
/// ditto
alias insert = insertFront;
///
@ -479,7 +480,7 @@ struct SList(T)
assert(l1 == l2);
}
/// Ditto.
/// ditto
size_t insertBefore(R)(Range r, R el)
if (!isInfinite!R
&& isInputRange!R
@ -511,7 +512,7 @@ struct SList(T)
assert(l1 == l2);
}
/// Ditto.
/// ditto
size_t insertBefore(Range r, ref T el) @trusted
in
{
@ -745,7 +746,7 @@ struct SList(T)
return typeof(return)(this.head);
}
/// Ditto.
/// ditto
ConstRange opIndex() const
{
return typeof(return)(this.head);
@ -772,7 +773,7 @@ struct SList(T)
return this = that[];
}
/// Ditto.
/// ditto
ref typeof(this) opAssign(R)(R that)
if (is(R == SList))
{
@ -1018,7 +1019,7 @@ struct DList(T)
/// The range types for $(D_PSYMBOL DList).
alias Range = DRange!DList;
/// Ditto.
/// ditto
alias ConstRange = DRange!(const DList);
private alias Entry = DEntry!T;
@ -1113,7 +1114,7 @@ struct DList(T)
assert(l.empty);
}
/// Ditto.
/// ditto
this(const size_t len, shared Allocator allocator = defaultAllocator)
{
this(len, T.init, allocator);
@ -1127,7 +1128,7 @@ struct DList(T)
assert(l.front == 0);
}
/// Ditto.
/// ditto
this(shared Allocator allocator)
in
{
@ -1161,7 +1162,7 @@ struct DList(T)
this(init[], allocator);
}
/// Ditto.
/// ditto
this(R)(R init, shared Allocator allocator = defaultAllocator) @trusted
if (is(R == DList))
{
@ -1352,7 +1353,7 @@ struct DList(T)
return moveFront(this.head, el);
}
/// Ditto.
/// ditto
size_t insertFront(R)(ref R el) @trusted
if (isImplicitlyConvertible!(R, T))
{
@ -1384,7 +1385,7 @@ struct DList(T)
assert(l.back == 5);
}
/// Ditto.
/// ditto
size_t insertFront(R)(R el)
if (!isInfinite!R
&& isInputRange!R
@ -1412,7 +1413,7 @@ struct DList(T)
assert(l1.head is l1.head.next.prev);
}
/// Ditto.
/// ditto
size_t insertFront(size_t R)(T[R] el)
{
return insertFront!(T[])(el[]);
@ -1478,7 +1479,7 @@ struct DList(T)
return moveBack(this.tail, el);
}
/// Ditto.
/// ditto
size_t insertBack(R)(ref R el) @trusted
if (isImplicitlyConvertible!(R, T))
{
@ -1510,7 +1511,7 @@ struct DList(T)
assert(l.back == value);
}
/// Ditto.
/// ditto
size_t insertBack(R)(R el) @trusted
if (!isInfinite!R
&& isInputRange!R
@ -1535,7 +1536,7 @@ struct DList(T)
return inserted;
}
/// Ditto.
/// ditto
size_t insertBack(size_t R)(T[R] el)
{
return insertBack!(T[])(el[]);
@ -1560,7 +1561,7 @@ struct DList(T)
assert(l2.back == 9);
}
/// Ditto.
/// ditto
alias insert = insertBack;
version (assert)
@ -1607,7 +1608,7 @@ struct DList(T)
assert(l1 == l2);
}
/// Ditto.
/// ditto
size_t insertBefore(Range r, ref T el) @trusted
in
{
@ -1642,7 +1643,7 @@ struct DList(T)
assert(l1 == l2);
}
/// Ditto.
/// ditto
size_t insertBefore(R)(Range r, R el)
if (!isInfinite!R
&& isInputRange!R
@ -1733,7 +1734,7 @@ struct DList(T)
assert(l.length == 1);
}
/// Ditto.
/// ditto
size_t insertAfter(Range r, ref T el) @trusted
in
{
@ -1768,7 +1769,7 @@ struct DList(T)
assert(l1 == l2);
}
/// Ditto.
/// ditto
size_t insertAfter(R)(Range r, R el)
if (!isInfinite!R
&& isInputRange!R
@ -1924,7 +1925,7 @@ struct DList(T)
assert(l.empty);
}
/// Ditto.
/// ditto
void removeBack()
in
{
@ -1997,7 +1998,7 @@ struct DList(T)
assert(l.removeFront(3) == 0);
}
/// Ditto.
/// ditto
size_t removeBack(const size_t howMany)
out (removed)
{
@ -2110,7 +2111,7 @@ struct DList(T)
return typeof(return)(this.head, this.tail);
}
/// Ditto.
/// ditto
ConstRange opIndex() const
{
return typeof(return)(this.head, this.tail);
@ -2137,7 +2138,7 @@ struct DList(T)
return this = that[];
}
/// Ditto.
/// ditto
ref typeof(this) opAssign(R)(R that)
if (is(R == DList))
{

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

@ -115,7 +115,7 @@ struct Queue(T)
enqueueEntry(temp);
}
/// Ditto.
/// ditto
void enqueue(T x)
{
auto temp = allocateEntry();
@ -212,7 +212,7 @@ struct Queue(T)
return result;
}
/// Ditto.
/// ditto
int opApply(scope int delegate(ref T) @nogc dg)
{
int result;

12
source/tanya/container/set.d
View File

@ -156,7 +156,7 @@ struct Set(T)
/// The range types for $(D_PSYMBOL Set).
alias Range = .Range!T;
/// Ditto.
/// ditto
alias ConstRange = .Range!(const T);
invariant
@ -186,7 +186,7 @@ struct Set(T)
rehash(n);
}
/// Ditto.
/// ditto
this(shared Allocator allocator)
in
{
@ -232,7 +232,7 @@ struct Set(T)
this.data = typeof(this.data)(init.data, allocator);
}
/// Ditto.
/// ditto
this(S)(S init, shared Allocator allocator = defaultAllocator)
if (is(S == Set))
in
@ -266,7 +266,7 @@ struct Set(T)
return this;
}
/// Ditto.
/// ditto
ref typeof(this) opAssign(S)(S that) @trusted
if (is(S == Set))
{
@ -614,7 +614,7 @@ struct Set(T)
return typeof(return)(this.data[]);
}
/// Ditto.
/// ditto
ConstRange opIndex() const
{
return typeof(return)(this.data[]);
@ -702,7 +702,7 @@ private @nogc unittest
// Static checks.
private unittest
{
import std.range.primitives;
import tanya.range.primitive;
static assert(isBidirectionalRange!(Set!int.ConstRange));
static assert(isBidirectionalRange!(Set!int.Range));

40
source/tanya/container/string.d
View File

@ -417,7 +417,7 @@ struct String
}
}
/// Ditto.
/// ditto
this(S)(ref S init, shared Allocator allocator = defaultAllocator)
nothrow @trusted @nogc
if (is(Unqual!S == String))
@ -428,7 +428,7 @@ struct String
this.length_ = init.length;
}
/// Ditto.
/// ditto
this(shared Allocator allocator) pure nothrow @safe @nogc
in
{
@ -585,7 +585,7 @@ struct String
return 1;
}
/// Ditto.
/// ditto
size_t insertBack(const wchar chr) @trusted @nogc
{
reserve(length + 3);
@ -620,7 +620,7 @@ struct String
defaultAllocator.dispose(exception);
}
/// Ditto.
/// ditto
size_t insertBack(const dchar chr) @trusted @nogc
{
reserve(length + dchar.sizeof);
@ -730,7 +730,7 @@ struct String
}
}
/// Ditto.
/// ditto
size_t insertBack(R)(R str) @trusted
if (!isInfinite!R
&& isInputRange!R
@ -796,7 +796,7 @@ struct String
return this.length_ - oldLength;
}
/// Ditto.
/// ditto
size_t insertBack(R)(R str) @trusted
if (!isInfinite!R
&& isInputRange!R
@ -815,7 +815,7 @@ struct String
return insertedLength;
}
/// Ditto.
/// ditto
alias insert = insertBack;
/**
@ -943,7 +943,7 @@ struct String
return target;
}
/// Ditto.
/// ditto
ByCodeUnit!char opSliceAssign(const char[] value,
const size_t i,
const size_t j)
@ -959,7 +959,7 @@ struct String
return opSlice(i, j);
}
/// Ditto.
/// ditto
ByCodeUnit!char opSliceAssign(const char value,
const size_t i,
const size_t j)
@ -1072,7 +1072,7 @@ struct String
return typeof(return)(this, this.data, this.data + length);
}
/// Ditto.
/// ditto
ByCodeUnit!(const char) opIndex() const pure nothrow @trusted @nogc
{
return typeof(return)(this, this.data, this.data + length);
@ -1105,7 +1105,7 @@ struct String
return typeof(return)(this, this.data, this.data + length);
}
/// Ditto.
/// ditto
ByCodePoint!(const char) byCodePoint() const pure nothrow @trusted @nogc
{
return typeof(return)(this, this.data, this.data + length);
@ -1173,7 +1173,7 @@ struct String
return typeof(return)(this, this.data + i, this.data + j);
}
/// Ditto.
/// ditto
ByCodeUnit!(const char) opSlice(const size_t i, const size_t j)
const pure nothrow @trusted @nogc
in
@ -1240,7 +1240,7 @@ struct String
return this;
}
/// Ditto.
/// ditto
ref String opAssign(S)(ref S that) @trusted
if (is(Unqual!S == String))
{
@ -1301,7 +1301,7 @@ struct String
return cmp(this.data[0 .. length], that.data[0 .. that.length]);
}
/// Ditto.
/// ditto
int opCmp(S)(ByCodeUnit!S that) const @trusted
if (is(Unqual!S == char))
{
@ -1309,7 +1309,7 @@ struct String
that.begin[0 .. that.end - that.begin]);
}
/// Ditto.
/// ditto
int opCmp(S)(ByCodePoint!S that) const @trusted
if (is(Unqual!S == char))
{
@ -1317,7 +1317,7 @@ struct String
that.begin[0 .. that.end - that.begin]);
}
/// Ditto.
/// ditto
int opCmp()(const char[] that) const @trusted
{
return cmp(this.data[0 .. length], that);
@ -1362,7 +1362,7 @@ struct String
that.begin[0 .. that.end - that.begin]);
}
/// Ditto.
/// ditto
bool opEquals(S)(ByCodePoint!S that) const @trusted
if (is(Unqual!S == char))
{
@ -1370,7 +1370,7 @@ struct String
that.begin[0 .. that.end - that.begin]);
}
/// Ditto.
/// ditto
bool opEquals()(const char[] that) const @trusted
{
return equal(this.data[0 .. length], that);
@ -1443,7 +1443,7 @@ struct String
assert(s2 == "cup");
}
/// Ditto.
/// ditto
ByCodeUnit!char opIndexAssign(const char value) pure nothrow @safe @nogc
{
return opSliceAssign(value, 0, length);
@ -1456,7 +1456,7 @@ struct String
assert(s1 == "aaa");
}
/// Ditto.
/// ditto
ByCodeUnit!char opIndexAssign(const char[] value) pure nothrow @safe @nogc
{
return opSliceAssign(value, 0, length);

501
source/tanya/encoding/ascii.d Normal file
View File

@ -0,0 +1,501 @@
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
/**
* Functions operating on ASCII characters.
*
* ASCII is $(B A)merican $(B S)tandard $(B C)ode for $(B I)nformation
* $(B I)nterchange.
*
* Copyright: Eugene Wissner 2017.
* License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
* Mozilla Public License, v. 2.0).
* Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
* Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/encoding/ascii.d,
* tanya/encoding/ascii.d)
*/
module tanya.encoding.ascii;
import tanya.meta.trait;
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.
/// A..Za..z.
const string letters = "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz";
const string uppercase = "ABCDEFGHIJKLMNOPQRSTUVWXYZ"; /// A..Z.
const 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 ";
/// Letter case specifier.
enum LetterCase : bool
{
upper, /// Uppercase.
lower, /// Lowercase.
}
/**
* Checks for an uppecase alphabetic character.
*
* Params:
* C = Some character type.
* c = Some character.
*
* Returns: $(D_KEYWORD true) if $(D_PARAM c) is an uppercase alphabetic
* character, $(D_KEYWORD false) otherwise.
*/
bool isUpper(C)(C c)
if (isSomeChar!C)
{
return (c >= 'A') && (c <= 'Z');
}
///
pure nothrow @safe @nogc unittest
{
assert(isUpper('A'));
assert(isUpper('Z'));
assert(isUpper('L'));
assert(!isUpper('a'));
assert(!isUpper('!'));
}
/**
* Checks for a lowercase alphabetic character.
*
* Params:
* C = Some character type.
* c = Some character.
*
* Returns: $(D_KEYWORD true) if $(D_PARAM c) is a lowercase alphabetic
* character, $(D_KEYWORD false) otherwise.
*/
bool isLower(C)(C c)
if (isSomeChar!C)
{
return (c >= 'a') && (c <= 'z');
}
///
pure nothrow @safe @nogc unittest
{
assert(isLower('a'));
assert(isLower('z'));
assert(isLower('l'));
assert(!isLower('A'));
assert(!isLower('!'));
}
/**
* Checks for an alphabetic character (upper- or lowercase).
*
* Params:
* C = Some character type.
* c = Some character.
*
* Returns: $(D_KEYWORD true) if $(D_PARAM c) is an alphabetic character,
* $(D_KEYWORD false) otherwise.
*/
bool isAlpha(C)(C c)
if (isSomeChar!C)
{
return isUpper(c) || isLower(c);
}
///
pure nothrow @safe @nogc unittest
{
assert(isAlpha('A'));
assert(isAlpha('Z'));
assert(isAlpha('L'));
assert(isAlpha('a'));
assert(isAlpha('z'));
assert(isAlpha('l'));
assert(!isAlpha('!'));
}
/**
* Checks for a digit.
*
* Params:
* C = Some character type.
* c = Some character.
*
* Returns: $(D_KEYWORD true) if $(D_PARAM c) is a digit,
* $(D_KEYWORD false) otherwise.
*/
bool isDigit(C)(C c)
if (isSomeChar!C)
{
return (c >= '0') && (c <= '9');
}
///
pure nothrow @safe @nogc unittest
{
assert(isDigit('0'));
assert(isDigit('1'));
assert(isDigit('2'));
assert(isDigit('3'));
assert(isDigit('4'));
assert(isDigit('5'));
assert(isDigit('6'));
assert(isDigit('7'));
assert(isDigit('8'));
assert(isDigit('9'));
assert(!isDigit('a'));
assert(!isDigit('!'));
}
/**
* Checks for an alphabetic character (upper- or lowercase) or a digit.
*
* Params:
* C = Some character type.
* c = Some character.
*
* Returns: $(D_KEYWORD true) if $(D_PARAM c) is an alphabetic character or a
* digit, $(D_KEYWORD false) otherwise.
*/
bool isAlphaNum(C)(C c)
if (isSomeChar!C)
{
return isAlpha(c) || isDigit(c);
}
///
pure nothrow @safe @nogc unittest
{
assert(isAlphaNum('0'));
assert(isAlphaNum('1'));
assert(isAlphaNum('9'));
assert(isAlphaNum('A'));
assert(isAlphaNum('Z'));
assert(isAlphaNum('L'));
assert(isAlphaNum('a'));
assert(isAlphaNum('z'));
assert(isAlphaNum('l'));
assert(!isAlphaNum('!'));
}
/**
* Checks for a 7-bit ASCII character.
*
* Params:
* C = Some character type.
* c = Some character.
*
* Returns: $(D_KEYWORD true) if $(D_PARAM c) is an ASCII character,
* $(D_KEYWORD false) otherwise.
*/
bool isASCII(C)(C c)
if (isSomeChar!C)
{
return c < 128;
}
///
pure nothrow @safe @nogc unittest
{
assert(isASCII('0'));
assert(isASCII('L'));
assert(isASCII('l'));
assert(isASCII('!'));
assert(!isASCII('©'));
assert(!isASCII('§'));
assert(!isASCII(char.init)); // 0xFF
assert(!isASCII(wchar.init)); // 0xFFFF
assert(!isASCII(dchar.init)); // 0xFFFF
}
/**
* Checks for a control character.
*
* Control characters are non-printable characters. Their ASCII codes are those
* between 0x00 (NUL) and 0x1f (US), and 0x7f (DEL).
*
* Params:
* C = Some character type.
* c = Some character.
*
* Returns: $(D_KEYWORD true) if $(D_PARAM c) is a control character,
* $(D_KEYWORD false) otherwise.
*
* See_Also: $(D_PSYMBOL isPrintable), $(D_PSYMBOL isGraphical).
*/
bool isControl(C)(C c)
if (isSomeChar!C)
{
return (c <= 0x1f) || (c == 0x7f);
}
///
pure nothrow @safe @nogc unittest
{
assert(isControl('\t'));
assert(isControl('\0'));
assert(isControl('\u007f'));
assert(!isControl(' '));
assert(!isControl('a'));
assert(!isControl(char.init)); // 0xFF
assert(!isControl(wchar.init)); // 0xFFFF
}
/**
* Checks for a whitespace character.
*
* Whitespace characters are:
*
* $(UL
* $(LI Whitespace)
* $(LI Horizontal Tab (HT))
* $(LI Line Feed (LF))
* $(LI Carriage Return (CR))
* $(LI Vertical Tab (VT))
* $(LI Form Feed (FF))
* )
*
* Params:
* C = Some character type.
* c = Some character.
*
* Returns: $(D_KEYWORD true) if $(D_PARAM c) is a whitespace character,
* $(D_KEYWORD false) otherwise.
*
* See_Also: $(D_PSYMBOL whitespace).
*/
bool isWhite(C)(C c)
if (isSomeChar!C)
{
return ((c >= 0x09) && (c <= 0x0d)) || (c == 0x20);
}
///
pure nothrow @safe @nogc unittest
{
assert(isWhite('\t'));
assert(isWhite('\n'));
assert(isWhite('\v'));
assert(isWhite('\f'));
assert(isWhite('\r'));
assert(isWhite(' '));
}
/**
* Checks for a graphical character.
*
* Graphical characters are printable characters but whitespace characters.
*
* Params:
* C = Some character type.
* c = Some character.
*
* Returns: $(D_KEYWORD true) if $(D_PARAM c) is a control character,
* $(D_KEYWORD false) otherwise.
*
* See_Also: $(D_PSYMBOL isControl), $(D_PSYMBOL isWhite).
*/
bool isGraphical(C)(C c)
if (isSomeChar!C)
{
return (c > 0x20) && (c < 0x7f);
}
///
pure nothrow @safe @nogc unittest
{
assert(isGraphical('a'));
assert(isGraphical('0'));
assert(!isGraphical('\u007f'));
assert(!isGraphical('§'));
assert(!isGraphical('\n'));
assert(!isGraphical(' '));
}
/**
* Checks for a printable character.
*
* This is the opposite of a control character.
*
* Params:
* C = Some character type.
* c = Some character.
*
* Returns: $(D_KEYWORD true) if $(D_PARAM c) is a control character,
* $(D_KEYWORD false) otherwise.
*
* See_Also: $(D_PSYMBOL isControl).
*/
bool isPrintable(C)(C c)
if (isSomeChar!C)
{
return (c >= 0x20) && (c < 0x7f);
}
///
pure nothrow @safe @nogc unittest
{
assert(isPrintable('a'));
assert(isPrintable('0'));
assert(!isPrintable('\u007f'));
assert(!isPrintable('§'));
assert(!isPrintable('\n'));
assert(isPrintable(' '));
}
/**
* Checks for a hexadecimal digit.
*
* Params:
* C = Some character type.
* c = Some character.
*
* Returns: $(D_KEYWORD true) if $(D_PARAM c) is a hexadecimal digit,
* $(D_KEYWORD false) otherwise.
*/
bool isHexDigit(C)(C c)
if (isSomeChar!C)
{
return ((c >= '0') && (c <= '9'))
|| ((c >= 'a') && (c <= 'f'))
|| ((c >= 'A') && (c <= 'F'));
}
///
pure nothrow @safe @nogc unittest
{
assert(isHexDigit('0'));
assert(isHexDigit('1'));
assert(isHexDigit('8'));
assert(isHexDigit('9'));
assert(isHexDigit('A'));
assert(isHexDigit('F'));
assert(!isHexDigit('G'));
assert(isHexDigit('a'));
assert(isHexDigit('f'));
assert(!isHexDigit('g'));
}
/**
* Checks for an octal character.
*
* Params:
* C = Some character type.
* c = Some character.
*
* Returns: $(D_KEYWORD true) if $(D_PARAM c) is an octal character,
* $(D_KEYWORD false) otherwise.
*/
bool isOctalDigit(C)(C c)
if (isSomeChar!C)
{
return (c >= '0') && (c <= '7');
}
///
pure nothrow @safe @nogc unittest
{
assert(isOctalDigit('0'));
assert(isOctalDigit('1'));
assert(isOctalDigit('2'));
assert(isOctalDigit('3'));
assert(isOctalDigit('4'));
assert(isOctalDigit('5'));
assert(isOctalDigit('6'));
assert(isOctalDigit('7'));
assert(!isOctalDigit('8'));
}
/**
* Checks for a octal character.
*
* Params:
* C = Some character type.
* c = Some character.
*
* Returns: $(D_KEYWORD true) if $(D_PARAM c) is a octal character,
* $(D_KEYWORD false) otherwise.
*/
bool isPunctuation(C)(C c)
if (isSomeChar!C)
{
return ((c >= 0x21) && (c <= 0x2f))
|| ((c >= 0x3a) && (c <= 0x40))
|| ((c >= 0x5b) && (c <= 0x60))
|| ((c >= 0x7b) && (c <= 0x7e));
}
///
pure nothrow @safe @nogc unittest
{
assert(isPunctuation('!'));
assert(isPunctuation(':'));
assert(isPunctuation('\\'));
assert(isPunctuation('|'));
assert(!isPunctuation('0'));
assert(!isPunctuation(' '));
}
/**
* Converts $(D_PARAM c) to uppercase.
*
* If $(D_PARAM c) is not a lowercase character, $(D_PARAM c) is returned
* unchanged.
*
* Params:
* C = Some character type.
* c = Some character.
*
* Returns: The lowercase of $(D_PARAM c) if available, just $(D_PARAM c)
* otherwise.
*/
C toUpper(C)(const C c)
if (isSomeChar!C)
{
return isLower(c) ? (cast(C) (c - 32)) : c;
}
///
pure nothrow @safe @nogc unittest
{
assert(toUpper('a') == 'A');
assert(toUpper('A') == 'A');
assert(toUpper('!') == '!');
}
/**
* Converts $(D_PARAM c) to lowercase.
*
* If $(D_PARAM c) is not an uppercase character, $(D_PARAM c) is returned
* unchanged.
*
* Params:
* C = Some character type.
* c = Some character.
*
* Returns: The uppercase of $(D_PARAM c) if available, just $(D_PARAM c)
* otherwise.
*/
C toLower(C)(const C c)
if (isSomeChar!C)
{
return isUpper(c) ? (cast(C) (c + 32)) : c;
}
///
pure nothrow @safe @nogc unittest
{
assert(toLower('A') == 'a');
assert(toLower('a') == 'a');
assert(toLower('!') == '!');
}

17
source/tanya/encoding/package.d Normal file
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@ -0,0 +1,17 @@
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
/**
* This package provides tools to work with text encodings.
*
* Copyright: Eugene Wissner 2017.
* License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
* Mozilla Public License, v. 2.0).
* Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
* Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/encoding/package.d,
* tanya/encoding/package.d)
*/
module tanya.encoding;
public import tanya.encoding.ascii;

6
source/tanya/format/conv.d
View File

@ -64,7 +64,7 @@ template to(To)
return from;
}
/// Ditto.
/// ditto
To to(From)(From from)
if (is(Unqual!To == Unqual!From) || (isNumeric!From && isFloatingPoint!To))
{
@ -358,7 +358,7 @@ private @nogc unittest
defaultAllocator.dispose(exception);
}
/// Ditto.
/// ditto
To to(To, From)(auto ref const From from)
if ((is(From == String) || isSomeString!From) && is(Unqual!To == bool))
{
@ -443,7 +443,7 @@ pure nothrow @safe @nogc unittest
assert(false.to!int == 0);
}
/// Ditto.
/// ditto
To to(To, From)(const From from)
if (is(Unqual!From == bool) && is(Unqual!To == String))
{

1740
source/tanya/format/package.d
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File diff suppressed because it is too large Load Diff

100
source/tanya/math/mp.d
View File

@ -15,9 +15,9 @@
module tanya.math.mp;
import std.algorithm;
import std.ascii;
import std.range;
import tanya.container.array;
import tanya.encoding.ascii;
import tanya.memory;
import tanya.meta.trait;
import tanya.meta.transform;
@ -69,24 +69,23 @@ struct Integer
* Precondition: $(D_INLINECODE allocator !is null)
*/
this(T)(const T value, shared Allocator allocator = defaultAllocator)
if (isIntegral!T)
if (isIntegral!T)
{
this(allocator);
this = value;
}
/// Ditto.
/// ditto
this(T)(ref T value, shared Allocator allocator = defaultAllocator)
if (is(Unqual!T == Integer))
if (is(Unqual!T == Integer))
{
this(allocator);
this = value;
}
/// Ditto.
/// ditto
this(T)(T value, shared Allocator allocator = defaultAllocator)
nothrow @safe @nogc
if (is(T == Integer))
if (is(T == Integer))
{
this(allocator);
if (allocator is value.allocator)
@ -104,7 +103,7 @@ struct Integer
}
}
/// Ditto.
/// ditto
this(shared Allocator allocator) pure nothrow @safe @nogc
in
{
@ -129,8 +128,8 @@ struct Integer
this(R)(const Sign sign,
R value,
shared Allocator allocator = defaultAllocator)
if (isBidirectionalRange!R && hasLength!R
&& is(Unqual!(ElementType!R) == ubyte))
if (isBidirectionalRange!R && hasLength!R
&& is(Unqual!(ElementType!R) == ubyte))
{
this(allocator);
grow(value.length / (digitBitCount / 8) + 1);
@ -156,6 +155,7 @@ struct Integer
}
}
///
nothrow @safe @nogc unittest
{
ubyte[8] range = [ 0x66, 0x77, 0x88, 0x99, 0xaa, 0xbb, 0xdd, 0xee ];
@ -173,10 +173,9 @@ struct Integer
*
* Precondition: $(D_INLINECODE allocator !is null)
*/
this(R)(R value,
shared Allocator allocator = defaultAllocator)
if (isBidirectionalRange!R && hasLength!R
&& is(Unqual!(ElementType!R) == ubyte))
this(R)(R value, shared Allocator allocator = defaultAllocator)
if (isBidirectionalRange!R && hasLength!R
&& is(Unqual!(ElementType!R) == ubyte))
{
this(Sign.positive, value, allocator);
@ -280,6 +279,19 @@ struct Integer
}
}
///
private nothrow @safe @nogc unittest
{
{
Integer i;
assert(i.length == 0);
}
{
auto i = Integer(-123456789);
assert(i.length == 4);
}
}
/**
* Assigns a new value.
*
@ -290,7 +302,7 @@ struct Integer
* Returns: $(D_KEYWORD this).
*/
ref Integer opAssign(T)(const T value)
if (isIntegral!T)
if (isIntegral!T)
{
rep[0 .. this.size].fill(digit.init);
grow(digitBitCount / 8 + 1);
@ -323,9 +335,9 @@ struct Integer
return this;
}
/// Ditto.
/// ditto
ref Integer opAssign(T)(ref T value) @trusted
if (is(Unqual!T == Integer))
if (is(Unqual!T == Integer))
{
this.rep = allocator.resize(this.rep, value.size);
value.rep[0 .. value.size].copy(this.rep[0 .. value.size]);
@ -335,9 +347,9 @@ struct Integer
return this;
}
/// Ditto.
/// ditto
ref Integer opAssign(T)(T value) nothrow @safe @nogc
if (is(T == Integer))
if (is(T == Integer))
{
swap(this.rep, value.rep);
swap(this.sign, value.sign);
@ -359,9 +371,9 @@ struct Integer
return this.size > 0;
}
/// Ditto.
/// ditto
T opCast(T)() const
if (isIntegral!T && isUnsigned!T)
if (isIntegral!T && isUnsigned!T)
{
T ret;
ubyte shift;
@ -373,9 +385,9 @@ struct Integer
return ret;
}
/// Ditto.
/// ditto
T opCast(T)() const
if (isIntegral!T && isSigned!T)
if (isIntegral!T && isSigned!T)
{
return this.sign ? -(cast(Unsigned!T) this) : cast(Unsigned!T) this;
}
@ -405,7 +417,7 @@ struct Integer
assert(cast(long) integer == 0);
}
/* trim unused digits
/* Trim unused digits.
*
* This is used to ensure that leading zero digits are
* trimed and the leading "size" digit will be non-zero
@ -665,9 +677,9 @@ struct Integer
assert(integer1 > integer2);
}
/// Ditto.
/// ditto
int opCmp(I)(const I that) const
if (isIntegral!I)
if (isIntegral!I)
{
if (that < 0 && !this.sign)
{
@ -713,7 +725,7 @@ struct Integer
* Returns: Whether the two integers are equal.
*/
bool opEquals(I)(auto ref const I that) const
if (is(I : Integer) || isIntegral!I)
if (is(I : Integer) || isIntegral!I)
{
return opCmp!I(that) == 0;
}
@ -777,7 +789,7 @@ struct Integer
}
}
/// Ditto.
/// ditto
ref Integer opOpAssign(string op : "-")(auto ref const Integer operand)
{
if (this.sign != operand.sign)
@ -825,7 +837,7 @@ struct Integer
}
}
/// Ditto.
/// ditto
ref Integer opOpAssign(string op : "*")(auto ref const Integer operand)
{
const digits = this.size + operand.size + 1;
@ -849,7 +861,7 @@ struct Integer
assert(h1 == 56088);
}
/// Ditto.
/// ditto
ref Integer opOpAssign(string op : "/")(auto ref const Integer operand)
in
{
@ -861,7 +873,7 @@ struct Integer
return this;
}
/// Ditto.
/// ditto
ref Integer opOpAssign(string op : "%")(auto ref const Integer operand)
in
{
@ -894,7 +906,7 @@ struct Integer
assert(h1 == 123);
}
/// Ditto.
/// ditto
ref Integer opOpAssign(string op : ">>")(const size_t operand)
{
if (operand == 0)
@ -956,7 +968,7 @@ struct Integer
assert(integer == 0);
}
/// Ditto.
/// ditto
ref Integer opOpAssign(string op : "<<")(const size_t operand)
{
const step = operand / digitBitCount;
@ -1015,7 +1027,7 @@ struct Integer
return ret;
}
/// Ditto.
/// ditto
Integer opUnary(string op : "-")() const
{
auto ret = Integer(this, allocator);
@ -1056,7 +1068,7 @@ struct Integer
assert(h2 == ~cast(ubyte) 79);
}
/// Ditto.
/// ditto
ref Integer opUnary(string op : "++")()
{
if (this.sign)
@ -1070,7 +1082,7 @@ struct Integer
return this;
}
/// Ditto.
/// ditto
ref Integer opUnary(string op : "--")()
{
if (this.size == 0)
@ -1135,14 +1147,14 @@ struct Integer
* Returns: Result.
*/
Integer opBinary(string op)(auto ref const Integer operand) const
if ((op == "+" || op == "-") || (op == "*"))
if ((op == "+" || op == "-") || (op == "*"))
{
mixin("return Integer(this, allocator) " ~ op ~ "= operand;");
}
/// Ditto.
/// ditto
Integer opBinary(string op)(const auto ref Integer operand) const
if (op == "/" || op == "%")
if (op == "/" || op == "%")
in
{
assert(operand.length > 0, "Division by zero.");
@ -1152,9 +1164,9 @@ struct Integer
mixin("return Integer(this, allocator) " ~ op ~ "= operand;");
}
/// Ditto.
/// ditto
Integer opBinary(string op)(const size_t operand) const
if (op == "<<" || op == ">>")
if (op == "<<" || op == ">>")
{
mixin("return Integer(this, allocator) " ~ op ~ "= operand;");
}
@ -1260,9 +1272,9 @@ struct Integer
auto ref Q quotient,
ref ARGS args)
const nothrow @safe @nogc
if ((is(Q : typeof(null))
|| (is(Q : Integer) && __traits(isRef, quotient)))
&& (ARGS.length == 0 || (ARGS.length == 1 && is(ARGS[0] : Integer))))
if ((is(Q : typeof(null))
|| (is(Q : Integer) && __traits(isRef, quotient)))
&& (ARGS.length == 0 || (ARGS.length == 1 && is(ARGS[0] : Integer))))
in
{
assert(divisor != 0, "Division by zero.");

105
source/tanya/math/nbtheory.d Normal file
View File

@ -0,0 +1,105 @@
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
/**
* Number theory.
*
* Copyright: Eugene Wissner 2017.
* License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
* Mozilla Public License, v. 2.0).
* Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
* Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/math/nbtheory.d,
* tanya/math/nbtheory.d)
*/
module tanya.math.nbtheory;
import tanya.math.mp;
import tanya.meta.trait;
/**
* Calculates the absolute value of a number.
*
* Params:
* I = Value type.
* x = Value.
*
* Returns: Absolute value of $(D_PARAM x).
*/
I abs(I)(I x)
if (isIntegral!I)
{
static if (isSigned!I)
{
return x >= 0 ? x : -x;
}
else
{
return x;
}
}
///
pure nothrow @safe @nogc unittest
{
int i = -1;
assert(i.abs == 1);
static assert(is(typeof(i.abs) == int));
uint u = 1;
assert(u.abs == 1);
static assert(is(typeof(u.abs) == uint));
}
version (D_Ddoc)
{
/// ditto
I abs(I)(I x)
if (isFloatingPoint!I);
}
else version (TanyaPhobos)
{
import core.math;
I abs(I)(I x)
if (isFloatingPoint!I)
{
return fabs(cast(real) x);
}
}
else
{
extern I abs(I)(I number) pure nothrow @safe @nogc
if (isFloatingPoint!I);
}
///
pure nothrow @safe @nogc unittest
{
float f = -1.64;
assert(f.abs == 1.64F);
static assert(is(typeof(f.abs) == float));
double d = -1.64;
assert(d.abs == 1.64);
static assert(is(typeof(d.abs) == double));
real r = -1.64;
assert(r.abs == 1.64L);
static assert(is(typeof(r.abs) == real));
}
/// ditto
I abs(I : Integer)(const auto ref I x)
{
auto result = Integer(x, x.allocator);
result.sign = Sign.positive;
return result;
}
/// ditto
I abs(I : Integer)(I x)
{
x.sign = Sign.positive;
return x;
}

617
source/tanya/math/package.d
View File

@ -5,6 +5,13 @@
/**
* This package provides mathematical functions.
*
* The $(D_PSYMBOL tanya.math) package itself provides only representation
* functions for built-in types, such as functions that provide information
* about internal representation of floating-point numbers and low-level
* operatons on these. Actual mathematical functions and additional types can
* be found in its submodules. $(D_PSYMBOL tanya.math) doesn't import any
* submodules publically, they should be imported explicitly.
*
* Copyright: Eugene Wissner 2016-2017.
* License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
* Mozilla Public License, v. 2.0).
@ -14,13 +21,542 @@
*/
module tanya.math;
public import tanya.math.mp;
public import tanya.math.random;
import tanya.math.mp;
import tanya.math.nbtheory;
import tanya.meta.trait;
version (unittest)
/// Floating-point number precisions according to IEEE-754.
enum IEEEPrecision : ubyte
{
import std.algorithm.iteration;
single = 4, /// Single precision: 64-bit.
double_ = 8, /// Single precision: 64-bit.
doubleExtended = 10, /// Double extended precision: 80-bit.
}
/**
* Tests the precision of floating-point type $(D_PARAM F).
*
* For $(D_KEYWORD float), $(D_PSYMBOL ieeePrecision) always evaluates to
* $(D_INLINECODE IEEEPrecision.single); for $(D_KEYWORD double) - to
* $(D_INLINECODE IEEEPrecision.double). It returns different values only
* for $(D_KEYWORD real), since $(D_KEYWORD real) is a platform-dependent type.
*
* If $(D_PARAM F) is a $(D_KEYWORD real) and the target platform isn't
* currently supported, static assertion error will be raised (you can use
* $(D_INLINECODE is(typeof(ieeePrecision!F))) for testing the platform support
* without a compilation error).
*
* Params:
* F = Type to be tested.
*
* Returns: Precision according to IEEE-754.
*
* See_Also: $(D_PSYMBOL IEEEPrecision).
*/
template ieeePrecision(F)
if (isFloatingPoint!F)
{
static if (F.sizeof == float.sizeof)
{
enum IEEEPrecision ieeePrecision = IEEEPrecision.single;
}
else static if (F.sizeof == double.sizeof)
{
enum IEEEPrecision ieeePrecision = IEEEPrecision.double_;
}
else version (X86)
{
enum IEEEPrecision ieeePrecision = IEEEPrecision.doubleExtended;
}
else version (X86_64)
{
enum IEEEPrecision ieeePrecision = IEEEPrecision.doubleExtended;
}
else
{
static assert(false, "Unsupported IEEE 754 floating point precision");
}
}
///
pure nothrow @safe @nogc unittest
{
static assert(ieeePrecision!float == IEEEPrecision.single);
static assert(ieeePrecision!double == IEEEPrecision.double_);
}
private union FloatBits(F)
{
F floating;
static if (ieeePrecision!F == IEEEPrecision.single)
{
uint integral;
enum uint expMask = 0x7f800000;
}
else static if (ieeePrecision!F == IEEEPrecision.double_)
{
ulong integral;
enum ulong expMask = 0x7ff0000000000000;
}
else static if (ieeePrecision!F == IEEEPrecision.doubleExtended)
{
struct // Little-endian.
{
ulong mantissa;
ushort exp;
}
enum ulong mantissaMask = 0x7fffffffffffffff;
enum uint expMask = 0x7fff;
}
else
{
static assert(false, "Unsupported IEEE 754 floating point precision");
}
}
/**
* Floating-point number classifications.
*/
enum FloatingPointClass : ubyte
{
/**
* Not a Number.
*
* See_Also: $(D_PSYMBOL isNaN).
*/
nan,
/// Zero.
zero,
/**
* Infinity.
*
* See_Also: $(D_PSYMBOL isInfinity).
*/
infinite,
/**
* Denormalized number.
*
* See_Also: $(D_PSYMBOL isSubnormal).
*/
subnormal,
/**
* Normalized number.
*
* See_Also: $(D_PSYMBOL isNormal).
*/
normal,
}
/**
* Returns whether $(D_PARAM x) is a NaN, zero, infinity, subnormal or
* normalized number.
*
* This function doesn't distinguish between negative and positive infinity,
* negative and positive NaN or negative and positive zero.
*
* Params:
* F = Type of the floating point number.
* x = Floating point number.
*
* Returns: Classification of $(D_PARAM x).
*/
FloatingPointClass classify(F)(F x)
if (isFloatingPoint!F)
{
if (x == 0)
{
return FloatingPointClass.zero;
}
FloatBits!F bits;
bits.floating = abs(x);
static if (ieeePrecision!F == IEEEPrecision.single)
{
if (bits.integral > bits.expMask)
{
return FloatingPointClass.nan;
}
else if (bits.integral == bits.expMask)
{
return FloatingPointClass.infinite;
}
else if (bits.integral < (1 << 23))
{
return FloatingPointClass.subnormal;
}
}
else static if (ieeePrecision!F == IEEEPrecision.double_)
{
if (bits.integral > bits.expMask)
{
return FloatingPointClass.nan;
}
else if (bits.integral == bits.expMask)
{
return FloatingPointClass.infinite;
}
else if (bits.integral < (1L << 52))
{
return FloatingPointClass.subnormal;
}
}
else static if (ieeePrecision!F == IEEEPrecision.doubleExtended)
{
if (bits.exp == bits.expMask)
{
if ((bits.mantissa & bits.mantissaMask) == 0)
{
return FloatingPointClass.infinite;
}
else
{
return FloatingPointClass.nan;
}
}
else if (bits.exp == 0)
{
return FloatingPointClass.subnormal;
}
else if (bits.mantissa < (1L << 63)) // "Unnormal".
{
return FloatingPointClass.nan;
}
}
return FloatingPointClass.normal;
}
///
pure nothrow @safe @nogc unittest
{
assert(classify(0.0) == FloatingPointClass.zero);
assert(classify(double.nan) == FloatingPointClass.nan);
assert(classify(double.infinity) == FloatingPointClass.infinite);
assert(classify(-double.infinity) == FloatingPointClass.infinite);
assert(classify(1.4) == FloatingPointClass.normal);
assert(classify(1.11254e-307 / 10) == FloatingPointClass.subnormal);
assert(classify(0.0f) == FloatingPointClass.zero);
assert(classify(float.nan) == FloatingPointClass.nan);
assert(classify(float.infinity) == FloatingPointClass.infinite);
assert(classify(-float.infinity) == FloatingPointClass.infinite);
assert(classify(0.3) == FloatingPointClass.normal);
assert(classify(5.87747e-38f / 10) == FloatingPointClass.subnormal);
assert(classify(0.0L) == FloatingPointClass.zero);
assert(classify(real.nan) == FloatingPointClass.nan);
assert(classify(real.infinity) == FloatingPointClass.infinite);
assert(classify(-real.infinity) == FloatingPointClass.infinite);
}
private pure nothrow @nogc @safe unittest
{
static if (ieeePrecision!float == IEEEPrecision.doubleExtended)
{
assert(classify(1.68105e-10) == FloatingPointClass.normal);
assert(classify(1.68105e-4932L) == FloatingPointClass.subnormal);
// Emulate unnormals, because they aren't generated anymore since i386
FloatBits!real unnormal;
unnormal.exp = 0x123;
unnormal.mantissa = 0x1;
assert(classify(unnormal) == FloatingPointClass.subnormal);
}
}
/**
* Determines whether $(D_PARAM x) is a finite number.
*
* Params:
* F = Type of the floating point number.
* x = Floating point number.
*
* Returns: $(D_KEYWORD true) if $(D_PARAM x) is a finite number,
* $(D_KEYWORD false) otherwise.
*
* See_Also: $(D_PSYMBOL isInfinity).
*/
bool isFinite(F)(F x)
if (isFloatingPoint!F)
{
FloatBits!F bits;
static if (ieeePrecision!F == IEEEPrecision.single
|| ieeePrecision!F == IEEEPrecision.double_)
{
bits.floating = x;
bits.integral &= bits.expMask;
return bits.integral != bits.expMask;
}
else static if (ieeePrecision!F == IEEEPrecision.doubleExtended)
{
bits.floating = abs(x);
return (bits.exp != bits.expMask)
&& (bits.exp == 0 || bits.mantissa >= (1L << 63));
}
}
///
pure nothrow @safe @nogc unittest
{
assert(!isFinite(float.infinity));
assert(!isFinite(-double.infinity));
assert(isFinite(0.0));
assert(!isFinite(float.nan));
assert(isFinite(5.87747e-38f / 10));
assert(isFinite(1.11254e-307 / 10));
assert(isFinite(0.5));
}
/**
* Determines whether $(D_PARAM x) is $(B n)ot $(B a) $(B n)umber (NaN).
*
* Params:
* F = Type of the floating point number.
* x = Floating point number.
*
* Returns: $(D_KEYWORD true) if $(D_PARAM x) is not a number,
* $(D_KEYWORD false) otherwise.
*/
bool isNaN(F)(F x)
if (isFloatingPoint!F)
{
FloatBits!F bits;
bits.floating = abs(x);
static if (ieeePrecision!F == IEEEPrecision.single
|| ieeePrecision!F == IEEEPrecision.double_)
{
return bits.integral > bits.expMask;
}
else static if (ieeePrecision!F == IEEEPrecision.doubleExtended)
{
const maskedMantissa = bits.mantissa & bits.mantissaMask;
if ((bits.exp == bits.expMask && maskedMantissa != 0)
|| ((bits.exp != 0) && (bits.mantissa < (1L << 63))))
{
return true;
}
return false;
}
}
///
pure nothrow @safe @nogc unittest
{
assert(isNaN(float.init));
assert(isNaN(double.init));
assert(isNaN(real.init));
}
/**
* Determines whether $(D_PARAM x) is a positive or negative infinity.
*
* Params:
* F = Type of the floating point number.
* x = Floating point number.
*
* Returns: $(D_KEYWORD true) if $(D_PARAM x) is infinity, $(D_KEYWORD false)
* otherwise.
*
* See_Also: $(D_PSYMBOL isFinite).
*/
bool isInfinity(F)(F x)
if (isFloatingPoint!F)
{
FloatBits!F bits;
bits.floating = abs(x);
static if (ieeePrecision!F == IEEEPrecision.single
|| ieeePrecision!F == IEEEPrecision.double_)
{
return bits.integral == bits.expMask;
}
else static if (ieeePrecision!F == IEEEPrecision.doubleExtended)
{
return (bits.exp == bits.expMask)
&& ((bits.mantissa & bits.mantissaMask) == 0);
}
}
///
pure nothrow @safe @nogc unittest
{
assert(isInfinity(float.infinity));
assert(isInfinity(-float.infinity));
assert(isInfinity(double.infinity));
assert(isInfinity(-double.infinity));
assert(isInfinity(real.infinity));
assert(isInfinity(-real.infinity));
}
/**
* Determines whether $(D_PARAM x) is a denormilized number or not.
* Denormalized number is a number between `0` and `1` that cannot be
* represented as
*
* <pre>
* m*2<sup>e</sup>
* </pre>
*
* where $(I m) is the mantissa and $(I e) is an exponent that fits into the
* exponent field of the type $(D_PARAM F).
*
* `0` is neither normalized nor denormalized.
*
* Params:
* F = Type of the floating point number.
* x = Floating point number.
*
* Returns: $(D_KEYWORD true) if $(D_PARAM x) is a denormilized number,
* $(D_KEYWORD false) otherwise.
*
* See_Also: $(D_PSYMBOL isNormal).
*/
bool isSubnormal(F)(F x)
if (isFloatingPoint!F)
{
FloatBits!F bits;
bits.floating = abs(x);
static if (ieeePrecision!F == IEEEPrecision.single)
{
return bits.integral < (1 << 23) && bits.integral > 0;
}
else static if (ieeePrecision!F == IEEEPrecision.double_)
{
return bits.integral < (1L << 52) && bits.integral > 0;
}
else static if (ieeePrecision!F == IEEEPrecision.doubleExtended)
{
return bits.exp == 0 && bits.mantissa != 0;
}
}
///
pure nothrow @safe @nogc unittest
{
assert(!isSubnormal(0.0f));
assert(!isSubnormal(float.nan));
assert(!isSubnormal(float.infinity));
assert(!isSubnormal(0.3f));
assert(isSubnormal(5.87747e-38f / 10));
assert(!isSubnormal(0.0));
assert(!isSubnormal(double.nan));
assert(!isSubnormal(double.infinity));
assert(!isSubnormal(1.4));
assert(isSubnormal(1.11254e-307 / 10));
assert(!isSubnormal(0.0L));
assert(!isSubnormal(real.nan));
assert(!isSubnormal(real.infinity));
}
/**
* Determines whether $(D_PARAM x) is a normilized number or not.
* Normalized number is a number that can be represented as
*
* <pre>
* m*2<sup>e</sup>
* </pre>
*
* where $(I m) is the mantissa and $(I e) is an exponent that fits into the
* exponent field of the type $(D_PARAM F).
*
* `0` is neither normalized nor denormalized.
*
* Params:
* F = Type of the floating point number.
* x = Floating point number.
*
* Returns: $(D_KEYWORD true) if $(D_PARAM x) is a normilized number,
* $(D_KEYWORD false) otherwise.
*
* See_Also: $(D_PSYMBOL isSubnormal).
*/
bool isNormal(F)(F x)
if (isFloatingPoint!F)
{
static if (ieeePrecision!F == IEEEPrecision.single
|| ieeePrecision!F == IEEEPrecision.double_)
{
FloatBits!F bits;
bits.floating = x;
bits.integral &= bits.expMask;
return bits.integral != 0 && bits.integral != bits.expMask;
}
else static if (ieeePrecision!F == IEEEPrecision.doubleExtended)
{
return classify(x) == FloatingPointClass.normal;
}
}
///
pure nothrow @safe @nogc unittest
{
assert(!isNormal(0.0f));
assert(!isNormal(float.nan));
assert(!isNormal(float.infinity));
assert(isNormal(0.3f));
assert(!isNormal(5.87747e-38f / 10));
assert(!isNormal(0.0));
assert(!isNormal(double.nan));
assert(!isNormal(double.infinity));
assert(isNormal(1.4));
assert(!isNormal(1.11254e-307 / 10));
assert(!isNormal(0.0L));
assert(!isNormal(real.nan));
assert(!isNormal(real.infinity));
}
/**
* Determines whether the sign bit of $(D_PARAM x) is set or not.
*
* If the sign bit, $(D_PARAM x) is a negative number, otherwise positive.
*
* Params:
* F = Type of the floating point number.
* x = Floating point number.
*
* Returns: $(D_KEYWORD true) if the sign bit of $(D_PARAM x) is set,
* $(D_KEYWORD false) otherwise.
*/
bool signBit(F)(F x)
if (isFloatingPoint!F)
{
FloatBits!F bits;
bits.floating = x;
static if (ieeePrecision!F == IEEEPrecision.single)
{
return (bits.integral & (1 << 31)) != 0;
}
else static if (ieeePrecision!F == IEEEPrecision.double_)
{
return (bits.integral & (1L << 63)) != 0;
}
else static if (ieeePrecision!F == IEEEPrecision.doubleExtended)
{
return (bits.exp & (1 << 15)) != 0;
}
}
///
pure nothrow @safe @nogc unittest
{
assert(signBit(-1.0f));
assert(!signBit(1.0f));
assert(signBit(-1.0));
assert(!signBit(1.0));
assert(signBit(-1.0L));
assert(!signBit(1.0L));
}
/**
@ -43,7 +579,7 @@ version (unittest)
* Precondition: $(D_INLINECODE z > 0)
*/
H pow(I, G, H)(in auto ref I x, in auto ref G y, in auto ref H z)
if (isIntegral!I && isIntegral!G && isIntegral!H)
if (isIntegral!I && isIntegral!G && isIntegral!H)
in
{
assert(z > 0, "Division by zero.");
@ -82,9 +618,9 @@ body
return result;
}
/// Ditto.
/// ditto
I pow(I)(const auto ref I x, const auto ref I y, const auto ref I z)
if (is(I == Integer))
if (is(I == Integer))
in
{
assert(z.length > 0, "Division by zero.");
@ -137,7 +673,7 @@ pure nothrow @safe @nogc unittest
}
///
unittest
nothrow @safe @nogc unittest
{
assert(pow(Integer(3), Integer(5), Integer(7)) == 5);
assert(pow(Integer(2), Integer(2), Integer(1)) == 0);
@ -165,41 +701,40 @@ bool isPseudoprime(ulong x) nothrow pure @safe @nogc
}
///
unittest
pure nothrow @safe @nogc unittest
{
uint[30] known = [74623, 74653, 74687, 74699, 74707, 74713, 74717, 74719,
74843, 74747, 74759, 74761, 74771, 74779, 74797, 74821,
74827, 9973, 104729, 15485867, 49979693, 104395303,
593441861, 104729, 15485867, 49979693, 104395303,
593441861, 899809363, 982451653];
known.each!((ref x) => assert(isPseudoprime(x)));
assert(74623.isPseudoprime);
assert(104729.isPseudoprime);
assert(15485867.isPseudoprime);
assert(!15485868.isPseudoprime);
}
/**
* Params:
* I = Value type.
* x = Value.
*
* Returns: The absolute value of a number.
*/
I abs(I : Integer)(const auto ref I x)
private pure nothrow @safe @nogc unittest
{
auto result = Integer(x, x.allocator);
result.sign = Sign.positive;
return result;
}
/// Ditto.
I abs(I : Integer)(I x)
{
x.sign = Sign.positive;
return x;
}
/// Ditto.
I abs(I)(const I x)
if (isIntegral!I)
{
return x >= 0 ? x : -x;
assert(74653.isPseudoprime);
assert(74687.isPseudoprime);
assert(74699.isPseudoprime);
assert(74707.isPseudoprime);
assert(74713.isPseudoprime);
assert(74717.isPseudoprime);
assert(74719.isPseudoprime);
assert(74747.isPseudoprime);
assert(74759.isPseudoprime);
assert(74761.isPseudoprime);
assert(74771.isPseudoprime);
assert(74779.isPseudoprime);
assert(74797.isPseudoprime);
assert(74821.isPseudoprime);
assert(74827.isPseudoprime);
assert(9973.isPseudoprime);
assert(49979693.isPseudoprime);
assert(104395303.isPseudoprime);
assert(593441861.isPseudoprime);
assert(104729.isPseudoprime);
assert(15485867.isPseudoprime);
assert(49979693.isPseudoprime);
assert(104395303.isPseudoprime);
assert(593441861.isPseudoprime);
assert(899809363.isPseudoprime);
assert(982451653.isPseudoprime);
}

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

@ -227,8 +227,9 @@ class Entropy
* See_Also:
* $(D_PSYMBOL EntropySource)
*/
Entropy opOpAssign(string Op)(EntropySource source) pure nothrow @safe @nogc
if (Op == "~")
Entropy opOpAssign(string op)(EntropySource source)
pure nothrow @safe @nogc
if (op == "~")
in
{
assert(sourceCount_ <= sources.length);

441
source/tanya/memory/arch/x86_64.d
View File

@ -1,441 +0,0 @@
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
/*
* Implementions of functions found in $(D_PSYMBOL tanya.memory.op) for x64.
*
* Copyright: Eugene Wissner 2017.
* License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
* Mozilla Public License, v. 2.0).
* Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
* Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/memory/arch/x86_64.d,
* tanya/memory/arch/x86_64.d)
*/
module tanya.memory.arch.x86_64;
import tanya.memory.op;
version (D_InlineAsm_X86_64):
pragma(inline, true)
package (tanya.memory) void copy(const void[] source, void[] target)
pure nothrow @system @nogc
{
asm pure nothrow @nogc
{
naked;
// RDI and RSI should be preserved.
mov RAX, RDI;
mov R8, RSI;
}
// Set the registers for movsb/movsq.
version (Windows) asm pure nothrow @nogc
{
// RDX - source.
// RCX - target.
mov RDI, [ RCX + 8 ];
mov RSI, [ RDX + 8 ];
mov RDX, [ RDX ];
}
else asm pure nothrow @nogc
{
// RDX - source length.
// RCX - source data.
// RDI - target length
// RSI - target data.
mov RDI, RSI;
mov RSI, RCX;
}
asm pure nothrow @nogc
{
cmp RDX, 0x08;
jc aligned_1;
test EDI, 0x07;
jz aligned_8;
naligned:
movsb;
dec RDX;
test EDI, 0x07;
jnz naligned;
aligned_8:
mov RCX, RDX;
shr RCX, 0x03;
rep;
movsq;
and EDX, 0x07;
jz end;
aligned_1:
// Write the remaining bytes.
mov RCX, RDX;
rep;
movsb;
end: // Restore registers.
mov RSI, R8;
mov RDI, RAX;
ret;
}
}
package (tanya.memory) template fill(ubyte Byte)
{
private enum const(char[]) MovArrayPointer(string Destination)()
{
string asmCode = "asm pure nothrow @nogc { mov ";
version (Windows)
{
asmCode ~= Destination ~ ", [ RCX + 8 ];";
}
else
{
asmCode ~= Destination ~ ", RSI;";
}
return asmCode ~ "}";
}
pragma(inline, true)
void fill(void[] memory)
{
asm pure nothrow @nogc
{
naked;
}
version (Windows) asm pure nothrow @nogc
{
/*
* RCX - array.
*/
mov R8, [ RCX ];
}
else asm pure nothrow @nogc
{
/*
* RSI - pointer.
* RDI - length.
*/
mov R8, RDI;
}
mixin(MovArrayPointer!"R9");
asm pure nothrow @nogc
{
// Check for zero length.
test R8, R8;
jz end;
}
// Set 128- and 64-bit registers to values we want to fill with.
static if (Byte == 0)
{
asm pure nothrow @nogc
{
xor RAX, RAX;
pxor XMM0, XMM0;
}
}
else
{
enum ulong FilledBytes = FilledBytes!Byte;
asm pure nothrow @nogc
{
mov RAX, FilledBytes;
movq XMM0, RAX;
movlhps XMM0, XMM0;
}
}
asm pure nothrow @nogc
{
// Check if the pointer is aligned to a 16-byte boundary.
and R9, -0x10;
}
// Compute the number of misaligned bytes.
mixin(MovArrayPointer!"R10");
asm pure nothrow @nogc
{
sub R10, R9;
test R10, R10;
jz aligned;
// Get the number of bytes to be written until we are aligned.
mov RDX, 0x10;
sub RDX, R10;
}
mixin(MovArrayPointer!"R9");
asm pure nothrow @nogc
{
naligned:
mov [ R9 ], AL; // Write a byte.
// Advance the pointer. Decrease the total number of bytes
// and the misaligned ones.
inc R9;
dec RDX;
dec R8;
// Checks if we are aligned.
test RDX, RDX;
jnz naligned;
aligned:
// Checks if we're done writing bytes.
test R8, R8;
jz end;
// Write 1 byte at a time.
cmp R8, 8;
jl aligned_1;
// Write 8 bytes at a time.
cmp R8, 16;
jl aligned_8;
// Write 16 bytes at a time.
cmp R8, 32;
jl aligned_16;
// Write 32 bytes at a time.
cmp R8, 64;
jl aligned_32;
aligned_64:
movdqa [ R9 ], XMM0;
movdqa [ R9 + 16 ], XMM0;
movdqa [ R9 + 32 ], XMM0;
movdqa [ R9 + 48 ], XMM0;
add R9, 64;
sub R8, 64;
cmp R8, 64;
jge aligned_64;
// Checks if we're done writing bytes.
test R8, R8;
jz end;
// Write 1 byte at a time.
cmp R8, 8;
jl aligned_1;
// Write 8 bytes at a time.
cmp R8, 16;
jl aligned_8;
// Write 16 bytes at a time.
cmp R8, 32;
jl aligned_16;
aligned_32:
movdqa [ R9 ], XMM0;
movdqa [ R9 + 16 ], XMM0;
add R9, 32;
sub R8, 32;
// Checks if we're done writing bytes.
test R8, R8;
jz end;
// Write 1 byte at a time.
cmp R8, 8;
jl aligned_1;
// Write 8 bytes at a time.
cmp R8, 16;
jl aligned_8;
aligned_16:
movdqa [ R9 ], XMM0;
add R9, 16;
sub R8, 16;
// Checks if we're done writing bytes.
test R8, R8;
jz end;
// Write 1 byte at a time.
cmp R8, 8;
jl aligned_1;
aligned_8:
mov [ R9 ], RAX;
add R9, 8;
sub R8, 8;
// Checks if we're done writing bytes.
test R8, R8;
jz end;
aligned_1:
mov [ R9 ], AL;
inc R9;
dec R8;
test R8, R8;
jnz aligned_1;
end:
ret;
}
}
}
pragma(inline, true)
package (tanya.memory) void copyBackward(const void[] source, void[] target)
pure nothrow @system @nogc
{
asm pure nothrow @nogc
{
naked;
// Save the registers should be restored.
mov R8, RSI;
mov R9, RDI;
}
// Prepare the registers for movsb.
version (Windows) asm pure nothrow @nogc
{
// RDX - source.
// RCX - target.
mov RAX, [ RCX + 8 ];
mov R10, [ RDX + 8 ];
mov RCX, [ RDX ];
lea RDI, [ RAX + RCX - 1 ];
lea RSI, [ R10 + RCX - 1 ];
}
else asm pure nothrow @nogc
{
// RDX - source length.
// RCX - source data.
// RDI - target length
// RSI - target data.
lea RDI, [ RSI + RDX - 1 ];
lea RSI, [ RCX + RDX - 1 ];
mov RCX, RDX;
}
asm pure nothrow @nogc
{
std; // Set the direction flag.
rep;
movsb;
cld; // Clear the direction flag.
// Restore registers.
mov RDI, R9;
mov RSI, R8;
ret;
}
}
pragma(inline, true)
package (tanya.memory) int cmp(const void[] r1, const void[] r2)
pure nothrow @system @nogc
{
asm pure nothrow @nogc
{
naked;
// RDI and RSI should be preserved.
mov R9, RDI;
mov R8, RSI;
}
// Set the registers for cmpsb/cmpsq.
version (Windows) asm pure nothrow @nogc
{
// RDX - r1.
// RCX - r2.
mov RDI, [ RCX + 8 ];
mov RSI, [ RDX + 8 ];
mov RDX, [ RDX ];
mov RCX, [ RCX ];
}
else asm pure nothrow @nogc
{
// RDX - r1 length.
// RCX - r1 data.
// RDI - r2 length
// RSI - r2 data.
mov RSI, RCX;
mov RCX, RDI;
mov RDI, R8;
}
asm pure nothrow @nogc
{
// Compare the lengths.
cmp RDX, RCX;
jl less;
jg greater;
// Check if we're aligned.
cmp RDX, 0x08;
jc aligned_1;
test EDI, 0x07;
jz aligned_8;
naligned:
cmpsb;
jl less;
jg greater;
dec RDX;
test EDI, 0x07;
jnz naligned;
aligned_8:
mov RCX, RDX;
shr RCX, 0x03;
repe;
cmpsq;
jl less;
jg greater;
and EDX, 0x07;
jz equal;
aligned_1: // Compare the remaining bytes.
mov RCX, RDX;
repe;
cmpsb;
jl less;
jg greater;
equal:
xor RAX, RAX; // Return 0.
jmp end;
greater:
mov RAX, 1;
jmp end;
less:
mov RAX, -1;
jmp end;
end: // Restore registers.
mov RSI, R8;
mov RDI, R9;
ret;
}
}

28
source/tanya/memory/mmappool.d
View File

@ -14,9 +14,9 @@
*/
module tanya.memory.mmappool;
import core.stdc.string;
import std.algorithm.comparison;
import tanya.memory.allocator;
import tanya.memory.op;
version (Posix)
{
@ -24,7 +24,7 @@ version (Posix)
MAP_ANON, MAP_FAILED;
import core.sys.posix.unistd;
extern (C)
extern(C)
private void* mmap(void* addr,
size_t len,
int prot,
@ -32,7 +32,7 @@ version (Posix)
int fd,
off_t offset) pure nothrow @system @nogc;
extern (C)
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
@ -56,11 +56,11 @@ else version (Windows)
{
import core.sys.windows.winbase : GetSystemInfo, SYSTEM_INFO;
extern (Windows)
extern(Windows)
private void* VirtualAlloc(void*, size_t, uint, uint)
pure nothrow @system @nogc;
extern (Windows)
extern(Windows)
private int VirtualFree(void* addr, size_t len, uint)
pure nothrow @system @nogc;
@ -89,6 +89,7 @@ else version (Windows)
* block as free and only if all blocks in the region are free, the complete
* region is deallocated.
*
* <pre>
* ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
* | | | | | || | | |
* | |prev <----------- | || | | |
@ -100,6 +101,7 @@ else version (Windows)
* | N | -----------> next| || N | | |
* | | | | | || | | |
* ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
* </pre>
*/
final class MmapPool : Allocator
{
@ -345,10 +347,10 @@ final class MmapPool : Allocator
|| dataSize < size
|| block1.next.size + BlockEntry.sizeof < delta)
{
/* * It is the last block in the region
* * The next block is too small
* * The next block isn't free
* * Requested size is too large
/* - It is the last block in the region
* - The next block isn't free
* - The next block is too small
* - Requested size is too large
*/
return false;
}
@ -363,8 +365,8 @@ final class MmapPool : Allocator
{
block1.next.next.prev = block2;
}
// block1.next and block2 can overlap.
memmove(cast(void*) block2, cast(void*) block1.next, BlockEntry.sizeof);
copyBackward((cast(void*) block1.next)[0 .. BlockEntry.sizeof],
(cast(void*) block2)[0 .. BlockEntry.sizeof]);
block1.next = block2;
}
else
@ -436,7 +438,7 @@ final class MmapPool : Allocator
}
if (p !is null)
{
memcpy(reallocP.ptr, p.ptr, min(p.length, size));
copy(p[0 .. min(p.length, size)], reallocP);
deallocate(p);
}
p = reallocP;
@ -500,7 +502,7 @@ final class MmapPool : Allocator
void* data = initializeRegion(instanceSize, head, pageSize);
if (data !is null)
{
memcpy(data, typeid(MmapPool).initializer.ptr, instanceSize);
copy(typeid(MmapPool).initializer, data[0 .. instanceSize]);
instance_ = cast(shared MmapPool) data;
instance_.head = head;
instance_.pageSize = pageSize;

265
source/tanya/memory/op.d
View File

@ -14,9 +14,22 @@
*/
module tanya.memory.op;
version (D_InlineAsm_X86_64)
version (TanyaNative)
{
static import tanya.memory.arch.x86_64;
extern private void fillMemory(void[], size_t) pure nothrow @system @nogc;
extern private void copyMemory(const void[], void[])
pure nothrow @system @nogc;
extern private void moveMemory(const void[], void[])
pure nothrow @system @nogc;
extern private int cmpMemory(const void[], const void[])
pure nothrow @system @nogc;
}
else
{
import core.stdc.string;
}
private enum alignMask = size_t.sizeof - 1;
@ -45,46 +58,13 @@ in
}
body
{
version (D_InlineAsm_X86_64)
version (TanyaNative)
{
tanya.memory.arch.x86_64.copy(source, target);
copyMemory(source, target);
}
else // Naive implementation.
else
{
auto source1 = cast(const(ubyte)*) source;
auto target1 = cast(ubyte*) target;
auto count = source.length;
// Check if the pointers are aligned or at least can be aligned
// properly.
ushort naligned = (cast(size_t) source.ptr) & alignMask;
if (naligned == ((cast(size_t) target.ptr) & alignMask))
{
// Align the pointers if possible.
if (naligned != 0)
{
count -= naligned;
while (naligned--)
{
*target1++ = *source1++;
}
}
// Copy size_t.sizeof bytes at once.
auto longSource = cast(const(size_t)*) source1;
auto longTarget = cast(size_t*) target1;
for (; count >= size_t.sizeof; count -= size_t.sizeof)
{
*longTarget++ = *longSource++;
}
// Adjust the original pointers.
source1 = cast(const(ubyte)*) longSource;
target1 = cast(ubyte*) longTarget;
}
// Copy the remaining bytes by one.
while (count--)
{
*target1++ = *source1++;
}
memcpy(target.ptr, source.ptr, source.length);
}
}
@ -120,58 +100,34 @@ private pure nothrow @safe @nogc unittest
/*
* size_t value each of which bytes is set to `Byte`.
*/
package template FilledBytes(ubyte Byte, ubyte I = 0)
private template filledBytes(ubyte Byte, ubyte I = 0)
{
static if (I == size_t.sizeof)
{
enum size_t FilledBytes = Byte;
enum size_t filledBytes = Byte;
}
else
{
enum size_t FilledBytes = (FilledBytes!(Byte, I + 1) << 8) | Byte;
enum size_t filledBytes = (filledBytes!(Byte, I + 1) << 8) | Byte;
}
}
/**
* Fills $(D_PARAM memory) with single $(D_PARAM Byte)s.
* Fills $(D_PARAM memory) with the single byte $(D_PARAM c).
*
* Param:
* Byte = The value to fill $(D_PARAM memory) with.
* c = The value to fill $(D_PARAM memory) with.
* memory = Memory block.
*/
void fill(ubyte Byte = 0)(void[] memory) @trusted
void fill(ubyte c = 0)(void[] memory) @trusted
{
version (D_InlineAsm_X86_64)
version (TanyaNative)
{
tanya.memory.arch.x86_64.fill!Byte(memory);
fillMemory(memory, filledBytes!c);
}
else // Naive implementation.
else
{
auto n = memory.length;
ubyte* vp = cast(ubyte*) memory.ptr;
// Align.
while (((cast(size_t) vp) & alignMask) != 0)
{
*vp++ = Byte;
--n;
}
// Set size_t.sizeof bytes at ones.
auto sp = cast(size_t*) vp;
while (n / size_t.sizeof > 0)
{
*sp++ = FilledBytes!Byte;
n -= size_t.sizeof;
}
// Write the remaining bytes.
vp = cast(ubyte*) sp;
while (n--)
{
*vp = Byte;
++vp;
}
memset(memory.ptr, c, memory.length);
}
}
@ -240,41 +196,13 @@ in
}
body
{
version (D_InlineAsm_X86_64)
version (TanyaNative)
{
tanya.memory.arch.x86_64.copyBackward(source, target);
moveMemory(source, target);
}
else // Naive implementation.
else
{
auto count = source.length;
// Try to align the pointers if possible.
if (((cast(size_t) source.ptr) & alignMask) == ((cast(size_t) target.ptr) & alignMask))
{
while (((cast(size_t) (source.ptr + count)) & alignMask) != 0)
{
if (!count--)
{
return;
}
(cast(ubyte[]) target)[count]
= (cast(const(ubyte)[]) source)[count];
}
}
// Write as long we're aligned.
for (; count >= size_t.sizeof; count -= size_t.sizeof)
{
*(cast(size_t*) (target.ptr + count - size_t.sizeof))
= *(cast(const(size_t)*) (source.ptr + count - size_t.sizeof));
}
// Write the remaining bytes.
while (count--)
{
(cast(ubyte[]) target)[count]
= (cast(const(ubyte)[]) source)[count];
}
memmove(target.ptr, source.ptr, source.length);
}
}
@ -316,60 +244,17 @@ private nothrow @safe @nogc unittest
*/
int cmp(const void[] r1, const void[] r2) pure nothrow @trusted @nogc
{
version (D_InlineAsm_X86_64)
version (TanyaNative)
{
return tanya.memory.arch.x86_64.cmp(r1, r2);
return cmpMemory(r1, r2);
}
else // Naive implementation.
else
{
if (r1.length > r2.length)
{
return 1;
}
else if (r1.length < r2.length)
{
return -1;
}
auto p1 = cast(const(ubyte)*) r1;
auto p2 = cast(const(ubyte)*) r2;
auto count = r1.length;
// Check if the pointers are aligned or at least can be aligned
// properly.
if (((cast(size_t) p1) & alignMask) == ((cast(size_t) p2) & alignMask))
{
// Align the pointers if possible.
for (; ((cast(size_t) p1) & alignMask) != 0; ++p1, ++p2, --count)
{
if (*p1 != *p2)
{
return *p1 - *p2;
}
}
// Compare size_t.sizeof bytes at once.
for (; count >= size_t.sizeof; count -= size_t.sizeof)
{
if (*(cast(const(size_t)*) p1) > *(cast(const(size_t)*) p2))
{
return 1;
}
else if (*(cast(const(size_t)*) p1) < *(cast(const(size_t)*) p2))
{
return -1;
}
p1 += size_t.sizeof;
p2 += size_t.sizeof;
}
}
// Compare the remaining bytes by one.
for (; count--; ++p1, ++p2)
{
if (*p1 != *p2)
{
return *p1 - *p2;
}
}
return 0;
return r1.length < r2.length ? -1 : memcmp(r1.ptr, r2.ptr, r1.length);
}
}
@ -402,3 +287,79 @@ private pure nothrow @safe @nogc unittest
assert(cmp(r1[0 .. $ - 1], r2[0 .. $ - 1]) == 0);
assert(cmp(r1[0 .. 8], r2[0 .. 8]) == 0);
}
/**
* Finds the first occurrence of $(D_PARAM needle) in $(D_PARAM haystack) if
* any.
*
* Params:
* haystack = Memory block.
* needle = A byte.
*
* Returns: The subrange of $(D_PARAM haystack) whose first element is the
* first occurrence of $(D_PARAM needle). If $(D_PARAM needle)
* couldn't be found, an empty `inout void[]` is returned.
*/
inout(void[]) find(return inout void[] haystack, const ubyte needle)
pure nothrow @trusted @nogc
{
auto length = haystack.length;
const size_t needleWord = size_t.max * needle;
enum size_t highBits = filledBytes!(0x01, 0);
enum size_t mask = filledBytes!(0x80, 0);
// Align
auto bytes = cast(inout(ubyte)*) haystack;
while (length > 0 && ((cast(size_t) bytes) & 3) != 0)
{
if (*bytes == needle)
{
return bytes[0 .. length];
}
bytes++;
length--;
}
// Check if some of the words has the needle
auto words = cast(inout(size_t)*) bytes;
while (length >= size_t.sizeof)
{
if (((*words ^ needleWord) - highBits) & (~*words) & mask)
{
break;
}
words++;
length -= size_t.sizeof;
}
// Find the exact needle position in the word
bytes = cast(inout(ubyte)*) words;
while (length > 0)
{
if (*bytes == needle)
{
return bytes[0 .. length];
}
bytes++;
length--;
}
return haystack[$ .. $];
}
///
pure nothrow @safe @nogc unittest
{
const ubyte[9] haystack = ['a', 'b', 'c', 'd', 'e', 'f', 'b', 'g', 'h'];
assert(find(haystack, 'a') == haystack[]);
assert(find(haystack, 'b') == haystack[1 .. $]);
assert(find(haystack, 'c') == haystack[2 .. $]);
assert(find(haystack, 'd') == haystack[3 .. $]);
assert(find(haystack, 'e') == haystack[4 .. $]);
assert(find(haystack, 'f') == haystack[5 .. $]);
assert(find(haystack, 'h') == haystack[8 .. $]);
assert(find(haystack, 'i').length == 0);
assert(find(null, 'a').length == 0);
}

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

@ -18,9 +18,9 @@ import core.exception;
import std.algorithm.iteration;
import std.algorithm.mutation;
import std.conv;
import std.range;
public import tanya.memory.allocator;
import tanya.memory.mmappool;
import tanya.range.primitive;
import tanya.meta.trait;
/**
@ -72,7 +72,7 @@ mixin template DefaultAllocator()
return allocator_;
}
/// Ditto.
/// ditto
@property shared(Allocator) allocator() const pure nothrow @trusted @nogc
out (allocator)
{

14
source/tanya/memory/smartref.d
View File

@ -21,9 +21,9 @@ import core.exception;
import std.algorithm.comparison;
import std.algorithm.mutation;
import std.conv;
import std.range;
import tanya.memory;
import tanya.meta.trait;
import tanya.range.primitive;
private template Payload(T)
{
@ -127,7 +127,7 @@ struct RefCounted(T)
this.storage.payload = value;
}
/// Ditto.
/// ditto
this(shared Allocator allocator)
in
{
@ -209,7 +209,7 @@ struct RefCounted(T)
assert(*rc == 7);
}
/// Ditto.
/// ditto
ref typeof(this) opAssign(typeof(null))
{
if (this.storage is null)
@ -237,7 +237,7 @@ struct RefCounted(T)
assert(!rc.isInitialized);
}
/// Ditto.
/// ditto
ref typeof(this) opAssign(typeof(this) rhs)
{
swap(this.allocator_, rhs.allocator_);
@ -660,7 +660,7 @@ struct Unique(T)
this.payload = value;
}
/// Ditto.
/// ditto
this(shared Allocator allocator)
in
{
@ -706,14 +706,14 @@ struct Unique(T)
return this;
}
/// Ditto.
/// ditto
ref typeof(this) opAssign(typeof(null))
{
allocator.dispose(this.payload);
return this;
}
/// Ditto.
/// ditto
ref typeof(this) opAssign(typeof(this) rhs)
{
swap(this.allocator_, rhs.allocator_);

23
source/tanya/meta/metafunction.d
View File

@ -765,7 +765,7 @@ import tanya.meta.transform;
*/
alias Alias(alias T) = T;
/// Ditto.
/// ditto
alias Alias(T) = T;
///
@ -926,7 +926,7 @@ template staticIndexOf(T, L...)
enum ptrdiff_t staticIndexOf = indexOf!(0, AliasSeq!(T, L));
}
/// Ditto.
/// ditto
template staticIndexOf(alias T, L...)
{
enum ptrdiff_t staticIndexOf = indexOf!(0, AliasSeq!(T, L));
@ -1094,9 +1094,6 @@ if (isTemplate!cmp)
}
}
deprecated("Use tanya.meta.metafunction.isSorted instead")
alias staticIsSorted = isSorted;
///
pure nothrow @safe @nogc unittest
{
@ -1233,19 +1230,19 @@ template Replace(T, U, L...)
alias Replace = ReplaceOne!(T, U, L);
}
/// Ditto.
/// ditto
template Replace(alias T, U, L...)
{
alias Replace = ReplaceOne!(T, U, L);
}
/// Ditto.
/// ditto
template Replace(T, alias U, L...)
{
alias Replace = ReplaceOne!(T, U, L);
}
/// Ditto.
/// ditto
template Replace(alias T, alias U, L...)
{
alias Replace = ReplaceOne!(T, U, L);
@ -1296,19 +1293,19 @@ template ReplaceAll(T, U, L...)
alias ReplaceAll = ReplaceAllImpl!(T, U, L);
}
/// Ditto.
/// ditto
template ReplaceAll(alias T, U, L...)
{
alias ReplaceAll = ReplaceAllImpl!(T, U, L);
}
/// Ditto.
/// ditto
template ReplaceAll(T, alias U, L...)
{
alias ReplaceAll = ReplaceAllImpl!(T, U, L);
}
/// Ditto.
/// ditto
template ReplaceAll(alias T, alias U, L...)
{
alias ReplaceAll = ReplaceAllImpl!(T, U, L);
@ -1550,7 +1547,7 @@ template Erase(T, L...)
alias Erase = EraseOne!(T, L);
}
/// Ditto.
/// ditto
template Erase(alias T, L...)
{
alias Erase = EraseOne!(T, L);
@ -1593,7 +1590,7 @@ template EraseAll(T, L...)
alias EraseAll = EraseAllImpl!(T, L);
}
/// Ditto.
/// ditto
template EraseAll(alias T, L...)
{
alias EraseAll = EraseAllImpl!(T, L);

55
source/tanya/meta/trait.d
View File

@ -964,41 +964,6 @@ pure nothrow @safe @nogc unittest
static assert(!isAggregateType!void);
}
/**
* Determines whether $(D_PARAM T) is some type.
*
* Params:
* T = A symbol.
*
* Returns: $(D_KEYWORD true) if $(D_PARAM T) is a type,
* $(D_KEYWORD false) otherwise.
*/
deprecated("Use isTypeTuple instead")
enum bool isType(alias T) = is(T);
/// Ditto.
deprecated("Use isTypeTuple instead")
enum bool isType(T) = true;
///
pure nothrow @safe @nogc unittest
{
class C;
enum E : bool;
union U;
struct T();
static assert(isType!C);
static assert(isType!E);
static assert(isType!U);
static assert(isType!void);
static assert(isType!int);
static assert(!isType!T);
static assert(isType!(T!()));
static assert(!isType!5);
static assert(!isType!(tanya.meta.trait));
}
/**
* Determines whether $(D_PARAM T) is a narrow string, i.e. consists of
* $(D_KEYWORD char) or $(D_KEYWORD wchar).
@ -1282,6 +1247,9 @@ pure nothrow @safe @nogc unittest
static assert(!isAbstractClass!E);
}
private enum bool isType(alias T) = is(T);
private enum bool isType(T) = true;
/**
* Determines whether $(D_PARAM Args) contains only types.
*
@ -1300,6 +1268,21 @@ pure nothrow @safe @nogc unittest
static assert(isTypeTuple!());
static assert(!isTypeTuple!(int, 8, Object));
static assert(!isTypeTuple!(5, 8, 2));
class C;
enum E : bool;
union U;
struct T();
static assert(isTypeTuple!C);
static assert(isTypeTuple!E);
static assert(isTypeTuple!U);
static assert(isTypeTuple!void);
static assert(isTypeTuple!int);
static assert(!isTypeTuple!T);
static assert(isTypeTuple!(T!()));
static assert(!isTypeTuple!5);
static assert(!isTypeTuple!(tanya.meta.trait));
}
/**
@ -2982,7 +2965,7 @@ template getUDAs(alias symbol, alias attr)
{
alias FindUDA = AliasSeq!();
}
else static if ((isType!attr && is(TypeOf!(T[0]) == attr))
else static if ((isTypeTuple!attr && is(TypeOf!(T[0]) == attr))
|| (is(typeof(T[0] == attr)) && (T[0] == attr))
|| isInstanceOf!(attr, TypeOf!(T[0])))
{

2
source/tanya/meta/transform.d
View File

@ -721,7 +721,7 @@ pure nothrow @safe @nogc unittest
*/
alias TypeOf(T) = T;
/// Ditto.
/// ditto
template TypeOf(alias T)
if (isExpressions!T || isTemplate!T)
{

2
source/tanya/net/inet.d
View File

@ -15,9 +15,9 @@
module tanya.net.inet;
import std.math;
import std.range.primitives;
import tanya.meta.trait;
import tanya.meta.transform;
import tanya.range.primitive;
/**
* Represents an unsigned integer as an $(D_KEYWORD ubyte) range.

9
source/tanya/net/uri.d
View File

@ -14,8 +14,7 @@
*/
module tanya.net.uri;
import std.ascii : isAlphaNum, isDigit;
import std.uni : isAlpha, isNumber;
import tanya.encoding.ascii;
import tanya.memory;
/**
@ -199,8 +198,8 @@ struct URL
this.pass = source[start + i + 1 .. pos];
}
}
else if (!c.isAlpha &&
!c.isNumber &&
else if (!c.isAlpha() &&
!c.isDigit() &&
c != '!' &&
c != ';' &&
c != '=' &&
@ -554,7 +553,7 @@ if (T == "scheme"
return mixin("ret." ~ T);
}
/// Ditto.
/// ditto
URL parseURL(const char[] source) @nogc
{
return URL(source);

457
source/tanya/network/socket.d
View File

@ -44,12 +44,52 @@ version (Posix)
}
else version (Windows)
{
import core.sys.windows.winbase : GetModuleHandle,
GetProcAddress,
ERROR_IO_PENDING,
ERROR_IO_INCOMPLETE;
import core.sys.windows.winsock2 : sockaddr,
freeaddrinfo,
getaddrinfo,
SD_RECEIVE,
SD_SEND,
SD_BOTH,
MSG_OOB,
MSG_PEEK,
MSG_DONTROUTE,
socklen_t,
SOCKADDR,
SOCKADDR_STORAGE,
addrinfo,
sockaddr_in,
sockaddr_in6,
shutdown,
closesocket,
listen,
socket,
bind,
accept,
WSAGetLastError,
recv,
send,
getsockopt,
setsockopt,
ioctlsocket,
FIONBIO,
SOL_SOCKET,
SO_TYPE;
import tanya.async.iocp;
import core.sys.windows.basetyps;
import core.sys.windows.mswsock;
import core.sys.windows.winbase;
import core.sys.windows.windef;
import core.sys.windows.winsock2;
import tanya.sys.windows.error : EWOULDBLOCK = WSAEWOULDBLOCK,
ECONNABORTED = WSAECONNABORTED,
ENOBUFS = WSAENOBUFS,
EOPNOTSUPP = WSAEOPNOTSUPP,
EPROTONOSUPPORT = WSAEPROTONOSUPPORT,
EPROTOTYPE = WSAEPROTOTYPE,
ETIMEDOUT = WSAETIMEDOUT,
ESOCKTNOSUPPORT = WSAESOCKTNOSUPPORT;
import tanya.sys.windows.def;
public import tanya.sys.windows.winbase;
public import tanya.sys.windows.winsock2;
enum SocketType : size_t
{
@ -58,177 +98,6 @@ else version (Windows)
private alias LingerField = ushort;
enum : uint
{
IOC_UNIX = 0x00000000,
IOC_WS2 = 0x08000000,
IOC_PROTOCOL = 0x10000000,
IOC_VOID = 0x20000000, // No parameters.
IOC_OUT = 0x40000000, // Copy parameters back.
IOC_IN = 0x80000000, // Copy parameters into.
IOC_VENDOR = 0x18000000,
IOC_INOUT = (IOC_IN | IOC_OUT), // Copy parameter into and get back.
}
template _WSAIO(int x, int y)
{
enum _WSAIO = IOC_VOID | x | y;
}
template _WSAIOR(int x, int y)
{
enum _WSAIOR = IOC_OUT | x | y;
}
template _WSAIOW(int x, int y)
{
enum _WSAIOW = IOC_IN | x | y;
}
template _WSAIORW(int x, int y)
{
enum _WSAIORW = IOC_INOUT | x | y;
}
alias SIO_ASSOCIATE_HANDLE = _WSAIOW!(IOC_WS2, 1);
alias SIO_ENABLE_CIRCULAR_QUEUEING = _WSAIO!(IOC_WS2, 2);
alias SIO_FIND_ROUTE = _WSAIOR!(IOC_WS2, 3);
alias SIO_FLUSH = _WSAIO!(IOC_WS2, 4);
alias SIO_GET_BROADCAST_ADDRESS = _WSAIOR!(IOC_WS2, 5);
alias SIO_GET_EXTENSION_FUNCTION_POINTER = _WSAIORW!(IOC_WS2, 6);
alias SIO_GET_QOS = _WSAIORW!(IOC_WS2, 7);
alias SIO_GET_GROUP_QOS = _WSAIORW!(IOC_WS2, 8);
alias SIO_MULTIPOINT_LOOPBACK = _WSAIOW!(IOC_WS2, 9);
alias SIO_MULTICAST_SCOPE = _WSAIOW!(IOC_WS2, 10);
alias SIO_SET_QOS = _WSAIOW!(IOC_WS2, 11);
alias SIO_SET_GROUP_QOS = _WSAIOW!(IOC_WS2, 12);
alias SIO_TRANSLATE_HANDLE = _WSAIORW!(IOC_WS2, 13);
alias SIO_ROUTING_INTERFACE_QUERY = _WSAIORW!(IOC_WS2, 20);
alias SIO_ROUTING_INTERFACE_CHANGE = _WSAIOW!(IOC_WS2, 21);
alias SIO_ADDRESS_LIST_QUERY = _WSAIOR!(IOC_WS2, 22);
alias SIO_ADDRESS_LIST_CHANGE = _WSAIO!(IOC_WS2, 23);
alias SIO_QUERY_TARGET_PNP_HANDLE = _WSAIOR!(IOC_WS2, 24);
alias SIO_NSP_NOTIFY_CHANGE = _WSAIOW!(IOC_WS2, 25);
private alias GROUP = uint;
enum
{
WSA_FLAG_OVERLAPPED = 0x01,
MAX_PROTOCOL_CHAIN = 7,
WSAPROTOCOL_LEN = 255,
}
struct WSAPROTOCOLCHAIN
{
int ChainLen;
DWORD[MAX_PROTOCOL_CHAIN] ChainEntries;
}
alias LPWSAPROTOCOLCHAIN = WSAPROTOCOLCHAIN*;
struct WSAPROTOCOL_INFO
{
DWORD dwServiceFlags1;
DWORD dwServiceFlags2;
DWORD dwServiceFlags3;
DWORD dwServiceFlags4;
DWORD dwProviderFlags;
GUID ProviderId;
DWORD dwCatalogEntryId;
WSAPROTOCOLCHAIN ProtocolChain;
int iVersion;
int iAddressFamily;
int iMaxSockAddr;
int iMinSockAddr;
int iSocketType;
int iProtocol;
int iProtocolMaxOffset;
int iNetworkByteOrder;
int iSecurityScheme;
DWORD dwMessageSize;
DWORD dwProviderReserved;
TCHAR[WSAPROTOCOL_LEN + 1] szProtocol;
}
alias LPWSAPROTOCOL_INFO = WSAPROTOCOL_INFO*;
extern (Windows) @nogc nothrow
{
private SOCKET WSASocketW(int af,
int type,
int protocol,
LPWSAPROTOCOL_INFO lpProtocolInfo,
GROUP g,
DWORD dwFlags);
int WSARecv(SOCKET s,
LPWSABUF lpBuffers,
DWORD dwBufferCount,
LPDWORD lpNumberOfBytesRecvd,
LPDWORD lpFlags,
LPOVERLAPPED lpOverlapped,
LPWSAOVERLAPPED_COMPLETION_ROUTINE lpCompletionRoutine);
int WSASend(SOCKET s,
LPWSABUF lpBuffers,
DWORD dwBufferCount,
LPDWORD lpNumberOfBytesRecvd,
DWORD lpFlags,
LPOVERLAPPED lpOverlapped,
LPWSAOVERLAPPED_COMPLETION_ROUTINE lpCompletionRoutine);
int WSAIoctl(SOCKET s,
uint dwIoControlCode,
void* lpvInBuffer,
uint cbInBuffer,
void* lpvOutBuffer,
uint cbOutBuffer,
uint* lpcbBytesReturned,
LPWSAOVERLAPPED lpOverlapped,
LPWSAOVERLAPPED_COMPLETION_ROUTINE lpCompletionRoutine);
alias LPFN_ACCEPTEX = BOOL function(SOCKET,
SOCKET,
PVOID,
DWORD,
DWORD,
DWORD,
LPDWORD,
LPOVERLAPPED);
}
alias WSASocket = WSASocketW;
alias LPFN_GETACCEPTEXSOCKADDRS = VOID function(PVOID,
DWORD,
DWORD,
DWORD,
SOCKADDR**,
LPINT,
SOCKADDR**,
LPINT);
const GUID WSAID_GETACCEPTEXSOCKADDRS = {
0xb5367df2, 0xcbac, 0x11cf,
[ 0x95, 0xca, 0x00, 0x80, 0x5f, 0x48, 0xa1, 0x92 ],
};
struct WSABUF
{
ULONG len;
CHAR* buf;
}
alias WSABUF* LPWSABUF;
struct WSAOVERLAPPED
{
ULONG_PTR Internal;
ULONG_PTR InternalHigh;
union
{
struct
{
DWORD Offset;
DWORD OffsetHigh;
}
PVOID Pointer;
}
HANDLE hEvent;
}
alias LPWSAOVERLAPPED = WSAOVERLAPPED*;
enum SO_UPDATE_ACCEPT_CONTEXT = 0x700B;
enum OverlappedSocketEvent
{
accept = 1,
@ -241,13 +110,38 @@ else version (Windows)
private WSABUF buffer;
}
/**
* Socket returned if a connection has been established.
*
* Note: Available only on Windows.
*/
class OverlappedConnectedSocket : ConnectedSocket
{
/**
* Create a socket.
*
* Params:
* handle = Socket handle.
* af = Address family.
*/
this(SocketType handle, AddressFamily af) @nogc
{
super(handle, af);
}
/**
* Begins to asynchronously receive data from a connected socket.
*
* Params:
* buffer = Storage location for the received data.
* flags = Flags.
* overlapped = Unique operation identifier.
*
* Returns: $(D_KEYWORD true) if the operation could be finished synchronously.
* $(D_KEYWORD false) otherwise.
*
* Throws: $(D_PSYMBOL SocketException) if unable to receive.
*/
bool beginReceive(ubyte[] buffer,
SocketState overlapped,
Flags flags = Flags(Flag.none)) @nogc @trusted
@ -260,12 +154,12 @@ else version (Windows)
overlapped.buffer.buf = cast(char*) buffer.ptr;
auto result = WSARecv(handle_,
&overlapped.buffer,
cast(WSABUF*) &overlapped.buffer,
1u,
NULL,
null,
&receiveFlags,
&overlapped.overlapped,
NULL);
null);
if (result == socketError && !wouldHaveBlocked)
{
@ -274,6 +168,18 @@ else version (Windows)
return result == 0;
}
/**
* Ends a pending asynchronous read.
*
* Params:
* overlapped = Unique operation identifier.
*
* Returns: Number of bytes received.
*
* Throws: $(D_PSYMBOL SocketException) if unable to receive.
*
* Postcondition: $(D_INLINECODE result >= 0).
*/
int endReceive(SocketState overlapped) @nogc @trusted
out (count)
{
@ -298,6 +204,19 @@ else version (Windows)
return lpNumber;
}
/**
* Sends data asynchronously to a connected socket.
*
* Params:
* buffer = Data to be sent.
* flags = Flags.
* overlapped = Unique operation identifier.
*
* Returns: $(D_KEYWORD true) if the operation could be finished synchronously.
* $(D_KEYWORD false) otherwise.
*
* Throws: $(D_PSYMBOL SocketException) if unable to send.
*/
bool beginSend(ubyte[] buffer,
SocketState overlapped,
Flags flags = Flags(Flag.none)) @nogc @trusted
@ -310,10 +229,10 @@ else version (Windows)
auto result = WSASend(handle_,
&overlapped.buffer,
1u,
NULL,
null,
cast(DWORD) flags,
&overlapped.overlapped,
NULL);
null);
if (result == socketError && !wouldHaveBlocked)
{
@ -323,6 +242,18 @@ else version (Windows)
return result == 0;
}
/**
* Ends a pending asynchronous send.
*
* Params:
* overlapped = Unique operation identifier.
*
* Returns: Number of bytes sent.
*
* Throws: $(D_PSYMBOL SocketException) if unable to receive.
*
* Postcondition: $(D_INLINECODE result >= 0).
*/
int endSend(SocketState overlapped) @nogc @trusted
out (count)
{
@ -344,11 +275,22 @@ else version (Windows)
}
}
/**
* Windows stream socket overlapped I/O.
*/
class OverlappedStreamSocket : StreamSocket
{
// Accept extension function pointer.
package LPFN_ACCEPTEX acceptExtension;
/**
* Create a socket.
*
* Params:
* af = Address family.
*
* Throws: $(D_PSYMBOL SocketException) on errors.
*/
this(AddressFamily af) @nogc @trusted
{
super(af);
@ -368,8 +310,8 @@ else version (Windows)
&acceptExtension,
acceptExtension.sizeof,
&dwBytes,
NULL,
NULL);
null,
null);
if (!result == socketError)
{
throw make!SocketException(defaultAllocator,
@ -377,6 +319,17 @@ else version (Windows)
}
}
/**
* Begins an asynchronous operation to accept an incoming connection attempt.
*
* Params:
* overlapped = Unique operation identifier.
*
* Returns: $(D_KEYWORD true) if the operation could be finished synchronously.
* $(D_KEYWORD false) otherwise.
*
* Throws: $(D_PSYMBOL SocketException) on accept errors.
*/
bool beginAccept(SocketState overlapped) @nogc @trusted
{
auto socket = cast(SocketType) socket(addressFamily, 1, 0);
@ -412,6 +365,17 @@ else version (Windows)
return result == TRUE;
}
/**
* Asynchronously accepts an incoming connection attempt and creates a
* new socket to handle remote host communication.
*
* Params:
* overlapped = Unique operation identifier.
*
* Returns: Connected socket.
*
* Throws: $(D_PSYMBOL SocketException) if unable to accept.
*/
OverlappedConnectedSocket endAccept(SocketState overlapped)
@nogc @trusted
{
@ -433,133 +397,6 @@ else version (Windows)
}
}
}
else version (D_Ddoc)
{
/// Native socket representation type.
enum SocketType;
/**
* Socket returned if a connection has been established.
*
* Note: Available only on Windows.
*/
class OverlappedConnectedSocket : ConnectedSocket
{
/**
* Create a socket.
*
* Params:
* handle = Socket handle.
* af = Address family.
*/
this(SocketType handle, AddressFamily af) @nogc;
/**
* Begins to asynchronously receive data from a connected socket.
*
* Params:
* buffer = Storage location for the received data.
* flags = Flags.
* overlapped = Unique operation identifier.
*
* Returns: $(D_KEYWORD true) if the operation could be finished synchronously.
* $(D_KEYWORD false) otherwise.
*
* Throws: $(D_PSYMBOL SocketException) if unable to receive.
*/
bool beginReceive(ubyte[] buffer,
SocketState overlapped,
Flags flags = Flags(Flag.none)) @nogc @trusted;
/**
* Ends a pending asynchronous read.
*
* Params:
* overlapped = Unique operation identifier.
*
* Returns: Number of bytes received.
*
* Throws: $(D_PSYMBOL SocketException) if unable to receive.
*
* Postcondition: $(D_INLINECODE result >= 0).
*/
int endReceive(SocketState overlapped) @nogc @trusted;
/**
* Sends data asynchronously to a connected socket.
*
* Params:
* buffer = Data to be sent.
* flags = Flags.
* overlapped = Unique operation identifier.
*
* Returns: $(D_KEYWORD true) if the operation could be finished synchronously.
* $(D_KEYWORD false) otherwise.
*
* Throws: $(D_PSYMBOL SocketException) if unable to send.
*/
bool beginSend(ubyte[] buffer,
SocketState overlapped,
Flags flags = Flags(Flag.none)) @nogc @trusted;
/**
* Ends a pending asynchronous send.
*
* Params:
* overlapped = Unique operation identifier.
*
* Returns: Number of bytes sent.
*
* Throws: $(D_PSYMBOL SocketException) if unable to receive.
*
* Postcondition: $(D_INLINECODE result >= 0).
*/
int endSend(SocketState overlapped) @nogc @trusted;
}
/**
* Windows stream socket overlapped I/O.
*/
class OverlappedStreamSocket : StreamSocket
{
/**
* Create a socket.
*
* Params:
* af = Address family.
*
* Throws: $(D_PSYMBOL SocketException) on errors.
*/
this(AddressFamily af) @nogc @trusted;
/**
* Begins an asynchronous operation to accept an incoming connection attempt.
*
* Params:
* overlapped = Unique operation identifier.
*
* Returns: $(D_KEYWORD true) if the operation could be finished synchronously.
* $(D_KEYWORD false) otherwise.
*
* Throws: $(D_PSYMBOL SocketException) on accept errors.
*/
bool beginAccept(SocketState overlapped) @nogc @trusted;
/**
* Asynchronously accepts an incoming connection attempt and creates a
* new socket to handle remote host communication.
*
* Params:
* overlapped = Unique operation identifier.
*
* Returns: Connected socket.
*
* Throws: $(D_PSYMBOL SocketException) if unable to accept.
*/
OverlappedConnectedSocket endAccept(SocketState overlapped)
@nogc @trusted;
}
}
/**
* Socket option that specifies what should happen when the socket that

6
source/tanya/os/error.d
View File

@ -234,7 +234,7 @@ struct ErrorCode
return this.value_;
}
/// Ditto.
/// ditto
ErrorNo opCast(T : int)() const
{
return this.value_;
@ -264,7 +264,7 @@ struct ErrorCode
return this;
}
/// Ditto.
/// ditto
ref ErrorCode opAssign()(auto ref const ErrorCode that)
pure nothrow @safe @nogc
{
@ -305,7 +305,7 @@ struct ErrorCode
return this.value_ == that;
}
/// Ditto.
/// ditto
bool opEquals()(auto ref const ErrorCode that)
const pure nothrow @safe @nogc
{

2
source/tanya/range/array.d
View File

@ -143,7 +143,7 @@ body
array = array[1 .. $];
}
/// Ditto.
/// ditto
void popBack(T)(ref T[] array)
in
{

3
source/tanya/range/package.d
View File

@ -3,7 +3,7 @@
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
/**
* This package contains generic function and templates to be used with D
* This package contains generic functions and templates to be used with D
* ranges.
*
* Copyright: Eugene Wissner 2017.
@ -16,3 +16,4 @@
module tanya.range;
public import tanya.range.array;
public import tanya.range.primitive;

908
source/tanya/range/primitive.d Normal file
View File

@ -0,0 +1,908 @@
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
/**
* This module defines primitives for working with ranges.
*
* Copyright: Eugene Wissner 2017.
* 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/primitive.d,
* tanya/range/primitive.d)
*/
module tanya.range.primitive;
import tanya.meta.trait;
/**
* Returns the element type of the range $(D_PARAM R).
*
* Element type is the return type of such primitives like
* $(D_INLINECODE R.front) and (D_INLINECODE R.back) or the array base type.
*
* If $(D_PARAM R) is a string, $(D_PSYMBOL ElementType) doesn't distinguish
* between narrow and wide strings, it just returns the base type of the
* underlying array ($(D_KEYWORD char), $(D_KEYWORD wchar) or
* $(D_KEYWORD dchar)).
*
* Params:
* R = Any range type.
*
* Returns: Element type of the range $(D_PARAM R).
*/
template ElementType(R)
if (isInputRange!R)
{
static if (is(R U : U[]))
{
alias ElementType = U;
}
else
{
alias ElementType = ReturnType!((R r) => r.front());
}
}
/**
* Detects whether $(D_PARAM R) has a length property.
*
* $(D_PARAM R) does not have to be a range to support the length.
*
* Length mustn't be a $(D_KEYWORD @property) or a function, it can be a member
* variable or $(D_KEYWORD enum). But its type (or the type returned by the
* appropriate function) should be $(D_KEYWORD size_t), otherwise
* $(D_PSYMBOL hasLength) is $(D_KEYWORD false).
*
* All dynamic arrays except $(D_KEYWORD void)-arrays have length.
*
* Params:
* R = A type.
*
* Returns: $(D_KEYWORD true) if $(D_PARAM R) has a length property,
* $(D_KEYWORD false) otherwise.
*
* See_Also: $(D_PSYMBOL isInfinite).
*/
template hasLength(R)
{
enum bool hasLength = is(ReturnType!((R r) => r.length) == size_t)
&& !is(ElementType!R == void);
}
///
pure nothrow @safe @nogc unittest
{
static assert(hasLength!(char[]));
static assert(hasLength!(int[]));
static assert(hasLength!(const(int)[]));
struct A
{
enum size_t length = 1;
}
static assert(hasLength!(A));
struct B
{
@property size_t length() const pure nothrow @safe @nogc
{
return 0;
}
}
static assert(hasLength!(B));
struct C
{
@property const(size_t) length() const pure nothrow @safe @nogc
{
return 0;
}
}
static assert(!hasLength!(C));
}
/**
* Determines whether $(D_PARAM R) is a forward range with slicing support
* ($(D_INLINECODE R[i .. j])).
*
* For finite ranges, the result of `opSlice()` must be of the same type as the
* original range. If the range defines opDollar, it must support subtraction.
*
* For infinite ranges, the result of `opSlice()` must be of the same type as
* the original range only if it defines `opDollar()`. Otherwise it can be any
* forward range.
*
* For both finite and infinite ranges, the result of `opSlice()` must have
* length.
*
* Params:
* R = The type to be tested.
*
* Returns: $(D_KEYWORD true) if $(D_PARAM R) supports slicing,
* $(D_KEYWORD false) otherwise.
*/
template hasSlicing(R)
{
private enum bool hasDollar = is(typeof((R r) => r[0 .. $]));
private enum bool subDollar = !hasDollar
|| isInfinite!R
|| is(ReturnType!((R r) => r[0 .. $ - 1]) == R);
static if (isForwardRange!R
&& is(ReturnType!((R r) => r[0 .. 0]) T)
&& (!hasDollar || is(ReturnType!((R r) => r[0 .. $]) == R))
&& subDollar
&& isForwardRange!(ReturnType!((ref R r) => r[0 .. 0])))
{
enum bool hasSlicing = (is(T == R) || isInfinite!R)
&& hasLength!T;
}
else
{
enum bool hasSlicing = false;
}
}
///
pure nothrow @safe @nogc unittest
{
static assert(hasSlicing!(int[]));
static assert(hasSlicing!(const(int)[]));
static assert(hasSlicing!(dstring));
static assert(hasSlicing!(string));
static assert(!hasSlicing!(const int[]));
static assert(!hasSlicing!(void[]));
struct A
{
int front() pure nothrow @safe @nogc
{
return 0;
}
void popFront() pure nothrow @safe @nogc
{
}
bool empty() const pure nothrow @safe @nogc
{
return false;
}
typeof(this) save() pure nothrow @safe @nogc
{
return this;
}
@property size_t length() const pure nothrow @safe @nogc
{
return 0;
}
typeof(this) opSlice(const size_t i, const size_t j)
pure nothrow @safe @nogc
{
return this;
}
}
static assert(hasSlicing!A);
struct B
{
struct Dollar
{
}
int front() pure nothrow @safe @nogc
{
return 0;
}
void popFront() pure nothrow @safe @nogc
{
}
bool empty() const pure nothrow @safe @nogc
{
return false;
}
typeof(this) save() pure nothrow @safe @nogc
{
return this;
}
@property size_t length() const pure nothrow @safe @nogc
{
return 0;
}
@property Dollar opDollar() const pure nothrow @safe @nogc
{
return Dollar();
}
typeof(this) opSlice(const size_t i, const Dollar j)
pure nothrow @safe @nogc
{
return this;
}
}
static assert(!hasSlicing!B);
struct C
{
int front() pure nothrow @safe @nogc
{
return 0;
}
void popFront() pure nothrow @safe @nogc
{
}
enum bool empty = false;
typeof(this) save() pure nothrow @safe @nogc
{
return this;
}
typeof(this) opSlice(const size_t i, const size_t j)
pure nothrow @safe @nogc
{
return this;
}
}
static assert(!hasSlicing!C);
struct D
{
struct Range
{
int front() pure nothrow @safe @nogc
{
return 0;
}
void popFront() pure nothrow @safe @nogc
{
}
bool empty() const pure nothrow @safe @nogc
{
return true;
}
typeof(this) save() pure nothrow @safe @nogc
{
return this;
}
@property size_t length() const pure nothrow @safe @nogc
{
return 0;
}
}
int front() pure nothrow @safe @nogc
{
return 0;
}
void popFront() pure nothrow @safe @nogc
{
}
enum bool empty = false;
typeof(this) save() pure nothrow @safe @nogc
{
return this;
}
Range opSlice(const size_t i, const size_t j)
pure nothrow @safe @nogc
{
return Range();
}
}
static assert(hasSlicing!D);
}
version (TanyaPhobos)
{
public import std.range.primitives : isInputRange,
isForwardRange,
isBidirectionalRange,
isRandomAccessRange,
isInfinite;
}
else:
import tanya.meta.transform;
version (unittest)
{
mixin template InputRangeStub()
{
@property int front() pure nothrow @safe @nogc
{
return 0;
}
@property bool empty() const pure nothrow @safe @nogc
{
return false;
}
void popFront() pure nothrow @safe @nogc
{
}
}
mixin template BidirectionalRangeStub()
{
@property int back() pure nothrow @safe @nogc
{
return 0;
}
void popBack() pure nothrow @safe @nogc
{
}
}
}
private template isDynamicArrayRange(R)
{
static if (is(R E : E[]))
{
enum bool isDynamicArrayRange = !is(E == void);
}
else
{
enum bool isDynamicArrayRange = false;
}
}
/**
* Determines whether $(D_PARAM R) is an input range.
*
* An input range should define following primitives:
*
* $(UL
* $(LI front)
* $(LI empty)
* $(LI popFront)
* )
*
* Params:
* R = The type to be tested.
*
* Returns: $(D_KEYWORD true) if $(D_PARAM R) is an input range,
* $(D_KEYWORD false) otherwise.
*/
template isInputRange(R)
{
static if (is(ReturnType!((R r) => r.front()) U)
&& is(ReturnType!((R r) => r.empty) == bool))
{
enum bool isInputRange = !is(U == void)
&& is(typeof(R.popFront()));
}
else
{
enum bool isInputRange = isDynamicArrayRange!R;
}
}
///
pure nothrow @safe @nogc unittest
{
static struct Range
{
void popFront() pure nothrow @safe @nogc
{
}
int front() pure nothrow @safe @nogc
{
return 0;
}
bool empty() const pure nothrow @safe @nogc
{
return true;
}
}
static assert(isInputRange!Range);
static assert(isInputRange!(int[]));
static assert(!isInputRange!(void[]));
}
private pure nothrow @safe @nogc unittest
{
static struct Range1(T)
{
void popFront()
{
}
int front()
{
return 0;
}
T empty() const
{
return true;
}
}
static assert(!isInputRange!(Range1!int));
static assert(!isInputRange!(Range1!(const bool)));
static struct Range2
{
int popFront() pure nothrow @safe @nogc
{
return 100;
}
int front() pure nothrow @safe @nogc
{
return 100;
}
bool empty() const pure nothrow @safe @nogc
{
return true;
}
}
static assert(isInputRange!Range2);
static struct Range3
{
void popFront() pure nothrow @safe @nogc
{
}
void front() pure nothrow @safe @nogc
{
}
bool empty() const pure nothrow @safe @nogc
{
return true;
}
}
static assert(!isInputRange!Range3);
static struct Range4
{
void popFront() pure nothrow @safe @nogc
{
}
int front() pure nothrow @safe @nogc
{
return 0;
}
enum bool empty = false;
}
static assert(isInputRange!Range4);
}
/**
* Determines whether $(D_PARAM R) is a forward range.
*
* A forward range is an input range that also defines:
*
* $(UL
* $(LI save)
* )
*
* Params:
* R = The type to be tested.
*
* Returns: $(D_KEYWORD true) if $(D_PARAM R) is a forward range,
* $(D_KEYWORD false) otherwise.
*
* See_Also: $(D_PSYMBOL isInputRange).
*/
template isForwardRange(R)
{
static if (is(ReturnType!((R r) => r.save()) U))
{
enum bool isForwardRange = isInputRange!R && is(U == R);
}
else
{
enum bool isForwardRange = isDynamicArrayRange!R;
}
}
///
pure nothrow @safe @nogc unittest
{
static struct Range
{
void popFront() pure nothrow @safe @nogc
{
}
int front() pure nothrow @safe @nogc
{
return 0;
}
bool empty() const pure nothrow @safe @nogc
{
return true;
}
typeof(this) save() pure nothrow @safe @nogc
{
return this;
}
}
static assert(isForwardRange!Range);
static assert(isForwardRange!(int[]));
static assert(!isForwardRange!(void[]));
}
private pure nothrow @safe @nogc unittest
{
static struct Range1
{
}
static struct Range2
{
mixin InputRangeStub;
Range1 save() pure nothrow @safe @nogc
{
return Range1();
}
}
static assert(!isForwardRange!Range2);
static struct Range3
{
mixin InputRangeStub;
const(typeof(this)) save() const pure nothrow @safe @nogc
{
return this;
}
}
static assert(!isForwardRange!Range3);
}
/**
* Determines whether $(D_PARAM R) is a bidirectional range.
*
* A bidirectional range is a forward range that also defines:
*
* $(UL
* $(LI back)
* $(LI popBack)
* )
*
* Params:
* R = The type to be tested.
*
* Returns: $(D_KEYWORD true) if $(D_PARAM R) is a bidirectional range,
* $(D_KEYWORD false) otherwise.
*
* See_Also: $(D_PSYMBOL isForwardRange).
*/
template isBidirectionalRange(R)
{
static if (is(ReturnType!((R r) => r.back()) U))
{
enum bool isBidirectionalRange = isForwardRange!R
&& is(U == ReturnType!((R r) => r.front()))
&& is(typeof(R.popBack()));
}
else
{
enum bool isBidirectionalRange = isDynamicArrayRange!R;
}
}
///
pure nothrow @safe @nogc unittest
{
static struct Range
{
void popFront() pure nothrow @safe @nogc
{
}
void popBack() pure nothrow @safe @nogc
{
}
@property int front() pure nothrow @safe @nogc
{
return 0;
}
@property int back() pure nothrow @safe @nogc
{
return 0;
}
bool empty() const pure nothrow @safe @nogc
{
return true;
}
Range save() pure nothrow @safe @nogc
{
return this;
}
}
static assert(isBidirectionalRange!Range);
static assert(isBidirectionalRange!(int[]));
static assert(!isBidirectionalRange!(void[]));
}
private nothrow @safe @nogc unittest
{
static struct Range(T, U)
{
void popFront() pure nothrow @safe @nogc
{
}
void popBack() pure nothrow @safe @nogc
{
}
@property T front() pure nothrow @safe @nogc
{
return T.init;
}
@property U back() pure nothrow @safe @nogc
{
return U.init;
}
bool empty() const pure nothrow @safe @nogc
{
return true;
}
Range save() pure nothrow @safe @nogc
{
return this;
}
}
static assert(!isBidirectionalRange!(Range!(int, uint)));
static assert(!isBidirectionalRange!(Range!(int, const int)));
}
/**
* Determines whether $(D_PARAM R) is a random-access range.
*
* A random-access range is a range that allows random access to its
* elements by index using $(D_INLINECODE [])-operator (defined with
* $(D_INLINECODE opIndex())). Further a random access range should be a
* bidirectional range that also has a length or an infinite forward range.
*
* Params:
* R = The type to be tested.
*
* Returns: $(D_KEYWORD true) if $(D_PARAM R) is a random-access range,
* $(D_KEYWORD false) otherwise.
*
* See_Also: $(D_PSYMBOL isBidirectionalRange),
* $(D_PSYMBOL isForwardRange),
* $(D_PSYMBOL isInfinite),
* $(D_PSYMBOL hasLength).
*/
template isRandomAccessRange(R)
{
static if (is(ReturnType!((R r) => r.opIndex(size_t.init)) U))
{
private enum bool isBidirectional = isBidirectionalRange!R
&& hasLength!R;
private enum bool isForward = isInfinite!R && isForwardRange!R;
enum bool isRandomAccessRange = (isBidirectional || isForward)
&& is(U == ReturnType!((R r) => r.front()));
}
else
{
enum bool isRandomAccessRange = isDynamicArrayRange!R;
}
}
///
pure nothrow @safe @nogc unittest
{
static struct A
{
void popFront() pure nothrow @safe @nogc
{
}
void popBack() pure nothrow @safe @nogc
{
}
@property int front() pure nothrow @safe @nogc
{
return 0;
}
@property int back() pure nothrow @safe @nogc
{
return 0;
}
bool empty() const pure nothrow @safe @nogc
{
return true;
}
typeof(this) save() pure nothrow @safe @nogc
{
return this;
}
int opIndex(const size_t pos) pure nothrow @safe @nogc
{
return 0;
}
size_t length() const pure nothrow @safe @nogc
{
return 0;
}
}
static assert(isRandomAccessRange!A);
static assert(isRandomAccessRange!(int[]));
static assert(!isRandomAccessRange!(void[]));
static struct B
{
void popFront() pure nothrow @safe @nogc
{
}
@property int front() pure nothrow @safe @nogc
{
return 0;
}
enum bool empty = false;
typeof(this) save() pure nothrow @safe @nogc
{
return this;
}
int opIndex(const size_t pos) pure nothrow @safe @nogc
{
return 0;
}
}
static assert(isRandomAccessRange!B);
}
private pure nothrow @safe @nogc unittest
{
static struct Range1
{
mixin InputRangeStub;
mixin BidirectionalRangeStub;
typeof(this) save() pure nothrow @safe @nogc
{
return this;
}
int opIndex(const size_t pos) pure nothrow @safe @nogc
{
return 0;
}
}
static assert(!isRandomAccessRange!Range1);
static struct Range2(Args...)
{
mixin InputRangeStub;
mixin BidirectionalRangeStub;
typeof(this) save() pure nothrow @safe @nogc
{
return this;
}
int opIndex(Args) pure nothrow @safe @nogc
{
return 0;
}
size_t length() const pure nothrow @safe @nogc
{
return 0;
}
}
static assert(isRandomAccessRange!(Range2!size_t));
static assert(!isRandomAccessRange!(Range2!()));
static assert(!isRandomAccessRange!(Range2!(size_t, size_t)));
static struct Range3
{
mixin InputRangeStub;
mixin BidirectionalRangeStub;
typeof(this) save() pure nothrow @safe @nogc
{
return this;
}
int opIndex(const size_t pos1, const size_t pos2 = 0)
pure nothrow @safe @nogc
{
return 0;
}
size_t length() const pure nothrow @safe @nogc
{
return 0;
}
}
static assert(isRandomAccessRange!Range3);
static struct Range4
{
mixin InputRangeStub;
mixin BidirectionalRangeStub;
typeof(this) save() pure nothrow @safe @nogc
{
return this;
}
int opIndex(const size_t pos1) pure nothrow @safe @nogc
{
return 0;
}
size_t opDollar() const pure nothrow @safe @nogc
{
return 0;
}
}
static assert(!isRandomAccessRange!Range4);
}
/**
* Determines whether $(D_PARAM R) is an infinite range.
*
* An infinite range is an input range whose `empty` member is defined as
* $(D_KEYWORD enum) which is always $(D_KEYWORD false).
*
* Params:
* R = A type.
*
* Returns: $(D_KEYWORD true) if $(D_PARAM R) is an infinite range,
* $(D_KEYWORD false) otherwise.
*/
template isInfinite(R)
{
static if (isInputRange!R && is(typeof({enum bool e = R.empty;})))
{
enum bool isInfinite = R.empty == false;
}
else
{
enum bool isInfinite = false;
}
}
///
pure nothrow @safe @nogc unittest
{
static assert(!isInfinite!int);
static struct NotRange
{
enum bool empty = false;
}
static assert(!isInfinite!NotRange);
static struct InfiniteRange
{
void popFront() pure nothrow @safe @nogc
{
}
@property int front() pure nothrow @safe @nogc
{
return 0;
}
enum bool empty = false;
}
static assert(isInfinite!InfiniteRange);
static struct InputRange
{
void popFront() pure nothrow @safe @nogc
{
}
@property int front() pure nothrow @safe @nogc
{
return 0;
}
@property bool empty() const pure nothrow @safe @nogc
{
return false;
}
}
static assert(!isInfinite!InputRange);
}
private pure nothrow @safe @nogc unittest
{
static struct StaticConstRange
{
void popFront() pure nothrow @safe @nogc
{
}
@property int front() pure nothrow @safe @nogc
{
return 0;
}
static bool empty = false;
}
static assert(!isInfinite!StaticConstRange);
static struct TrueRange
{
void popFront() pure nothrow @safe @nogc
{
}
@property int front() pure nothrow @safe @nogc
{
return 0;
}
static const bool empty = true;
}
static assert(!isInfinite!TrueRange);
}

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/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
/**
* Base type definitions and aliases.
*
* This module doesn't provide aliases for all types used by Windows, but only
* for types that can vary on different platforms. For example there is no
* need to define `INT32` alias for D, since $(D_KEYWORD int) is always a
* 32-bit signed integer. But `int` and its Windows alias `INT` is not the
* same on all platforms in C, so its size can be something differen than
* 32 bit, therefore an $(D_PSYMBOL INT) alias is available in this module.
* $(D_PARAM TCHAR) can be a $(D_KEYWORD char) if Unicode isn't supported or
* $(D_KEYWORD wchar) if Unicode is supported, so $(D_PSYMBOL TCHAR) is
* defined here.
* Also aliases for specific types like $(D_PSYMBOL SOCKET) are defined here.
*
* Copyright: Eugene Wissner 2017.
* License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
* Mozilla Public License, v. 2.0).
* Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
* Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/sys/windows/def.d,
* tanya/sys/windows/def.d)
*/
module tanya.sys.windows.def;
version (Windows):
alias BYTE = ubyte;
alias TBYTE = wchar; // If Unicode, otherwise char.
alias CHAR = char; // Signed or unsigned char.
alias TCHAR = wchar; // If Unicode, otherwise char.
alias SHORT = short;
alias USHORT = ushort;
alias WORD = ushort;
alias INT = int;
alias UINT = uint;
alias LONG = int;
alias ULONG = uint;
alias DWORD = uint;
alias LONGLONG = long; // Or double.
alias ULONGLONG = ulong; // Or double.
alias DWORDLONG = ulong;
alias FLOAT = float;
alias BOOL = int;
alias BOOLEAN = BYTE;
alias HANDLE = void*;
enum HANDLE INVALID_HANDLE_VALUE = cast(HANDLE) -1;
enum TRUE = 1;
enum FALSE = 0;
align(1) struct GUID
{
uint Data1;
ushort Data2;
ushort Data3;
char[8] Data4;
}

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/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
/**
* Copyright: Eugene Wissner 2017.
* 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)
*/
module tanya.sys.windows.error;
version (Windows):
private enum WSABASEERR = 10000;
enum
{
WSAEINTR = WSABASEERR + 4,
WSAEBADF = WSABASEERR + 9,
WSAEACCES = WSABASEERR + 13,
WSAEFAULT = WSABASEERR + 14,
WSAEINVAL = WSABASEERR + 22,
WSAEMFILE = WSABASEERR + 24,
WSAEWOULDBLOCK = WSABASEERR + 35,
WSAEINPROGRESS = WSABASEERR + 36,
WSAEALREADY = WSABASEERR + 37,
WSAENOTSOCK = WSABASEERR + 38,
WSAEDESTADDRREQ = WSABASEERR + 39,
WSAEMSGSIZE = WSABASEERR + 40,
WSAEPROTOTYPE = WSABASEERR + 41,
WSAENOPROTOOPT = WSABASEERR + 42,
WSAEPROTONOSUPPORT = WSABASEERR + 43,
WSAESOCKTNOSUPPORT = WSABASEERR + 44,
WSAEOPNOTSUPP = WSABASEERR + 45,
WSAEPFNOSUPPORT = WSABASEERR + 46,
WSAEAFNOSUPPORT = WSABASEERR + 47,
WSAEADDRINUSE = WSABASEERR + 48,
WSAEADDRNOTAVAIL = WSABASEERR + 49,
WSAENETDOWN = WSABASEERR + 50,
WSAENETUNREACH = WSABASEERR + 51,
WSAENETRESET = WSABASEERR + 52,
WSAECONNABORTED = WSABASEERR + 53,
WSAECONNRESET = WSABASEERR + 54,
WSAENOBUFS = WSABASEERR + 55,
WSAEISCONN = WSABASEERR + 56,
WSAENOTCONN = WSABASEERR + 57,
WSAESHUTDOWN = WSABASEERR + 58,
WSAETOOMANYREFS = WSABASEERR + 59,
WSAETIMEDOUT = WSABASEERR + 60,
WSAECONNREFUSED = WSABASEERR + 61,
WSAELOOP = WSABASEERR + 62,
WSAENAMETOOLONG = WSABASEERR + 63,
WSAEHOSTDOWN = WSABASEERR + 64,
WSAEHOSTUNREACH = WSABASEERR + 65,
WSAENOTEMPTY = WSABASEERR + 66,
WSAEPROCLIM = WSABASEERR + 67,
WSAEUSERS = WSABASEERR + 68,
WSAEDQUOT = WSABASEERR + 69,
WSAESTALE = WSABASEERR + 70,
WSAEREMOTE = WSABASEERR + 71,
WSASYSNOTREADY = WSABASEERR + 91,
WSAVERNOTSUPPORTED = WSABASEERR + 92,
WSANOTINITIALISED = WSABASEERR + 93,
WSAEDISCON = WSABASEERR + 101,
WSAENOMORE = WSABASEERR + 102,
WSAECANCELLED = WSABASEERR + 103,
WSAEINVALIDPROCTABLE = WSABASEERR + 104,
WSAEINVALIDPROVIDER = WSABASEERR + 105,
WSAEPROVIDERFAILEDINIT = WSABASEERR + 106,
WSASYSCALLFAILURE = WSABASEERR + 107,
WSASERVICE_NOT_FOUND = WSABASEERR + 108,
WSATYPE_NOT_FOUND = WSABASEERR + 109,
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,
WSANO_DATA = WSABASEERR + 1004,
WSA_QOS_RECEIVERS = WSABASEERR + 1005,
WSA_QOS_SENDERS = WSABASEERR + 1006,
WSA_QOS_NO_SENDERS = WSABASEERR + 1007,
WSA_QOS_NO_RECEIVERS = WSABASEERR + 1008,
WSA_QOS_REQUEST_CONFIRMED = WSABASEERR + 1009,
WSA_QOS_ADMISSION_FAILURE = WSABASEERR + 1010,
WSA_QOS_POLICY_FAILURE = WSABASEERR + 1011,
WSA_QOS_BAD_STYLE = WSABASEERR + 1012,
WSA_QOS_BAD_OBJECT = WSABASEERR + 1013,
WSA_QOS_TRAFFIC_CTRL_ERROR = WSABASEERR + 1014,
WSA_QOS_GENERIC_ERROR = WSABASEERR + 1015,
WSA_QOS_ESERVICETYPE = WSABASEERR + 1016,
WSA_QOS_EFLOWSPEC = WSABASEERR + 1017,
WSA_QOS_EPROVSPECBUF = WSABASEERR + 1018,
WSA_QOS_EFILTERSTYLE = WSABASEERR + 1019,
WSA_QOS_EFILTERTYPE = WSABASEERR + 1020,
WSA_QOS_EFILTERCOUNT = WSABASEERR + 1021,
WSA_QOS_EOBJLENGTH = WSABASEERR + 1022,
WSA_QOS_EFLOWCOUNT = WSABASEERR + 1023,
WSA_QOS_EUNKOWNPSOBJ = WSABASEERR + 1024,
WSA_QOS_EPOLICYOBJ = WSABASEERR + 1025,
WSA_QOS_EFLOWDESC = WSABASEERR + 1026,
WSA_QOS_EPSFLOWSPEC = WSABASEERR + 1027,
WSA_QOS_EPSFILTERSPEC = WSABASEERR + 1028,
WSA_QOS_ESDMODEOBJ = WSABASEERR + 1029,
WSA_QOS_ESHAPERATEOBJ = WSABASEERR + 1030,
WSA_QOS_RESERVED_PETYPE = WSABASEERR + 1031,
}

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/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
/**
* Copyright: Eugene Wissner 2017.
* License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
* Mozilla Public License, v. 2.0).
* Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
* Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/sys/windows/package.d,
* tanya/sys/windows/package.d)
*/
module tanya.sys.windows;
version (Windows):
public import tanya.sys.windows.def;
public import tanya.sys.windows.error;
public import tanya.sys.windows.winbase;
public import tanya.sys.windows.winsock2;

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/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
/**
* Definitions from winbase.h.
*
* Copyright: Eugene Wissner 2017.
* License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
* Mozilla Public License, v. 2.0).
* Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
* Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/sys/windows/winbase.d,
* tanya/sys/windows/winbase.d)
*/
module tanya.sys.windows.winbase;
version (Windows):
public import tanya.sys.windows.def;
struct OVERLAPPED
{
size_t Internal;
size_t InternalHigh;
union
{
struct
{
DWORD Offset;
DWORD OffsetHigh;
}
void* Pointer;
}
HANDLE hEvent;
}
extern(Windows)
HANDLE CreateIoCompletionPort(HANDLE FileHandle,
HANDLE ExistingCompletionPort,
size_t CompletionKey,
DWORD NumberOfConcurrentThreads)
nothrow @system @nogc;
extern(Windows)
BOOL GetQueuedCompletionStatus(HANDLE CompletionPort,
DWORD* lpNumberOfBytes,
size_t* lpCompletionKey,
OVERLAPPED** lpOverlapped,
DWORD dwMilliseconds) nothrow @system @nogc;
extern(Windows)
BOOL GetOverlappedResult(HANDLE hFile,
OVERLAPPED* lpOverlapped,
DWORD* lpNumberOfBytesTransferred,
BOOL bWait) nothrow @system @nogc;

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/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
/**
* Definitions from winsock2.h, ws2def.h and MSWSock.h.
*
* Copyright: Eugene Wissner 2017.
* License: $(LINK2 https://www.mozilla.org/en-US/MPL/2.0/,
* Mozilla Public License, v. 2.0).
* Authors: $(LINK2 mailto:info@caraus.de, Eugene Wissner)
* Source: $(LINK2 https://github.com/caraus-ecms/tanya/blob/master/source/tanya/sys/windows/winsock2.d,
* tanya/sys/windows/winsock2.d)
*/
module tanya.sys.windows.winsock2;
version (Windows):
public import tanya.sys.windows.def;
public import tanya.sys.windows.winbase;
alias SOCKET = size_t;
enum SOCKET INVALID_SOCKET = ~0;
enum SOCKET_ERROR = -1;
enum
{
IOC_UNIX = 0x00000000,
IOC_WS2 = 0x08000000,
IOC_PROTOCOL = 0x10000000,
IOC_VOID = 0x20000000, // No parameters.
IOC_OUT = 0x40000000, // Copy parameters back.
IOC_IN = 0x80000000, // Copy parameters into.
IOC_VENDOR = 0x18000000,
IOC_WSK = (IOC_WS2 | 0x07000000), // _WIN32_WINNT >= 0x0600.
IOC_INOUT = (IOC_IN | IOC_OUT), // Copy parameter into and get back.
}
template _WSAIO(int x, int y)
{
enum _WSAIO = IOC_VOID | x | y;
}
template _WSAIOR(int x, int y)
{
enum _WSAIOR = IOC_OUT | x | y;
}
template _WSAIOW(int x, int y)
{
enum _WSAIOW = IOC_IN | x | y;
}
template _WSAIORW(int x, int y)
{
enum _WSAIORW = IOC_INOUT | x | y;
}
alias SIO_ASSOCIATE_HANDLE = _WSAIOW!(IOC_WS2, 1);
alias SIO_ENABLE_CIRCULAR_QUEUEING = _WSAIO!(IOC_WS2, 2);
alias SIO_FIND_ROUTE = _WSAIOR!(IOC_WS2, 3);
alias SIO_FLUSH = _WSAIO!(IOC_WS2, 4);
alias SIO_GET_BROADCAST_ADDRESS = _WSAIOR!(IOC_WS2, 5);
alias SIO_GET_EXTENSION_FUNCTION_POINTER = _WSAIORW!(IOC_WS2, 6);
alias SIO_GET_QOS = _WSAIORW!(IOC_WS2, 7);
alias SIO_GET_GROUP_QOS = _WSAIORW!(IOC_WS2, 8);
alias SIO_MULTIPOINT_LOOPBACK = _WSAIOW!(IOC_WS2, 9);
alias SIO_MULTICAST_SCOPE = _WSAIOW!(IOC_WS2, 10);
alias SIO_SET_QOS = _WSAIOW!(IOC_WS2, 11);
alias SIO_SET_GROUP_QOS = _WSAIOW!(IOC_WS2, 12);
alias SIO_TRANSLATE_HANDLE = _WSAIORW!(IOC_WS2, 13);
alias SIO_ROUTING_INTERFACE_QUERY = _WSAIORW!(IOC_WS2, 20);
alias SIO_ROUTING_INTERFACE_CHANGE = _WSAIOW!(IOC_WS2, 21);
alias SIO_ADDRESS_LIST_QUERY = _WSAIOR!(IOC_WS2, 22);
alias SIO_ADDRESS_LIST_CHANGE = _WSAIO!(IOC_WS2, 23);
alias SIO_QUERY_TARGET_PNP_HANDLE = _WSAIOR!(IOC_WS2, 24);
alias SIO_NSP_NOTIFY_CHANGE = _WSAIOW!(IOC_WS2, 25);
alias GROUP = uint;
enum
{
WSA_FLAG_OVERLAPPED = 0x01,
WSA_FLAG_MULTIPOINT_C_ROOT = 0x02,
WSA_FLAG_MULTIPOINT_C_LEAF = 0x04,
WSA_FLAG_MULTIPOINT_D_ROOT = 0x08,
WSA_FLAG_MULTIPOINT_D_LEAF = 0x10,
WSA_FLAG_ACCESS_SYSTEM_SECURITY = 0x40,
WSA_FLAG_NO_HANDLE_INHERIT = 0x80,
WSA_FLAG_REGISTERED_IO = 0x100,
}
enum MAX_PROTOCOL_CHAIN = 7;
enum BASE_PROTOCOL = 1;
enum LAYERED_PROTOCOL = 0;
enum WSAPROTOCOL_LEN = 255;
struct WSAPROTOCOLCHAIN
{
int ChainLen;
DWORD[MAX_PROTOCOL_CHAIN] ChainEntries;
}
struct WSABUF
{
ULONG len;
CHAR* buf;
}
struct WSAPROTOCOL_INFO
{
DWORD dwServiceFlags1;
DWORD dwServiceFlags2;
DWORD dwServiceFlags3;
DWORD dwServiceFlags4;
DWORD dwProviderFlags;
GUID ProviderId;
DWORD dwCatalogEntryId;
WSAPROTOCOLCHAIN ProtocolChain;
int iVersion;
int iAddressFamily;
int iMaxSockAddr;
int iMinSockAddr;
int iSocketType;
int iProtocol;
int iProtocolMaxOffset;
int iNetworkByteOrder;
int iSecurityScheme;
DWORD dwMessageSize;
DWORD dwProviderReserved;
TCHAR[WSAPROTOCOL_LEN + 1] szProtocol;
}
const GUID WSAID_GETACCEPTEXSOCKADDRS = {
0xb5367df2, 0xcbac, 0x11cf,
[0x95, 0xca, 0x00, 0x80, 0x5f, 0x48, 0xa1, 0x92],
};
const GUID WSAID_ACCEPTEX = {
0xb5367df1, 0xcbac, 0x11cf,
[0x95, 0xca, 0x00, 0x80, 0x5f, 0x48, 0xa1, 0x92],
};
alias LPWSAOVERLAPPED_COMPLETION_ROUTINE = void function(DWORD dwError,
DWORD cbTransferred,
OVERLAPPED* lpOverlapped,
DWORD dwFlags) nothrow @nogc;
extern(Windows)
SOCKET WSASocket(int af,
int type,
int protocol,
WSAPROTOCOL_INFO* lpProtocolInfo,
GROUP g,
DWORD dwFlags) nothrow @system @nogc;
extern(Windows)
int WSARecv(SOCKET s,
WSABUF* lpBuffers,
DWORD dwBufferCount,
DWORD* lpNumberOfBytesRecvd,
DWORD* lpFlags,
OVERLAPPED* lpOverlapped,
LPWSAOVERLAPPED_COMPLETION_ROUTINE lpCompletionRoutine)
nothrow @system @nogc;
extern(Windows)
int WSASend(SOCKET s,
WSABUF* lpBuffers,
DWORD dwBufferCount,
DWORD* lpNumberOfBytesRecvd,
DWORD lpFlags,
OVERLAPPED* lpOverlapped,
LPWSAOVERLAPPED_COMPLETION_ROUTINE lpCompletionRoutine)
nothrow @system @nogc;
extern(Windows)
int WSAIoctl(SOCKET s,
uint dwIoControlCode,
void* lpvInBuffer,
uint cbInBuffer,
void* lpvOutBuffer,
uint cbOutBuffer,
uint* lpcbBytesReturned,
OVERLAPPED* lpOverlapped,
LPWSAOVERLAPPED_COMPLETION_ROUTINE lpCompletionRoutine)
nothrow @system @nogc;
alias ADDRESS_FAMILY = USHORT;
struct SOCKADDR
{
ADDRESS_FAMILY sa_family; // Address family.
CHAR[14] sa_data; // Up to 14 bytes of direct address.
}
alias LPFN_GETACCEPTEXSOCKADDRS = void function(void*,
DWORD,
DWORD,
DWORD,
SOCKADDR**,
INT*,
SOCKADDR**,
INT*) nothrow @nogc;
alias LPFN_ACCEPTEX = extern(Windows) BOOL function(SOCKET,
SOCKET,
void*,
DWORD,
DWORD,
DWORD,
DWORD*,
OVERLAPPED*) @nogc nothrow;
enum
{
SO_MAXDG = 0x7009,
SO_MAXPATHDG = 0x700A,
SO_UPDATE_ACCEPT_CONTEXT = 0x700B,
SO_CONNECT_TIME = 0x700C,
SO_UPDATE_CONNECT_CONTEXT = 0x7010,
}