Fixing a bunch of alloy clang issues.

This commit is contained in:
Ben Vanik 2014-07-12 21:52:33 -07:00
parent 9b78dd977b
commit 7ee79318e8
13 changed files with 157 additions and 56 deletions

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@ -14,9 +14,6 @@
#include <alloy/runtime/symbol_info.h> #include <alloy/runtime/symbol_info.h>
#include <alloy/runtime/thread_state.h> #include <alloy/runtime/thread_state.h>
// TODO(benvanik): reimplement packing functions
#include <DirectXPackedVector.h>
// TODO(benvanik): make a compile time flag? // TODO(benvanik): make a compile time flag?
//#define DYNAMIC_REGISTER_ACCESS_CHECK(address) false //#define DYNAMIC_REGISTER_ACCESS_CHECK(address) false
#define DYNAMIC_REGISTER_ACCESS_CHECK(address) \ #define DYNAMIC_REGISTER_ACCESS_CHECK(address) \
@ -38,10 +35,10 @@ using alloy::hir::Value;
using alloy::runtime::Function; using alloy::runtime::Function;
using alloy::runtime::FunctionInfo; using alloy::runtime::FunctionInfo;
#define IPRINT #define IPRINT(...) (void())
#define IFLUSH() #define IFLUSH() (void())
#define DPRINT #define DPRINT(...) (void())
#define DFLUSH() #define DFLUSH() (void())
//#define IPRINT if (ics.thread_state->thread_id() == 1) printf //#define IPRINT if (ics.thread_state->thread_id() == 1) printf
//#define IFLUSH() fflush(stdout) //#define IFLUSH() fflush(stdout)
@ -101,7 +98,7 @@ uint32_t AllocConstant(TranslationContext& ctx, Value* value) {
uint32_t AllocLabel(TranslationContext& ctx, Label* label) { uint32_t AllocLabel(TranslationContext& ctx, Label* label) {
// If it's a back-branch to an already tagged label avoid setting up // If it's a back-branch to an already tagged label avoid setting up
// a reference. // a reference.
uint32_t value = (uint32_t)label->tag; uint32_t value = *reinterpret_cast<uint32_t*>(label->tag);
if (value & 0x80000000) { if (value & 0x80000000) {
// Already set. // Already set.
return AllocConstant(ctx, value & ~0x80000000); return AllocConstant(ctx, value & ~0x80000000);
@ -124,11 +121,11 @@ uint32_t AllocLabel(TranslationContext& ctx, Label* label) {
uint32_t AllocDynamicRegister(TranslationContext& ctx, Value* value) { uint32_t AllocDynamicRegister(TranslationContext& ctx, Value* value) {
if (value->flags & VALUE_IS_ALLOCATED) { if (value->flags & VALUE_IS_ALLOCATED) {
return (uint32_t)value->tag; return *reinterpret_cast<uint32_t*>(value->tag);
} else { } else {
value->flags |= VALUE_IS_ALLOCATED; value->flags |= VALUE_IS_ALLOCATED;
auto reg = ctx.register_count++; auto reg = ctx.register_count++;
value->tag = (void*)reg; value->tag = reinterpret_cast<void*>(reg);
return (uint32_t)reg; return (uint32_t)reg;
} }
} }
@ -207,6 +204,7 @@ int TranslateInvalid(TranslationContext& ctx, Instr* i) {
uint32_t IntCode_COMMENT(IntCodeState& ics, const IntCode* i) { uint32_t IntCode_COMMENT(IntCodeState& ics, const IntCode* i) {
char* value = (char*)(i->src1_reg | ((uint64_t)i->src2_reg << 32)); char* value = (char*)(i->src1_reg | ((uint64_t)i->src2_reg << 32));
(void)(value);
IPRINT("XE[t] :%d: %s\n", ics.thread_state->thread_id(), value); IPRINT("XE[t] :%d: %s\n", ics.thread_state->thread_id(), value);
IFLUSH(); IFLUSH();
return IA_NEXT; return IA_NEXT;
@ -1186,12 +1184,7 @@ int Translate_LOAD_VECTOR_SHR(TranslationContext& ctx, Instr* i) {
} }
uint32_t IntCode_LOAD_CLOCK(IntCodeState& ics, const IntCode* i) { uint32_t IntCode_LOAD_CLOCK(IntCodeState& ics, const IntCode* i) {
LARGE_INTEGER counter; ics.rf[i->dest_reg].i64 = poly::threading::ticks();
uint64_t time = 0;
if (QueryPerformanceCounter(&counter)) {
time = counter.QuadPart;
}
ics.rf[i->dest_reg].i64 = time;
return IA_NEXT; return IA_NEXT;
} }
int Translate_LOAD_CLOCK(TranslationContext& ctx, Instr* i) { int Translate_LOAD_CLOCK(TranslationContext& ctx, Instr* i) {
@ -2664,7 +2657,7 @@ int Translate_MUL(TranslationContext& ctx, Instr* i) {
} }
} }
namespace { #if !XE_COMPILER_MSVC
uint64_t Mul128(uint64_t xi_low, uint64_t xi_high, uint64_t yi_low, uint64_t Mul128(uint64_t xi_low, uint64_t xi_high, uint64_t yi_low,
uint64_t yi_high) { uint64_t yi_high) {
// 128bit multiply, simplified for two input 64bit integers. // 128bit multiply, simplified for two input 64bit integers.
@ -2680,7 +2673,6 @@ uint64_t Mul128(uint64_t xi_low, uint64_t xi_high, uint64_t yi_low,
uint64_t f = yi_high & LO_WORD; uint64_t f = yi_high & LO_WORD;
uint64_t e = (yi_high & HI_WORD) >> 32LL; uint64_t e = (yi_high & HI_WORD) >> 32LL;
uint64_t acc = d * h; uint64_t acc = d * h;
uint64_t o1 = acc & LO_WORD;
acc >>= 32LL; acc >>= 32LL;
uint64_t carry = 0; uint64_t carry = 0;
@ -2692,7 +2684,6 @@ uint64_t Mul128(uint64_t xi_low, uint64_t xi_high, uint64_t yi_low,
if (acc < ac2) { if (acc < ac2) {
carry++; carry++;
} }
uint64_t rv2_lo = o1 | (acc << 32LL);
ac2 = (acc >> 32LL) | (carry << 32LL); ac2 = (acc >> 32LL) | (carry << 32LL);
carry = 0; carry = 0;
@ -2719,7 +2710,7 @@ uint64_t Mul128(uint64_t xi_low, uint64_t xi_high, uint64_t yi_low,
return rv2_hi; return rv2_hi;
} }
} #endif // !XE_COMPILER_MSVC
uint32_t IntCode_MUL_HI_I8_I8(IntCodeState& ics, const IntCode* i) { uint32_t IntCode_MUL_HI_I8_I8(IntCodeState& ics, const IntCode* i) {
int16_t v = (int16_t)ics.rf[i->src1_reg].i8 * (int16_t)ics.rf[i->src2_reg].i8; int16_t v = (int16_t)ics.rf[i->src1_reg].i8 * (int16_t)ics.rf[i->src2_reg].i8;
@ -3565,33 +3556,21 @@ int Translate_BYTE_SWAP(TranslationContext& ctx, Instr* i) {
uint32_t IntCode_CNTLZ_I8(IntCodeState& ics, const IntCode* i) { uint32_t IntCode_CNTLZ_I8(IntCodeState& ics, const IntCode* i) {
// CHECK // CHECK
assert_always(); assert_always();
DWORD index; ics.rf[i->dest_reg].i8 = poly::lzcnt(ics.rf[i->src1_reg].i8);
DWORD mask = ics.rf[i->src1_reg].i8;
BOOLEAN is_nonzero = _BitScanReverse(&index, mask);
ics.rf[i->dest_reg].i8 = is_nonzero ? (int8_t)(index - 24) ^ 0x7 : 8;
return IA_NEXT; return IA_NEXT;
} }
uint32_t IntCode_CNTLZ_I16(IntCodeState& ics, const IntCode* i) { uint32_t IntCode_CNTLZ_I16(IntCodeState& ics, const IntCode* i) {
// CHECK // CHECK
assert_always(); assert_always();
DWORD index; ics.rf[i->dest_reg].i8 = poly::lzcnt(ics.rf[i->src1_reg].i16);
DWORD mask = ics.rf[i->src1_reg].i16;
BOOLEAN is_nonzero = _BitScanReverse(&index, mask);
ics.rf[i->dest_reg].i8 = is_nonzero ? (int8_t)(index - 16) ^ 0xF : 16;
return IA_NEXT; return IA_NEXT;
} }
uint32_t IntCode_CNTLZ_I32(IntCodeState& ics, const IntCode* i) { uint32_t IntCode_CNTLZ_I32(IntCodeState& ics, const IntCode* i) {
DWORD index; ics.rf[i->dest_reg].i8 = poly::lzcnt(ics.rf[i->src1_reg].i32);
DWORD mask = ics.rf[i->src1_reg].i32;
BOOLEAN is_nonzero = _BitScanReverse(&index, mask);
ics.rf[i->dest_reg].i8 = is_nonzero ? (int8_t)index ^ 0x1F : 32;
return IA_NEXT; return IA_NEXT;
} }
uint32_t IntCode_CNTLZ_I64(IntCodeState& ics, const IntCode* i) { uint32_t IntCode_CNTLZ_I64(IntCodeState& ics, const IntCode* i) {
DWORD index; ics.rf[i->dest_reg].i8 = poly::lzcnt(ics.rf[i->src1_reg].i64);
DWORD64 mask = ics.rf[i->src1_reg].i64;
BOOLEAN is_nonzero = _BitScanReverse64(&index, mask);
ics.rf[i->dest_reg].i8 = is_nonzero ? (int8_t)index ^ 0x3F : 64;
return IA_NEXT; return IA_NEXT;
} }
int Translate_CNTLZ(TranslationContext& ctx, Instr* i) { int Translate_CNTLZ(TranslationContext& ctx, Instr* i) {
@ -3872,21 +3851,18 @@ uint32_t IntCode_PACK_FLOAT16_2(IntCodeState& ics, const IntCode* i) {
const vec128_t& src1 = ics.rf[i->src1_reg].v128; const vec128_t& src1 = ics.rf[i->src1_reg].v128;
vec128_t& dest = ics.rf[i->dest_reg].v128; vec128_t& dest = ics.rf[i->dest_reg].v128;
dest.ix = dest.iy = dest.iz = 0; dest.ix = dest.iy = dest.iz = 0;
dest.iw = dest.iw = (uint32_t(poly::float_to_half(src1.x)) << 16) |
((uint32_t)DirectX::PackedVector::XMConvertFloatToHalf(src1.x) << 16) | poly::float_to_half(src1.y);
DirectX::PackedVector::XMConvertFloatToHalf(src1.y);
return IA_NEXT; return IA_NEXT;
} }
uint32_t IntCode_PACK_FLOAT16_4(IntCodeState& ics, const IntCode* i) { uint32_t IntCode_PACK_FLOAT16_4(IntCodeState& ics, const IntCode* i) {
const vec128_t& src1 = ics.rf[i->src1_reg].v128; const vec128_t& src1 = ics.rf[i->src1_reg].v128;
vec128_t& dest = ics.rf[i->dest_reg].v128; vec128_t& dest = ics.rf[i->dest_reg].v128;
dest.ix = dest.iy = 0; dest.ix = dest.iy = 0;
dest.iz = dest.iz = (uint32_t(poly::float_to_half(src1.x)) << 16) |
((uint32_t)DirectX::PackedVector::XMConvertFloatToHalf(src1.x) << 16) | poly::float_to_half(src1.y);
DirectX::PackedVector::XMConvertFloatToHalf(src1.y); dest.iw = (uint32_t(poly::float_to_half(src1.z)) << 16) |
dest.iw = poly::float_to_half(src1.w);
((uint32_t)DirectX::PackedVector::XMConvertFloatToHalf(src1.z) << 16) |
DirectX::PackedVector::XMConvertFloatToHalf(src1.w);
return IA_NEXT; return IA_NEXT;
} }
uint32_t IntCode_PACK_SHORT_2(IntCodeState& ics, const IntCode* i) { uint32_t IntCode_PACK_SHORT_2(IntCodeState& ics, const IntCode* i) {
@ -3932,7 +3908,7 @@ uint32_t IntCode_UNPACK_FLOAT16_2(IntCodeState& ics, const IntCode* i) {
vec128_t& dest = ics.rf[i->dest_reg].v128; vec128_t& dest = ics.rf[i->dest_reg].v128;
uint32_t src = src1.iw; uint32_t src = src1.iw;
for (int n = 0; n < 2; n++) { for (int n = 0; n < 2; n++) {
dest.f4[n] = DirectX::PackedVector::XMConvertHalfToFloat((uint16_t)src); dest.f4[n] = poly::half_to_float(uint16_t(src));
src >>= 16; src >>= 16;
} }
dest.f4[2] = 0.0f; dest.f4[2] = 0.0f;
@ -3944,7 +3920,7 @@ uint32_t IntCode_UNPACK_FLOAT16_4(IntCodeState& ics, const IntCode* i) {
vec128_t& dest = ics.rf[i->dest_reg].v128; vec128_t& dest = ics.rf[i->dest_reg].v128;
uint64_t src = src1.iz | ((uint64_t)src1.iw << 32); uint64_t src = src1.iz | ((uint64_t)src1.iw << 32);
for (int n = 0; n < 4; n++) { for (int n = 0; n < 4; n++) {
dest.f4[n] = DirectX::PackedVector::XMConvertHalfToFloat((uint16_t)src); dest.f4[n] = poly::half_to_float(uint16_t(src));
src >>= 16; src >>= 16;
} }
return IA_NEXT; return IA_NEXT;

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@ -10,6 +10,8 @@
#ifndef ALLOY_FRONTEND_PPC_PPC_INSTR_TABLES_H_ #ifndef ALLOY_FRONTEND_PPC_PPC_INSTR_TABLES_H_
#define ALLOY_FRONTEND_PPC_PPC_INSTR_TABLES_H_ #define ALLOY_FRONTEND_PPC_PPC_INSTR_TABLES_H_
#include <cmath>
#include <alloy/frontend/ppc/ppc_instr.h> #include <alloy/frontend/ppc/ppc_instr.h>
namespace alloy { namespace alloy {

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@ -9,6 +9,8 @@
#include <alloy/hir/value.h> #include <alloy/hir/value.h>
#include <cmath>
namespace alloy { namespace alloy {
namespace hir { namespace hir {

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@ -12,6 +12,7 @@
#include <map> #include <map>
#include <mutex> #include <mutex>
#include <string>
#include <unordered_map> #include <unordered_map>
#include <alloy/core.h> #include <alloy/core.h>

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@ -70,7 +70,7 @@ namespace poly {
poly_assert((expr) != nullptr || !message) poly_assert((expr) != nullptr || !message)
#define assert_unhandled_case(variable) \ #define assert_unhandled_case(variable) \
assert_always("unhandled switch("## #variable##") case") assert_always("unhandled switch(" #variable ") case")
} // namespace poly } // namespace poly

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@ -15,32 +15,35 @@
#include <poly/config.h> #include <poly/config.h>
#include <poly/platform.h> #include <poly/platform.h>
#if XE_LIKE_OSX
#include <libkern/OSAtomic.h>
#endif // XE_LIKE_OSX
namespace poly { namespace poly {
// These functions are modeled off of the Apple OSAtomic routines // These functions are modeled off of the Apple OSAtomic routines
// http://developer.apple.com/library/mac/#documentation/DriversKernelHardware/Reference/libkern_ref/OSAtomic_h/ // http://developer.apple.com/library/mac/#documentation/DriversKernelHardware/Reference/libkern_ref/OSAtomic_h/
#if XE_LIKE_OSX #if XE_LIKE_OSX
#include <libkern/OSAtomic.h>
inline int32_t atomic_inc(volatile int32_t* value) { inline int32_t atomic_inc(volatile int32_t* value) {
return OSAtomicIncrement32Barrier(reinterpret_cast<volatile LONG*>(value)); return OSAtomicIncrement32Barrier(reinterpret_cast<volatile int32_t*>(value));
} }
inline int32_t atomic_dec(volatile int32_t* value) { inline int32_t atomic_dec(volatile int32_t* value) {
return OSAtomicDecrement32Barrier(reinterpret_cast<volatile LONG*>(value)); return OSAtomicDecrement32Barrier(reinterpret_cast<volatile int32_t*>(value));
} }
inline int32_t atomic_exchange(int32_t new_value, volatile int32_t* value) { inline int32_t atomic_exchange(int32_t new_value, volatile int32_t* value) {
// return OSAtomicCompareAndSwap32Barrier(*value, new_value, value);
} }
inline int64_t atomic_exchange(int64_t new_value, volatile int64_t* value) { inline int64_t atomic_exchange(int64_t new_value, volatile int64_t* value) {
// return OSAtomicCompareAndSwap64Barrier(*value, new_value, value);
} }
inline int32_t atomic_cas(int32_t old_value, int32_t new_value, inline int32_t atomic_cas(int32_t old_value, int32_t new_value,
volatile int32_t* value) { volatile int32_t* value) {
return OSAtomicCompareAndSwap32Barrier( return OSAtomicCompareAndSwap32Barrier(
old_value, new_value, reinterpret_cast<volatile LONG*>(value)); old_value, new_value, reinterpret_cast<volatile int32_t*>(value));
} }
#elif XE_LIKE_WIN32 #elif XE_LIKE_WIN32
@ -77,10 +80,10 @@ inline int32_t atomic_dec(volatile int32_t* value) {
} }
inline int32_t atomic_exchange(int32_t new_value, volatile int32_t* value) { inline int32_t atomic_exchange(int32_t new_value, volatile int32_t* value) {
// return __sync_val_compare_and_swap(*value, value, new_value);
} }
inline int64_t atomic_exchange(int64_t new_value, volatile int64_t* value) { inline int64_t atomic_exchange(int64_t new_value, volatile int64_t* value) {
// return __sync_val_compare_and_swap(*value, value, new_value);
} }
inline int32_t atomic_cas(int32_t old_value, int32_t new_value, inline int32_t atomic_cas(int32_t old_value, int32_t new_value,

69
src/poly/math.cc Normal file
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@ -0,0 +1,69 @@
/**
******************************************************************************
* Xenia : Xbox 360 Emulator Research Project *
******************************************************************************
* Copyright 2014 Ben Vanik. All rights reserved. *
* Released under the BSD license - see LICENSE in the root for more details. *
******************************************************************************
*/
#include <poly/math.h>
namespace poly {
// TODO(benvanik): replace with alternate implementation.
// XMConvertFloatToHalf
// Copyright (c) Microsoft Corporation. All rights reserved.
uint16_t float_to_half(float value) {
uint32_t Result;
uint32_t IValue = ((uint32_t *)(&value))[0];
uint32_t Sign = (IValue & 0x80000000U) >> 16U;
IValue = IValue & 0x7FFFFFFFU; // Hack off the sign
if (IValue > 0x47FFEFFFU) {
// The number is too large to be represented as a half. Saturate to
// infinity.
Result = 0x7FFFU;
} else {
if (IValue < 0x38800000U) {
// The number is too small to be represented as a normalized half.
// Convert it to a denormalized value.
uint32_t Shift = 113U - (IValue >> 23U);
IValue = (0x800000U | (IValue & 0x7FFFFFU)) >> Shift;
} else {
// Rebias the exponent to represent the value as a normalized half.
IValue += 0xC8000000U;
}
Result = ((IValue + 0x0FFFU + ((IValue >> 13U) & 1U)) >> 13U) & 0x7FFFU;
}
return (uint16_t)(Result | Sign);
}
// TODO(benvanik): replace with alternate implementation.
// XMConvertHalfToFloat
// Copyright (c) Microsoft Corporation. All rights reserved.
float half_to_float(uint16_t value) {
uint32_t Mantissa = (uint32_t)(value & 0x03FF);
uint32_t Exponent;
if ((value & 0x7C00) != 0) {
// The value is normalized
Exponent = (uint32_t)((value >> 10) & 0x1F);
} else if (Mantissa != 0) {
// The value is denormalized
// Normalize the value in the resulting float
Exponent = 1;
do {
Exponent--;
Mantissa <<= 1;
} while ((Mantissa & 0x0400) == 0);
Mantissa &= 0x03FF;
} else {
// The value is zero
Exponent = (uint32_t)-112;
}
uint32_t Result = ((value & 0x8000) << 16) | // Sign
((Exponent + 112) << 23) | // Exponent
(Mantissa << 13); // Mantissa
return *(float *)&Result;
}
} // namespace poly

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@ -25,6 +25,7 @@ namespace poly {
// return value is the size of the input operand (8, 16, 32, or 64). If the most // return value is the size of the input operand (8, 16, 32, or 64). If the most
// significant bit of value is one, the return value is zero. // significant bit of value is one, the return value is zero.
#if XE_COMPILER_MSVC #if XE_COMPILER_MSVC
#if 1
inline uint8_t lzcnt(uint8_t v) { inline uint8_t lzcnt(uint8_t v) {
return static_cast<uint8_t>(__lzcnt16(v) - 8); return static_cast<uint8_t>(__lzcnt16(v) - 8);
} }
@ -32,6 +33,32 @@ inline uint8_t lzcnt(uint16_t v) { return static_cast<uint8_t>(__lzcnt16(v)); }
inline uint8_t lzcnt(uint32_t v) { return static_cast<uint8_t>(__lzcnt(v)); } inline uint8_t lzcnt(uint32_t v) { return static_cast<uint8_t>(__lzcnt(v)); }
inline uint8_t lzcnt(uint64_t v) { return static_cast<uint8_t>(__lzcnt64(v)); } inline uint8_t lzcnt(uint64_t v) { return static_cast<uint8_t>(__lzcnt64(v)); }
#else #else
inline uint8_t lzcnt(uint8_t v) {
DWORD index;
DWORD mask = v;
BOOLEAN is_nonzero = _BitScanReverse(&index, mask);
return static_cast<uint8_t>(is_nonzero ? int8_t(index - 24) ^ 0x7 : 8);
}
inline uint8_t lzcnt(uint16_t v) {
DWORD index;
DWORD mask = v;
BOOLEAN is_nonzero = _BitScanReverse(&index, mask);
return static_cast<uint8_t>(is_nonzero ? int8_t(index - 16) ^ 0xF : 16);
}
inline uint8_t lzcnt(uint32_t v) {
DWORD index;
DWORD mask = v;
BOOLEAN is_nonzero = _BitScanReverse(&index, mask);
return static_cast<uint8_t>(is_nonzero ? int8_t(index) ^ 0x1F : 32);
}
inline uint8_t lzcnt(uint64_t v) {
DWORD index;
DWORD64 mask = v;
BOOLEAN is_nonzero = _BitScanReverse64(&index, mask);
return static_cast<uint8_t>(is_nonzero ? int8_t(index) ^ 0x3F : 64);
}
#endif // LZCNT supported
#else
inline uint8_t lzcnt(uint8_t v) { inline uint8_t lzcnt(uint8_t v) {
return static_cast<uint8_t>(__builtin_clzs(v) - 8); return static_cast<uint8_t>(__builtin_clzs(v) - 8);
} }
@ -121,6 +148,9 @@ int64_t m128_i64(const __m128& v) {
return m128_i64<N>(_mm_castps_pd(v)); return m128_i64<N>(_mm_castps_pd(v));
} }
uint16_t float_to_half(float value);
float half_to_float(uint16_t value);
} // namespace poly } // namespace poly
#endif // POLY_MATH_H_ #endif // POLY_MATH_H_

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@ -5,6 +5,7 @@
'atomic.h', 'atomic.h',
'config.h', 'config.h',
'cxx_compat.h', 'cxx_compat.h',
'math.cc',
'math.h', 'math.h',
'platform.h', 'platform.h',
'poly-private.h', 'poly-private.h',

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@ -18,6 +18,9 @@
namespace poly { namespace poly {
namespace threading { namespace threading {
// Gets the current high-perforance tick count.
uint64_t ticks();
// Gets a stable thread-specific ID, but may not be. Use for informative // Gets a stable thread-specific ID, but may not be. Use for informative
// purposes only. // purposes only.
uint32_t current_thread_id(); uint32_t current_thread_id();

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@ -9,12 +9,16 @@
#include <poly/threading.h> #include <poly/threading.h>
#include <mach/mach.h>
#include <mach/mach_time.h>
#include <pthread.h> #include <pthread.h>
#include <time.h> #include <time.h>
namespace poly { namespace poly {
namespace threading { namespace threading {
uint64_t ticks() { return mach_absolute_time(); }
uint32_t current_thread_id() { uint32_t current_thread_id() {
mach_port_t tid = pthread_mach_thread_np(pthread_self()); mach_port_t tid = pthread_mach_thread_np(pthread_self());
return static_cast<uint32_t>(tid); return static_cast<uint32_t>(tid);

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@ -14,6 +14,15 @@
namespace poly { namespace poly {
namespace threading { namespace threading {
uint64_t ticks() {
LARGE_INTEGER counter;
uint64_t time = 0;
if (QueryPerformanceCounter(&counter)) {
time = counter.QuadPart;
}
return time;
}
uint32_t current_thread_id() { uint32_t current_thread_id() {
return static_cast<uint32_t>(GetCurrentThreadId()); return static_cast<uint32_t>(GetCurrentThreadId());
} }

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@ -11,6 +11,7 @@
#define XENIA_TYPES_H_ #define XENIA_TYPES_H_
#include <cstdint> #include <cstdint>
#include <functional>
#include <xenia/platform.h> #include <xenia/platform.h>