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Ryujinx/ARMeilleure/Instructions/SoftFallback.cs
gdkchan a731ab3a2a Add a new JIT compiler for CPU code (#693)
* Start of the ARMeilleure project

* Refactoring around the old IRAdapter, now renamed to PreAllocator

* Optimize the LowestBitSet method

* Add CLZ support and fix CLS implementation

* Add missing Equals and GetHashCode overrides on some structs, misc small tweaks

* Implement the ByteSwap IR instruction, and some refactoring on the assembler

* Implement the DivideUI IR instruction and fix 64-bits IDIV

* Correct constant operand type on CSINC

* Move division instructions implementation to InstEmitDiv

* Fix destination type for the ConditionalSelect IR instruction

* Implement UMULH and SMULH, with new IR instructions

* Fix some issues with shift instructions

* Fix constant types for BFM instructions

* Fix up new tests using the new V128 struct

* Update tests

* Move DIV tests to a separate file

* Add support for calls, and some instructions that depends on them

* Start adding support for SIMD & FP types, along with some of the related ARM instructions

* Fix some typos and the divide instruction with FP operands

* Fix wrong method call on Clz_V

* Implement ARM FP & SIMD move instructions, Saddlv_V, and misc. fixes

* Implement SIMD logical instructions and more misc. fixes

* Fix PSRAD x86 instruction encoding, TRN, UABD and UABDL implementations

* Implement float conversion instruction, merge in LDj3SNuD fixes, and some other misc. fixes

* Implement SIMD shift instruction and fix Dup_V

* Add SCVTF and UCVTF (vector, fixed-point) variants to the opcode table

* Fix check with tolerance on tester

* Implement FP & SIMD comparison instructions, and some fixes

* Update FCVT (Scalar) encoding on the table to support the Half-float variants

* Support passing V128 structs, some cleanup on the register allocator, merge LDj3SNuD fixes

* Use old memory access methods, made a start on SIMD memory insts support, some fixes

* Fix float constant passed to functions, save and restore non-volatile XMM registers, other fixes

* Fix arguments count with struct return values, other fixes

* More instructions

* Misc. fixes and integrate LDj3SNuD fixes

* Update tests

* Add a faster linear scan allocator, unwinding support on windows, and other changes

* Update Ryujinx.HLE

* Update Ryujinx.Graphics

* Fix V128 return pointer passing, RCX is clobbered

* Update Ryujinx.Tests

* Update ITimeZoneService

* Stop using GetFunctionPointer as that can't be called from native code, misc. fixes and tweaks

* Use generic GetFunctionPointerForDelegate method and other tweaks

* Some refactoring on the code generator, assert on invalid operations and use a separate enum for intrinsics

* Remove some unused code on the assembler

* Fix REX.W prefix regression on float conversion instructions, add some sort of profiler

* Add hardware capability detection

* Fix regression on Sha1h and revert Fcm** changes

* Add SSE2-only paths on vector extract and insert, some refactoring on the pre-allocator

* Fix silly mistake introduced on last commit on CpuId

* Generate inline stack probes when the stack allocation is too large

* Initial support for the System-V ABI

* Support multiple destination operands

* Fix SSE2 VectorInsert8 path, and other fixes

* Change placement of XMM callee save and restore code to match other compilers

* Rename Dest to Destination and Inst to Instruction

* Fix a regression related to calls and the V128 type

* Add an extra space on comments to match code style

* Some refactoring

* Fix vector insert FP32 SSE2 path

* Port over the ARM32 instructions

* Avoid memory protection races on JIT Cache

* Another fix on VectorInsert FP32 (thanks to LDj3SNuD

* Float operands don't need to use the same register when VEX is supported

* Add a new register allocator, higher quality code for hot code (tier up), and other tweaks

* Some nits, small improvements on the pre allocator

* CpuThreadState is gone

* Allow changing CPU emulators with a config entry

* Add runtime identifiers on the ARMeilleure project

* Allow switching between CPUs through a config entry (pt. 2)

* Change win10-x64 to win-x64 on projects

* Update the Ryujinx project to use ARMeilleure

* Ensure that the selected register is valid on the hybrid allocator

* Allow exiting on returns to 0 (should fix test regression)

* Remove register assignments for most used variables on the hybrid allocator

* Do not use fixed registers as spill temp

* Add missing namespace and remove unneeded using

* Address PR feedback

* Fix types, etc

* Enable AssumeStrictAbiCompliance by default

* Ensure that Spill and Fill don't load or store any more than necessary
2019-08-08 21:56:22 +03:00

1307 lines
36 KiB
C#

using ARMeilleure.State;
using System;
namespace ARMeilleure.Instructions
{
static class SoftFallback
{
#region "ShlReg"
public static long SignedShlReg(long value, long shift, bool round, int size)
{
int eSize = 8 << size;
int shiftLsB = (sbyte)shift;
if (shiftLsB < 0)
{
return SignedShrReg(value, -shiftLsB, round, eSize);
}
else if (shiftLsB > 0)
{
if (shiftLsB >= eSize)
{
return 0L;
}
return value << shiftLsB;
}
else /* if (shiftLsB == 0) */
{
return value;
}
}
public static ulong UnsignedShlReg(ulong value, ulong shift, bool round, int size)
{
int eSize = 8 << size;
int shiftLsB = (sbyte)shift;
if (shiftLsB < 0)
{
return UnsignedShrReg(value, -shiftLsB, round, eSize);
}
else if (shiftLsB > 0)
{
if (shiftLsB >= eSize)
{
return 0UL;
}
return value << shiftLsB;
}
else /* if (shiftLsB == 0) */
{
return value;
}
}
public static long SignedShlRegSatQ(long value, long shift, bool round, int size)
{
ExecutionContext context = NativeInterface.GetContext();
int eSize = 8 << size;
int shiftLsB = (sbyte)shift;
if (shiftLsB < 0)
{
return SignedShrReg(value, -shiftLsB, round, eSize);
}
else if (shiftLsB > 0)
{
if (shiftLsB >= eSize)
{
return SignedSignSatQ(value, eSize, context);
}
if (eSize == 64)
{
long shl = value << shiftLsB;
long shr = shl >> shiftLsB;
if (shr != value)
{
return SignedSignSatQ(value, eSize, context);
}
else /* if (shr == value) */
{
return shl;
}
}
else /* if (eSize != 64) */
{
return SignedSrcSignedDstSatQ(value << shiftLsB, size);
}
}
else /* if (shiftLsB == 0) */
{
return value;
}
}
public static ulong UnsignedShlRegSatQ(ulong value, ulong shift, bool round, int size)
{
ExecutionContext context = NativeInterface.GetContext();
int eSize = 8 << size;
int shiftLsB = (sbyte)shift;
if (shiftLsB < 0)
{
return UnsignedShrReg(value, -shiftLsB, round, eSize);
}
else if (shiftLsB > 0)
{
if (shiftLsB >= eSize)
{
return UnsignedSignSatQ(value, eSize, context);
}
if (eSize == 64)
{
ulong shl = value << shiftLsB;
ulong shr = shl >> shiftLsB;
if (shr != value)
{
return UnsignedSignSatQ(value, eSize, context);
}
else /* if (shr == value) */
{
return shl;
}
}
else /* if (eSize != 64) */
{
return UnsignedSrcUnsignedDstSatQ(value << shiftLsB, size);
}
}
else /* if (shiftLsB == 0) */
{
return value;
}
}
private static long SignedShrReg(long value, int shift, bool round, int eSize) // shift := [1, 128]; eSize := {8, 16, 32, 64}.
{
if (round)
{
if (shift >= eSize)
{
return 0L;
}
long roundConst = 1L << (shift - 1);
long add = value + roundConst;
if (eSize == 64)
{
if ((~value & (value ^ add)) < 0L)
{
return (long)((ulong)add >> shift);
}
else
{
return add >> shift;
}
}
else /* if (eSize != 64) */
{
return add >> shift;
}
}
else /* if (!round) */
{
if (shift >= eSize)
{
if (value < 0L)
{
return -1L;
}
else /* if (value >= 0L) */
{
return 0L;
}
}
return value >> shift;
}
}
private static ulong UnsignedShrReg(ulong value, int shift, bool round, int eSize) // shift := [1, 128]; eSize := {8, 16, 32, 64}.
{
if (round)
{
if (shift > 64)
{
return 0UL;
}
ulong roundConst = 1UL << (shift - 1);
ulong add = value + roundConst;
if (eSize == 64)
{
if ((add < value) && (add < roundConst))
{
if (shift == 64)
{
return 1UL;
}
return (add >> shift) | (0x8000000000000000UL >> (shift - 1));
}
else
{
if (shift == 64)
{
return 0UL;
}
return add >> shift;
}
}
else /* if (eSize != 64) */
{
if (shift == 64)
{
return 0UL;
}
return add >> shift;
}
}
else /* if (!round) */
{
if (shift >= eSize)
{
return 0UL;
}
return value >> shift;
}
}
private static long SignedSignSatQ(long op, int eSize, ExecutionContext context) // eSize := {8, 16, 32, 64}.
{
long tMaxValue = (1L << (eSize - 1)) - 1L;
long tMinValue = -(1L << (eSize - 1));
if (op > 0L)
{
context.Fpsr |= FPSR.Qc;
return tMaxValue;
}
else if (op < 0L)
{
context.Fpsr |= FPSR.Qc;
return tMinValue;
}
else
{
return 0L;
}
}
private static ulong UnsignedSignSatQ(ulong op, int eSize, ExecutionContext context) // eSize := {8, 16, 32, 64}.
{
ulong tMaxValue = ulong.MaxValue >> (64 - eSize);
if (op > 0UL)
{
context.Fpsr |= FPSR.Qc;
return tMaxValue;
}
else
{
return 0UL;
}
}
#endregion
#region "ShrImm64"
public static long SignedShrImm64(long value, long roundConst, int shift)
{
if (roundConst == 0L)
{
if (shift <= 63)
{
return value >> shift;
}
else /* if (shift == 64) */
{
if (value < 0L)
{
return -1L;
}
else /* if (value >= 0L) */
{
return 0L;
}
}
}
else /* if (roundConst == 1L << (shift - 1)) */
{
if (shift <= 63)
{
long add = value + roundConst;
if ((~value & (value ^ add)) < 0L)
{
return (long)((ulong)add >> shift);
}
else
{
return add >> shift;
}
}
else /* if (shift == 64) */
{
return 0L;
}
}
}
public static ulong UnsignedShrImm64(ulong value, long roundConst, int shift)
{
if (roundConst == 0L)
{
if (shift <= 63)
{
return value >> shift;
}
else /* if (shift == 64) */
{
return 0UL;
}
}
else /* if (roundConst == 1L << (shift - 1)) */
{
ulong add = value + (ulong)roundConst;
if ((add < value) && (add < (ulong)roundConst))
{
if (shift <= 63)
{
return (add >> shift) | (0x8000000000000000UL >> (shift - 1));
}
else /* if (shift == 64) */
{
return 1UL;
}
}
else
{
if (shift <= 63)
{
return add >> shift;
}
else /* if (shift == 64) */
{
return 0UL;
}
}
}
}
#endregion
#region "Rounding"
public static double Round(double value)
{
ExecutionContext context = NativeInterface.GetContext();
FPRoundingMode roundMode = context.Fpcr.GetRoundingMode();
if (roundMode == FPRoundingMode.ToNearest)
{
return Math.Round(value); // even
}
else if (roundMode == FPRoundingMode.TowardsPlusInfinity)
{
return Math.Ceiling(value);
}
else if (roundMode == FPRoundingMode.TowardsMinusInfinity)
{
return Math.Floor(value);
}
else /* if (roundMode == FPRoundingMode.TowardsZero) */
{
return Math.Truncate(value);
}
}
public static float RoundF(float value)
{
ExecutionContext context = NativeInterface.GetContext();
FPRoundingMode roundMode = context.Fpcr.GetRoundingMode();
if (roundMode == FPRoundingMode.ToNearest)
{
return MathF.Round(value); // even
}
else if (roundMode == FPRoundingMode.TowardsPlusInfinity)
{
return MathF.Ceiling(value);
}
else if (roundMode == FPRoundingMode.TowardsMinusInfinity)
{
return MathF.Floor(value);
}
else /* if (roundMode == FPRoundingMode.TowardsZero) */
{
return MathF.Truncate(value);
}
}
#endregion
#region "Saturation"
public static int SatF32ToS32(float value)
{
if (float.IsNaN(value)) return 0;
return value >= int.MaxValue ? int.MaxValue :
value <= int.MinValue ? int.MinValue : (int)value;
}
public static long SatF32ToS64(float value)
{
if (float.IsNaN(value)) return 0;
return value >= long.MaxValue ? long.MaxValue :
value <= long.MinValue ? long.MinValue : (long)value;
}
public static uint SatF32ToU32(float value)
{
if (float.IsNaN(value)) return 0;
return value >= uint.MaxValue ? uint.MaxValue :
value <= uint.MinValue ? uint.MinValue : (uint)value;
}
public static ulong SatF32ToU64(float value)
{
if (float.IsNaN(value)) return 0;
return value >= ulong.MaxValue ? ulong.MaxValue :
value <= ulong.MinValue ? ulong.MinValue : (ulong)value;
}
public static int SatF64ToS32(double value)
{
if (double.IsNaN(value)) return 0;
return value >= int.MaxValue ? int.MaxValue :
value <= int.MinValue ? int.MinValue : (int)value;
}
public static long SatF64ToS64(double value)
{
if (double.IsNaN(value)) return 0;
return value >= long.MaxValue ? long.MaxValue :
value <= long.MinValue ? long.MinValue : (long)value;
}
public static uint SatF64ToU32(double value)
{
if (double.IsNaN(value)) return 0;
return value >= uint.MaxValue ? uint.MaxValue :
value <= uint.MinValue ? uint.MinValue : (uint)value;
}
public static ulong SatF64ToU64(double value)
{
if (double.IsNaN(value)) return 0;
return value >= ulong.MaxValue ? ulong.MaxValue :
value <= ulong.MinValue ? ulong.MinValue : (ulong)value;
}
#endregion
#region "Saturating"
public static long SignedSrcSignedDstSatQ(long op, int size)
{
ExecutionContext context = NativeInterface.GetContext();
int eSize = 8 << size;
long tMaxValue = (1L << (eSize - 1)) - 1L;
long tMinValue = -(1L << (eSize - 1));
if (op > tMaxValue)
{
context.Fpsr |= FPSR.Qc;
return tMaxValue;
}
else if (op < tMinValue)
{
context.Fpsr |= FPSR.Qc;
return tMinValue;
}
else
{
return op;
}
}
public static ulong SignedSrcUnsignedDstSatQ(long op, int size)
{
ExecutionContext context = NativeInterface.GetContext();
int eSize = 8 << size;
ulong tMaxValue = (1UL << eSize) - 1UL;
ulong tMinValue = 0UL;
if (op > (long)tMaxValue)
{
context.Fpsr |= FPSR.Qc;
return tMaxValue;
}
else if (op < (long)tMinValue)
{
context.Fpsr |= FPSR.Qc;
return tMinValue;
}
else
{
return (ulong)op;
}
}
public static long UnsignedSrcSignedDstSatQ(ulong op, int size)
{
ExecutionContext context = NativeInterface.GetContext();
int eSize = 8 << size;
long tMaxValue = (1L << (eSize - 1)) - 1L;
if (op > (ulong)tMaxValue)
{
context.Fpsr |= FPSR.Qc;
return tMaxValue;
}
else
{
return (long)op;
}
}
public static ulong UnsignedSrcUnsignedDstSatQ(ulong op, int size)
{
ExecutionContext context = NativeInterface.GetContext();
int eSize = 8 << size;
ulong tMaxValue = (1UL << eSize) - 1UL;
if (op > tMaxValue)
{
context.Fpsr |= FPSR.Qc;
return tMaxValue;
}
else
{
return op;
}
}
public static long UnarySignedSatQAbsOrNeg(long op)
{
ExecutionContext context = NativeInterface.GetContext();
if (op == long.MinValue)
{
context.Fpsr |= FPSR.Qc;
return long.MaxValue;
}
else
{
return op;
}
}
public static long BinarySignedSatQAdd(long op1, long op2)
{
ExecutionContext context = NativeInterface.GetContext();
long add = op1 + op2;
if ((~(op1 ^ op2) & (op1 ^ add)) < 0L)
{
context.Fpsr |= FPSR.Qc;
if (op1 < 0L)
{
return long.MinValue;
}
else
{
return long.MaxValue;
}
}
else
{
return add;
}
}
public static ulong BinaryUnsignedSatQAdd(ulong op1, ulong op2)
{
ExecutionContext context = NativeInterface.GetContext();
ulong add = op1 + op2;
if ((add < op1) && (add < op2))
{
context.Fpsr |= FPSR.Qc;
return ulong.MaxValue;
}
else
{
return add;
}
}
public static long BinarySignedSatQSub(long op1, long op2)
{
ExecutionContext context = NativeInterface.GetContext();
long sub = op1 - op2;
if (((op1 ^ op2) & (op1 ^ sub)) < 0L)
{
context.Fpsr |= FPSR.Qc;
if (op1 < 0L)
{
return long.MinValue;
}
else
{
return long.MaxValue;
}
}
else
{
return sub;
}
}
public static ulong BinaryUnsignedSatQSub(ulong op1, ulong op2)
{
ExecutionContext context = NativeInterface.GetContext();
ulong sub = op1 - op2;
if (op1 < op2)
{
context.Fpsr |= FPSR.Qc;
return ulong.MinValue;
}
else
{
return sub;
}
}
public static long BinarySignedSatQAcc(ulong op1, long op2)
{
ExecutionContext context = NativeInterface.GetContext();
if (op1 <= (ulong)long.MaxValue)
{
// op1 from ulong.MinValue to (ulong)long.MaxValue
// op2 from long.MinValue to long.MaxValue
long add = (long)op1 + op2;
if ((~op2 & add) < 0L)
{
context.Fpsr |= FPSR.Qc;
return long.MaxValue;
}
else
{
return add;
}
}
else if (op2 >= 0L)
{
// op1 from (ulong)long.MaxValue + 1UL to ulong.MaxValue
// op2 from (long)ulong.MinValue to long.MaxValue
context.Fpsr |= FPSR.Qc;
return long.MaxValue;
}
else
{
// op1 from (ulong)long.MaxValue + 1UL to ulong.MaxValue
// op2 from long.MinValue to (long)ulong.MinValue - 1L
ulong add = op1 + (ulong)op2;
if (add > (ulong)long.MaxValue)
{
context.Fpsr |= FPSR.Qc;
return long.MaxValue;
}
else
{
return (long)add;
}
}
}
public static ulong BinaryUnsignedSatQAcc(long op1, ulong op2)
{
ExecutionContext context = NativeInterface.GetContext();
if (op1 >= 0L)
{
// op1 from (long)ulong.MinValue to long.MaxValue
// op2 from ulong.MinValue to ulong.MaxValue
ulong add = (ulong)op1 + op2;
if ((add < (ulong)op1) && (add < op2))
{
context.Fpsr |= FPSR.Qc;
return ulong.MaxValue;
}
else
{
return add;
}
}
else if (op2 > (ulong)long.MaxValue)
{
// op1 from long.MinValue to (long)ulong.MinValue - 1L
// op2 from (ulong)long.MaxValue + 1UL to ulong.MaxValue
return (ulong)op1 + op2;
}
else
{
// op1 from long.MinValue to (long)ulong.MinValue - 1L
// op2 from ulong.MinValue to (ulong)long.MaxValue
long add = op1 + (long)op2;
if (add < (long)ulong.MinValue)
{
context.Fpsr |= FPSR.Qc;
return ulong.MinValue;
}
else
{
return (ulong)add;
}
}
}
#endregion
#region "Count"
public static ulong CountLeadingSigns(ulong value, int size) // size is 8, 16, 32 or 64 (SIMD&FP or Base Inst.).
{
value ^= value >> 1;
int highBit = size - 2;
for (int bit = highBit; bit >= 0; bit--)
{
if (((int)(value >> bit) & 0b1) != 0)
{
return (ulong)(highBit - bit);
}
}
return (ulong)(size - 1);
}
private static readonly byte[] ClzNibbleTbl = { 4, 3, 2, 2, 1, 1, 1, 1, 0, 0, 0, 0, 0, 0, 0, 0 };
public static ulong CountLeadingZeros(ulong value, int size) // size is 8, 16, 32 or 64 (SIMD&FP or Base Inst.).
{
if (value == 0ul)
{
return (ulong)size;
}
int nibbleIdx = size;
int preCount, count = 0;
do
{
nibbleIdx -= 4;
preCount = ClzNibbleTbl[(int)(value >> nibbleIdx) & 0b1111];
count += preCount;
}
while (preCount == 4);
return (ulong)count;
}
public static ulong CountSetBits8(ulong value) // "size" is 8 (SIMD&FP Inst.).
{
value = ((value >> 1) & 0x55ul) + (value & 0x55ul);
value = ((value >> 2) & 0x33ul) + (value & 0x33ul);
return (value >> 4) + (value & 0x0ful);
}
#endregion
#region "Table"
public static V128 Tbl1_V64(V128 vector, V128 tb0)
{
return Tbl(vector, 8, tb0);
}
public static V128 Tbl1_V128(V128 vector, V128 tb0)
{
return Tbl(vector, 16, tb0);
}
public static V128 Tbl2_V64(V128 vector, V128 tb0, V128 tb1)
{
return Tbl(vector, 8, tb0, tb1);
}
public static V128 Tbl2_V128(V128 vector, V128 tb0, V128 tb1)
{
return Tbl(vector, 16, tb0, tb1);
}
public static V128 Tbl3_V64(V128 vector, V128 tb0, V128 tb1, V128 tb2)
{
return Tbl(vector, 8, tb0, tb1, tb2);
}
public static V128 Tbl3_V128(V128 vector, V128 tb0, V128 tb1, V128 tb2)
{
return Tbl(vector, 16, tb0, tb1, tb2);
}
public static V128 Tbl4_V64(V128 vector, V128 tb0, V128 tb1, V128 tb2, V128 tb3)
{
return Tbl(vector, 8, tb0, tb1, tb2, tb3);
}
public static V128 Tbl4_V128(V128 vector, V128 tb0, V128 tb1, V128 tb2, V128 tb3)
{
return Tbl(vector, 16, tb0, tb1, tb2, tb3);
}
private static V128 Tbl(V128 vector, int bytes, params V128[] tb)
{
byte[] res = new byte[16];
byte[] table = new byte[tb.Length * 16];
for (byte index = 0; index < tb.Length; index++)
{
Buffer.BlockCopy(tb[index].ToArray(), 0, table, index * 16, 16);
}
byte[] v = vector.ToArray();
for (byte index = 0; index < bytes; index++)
{
byte tblIndex = v[index];
if (tblIndex < table.Length)
{
res[index] = table[tblIndex];
}
}
return new V128(res);
}
#endregion
#region "Crc32"
private const uint Crc32RevPoly = 0xedb88320;
private const uint Crc32cRevPoly = 0x82f63b78;
public static uint Crc32b(uint crc, byte value) => Crc32 (crc, Crc32RevPoly, value);
public static uint Crc32h(uint crc, ushort value) => Crc32h(crc, Crc32RevPoly, value);
public static uint Crc32w(uint crc, uint value) => Crc32w(crc, Crc32RevPoly, value);
public static uint Crc32x(uint crc, ulong value) => Crc32x(crc, Crc32RevPoly, value);
public static uint Crc32cb(uint crc, byte value) => Crc32 (crc, Crc32cRevPoly, value);
public static uint Crc32ch(uint crc, ushort value) => Crc32h(crc, Crc32cRevPoly, value);
public static uint Crc32cw(uint crc, uint value) => Crc32w(crc, Crc32cRevPoly, value);
public static uint Crc32cx(uint crc, ulong value) => Crc32x(crc, Crc32cRevPoly, value);
private static uint Crc32h(uint crc, uint poly, ushort val)
{
crc = Crc32(crc, poly, (byte)(val >> 0));
crc = Crc32(crc, poly, (byte)(val >> 8));
return crc;
}
private static uint Crc32w(uint crc, uint poly, uint val)
{
crc = Crc32(crc, poly, (byte)(val >> 0));
crc = Crc32(crc, poly, (byte)(val >> 8));
crc = Crc32(crc, poly, (byte)(val >> 16));
crc = Crc32(crc, poly, (byte)(val >> 24));
return crc;
}
private static uint Crc32x(uint crc, uint poly, ulong val)
{
crc = Crc32(crc, poly, (byte)(val >> 0));
crc = Crc32(crc, poly, (byte)(val >> 8));
crc = Crc32(crc, poly, (byte)(val >> 16));
crc = Crc32(crc, poly, (byte)(val >> 24));
crc = Crc32(crc, poly, (byte)(val >> 32));
crc = Crc32(crc, poly, (byte)(val >> 40));
crc = Crc32(crc, poly, (byte)(val >> 48));
crc = Crc32(crc, poly, (byte)(val >> 56));
return crc;
}
private static uint Crc32(uint crc, uint poly, byte val)
{
crc ^= val;
for (int bit = 7; bit >= 0; bit--)
{
uint mask = (uint)(-(int)(crc & 1));
crc = (crc >> 1) ^ (poly & mask);
}
return crc;
}
#endregion
#region "Aes"
public static V128 Decrypt(V128 value, V128 roundKey)
{
return CryptoHelper.AesInvSubBytes(CryptoHelper.AesInvShiftRows(value ^ roundKey));
}
public static V128 Encrypt(V128 value, V128 roundKey)
{
return CryptoHelper.AesSubBytes(CryptoHelper.AesShiftRows(value ^ roundKey));
}
public static V128 InverseMixColumns(V128 value)
{
return CryptoHelper.AesInvMixColumns(value);
}
public static V128 MixColumns(V128 value)
{
return CryptoHelper.AesMixColumns(value);
}
#endregion
#region "Sha1"
public static V128 HashChoose(V128 hash_abcd, uint hash_e, V128 wk)
{
for (int e = 0; e <= 3; e++)
{
uint t = ShaChoose(hash_abcd.GetUInt32(1),
hash_abcd.GetUInt32(2),
hash_abcd.GetUInt32(3));
hash_e += Rol(hash_abcd.GetUInt32(0), 5) + t + wk.GetUInt32(e);
t = Rol(hash_abcd.GetUInt32(1), 30);
hash_abcd.Insert(1, t);
Rol32_160(ref hash_e, ref hash_abcd);
}
return hash_abcd;
}
public static uint FixedRotate(uint hash_e)
{
return hash_e.Rol(30);
}
public static V128 HashMajority(V128 hash_abcd, uint hash_e, V128 wk)
{
for (int e = 0; e <= 3; e++)
{
uint t = ShaMajority(hash_abcd.GetUInt32(1),
hash_abcd.GetUInt32(2),
hash_abcd.GetUInt32(3));
hash_e += Rol(hash_abcd.GetUInt32(0), 5) + t + wk.GetUInt32(e);
t = Rol(hash_abcd.GetUInt32(1), 30);
hash_abcd.Insert(1, t);
Rol32_160(ref hash_e, ref hash_abcd);
}
return hash_abcd;
}
public static V128 HashParity(V128 hash_abcd, uint hash_e, V128 wk)
{
for (int e = 0; e <= 3; e++)
{
uint t = ShaParity(hash_abcd.GetUInt32(1),
hash_abcd.GetUInt32(2),
hash_abcd.GetUInt32(3));
hash_e += Rol(hash_abcd.GetUInt32(0), 5) + t + wk.GetUInt32(e);
t = Rol(hash_abcd.GetUInt32(1), 30);
hash_abcd.Insert(1, t);
Rol32_160(ref hash_e, ref hash_abcd);
}
return hash_abcd;
}
public static V128 Sha1SchedulePart1(V128 w0_3, V128 w4_7, V128 w8_11)
{
ulong t2 = w4_7.GetUInt64(0);
ulong t1 = w0_3.GetUInt64(1);
V128 result = new V128(t1, t2);
return result ^ (w0_3 ^ w8_11);
}
public static V128 Sha1SchedulePart2(V128 tw0_3, V128 w12_15)
{
V128 t = tw0_3 ^ (w12_15 >> 32);
uint tE0 = t.GetUInt32(0);
uint tE1 = t.GetUInt32(1);
uint tE2 = t.GetUInt32(2);
uint tE3 = t.GetUInt32(3);
return new V128(tE0.Rol(1), tE1.Rol(1), tE2.Rol(1), tE3.Rol(1) ^ tE0.Rol(2));
}
private static void Rol32_160(ref uint y, ref V128 x)
{
uint xE3 = x.GetUInt32(3);
x <<= 32;
x.Insert(0, y);
y = xE3;
}
private static uint ShaChoose(uint x, uint y, uint z)
{
return ((y ^ z) & x) ^ z;
}
private static uint ShaMajority(uint x, uint y, uint z)
{
return (x & y) | ((x | y) & z);
}
private static uint ShaParity(uint x, uint y, uint z)
{
return x ^ y ^ z;
}
private static uint Rol(this uint value, int count)
{
return (value << count) | (value >> (32 - count));
}
#endregion
#region "Sha256"
public static V128 HashLower(V128 hash_abcd, V128 hash_efgh, V128 wk)
{
return Sha256Hash(hash_abcd, hash_efgh, wk, part1: true);
}
public static V128 HashUpper(V128 hash_efgh, V128 hash_abcd, V128 wk)
{
return Sha256Hash(hash_abcd, hash_efgh, wk, part1: false);
}
public static V128 Sha256SchedulePart1(V128 w0_3, V128 w4_7)
{
V128 result = new V128();
for (int e = 0; e <= 3; e++)
{
uint elt = (e <= 2 ? w0_3 : w4_7).GetUInt32(e <= 2 ? e + 1 : 0);
elt = elt.Ror(7) ^ elt.Ror(18) ^ elt.Lsr(3);
elt += w0_3.GetUInt32(e);
result.Insert(e, elt);
}
return result;
}
public static V128 Sha256SchedulePart2(V128 w0_3, V128 w8_11, V128 w12_15)
{
V128 result = new V128();
ulong t1 = w12_15.GetUInt64(1);
for (int e = 0; e <= 1; e++)
{
uint elt = t1.ULongPart(e);
elt = elt.Ror(17) ^ elt.Ror(19) ^ elt.Lsr(10);
elt += w0_3.GetUInt32(e) + w8_11.GetUInt32(e + 1);
result.Insert(e, elt);
}
t1 = result.GetUInt64(0);
for (int e = 2; e <= 3; e++)
{
uint elt = t1.ULongPart(e - 2);
elt = elt.Ror(17) ^ elt.Ror(19) ^ elt.Lsr(10);
elt += w0_3.GetUInt32(e) + (e == 2 ? w8_11 : w12_15).GetUInt32(e == 2 ? 3 : 0);
result.Insert(e, elt);
}
return result;
}
private static V128 Sha256Hash(V128 x, V128 y, V128 w, bool part1)
{
for (int e = 0; e <= 3; e++)
{
uint chs = ShaChoose(y.GetUInt32(0),
y.GetUInt32(1),
y.GetUInt32(2));
uint maj = ShaMajority(x.GetUInt32(0),
x.GetUInt32(1),
x.GetUInt32(2));
uint t1 = y.GetUInt32(3) + ShaHashSigma1(y.GetUInt32(0)) + chs + w.GetUInt32(e);
uint t2 = t1 + x.GetUInt32(3);
x.Insert(3, t2);
t2 = t1 + ShaHashSigma0(x.GetUInt32(0)) + maj;
y.Insert(3, t2);
Rol32_256(ref y, ref x);
}
return part1 ? x : y;
}
private static void Rol32_256(ref V128 y, ref V128 x)
{
uint yE3 = y.GetUInt32(3);
uint xE3 = x.GetUInt32(3);
y <<= 32;
x <<= 32;
y.Insert(0, xE3);
x.Insert(0, yE3);
}
private static uint ShaHashSigma0(uint x)
{
return x.Ror(2) ^ x.Ror(13) ^ x.Ror(22);
}
private static uint ShaHashSigma1(uint x)
{
return x.Ror(6) ^ x.Ror(11) ^ x.Ror(25);
}
private static uint Ror(this uint value, int count)
{
return (value >> count) | (value << (32 - count));
}
private static uint Lsr(this uint value, int count)
{
return value >> count;
}
private static uint ULongPart(this ulong value, int part)
{
return part == 0
? (uint)(value & 0xFFFFFFFFUL)
: (uint)(value >> 32);
}
#endregion
#region "Reverse"
public static uint ReverseBits8(uint value)
{
value = ((value & 0xaa) >> 1) | ((value & 0x55) << 1);
value = ((value & 0xcc) >> 2) | ((value & 0x33) << 2);
return (value >> 4) | ((value & 0x0f) << 4);
}
public static uint ReverseBits32(uint value)
{
value = ((value & 0xaaaaaaaa) >> 1) | ((value & 0x55555555) << 1);
value = ((value & 0xcccccccc) >> 2) | ((value & 0x33333333) << 2);
value = ((value & 0xf0f0f0f0) >> 4) | ((value & 0x0f0f0f0f) << 4);
value = ((value & 0xff00ff00) >> 8) | ((value & 0x00ff00ff) << 8);
return (value >> 16) | (value << 16);
}
public static ulong ReverseBits64(ulong value)
{
value = ((value & 0xaaaaaaaaaaaaaaaa) >> 1 ) | ((value & 0x5555555555555555) << 1 );
value = ((value & 0xcccccccccccccccc) >> 2 ) | ((value & 0x3333333333333333) << 2 );
value = ((value & 0xf0f0f0f0f0f0f0f0) >> 4 ) | ((value & 0x0f0f0f0f0f0f0f0f) << 4 );
value = ((value & 0xff00ff00ff00ff00) >> 8 ) | ((value & 0x00ff00ff00ff00ff) << 8 );
value = ((value & 0xffff0000ffff0000) >> 16) | ((value & 0x0000ffff0000ffff) << 16);
return (value >> 32) | (value << 32);
}
public static uint ReverseBytes16_32(uint value) => (uint)ReverseBytes16_64(value);
public static ulong ReverseBytes16_64(ulong value) => ReverseBytes(value, RevSize.Rev16);
public static ulong ReverseBytes32_64(ulong value) => ReverseBytes(value, RevSize.Rev32);
private enum RevSize
{
Rev16,
Rev32,
Rev64
}
private static ulong ReverseBytes(ulong value, RevSize size)
{
value = ((value & 0xff00ff00ff00ff00) >> 8) | ((value & 0x00ff00ff00ff00ff) << 8);
if (size == RevSize.Rev16)
{
return value;
}
value = ((value & 0xffff0000ffff0000) >> 16) | ((value & 0x0000ffff0000ffff) << 16);
if (size == RevSize.Rev32)
{
return value;
}
value = ((value & 0xffffffff00000000) >> 32) | ((value & 0x00000000ffffffff) << 32);
if (size == RevSize.Rev64)
{
return value;
}
throw new ArgumentException(nameof(size));
}
#endregion
}
}