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/**************************** emulator5.cpp ******************************** * Author: Agner Fog * date created: 2018-02-18 * Last modified: 2021-06-30 * Version: 1.11 * Project: Binary tools for ForwardCom instruction set * Description: * Emulator: Execution functions for single format instructions, continued * * Copyright 2018-2021 GNU General Public License http://www.gnu.org/licenses *****************************************************************************/ #include "stdafx.h" // Format 1.3 B. Two vector registers and a broadcast 8-bit immediate operand. static uint64_t gp2vec (CThread * t) { // Move value of general purpose register RS to scalar in vector register RD. uint8_t rd = t->operands[0]; uint8_t rs = t->operands[4]; uint64_t result = t->registers[rs]; // read general purpose register t->vectorLength[rd] = dataSizeTable[t->operandType]; // set length of destination t->vect = 4; // stop vector loop return result; } static uint64_t vec2gp (CThread * t) { // Move value of first element of vector register RS to general purpose register RD. uint8_t rd = t->operands[0]; uint8_t rs = t->operands[4]; uint8_t size = dataSizeTable[t->operandType]; if (size > t->vectorLength[rs]) size = t->vectorLength[rs]; // limit size to vector length uint64_t result = *(uint64_t*)(t->vectors.buf() + t->MaxVectorLength*rs); // read directly from vector if (size < 8) result &= ((uint64_t)1 << size*8) - 1; // mask off to size t->registers[rd] = result; // write to general purpose register t->vect = 4; // stop vector loop t->running = 2; // don't save RD t->returnType &= ~ 0x100; // debug return type not vector return result; } static uint64_t make_sequence (CThread * t) { // Make a vector with RS sequential numbers. First value is IM1. uint8_t rd = t->operands[0]; uint8_t rs = t->operands[4]; int32_t val = int8_t(t->pInstr->b[0]); // immediate operand, sign extended integer uint64_t num = t->registers[rs]; // number of elements uint32_t elementSize = dataSizeTable[t->operandType]; uint8_t dsizelog = dataSizeTableLog[t->operandType]; // log2(elementsize) SNum temp; // limit length uint64_t length = num << dsizelog; if (length > t->MaxVectorLength) { length = t->MaxVectorLength; num = length >> dsizelog; } // set length of rd t->vectorLength[rd] = (uint32_t)length; // loop through destination vector for (uint32_t pos = 0; pos < length; pos += elementSize) { switch (t->operandType) { case 0: case 1: case 2: case 3: t->writeVectorElement(rd, (uint64_t)(int64_t)val, pos); break; case 4: t->writeVectorElement(rd, (uint64_t)(int64_t)val, pos); // int128 t->writeVectorElement(rd, (uint64_t)((int64_t)val >> 63), pos+8); break; case 5: // float temp.f = float(val); // convert to float t->writeVectorElement(rd, temp.q, pos); break; case 6: // double temp.d = double(val); // convert to double t->writeVectorElement(rd, temp.q, pos); break; default: t->interrupt(INT_WRONG_PARAMETERS); } val++; // increment value } t->vect = 4; // stop vector loop t->running = 2; // don't save RD return 0; } static uint64_t compress(CThread * t) { // Compress vector RT of length RS to a vector of half the length and half the element size. // Double precision -> single precision, 64-bit integer -> 32-bit integer, etc. // operands: uint8_t rd = t->operands[0]; uint8_t rs = t->operands[4]; uint8_t IM1 = t->parm[4].b; if (IM1 & 0xC0) t->interrupt(INT_WRONG_PARAMETERS); //uint32_t initLength = t->vectorLength[rt]; uint32_t oldLength = t->vectorLength[rs]; // (uint32_t)t->registers[rs]; uint32_t newLength = oldLength / 2; uint32_t pos; // position in destination vector uint8_t overflowU = 0; // unsigned overflow in current element uint8_t overflowS = 0; // signed overflow in current element uint8_t overflowU2 = 0; // unsigned overflow in any element uint8_t overflowS2 = 0; // signed overflow in any element uint8_t overflowF2 = 0; // floating point overflow in any element SNum mask = t->parm[3]; // options mask int8_t * source = t->vectors.buf() + (uint64_t)rs * t->MaxVectorLength; // address of RS data int8_t * destination = t->vectors.buf() + (uint64_t)rd * t->MaxVectorLength; // address of RD data uint8_t roundingMode = (IM1 >> 3) & 7; // floating point rounding mode if (roundingMode == 0) roundingMode = ((t->parm[3].i >> MSKI_ROUNDING) & 7) | 4; uint8_t exceptionControl = IM1 & 7; // floating point exception enable bits: // 1: overflow, 2: underflow, 4: inexact if (exceptionControl == 0) { // floating point exception control exceptionControl = mask.i >> (MSKI_EXCEPTIONS + 1) & 7; // exceptions from NUMCONTR } else if (exceptionControl == 7) { exceptionControl = 0; // 7 means none (5 means all) } switch (t->operandType) { // source operand type case 0: // int8 -> int4 for (pos = 0; pos < newLength; pos += 1) { union { uint16_t s; uint8_t b[2]; } u; u.s = *(uint16_t*)(source + 2*pos); // two values to convert to one byte for (int i = 0; i < 2; i++) { // loop for two bytes to convert uint8_t val = u.b[i]; overflowU = val > 0x0F; // unsigned overflow overflowS = val - 0xF8 > 0x0F; // signed overflow overflowU2 |= overflowU; overflowS2 |= overflowS; switch (IM1 & 7) { case 0: default: // wrap around break; case 4: // signed integer overflow gives zero if (overflowS) val = 0; break; case 5: // signed integer overflow gives signed saturation if (overflowS) val = 0x7 + (val >> 7); break; case 6: // unsigned integer overflow gives zero if (overflowU) val = 0; break; case 7: // unsigned integer overflow gives unsigned saturation if (overflowU) val = 0xF; break; } u.b[i] = val; } uint8_t val2 = (u.b[0] & 0xF) | u.b[1] << 4; *(uint8_t*)(destination + pos) = val2; // store two values } t->returnType = 0x110; break; case 1: // int16 -> int8 for (pos = 0; pos < newLength; pos += 1) { uint16_t val = *(uint16_t*)(source + 2*pos); // value to convert overflowU = val > 0xFF; // unsigned overflow overflowS = val - 0xFF80 > 0xFF; // signed overflow overflowU2 |= overflowU; overflowS2 |= overflowS; switch (IM1 & 7) { case 0: default: // wrap around break; case 4: // signed integer overflow gives zero if (overflowS) val = 0; break; case 5: // signed integer overflow gives signed saturation if (overflowS) val = 0x7F + (val >> 15); break; case 6: // unsigned integer overflow gives zero if (overflowU) val = 0; break; case 7: // unsigned integer overflow gives unsigned saturation if (overflowU) val = 0xFF; break; } *(uint8_t*)(destination + pos) = (uint8_t)val; // store value } t->returnType = 0x110; break; case 2: // int32 -> int16 for (pos = 0; pos < newLength; pos += 2) { uint32_t val = *(uint32_t*)(source + 2*pos); // value to convert overflowU = val > 0xFFFF; // unsigned overflow overflowS = val - 0xFFFF8000 > 0xFFFF; // signed overflow switch (IM1 & 7) { case 0: default: // wrap around break; case 4: // signed integer overflow gives zero if (overflowS) val = 0; break; case 5: // signed integer overflow gives signed saturation if (overflowS) val = 0x7FFF + (val >> 31); break; case 6: // unsigned integer overflow gives zero if (overflowU) val = 0; break; case 7: // unsigned integer overflow gives unsigned saturation if (overflowU) val = 0xFFFF; break; } *(uint16_t*)(destination + pos) = (uint16_t)val; // store value } t->returnType = 0x111; break; case 3: // int64 -> int32 for (pos = 0; pos < newLength; pos += 4) { uint64_t val = *(uint64_t*)(source + 2*pos); // value to convert overflowU = val > 0xFFFFFFFFU; // unsigned overflow overflowS = val - 0xFFFFFFFF80000000 > 0xFFFFFFFFU; // signed overflow switch (IM1 & 7) { case 0: default: // wrap around break; case 4: // signed integer overflow gives zero if (overflowS) val = 0; break; case 5: // signed integer overflow gives signed saturation if (overflowS) val = 0x7FFFFFFF + (val >> 63); break; case 6: // unsigned integer overflow gives zero if (overflowU) val = 0; break; case 7: // unsigned integer overflow gives unsigned saturation if (overflowU) val = 0xFFFFFFFF; break; } *(uint32_t*)(destination + pos) = (uint32_t)val; // store value } t->returnType = 0x112; break; case 4: // int128 -> int64 for (pos = 0; pos < newLength; pos += 8) { uint64_t valLo = *(uint64_t*)(source + 2*pos); // value to convert, low part uint64_t valHi = *(uint64_t*)(source + 2*pos + 8); // value to convert, high part overflowU = valHi != 0; // unsigned overflow if ((int64_t)valLo < 0) overflowS = valHi+1 != 0; // signed overflow else overflowS = valHi != 0; overflowU2 |= overflowU; overflowS2 |= overflowS; switch (IM1 & 7) { case 0: default: // wrap around break; case 4: // signed integer overflow gives zero if (overflowS) valLo = 0; break; case 5: // signed integer overflow gives signed saturation if (overflowS) valLo = nsign_d + (valHi >> 63); break; case 6: // unsigned integer overflow gives zero if (overflowU) valHi = valLo = 0; break; case 7: // unsigned integer overflow gives unsigned saturation if (overflowU) valLo = 0xFFFFFFFFFFFFFFFF; break; } } t->returnType = 0x113; break; case 5: // float -> float16 for (pos = 0; pos < newLength; pos += 2) { SNum val; val.i = *(uint32_t*)(source + 2 * pos); // value to convert uint16_t val2 = float2half(val.f); // convert to half precision if (!isnan_or_inf_f(val.i)) { // check rounding mode switch (roundingMode) { case 1: // odd if not exact if (half2float(val2) != val.f) val2 |= 1; break; case 4: default: // nearest or even break; case 5: // down if (half2float(val2) > val.f) { if (val2 << 1 == 0) val2 = 0x8001; // 0 -> subnormal negative else if (int16_t(val2) > 0) val2--; else val2++; } break; case 6: // up if (half2float(val2) < val.f) { if (val2 << 1 == 0) val2 = 0x0001; // 0 -> subnormal positive else if (int16_t(val2) > 0) val2++; else val2--; } break; case 7: // towards zero if (half2float(val2) != val.f && (val2 << 1 != 0)) { val2--; } break; } // check overflow overflowS = (val2 & 0x7FFF) == 0x7C00 && !isinf_f(val.i);// detect overflow overflowF2 |= overflowS; if (overflowS) { // check for overflow if (exceptionControl & 1) { // overflow exception -> NAN val2 = (uint16_t)t->makeNan(nan_overflow_conv, 1); // overflow } } else if ((exceptionControl & 6) && val2 << 1 == 0 && val.f != 0.f) { val2 = (uint16_t)t->makeNan(nan_underflow, 1); // underflow exception (inexact implies underflow) } else if ((exceptionControl & 4) && half2float(val2) != val.f) { val2 = (uint16_t)t->makeNan(nan_inexact, 1); // inexact exception } } *(uint16_t*)(destination + pos) = val2; // store value } t->returnType = 0x118; break; case 6: // double -> float for (pos = 0; pos < newLength; pos += 4) { SNum val1, val2; val1.q = *(uint64_t*)(source + 2 * pos); // value to convert // check NAN and INF if (isnan_or_inf_d(val1.q)) { union { // single precision float float f; struct { // structure of a NAN uint32_t payload : 22; uint32_t quiet : 1; uint32_t expo : 8; uint32_t sign : 1; }; } u; u.payload = val1.i & ((1 << 22) - 1); // ForwardCom has right-justified NAN payload, unlike other binary systems u.quiet = val1.q >> 51 & 1; u.expo = 0xFF; u.sign = val1.q >> 63 & 1; val2.f = u.f; } else { val2.f = float(val1.d); // convert to single precision // check rounding mode uint8_t roundingMode = (IM1 >> 3) & 7; if (roundingMode == 0) roundingMode = ((t->parm[3].i >> MSKI_ROUNDING) & 7) | 4; switch (roundingMode) { case 1: // odd if not exact if (val2.f != val1.d) { val2.i |= 1; } break; case 4: default: // nearest or even break; case 5: // down if (val2.f > val1.d) { if (val2.f == 0.f) val2.i = 0x80000001; // 0 -> subnormal negative else if (val2.i > 0) val2.i--; else val2.i++; } break; case 6: // up if (val2.f < val1.d) { if (val2.f == 0.f) val2.i = 0x00000001; // 0 -> subnormal positive else if (val2.i > 0) val2.i++; else val2.i--; } break; case 7: // towards zero if (val2.f != val1.d && val2.f != 0.f) { val2.i--; } break; } // check overflow overflowS = isinf_f(val2.i) && !isinf_d(val1.q); // detect overflow overflowF2 |= overflowS; if (overflowS) { // check for overflow if (exceptionControl & 1) { // overflow exception -> NAN val2.q = t->makeNan(nan_overflow_conv, 5); // overflow } } else if ((exceptionControl & 6) && val2.f == 0.f && val1.d != 0.) { val2.q = t->makeNan(nan_underflow, 5); // underflow exception } else if ((exceptionControl & 4) && val2.f != val1.d) { val2.q = t->makeNan(nan_inexact, 5); // inexact exception } } *(uint32_t*)(destination + pos) = val2.i; // store value } t->returnType = 0x115; break; default: t->interrupt(INT_WRONG_PARAMETERS); } // check overflow traps /* if (mask.i & MSK_OVERFL_ALL) { if ((mask.i & MSK_OVERFL_SIGN) && overflowS2) t->interrupt(INT_OVERFL_SIGN); // signed overflow else if ((mask.i & MSK_OVERFL_UNSIGN) && overflowU2) t->interrupt(INT_OVERFL_UNSIGN); // unsigned overflow else if ((mask.i & MSK_OVERFL_FLOAT) && overflowF2) t->interrupt(INT_OVERFL_FLOAT); // float overflow } */ t->vectorLength[rd] = newLength; // save new vector length t->vect = 4; // stop vector loop t->running = 2; // don't save. result has already been saved return 0; } static uint64_t expand(CThread * t) { // Expand vector RS to a vector of the double length and the double element size. // OT specifies the element size or precision of the destination. // Half precision -> single precision, 32-bit integer -> 64-bit integer, etc. // Operands: uint8_t rd = t->operands[0]; uint8_t rs = t->operands[4]; uint8_t IM1 = t->parm[4].b; if (IM1 & 0xFC) t->interrupt(INT_WRONG_PARAMETERS); bool signExtend = (IM1 & 2) == 0; uint32_t initLength = t->vectorLength[rs]; uint32_t newLength = 2 * initLength; if (newLength > t->MaxVectorLength) newLength = t->MaxVectorLength; // uint32_t oldLength = newLength / 2; uint32_t pos; // position in source vector int8_t * source = t->vectors.buf() + (uint32_t)rs * t->MaxVectorLength; // address of RT data int8_t * destination = t->vectors.buf() + (uint32_t)rd * t->MaxVectorLength; // address of RD data if (rd == rs) { // source and destination are the same. Make a temporary copy of source to avoid overwriting memcpy(t->tempBuffer, source, initLength); source = t->tempBuffer; } switch (t->operandType) { case 0: // int4 -> int8 for (pos = 0; pos < newLength; pos += 1) { uint8_t val1 = *(uint8_t*)(source + pos); // values to convert union { uint16_t s; uint8_t b[2]; int8_t bs[2]; } val2; if (signExtend) { val2.bs[0] = (int8_t)val1 << 4 >> 4; // sign extend val2.bs[1] = (int8_t)val1 >> 4; // sign extend } else { val2.b[0] = val1 & 0xF; // zero extend val2.b[1] = val1 >> 4; // zero extend } *(uint16_t*)(destination + pos*2) = val2.s; // store value } break; case 1: // int8 -> int16 for (pos = 0; pos < newLength; pos += 1) { uint16_t val = *(uint8_t*)(source + pos); // value to convert if (signExtend) val = uint16_t((int16_t)(val << 8) >> 8); // sign extend *(uint16_t*)(destination + pos*2) = val; // store value } break; case 2: // int16 -> int32 for (pos = 0; pos < newLength; pos += 2) { uint32_t val = *(uint16_t*)(source + pos); // value to convert if (signExtend) val = uint32_t((int32_t)(val << 16) >> 16); // sign extend *(uint32_t*)(destination + pos*2) = val; // store value } break; case 3: // int32 -> int64 for (pos = 0; pos < newLength; pos += 4) { uint64_t val = *(uint32_t*)(source + pos); // value to convert if (signExtend) val = uint64_t((int64_t)(val << 32) >> 32); // sign extend *(uint64_t*)(destination + pos*2) = val; // store value } break; case 4: // int64 -> int128 for (pos = 0; pos < newLength; pos += 8) { uint64_t valLo = *(uint64_t*)(source + pos); // value to convert uint64_t valHi = 0; if (signExtend) valHi = uint64_t((int64_t)valLo >> 63); // sign extend *(uint64_t*)(destination + pos*2) = valLo; // store low part *(uint64_t*)(destination + pos*2 + 8) = valHi; // store high part } break; case 5: // float16 -> float for (pos = 0; pos < newLength; pos += 2) { uint16_t val1 = *(uint16_t*)(source + pos); // value to convert float val2 = half2float(val1); // convert half precision to float *(float*)(destination + pos*2) = val2; // store value } break; case 6: // float -> double for (pos = 0; pos < newLength; pos += 4) { SNum val1; val1.i = *(uint32_t*)(source + pos); // value to convert double val2 = val1.f; // convert to double precision // check NAN // ForwardCom has right-justified NAN payload, unlike other binary systems if (isnan_f(val1.i)) { union { // single precision float double d; struct { // structure of a NAN uint64_t payload : 51; uint64_t quiet : 1; uint64_t expo : 11; uint64_t sign : 1; }; } u; u.payload = val1.q & ((1 << 22) - 1); u.quiet = val1.i >> 22 & 1; u.expo = 0x7FF; u.sign = val1.q >> 63 & 1; val2 = u.d; } *(double*)(destination + pos*2) = val2; // store value } break; default: t->interrupt(INT_WRONG_PARAMETERS); } t->vectorLength[rd] = newLength; // save new vector length t->vect = 4; // stop vector loop t->running = 2; // don't save. result has already been saved return 0; } static uint64_t float2int (CThread * t) { // Conversion of floating point to signed or unsigned integer with the same operand size. // The rounding mode and overflow control is specified in IM1. SNum a = t->parm[1]; SNum b = t->parm[4]; int64_t result = 0; uint32_t dataSize = dataSizeTable[t->operandType]; uint8_t roundingMode = b.b >> 3 & 3; uint8_t signMode = roundingMode | (b.b & 2) << 1; // bit 0-1: rounding mode, bit 2: usigned bool overflow = false; bool invalid = false; if (dataSize == 2) { // float16 -> int16 const float max = (float)(int32_t)0x7FFF; const float min = -max - 1.0f; const float umax = (float)(uint32_t)0xFFFFu; if (isnan_h(a.s)) { invalid = true; } else { float f = half2float(a.s); switch (signMode) { // rounding mode: case 0: // nearest or even if (f >= max + 0.5f || f < min - 0.5f) overflow = true; result = (int)(nearbyint(f)); break; case 1: // down if (f >= max + 1.0f || f <= min) overflow = true; result = (int)(floor(f)); break; case 2: // up if (f > max || f <= min - 1.0f) overflow = true; result = (int)(ceil(f)); break; case 3: // towards zero if (f >= max + 1.0f || f <= min - 1.0f) overflow = true; result = (int)(f); break; case 4: // unsigned nearest or even if (f >= umax + 0.5f || f < - 0.5f) overflow = true; result = (int)(nearbyint(f)); break; case 5: case 7: // unsigned down if (f >= umax + 1.0f || f < 0.0f) overflow = true; result = (int)(floor(f)); break; case 6: // unsigned up if (f > umax || f <= -1.0f) overflow = true; else result = (int)(ceil(f)); } if (overflow) { switch (b.b & 7) { // overflow options case 0: default: // wrap around result &= 0xFFFFu; break; case 4: case 6: result = 0; break; case 5: // signed saturation result = 0x7FFF + int(f < 0); break; case 7: // unsigned saturation result = 0xFFFFu; break; } } if (invalid) { result = (b.b & 0x20) ? 0x8000u : 0; } } } else if (dataSize == 4) { // float -> int32 const float max = (float)(int32_t)nsign_f; const float min = -max - 1.0f; const float umax = (float)(uint32_t)0xFFFFFFFFu; if (isnan_f(a.i)) { invalid = true; } else { switch (signMode) { // rounding mode: case 0: // nearest or even if (a.f >= max + 0.5f || a.f < min - 0.5f) overflow = true; result = (int64_t)(nearbyint(a.f)); break; case 1: // down if (a.f >= max + 1.0f || a.f <= min) overflow = true; result = (int64_t)(floor(a.f)); break; case 2: // up if (a.f > max || a.f <= min - 1.0f) overflow = true; result = (int64_t)(ceil(a.f)); break; case 3: // towards zero if (a.f >= max + 1.0f || a.f <= min - 1.0f) overflow = true; result = (int64_t)(a.f); break; case 4: // unsigned nearest or even if (a.f >= umax + 0.5f || a.f < - 0.5f) overflow = true; result = (int64_t)(nearbyint(a.f)); break; case 5: case 7: // unsigned down if (a.f >= umax + 1.0f || a.f < 0.0f) overflow = true; result = (int64_t)(floor(a.f)); break; case 6: // unsigned up if (a.f > umax || a.f <= -1.0f) overflow = true; else result = (int64_t)(ceil(a.f)); } if (overflow) { switch (b.b & 7) { // overflow options case 0: // wrap around result &= 0xFFFFFFFFu; break; case 4: case 6: result = 0; break; case 5: // signed saturation result = 0x7FFFFFFF + int(a.f < 0); break; case 7: // unsigned saturation result = 0xFFFFFFFFu; break; } } if (invalid) { result = (b.b & 0x20) ? sign_f : 0; } } } else if (dataSize == 8) { // double -> int64 const double max = (double)(int64_t)nsign_d; const double min = -max - 1.0f; const double umax = (double)0xFFFFFFFFFFFFFFFFu; if (isnan_d(a.q)) { invalid = true; } else { switch (signMode) { // rounding mode: case 0: // nearest or even if (a.d >= max + 0.5 || a.d < min - 0.5) overflow = true; result = (int64_t)(nearbyint(a.d)); break; case 1: // down if (a.d >= max + 1.0 || a.d <= min) overflow = true; result = (int64_t)(floor(a.d)); break; case 2: // up if (a.d > max || a.d <= min - 1.0) overflow = true; result = (int64_t)(ceil(a.d)); break; case 3: // towards zero if (a.d >= max + 1.0 || a.d <= min - 1.0) overflow = true; result = (int64_t)(a.d); break; case 4: // unsigned nearest or even if (a.d >= umax + 0.5 || a.d < - 0.5) overflow = true; result = (uint64_t)(nearbyint(a.d)); break; case 5: case 7: // unsigned down if (a.d >= umax + 1.0 || a.d < 0.0) overflow = true; result = (uint64_t)(floor(a.d)); break; case 6: // unsigned up if (a.d > umax || a.d <= -1.0) overflow = true; result = (uint64_t)(ceil(a.d)); } } if (overflow) { switch (b.b & 7) { // overflow options case 0: // wrap around break; case 4: case 6: result = 0; break; case 5: // signed saturation result = nsign_d + int(a.d < 0); break; case 7: // unsigned saturation result = 0xFFFFFFFFFFFFFFFFu; break; } } if (invalid) { result = (b.b & 0x20) ? sign_d : 0; } } else t->interrupt(INT_WRONG_PARAMETERS); /* Traps not supported if (overflow && (mask.i & MSK_OVERFL_SIGN)) { t->interrupt(INT_OVERFL_SIGN); // signed overflow result = dataSizeMask[t->operandType] >> 1; // INT_MAX } if (invalid && (mask.i & MSK_FLOAT_NAN_LOSS)) { t->interrupt(INT_FLOAT_NAN_LOSS); // nan converted to integer result = dataSizeMask[t->operandType] >> 1; // INT_MAX } */ if ((t->operandType & 7) >= 5) t->operandType -= 3; // debug return type is integer return result; } static uint64_t int2float (CThread * t) { // Conversion of signed or unsigned integer to floating point with same operand size. SNum a = t->parm[1]; SNum IM1 = t->parm[4]; bool isSigned = (IM1.b & 1) == 0; // signed integer bool inexactX = (IM1.b & 4) != 0; // make NAN exception if inexact SNum result; uint32_t dataSize = dataSizeTable[t->operandType]; switch (dataSize) { case 2: // int16 -> float16 if (isSigned) { result.s = float2half(float(a.ss)); if (inexactX && int32_t(half2float(result.s)) != a.ss) { result.q = t->makeNan(nan_inexact, 1); } } else { // unsigned result.s = float2half(float(a.s)); if (inexactX && uint32_t(half2float(result.s)) != a.s) { result.q = t->makeNan(nan_inexact, 1); } } t->returnType = 0x118; // debug return type is float16 break; case 4: // int32 -> float if (isSigned) { result.f = (float)a.is; if (inexactX && int32_t(result.f) != a.is) { result.q = t->makeNan(nan_inexact, 5); } } else { result.f = (float)a.i; if (inexactX && uint32_t(result.f) != a.i) { result.q = t->makeNan(nan_inexact, 5); } } t->returnType = 0x115; // debug return type is float break; case 8: // int64 -> double if (isSigned) { result.d = (double)a.qs; if (inexactX && int64_t(result.d) != a.qs) { result.q = t->makeNan(nan_inexact, 6); } } else { result.d = (double)a.q; if (inexactX && uint64_t(result.d) != a.q) { result.q = t->makeNan(nan_inexact, 6); } } t->returnType = 0x116; // debug return type is double break; default: t->interrupt(INT_WRONG_PARAMETERS); result.q = 0; } return result.q; } static uint64_t round_ (CThread * t) { // Round floating point to integer in floating point representation. // The rounding mode is specified in IM1. // Conversion of floating point to signed integer with the same operand size. // The rounding mode is specified in IM1. SNum a = t->parm[1]; SNum b = t->parm[4]; SNum result; uint32_t dataSize = dataSizeTable[t->operandType]; if (dataSize == 4) { // float -> int32 switch (b.b) { // rounding mode: case 0: // nearest or even result.f = nearbyintf(a.f); break; case 1: // down result.f = floorf(a.f); break; case 2: // up result.f = ceilf(a.f); break; case 3: // towards zero result.f = truncf(a.f); break; default: t->interrupt(INT_WRONG_PARAMETERS); } } else if (dataSize == 8) { // double -> int64 switch (b.b) { // rounding mode: case 0: // nearest or even result.d = nearbyint(a.d); break; case 1: // down result.d = floor(a.d); break; case 2: // up result.d = ceil(a.d); break; case 3: // towards zero result.d = trunc(a.d); break; default: t->interrupt(INT_WRONG_PARAMETERS); } } return result.q; } static uint64_t round2n (CThread * t) { // Round to nearest multiple of 2n. // RD = 2^n * round(2^(−n)*RS). // n is a signed integer constant in IM1 SNum b = t->parm[4]; // n //SNum mask = t->parm[3]; uint32_t exponent1; uint64_t result = 0; if (t->operandType == 5) { // float union { uint32_t i; float f; struct { uint32_t mantissa : 23; uint32_t exponent : 8; uint32_t sign : 1; }; } u; u.i = t->parm[1].i; // input a if (isnan_f(u.i)) return u.i; // a is nan exponent1 = u.exponent; if (exponent1 == 0) { u.mantissa = 0; // a is zero or subnormal. return zero return u.i; } exponent1 -= b.i; // subtract b from exponent if ((int32_t)exponent1 <= 0) { // underflow //if (mask.i & MSK_FLOAT_UNDERFL) t->interrupt(INT_FLOAT_UNDERFL); return 0; } else if ((int32_t)exponent1 >= 0xFF) { // overflow //if (mask.i & MSK_OVERFL_FLOAT) t->interrupt(INT_OVERFL_FLOAT); return inf_f; } u.exponent = exponent1; u.f = nearbyintf(u.f); // round if (u.f != 0) u.exponent += b.i; // add b to exponent result = u.i; } else if (t->operandType == 6) { // double union { uint64_t q; double d; struct { uint64_t mantissa : 52; uint64_t exponent : 11; uint64_t sign : 1; }; } u; u.q = t->parm[1].q; // input a if (isnan_d(u.q)) return u.q; // a is nan exponent1 = u.exponent; if (exponent1 == 0) { u.mantissa = 0; // a is zero or subnormal. return zero return u.q; } exponent1 -= b.i; // subtract b from exponent if ((int32_t)exponent1 <= 0) { // underflow //if (mask.i & MSK_FLOAT_UNDERFL) t->interrupt(INT_FLOAT_UNDERFL); return 0; } else if ((int32_t)exponent1 >= 0x7FF) { // overflow //if (mask.i & MSK_OVERFL_FLOAT) t->interrupt(INT_OVERFL_FLOAT); return inf_d; } u.exponent = exponent1; u.d = nearbyint(u.d); // round if (u.d != 0) u.exponent += b.i; // add b to exponent result = u.q; } else t->interrupt(INT_WRONG_PARAMETERS); return result; } static uint64_t abs_ (CThread * t) { // Absolute value of integer. // IM1 determines handling of overflow: 0: wrap around, 1: saturate, 2: zero, 3: trap SNum a = t->parm[1]; // x SNum b = t->parm[4]; // option uint64_t sizemask = dataSizeMask[t->operandType]; // mask for operand size uint64_t signbit = (sizemask >> 1) + 1; // just the sign bit if (a.q & signbit) { // a is negative if (t->operandType > 4) { // floating point types return a.q & ~signbit; // just remove sign bit } if ((a.q & sizemask) == signbit) { // overflow switch (b.b & ~4) { case 0: // wrap around break; case 1: // saturate return a.q - 1; case 2: // zero return 0; default: t->interrupt(INT_WRONG_PARAMETERS); } if ((b.b & 4) /* && (t->parm[3].i & MSK_OVERFL_SIGN)*/) { // trap t->interrupt(INT_OVERFL_SIGN); // signed overflow } } a.qs = - a.qs; // change sign } return a.q; } static uint64_t fp_category (CThread * t) { // Check if floating point numbers belong to the categories indicated by constant // 0 ± NAN, 1 ± Zero, 2 −Subnormal, 3 +Subnormal, 4 −Normal, 5 +Normal, 6 −Infinite, 7 +Infinite SNum a = t->parm[1]; // x SNum b = t->parm[4]; // option uint32_t exponent; uint8_t category = 0; // detected category bits switch (t->operandType) { case 2: case 5: // float exponent = a.i >> 23 & 0xFF; // isolate exponent if (exponent == 0xFF) { // nan or inf if (a.i << 9) category = 1; // nan else if (a.i >> 31) category = 0x40; // -inf else category = 0x80; // + inf } else if (exponent == 0) { if ((a.i << 9) == 0) category = 2; // zero else if (a.i >> 31) category = 4; // - subnormal else category = 8; // + subnormal } else if (a.i >> 31) category = 0x10; // - normal else category = 0x20; // + normal break; case 3: case 6: // double exponent = a.q >> 52 & 0x7FF; // isolate exponent if (exponent == 0x7FF) { // nan or inf if (a.q << 12) category = 1; // nan else if (a.q >> 63) category = 0x40; // -inf else category = 0x80; // + inf } else if (exponent == 0) { if ((a.q << 12) == 0) category = 2; // zero else if (a.q >> 63) category = 4; // - subnormal else category = 8; // + subnormal } else if (a.q >> 63) category = 0x10; // - normal else category = 0x20; // + normal break; default: t->interrupt(INT_WRONG_PARAMETERS); } uint8_t result = (category & b.b) != 0; // test if a belongs to any of the indicated categories if ((t->operandType & 7) >= 5) t->operandType -= 3; // debug return type is integer return (t->numContr & ~(uint64_t)1) | result; // get remaining bits from NUMCONTR } static uint64_t broad_ (CThread * t) { // 18: Broadcast 8-bit signed constant into all elements of RD with length RS (31 in RS field gives scalar output). // 19: broadcast_max. Broadcast 8-bit constant into all elements of RD with maximum vector length. uint8_t rd = t->operands[0]; uint8_t rs = t->operands[4]; uint8_t rm = t->operands[1]; // mask register SNum b = t->parm[2]; // constant uint64_t length; // length of destination vector if (t->op == 18) { // length given by RS length = t->registers[rs]; if (length > t->MaxVectorLength) length = t->MaxVectorLength; } else { // length is maximum length = t->MaxVectorLength; } uint8_t dsizelog = dataSizeTableLog[t->operandType]; // log2(elementsize) length = length >> dsizelog << dsizelog; // round down to nearest multiple of operand size // set length of destination vector t->vectorLength[rd] = (uint32_t)length; // loop to set all elements for (uint32_t pos = 0; pos < (uint32_t)length; pos += 1 << dsizelog) { if ((rm & 0x1F) != 0x1F && !(t->readVectorElement(rm, pos) & 1)) { // mask is zero. get fallback if (t->op == 18 || rs >= 31) b.q = 0; // threre is no fallback. write zero else b.q = t->readVectorElement(rs, pos); // rs is fallback } t->writeVectorElement(rd, b.q, pos); // write vector element } t->vect = 4; // stop vector loop t->running = 2; // don't save RD return 0; } static uint32_t byteSwap(uint32_t x) { // swap bytes, used by byte_reverse function union { uint32_t i; uint8_t b[4]; } a, b; a.i = x; b.b[0] = a.b[3]; b.b[1] = a.b[2]; b.b[2] = a.b[1]; b.b[3] = a.b[0]; return b.i; } static uint8_t bitSwap(uint8_t x) { // swap bits, used by bit_reverse function x = x >> 4 | x << 4; // swap 4-bit nipples x = (x >> 2 & 0x33) | (x << 2 & 0xCC); // swap 2-bit groups x = (x >> 1 & 0x55) | (x << 1 & 0xAA); // swap single bits return x; } static uint64_t byte_reverse (CThread * t) { // Reverse the order of bits or bytes in each element of vector SNum a = t->parm[1]; // value uint8_t IM1 = t->parm[2].b; // immediate operand if (IM1 & 1) { // bit reverse: Reverse the order of bits in each element of vector union { uint64_t q; uint32_t i[2]; uint8_t b[8]; } u; u.q = a.q; uint8_t t1; uint32_t t2; switch (dataSizeTableLog[t->operandType]) { case 0: // 8 bit u.b[0] = bitSwap(u.b[0]); break; case 1: // 16 bit t1 = bitSwap(u.b[0]); u.b[0] = bitSwap(u.b[1]); u.b[1] = t1; break; case 2: // 32 bit u.i[0] = byteSwap(u.i[0]); for (t1 = 0; t1 < 4; t1++) u.b[t1] = bitSwap(u.b[t1]); break; case 3: // 64 bit t2 = byteSwap(u.i[0]); u.i[0] = byteSwap(u.i[1]); u.i[1] = t2; for (t1 = 0; t1 < 8; t1++) u.b[t1] = bitSwap(u.b[t1]); break; case 4: // 128 bit t->interrupt(INT_WRONG_PARAMETERS); } return u.q; } else { // byte reverse: Reverse the order of bytes in each element of a vector uint8_t rs = t->operands[4]; uint32_t tmp; switch (dataSizeTableLog[t->operandType]) { case 0: // 8 bit break; case 1: // 16 bit a.s = a.s >> 8 | a.b << 8; break; // swap bytes case 2: // 32 bit a.i = byteSwap(a.i); break; case 3: // 64 bit tmp = byteSwap(a.i); a.q = byteSwap(a.q >> 32) | (uint64_t)tmp << 32; break; case 4: // 128 bit tmp = byteSwap(a.i); t->parm[5].q = byteSwap(a.q >> 32) | (uint64_t)tmp << 32; a.q = t->readVectorElement(rs, t->vectorOffset + 8); // high part of input tmp = byteSwap(a.i); a.q = byteSwap(a.q >> 32) | (uint64_t)tmp << 32; break; } return a.q; } } /* static uint64_t truth_tab2 (CThread * t) { // Boolean function of two inputs, given by a truth table SNum a = t->parm[0]; // value SNum b = t->parm[1]; // value SNum c = t->parm[4]; // truth table return ((c.b >> ((a.b & 1) | (b.b & 1) << 1)) & 1) | (a.q & ~uint64_t(1)); } */ static uint64_t bool2bits(CThread * t) { // The boolean vector RT is packed into the lower n bits of RD, // taking bit 0 of each element // The length of RD will be at least sufficient to contain n bits. uint8_t rd = t->operands[0]; // destination vector uint8_t rt = t->operands[4]; // RT = source vector //uint8_t rs = t->operands[4]; // RS indicates length uint8_t * destination = (uint8_t*)t->vectors.buf() + (int64_t)rd * t->MaxVectorLength; // address of RD data //uint64_t length = t->registers[rs]; // value of RS = length of destination uint32_t length = t->vectorLength[rt]; // length of source uint8_t dsizelog = dataSizeTableLog[t->operandType]; // log2(elementsize) //if (length > t->MaxVectorLength) length = t->MaxVectorLength; // limit length uint32_t num = length >> dsizelog; // number of elements length = num << dsizelog; // round down length to nearest multiple of element size // collect bits into blocks of 32 bits uint32_t bitblock = 0; // loop through elements of source vector for (uint32_t i = 0; i < num; i++) { uint8_t bit = t->readVectorElement(rt, i << dsizelog) & 1; uint8_t bitindex = i & 31; // bit position with 32 bit block of destination bitblock |= bit << bitindex; // add bit to bitblock if (bitindex == 31 || i == num - 1) { // last bit in this block *(uint32_t*)(destination + (i/8 & -4)) = bitblock; // write 32 bit block to destination bitblock = 0; // start next block } } // round up length of destination to multiple of 4 bytes uint32_t destinationLength = ((num+7)/8 + 3) & -4; if (destinationLength == 0) { destinationLength = 4; *(uint32_t*)destination = 0; } // set length of destination vector (must be done after reading source because source and destination may be the same) t->vectorLength[rd] = destinationLength; t->vect = 4; // stop vector loop t->running = 2; // don't save RD if ((t->returnType & 7) >= 5) t->returnType -= 3; // make return type integer return 0; } static uint64_t bool_reduce(CThread * t) { // integer vector: bool_reduce. The boolean vector RT is reduced by combining bit 0 of all elements. // The output is a scalar integer where bit 0 is the AND combination of all the bits, // and bit 1 is the OR combination of all the bits. // The remaining bits are reserved for future use // float vector: category_reduce: Each bit in RD indicates that at least one element in RT belongs // to a certain category: // bit 0: NAN, bit 1: zero, bit 2: - subnormal, bitt 3: + subnormal, // bit 4: - normal, bit 5: + normal, bit 6: - INF, bit 7: + INF uint8_t rd = t->operands[0]; // destination vector uint8_t rt = t->operands[4]; // RT = source vector //uint8_t rs = t->operands[4]; // RS indicates length uint8_t bitOR = 0; // OR combination of all bits uint8_t bitAND = 1; // AND combination of all bits uint64_t result = 0; // result value uint8_t * source = (uint8_t*)t->vectors.buf() + rt*t->MaxVectorLength; // address of RT data //if (length > t->MaxVectorLength) length = t->MaxVectorLength; // limit length uint32_t elementSize = dataSizeTable[t->operandType]; // vector element size uint8_t dsizelog = dataSizeTableLog[t->operandType]; // log2(elementsize) uint32_t sourceLength = t->vectorLength[rt]; // length of source vector //uint64_t length = t->registers[rs]; // value of RS = length of destination uint32_t length = sourceLength; // length of source vector length = length >> dsizelog << dsizelog; // round down to nearest multiple of element size /*if (length > sourceLength) { length = sourceLength; // limit to length of source vector bitAND = 0; // bits beyond vector are 0 } */ switch (t->operandType) { case 0: case 1: case 2: case 3: case 4: // integer types: bool_reduce for (uint32_t pos = 0; pos < length; pos += elementSize) { // loop through elements of source vector uint8_t bit = *(source + pos) & 1; // get bit from source vector element bitOR |= bit; bitAND &= bit; } result = bitAND | bitOR << 1; break; case 5: // float type: category_reduce for (uint32_t pos = 0; pos < length; pos += elementSize) { // loop through elements of source vector uint32_t val = *(int32_t*)(source + pos); uint8_t exponent = val >> 23 & 0xFF; // isolate exponent uint8_t category; if (exponent == 0xFF) { // nan or inf if (val << 9) category = 1; // nan else if (val >> 31) category = 0x40; // -inf else category = 0x80; // + inf } else if (exponent == 0) { if ((val << 9) == 0) category = 2; // zero else if (val >> 31) category = 4; // - subnormal else category = 8; // + subnormal } else if (val >> 31) category = 0x10; // - normal else category = 0x20; // + normal result |= category; // combine categories } break; case 6: // double type: category_reduce for (uint32_t pos = 0; pos < length; pos += elementSize) { // loop through elements of source vector uint64_t val = *(int64_t*)(source + pos); uint32_t exponent = val >> 52 & 0x7FF; // isolate exponent uint8_t category; if (exponent == 0x7FF) { // nan or inf if (val << 12) category = 1; // nan else if (val >> 63) category = 0x40; // -inf else category = 0x80; // + inf } else if (exponent == 0) { if ((val << 12) == 0) category = 2; // zero else if (val >> 63) category = 4; // - subnormal else category = 8; // + subnormal } else if (val >> 63) category = 0x10; // - normal else category = 0x20; // + normal result |= category; // combine categories } break; default: t->interrupt(INT_WRONG_PARAMETERS); } t->vectorLength[rd] = 8; // set length of destination vector to 64 bits uint8_t * destination = (uint8_t*)t->vectors.buf() + rd*t->MaxVectorLength; // address of RD data *(uint64_t*)destination = result; // write 64 bits to destination // (using writeVectorElement would possibly write less than 64 bits, leaving some of the destination vector unchanged) t->vect = 4; // stop vector loop t->running = 2; // don't save RD. It has already been saved if ((t->returnType & 7) >= 5) t->returnType -= 3; // make return type integer return result; } static uint64_t push_v(CThread * t) { // push one or more vector registers on a stack pointed to by rd if (t->parm[2].i & 0xE0) { t->interrupt(INT_WRONG_PARAMETERS); return 0; // forward-growing stack not supported for vector registers } uint8_t reg0 = t->operands[0] & 0x1F; // pointer register uint8_t reg1 = t->operands[4] & 0x1F; // first push register uint8_t reglast = t->parm[2].i & 0x1F; // last push register uint8_t reg; // current regiser uint32_t length; // length of current register uint32_t length2; // length rounded up to nearest multiple of stack word size uint64_t pointer = t->registers[reg0]; const int stack_word_size = 8; t->operandType = 3; // must be 64 bits. // loop through registers to push for (reg = reg1; reg <= reglast; reg++) { length = t->vectorLength[reg]; length2 = (length + stack_word_size - 1) & -stack_word_size; // round up to multiple of 8 if (length != 0) { pointer -= length2; for (uint32_t j = 0; j < length2; j += 8) { uint64_t value = t->readVectorElement(reg, j); t->writeMemoryOperand(value, pointer + j); // write vector } t->returnType = 0x113; t->operands[0] = reg; t->listResult(0); } pointer -= stack_word_size; t->writeMemoryOperand(length, pointer); // write length t->returnType = 0x13; t->listResult(length); } t->registers[reg0] = pointer; t->returnType = 0x13; t->operands[0] = reg0; t->vect = 4; // stop vector loop t->running = 2; // don't store result register return pointer; } static uint64_t pop_v(CThread * t) { // pop one or more vector registers from a stack pointed to by rd if (t->parm[2].i & 0xE0) { t->interrupt(INT_WRONG_PARAMETERS); return 0; // forward-growing stack not supported for vector registers } uint8_t reg0 = t->operands[0] & 0x1F; // pointer register uint8_t reg1 = t->operands[4] & 0x1F; // first pop register uint8_t reglast = t->parm[2].i & 0x1F; // last pop register uint8_t reg; // current regiser uint32_t length; // length of current register uint32_t length2; // length rounded up to nearest multiple of stack word size uint64_t pointer = t->registers[reg0]; // value of stack pointer or pointer register const int stack_word_size = 8; t->operandType = 3; // must be 64 bits. // reverse loop through registers to pop for (reg = reglast; reg >= reg1; reg--) { length = (uint32_t)t->readMemoryOperand(pointer); // read length length2 = (length + stack_word_size - 1) & -stack_word_size; // round up to multiple of 8 t->vectorLength[reg] = length; // set vector length pointer += stack_word_size; // pop length if (length != 0) { for (uint32_t j = 0; j < length2; j += 8) { // read vector uint64_t value = t->readMemoryOperand(pointer + j); // read from memory t->writeVectorElement(reg, value, j); } pointer += length2; t->returnType = 0x113; t->operands[0] = reg; t->listResult(0); } t->returnType = 0x13; t->listResult(length); } t->registers[reg0] = pointer; t->returnType = 0x13; t->operands[0] = reg0; t->vect = 4; // stop vector loop t->running = 2; // don't store result register return pointer; } static uint64_t clear_(CThread * t) { // clear one or more vector registers uint8_t reg1 = t->operands[4] & 0x1F; // first register uint8_t reglast = t->parm[2].i & 0x1F; // last register uint8_t reg; // current regiser for (reg = reg1; reg <= reglast; reg++) { t->vectorLength[reg] = 0; } t->vect = 4; // stop vector loop t->running = 2; // don't store result register t->returnType = 0; return 0; } // Format 1.4 C. One vector register and a broadcast 16-bit immediate operand. static uint64_t move_i16 (CThread * t) { // Move 16 bit integer constant to 16-bit scalar uint8_t rd = t->operands[0]; // destination vector t->vectorLength[rd] = 2; // set length of destination t->vect = 4; // stop vector loop return t->parm[2].q; } //static uint64_t add_i16 (CThread * t) {return f_add(t);} // Add broadcasted 16 bit constant to 16-bit vector elements static uint64_t and_i16 (CThread * t) { // AND broadcasted 16 bit constant return t->parm[1].q & t->parm[2].q; } static uint64_t or_i16 (CThread * t) { // OR broadcasted 16 bit constant return t->parm[1].q | t->parm[2].q; } static uint64_t xor_i16 (CThread * t) { // XOR broadcasted 16 bit constant return t->parm[1].q ^ t->parm[2].q; } static uint64_t add_h16 (CThread * t) { // add constant to half precision vector return f_add_h(t); } static uint64_t mul_h16 (CThread * t) { // multiply half precision vector with constant return f_mul_h(t); } static uint64_t move_8shift8 (CThread * t) { // RD = IM2 << IM1. Sign-extend IM2 and shift left by the unsigned value IM1 to make 32/64 bit scalar // 40: 32 bit, 41: 64 bit uint8_t rd = t->operands[0]; // destination vector t->vectorLength[rd] = (t->op & 1) ? 8 : 4; // set length of destination t->vect = 4; // stop vector loop return (uint64_t)(int64_t(t->parm[2].ss) >> 8 << t->parm[2].bs); // shift and sign extend } static uint64_t add_8shift8 (CThread * t) { // RD += IM2 << IM1. Sign-extend IM2 and shift left by the unsigned value IM1, add to 32/64 bit vector // 42: 32 bit, 43: 64 bit int64_t save2 = t->parm[2].qs; t->parm[2].qs = int64_t(t->parm[2].ss) >> 8 << t->parm[2].bs; // shift and sign extend int64_t result = f_add(t); // use f_add for getting overflow traps t->parm[2].qs = save2; // restore constant return result; } static uint64_t and_8shift8 (CThread * t) { // RD &= IM2 << IM1. Sign-extend IM2 and shift left by the unsigned value IM1, AND with 32/64 bit vector // 44: 32 bit, 45: 64 bit int64_t a = int64_t(t->parm[2].ss) >> 8 << t->parm[2].bs; // shift and sign extend return t->parm[1].q & a; } static uint64_t or_8shift8 (CThread * t) { // RD |= IM2 << IM1. Sign-extend IM2 and shift left by the unsigned value IM1, OR with 32/64 bit vector // 46: 32 bit, 47: 64 bit int64_t a = int64_t(t->parm[2].ss) >> 8 << t->parm[2].bs; // shift and sign extend return t->parm[1].q | a; } static uint64_t xor_8shift8 (CThread * t) { // RD |= IM2 << IM1. Sign-extend IM2 and shift left by the unsigned value IM1, XOR with 32/64 bit vector // 48: 32 bit, 49: 64 bit int64_t a = int64_t(t->parm[2].ss) >> 8 << t->parm[2].bs; // shift and sign extend return t->parm[1].q ^ a; } static uint64_t move_half2float (CThread * t) { // Move converted half precision floating point constant to single precision scalar t->vectorLength[t->operands[0]] = 4; // set length of destination t->vectorLengthR = 4; t->vect = 4; // stop vector loop return t->parm[2].q; } static uint64_t move_half2double (CThread * t) { // Move converted half precision floating point constant to double precision scalar t->vectorLength[t->operands[0]] = 8; // set length of destination t->vect = 4; // stop vector loop return t->parm[2].q; } static uint64_t add_half2float (CThread * t) { // Add broadcast half precision floating point constant to single precision vector return f_add(t); } static uint64_t add_half2double (CThread * t) { // Add broadcast half precision floating point constant to double precision vector return f_add(t); } static uint64_t mul_half2float (CThread * t) { // multiply broadcast half precision floating point constant with single precision vector return f_mul(t); } static uint64_t mul_half2double (CThread * t) { // multiply broadcast half precision floating point constant with double precision vector return f_mul(t); } // Format 2.6 A. Three vector registers and a 32-bit immediate operand. static uint64_t load_hi (CThread * t) { // Make vector of two elements. dest[0] = 0, dest[1] = IM2. uint8_t rd = t->operands[0]; uint8_t dsize = dataSizeTable[t->operandType]; t->vectorLength[rd] = dsize * 2; // set length of destination t->writeVectorElement(rd, 0, 0); // write 0 t->writeVectorElement(rd, t->parm[2].q, dsize);// write IM2 t->vect = 4; // stop vector loop t->running = 2; // don't save RD return 0; } static uint64_t insert_hi (CThread * t) { // Make vector of two elements. dest[0] = src1[0], dest[1] = IM2. uint8_t rd = t->operands[0]; uint8_t dsize = dataSizeTable[t->operandType]; t->vectorLength[rd] = dsize * 2; // set length of destination t->writeVectorElement(rd, t->parm[1].q, 0); // write src1 t->writeVectorElement(rd, t->parm[2].q, dsize);// write IM2 t->vect = 4; // stop vector loop t->running = 2; // don't save RD return 0; } static uint64_t make_mask (CThread * t) { // Make vector where bit 0 of each element comes from bits in IM2, the remaining bits come from RT. SNum m = t->parm[3]; // mask or numcontr SNum b = t->parm[2]; // constant operand uint8_t dsizelog = dataSizeTableLog[t->operandType]; // log2(elementsize) uint32_t elementNum = t->vectorOffset >> dsizelog; // index to vector element if ((t->operandType & 7) >= 5) t->operandType -= 3; // debug return type is integer return (m.q & ~(uint64_t)1) | (b.i >> (elementNum & 31) & 1); } static uint64_t replace_ (CThread * t) { // Replace elements in RT by constant IM2 // format 2.6: 32 bits, format 3.1: 64 bits return t->parm[2].q; } static uint64_t replace_even (CThread * t) { // Replace even-numbered elements in RT by constant IM2 uint8_t dsizelog = dataSizeTableLog[t->operandType]; // log2(elementsize) uint32_t elementNum = t->vectorOffset >> dsizelog; // index to vector element return (elementNum & 1) ? t->parm[1].q : t->parm[2].q; } static uint64_t replace_odd (CThread * t) { // Replace odd-numbered elements in RT by constant IM2 uint8_t dsizelog = dataSizeTableLog[t->operandType]; // log2(elementsize) uint32_t elementNum = t->vectorOffset >> dsizelog; // index to vector element return (elementNum & 1) ? t->parm[2].q : t->parm[1].q; } static uint64_t broadcast_32 (CThread * t) { // Broadcast 32-bit or 64 -bit constant into all elements of RD with length RS (31 in RS field gives scalar output). uint8_t rd = t->operands[0]; uint8_t rs = t->operands[4]; uint8_t rm = t->operands[1]; // mask register uint32_t elementSize = dataSizeTable[t->operandType]; uint8_t dsizelog = dataSizeTableLog[t->operandType]; // log2(elementsize) uint64_t length; // length of destination int64_t value; if (rs == 31) length = elementSize; else length = t->registers[rs] << dsizelog >> dsizelog; // round length to multiple of elementSize if (length > t->MaxVectorLength) length = t->MaxVectorLength; t->vectorLength[rd] = (uint32_t)length; // set length of destination for (uint32_t pos = 0; pos < length; pos += elementSize) { // loop through vector if (rm >= 7 || (t->readVectorElement(rm, pos) & 1)) value = t->parm[2].qs; // check mask else value = 0; t->writeVectorElement(rd, value, pos); // write to destination } t->vect = 4; // stop vector loop t->running = 2; // don't save RD return 0; } static uint64_t permute (CThread * t) { // The vector elements of RS are permuted within each block of size RT bytes. // The number of elements in each block, n = RT / OS // format 2.2.6 op 1.1: index vector is last operand // format 2.6 op 8: index vector is constant IM2, 4 bits for each element uint8_t rd = t->operands[0]; // destination uint8_t rm = t->operands[1]; // mask register uint8_t vin; // input data register uint8_t vpat = 0; // pattern register uint8_t bs; // block size, g.p. register uint32_t pattern = 0; // IM2 = pattern, if constant bool constPat = false; // pattern is a constant if (t->fInstr->format2 == 0x226) { vin = t->operands[3]; // ru = input data vpat = t->operands[4]; // rs = pattern bs = t->operands[5]; // block size, g.p. register } else { // format 2.6 vin = t->operands[3]; // rs = input data bs = t->operands[4]; // block size, g.p. register pattern = t->parm[4].i; // IM2 = pattern, if constant constPat = true; } uint8_t dsizelog = dataSizeTableLog[t->operandType]; // log2(elementsize) //uint32_t elementSize = 1 << dsizelog; uint32_t length = t->vectorLength[vin]; // vector length t->vectorLength[rd] = length; // set length of destination int8_t * source = t->vectors.buf() + (uint32_t)(vin & 0x1F) * t->MaxVectorLength; // address of source data vector if (vin == rd) { // source and destination are the same. Make a temporary copy of source to avoid overwriting memcpy(t->tempBuffer, source, length); source = t->tempBuffer; } uint64_t blocksize = t->registers[bs]; // bytes per block uint64_t value; // value of element uint64_t index; // index to source element if (blocksize == 0 || (blocksize & (blocksize-1)) || blocksize > t->MaxVectorLength) { t->interrupt(INT_WRONG_PARAMETERS); // RS must be a power of 2 } else { uint32_t num = (uint32_t)blocksize >> dsizelog; // elements per block for (uint32_t block = 0; block < length; block += (uint32_t)blocksize) { // loop through blocks for (uint32_t element = 0; element < num; element++) { // loop through elements within block if (constPat) { // get index from constant index = (pattern >> (element&7)*4) & 0xF; // index to select block element } else { // get index from vector index = t->readVectorElement(vpat, block + (element << dsizelog)); } if (index < num && (rm == 7 || t->readVectorElement(rm, block + (element << dsizelog)) & 1)) { // check mask value = *(uint64_t*)(source + block + ((uint32_t)index << dsizelog)); // pick indexed element from source vector } else value = 0; // index out of range or mask = 0 t->writeVectorElement(rd, value, block + (element << dsizelog)); // write destination } } } t->vect = 4; // stop vector loop t->running = 2; // don't save RD return 0; } /* static uint64_t replace_bits (CThread * t) { // Replace a group of contiguous bits in RT by a specified constant SNum a = t->parm[1]; // input operand SNum b = t->parm[2]; // input constant uint64_t val = b.s; // value of replacement bits uint8_t pos = uint8_t(b.i >> 16); // position of replacement uint8_t num = uint8_t(b.i >> 24); // number of consecutive bits to replace uint64_t mask = ((uint64_t)1 << num) - 1; // mask with num 1-bits return (a.q & ~(mask<<pos)) | ((val & mask) << pos); }*/ // Format 2.5 A. Single format instructions with memory operands or mixed register types static uint64_t store_i32 (CThread * t) { // Store 32-bit constant IM2 to memory operand [RS+IM1] uint64_t value = t->parm[2].q; if ((t->parm[3].b & 1) == 0) value = 0; // check mask t->writeMemoryOperand(value, t->memAddress); t->running = 2; // don't save RD t->returnType = (t->returnType & 7) | 0x20; return 0; } //static uint64_t fence_ (CThread * t) {return f_nop(t);} static uint64_t compare_swap (CThread * t) { // Atomic compare and exchange with address [RS+IM2] uint64_t val1 = t->parm[0].q; uint64_t val2 = t->parm[1].q; // to do: use intrinsic compareandexchange or mutex or pause all threads if multiple threads uint64_t address = t->memAddress; uint64_t sizemask = dataSizeMask[t->operandType]; // mask for operand size uint64_t val3 = t->readMemoryOperand(address); // read value from memory if (((val3 ^ val1) & sizemask) == 0) { // value match t->writeMemoryOperand(val2, address); // write new value to memory } t->vect = 4; // stop vector loop return val3; // return old value } static uint64_t read_insert (CThread * t) { // Replace one element in vector RD, starting at offset RT*OS, with scalar memory operand [RS+IM2] uint8_t rd = t->operands[0]; uint8_t rs = t->operands[4]; uint32_t elementSize = dataSizeTable[t->operandType]; uint64_t value = t->readMemoryOperand(t->memAddress); uint64_t pos = t->registers[rs] * elementSize; if (pos < t->vectorLength[rd]) { t->writeVectorElement(rd, value, (uint32_t)pos); } t->vect = 4; // stop vector loop t->running = 2; // don't save RD return 0; } static uint64_t extract_store (CThread * t) { // Extract one element from vector RD, starting at offset RT*OS, with size OS into memory operand [RS+IM2] uint8_t rd = t->operands[0]; uint8_t rs = t->operands[4]; uint32_t elementSize = dataSizeTable[t->operandType]; uint64_t pos = t->registers[rs] * elementSize; uint64_t value = t->readVectorElement(rd, (uint32_t)pos); t->writeMemoryOperand(value, t->memAddress); t->returnType = (t->returnType & 7) | 0x20; // debug return type is memory t->vect = 4; // stop vector loop t->running = 2; // don't save RD t->vectorLengthR = elementSize; // size of memory destination return 0; } // Format 2.2.6 E. Four vector registers static uint64_t concatenate (CThread * t) { // A vector RU of length RT and a vector RS of length RT are concatenated into a vector RD of length 2*RT. uint8_t rd = t->operands[0]; uint8_t ru = t->operands[3]; uint8_t rs = t->operands[4]; uint8_t rt = t->operands[5]; uint64_t length1 = t->registers[rt]; if (length1 > t->MaxVectorLength) length1 = t->MaxVectorLength; uint32_t length2 = 2 * (uint32_t)length1; if (length2 > t->MaxVectorLength) length2 = t->MaxVectorLength; t->vectorLength[rd] = length2; // set length of destination vector int8_t * source1 = t->vectors.buf() + ru*t->MaxVectorLength; // address of RU data int8_t * source2 = t->vectors.buf() + rs*t->MaxVectorLength; // address of RS data int8_t * destination = t->vectors.buf() + rd*t->MaxVectorLength; // address of RD data memcpy(destination, source1, (uint32_t)length1); // copy from RU memcpy(destination + (uint32_t)length1, source2, length2 - (uint32_t)length1); // copy from RS t->vect = 4; // stop vector loop t->running = 2; // don't save RD return 0; } static uint64_t interleave (CThread * t) { // Interleave elements of vectors RU and RS of length RT/2 to produce vector RD of length RT. // Even-numbered elements of the destination come from RU and odd-numbered elements from RS. uint8_t rd = t->operands[0]; // destination uint8_t ru = t->operands[3]; // first input vector uint8_t rs = t->operands[4]; // second input vector uint8_t rt = t->operands[5]; // length uint8_t rm = t->operands[1]; // mask uint64_t length = t->registers[rt]; if (length > t->MaxVectorLength) length = t->MaxVectorLength; uint8_t dsizelog = dataSizeTableLog[t->operandType]; // log2(elementsize) length = length >> dsizelog << dsizelog; // round down to nearest multiple of element size uint32_t elementSize = 1 << dsizelog; // size of each element t->vectorLength[rd] = (uint32_t)length; // set length of destination uint8_t even = 1; uint32_t pos1 = 0; uint64_t value; for (uint32_t pos2 = 0; pos2 < length; pos2 += elementSize) { if (even) { value = t->readVectorElement(ru, pos1); } else { value = t->readVectorElement(rs, pos1); pos1 += elementSize; } even ^= 1; // toggle between even and odd if (rm < 7 && (t->readVectorElement(rm, pos2) & 1) == 0) value = 0; // mask is 0 t->writeVectorElement(rd, value, pos2); } t->vect = 4; // stop vector loop t->running = 2; // don't save RD return 0; } // Format 2.2.7 E. Three vector registers and a 16 bit immediate static uint64_t move_bits (CThread * t) { // Replace one or more contiguous bits at one position of RS with contiguous bits from another position of RT // Format 2.0.7 E: general purpose registers // Format 2.2.7 E: vector registers // The position in src2 is the lower 8 bits of IM2. a = IM2 & 0xFF. // The position in src1 is the upper 8 bits of IM2. b = IM2 >> 0xFF. // The number of bits to move is c = IM3. SNum s1 = t->parm[0]; // input operand src1 SNum s2 = t->parm[1]; // input operand src2 SNum im = t->parm[4]; // input operand IM2 SNum mask = t->parm[3]; // uint8_t c = t->pInstr->a.im3; // input operand IM3 = number of bits uint8_t pos1 = im.s >> 8; // bit position in src1. (can overflow, not handled) uint8_t pos2 = im.b; // bit position in src2. (can overflow, not handled) uint64_t bitmask = ((uint64_t)1 << c) - 1; // mask of c bits. (cannot overflow because c is max 63) uint64_t result = (s1.q & ~(bitmask << pos1)) | ((s2.q >> pos2) & bitmask) << pos1; if ((mask.b & 1) == 0) { // single format instructions with template E must handle mask here result = s1.q; // fallback if (t->operands[2] == 31) result = 0; // fallback = 0 } return result; } static uint64_t mask_length (CThread * t) { // Make a boolean vector to mask the first n bytes of a vector. // The output vector RD will have the same length as the input vector RS. // RT indicates the length of the part that is enabled by the mask (n). // IM3 contains the following option bits: // bit 0 = 0: bit 0 will be 1 in the first n bytes in the output and 0 in the rest. // bit 0 = 1: bit 0 will be 0 in the first n bytes in the output and 1 in the rest. // bit 1 = 1: copy remaining bits from input vector RT into each vector element. // bit 2 = 1: copy remaining bits from the numeric control register. // bit 4 = 1: broadcast remaining bits from IM2 into all 32-bit words of RD: // Bit 1-7 of IM2 go to bit 1-7 of RD. Bit 8-11 of IM2 go to bit 20-23 of RD. Bit 12-15 of IM2 go to bit 26-29 of RD. // Output bits that are not set by any of these options will be zero. If multiple options are specified, the results will be OR’ed. uint8_t rd = t->operands[0]; // destination uint8_t rs = t->operands[3]; // src2 uint8_t rt = t->operands[4]; // length SNum s2 = t->parm[0]; // input operand src2 SNum im2 = t->parm[4]; // input operand IM2 uint8_t im3 = t->pInstr->a.im3; // input operand IM3 = options t->vectorLengthR = t->vectorLength[rd] = t->vectorLength[rs]; // set length of destination uint8_t dsizelog = dataSizeTableLog[t->operandType]; // log2(elementsize) uint64_t n = t->registers[rt]; // number of masked elements uint32_t i = t->vectorOffset >> dsizelog; // current element index uint8_t bit = i < n; // element is within the first n bit ^= im3 & 1; // invert option uint64_t result = 0; if (im3 & 2) result |= s2.q; // copy remaining bits from src1 if (im3 & 4) result |= t->numContr; // copy remaining bits from NUMCONTR if (im3 & 0x10) { // copy bits from IM2 uint32_t rr = (im2.b & ~1) | bit; // bit 1-7 -> bit 1-7 rr |= (im2.s & 0xF00) << 12; // bit 8-11 -> bit 20-23 rr |= (im2.s & 0xF000) << 14; // bit 12-15 -> bit 26-29 result |= rr | ((uint64_t)rr << 32); // copy these bits twice } result = (result & ~(uint64_t)1) | bit; // combine return result; } static uint64_t truth_tab3 (CThread * t) { // Bitwise boolean function of three inputs, given by a truth table SNum a = t->parm[0]; // first operand SNum b = t->parm[1]; // second operand SNum c = t->parm[2]; // third operand SNum mask = t->parm[3]; // mask register uint32_t table = t->pInstr->a.im2; // truth table uint8_t options = t->pInstr->a.im3; // option bits uint32_t dataSize = dataSizeTableBits[t->operandType]; // number of bits if (options & 3) dataSize = 1; // only a single bit uint64_t result = 0; // calculate result for (int i = dataSize - 1; i >= 0; i--) { // loop through bits uint64_t bit_pointer = uint64_t(1) << i; // selected bit uint8_t index = 0; // index into truth table if (a.q & bit_pointer) index = 1; if (b.q & bit_pointer) index |= 2; if (c.q & bit_pointer) index |= 4; uint64_t bit = table >> index & 1; // lookup in truth table result = result << 1 | bit; // insert bit into result } if (options & 2) { // take remaining bits from mask or numcontr result |= mask.q & ~(uint64_t)1; } return result; } static uint64_t repeat_block (CThread * t) { // Repeat a block of data to make a longer vector. // RS is input vector containing data block to repeat. // IM2 is length in bytes of the block to repeat (must be a multiple of 4). // RT is the length of destination vector RD. uint8_t rd = t->operands[0]; uint8_t rs = t->operands[3]; uint8_t rt = t->operands[4]; uint32_t blen = t->parm[4].i; // block length uint64_t length = t->registers[rt]; // length of destination if (length > t->MaxVectorLength) length = t->MaxVectorLength; if (blen > t->MaxVectorLength) blen = t->MaxVectorLength; t->vectorLength[rd] = (uint32_t)length; // set length of destination if (blen & 3) t->interrupt(INT_WRONG_PARAMETERS); // must be a multiple of 4 int8_t * source = t->vectors.buf() + rs*t->MaxVectorLength; // address of RS data int8_t * destination = t->vectors.buf() + rd*t->MaxVectorLength; // address of RD data if (length > t->vectorLength[rs]) { // reading beyond the end of the source vector. make sure the rest is zero memset(source + t->vectorLength[rs], 0, size_t(length - t->vectorLength[rs])); } for (uint32_t pos = 0; pos < length; pos += blen) { // loop through blocks uint32_t blen2 = blen; if (pos + blen2 > length) blen2 = (uint32_t)length - pos; // avoid last block going too far memcpy(destination + pos, source, blen2); // copy block } t->vect = 4; // stop vector loop t->running = 2; // don't save RD return 0; } static uint64_t repeat_within_blocks (CThread * t) { // Broadcast the first element of each block of data in a vector to the entire block. // RS is input vector containing data blocks. // IM2 is length in bytes of each block (must be a multiple of the operand size). // RT is length of destination vector RD. // The operand size must be at least 4 bytes. uint8_t rd = t->operands[0]; uint8_t rs = t->operands[3]; uint8_t rt = t->operands[4]; uint32_t blen = t->parm[4].i; // block length uint64_t length = t->registers[rt]; // length of destination if (length > t->MaxVectorLength) length = t->MaxVectorLength; if (blen > t->MaxVectorLength) blen = t->MaxVectorLength; t->vectorLength[rd] = (uint32_t)length; // set length of destination uint32_t elementSize = dataSizeTable[t->operandType]; if (elementSize < 4 || (blen & (elementSize - 1))) t->interrupt(INT_WRONG_PARAMETERS); // must be a multiple of elementsize int8_t * source = t->vectors.buf() + rs*t->MaxVectorLength; // address of RS data int8_t * destination = t->vectors.buf() + rd*t->MaxVectorLength; // address of RD data if (length > t->vectorLength[rs]) { // reading beyond the end of the source vector. make sure the rest is zero memset(source + t->vectorLength[rs], 0, size_t(length - t->vectorLength[rs])); } for (uint32_t pos = 0; pos < length; pos += blen) { // loop through blocks uint32_t blen2 = blen; if (pos + blen2 > length) blen2 = (uint32_t)length - pos; // avoid last block going too far for (uint32_t i = 0; i < blen2; i += elementSize) { // loop within block memcpy(destination + pos + i, source + pos, elementSize); // copy first element } } t->vect = 4; // stop vector loop t->running = 2; // don't save RD return 0; } // tables of single format instructions // Format 1.3 B. Two vector registers and a broadcast 8-bit immediate operand. PFunc funcTab7[64] = { gp2vec, vec2gp, 0, make_sequence, insert_, extract_, compress, expand, // 0 - 7 0, 0, 0, 0, float2int, int2float, round_, round2n, // 8 - 15 abs_, fp_category, broad_, broad_, byte_reverse, bitscan_, popcount_, 0, // 16 - 23 0, bool2bits, bool_reduce, 0, 0, 0, 0, 0, // 24 - 31 0, 0, 0, 0, 0, 0, 0, 0, // 32 - 39 0, 0, 0, 0, 0, 0, 0, 0, // 40 - 47 0, 0, 0, 0, 0, 0, 0, 0, // 48 - 55 push_v, pop_v, clear_, 0, 0, 0, 0, 0, // 56 - 63 }; // Format 1.4 C. One vector register and a broadcast 16-bit immediate operand. PFunc funcTab8[64] = { move_i16, f_add, and_i16, or_i16, xor_i16, 0, 0, 0, // 0 - 7 move_8shift8, move_8shift8, add_8shift8, add_8shift8, and_8shift8, and_8shift8, or_8shift8, or_8shift8, // 8 - 15 xor_8shift8, xor_8shift8, 0, 0, 0, 0, 0, 0, // 16 - 23 0, 0, 0, 0, 0, 0, 0, 0, // 24 - 31 move_half2float, move_half2double, add_half2float, add_half2double, mul_half2float, mul_half2double, 0, 0, // 32 - 39 add_h16, mul_h16, 0, 0, 0, 0, 0, 0, // 40 - 47 0, 0, 0, 0, 0, 0, 0, 0, // 48 - 55 0, 0, 0, 0, 0, 0, 0, 0, // 56 - 63 }; // Format 2.5 A. Single format instructions with memory operands or mixed register types PFunc funcTab10[64] = { 0, 0, 0, 0, 0, 0, 0, 0, // 0 - 7 store_i32, 0, 0, 0, 0, 0, 0, 0, // 8 - 15 f_nop, 0, compare_swap, 0, 0, 0, 0, 0, // 16 - 23 0, 0, 0, 0, 0, 0, 0, 0, // 24 - 31 read_insert, 0, 0, 0, 0, 0, 0, 0, // 32 - 39 extract_store, 0, 0, 0, 0, 0, 0, 0, // 40 - 47 }; // Format 2.6 A. Three vector registers and a 32-bit immediate operand. PFunc funcTab11[64] = { load_hi, insert_hi, make_mask, replace_, replace_even, replace_odd, broadcast_32, 0, // 0 - 7 permute, 0, 0, 0, 0, 0, 0, 0 // 8 - 15 }; // Format 3.1 A. Three vector registers and a 64-bit immediate operand. PFunc funcTab13[64] = { 0, 0, 0, 0, 0, 0, 0, 0, // 0 - 7 0, 0, 0, 0, 0, 0, 0, 0, // 8 - 15 0, 0, 0, 0, 0, 0, 0, 0, // 16 - 23 0, 0, 0, 0, 0, 0, 0, 0, // 34 - 31 replace_, broadcast_32, 0, 0, 0, 0, 0, 0, // 32 - 39 }; // Dispatch functions for single format instruction with E template. // (full tables of all possible single format instruction with E template would // be too large with most places unused). // Format 2.0.6 E. Four general purpose registers static uint64_t dispatch206_1 (CThread * t) { switch (t->op) { case 8: return truth_tab3(t); default: t->interrupt(INT_UNKNOWN_INST); } return 0; } // Format 2.0.7 E. Three general purpose registers and a 16-bit immediate constant static uint64_t dispatch207_1 (CThread * t) { switch (t->op) { case 0: return move_bits(t); default: t->interrupt(INT_UNKNOWN_INST); } return 0; } // Format 2.2.6 E. Four vector registers static uint64_t dispatch226_1 (CThread * t) { switch (t->op) { case 0: return concatenate(t); case 1: return permute(t); case 2: return interleave(t); case 8: return truth_tab3(t); default: t->interrupt(INT_UNKNOWN_INST); } return 0; } // Format 2.2.7 E. Three vector registers and a 16-bit immediate constant static uint64_t dispatch227_1 (CThread * t) { switch (t->op) { case 0: return move_bits(t); case 1: return mask_length(t); case 8: return repeat_block(t); case 9: return repeat_within_blocks(t); default: t->interrupt(INT_UNKNOWN_INST); } return 0; } // Table of dispatch functions for all possible single format instructions with E template PFunc EDispatchTable[96] = { 0, 0, 0, 0, 0, 0, dispatch206_1, dispatch207_1, // 2.0.x i.1 0, 0, 0, 0, 0, 0, dispatch226_1, dispatch227_1, // 2.2.x i.1 0, 0, 0, 0, 0, 0, 0, 0, // 3.0.x i.1 0, 0, 0, 0, 0, 0, 0, 0, // 3.2.x i.1 0, 0, 0, 0, 0, 0, 0, 0, // 2.0.x i.2 0, 0, 0, 0, 0, 0, 0, 0, // 2.2.x i.2 0, 0, 0, 0, 0, 0, 0, 0, // 3.0.x i.2 0, 0, 0, 0, 0, 0, 0, 0, // 3.2.x i.2 0, 0, 0, 0, 0, 0, 0, 0, // 2.0.x i.3 0, 0, 0, 0, 0, 0, 0, 0, // 2.2.x i.3 0, 0, 0, 0, 0, 0, 0, 0, // 3.0.x i.3 0, 0, 0, 0, 0, 0, 0, 0 // 3.2.x i.3 };
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