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Duckstation/src/core/cpu_pgxp.cpp
Stenzek bc2c334370
Misc: Combine some redundant functions
2023-12-13 20:56:40 +10:00

1602 lines
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// SPDX-FileCopyrightText: 2016 iCatButler, 2019-2023 Connor McLaughlin <stenzek@gmail.com>
// SPDX-License-Identifier: GPL-2.0+
#include "cpu_pgxp.h"
#include "bus.h"
#include "cpu_core.h"
#include "settings.h"
#include "common/assert.h"
#include "common/log.h"
#include <climits>
#include <cmath>
Log_SetChannel(CPU::PGXP);
namespace CPU::PGXP {
namespace {
enum : u32
{
VERTEX_CACHE_WIDTH = 0x800 * 2,
VERTEX_CACHE_HEIGHT = 0x800 * 2,
VERTEX_CACHE_SIZE = VERTEX_CACHE_WIDTH * VERTEX_CACHE_HEIGHT,
PGXP_MEM_SIZE = (static_cast<u32>(Bus::RAM_8MB_SIZE) + static_cast<u32>(CPU::SCRATCHPAD_SIZE)) / 4,
PGXP_MEM_SCRATCH_OFFSET = Bus::RAM_8MB_SIZE / 4
};
#define NONE 0
#define ALL 0xFFFFFFFF
#define VALID 1
#define VALID_0 (VALID << 0)
#define VALID_1 (VALID << 8)
#define VALID_2 (VALID << 16)
#define VALID_3 (VALID << 24)
#define VALID_01 (VALID_0 | VALID_1)
#define VALID_012 (VALID_0 | VALID_1 | VALID_2)
#define VALID_ALL (VALID_0 | VALID_1 | VALID_2 | VALID_3)
#define INV_VALID_ALL (ALL ^ VALID_ALL)
union psx_value
{
u32 d;
s32 sd;
struct
{
u16 l, h;
} w;
struct
{
s16 l, h;
} sw;
};
} // namespace
static void CacheVertex(s16 sx, s16 sy, const PGXP_value& vertex);
static PGXP_value* GetCachedVertex(short sx, short sy);
static float TruncateVertexPosition(float p);
static bool IsWithinTolerance(float precise_x, float precise_y, int int_x, int int_y);
static void MakeValid(PGXP_value* pV, u32 psxV);
static void Validate(PGXP_value* pV, u32 psxV);
static void MaskValidate(PGXP_value* pV, u32 psxV, u32 mask, u32 validMask);
static double f16Sign(double in);
static double f16Unsign(double in);
static double f16Overflow(double in);
static PGXP_value* GetPtr(u32 addr);
static void ValidateAndCopyMem(PGXP_value* dest, u32 addr, u32 value);
static void ValidateAndCopyMem16(PGXP_value* dest, u32 addr, u32 value, bool sign);
static void CPU_MTC2_int(const PGXP_value& value, u32 reg);
static void CPU_BITWISE(u32 instr, u32 rdVal, u32 rsVal, u32 rtVal);
static void WriteMem(const PGXP_value* value, u32 addr);
static void WriteMem16(const PGXP_value* src, u32 addr);
static const PGXP_value PGXP_value_invalid = {0.f, 0.f, 0.f, 0, {0}};
static const PGXP_value PGXP_value_zero = {0.f, 0.f, 0.f, 0, {VALID_ALL}};
static PGXP_value* s_mem = nullptr;
static PGXP_value* s_vertex_cache = nullptr;
} // namespace CPU::PGXP
void CPU::PGXP::Initialize()
{
std::memset(g_state.pgxp_gpr, 0, sizeof(g_state.pgxp_gpr));
std::memset(g_state.pgxp_cop0, 0, sizeof(g_state.pgxp_cop0));
std::memset(g_state.pgxp_gte, 0, sizeof(g_state.pgxp_gte));
if (!s_mem)
{
s_mem = static_cast<PGXP_value*>(std::calloc(PGXP_MEM_SIZE, sizeof(PGXP_value)));
if (!s_mem)
Panic("Failed to allocate PGXP memory");
}
if (g_settings.gpu_pgxp_vertex_cache && !s_vertex_cache)
{
s_vertex_cache = static_cast<PGXP_value*>(std::calloc(VERTEX_CACHE_SIZE, sizeof(PGXP_value)));
if (!s_vertex_cache)
{
Log_ErrorPrint("Failed to allocate memory for vertex cache, disabling.");
g_settings.gpu_pgxp_vertex_cache = false;
}
}
if (s_vertex_cache)
std::memset(s_vertex_cache, 0, sizeof(PGXP_value) * VERTEX_CACHE_SIZE);
}
void CPU::PGXP::Reset()
{
std::memset(g_state.pgxp_gpr, 0, sizeof(g_state.pgxp_gpr));
std::memset(g_state.pgxp_cop0, 0, sizeof(g_state.pgxp_cop0));
std::memset(g_state.pgxp_gte, 0, sizeof(g_state.pgxp_gte));
if (s_mem)
std::memset(s_mem, 0, sizeof(PGXP_value) * PGXP_MEM_SIZE);
if (s_vertex_cache)
std::memset(s_vertex_cache, 0, sizeof(PGXP_value) * VERTEX_CACHE_SIZE);
}
void CPU::PGXP::Shutdown()
{
if (s_vertex_cache)
{
std::free(s_vertex_cache);
s_vertex_cache = nullptr;
}
if (s_mem)
{
std::free(s_mem);
s_mem = nullptr;
}
std::memset(g_state.pgxp_gte, 0, sizeof(g_state.pgxp_gte));
std::memset(g_state.pgxp_gpr, 0, sizeof(g_state.pgxp_gpr));
std::memset(g_state.pgxp_cop0, 0, sizeof(g_state.pgxp_cop0));
}
// Instruction register decoding
#define op(_instr) (_instr >> 26) // The op part of the instruction register
#define func(_instr) ((_instr)&0x3F) // The funct part of the instruction register
#define sa(_instr) ((_instr >> 6) & 0x1F) // The sa part of the instruction register
#define rd(_instr) ((_instr >> 11) & 0x1F) // The rd part of the instruction register
#define rt(_instr) ((_instr >> 16) & 0x1F) // The rt part of the instruction register
#define rs(_instr) ((_instr >> 21) & 0x1F) // The rs part of the instruction register
#define imm(_instr) (_instr & 0xFFFF) // The immediate part of the instruction register
#define cop2idx(_instr) (((_instr >> 11) & 0x1F) | ((_instr >> 17) & 0x20))
#define SX0 (g_state.pgxp_gte[12].x)
#define SY0 (g_state.pgxp_gte[12].y)
#define SX1 (g_state.pgxp_gte[13].x)
#define SY1 (g_state.pgxp_gte[13].y)
#define SX2 (g_state.pgxp_gte[14].x)
#define SY2 (g_state.pgxp_gte[14].y)
#define SXY0 (g_state.pgxp_gte[12])
#define SXY1 (g_state.pgxp_gte[13])
#define SXY2 (g_state.pgxp_gte[14])
#define SXYP (g_state.pgxp_gte[15])
ALWAYS_INLINE_RELEASE void CPU::PGXP::MakeValid(PGXP_value* pV, u32 psxV)
{
if ((pV->flags & VALID_01) == VALID_01)
return;
pV->x = static_cast<float>(static_cast<s16>(Truncate16(psxV)));
pV->y = static_cast<float>(static_cast<s16>(Truncate16(psxV >> 16)));
pV->z = 0.0f;
pV->flags = VALID_01;
pV->value = psxV;
}
ALWAYS_INLINE_RELEASE void CPU::PGXP::Validate(PGXP_value* pV, u32 psxV)
{
pV->flags &= (pV->value == psxV) ? ALL : INV_VALID_ALL;
}
ALWAYS_INLINE_RELEASE void CPU::PGXP::MaskValidate(PGXP_value* pV, u32 psxV, u32 mask, u32 validMask)
{
pV->flags &= ((pV->value & mask) == (psxV & mask)) ? ALL : (ALL ^ (validMask));
}
ALWAYS_INLINE_RELEASE double CPU::PGXP::f16Sign(double in)
{
const s32 s = static_cast<s32>(static_cast<s64>(in * (USHRT_MAX + 1)));
return static_cast<double>(s) / static_cast<double>(USHRT_MAX + 1);
}
ALWAYS_INLINE_RELEASE double CPU::PGXP::f16Unsign(double in)
{
return (in >= 0) ? in : (in + (USHRT_MAX + 1));
}
ALWAYS_INLINE_RELEASE double CPU::PGXP::f16Overflow(double in)
{
double out = 0;
s64 v = ((s64)in) >> 16;
out = (double)v;
return out;
}
ALWAYS_INLINE_RELEASE CPU::PGXP_value* CPU::PGXP::GetPtr(u32 addr)
{
if ((addr & SCRATCHPAD_ADDR_MASK) == SCRATCHPAD_ADDR)
return &s_mem[PGXP_MEM_SCRATCH_OFFSET + ((addr & SCRATCHPAD_OFFSET_MASK) >> 2)];
const u32 paddr = (addr & PHYSICAL_MEMORY_ADDRESS_MASK);
if (paddr < Bus::RAM_MIRROR_END)
return &s_mem[(paddr & Bus::g_ram_mask) >> 2];
else
return nullptr;
}
ALWAYS_INLINE_RELEASE void CPU::PGXP::ValidateAndCopyMem(PGXP_value* dest, u32 addr, u32 value)
{
PGXP_value* pMem = GetPtr(addr);
if (!pMem)
{
*dest = PGXP_value_invalid;
return;
}
Validate(pMem, value);
*dest = *pMem;
}
ALWAYS_INLINE_RELEASE void CPU::PGXP::ValidateAndCopyMem16(PGXP_value* dest, u32 addr, u32 value, bool sign)
{
PGXP_value* pMem = GetPtr(addr);
if (!pMem)
{
*dest = PGXP_value_invalid;
return;
}
psx_value val{0}, mask{0};
u32 valid_mask = 0;
// determine if high or low word
const bool hiword = ((addr & 2) != 0);
if (hiword)
{
val.w.h = static_cast<u16>(value);
mask.w.h = 0xFFFF;
valid_mask = VALID_1;
}
else
{
val.w.l = static_cast<u16>(value);
mask.w.l = 0xFFFF;
valid_mask = VALID_0;
}
// validate and copy whole value
MaskValidate(pMem, val.d, mask.d, valid_mask);
*dest = *pMem;
// if high word then shift
if (hiword)
{
dest->x = dest->y;
dest->compFlags[0] = dest->compFlags[1];
}
// only set y as valid if x is also valid.. don't want to make fake values
if (dest->compFlags[0] == VALID)
{
dest->y = (dest->x < 0) ? -1.f * sign : 0.f;
dest->compFlags[1] = VALID;
}
else
{
dest->y = 0.0f;
dest->compFlags[1] = 0;
}
dest->value = value;
}
ALWAYS_INLINE_RELEASE void CPU::PGXP::WriteMem(const PGXP_value* value, u32 addr)
{
PGXP_value* pMem = GetPtr(addr);
if (pMem)
*pMem = *value;
}
ALWAYS_INLINE_RELEASE void CPU::PGXP::WriteMem16(const PGXP_value* src, u32 addr)
{
PGXP_value* dest = GetPtr(addr);
if (!dest)
return;
// determine if high or low word
const bool hiword = ((addr & 2) != 0);
if (hiword)
{
dest->y = src->x;
dest->compFlags[1] = src->compFlags[0];
dest->value = (dest->value & UINT32_C(0x0000FFFF)) | (src->value << 16);
}
else
{
dest->x = src->x;
dest->compFlags[0] = src->compFlags[0];
dest->value = (dest->value & UINT32_C(0xFFFF0000)) | (src->value & UINT32_C(0x0000FFFF));
}
// overwrite z/w if valid
if (src->compFlags[2] == VALID)
{
dest->z = src->z;
dest->compFlags[2] = src->compFlags[2];
}
}
void CPU::PGXP::GTE_PushSXYZ2f(float x, float y, float z, u32 v)
{
// push values down FIFO
SXY0 = SXY1;
SXY1 = SXY2;
SXY2.x = x;
SXY2.y = y;
SXY2.z = z;
SXY2.value = v;
SXY2.flags = VALID_ALL;
if (g_settings.gpu_pgxp_vertex_cache)
CacheVertex(static_cast<s16>(Truncate16(v)), static_cast<s16>(Truncate16(v >> 16)), SXY2);
}
#define VX(n) (psxRegs.CP2D.p[n << 1].sw.l)
#define VY(n) (psxRegs.CP2D.p[n << 1].sw.h)
#define VZ(n) (psxRegs.CP2D.p[(n << 1) + 1].sw.l)
int CPU::PGXP::GTE_NCLIP_valid(u32 sxy0, u32 sxy1, u32 sxy2)
{
Validate(&SXY0, sxy0);
Validate(&SXY1, sxy1);
Validate(&SXY2, sxy2);
// Don't use accurate clipping for game-constructed values, which don't have a valid Z.
return (((SXY0.flags & SXY1.flags & SXY2.flags & VALID_012) == VALID_012));
}
float CPU::PGXP::GTE_NCLIP()
{
float nclip = ((SX0 * SY1) + (SX1 * SY2) + (SX2 * SY0) - (SX0 * SY2) - (SX1 * SY0) - (SX2 * SY1));
// ensure fractional values are not incorrectly rounded to 0
float nclipAbs = std::abs(nclip);
if ((0.1f < nclipAbs) && (nclipAbs < 1.f))
nclip += (nclip < 0.f ? -1 : 1);
// float AX = SX1 - SX0;
// float AY = SY1 - SY0;
// float BX = SX2 - SX0;
// float BY = SY2 - SY0;
//// normalise A and B
// float mA = sqrt((AX*AX) + (AY*AY));
// float mB = sqrt((BX*BX) + (BY*BY));
//// calculate AxB to get Z component of C
// float CZ = ((AX * BY) - (AY * BX)) * (1 << 12);
return nclip;
}
ALWAYS_INLINE_RELEASE void CPU::PGXP::CPU_MTC2_int(const PGXP_value& value, u32 reg)
{
switch (reg)
{
case 15:
// push FIFO
SXY0 = SXY1;
SXY1 = SXY2;
SXY2 = value;
SXYP = SXY2;
break;
case 31:
return;
}
g_state.pgxp_gte[reg] = value;
}
////////////////////////////////////
// Data transfer tracking
////////////////////////////////////
void CPU::PGXP::CPU_MFC2(u32 instr, u32 rdVal)
{
// CPU[Rt] = GTE_D[Rd]
const u32 idx = cop2idx(instr);
Validate(&g_state.pgxp_gte[idx], rdVal);
g_state.pgxp_gpr[rt(instr)] = g_state.pgxp_gte[idx];
g_state.pgxp_gpr[rt(instr)].value = rdVal;
}
void CPU::PGXP::CPU_MTC2(u32 instr, u32 rtVal)
{
// GTE_D[Rd] = CPU[Rt]
const u32 idx = cop2idx(instr);
Validate(&g_state.pgxp_gpr[rt(instr)], rtVal);
CPU_MTC2_int(g_state.pgxp_gpr[rt(instr)], idx);
g_state.pgxp_gte[idx].value = rtVal;
}
////////////////////////////////////
// Memory Access
////////////////////////////////////
void CPU::PGXP::CPU_LWC2(u32 instr, u32 addr, u32 rtVal)
{
// GTE_D[Rt] = Mem[addr]
PGXP_value val;
ValidateAndCopyMem(&val, addr, rtVal);
CPU_MTC2_int(val, rt(instr));
}
void CPU::PGXP::CPU_SWC2(u32 instr, u32 addr, u32 rtVal)
{
// Mem[addr] = GTE_D[Rt]
Validate(&g_state.pgxp_gte[rt(instr)], rtVal);
WriteMem(&g_state.pgxp_gte[rt(instr)], addr);
}
ALWAYS_INLINE_RELEASE void CPU::PGXP::CacheVertex(s16 sx, s16 sy, const PGXP_value& vertex)
{
if (sx >= -0x800 && sx <= 0x7ff && sy >= -0x800 && sy <= 0x7ff)
{
// Write vertex into cache
s_vertex_cache[(sy + 0x800) * VERTEX_CACHE_WIDTH + (sx + 0x800)] = vertex;
}
}
ALWAYS_INLINE_RELEASE CPU::PGXP_value* CPU::PGXP::GetCachedVertex(short sx, short sy)
{
if (sx >= -0x800 && sx <= 0x7ff && sy >= -0x800 && sy <= 0x7ff)
{
// Return pointer to cache entry
return &s_vertex_cache[(sy + 0x800) * VERTEX_CACHE_WIDTH + (sx + 0x800)];
}
return nullptr;
}
ALWAYS_INLINE_RELEASE float CPU::PGXP::TruncateVertexPosition(float p)
{
const s32 int_part = static_cast<s32>(p);
const float int_part_f = static_cast<float>(int_part);
return static_cast<float>(static_cast<s16>(int_part << 5) >> 5) + (p - int_part_f);
}
ALWAYS_INLINE_RELEASE bool CPU::PGXP::IsWithinTolerance(float precise_x, float precise_y, int int_x, int int_y)
{
const float tolerance = g_settings.gpu_pgxp_tolerance;
if (tolerance < 0.0f)
return true;
return (std::abs(precise_x - static_cast<float>(int_x)) <= tolerance &&
std::abs(precise_y - static_cast<float>(int_y)) <= tolerance);
}
bool CPU::PGXP::GetPreciseVertex(u32 addr, u32 value, int x, int y, int xOffs, int yOffs, float* out_x, float* out_y,
float* out_w)
{
const PGXP_value* vert = GetPtr(addr);
if (vert && ((vert->flags & VALID_01) == VALID_01) && (vert->value == value))
{
// There is a value here with valid X and Y coordinates
*out_x = TruncateVertexPosition(vert->x) + static_cast<float>(xOffs);
*out_y = TruncateVertexPosition(vert->y) + static_cast<float>(yOffs);
*out_w = vert->z / 32768.0f;
if (IsWithinTolerance(*out_x, *out_y, x, y))
{
// check validity of z component
return ((vert->flags & VALID_2) == VALID_2);
}
}
if (g_settings.gpu_pgxp_vertex_cache)
{
const short psx_x = (short)(value & 0xFFFFu);
const short psx_y = (short)(value >> 16);
// Look in cache for valid vertex
vert = GetCachedVertex(psx_x, psx_y);
if (vert && (vert->flags & VALID_01) == VALID_01)
{
*out_x = TruncateVertexPosition(vert->x) + static_cast<float>(xOffs);
*out_y = TruncateVertexPosition(vert->y) + static_cast<float>(yOffs);
*out_w = vert->z / 32768.0f;
if (IsWithinTolerance(*out_x, *out_y, x, y))
return false;
}
}
// no valid value can be found anywhere, use the native PSX data
*out_x = static_cast<float>(x);
*out_y = static_cast<float>(y);
*out_w = 1.0f;
return false;
}
// Instruction register decoding
#define op(_instr) (_instr >> 26) // The op part of the instruction register
#define func(_instr) ((_instr)&0x3F) // The funct part of the instruction register
#define sa(_instr) ((_instr >> 6) & 0x1F) // The sa part of the instruction register
#define rd(_instr) ((_instr >> 11) & 0x1F) // The rd part of the instruction register
#define rt(_instr) ((_instr >> 16) & 0x1F) // The rt part of the instruction register
#define rs(_instr) ((_instr >> 21) & 0x1F) // The rs part of the instruction register
#define imm(_instr) (_instr & 0xFFFF) // The immediate part of the instruction register
#define imm_sext(_instr) \
static_cast<s32>(static_cast<s16>(_instr & 0xFFFF)) // The immediate part of the instruction register
void CPU::PGXP::CPU_LW(u32 instr, u32 addr, u32 rtVal)
{
// Rt = Mem[Rs + Im]
ValidateAndCopyMem(&g_state.pgxp_gpr[rt(instr)], addr, rtVal);
}
void CPU::PGXP::CPU_LBx(u32 instr, u32 addr, u32 rtVal)
{
g_state.pgxp_gpr[rt(instr)] = PGXP_value_invalid;
}
void CPU::PGXP::CPU_LH(u32 instr, u32 addr, u32 rtVal)
{
// Rt = Mem[Rs + Im] (sign extended)
ValidateAndCopyMem16(&g_state.pgxp_gpr[rt(instr)], addr, rtVal, true);
}
void CPU::PGXP::CPU_LHU(u32 instr, u32 addr, u32 rtVal)
{
// Rt = Mem[Rs + Im] (zero extended)
ValidateAndCopyMem16(&g_state.pgxp_gpr[rt(instr)], addr, rtVal, false);
}
void CPU::PGXP::CPU_SB(u32 instr, u32 addr, u32 rtVal)
{
WriteMem(&PGXP_value_invalid, addr);
}
void CPU::PGXP::CPU_SH(u32 instr, u32 addr, u32 rtVal)
{
PGXP_value* val = &g_state.pgxp_gpr[rt(instr)];
Validate(val, rtVal);
WriteMem16(val, addr);
}
void CPU::PGXP::CPU_SW(u32 instr, u32 addr, u32 rtVal)
{
// Mem[Rs + Im] = Rt
PGXP_value* val = &g_state.pgxp_gpr[rt(instr)];
Validate(val, rtVal);
WriteMem(val, addr);
}
void CPU::PGXP::CPU_MOVE_Packed(u32 rd_and_rs, u32 rsVal)
{
const u32 Rs = (rd_and_rs & 0xFFu);
const u32 Rd = (rd_and_rs >> 8);
CPU_MOVE(Rd, Rs, rsVal);
}
void CPU::PGXP::CPU_MOVE(u32 Rd, u32 Rs, u32 rsVal)
{
Validate(&g_state.pgxp_gpr[Rs], rsVal);
g_state.pgxp_gpr[Rd] = g_state.pgxp_gpr[Rs];
}
void CPU::PGXP::CPU_ADDI(u32 instr, u32 rsVal)
{
// Rt = Rs + Imm (signed)
Validate(&g_state.pgxp_gpr[rs(instr)], rsVal);
PGXP_value ret = g_state.pgxp_gpr[rs(instr)];
psx_value tempImm;
tempImm.d = SignExtend32(static_cast<u16>(imm(instr)));
if (tempImm.d != 0)
{
ret.x = (float)f16Unsign(ret.x);
ret.x += (float)tempImm.w.l;
// carry on over/underflow
float of = (ret.x > USHRT_MAX) ? 1.f : (ret.x < 0) ? -1.f : 0.f;
ret.x = (float)f16Sign(ret.x);
// ret.x -= of * (USHRT_MAX + 1);
ret.y += tempImm.sw.h + of;
// truncate on overflow/underflow
ret.y += (ret.y > SHRT_MAX) ? -(USHRT_MAX + 1) : (ret.y < SHRT_MIN) ? USHRT_MAX + 1 : 0.f;
}
g_state.pgxp_gpr[rt(instr)] = ret;
g_state.pgxp_gpr[rt(instr)].value = rsVal + imm_sext(instr);
}
void CPU::PGXP::CPU_ANDI(u32 instr, u32 rsVal)
{
// Rt = Rs & Imm
const u32 rtVal = rsVal & imm(instr);
psx_value vRt;
PGXP_value ret;
Validate(&g_state.pgxp_gpr[rs(instr)], rsVal);
ret = g_state.pgxp_gpr[rs(instr)];
vRt.d = rtVal;
ret.y = 0.f; // remove upper 16-bits
switch (imm(instr))
{
case 0:
// if 0 then x == 0
ret.x = 0.f;
break;
case 0xFFFF:
// if saturated then x == x
break;
default:
// otherwise x is low precision value
ret.x = vRt.sw.l;
ret.flags |= VALID_0;
}
ret.flags |= VALID_1;
g_state.pgxp_gpr[rt(instr)] = ret;
g_state.pgxp_gpr[rt(instr)].value = rtVal;
}
void CPU::PGXP::CPU_ORI(u32 instr, u32 rsVal)
{
// Rt = Rs | Imm
const u32 rtVal = rsVal | imm(instr);
psx_value vRt;
PGXP_value ret;
Validate(&g_state.pgxp_gpr[rs(instr)], rsVal);
ret = g_state.pgxp_gpr[rs(instr)];
vRt.d = rtVal;
switch (imm(instr))
{
case 0:
// if 0 then x == x
break;
default:
// otherwise x is low precision value
ret.x = vRt.sw.l;
ret.flags |= VALID_0;
}
ret.value = rtVal;
g_state.pgxp_gpr[rt(instr)] = ret;
}
void CPU::PGXP::CPU_XORI(u32 instr, u32 rsVal)
{
// Rt = Rs ^ Imm
const u32 rtVal = rsVal ^ imm(instr);
psx_value vRt;
PGXP_value ret;
Validate(&g_state.pgxp_gpr[rs(instr)], rsVal);
ret = g_state.pgxp_gpr[rs(instr)];
vRt.d = rtVal;
switch (imm(instr))
{
case 0:
// if 0 then x == x
break;
default:
// otherwise x is low precision value
ret.x = vRt.sw.l;
ret.flags |= VALID_0;
}
ret.value = rtVal;
g_state.pgxp_gpr[rt(instr)] = ret;
}
void CPU::PGXP::CPU_SLTI(u32 instr, u32 rsVal)
{
// Rt = Rs < Imm (signed)
psx_value tempImm;
PGXP_value ret;
Validate(&g_state.pgxp_gpr[rs(instr)], rsVal);
ret = g_state.pgxp_gpr[rs(instr)];
tempImm.w.h = imm(instr);
ret.y = 0.f;
ret.x = (g_state.pgxp_gpr[rs(instr)].x < tempImm.sw.h) ? 1.f : 0.f;
ret.flags |= VALID_1;
ret.value = BoolToUInt32(static_cast<s32>(rsVal) < imm_sext(instr));
g_state.pgxp_gpr[rt(instr)] = ret;
}
void CPU::PGXP::CPU_SLTIU(u32 instr, u32 rsVal)
{
// Rt = Rs < Imm (Unsigned)
psx_value tempImm;
PGXP_value ret;
Validate(&g_state.pgxp_gpr[rs(instr)], rsVal);
ret = g_state.pgxp_gpr[rs(instr)];
tempImm.w.h = imm(instr);
ret.y = 0.f;
ret.x = (f16Unsign(g_state.pgxp_gpr[rs(instr)].x) < tempImm.w.h) ? 1.f : 0.f;
ret.flags |= VALID_1;
ret.value = BoolToUInt32(rsVal < imm(instr));
g_state.pgxp_gpr[rt(instr)] = ret;
}
////////////////////////////////////
// Load Upper
////////////////////////////////////
void CPU::PGXP::CPU_LUI(u32 instr)
{
// Rt = Imm << 16
g_state.pgxp_gpr[rt(instr)] = PGXP_value_zero;
g_state.pgxp_gpr[rt(instr)].y = (float)(s16)imm(instr);
g_state.pgxp_gpr[rt(instr)].value = static_cast<u32>(imm(instr)) << 16;
g_state.pgxp_gpr[rt(instr)].flags = VALID_01;
}
////////////////////////////////////
// Register Arithmetic
////////////////////////////////////
void CPU::PGXP::CPU_ADD(u32 instr, u32 rsVal, u32 rtVal)
{
// Rd = Rs + Rt (signed)
PGXP_value ret;
Validate(&g_state.pgxp_gpr[rs(instr)], rsVal);
Validate(&g_state.pgxp_gpr[rt(instr)], rtVal);
if (rtVal == 0)
{
ret = g_state.pgxp_gpr[rs(instr)];
}
else if (rsVal == 0)
{
ret = g_state.pgxp_gpr[rt(instr)];
}
else
{
// iCB: Only require one valid input
if (((g_state.pgxp_gpr[rt(instr)].flags & VALID_01) != VALID_01) !=
((g_state.pgxp_gpr[rs(instr)].flags & VALID_01) != VALID_01))
{
MakeValid(&g_state.pgxp_gpr[rs(instr)], rsVal);
MakeValid(&g_state.pgxp_gpr[rt(instr)], rtVal);
}
ret = g_state.pgxp_gpr[rs(instr)];
ret.x = (float)f16Unsign(ret.x);
ret.x += (float)f16Unsign(g_state.pgxp_gpr[rt(instr)].x);
// carry on over/underflow
float of = (ret.x > USHRT_MAX) ? 1.f : (ret.x < 0) ? -1.f : 0.f;
ret.x = (float)f16Sign(ret.x);
// ret.x -= of * (USHRT_MAX + 1);
ret.y += g_state.pgxp_gpr[rt(instr)].y + of;
// truncate on overflow/underflow
ret.y += (ret.y > SHRT_MAX) ? -(USHRT_MAX + 1) : (ret.y < SHRT_MIN) ? USHRT_MAX + 1 : 0.f;
// TODO: decide which "z/w" component to use
ret.halfFlags[0] &= g_state.pgxp_gpr[rt(instr)].halfFlags[0];
}
if (!(ret.flags & VALID_2) && (g_state.pgxp_gpr[rt(instr)].flags & VALID_2))
{
ret.z = g_state.pgxp_gpr[rt(instr)].z;
ret.flags |= VALID_2;
}
ret.value = rsVal + rtVal;
g_state.pgxp_gpr[rd(instr)] = ret;
}
void CPU::PGXP::CPU_SUB(u32 instr, u32 rsVal, u32 rtVal)
{
// Rd = Rs - Rt (signed)
PGXP_value ret;
Validate(&g_state.pgxp_gpr[rs(instr)], rsVal);
Validate(&g_state.pgxp_gpr[rt(instr)], rtVal);
// iCB: Only require one valid input
if (((g_state.pgxp_gpr[rt(instr)].flags & VALID_01) != VALID_01) !=
((g_state.pgxp_gpr[rs(instr)].flags & VALID_01) != VALID_01))
{
MakeValid(&g_state.pgxp_gpr[rs(instr)], rsVal);
MakeValid(&g_state.pgxp_gpr[rt(instr)], rtVal);
}
ret = g_state.pgxp_gpr[rs(instr)];
ret.x = (float)f16Unsign(ret.x);
ret.x -= (float)f16Unsign(g_state.pgxp_gpr[rt(instr)].x);
// carry on over/underflow
float of = (ret.x > USHRT_MAX) ? 1.f : (ret.x < 0) ? -1.f : 0.f;
ret.x = (float)f16Sign(ret.x);
// ret.x -= of * (USHRT_MAX + 1);
ret.y -= g_state.pgxp_gpr[rt(instr)].y - of;
// truncate on overflow/underflow
ret.y += (ret.y > SHRT_MAX) ? -(USHRT_MAX + 1) : (ret.y < SHRT_MIN) ? USHRT_MAX + 1 : 0.f;
ret.halfFlags[0] &= g_state.pgxp_gpr[rt(instr)].halfFlags[0];
ret.value = rsVal - rtVal;
if (!(ret.flags & VALID_2) && (g_state.pgxp_gpr[rt(instr)].flags & VALID_2))
{
ret.z = g_state.pgxp_gpr[rt(instr)].z;
ret.flags |= VALID_2;
}
g_state.pgxp_gpr[rd(instr)] = ret;
}
ALWAYS_INLINE_RELEASE void CPU::PGXP::CPU_BITWISE(u32 instr, u32 rdVal, u32 rsVal, u32 rtVal)
{
// Rd = Rs & Rt
psx_value vald, vals, valt;
PGXP_value ret;
Validate(&g_state.pgxp_gpr[rs(instr)], rsVal);
Validate(&g_state.pgxp_gpr[rt(instr)], rtVal);
// iCB: Only require one valid input
if (((g_state.pgxp_gpr[rt(instr)].flags & VALID_01) != VALID_01) !=
((g_state.pgxp_gpr[rs(instr)].flags & VALID_01) != VALID_01))
{
MakeValid(&g_state.pgxp_gpr[rs(instr)], rsVal);
MakeValid(&g_state.pgxp_gpr[rt(instr)], rtVal);
}
vald.d = rdVal;
vals.d = rsVal;
valt.d = rtVal;
// CPU_reg[rd(instr)].valid = CPU_reg[rs(instr)].valid && CPU_reg[rt(instr)].valid;
ret.flags = VALID_01;
if (vald.w.l == 0)
{
ret.x = 0.f;
}
else if (vald.w.l == vals.w.l)
{
ret.x = g_state.pgxp_gpr[rs(instr)].x;
ret.compFlags[0] = g_state.pgxp_gpr[rs(instr)].compFlags[0];
}
else if (vald.w.l == valt.w.l)
{
ret.x = g_state.pgxp_gpr[rt(instr)].x;
ret.compFlags[0] = g_state.pgxp_gpr[rt(instr)].compFlags[0];
}
else
{
ret.x = (float)vald.sw.l;
ret.compFlags[0] = VALID;
}
if (vald.w.h == 0)
{
ret.y = 0.f;
}
else if (vald.w.h == vals.w.h)
{
ret.y = g_state.pgxp_gpr[rs(instr)].y;
ret.compFlags[1] &= g_state.pgxp_gpr[rs(instr)].compFlags[1];
}
else if (vald.w.h == valt.w.h)
{
ret.y = g_state.pgxp_gpr[rt(instr)].y;
ret.compFlags[1] &= g_state.pgxp_gpr[rt(instr)].compFlags[1];
}
else
{
ret.y = (float)vald.sw.h;
ret.compFlags[1] = VALID;
}
// iCB Hack: Force validity if even one half is valid
// if ((ret.hFlags & VALID_HALF) || (ret.lFlags & VALID_HALF))
// ret.valid = 1;
// /iCB Hack
// Get a valid W
if ((g_state.pgxp_gpr[rs(instr)].flags & VALID_2) == VALID_2)
{
ret.z = g_state.pgxp_gpr[rs(instr)].z;
ret.compFlags[2] = g_state.pgxp_gpr[rs(instr)].compFlags[2];
}
else if ((g_state.pgxp_gpr[rt(instr)].flags & VALID_2) == VALID_2)
{
ret.z = g_state.pgxp_gpr[rt(instr)].z;
ret.compFlags[2] = g_state.pgxp_gpr[rt(instr)].compFlags[2];
}
else
{
ret.z = 0.0f;
ret.compFlags[2] = 0;
}
ret.value = rdVal;
g_state.pgxp_gpr[rd(instr)] = ret;
}
void CPU::PGXP::CPU_AND_(u32 instr, u32 rsVal, u32 rtVal)
{
// Rd = Rs & Rt
const u32 rdVal = rsVal & rtVal;
CPU_BITWISE(instr, rdVal, rsVal, rtVal);
}
void CPU::PGXP::CPU_OR_(u32 instr, u32 rsVal, u32 rtVal)
{
// Rd = Rs | Rt
const u32 rdVal = rsVal | rtVal;
CPU_BITWISE(instr, rdVal, rsVal, rtVal);
}
void CPU::PGXP::CPU_XOR_(u32 instr, u32 rsVal, u32 rtVal)
{
// Rd = Rs ^ Rt
const u32 rdVal = rsVal ^ rtVal;
CPU_BITWISE(instr, rdVal, rsVal, rtVal);
}
void CPU::PGXP::CPU_NOR(u32 instr, u32 rsVal, u32 rtVal)
{
// Rd = Rs NOR Rt
const u32 rdVal = ~(rsVal | rtVal);
CPU_BITWISE(instr, rdVal, rsVal, rtVal);
}
void CPU::PGXP::CPU_SLT(u32 instr, u32 rsVal, u32 rtVal)
{
// Rd = Rs < Rt (signed)
PGXP_value ret;
Validate(&g_state.pgxp_gpr[rs(instr)], rsVal);
Validate(&g_state.pgxp_gpr[rt(instr)], rtVal);
// iCB: Only require one valid input
if (((g_state.pgxp_gpr[rt(instr)].flags & VALID_01) != VALID_01) !=
((g_state.pgxp_gpr[rs(instr)].flags & VALID_01) != VALID_01))
{
MakeValid(&g_state.pgxp_gpr[rs(instr)], rsVal);
MakeValid(&g_state.pgxp_gpr[rt(instr)], rtVal);
}
ret = g_state.pgxp_gpr[rs(instr)];
ret.y = 0.f;
ret.compFlags[1] = VALID;
ret.x = (g_state.pgxp_gpr[rs(instr)].y < g_state.pgxp_gpr[rt(instr)].y) ? 1.f :
(f16Unsign(g_state.pgxp_gpr[rs(instr)].x) < f16Unsign(g_state.pgxp_gpr[rt(instr)].x)) ? 1.f :
0.f;
ret.value = BoolToUInt32(static_cast<s32>(rsVal) < static_cast<s32>(rtVal));
g_state.pgxp_gpr[rd(instr)] = ret;
}
void CPU::PGXP::CPU_SLTU(u32 instr, u32 rsVal, u32 rtVal)
{
// Rd = Rs < Rt (unsigned)
PGXP_value ret;
Validate(&g_state.pgxp_gpr[rs(instr)], rsVal);
Validate(&g_state.pgxp_gpr[rt(instr)], rtVal);
// iCB: Only require one valid input
if (((g_state.pgxp_gpr[rt(instr)].flags & VALID_01) != VALID_01) !=
((g_state.pgxp_gpr[rs(instr)].flags & VALID_01) != VALID_01))
{
MakeValid(&g_state.pgxp_gpr[rs(instr)], rsVal);
MakeValid(&g_state.pgxp_gpr[rt(instr)], rtVal);
}
ret = g_state.pgxp_gpr[rs(instr)];
ret.y = 0.f;
ret.compFlags[1] = VALID;
ret.x = (f16Unsign(g_state.pgxp_gpr[rs(instr)].y) < f16Unsign(g_state.pgxp_gpr[rt(instr)].y)) ? 1.f :
(f16Unsign(g_state.pgxp_gpr[rs(instr)].x) < f16Unsign(g_state.pgxp_gpr[rt(instr)].x)) ? 1.f :
0.f;
ret.value = BoolToUInt32(rsVal < rtVal);
g_state.pgxp_gpr[rd(instr)] = ret;
}
////////////////////////////////////
// Register mult/div
////////////////////////////////////
void CPU::PGXP::CPU_MULT(u32 instr, u32 rsVal, u32 rtVal)
{
// Hi/Lo = Rs * Rt (signed)
Validate(&g_state.pgxp_gpr[rs(instr)], rsVal);
Validate(&g_state.pgxp_gpr[rt(instr)], rtVal);
// iCB: Only require one valid input
if (((g_state.pgxp_gpr[rt(instr)].flags & VALID_01) != VALID_01) !=
((g_state.pgxp_gpr[rs(instr)].flags & VALID_01) != VALID_01))
{
MakeValid(&g_state.pgxp_gpr[rs(instr)], rsVal);
MakeValid(&g_state.pgxp_gpr[rt(instr)], rtVal);
}
g_state.pgxp_gpr[static_cast<u8>(Reg::lo)] = g_state.pgxp_gpr[static_cast<u8>(Reg::hi)] = g_state.pgxp_gpr[rs(instr)];
g_state.pgxp_gpr[static_cast<u8>(Reg::lo)].halfFlags[0] = g_state.pgxp_gpr[static_cast<u8>(Reg::hi)].halfFlags[0] =
(g_state.pgxp_gpr[rs(instr)].halfFlags[0] & g_state.pgxp_gpr[rt(instr)].halfFlags[0]);
double xx, xy, yx, yy;
double lx = 0, ly = 0, hx = 0, hy = 0;
// Multiply out components
xx = f16Unsign(g_state.pgxp_gpr[rs(instr)].x) * f16Unsign(g_state.pgxp_gpr[rt(instr)].x);
xy = f16Unsign(g_state.pgxp_gpr[rs(instr)].x) * (g_state.pgxp_gpr[rt(instr)].y);
yx = (g_state.pgxp_gpr[rs(instr)].y) * f16Unsign(g_state.pgxp_gpr[rt(instr)].x);
yy = (g_state.pgxp_gpr[rs(instr)].y) * (g_state.pgxp_gpr[rt(instr)].y);
// Split values into outputs
lx = xx;
ly = f16Overflow(xx);
ly += xy + yx;
hx = f16Overflow(ly);
hx += yy;
hy = f16Overflow(hx);
g_state.pgxp_gpr[static_cast<u8>(Reg::lo)].x = (float)f16Sign(lx);
g_state.pgxp_gpr[static_cast<u8>(Reg::lo)].y = (float)f16Sign(ly);
g_state.pgxp_gpr[static_cast<u8>(Reg::hi)].x = (float)f16Sign(hx);
g_state.pgxp_gpr[static_cast<u8>(Reg::hi)].y = (float)f16Sign(hy);
// compute PSX value
const u64 result = static_cast<u64>(static_cast<s64>(SignExtend64(rsVal)) * static_cast<s64>(SignExtend64(rtVal)));
g_state.pgxp_gpr[static_cast<u8>(Reg::hi)].value = Truncate32(result >> 32);
g_state.pgxp_gpr[static_cast<u8>(Reg::lo)].value = Truncate32(result);
}
void CPU::PGXP::CPU_MULTU(u32 instr, u32 rsVal, u32 rtVal)
{
// Hi/Lo = Rs * Rt (unsigned)
Validate(&g_state.pgxp_gpr[rs(instr)], rsVal);
Validate(&g_state.pgxp_gpr[rt(instr)], rtVal);
// iCB: Only require one valid input
if (((g_state.pgxp_gpr[rt(instr)].flags & VALID_01) != VALID_01) !=
((g_state.pgxp_gpr[rs(instr)].flags & VALID_01) != VALID_01))
{
MakeValid(&g_state.pgxp_gpr[rs(instr)], rsVal);
MakeValid(&g_state.pgxp_gpr[rt(instr)], rtVal);
}
g_state.pgxp_gpr[static_cast<u8>(Reg::lo)] = g_state.pgxp_gpr[static_cast<u8>(Reg::hi)] = g_state.pgxp_gpr[rs(instr)];
g_state.pgxp_gpr[static_cast<u8>(Reg::lo)].halfFlags[0] = g_state.pgxp_gpr[static_cast<u8>(Reg::hi)].halfFlags[0] =
(g_state.pgxp_gpr[rs(instr)].halfFlags[0] & g_state.pgxp_gpr[rt(instr)].halfFlags[0]);
double xx, xy, yx, yy;
double lx = 0, ly = 0, hx = 0, hy = 0;
// Multiply out components
xx = f16Unsign(g_state.pgxp_gpr[rs(instr)].x) * f16Unsign(g_state.pgxp_gpr[rt(instr)].x);
xy = f16Unsign(g_state.pgxp_gpr[rs(instr)].x) * f16Unsign(g_state.pgxp_gpr[rt(instr)].y);
yx = f16Unsign(g_state.pgxp_gpr[rs(instr)].y) * f16Unsign(g_state.pgxp_gpr[rt(instr)].x);
yy = f16Unsign(g_state.pgxp_gpr[rs(instr)].y) * f16Unsign(g_state.pgxp_gpr[rt(instr)].y);
// Split values into outputs
lx = xx;
ly = f16Overflow(xx);
ly += xy + yx;
hx = f16Overflow(ly);
hx += yy;
hy = f16Overflow(hx);
g_state.pgxp_gpr[static_cast<u8>(Reg::lo)].x = (float)f16Sign(lx);
g_state.pgxp_gpr[static_cast<u8>(Reg::lo)].y = (float)f16Sign(ly);
g_state.pgxp_gpr[static_cast<u8>(Reg::hi)].x = (float)f16Sign(hx);
g_state.pgxp_gpr[static_cast<u8>(Reg::hi)].y = (float)f16Sign(hy);
// compute PSX value
const u64 result = ZeroExtend64(rsVal) * ZeroExtend64(rtVal);
g_state.pgxp_gpr[static_cast<u8>(Reg::hi)].value = Truncate32(result >> 32);
g_state.pgxp_gpr[static_cast<u8>(Reg::lo)].value = Truncate32(result);
}
void CPU::PGXP::CPU_DIV(u32 instr, u32 rsVal, u32 rtVal)
{
// Lo = Rs / Rt (signed)
// Hi = Rs % Rt (signed)
Validate(&g_state.pgxp_gpr[rs(instr)], rsVal);
Validate(&g_state.pgxp_gpr[rt(instr)], rtVal);
//// iCB: Only require one valid input
if (((g_state.pgxp_gpr[rt(instr)].flags & VALID_01) != VALID_01) !=
((g_state.pgxp_gpr[rs(instr)].flags & VALID_01) != VALID_01))
{
MakeValid(&g_state.pgxp_gpr[rs(instr)], rsVal);
MakeValid(&g_state.pgxp_gpr[rt(instr)], rtVal);
}
g_state.pgxp_gpr[static_cast<u8>(Reg::lo)] = g_state.pgxp_gpr[static_cast<u8>(Reg::hi)] = g_state.pgxp_gpr[rs(instr)];
g_state.pgxp_gpr[static_cast<u8>(Reg::lo)].halfFlags[0] = g_state.pgxp_gpr[static_cast<u8>(Reg::hi)].halfFlags[0] =
(g_state.pgxp_gpr[rs(instr)].halfFlags[0] & g_state.pgxp_gpr[rt(instr)].halfFlags[0]);
double vs = f16Unsign(g_state.pgxp_gpr[rs(instr)].x) + (g_state.pgxp_gpr[rs(instr)].y) * (double)(1 << 16);
double vt = f16Unsign(g_state.pgxp_gpr[rt(instr)].x) + (g_state.pgxp_gpr[rt(instr)].y) * (double)(1 << 16);
double lo = vs / vt;
g_state.pgxp_gpr[static_cast<u8>(Reg::lo)].y = (float)f16Sign(f16Overflow(lo));
g_state.pgxp_gpr[static_cast<u8>(Reg::lo)].x = (float)f16Sign(lo);
double hi = fmod(vs, vt);
g_state.pgxp_gpr[static_cast<u8>(Reg::hi)].y = (float)f16Sign(f16Overflow(hi));
g_state.pgxp_gpr[static_cast<u8>(Reg::hi)].x = (float)f16Sign(hi);
// compute PSX value
if (static_cast<s32>(rtVal) == 0)
{
// divide by zero
g_state.pgxp_gpr[static_cast<u8>(Reg::lo)].value =
(static_cast<s32>(rsVal) >= 0) ? UINT32_C(0xFFFFFFFF) : UINT32_C(1);
g_state.pgxp_gpr[static_cast<u8>(Reg::hi)].value = static_cast<u32>(static_cast<s32>(rsVal));
}
else if (rsVal == UINT32_C(0x80000000) && static_cast<s32>(rtVal) == -1)
{
// unrepresentable
g_state.pgxp_gpr[static_cast<u8>(Reg::lo)].value = UINT32_C(0x80000000);
g_state.pgxp_gpr[static_cast<u8>(Reg::hi)].value = 0;
}
else
{
g_state.pgxp_gpr[static_cast<u8>(Reg::lo)].value =
static_cast<u32>(static_cast<s32>(rsVal) / static_cast<s32>(rtVal));
g_state.pgxp_gpr[static_cast<u8>(Reg::hi)].value =
static_cast<u32>(static_cast<s32>(rsVal) % static_cast<s32>(rtVal));
}
}
void CPU::PGXP::CPU_DIVU(u32 instr, u32 rsVal, u32 rtVal)
{
// Lo = Rs / Rt (unsigned)
// Hi = Rs % Rt (unsigned)
Validate(&g_state.pgxp_gpr[rs(instr)], rsVal);
Validate(&g_state.pgxp_gpr[rt(instr)], rtVal);
//// iCB: Only require one valid input
if (((g_state.pgxp_gpr[rt(instr)].flags & VALID_01) != VALID_01) !=
((g_state.pgxp_gpr[rs(instr)].flags & VALID_01) != VALID_01))
{
MakeValid(&g_state.pgxp_gpr[rs(instr)], rsVal);
MakeValid(&g_state.pgxp_gpr[rt(instr)], rtVal);
}
g_state.pgxp_gpr[static_cast<u8>(Reg::lo)] = g_state.pgxp_gpr[static_cast<u8>(Reg::hi)] = g_state.pgxp_gpr[rs(instr)];
g_state.pgxp_gpr[static_cast<u8>(Reg::lo)].halfFlags[0] = g_state.pgxp_gpr[static_cast<u8>(Reg::hi)].halfFlags[0] =
(g_state.pgxp_gpr[rs(instr)].halfFlags[0] & g_state.pgxp_gpr[rt(instr)].halfFlags[0]);
double vs = f16Unsign(g_state.pgxp_gpr[rs(instr)].x) + f16Unsign(g_state.pgxp_gpr[rs(instr)].y) * (double)(1 << 16);
double vt = f16Unsign(g_state.pgxp_gpr[rt(instr)].x) + f16Unsign(g_state.pgxp_gpr[rt(instr)].y) * (double)(1 << 16);
double lo = vs / vt;
g_state.pgxp_gpr[static_cast<u8>(Reg::lo)].y = (float)f16Sign(f16Overflow(lo));
g_state.pgxp_gpr[static_cast<u8>(Reg::lo)].x = (float)f16Sign(lo);
double hi = fmod(vs, vt);
g_state.pgxp_gpr[static_cast<u8>(Reg::hi)].y = (float)f16Sign(f16Overflow(hi));
g_state.pgxp_gpr[static_cast<u8>(Reg::hi)].x = (float)f16Sign(hi);
if (rtVal == 0)
{
// divide by zero
g_state.pgxp_gpr[static_cast<u8>(Reg::lo)].value = UINT32_C(0xFFFFFFFF);
g_state.pgxp_gpr[static_cast<u8>(Reg::hi)].value = rsVal;
}
else
{
g_state.pgxp_gpr[static_cast<u8>(Reg::lo)].value = rsVal / rtVal;
g_state.pgxp_gpr[static_cast<u8>(Reg::hi)].value = rsVal % rtVal;
}
}
////////////////////////////////////
// Shift operations (sa)
////////////////////////////////////
void CPU::PGXP::CPU_SLL(u32 instr, u32 rtVal)
{
// Rd = Rt << Sa
const u32 rdVal = rtVal << sa(instr);
PGXP_value ret;
u32 sh = sa(instr);
Validate(&g_state.pgxp_gpr[rt(instr)], rtVal);
ret = g_state.pgxp_gpr[rt(instr)];
// TODO: Shift flags
double x = f16Unsign(g_state.pgxp_gpr[rt(instr)].x);
double y = f16Unsign(g_state.pgxp_gpr[rt(instr)].y);
if (sh >= 32)
{
x = 0.f;
y = 0.f;
}
else if (sh == 16)
{
y = f16Sign(x);
x = 0.f;
}
else if (sh >= 16)
{
y = x * (1 << (sh - 16));
y = f16Sign(y);
x = 0.f;
}
else
{
x = x * (1 << sh);
y = y * (1 << sh);
y += f16Overflow(x);
x = f16Sign(x);
y = f16Sign(y);
}
ret.x = (float)x;
ret.y = (float)y;
ret.value = rdVal;
g_state.pgxp_gpr[rd(instr)] = ret;
}
void CPU::PGXP::CPU_SRL(u32 instr, u32 rtVal)
{
// Rd = Rt >> Sa
const u32 rdVal = rtVal >> sa(instr);
PGXP_value ret;
u32 sh = sa(instr);
Validate(&g_state.pgxp_gpr[rt(instr)], rtVal);
ret = g_state.pgxp_gpr[rt(instr)];
double x = g_state.pgxp_gpr[rt(instr)].x, y = f16Unsign(g_state.pgxp_gpr[rt(instr)].y);
psx_value iX;
iX.d = rtVal;
psx_value iY;
iY.d = rtVal;
iX.sd = (iX.sd << 16) >> 16; // remove Y
iY.sw.l = iX.sw.h; // overwrite x with sign(x)
// Shift test values
psx_value dX;
dX.sd = iX.sd >> sh;
psx_value dY;
dY.d = iY.d >> sh;
if (dX.sw.l != iX.sw.h)
x = x / (1 << sh);
else
x = dX.sw.l; // only sign bits left
if (dY.sw.l != iX.sw.h)
{
if (sh == 16)
{
x = y;
}
else if (sh < 16)
{
x += y * (1 << (16 - sh));
if (g_state.pgxp_gpr[rt(instr)].x < 0)
x += 1 << (16 - sh);
}
else
{
x += y / (1 << (sh - 16));
}
}
if ((dY.sw.h == 0) || (dY.sw.h == -1))
y = dY.sw.h;
else
y = y / (1 << sh);
x = f16Sign(x);
y = f16Sign(y);
ret.x = (float)x;
ret.y = (float)y;
ret.value = rdVal;
g_state.pgxp_gpr[rd(instr)] = ret;
}
void CPU::PGXP::CPU_SRA(u32 instr, u32 rtVal)
{
// Rd = Rt >> Sa
const u32 rdVal = static_cast<u32>(static_cast<s32>(rtVal) >> sa(instr));
PGXP_value ret;
u32 sh = sa(instr);
Validate(&g_state.pgxp_gpr[rt(instr)], rtVal);
ret = g_state.pgxp_gpr[rt(instr)];
double x = g_state.pgxp_gpr[rt(instr)].x, y = g_state.pgxp_gpr[rt(instr)].y;
psx_value iX;
iX.d = rtVal;
psx_value iY;
iY.d = rtVal;
iX.sd = (iX.sd << 16) >> 16; // remove Y
iY.sw.l = iX.sw.h; // overwrite x with sign(x)
// Shift test values
psx_value dX;
dX.sd = iX.sd >> sh;
psx_value dY;
dY.sd = iY.sd >> sh;
if (dX.sw.l != iX.sw.h)
x = x / (1 << sh);
else
x = dX.sw.l; // only sign bits left
if (dY.sw.l != iX.sw.h)
{
if (sh == 16)
{
x = y;
}
else if (sh < 16)
{
x += y * (1 << (16 - sh));
if (g_state.pgxp_gpr[rt(instr)].x < 0)
x += 1 << (16 - sh);
}
else
{
x += y / (1 << (sh - 16));
}
}
if ((dY.sw.h == 0) || (dY.sw.h == -1))
y = dY.sw.h;
else
y = y / (1 << sh);
x = f16Sign(x);
y = f16Sign(y);
ret.x = (float)x;
ret.y = (float)y;
// Use low precision/rounded values when we're not shifting an entire component,
// and it's not originally from a 3D value. Too many false positives in P2/etc.
// What we probably should do is not set the valid flag on non-3D values to begin
// with, only letting them become valid when used in another expression.
if (!(ret.flags & VALID_2) && sh < 16)
{
ret.flags = 0;
MakeValid(&ret, rdVal);
}
ret.value = rdVal;
g_state.pgxp_gpr[rd(instr)] = ret;
}
////////////////////////////////////
// Shift operations variable
////////////////////////////////////
void CPU::PGXP::CPU_SLLV(u32 instr, u32 rtVal, u32 rsVal)
{
// Rd = Rt << Rs
const u32 rdVal = rtVal << rsVal;
PGXP_value ret;
u32 sh = rsVal & 0x1F;
Validate(&g_state.pgxp_gpr[rt(instr)], rtVal);
Validate(&g_state.pgxp_gpr[rs(instr)], rsVal);
ret = g_state.pgxp_gpr[rt(instr)];
double x = f16Unsign(g_state.pgxp_gpr[rt(instr)].x);
double y = f16Unsign(g_state.pgxp_gpr[rt(instr)].y);
if (sh >= 32)
{
x = 0.f;
y = 0.f;
}
else if (sh == 16)
{
y = f16Sign(x);
x = 0.f;
}
else if (sh >= 16)
{
y = x * (1 << (sh - 16));
y = f16Sign(y);
x = 0.f;
}
else
{
x = x * (1 << sh);
y = y * (1 << sh);
y += f16Overflow(x);
x = f16Sign(x);
y = f16Sign(y);
}
ret.x = (float)x;
ret.y = (float)y;
ret.value = rdVal;
g_state.pgxp_gpr[rd(instr)] = ret;
}
void CPU::PGXP::CPU_SRLV(u32 instr, u32 rtVal, u32 rsVal)
{
// Rd = Rt >> Sa
const u32 rdVal = rtVal >> rsVal;
PGXP_value ret;
u32 sh = rsVal & 0x1F;
Validate(&g_state.pgxp_gpr[rt(instr)], rtVal);
Validate(&g_state.pgxp_gpr[rs(instr)], rsVal);
ret = g_state.pgxp_gpr[rt(instr)];
double x = g_state.pgxp_gpr[rt(instr)].x, y = f16Unsign(g_state.pgxp_gpr[rt(instr)].y);
psx_value iX;
iX.d = rtVal;
psx_value iY;
iY.d = rtVal;
iX.sd = (iX.sd << 16) >> 16; // remove Y
iY.sw.l = iX.sw.h; // overwrite x with sign(x)
// Shift test values
psx_value dX;
dX.sd = iX.sd >> sh;
psx_value dY;
dY.d = iY.d >> sh;
if (dX.sw.l != iX.sw.h)
x = x / (1 << sh);
else
x = dX.sw.l; // only sign bits left
if (dY.sw.l != iX.sw.h)
{
if (sh == 16)
{
x = y;
}
else if (sh < 16)
{
x += y * (1 << (16 - sh));
if (g_state.pgxp_gpr[rt(instr)].x < 0)
x += 1 << (16 - sh);
}
else
{
x += y / (1 << (sh - 16));
}
}
if ((dY.sw.h == 0) || (dY.sw.h == -1))
y = dY.sw.h;
else
y = y / (1 << sh);
x = f16Sign(x);
y = f16Sign(y);
ret.x = (float)x;
ret.y = (float)y;
ret.value = rdVal;
g_state.pgxp_gpr[rd(instr)] = ret;
}
void CPU::PGXP::CPU_SRAV(u32 instr, u32 rtVal, u32 rsVal)
{
// Rd = Rt >> Sa
const u32 rdVal = static_cast<u32>(static_cast<s32>(rtVal) >> rsVal);
PGXP_value ret;
u32 sh = rsVal & 0x1F;
Validate(&g_state.pgxp_gpr[rt(instr)], rtVal);
Validate(&g_state.pgxp_gpr[rs(instr)], rsVal);
ret = g_state.pgxp_gpr[rt(instr)];
double x = g_state.pgxp_gpr[rt(instr)].x, y = g_state.pgxp_gpr[rt(instr)].y;
psx_value iX;
iX.d = rtVal;
psx_value iY;
iY.d = rtVal;
iX.sd = (iX.sd << 16) >> 16; // remove Y
iY.sw.l = iX.sw.h; // overwrite x with sign(x)
// Shift test values
psx_value dX;
dX.sd = iX.sd >> sh;
psx_value dY;
dY.sd = iY.sd >> sh;
if (dX.sw.l != iX.sw.h)
x = x / (1 << sh);
else
x = dX.sw.l; // only sign bits left
if (dY.sw.l != iX.sw.h)
{
if (sh == 16)
{
x = y;
}
else if (sh < 16)
{
x += y * (1 << (16 - sh));
if (g_state.pgxp_gpr[rt(instr)].x < 0)
x += 1 << (16 - sh);
}
else
{
x += y / (1 << (sh - 16));
}
}
if ((dY.sw.h == 0) || (dY.sw.h == -1))
y = dY.sw.h;
else
y = y / (1 << sh);
x = f16Sign(x);
y = f16Sign(y);
ret.x = (float)x;
ret.y = (float)y;
ret.value = rdVal;
g_state.pgxp_gpr[rd(instr)] = ret;
}
void CPU::PGXP::CPU_MFC0(u32 instr, u32 rdVal)
{
// CPU[Rt] = CP0[Rd]
Validate(&g_state.pgxp_cop0[rd(instr)], rdVal);
g_state.pgxp_gpr[rt(instr)] = g_state.pgxp_cop0[rd(instr)];
g_state.pgxp_gpr[rt(instr)].value = rdVal;
}
void CPU::PGXP::CPU_MTC0(u32 instr, u32 rdVal, u32 rtVal)
{
// CP0[Rd] = CPU[Rt]
Validate(&g_state.pgxp_gpr[rt(instr)], rtVal);
g_state.pgxp_cop0[rd(instr)] = g_state.pgxp_gpr[rt(instr)];
g_state.pgxp_cop0[rd(instr)].value = rdVal;
}
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