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mirror of https://github.com/RPCS3/rpcs3.git synced 2024-11-25 12:12:50 +01:00

glsl: Improve VGPR usage

- VGPR usage lowered from 159 -> 127 for texturing. Occupancy doubled from 1 to 2
- Eliminate most temporary registers
This commit is contained in:
kd-11 2020-05-02 00:25:42 +03:00 committed by kd-11
parent 9a4c26dc8c
commit 4f7c020e63
3 changed files with 210 additions and 169 deletions

View File

@ -89,7 +89,24 @@ layout(location=0) in vec4 in_regs[16];
#define GET_BITS(word, offset, count) bitfieldExtract(inst.words[word], offset, count)
#define TEST_BIT(word, offset) (GET_BITS(word, offset, 1) > 0)
#define reg_mov(d, s, m) d = mix(d, s, m)
#define select mix
#define reg_mov(d, s, m) d = select(d, s, m)
// GPR set
vec4 vr0, vr1; // GP vector register
uint ur0, ur1; // GP unsigned register (scalar)
uvec4 uvr0; // GP unsigned register (vector)
bvec4 bvr0, bvr1; // GP boolean register (vector)
float sr0; // GP scalar register
vec4 vrr; // value return (dst register)
vec4 s0, s1, s2; // instruction src (src0, src1, src2)
vec4 wpos; // window position register WPOS
vec4 fogc; // Fog coordinate register FOGC
const vec4 vr_zero = vec4(0.);
const vec4 vr_one = vec4(1.);
bool shader_attribute(const in uint mask)
{
@ -142,7 +159,7 @@ const float modifier_scale[] = {1.f, 2.f, 4.f, 8.f, 1.f, 0.5f, 0.25f, 0.125f};
vec4 regs16[48];
vec4 regs32[48];
vec4 cc[2] = { vec4(0.), vec4(0.) };
vec4 cc[2];
int inst_length = 1;
int ip = -1;
instruction_t inst;
@ -155,48 +172,54 @@ int loop_end_addr = -1;
int counter = 0;
#endif
vec4 wpos = gl_FragCoord * vec4(abs(wpos_scale), wpos_scale, 1., 1.) + vec4(0., wpos_bias, 0., 0.);
vec4 fogc = fetch_fog_value(fog_mode, in_regs[5]);
vec4 read_src(const in int index)
{
const uint type = GET_BITS(index + 1, 0, 2);
vec4 value;
ur0 = GET_BITS(index + 1, 0, 2);
switch (type)
switch (ur0)
{
case RSX_FP_REGISTER_TYPE_TEMP:
{
const uint i = GET_BITS(index + 1, 2, 6);
switch(index)
{
case 0:
ur1 = GET_BITS(1, 2, 6); break;
case 1:
ur1 = GET_BITS(2, 2, 6); break;
case 2:
ur1 = GET_BITS(3, 2, 6); break;
}
if (TEST_BIT(index + 1, 8))
{
value = regs16[i];
vr0 = regs16[ur1];
}
else
{
value = regs32[i];
vr0 = regs32[ur1];
}
break;
}
case RSX_FP_REGISTER_TYPE_INPUT:
{
const uint i = GET_BITS(0, 13, 4);
switch (i)
ur1 = GET_BITS(0, 13, 4);
switch (ur1)
{
case 0:
value = wpos; break;
vr0 = wpos; break;
case 1:
value = gl_FrontFacing? in_regs[3] : in_regs[1]; break;
vr0 = gl_FrontFacing? in_regs[3] : in_regs[1]; break;
case 2:
value = gl_FrontFacing? in_regs[4] : in_regs[2]; break;
vr0 = gl_FrontFacing? in_regs[4] : in_regs[2]; break;
case 3:
value = fogc; break;
vr0 = fogc; break;
case 13:
value = in_regs[6]; break;
vr0 = in_regs[6]; break;
case 14:
value = gl_FrontFacing? vec4(1.) : vec4(-1.); break;
vr0 = gl_FrontFacing? vr_one : -vr_one; break;
default:
value = in_regs[i + 3]; break;
ur1 += 3;
vr0 = in_regs[ur1]; break;
}
break;
@ -204,28 +227,30 @@ vec4 read_src(const in int index)
case RSX_FP_REGISTER_TYPE_CONSTANT:
{
inst_length = 2;
uvec4 result =
uvr0 =
((fp_instructions[ip + 1] << 8) & uvec4(0xFF00FF00)) |
((fp_instructions[ip + 1] >> 8) & uvec4(0x00FF00FF));
value = uintBitsToFloat(result);
vr0 = uintBitsToFloat(uvr0);
break;
}
}
value = shuffle(value, GET_BITS(index + 1, 9, 8));
ur1 = GET_BITS(index + 1, 9, 8);
vr0 = shuffle(vr0, ur1);
// abs
if (index == 0)
{
value = (TEST_BIT(1, 29))? abs(value) : value;
if (TEST_BIT(1, 29)) vr0 = abs(vr0);
}
else
{
value = (TEST_BIT(index + 1, 18))? abs(value) : value;
ur1 = index + 1;
if (TEST_BIT(ur1, 18)) vr0 = abs(vr0);
}
// neg
return (TEST_BIT(index + 1, 17))? -value : value;
return (TEST_BIT(index + 1, 17))? -vr0 : vr0;
}
vec4 read_cond()
@ -233,36 +258,40 @@ vec4 read_cond()
return shuffle(cc[GET_BITS(1, 31, 1)], GET_BITS(1, 21, 8));
}
bvec4 decode_cond(const in uint mode, const in vec4 cond)
{
switch (mode)
{
case EXEC_GT | EXEC_EQ:
return greaterThanEqual(cond, vr_zero);
case EXEC_LT | EXEC_EQ:
return lessThanEqual(cond, vr_zero);
case EXEC_LT | EXEC_GT:
return notEqual(cond, vr_zero);
case EXEC_GT:
return greaterThan(cond, vr_zero);
case EXEC_LT:
return lessThan(cond, vr_zero);
case EXEC_EQ:
return equal(cond, vr_zero);
default:
return bvec4(vr_zero);
}
}
#if defined(WITH_FLOW_CTRL) || defined(WITH_KIL)
bool check_cond()
{
const uint exec_mask = GET_BITS(1, 18, 3);
if (exec_mask == 0x7)
ur0 = GET_BITS(1, 18, 3);
if (ur0 == 0x7)
{
return true;
}
else
{
const vec4 cond = read_cond();
switch (exec_mask)
{
case EXEC_GT | EXEC_EQ:
return any(greaterThanEqual(cond, vec4(0.)));
case EXEC_LT | EXEC_EQ:
return any(lessThanEqual(cond, vec4(0.)));
case EXEC_LT | EXEC_GT:
return any(notEqual(cond, vec4(0.)));
case EXEC_GT:
return any(greaterThan(cond, vec4(0.)));
case EXEC_LT:
return any(lessThan(cond, vec4(0.)));
case EXEC_EQ:
return any(equal(cond, vec4(0.)));
default:
return false;
}
}
vr0 = read_cond();
bvr0 = decode_cond(ur0, vr0);
return any(bvr0);
}
#endif
@ -271,82 +300,79 @@ bool check_cond()
vec4 _texture(in vec4 coord, float bias)
{
const uint tex_num = GET_BITS(0, 17, 4);
if (!IS_TEXTURE_RESIDENT(tex_num))
ur0 = GET_BITS(0, 17, 4);
if (!IS_TEXTURE_RESIDENT(ur0))
{
return vec4(0., 0., 0., 1.);
return vr_zero;
}
const uint type = bitfieldExtract(texture_control, int(tex_num + tex_num), 2);
coord.xy *= texture_parameters[tex_num].scale;
ur1 = ur0 + ur0;
const uint type = bitfieldExtract(texture_control, int(ur1), 2);
coord.xy *= texture_parameters[ur0].scale;
vec4 value;
switch (type)
{
case 0:
value = texture(SAMPLER1D(tex_num), coord.x, bias); break;
vr0 = texture(SAMPLER1D(ur0), coord.x, bias); break;
case 1:
value = texture(SAMPLER2D(tex_num), coord.xy, bias); break;
vr0 = texture(SAMPLER2D(ur0), coord.xy, bias); break;
case 2:
value = texture(SAMPLERCUBE(tex_num), coord.xyz, bias); break;
vr0 = texture(SAMPLERCUBE(ur0), coord.xyz, bias); break;
case 3:
value = texture(SAMPLER3D(tex_num), coord.xyz, bias); break;
vr0 = texture(SAMPLER3D(ur0), coord.xyz, bias); break;
}
if (TEST_BIT(0, 21))
{
value = fma(value, vec4(2.), vec4(-1.));
vr0 = vr0 * 2. - 1.;
}
return value;
return vr0;
}
vec4 _textureLod(in vec4 coord, float lod)
{
const uint tex_num = GET_BITS(0, 17, 4);
if (!IS_TEXTURE_RESIDENT(tex_num))
ur0 = GET_BITS(0, 17, 4);
if (!IS_TEXTURE_RESIDENT(ur0))
{
return vec4(0., 0., 0., 1.);
return vr_zero;
}
const uint type = bitfieldExtract(texture_control, int(tex_num + tex_num), 2);
coord.xy *= texture_parameters[tex_num].scale;
ur1 = ur0 + ur0;
const uint type = bitfieldExtract(texture_control, int(ur1), 2);
coord.xy *= texture_parameters[ur0].scale;
vec4 value;
switch (type)
{
case 0:
value = textureLod(SAMPLER1D(tex_num), coord.x, lod); break;
vr0 = textureLod(SAMPLER1D(ur0), coord.x, lod); break;
case 1:
value = textureLod(SAMPLER2D(tex_num), coord.xy, lod); break;
vr0 = textureLod(SAMPLER2D(ur0), coord.xy, lod); break;
case 2:
value = textureLod(SAMPLERCUBE(tex_num), coord.xyz, lod); break;
vr0 = textureLod(SAMPLERCUBE(ur0), coord.xyz, lod); break;
case 3:
value = textureLod(SAMPLER3D(tex_num), coord.xyz, lod); break;
vr0 = textureLod(SAMPLER3D(ur0), coord.xyz, lod); break;
}
if (TEST_BIT(0, 21))
{
value = fma(value, vec4(2.), vec4(-1.));
vr0 = vr0 * 2. - 1.;
}
return value;
return vr0;
}
#endif
void write_dst(in vec4 value)
void write_dst(const in vec4 value)
{
bvec4 inst_mask = bvec4(
TEST_BIT(0, 9),
TEST_BIT(0, 10),
TEST_BIT(0, 11),
TEST_BIT(0, 12));
uvr0 = uvec4(uint(1 << 9), uint(1 << 10), uint(1 << 11), uint(1 << 12));
bvr0 = bvec4(uvr0 & inst.words.xxxx);
if (TEST_BIT(0, 8)) // SET COND
{
uint index = GET_BITS(1, 30, 1);
reg_mov(cc[index], value, inst_mask);
ur0 = GET_BITS(1, 30, 1);
reg_mov(cc[ur0], value, bvr0);
}
if (TEST_BIT(0, 30)) // NO DEST
@ -354,49 +380,31 @@ void write_dst(in vec4 value)
return;
}
ur1 = GET_BITS(2, 28, 3);
sr0 = modifier_scale[ur1];
vr0 = value * sr0;
if (TEST_BIT(0, 31)) // SAT
{
value = clamp(value, 0, 1);
vr0 = clamp(vr0, 0, 1);
}
const uint exec_mask = GET_BITS(1, 18, 3);
if (exec_mask != 0x7)
ur0 = GET_BITS(1, 18, 3);
if (ur0 != 0x7)
{
bvec4 write_mask;
const vec4 cond = read_cond();
switch (exec_mask)
{
case 0:
return;
case EXEC_GT | EXEC_EQ:
write_mask = greaterThanEqual(cond, vec4(0.)); break;
case EXEC_LT | EXEC_EQ:
write_mask = lessThanEqual(cond, vec4(0.)); break;
case EXEC_LT | EXEC_GT:
write_mask = notEqual(cond, vec4(0.)); break;
case EXEC_GT:
write_mask = greaterThan(cond, vec4(0.)); break;
case EXEC_LT:
write_mask = lessThan(cond, vec4(0.)); break;
case EXEC_EQ:
write_mask = equal(cond, vec4(0.)); break;
}
inst_mask = bvec4(uvec4(inst_mask) & uvec4(write_mask));
vr1 = read_cond();
bvr1 = decode_cond(ur0, vr1);
bvr0 = bvec4(uvec4(bvr0) & uvec4(bvr1));
}
const uint scale = GET_BITS(2, 28, 3);
value *= modifier_scale[scale];
const uint index = GET_BITS(0, 1, 6);
ur1 = GET_BITS(0, 1, 6);
if (TEST_BIT(0, 7))
{
reg_mov(regs16[index], value, inst_mask);
reg_mov(regs16[ur1], vr0, bvr0);
}
else
{
reg_mov(regs32[index], value, inst_mask);
reg_mov(regs32[ur1], vr0, bvr0);
}
}
@ -407,14 +415,52 @@ void initialize()
// NOTE: Attempting to zero-initialize all the registers will slow things to a crawl!
uint register_count = bitfieldExtract(shader_control, 24, 6);
uint i = 0, j = 0;
ur0 = 0, ur1 = 0;
while (register_count > 0)
{
regs32[i++] = vec4(0.);
regs16[j++] = vec4(0.);
regs16[j++] = vec4(0.);
regs32[ur0++] = vr_zero;
regs16[ur1++] = vr_zero;
regs16[ur1++] = vr_zero;
register_count--;
}
// Fog coord
fogc = in_regs[5];
switch(fog_mode)
{
case 0:
//linear
fogc.y = fog_param1 * fogc.x + (fog_param0 - 1.);
break;
case 1:
//exponential
fogc.y = exp(11.084 * (fog_param1 * fogc.x + fog_param0 - 1.5));
break;
case 2:
//exponential2
fogc.y = exp(-pow(4.709 * (fog_param1 * fogc.x + fog_param0 - 1.5), 2.));
break;
case 3:
//exponential_abs
fogc.y = exp(11.084 * (fog_param1 * abs(fogc.x) + fog_param0 - 1.5));
break;
case 4:
//exponential2_abs
fogc.y = exp(-pow(4.709 * (fog_param1 * abs(fogc.x) + fog_param0 - 1.5), 2.));
break;
case 5:
//linear_abs
fogc.y = fog_param1 * abs(fogc.x) + (fog_param0 - 1.);
break;
default:
fogc = in_regs[5];
}
fogc.y = clamp(fogc.y, 0., 1.);
// WPOS
vr0 = vec4(abs(wpos_scale), wpos_scale, 1., 1.);
vr1 = vec4(0., wpos_bias, 0., 0.);
wpos = gl_FragCoord * vr0 + vr1;
})"
R"(
@ -423,7 +469,6 @@ void main()
{
initialize();
vec4 value, s0, s1, s2;
inst.end = false;
bool handled;
@ -545,62 +590,62 @@ void main()
switch (inst.opcode)
{
case RSX_FP_OPCODE_MOV:
value = s0; break;
vrr = s0; break;
case RSX_FP_OPCODE_FRC:
value = fract(s0); break;
vrr = fract(s0); break;
case RSX_FP_OPCODE_FLR:
value = floor(s0); break;
vrr = floor(s0); break;
case RSX_FP_OPCODE_DDX:
value = dFdx(s0); break;
vrr = dFdx(s0); break;
case RSX_FP_OPCODE_DDY:
value = dFdy(s0); break;
vrr = dFdy(s0); break;
case RSX_FP_OPCODE_RCP:
value = (1.f / s0.xxxx); break;
vrr = (1.f / s0.xxxx); break;
case RSX_FP_OPCODE_RSQ:
value = inversesqrt(s0.xxxx); break;
vrr = inversesqrt(s0.xxxx); break;
case RSX_FP_OPCODE_EX2:
value = exp2(s0.xxxx); break;
vrr = exp2(s0.xxxx); break;
case RSX_FP_OPCODE_LG2:
value = log2(s0.xxxx); break;
vrr = log2(s0.xxxx); break;
case RSX_FP_OPCODE_STR:
value = vec4(1.); break;
vrr = vr_one; break;
case RSX_FP_OPCODE_SFL:
value = vec4(0.); break;
vrr = vr_zero; break;
case RSX_FP_OPCODE_COS:
value = cos(s0.xxxx); break;
vrr = cos(s0.xxxx); break;
case RSX_FP_OPCODE_SIN:
value = sin(s0.xxxx); break;
vrr = sin(s0.xxxx); break;
case RSX_FP_OPCODE_NRM:
value.xyz = normalize(s0.xyz); break;
vrr.xyz = normalize(s0.xyz); break;
#ifdef WITH_TEXTURES
case RSX_FP_OPCODE_TEX:
value = _texture(s0, 0.f); break;
vrr = _texture(s0, 0.f); break;
case RSX_FP_OPCODE_TXP:
value = _texture(vec4(s0.xyz / s0.w, s0.w), 0.f); break;
vrr = _texture(vec4(s0.xyz / s0.w, s0.w), 0.f); break;
#endif
#ifdef WITH_PACKING
case RSX_FP_OPCODE_PK2:
value = vec4(uintBitsToFloat(packHalf2x16(s0.xy))); break;
vrr = vec4(uintBitsToFloat(packHalf2x16(s0.xy))); break;
case RSX_FP_OPCODE_PK4:
value = vec4(uintBitsToFloat(packSnorm4x8(s0))); break;
vrr = vec4(uintBitsToFloat(packSnorm4x8(s0))); break;
case RSX_FP_OPCODE_PK16:
value = vec4(uintBitsToFloat(packSnorm2x16(s0.xy))); break;
vrr = vec4(uintBitsToFloat(packSnorm2x16(s0.xy))); break;
case RSX_FP_OPCODE_PKG:
// Should be similar to PKB but with gamma correction, see description of PK4UBG in khronos page
case RSX_FP_OPCODE_PKB:
value = vec4(uintBitsToFloat(packUnorm4x8(s0))); break;
vrr = vec4(uintBitsToFloat(packUnorm4x8(s0))); break;
case RSX_FP_OPCODE_UP2:
value = unpackHalf2x16(floatBitsToUint(s0.x)).xyxy; break;
vrr = unpackHalf2x16(floatBitsToUint(s0.x)).xyxy; break;
case RSX_FP_OPCODE_UP4:
value = unpackSnorm4x8(floatBitsToUint(s0.x)); break;
vrr = unpackSnorm4x8(floatBitsToUint(s0.x)); break;
case RSX_FP_OPCODE_UP16:
value = unpackSnorm2x16(floatBitsToUint(s0.x)).xyxy; break;
vrr = unpackSnorm2x16(floatBitsToUint(s0.x)).xyxy; break;
case RSX_FP_OPCODE_UPG:
// Same as UPB with gamma correction
case RSX_FP_OPCODE_UPB:
value = unpackUnorm4x8(floatBitsToUint(s0.x)); break;
vrr = unpackUnorm4x8(floatBitsToUint(s0.x)); break;
#endif
default:
handled = false;
@ -614,48 +659,48 @@ void main()
switch (inst.opcode)
{
case RSX_FP_OPCODE_MUL:
value = s0 * s1; break;
vrr = s0 * s1; break;
case RSX_FP_OPCODE_ADD:
value = s0 + s1; break;
vrr = s0 + s1; break;
case RSX_FP_OPCODE_DP2:
value = dot(s0.xy, s1.xy).xxxx; break;
vrr = dot(s0.xy, s1.xy).xxxx; break;
case RSX_FP_OPCODE_DP3:
value = dot(s0.xyz, s1.xyz).xxxx; break;
vrr = dot(s0.xyz, s1.xyz).xxxx; break;
case RSX_FP_OPCODE_DP4:
value = dot(s0, s1).xxxx; break;
vrr = dot(s0, s1).xxxx; break;
case RSX_FP_OPCODE_DST:
value = _distance(s0, s1); break;
vrr = _distance(s0, s1); break;
case RSX_FP_OPCODE_MIN:
value = min(s0, s1); break;
vrr = min(s0, s1); break;
case RSX_FP_OPCODE_MAX:
value = max(s0, s1); break;
vrr = max(s0, s1); break;
case RSX_FP_OPCODE_SLT:
value = vec4(lessThan(s0, s1)); break;
vrr = vec4(lessThan(s0, s1)); break;
case RSX_FP_OPCODE_SGE:
value = vec4(greaterThanEqual(s0, s1)); break;
vrr = vec4(greaterThanEqual(s0, s1)); break;
case RSX_FP_OPCODE_SLE:
value = vec4(lessThanEqual(s0, s1)); break;
vrr = vec4(lessThanEqual(s0, s1)); break;
case RSX_FP_OPCODE_SGT:
value = vec4(greaterThan(s0, s1)); break;
vrr = vec4(greaterThan(s0, s1)); break;
case RSX_FP_OPCODE_SNE:
value = vec4(notEqual(s0, s1)); break;
vrr = vec4(notEqual(s0, s1)); break;
case RSX_FP_OPCODE_SEQ:
value = vec4(equal(s0, s1)); break;
vrr = vec4(equal(s0, s1)); break;
case RSX_FP_OPCODE_POW:
value = pow(s0, s1).xxxx; break;
vrr = pow(s0, s1).xxxx; break;
case RSX_FP_OPCODE_DIV:
value = s0 / s1.xxxx; break;
vrr = s0 / s1.xxxx; break;
case RSX_FP_OPCODE_DIVSQ:
value = s0 * inversesqrt(s1.xxxx); break;
vrr = s0 * inversesqrt(s1.xxxx); break;
case RSX_FP_OPCODE_REFL:
value = reflect(s0, s1); break;
vrr = reflect(s0, s1); break;
#ifdef WITH_TEXTURES
//case RSX_FP_OPCODE_TXD:
case RSX_FP_OPCODE_TXL:
value = _textureLod(s0, s1.x); break;
vrr = _textureLod(s0, s1.x); break;
case RSX_FP_OPCODE_TXB:
value = _texture(s0, s1.x); break;
vrr = _texture(s0, s1.x); break;
//case RSX_FP_OPCODE_TEXBEM:
//case RSX_FP_OPCODE_TXPBEM:
#endif
@ -671,11 +716,11 @@ void main()
switch (inst.opcode)
{
case RSX_FP_OPCODE_MAD:
value = fma(s0, s1, s2); break;
vrr = fma(s0, s1, s2); break;
case RSX_FP_OPCODE_LRP:
value = mix(s1, s2, s0); break;
vrr = mix(s1, s2, s0); break;
case RSX_FP_OPCODE_DP2A:
value = dot(s0.xy, s1.xy).xxxx + s2.xxxx; break;
vrr = dot(s0.xy, s1.xy).xxxx + s2.xxxx; break;
}
}
#if 0
@ -686,7 +731,7 @@ void main()
case RSX_FP_OPCODE_LIF:
case RSX_FP_OPCODE_TIMESWTEX:
#endif
write_dst(value);
write_dst(vrr);
}
#ifdef WITH_HALF_OUTPUT_REGISTER

View File

@ -300,8 +300,6 @@ namespace gl
" uvec4 fp_instructions[];\n"
"};\n\n";
::program_common::insert_fog_declaration(builder, "vec4", "fogc", true);
builder << program_common::interpreter::get_fragment_interpreter();
const std::string s = builder.str();

View File

@ -185,8 +185,6 @@ namespace vk
" uvec4 fp_instructions[];\n"
"};\n\n";
::program_common::insert_fog_declaration(builder, "vec4", "fogc", true);
builder << program_common::interpreter::get_fragment_interpreter();
const std::string s = builder.str();