/* * Copyright (C) 2008 Nicolai Haehnle. * * All Rights Reserved. * * Permission is hereby granted, free of charge, to any person obtaining * a copy of this software and associated documentation files (the * "Software"), to deal in the Software without restriction, including * without limitation the rights to use, copy, modify, merge, publish, * distribute, sublicense, and/or sell copies of the Software, and to * permit persons to whom the Software is furnished to do so, subject to * the following conditions: * * The above copyright notice and this permission notice (including the * next paragraph) shall be included in all copies or substantial * portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. * IN NO EVENT SHALL THE COPYRIGHT OWNER(S) AND/OR ITS SUPPLIERS BE * LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION * OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION * WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. * */ /** * @file * * Shareable transformations that transform "special" ALU instructions * into ALU instructions that are supported by hardware. * */ #include "radeon_program_alu.h" #include "shader/prog_parameter.h" static struct prog_instruction *emit1(struct gl_program* p, gl_inst_opcode Opcode, GLuint Saturate, struct prog_dst_register DstReg, struct prog_src_register SrcReg) { struct prog_instruction *fpi = radeonAppendInstructions(p, 1); fpi->Opcode = Opcode; fpi->SaturateMode = Saturate; fpi->DstReg = DstReg; fpi->SrcReg[0] = SrcReg; return fpi; } static struct prog_instruction *emit2(struct gl_program* p, gl_inst_opcode Opcode, GLuint Saturate, struct prog_dst_register DstReg, struct prog_src_register SrcReg0, struct prog_src_register SrcReg1) { struct prog_instruction *fpi = radeonAppendInstructions(p, 1); fpi->Opcode = Opcode; fpi->SaturateMode = Saturate; fpi->DstReg = DstReg; fpi->SrcReg[0] = SrcReg0; fpi->SrcReg[1] = SrcReg1; return fpi; } static struct prog_instruction *emit3(struct gl_program* p, gl_inst_opcode Opcode, GLuint Saturate, struct prog_dst_register DstReg, struct prog_src_register SrcReg0, struct prog_src_register SrcReg1, struct prog_src_register SrcReg2) { struct prog_instruction *fpi = radeonAppendInstructions(p, 1); fpi->Opcode = Opcode; fpi->SaturateMode = Saturate; fpi->DstReg = DstReg; fpi->SrcReg[0] = SrcReg0; fpi->SrcReg[1] = SrcReg1; fpi->SrcReg[2] = SrcReg2; return fpi; } static void set_swizzle(struct prog_src_register *SrcReg, int coordinate, int swz) { SrcReg->Swizzle &= ~(7 << (3*coordinate)); SrcReg->Swizzle |= swz << (3*coordinate); } static void set_negate_base(struct prog_src_register *SrcReg, int coordinate, int negate) { SrcReg->NegateBase &= ~(1 << coordinate); SrcReg->NegateBase |= (negate << coordinate); } static struct prog_dst_register dstreg(int file, int index) { struct prog_dst_register dst; dst.File = file; dst.Index = index; dst.WriteMask = WRITEMASK_XYZW; dst.CondMask = COND_TR; dst.CondSwizzle = SWIZZLE_NOOP; dst.CondSrc = 0; dst.pad = 0; return dst; } static struct prog_dst_register dstregtmpmask(int index, int mask) { struct prog_dst_register dst; dst.File = PROGRAM_TEMPORARY; dst.Index = index; dst.WriteMask = mask; dst.CondMask = COND_TR; dst.CondSwizzle = SWIZZLE_NOOP; dst.CondSrc = 0; dst.pad = 0; return dst; } static const struct prog_src_register builtin_zero = { .File = PROGRAM_BUILTIN, .Index = 0, .Swizzle = SWIZZLE_0000 }; static const struct prog_src_register builtin_one = { .File = PROGRAM_BUILTIN, .Index = 0, .Swizzle = SWIZZLE_1111 }; static const struct prog_src_register srcreg_undefined = { .File = PROGRAM_UNDEFINED, .Index = 0, .Swizzle = SWIZZLE_NOOP }; static struct prog_src_register srcreg(int file, int index) { struct prog_src_register src = srcreg_undefined; src.File = file; src.Index = index; return src; } static struct prog_src_register srcregswz(int file, int index, int swz) { struct prog_src_register src = srcreg_undefined; src.File = file; src.Index = index; src.Swizzle = swz; return src; } static struct prog_src_register absolute(struct prog_src_register reg) { struct prog_src_register newreg = reg; newreg.Abs = 1; newreg.NegateBase = 0; newreg.NegateAbs = 0; return newreg; } static struct prog_src_register negate(struct prog_src_register reg) { struct prog_src_register newreg = reg; newreg.NegateAbs = !newreg.NegateAbs; return newreg; } static struct prog_src_register swizzle(struct prog_src_register reg, GLuint x, GLuint y, GLuint z, GLuint w) { struct prog_src_register swizzled = reg; swizzled.Swizzle = MAKE_SWIZZLE4( x >= 4 ? x : GET_SWZ(reg.Swizzle, x), y >= 4 ? y : GET_SWZ(reg.Swizzle, y), z >= 4 ? z : GET_SWZ(reg.Swizzle, z), w >= 4 ? w : GET_SWZ(reg.Swizzle, w)); return swizzled; } static struct prog_src_register scalar(struct prog_src_register reg) { return swizzle(reg, SWIZZLE_X, SWIZZLE_X, SWIZZLE_X, SWIZZLE_X); } static void transform_ABS(struct radeon_transform_context* t, struct prog_instruction* inst) { struct prog_src_register src = inst->SrcReg[0]; src.Abs = 1; src.NegateBase = 0; src.NegateAbs = 0; emit1(t->Program, OPCODE_MOV, inst->SaturateMode, inst->DstReg, src); } static void transform_DPH(struct radeon_transform_context* t, struct prog_instruction* inst) { struct prog_src_register src0 = inst->SrcReg[0]; if (src0.NegateAbs) { if (src0.Abs) { int tempreg = radeonFindFreeTemporary(t); emit1(t->Program, OPCODE_MOV, 0, dstreg(PROGRAM_TEMPORARY, tempreg), src0); src0 = srcreg(src0.File, src0.Index); } else { src0.NegateAbs = 0; src0.NegateBase ^= NEGATE_XYZW; } } set_swizzle(&src0, 3, SWIZZLE_ONE); set_negate_base(&src0, 3, 0); emit2(t->Program, OPCODE_DP4, inst->SaturateMode, inst->DstReg, src0, inst->SrcReg[1]); } /** * [1, src0.y*src1.y, src0.z, src1.w] * So basically MUL with lotsa swizzling. */ static void transform_DST(struct radeon_transform_context* t, struct prog_instruction* inst) { emit2(t->Program, OPCODE_MUL, inst->SaturateMode, inst->DstReg, swizzle(inst->SrcReg[0], SWIZZLE_ONE, SWIZZLE_Y, SWIZZLE_Z, SWIZZLE_ONE), swizzle(inst->SrcReg[1], SWIZZLE_ONE, SWIZZLE_Y, SWIZZLE_ONE, SWIZZLE_W)); } static void transform_FLR(struct radeon_transform_context* t, struct prog_instruction* inst) { int tempreg = radeonFindFreeTemporary(t); emit1(t->Program, OPCODE_FRC, 0, dstreg(PROGRAM_TEMPORARY, tempreg), inst->SrcReg[0]); emit2(t->Program, OPCODE_ADD, inst->SaturateMode, inst->DstReg, inst->SrcReg[0], negate(srcreg(PROGRAM_TEMPORARY, tempreg))); } /** * Definition of LIT (from ARB_fragment_program): * * tmp = VectorLoad(op0); * if (tmp.x < 0) tmp.x = 0; * if (tmp.y < 0) tmp.y = 0; * if (tmp.w < -(128.0-epsilon)) tmp.w = -(128.0-epsilon); * else if (tmp.w > 128-epsilon) tmp.w = 128-epsilon; * result.x = 1.0; * result.y = tmp.x; * result.z = (tmp.x > 0) ? RoughApproxPower(tmp.y, tmp.w) : 0.0; * result.w = 1.0; * * The longest path of computation is the one leading to result.z, * consisting of 5 operations. This implementation of LIT takes * 5 slots, if the subsequent optimization passes are clever enough * to pair instructions correctly. */ static void transform_LIT(struct radeon_transform_context* t, struct prog_instruction* inst) { static const GLfloat LitConst[4] = { -127.999999 }; GLuint constant; GLuint constant_swizzle; GLuint temp; int needTemporary = 0; struct prog_src_register srctemp; constant = _mesa_add_unnamed_constant(t->Program->Parameters, LitConst, 1, &constant_swizzle); if (inst->DstReg.WriteMask != WRITEMASK_XYZW) { needTemporary = 1; } else if (inst->DstReg.File != PROGRAM_TEMPORARY) { // LIT is typically followed by DP3/DP4, so there's no point // in creating special code for this case needTemporary = 1; } if (needTemporary) { temp = radeonFindFreeTemporary(t); } else { temp = inst->DstReg.Index; } srctemp = srcreg(PROGRAM_TEMPORARY, temp); // tmp.x = max(0.0, Src.x); // tmp.y = max(0.0, Src.y); // tmp.w = clamp(Src.z, -128+eps, 128-eps); emit2(t->Program, OPCODE_MAX, 0, dstregtmpmask(temp, WRITEMASK_XYW), inst->SrcReg[0], swizzle(srcreg(PROGRAM_CONSTANT, constant), SWIZZLE_ZERO, SWIZZLE_ZERO, SWIZZLE_ZERO, constant_swizzle&3)); emit2(t->Program, OPCODE_MIN, 0, dstregtmpmask(temp, WRITEMASK_Z), swizzle(srctemp, SWIZZLE_W, SWIZZLE_W, SWIZZLE_W, SWIZZLE_W), negate(srcregswz(PROGRAM_CONSTANT, constant, constant_swizzle))); // tmp.w = Pow(tmp.y, tmp.w) emit1(t->Program, OPCODE_LG2, 0, dstregtmpmask(temp, WRITEMASK_W), swizzle(srctemp, SWIZZLE_Y, SWIZZLE_Y, SWIZZLE_Y, SWIZZLE_Y)); emit2(t->Program, OPCODE_MUL, 0, dstregtmpmask(temp, WRITEMASK_W), swizzle(srctemp, SWIZZLE_W, SWIZZLE_W, SWIZZLE_W, SWIZZLE_W), swizzle(srctemp, SWIZZLE_Z, SWIZZLE_Z, SWIZZLE_Z, SWIZZLE_Z)); emit1(t->Program, OPCODE_EX2, 0, dstregtmpmask(temp, WRITEMASK_W), swizzle(srctemp, SWIZZLE_W, SWIZZLE_W, SWIZZLE_W, SWIZZLE_W)); // tmp.z = (tmp.x > 0) ? tmp.w : 0.0 emit3(t->Program, OPCODE_CMP, inst->SaturateMode, dstregtmpmask(temp, WRITEMASK_Z), negate(swizzle(srctemp, SWIZZLE_X, SWIZZLE_X, SWIZZLE_X, SWIZZLE_X)), swizzle(srctemp, SWIZZLE_W, SWIZZLE_W, SWIZZLE_W, SWIZZLE_W), builtin_zero); // tmp.x, tmp.y, tmp.w = 1.0, tmp.x, 1.0 emit1(t->Program, OPCODE_MOV, inst->SaturateMode, dstregtmpmask(temp, WRITEMASK_XYW), swizzle(srctemp, SWIZZLE_ONE, SWIZZLE_X, SWIZZLE_ONE, SWIZZLE_ONE)); if (needTemporary) emit1(t->Program, OPCODE_MOV, 0, inst->DstReg, srctemp); } static void transform_LRP(struct radeon_transform_context* t, struct prog_instruction* inst) { int tempreg = radeonFindFreeTemporary(t); emit2(t->Program, OPCODE_ADD, 0, dstreg(PROGRAM_TEMPORARY, tempreg), inst->SrcReg[1], negate(inst->SrcReg[2])); emit3(t->Program, OPCODE_MAD, inst->SaturateMode, inst->DstReg, inst->SrcReg[0], srcreg(PROGRAM_TEMPORARY, tempreg), inst->SrcReg[2]); } static void transform_POW(struct radeon_transform_context* t, struct prog_instruction* inst) { int tempreg = radeonFindFreeTemporary(t); struct prog_dst_register tempdst = dstreg(PROGRAM_TEMPORARY, tempreg); struct prog_src_register tempsrc = srcreg(PROGRAM_TEMPORARY, tempreg); tempdst.WriteMask = WRITEMASK_W; tempsrc.Swizzle = SWIZZLE_WWWW; emit1(t->Program, OPCODE_LG2, 0, tempdst, scalar(inst->SrcReg[0])); emit2(t->Program, OPCODE_MUL, 0, tempdst, tempsrc, scalar(inst->SrcReg[1])); emit1(t->Program, OPCODE_EX2, inst->SaturateMode, inst->DstReg, tempsrc); } static void transform_RSQ(struct radeon_transform_context* t, struct prog_instruction* inst) { emit1(t->Program, OPCODE_RSQ, inst->SaturateMode, inst->DstReg, absolute(inst->SrcReg[0])); } static void transform_SGE(struct radeon_transform_context* t, struct prog_instruction* inst) { int tempreg = radeonFindFreeTemporary(t); emit2(t->Program, OPCODE_ADD, 0, dstreg(PROGRAM_TEMPORARY, tempreg), inst->SrcReg[0], negate(inst->SrcReg[1])); emit3(t->Program, OPCODE_CMP, inst->SaturateMode, inst->DstReg, srcreg(PROGRAM_TEMPORARY, tempreg), builtin_zero, builtin_one); } static void transform_SLT(struct radeon_transform_context* t, struct prog_instruction* inst) { int tempreg = radeonFindFreeTemporary(t); emit2(t->Program, OPCODE_ADD, 0, dstreg(PROGRAM_TEMPORARY, tempreg), inst->SrcReg[0], negate(inst->SrcReg[1])); emit3(t->Program, OPCODE_CMP, inst->SaturateMode, inst->DstReg, srcreg(PROGRAM_TEMPORARY, tempreg), builtin_one, builtin_zero); } static void transform_SUB(struct radeon_transform_context* t, struct prog_instruction* inst) { emit2(t->Program, OPCODE_ADD, inst->SaturateMode, inst->DstReg, inst->SrcReg[0], negate(inst->SrcReg[1])); } static void transform_SWZ(struct radeon_transform_context* t, struct prog_instruction* inst) { emit1(t->Program, OPCODE_MOV, inst->SaturateMode, inst->DstReg, inst->SrcReg[0]); } static void transform_XPD(struct radeon_transform_context* t, struct prog_instruction* inst) { int tempreg = radeonFindFreeTemporary(t); emit2(t->Program, OPCODE_MUL, 0, dstreg(PROGRAM_TEMPORARY, tempreg), swizzle(inst->SrcReg[0], SWIZZLE_Z, SWIZZLE_X, SWIZZLE_Y, SWIZZLE_W), swizzle(inst->SrcReg[1], SWIZZLE_Y, SWIZZLE_Z, SWIZZLE_X, SWIZZLE_W)); emit3(t->Program, OPCODE_MAD, inst->SaturateMode, inst->DstReg, swizzle(inst->SrcReg[0], SWIZZLE_Y, SWIZZLE_Z, SWIZZLE_X, SWIZZLE_W), swizzle(inst->SrcReg[1], SWIZZLE_Z, SWIZZLE_X, SWIZZLE_Y, SWIZZLE_W), negate(srcreg(PROGRAM_TEMPORARY, tempreg))); } /** * Can be used as a transformation for @ref radeonClauseLocalTransform, * no userData necessary. * * Eliminates the following ALU instructions: * ABS, DPH, DST, FLR, LIT, LRP, POW, SGE, SLT, SUB, SWZ, XPD * using: * MOV, ADD, MUL, MAD, FRC, DP3, LG2, EX2, CMP * * Transforms RSQ to Radeon's native RSQ by explicitly setting * absolute value. * * @note should be applicable to R300 and R500 fragment programs. */ GLboolean radeonTransformALU(struct radeon_transform_context* t, struct prog_instruction* inst, void* unused) { switch(inst->Opcode) { case OPCODE_ABS: transform_ABS(t, inst); return GL_TRUE; case OPCODE_DPH: transform_DPH(t, inst); return GL_TRUE; case OPCODE_DST: transform_DST(t, inst); return GL_TRUE; case OPCODE_FLR: transform_FLR(t, inst); return GL_TRUE; case OPCODE_LIT: transform_LIT(t, inst); return GL_TRUE; case OPCODE_LRP: transform_LRP(t, inst); return GL_TRUE; case OPCODE_POW: transform_POW(t, inst); return GL_TRUE; case OPCODE_RSQ: transform_RSQ(t, inst); return GL_TRUE; case OPCODE_SGE: transform_SGE(t, inst); return GL_TRUE; case OPCODE_SLT: transform_SLT(t, inst); return GL_TRUE; case OPCODE_SUB: transform_SUB(t, inst); return GL_TRUE; case OPCODE_SWZ: transform_SWZ(t, inst); return GL_TRUE; case OPCODE_XPD: transform_XPD(t, inst); return GL_TRUE; default: return GL_FALSE; } } static void sincos_constants(struct radeon_transform_context* t, GLuint *constants) { static const GLfloat SinCosConsts[2][4] = { { 1.273239545, // 4/PI -0.405284735, // -4/(PI*PI) 3.141592654, // PI 0.2225 // weight }, { 0.75, 0.5, 0.159154943, // 1/(2*PI) 6.283185307 // 2*PI } }; int i; for(i = 0; i < 2; ++i) { GLuint swz; constants[i] = _mesa_add_unnamed_constant(t->Program->Parameters, SinCosConsts[i], 4, &swz); ASSERT(swz == SWIZZLE_NOOP); } } /** * Approximate sin(x), where x is clamped to (-pi/2, pi/2). * * MUL tmp.xy, src, { 4/PI, -4/(PI^2) } * MAD tmp.x, tmp.y, |src|, tmp.x * MAD tmp.y, tmp.x, |tmp.x|, -tmp.x * MAD dest, tmp.y, weight, tmp.x */ static void sin_approx(struct radeon_transform_context* t, struct prog_dst_register dst, struct prog_src_register src, const GLuint* constants) { GLuint tempreg = radeonFindFreeTemporary(t); emit2(t->Program, OPCODE_MUL, 0, dstregtmpmask(tempreg, WRITEMASK_XY), swizzle(src, SWIZZLE_X, SWIZZLE_X, SWIZZLE_X, SWIZZLE_X), srcreg(PROGRAM_CONSTANT, constants[0])); emit3(t->Program, OPCODE_MAD, 0, dstregtmpmask(tempreg, WRITEMASK_X), swizzle(srcreg(PROGRAM_TEMPORARY, tempreg), SWIZZLE_Y, SWIZZLE_Y, SWIZZLE_Y, SWIZZLE_Y), absolute(swizzle(src, SWIZZLE_X, SWIZZLE_X, SWIZZLE_X, SWIZZLE_X)), swizzle(srcreg(PROGRAM_TEMPORARY, tempreg), SWIZZLE_X, SWIZZLE_X, SWIZZLE_X, SWIZZLE_X)); emit3(t->Program, OPCODE_MAD, 0, dstregtmpmask(tempreg, WRITEMASK_Y), swizzle(srcreg(PROGRAM_TEMPORARY, tempreg), SWIZZLE_X, SWIZZLE_X, SWIZZLE_X, SWIZZLE_X), absolute(swizzle(srcreg(PROGRAM_TEMPORARY, tempreg), SWIZZLE_X, SWIZZLE_X, SWIZZLE_X, SWIZZLE_X)), negate(swizzle(srcreg(PROGRAM_TEMPORARY, tempreg), SWIZZLE_X, SWIZZLE_X, SWIZZLE_X, SWIZZLE_X))); emit3(t->Program, OPCODE_MAD, 0, dst, swizzle(srcreg(PROGRAM_TEMPORARY, tempreg), SWIZZLE_Y, SWIZZLE_Y, SWIZZLE_Y, SWIZZLE_Y), swizzle(srcreg(PROGRAM_CONSTANT, constants[0]), SWIZZLE_W, SWIZZLE_W, SWIZZLE_W, SWIZZLE_W), swizzle(srcreg(PROGRAM_TEMPORARY, tempreg), SWIZZLE_X, SWIZZLE_X, SWIZZLE_X, SWIZZLE_X)); } /** * Translate the trigonometric functions COS, SIN, and SCS * using only the basic instructions * MOV, ADD, MUL, MAD, FRC */ GLboolean radeonTransformTrigSimple(struct radeon_transform_context* t, struct prog_instruction* inst, void* unused) { if (inst->Opcode != OPCODE_COS && inst->Opcode != OPCODE_SIN && inst->Opcode != OPCODE_SCS) return GL_FALSE; GLuint constants[2]; GLuint tempreg = radeonFindFreeTemporary(t); sincos_constants(t, constants); if (inst->Opcode == OPCODE_COS) { // MAD tmp.x, src, 1/(2*PI), 0.75 // FRC tmp.x, tmp.x // MAD tmp.z, tmp.x, 2*PI, -PI emit3(t->Program, OPCODE_MAD, 0, dstregtmpmask(tempreg, WRITEMASK_W), swizzle(inst->SrcReg[0], SWIZZLE_X, SWIZZLE_X, SWIZZLE_X, SWIZZLE_X), swizzle(srcreg(PROGRAM_CONSTANT, constants[1]), SWIZZLE_Z, SWIZZLE_Z, SWIZZLE_Z, SWIZZLE_Z), swizzle(srcreg(PROGRAM_CONSTANT, constants[1]), SWIZZLE_X, SWIZZLE_X, SWIZZLE_X, SWIZZLE_X)); emit1(t->Program, OPCODE_FRC, 0, dstregtmpmask(tempreg, WRITEMASK_W), swizzle(srcreg(PROGRAM_TEMPORARY, tempreg), SWIZZLE_W, SWIZZLE_W, SWIZZLE_W, SWIZZLE_W)); emit3(t->Program, OPCODE_MAD, 0, dstregtmpmask(tempreg, WRITEMASK_W), swizzle(srcreg(PROGRAM_TEMPORARY, tempreg), SWIZZLE_W, SWIZZLE_W, SWIZZLE_W, SWIZZLE_W), swizzle(srcreg(PROGRAM_CONSTANT, constants[1]), SWIZZLE_W, SWIZZLE_W, SWIZZLE_W, SWIZZLE_W), negate(swizzle(srcreg(PROGRAM_CONSTANT, constants[0]), SWIZZLE_Z, SWIZZLE_Z, SWIZZLE_Z, SWIZZLE_Z))); sin_approx(t, inst->DstReg, swizzle(srcreg(PROGRAM_TEMPORARY, tempreg), SWIZZLE_W, SWIZZLE_W, SWIZZLE_W, SWIZZLE_W), constants); } else if (inst->Opcode == OPCODE_SIN) { emit3(t->Program, OPCODE_MAD, 0, dstregtmpmask(tempreg, WRITEMASK_W), swizzle(inst->SrcReg[0], SWIZZLE_X, SWIZZLE_X, SWIZZLE_X, SWIZZLE_X), swizzle(srcreg(PROGRAM_CONSTANT, constants[1]), SWIZZLE_Z, SWIZZLE_Z, SWIZZLE_Z, SWIZZLE_Z), swizzle(srcreg(PROGRAM_CONSTANT, constants[1]), SWIZZLE_Y, SWIZZLE_Y, SWIZZLE_Y, SWIZZLE_Y)); emit1(t->Program, OPCODE_FRC, 0, dstregtmpmask(tempreg, WRITEMASK_W), swizzle(srcreg(PROGRAM_TEMPORARY, tempreg), SWIZZLE_W, SWIZZLE_W, SWIZZLE_W, SWIZZLE_W)); emit3(t->Program, OPCODE_MAD, 0, dstregtmpmask(tempreg, WRITEMASK_W), swizzle(srcreg(PROGRAM_TEMPORARY, tempreg), SWIZZLE_W, SWIZZLE_W, SWIZZLE_W, SWIZZLE_W), swizzle(srcreg(PROGRAM_CONSTANT, constants[1]), SWIZZLE_W, SWIZZLE_W, SWIZZLE_W, SWIZZLE_W), negate(swizzle(srcreg(PROGRAM_CONSTANT, constants[0]), SWIZZLE_Z, SWIZZLE_Z, SWIZZLE_Z, SWIZZLE_Z))); sin_approx(t, inst->DstReg, swizzle(srcreg(PROGRAM_TEMPORARY, tempreg), SWIZZLE_W, SWIZZLE_W, SWIZZLE_W, SWIZZLE_W), constants); } else { emit3(t->Program, OPCODE_MAD, 0, dstregtmpmask(tempreg, WRITEMASK_XY), swizzle(inst->SrcReg[0], SWIZZLE_X, SWIZZLE_X, SWIZZLE_X, SWIZZLE_X), swizzle(srcreg(PROGRAM_CONSTANT, constants[1]), SWIZZLE_Z, SWIZZLE_Z, SWIZZLE_Z, SWIZZLE_Z), swizzle(srcreg(PROGRAM_CONSTANT, constants[1]), SWIZZLE_X, SWIZZLE_Y, SWIZZLE_Z, SWIZZLE_W)); emit1(t->Program, OPCODE_FRC, 0, dstregtmpmask(tempreg, WRITEMASK_XY), srcreg(PROGRAM_TEMPORARY, tempreg)); emit3(t->Program, OPCODE_MAD, 0, dstregtmpmask(tempreg, WRITEMASK_XY), srcreg(PROGRAM_TEMPORARY, tempreg), swizzle(srcreg(PROGRAM_CONSTANT, constants[1]), SWIZZLE_W, SWIZZLE_W, SWIZZLE_W, SWIZZLE_W), negate(swizzle(srcreg(PROGRAM_CONSTANT, constants[0]), SWIZZLE_Z, SWIZZLE_Z, SWIZZLE_Z, SWIZZLE_Z))); struct prog_dst_register dst = inst->DstReg; dst.WriteMask = inst->DstReg.WriteMask & WRITEMASK_X; sin_approx(t, dst, swizzle(srcreg(PROGRAM_TEMPORARY, tempreg), SWIZZLE_X, SWIZZLE_X, SWIZZLE_X, SWIZZLE_X), constants); dst.WriteMask = inst->DstReg.WriteMask & WRITEMASK_Y; sin_approx(t, dst, swizzle(srcreg(PROGRAM_TEMPORARY, tempreg), SWIZZLE_Y, SWIZZLE_Y, SWIZZLE_Y, SWIZZLE_Y), constants); } return GL_TRUE; } /** * Transform the trigonometric functions COS, SIN, and SCS * to include pre-scaling by 1/(2*PI) and taking the fractional * part, so that the input to COS and SIN is always in the range [0,1). * SCS is replaced by one COS and one SIN instruction. * * @warning This transformation implicitly changes the semantics of SIN and COS! */ GLboolean radeonTransformTrigScale(struct radeon_transform_context* t, struct prog_instruction* inst, void* unused) { if (inst->Opcode != OPCODE_COS && inst->Opcode != OPCODE_SIN && inst->Opcode != OPCODE_SCS) return GL_FALSE; static const GLfloat RCP_2PI[] = { 0.15915494309189535 }; GLuint temp; GLuint constant; GLuint constant_swizzle; temp = radeonFindFreeTemporary(t); constant = _mesa_add_unnamed_constant(t->Program->Parameters, RCP_2PI, 1, &constant_swizzle); emit2(t->Program, OPCODE_MUL, 0, dstregtmpmask(temp, WRITEMASK_W), swizzle(inst->SrcReg[0], SWIZZLE_X, SWIZZLE_X, SWIZZLE_X, SWIZZLE_X), srcregswz(PROGRAM_CONSTANT, constant, constant_swizzle)); emit1(t->Program, OPCODE_FRC, 0, dstregtmpmask(temp, WRITEMASK_W), srcreg(PROGRAM_TEMPORARY, temp)); if (inst->Opcode == OPCODE_COS) { emit1(t->Program, OPCODE_COS, inst->SaturateMode, inst->DstReg, srcregswz(PROGRAM_TEMPORARY, temp, SWIZZLE_WWWW)); } else if (inst->Opcode == OPCODE_SIN) { emit1(t->Program, OPCODE_SIN, inst->SaturateMode, inst->DstReg, srcregswz(PROGRAM_TEMPORARY, temp, SWIZZLE_WWWW)); } else if (inst->Opcode == OPCODE_SCS) { struct prog_dst_register moddst = inst->DstReg; if (inst->DstReg.WriteMask & WRITEMASK_X) { moddst.WriteMask = WRITEMASK_X; emit1(t->Program, OPCODE_COS, inst->SaturateMode, moddst, srcregswz(PROGRAM_TEMPORARY, temp, SWIZZLE_WWWW)); } if (inst->DstReg.WriteMask & WRITEMASK_Y) { moddst.WriteMask = WRITEMASK_Y; emit1(t->Program, OPCODE_SIN, inst->SaturateMode, moddst, srcregswz(PROGRAM_TEMPORARY, temp, SWIZZLE_WWWW)); } } return GL_TRUE; } /** * Rewrite DDX/DDY instructions to properly work with r5xx shaders. * The r5xx MDH/MDV instruction provides per-quad partial derivatives. * It takes the form A*B+C. A and C are set by setting src0. B should be -1. * * @warning This explicitly changes the form of DDX and DDY! */ GLboolean radeonTransformDeriv(struct radeon_transform_context* t, struct prog_instruction* inst, void* unused) { if (inst->Opcode != OPCODE_DDX && inst->Opcode != OPCODE_DDY) return GL_FALSE; struct prog_src_register B = inst->SrcReg[1]; B.Swizzle = MAKE_SWIZZLE4(SWIZZLE_ONE, SWIZZLE_ONE, SWIZZLE_ONE, SWIZZLE_ONE); B.NegateBase = NEGATE_XYZW; emit2(t->Program, inst->Opcode, inst->SaturateMode, inst->DstReg, inst->SrcReg[0], B); return GL_TRUE; }