/* * Copyright 2008 Corbin Simpson * * 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. * */ #include "r500_fragprog.h" #include #include "radeon_compiler_util.h" #include "../r300_reg.h" /** * Rewrite IF instructions to use the ALU result special register. */ int r500_transform_IF( struct radeon_compiler * c, struct rc_instruction * inst, void* data) { struct rc_instruction * inst_mov; if (inst->U.I.Opcode != RC_OPCODE_IF) return 0; inst_mov = rc_insert_new_instruction(c, inst->Prev); inst_mov->U.I.Opcode = RC_OPCODE_MOV; inst_mov->U.I.DstReg.WriteMask = 0; inst_mov->U.I.WriteALUResult = RC_ALURESULT_W; inst_mov->U.I.ALUResultCompare = RC_COMPARE_FUNC_NOTEQUAL; inst_mov->U.I.SrcReg[0] = inst->U.I.SrcReg[0]; inst_mov->U.I.SrcReg[0].Swizzle = combine_swizzles4(inst_mov->U.I.SrcReg[0].Swizzle, RC_SWIZZLE_UNUSED, RC_SWIZZLE_UNUSED, RC_SWIZZLE_UNUSED, RC_SWIZZLE_X); inst->U.I.SrcReg[0].File = RC_FILE_SPECIAL; inst->U.I.SrcReg[0].Index = RC_SPECIAL_ALU_RESULT; inst->U.I.SrcReg[0].Swizzle = RC_SWIZZLE_XYZW; inst->U.I.SrcReg[0].Negate = 0; return 1; } static int r500_swizzle_is_native(rc_opcode opcode, struct rc_src_register reg) { unsigned int relevant; int i; if (opcode == RC_OPCODE_TEX || opcode == RC_OPCODE_TXB || opcode == RC_OPCODE_TXP || opcode == RC_OPCODE_KIL) { if (reg.Abs) return 0; if (opcode == RC_OPCODE_KIL && (reg.Swizzle != RC_SWIZZLE_XYZW || reg.Negate != RC_MASK_NONE)) return 0; if (reg.Negate) reg.Negate ^= RC_MASK_XYZW; for(i = 0; i < 4; ++i) { unsigned int swz = GET_SWZ(reg.Swizzle, i); if (swz == RC_SWIZZLE_UNUSED) { reg.Negate &= ~(1 << i); continue; } if (swz >= 4) return 0; } if (reg.Negate) return 0; return 1; } else if (opcode == RC_OPCODE_DDX || opcode == RC_OPCODE_DDY) { /* DDX/MDH and DDY/MDV explicitly ignore incoming swizzles; * if it doesn't fit perfectly into a .xyzw case... */ if (reg.Swizzle == RC_SWIZZLE_XYZW && !reg.Abs && !reg.Negate) return 1; return 0; } else { /* ALU instructions support almost everything */ relevant = 0; for(i = 0; i < 3; ++i) { unsigned int swz = GET_SWZ(reg.Swizzle, i); if (swz != RC_SWIZZLE_UNUSED && swz != RC_SWIZZLE_ZERO) relevant |= 1 << i; } if ((reg.Negate & relevant) && ((reg.Negate & relevant) != relevant)) return 0; return 1; } } /** * Split source register access. * * The only thing we *cannot* do in an ALU instruction is per-component * negation. */ static void r500_swizzle_split(struct rc_src_register src, unsigned int usemask, struct rc_swizzle_split * split) { unsigned int negatebase[2] = { 0, 0 }; int i; for(i = 0; i < 4; ++i) { unsigned int swz = GET_SWZ(src.Swizzle, i); if (swz == RC_SWIZZLE_UNUSED || !GET_BIT(usemask, i)) continue; negatebase[GET_BIT(src.Negate, i)] |= 1 << i; } split->NumPhases = 0; for(i = 0; i <= 1; ++i) { if (!negatebase[i]) continue; split->Phase[split->NumPhases++] = negatebase[i]; } } struct rc_swizzle_caps r500_swizzle_caps = { .IsNative = r500_swizzle_is_native, .Split = r500_swizzle_split }; static char *toswiz(int swiz_val) { switch(swiz_val) { case 0: return "R"; case 1: return "G"; case 2: return "B"; case 3: return "A"; case 4: return "0"; case 5: return "H"; case 6: return "1"; case 7: return "U"; } return NULL; } static char *toop(int op_val) { char *str = NULL; switch (op_val) { case 0: str = "MAD"; break; case 1: str = "DP3"; break; case 2: str = "DP4"; break; case 3: str = "D2A"; break; case 4: str = "MIN"; break; case 5: str = "MAX"; break; case 6: str = "Reserved"; break; case 7: str = "CND"; break; case 8: str = "CMP"; break; case 9: str = "FRC"; break; case 10: str = "SOP"; break; case 11: str = "MDH"; break; case 12: str = "MDV"; break; } return str; } static char *to_alpha_op(int op_val) { char *str = NULL; switch (op_val) { case 0: str = "MAD"; break; case 1: str = "DP"; break; case 2: str = "MIN"; break; case 3: str = "MAX"; break; case 4: str = "Reserved"; break; case 5: str = "CND"; break; case 6: str = "CMP"; break; case 7: str = "FRC"; break; case 8: str = "EX2"; break; case 9: str = "LN2"; break; case 10: str = "RCP"; break; case 11: str = "RSQ"; break; case 12: str = "SIN"; break; case 13: str = "COS"; break; case 14: str = "MDH"; break; case 15: str = "MDV"; break; } return str; } static char *to_mask(int val) { char *str = NULL; switch(val) { case 0: str = "NONE"; break; case 1: str = "R"; break; case 2: str = "G"; break; case 3: str = "RG"; break; case 4: str = "B"; break; case 5: str = "RB"; break; case 6: str = "GB"; break; case 7: str = "RGB"; break; case 8: str = "A"; break; case 9: str = "AR"; break; case 10: str = "AG"; break; case 11: str = "ARG"; break; case 12: str = "AB"; break; case 13: str = "ARB"; break; case 14: str = "AGB"; break; case 15: str = "ARGB"; break; } return str; } static char *to_texop(int val) { switch(val) { case 0: return "NOP"; case 1: return "LD"; case 2: return "TEXKILL"; case 3: return "PROJ"; case 4: return "LODBIAS"; case 5: return "LOD"; case 6: return "DXDY"; } return NULL; } void r500FragmentProgramDump(struct radeon_compiler *c, void *user) { struct r300_fragment_program_compiler *compiler = (struct r300_fragment_program_compiler*)c; struct r500_fragment_program_code *code = &compiler->code->code.r500; int n, i; uint32_t inst; uint32_t inst0; char *str = NULL; fprintf(stderr, "R500 Fragment Program:\n--------\n"); for (n = 0; n < code->inst_end+1; n++) { inst0 = inst = code->inst[n].inst0; fprintf(stderr,"%d\t0:CMN_INST 0x%08x:", n, inst); switch(inst & 0x3) { case R500_INST_TYPE_ALU: str = "ALU"; break; case R500_INST_TYPE_OUT: str = "OUT"; break; case R500_INST_TYPE_FC: str = "FC"; break; case R500_INST_TYPE_TEX: str = "TEX"; break; }; fprintf(stderr,"%s %s %s %s %s ", str, inst & R500_INST_TEX_SEM_WAIT ? "TEX_WAIT" : "", inst & R500_INST_LAST ? "LAST" : "", inst & R500_INST_NOP ? "NOP" : "", inst & R500_INST_ALU_WAIT ? "ALU WAIT" : ""); fprintf(stderr,"wmask: %s omask: %s\n", to_mask((inst >> 11) & 0xf), to_mask((inst >> 15) & 0xf)); switch(inst0 & 0x3) { case R500_INST_TYPE_ALU: case R500_INST_TYPE_OUT: fprintf(stderr,"\t1:RGB_ADDR 0x%08x:", code->inst[n].inst1); inst = code->inst[n].inst1; fprintf(stderr,"Addr0: %d%c, Addr1: %d%c, Addr2: %d%c, srcp:%d\n", inst & 0xff, (inst & (1<<8)) ? 'c' : 't', (inst >> 10) & 0xff, (inst & (1<<18)) ? 'c' : 't', (inst >> 20) & 0xff, (inst & (1<<28)) ? 'c' : 't', (inst >> 30)); fprintf(stderr,"\t2:ALPHA_ADDR 0x%08x:", code->inst[n].inst2); inst = code->inst[n].inst2; fprintf(stderr,"Addr0: %d%c, Addr1: %d%c, Addr2: %d%c, srcp:%d\n", inst & 0xff, (inst & (1<<8)) ? 'c' : 't', (inst >> 10) & 0xff, (inst & (1<<18)) ? 'c' : 't', (inst >> 20) & 0xff, (inst & (1<<28)) ? 'c' : 't', (inst >> 30)); fprintf(stderr,"\t3 RGB_INST: 0x%08x:", code->inst[n].inst3); inst = code->inst[n].inst3; fprintf(stderr,"rgb_A_src:%d %s/%s/%s %d rgb_B_src:%d %s/%s/%s %d targ: %d\n", (inst) & 0x3, toswiz((inst >> 2) & 0x7), toswiz((inst >> 5) & 0x7), toswiz((inst >> 8) & 0x7), (inst >> 11) & 0x3, (inst >> 13) & 0x3, toswiz((inst >> 15) & 0x7), toswiz((inst >> 18) & 0x7), toswiz((inst >> 21) & 0x7), (inst >> 24) & 0x3, (inst >> 29) & 0x3); fprintf(stderr,"\t4 ALPHA_INST:0x%08x:", code->inst[n].inst4); inst = code->inst[n].inst4; fprintf(stderr,"%s dest:%d%s alp_A_src:%d %s %d alp_B_src:%d %s %d targ %d w:%d\n", to_alpha_op(inst & 0xf), (inst >> 4) & 0x7f, inst & (1<<11) ? "(rel)":"", (inst >> 12) & 0x3, toswiz((inst >> 14) & 0x7), (inst >> 17) & 0x3, (inst >> 19) & 0x3, toswiz((inst >> 21) & 0x7), (inst >> 24) & 0x3, (inst >> 29) & 0x3, (inst >> 31) & 0x1); fprintf(stderr,"\t5 RGBA_INST: 0x%08x:", code->inst[n].inst5); inst = code->inst[n].inst5; fprintf(stderr,"%s dest:%d%s rgb_C_src:%d %s/%s/%s %d alp_C_src:%d %s %d\n", toop(inst & 0xf), (inst >> 4) & 0x7f, inst & (1<<11) ? "(rel)":"", (inst >> 12) & 0x3, toswiz((inst >> 14) & 0x7), toswiz((inst >> 17) & 0x7), toswiz((inst >> 20) & 0x7), (inst >> 23) & 0x3, (inst >> 25) & 0x3, toswiz((inst >> 27) & 0x7), (inst >> 30) & 0x3); break; case R500_INST_TYPE_FC: fprintf(stderr, "\t2:FC_INST 0x%08x:", code->inst[n].inst2); inst = code->inst[n].inst2; /* JUMP_FUNC JUMP_ANY*/ fprintf(stderr, "0x%02x %1x ", inst >> 8 & 0xff, (inst & R500_FC_JUMP_ANY) >> 5); /* OP */ switch(inst & 0x7){ case R500_FC_OP_JUMP: fprintf(stderr, "JUMP"); break; case R500_FC_OP_LOOP: fprintf(stderr, "LOOP"); break; case R500_FC_OP_ENDLOOP: fprintf(stderr, "ENDLOOP"); break; case R500_FC_OP_REP: fprintf(stderr, "REP"); break; case R500_FC_OP_ENDREP: fprintf(stderr, "ENDREP"); break; case R500_FC_OP_BREAKLOOP: fprintf(stderr, "BREAKLOOP"); break; case R500_FC_OP_BREAKREP: fprintf(stderr, "BREAKREP"); break; case R500_FC_OP_CONTINUE: fprintf(stderr, "CONTINUE"); break; } fprintf(stderr," "); /* A_OP */ switch(inst & (0x3 << 6)){ case R500_FC_A_OP_NONE: fprintf(stderr, "NONE"); break; case R500_FC_A_OP_POP: fprintf(stderr, "POP"); break; case R500_FC_A_OP_PUSH: fprintf(stderr, "PUSH"); break; } /* B_OP0 B_OP1 */ for(i=0; i<2; i++){ fprintf(stderr, " "); switch(inst & (0x3 << (24 + (i * 2)))){ /* R500_FC_B_OP0_NONE * R500_FC_B_OP1_NONE */ case 0: fprintf(stderr, "NONE"); break; case R500_FC_B_OP0_DECR: case R500_FC_B_OP1_DECR: fprintf(stderr, "DECR"); break; case R500_FC_B_OP0_INCR: case R500_FC_B_OP1_INCR: fprintf(stderr, "INCR"); break; } } /*POP_CNT B_ELSE */ fprintf(stderr, " %d %1x", (inst >> 16) & 0x1f, (inst & R500_FC_B_ELSE) >> 4); inst = code->inst[n].inst3; /* JUMP_ADDR */ fprintf(stderr, " %d", inst >> 16); if(code->inst[n].inst2 & R500_FC_IGNORE_UNCOVERED){ fprintf(stderr, " IGN_UNC"); } inst = code->inst[n].inst3; fprintf(stderr, "\n\t3:FC_ADDR 0x%08x:", inst); fprintf(stderr, "BOOL: 0x%02x, INT: 0x%02x, JUMP_ADDR: %d, JMP_GLBL: %1x\n", inst & 0x1f, (inst >> 8) & 0x1f, (inst >> 16) & 0x1ff, inst >> 31); break; case R500_INST_TYPE_TEX: inst = code->inst[n].inst1; fprintf(stderr,"\t1:TEX_INST: 0x%08x: id: %d op:%s, %s, %s %s\n", inst, (inst >> 16) & 0xf, to_texop((inst >> 22) & 0x7), (inst & (1<<25)) ? "ACQ" : "", (inst & (1<<26)) ? "IGNUNC" : "", (inst & (1<<27)) ? "UNSCALED" : "SCALED"); inst = code->inst[n].inst2; fprintf(stderr,"\t2:TEX_ADDR: 0x%08x: src: %d%s %s/%s/%s/%s dst: %d%s %s/%s/%s/%s\n", inst, inst & 127, inst & (1<<7) ? "(rel)" : "", toswiz((inst >> 8) & 0x3), toswiz((inst >> 10) & 0x3), toswiz((inst >> 12) & 0x3), toswiz((inst >> 14) & 0x3), (inst >> 16) & 127, inst & (1<<23) ? "(rel)" : "", toswiz((inst >> 24) & 0x3), toswiz((inst >> 26) & 0x3), toswiz((inst >> 28) & 0x3), toswiz((inst >> 30) & 0x3)); fprintf(stderr,"\t3:TEX_DXDY: 0x%08x\n", code->inst[n].inst3); break; } fprintf(stderr,"\n"); } }