/* * Copyright (C) 2009 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. * */ #include "radeon_program_pair.h" #include #include "radeon_compiler.h" #include "radeon_compiler_util.h" #include "radeon_dataflow.h" #define VERBOSE 0 #define DBG(...) do { if (VERBOSE) fprintf(stderr, __VA_ARGS__); } while(0) struct schedule_instruction { struct rc_instruction * Instruction; /** Next instruction in the linked list of ready instructions. */ struct schedule_instruction *NextReady; /** Values that this instruction reads and writes */ struct reg_value * WriteValues[4]; struct reg_value * ReadValues[12]; unsigned int NumWriteValues:3; unsigned int NumReadValues:4; /** * Number of (read and write) dependencies that must be resolved before * this instruction can be scheduled. */ unsigned int NumDependencies:5; /** List of all readers (see rc_get_readers() for the definition of * "all readers"), even those outside the basic block this instruction * lives in. */ struct rc_reader_data GlobalReaders; }; /** * Used to keep track of which instructions read a value. */ struct reg_value_reader { struct schedule_instruction *Reader; struct reg_value_reader *Next; }; /** * Used to keep track which values are stored in each component of a * RC_FILE_TEMPORARY. */ struct reg_value { struct schedule_instruction * Writer; /** * Unordered linked list of instructions that read from this value. * When this value becomes available, we increase all readers' * dependency count. */ struct reg_value_reader *Readers; /** * Number of readers of this value. This is decremented each time * a reader of the value is committed. * When the reader cound reaches zero, the dependency count * of the instruction writing \ref Next is decremented. */ unsigned int NumReaders; struct reg_value *Next; /**< Pointer to the next value to be written to the same register */ }; struct register_state { struct reg_value * Values[4]; }; struct remap_reg { struct rc_instruciont * Inst; unsigned int OldIndex:(RC_REGISTER_INDEX_BITS+1); unsigned int OldSwizzle:3; unsigned int NewIndex:(RC_REGISTER_INDEX_BITS+1); unsigned int NewSwizzle:3; unsigned int OnlyTexReads:1; struct remap_reg * Next; }; struct schedule_state { struct radeon_compiler * C; struct schedule_instruction * Current; struct register_state Temporary[RC_REGISTER_MAX_INDEX]; /** * Linked lists of instructions that can be scheduled right now, * based on which ALU/TEX resources they require. */ /*@{*/ struct schedule_instruction *ReadyFullALU; struct schedule_instruction *ReadyRGB; struct schedule_instruction *ReadyAlpha; struct schedule_instruction *ReadyTEX; /*@}*/ }; static struct reg_value ** get_reg_valuep(struct schedule_state * s, rc_register_file file, unsigned int index, unsigned int chan) { if (file != RC_FILE_TEMPORARY) return 0; if (index >= RC_REGISTER_MAX_INDEX) { rc_error(s->C, "%s: index %i out of bounds\n", __FUNCTION__, index); return 0; } return &s->Temporary[index].Values[chan]; } static void add_inst_to_list(struct schedule_instruction ** list, struct schedule_instruction * inst) { inst->NextReady = *list; *list = inst; } static void add_inst_to_list_end(struct schedule_instruction ** list, struct schedule_instruction * inst) { if(!*list){ *list = inst; }else{ struct schedule_instruction * temp = *list; while(temp->NextReady){ temp = temp->NextReady; } temp->NextReady = inst; } } static void instruction_ready(struct schedule_state * s, struct schedule_instruction * sinst) { DBG("%i is now ready\n", sinst->Instruction->IP); /* Adding Ready TEX instructions to the end of the "Ready List" helps * us emit TEX instructions in blocks without losing our place. */ if (sinst->Instruction->Type == RC_INSTRUCTION_NORMAL) add_inst_to_list_end(&s->ReadyTEX, sinst); else if (sinst->Instruction->U.P.Alpha.Opcode == RC_OPCODE_NOP) add_inst_to_list(&s->ReadyRGB, sinst); else if (sinst->Instruction->U.P.RGB.Opcode == RC_OPCODE_NOP) add_inst_to_list(&s->ReadyAlpha, sinst); else add_inst_to_list(&s->ReadyFullALU, sinst); } static void decrease_dependencies(struct schedule_state * s, struct schedule_instruction * sinst) { assert(sinst->NumDependencies > 0); sinst->NumDependencies--; if (!sinst->NumDependencies) instruction_ready(s, sinst); } /** * This function decreases the dependencies of the next instruction that * wants to write to each of sinst's read values. */ static void commit_update_reads(struct schedule_state * s, struct schedule_instruction * sinst){ unsigned int i; for(i = 0; i < sinst->NumReadValues; ++i) { struct reg_value * v = sinst->ReadValues[i]; assert(v->NumReaders > 0); v->NumReaders--; if (!v->NumReaders) { if (v->Next) decrease_dependencies(s, v->Next->Writer); } } } static void commit_update_writes(struct schedule_state * s, struct schedule_instruction * sinst){ unsigned int i; for(i = 0; i < sinst->NumWriteValues; ++i) { struct reg_value * v = sinst->WriteValues[i]; if (v->NumReaders) { for(struct reg_value_reader * r = v->Readers; r; r = r->Next) { decrease_dependencies(s, r->Reader); } } else { /* This happens in instruction sequences of the type * OP r.x, ...; * OP r.x, r.x, ...; * See also the subtlety in how instructions that both * read and write the same register are scanned. */ if (v->Next) decrease_dependencies(s, v->Next->Writer); } } } static void commit_alu_instruction(struct schedule_state * s, struct schedule_instruction * sinst) { DBG("%i: commit\n", sinst->Instruction->IP); commit_update_reads(s, sinst); commit_update_writes(s, sinst); } /** * Emit all ready texture instructions in a single block. * * Emit as a single block to (hopefully) sample many textures in parallel, * and to avoid hardware indirections on R300. */ static void emit_all_tex(struct schedule_state * s, struct rc_instruction * before) { struct schedule_instruction *readytex; struct rc_instruction * inst_begin; assert(s->ReadyTEX); /* Node marker for R300 */ inst_begin = rc_insert_new_instruction(s->C, before->Prev); inst_begin->U.I.Opcode = RC_OPCODE_BEGIN_TEX; /* Link texture instructions back in */ readytex = s->ReadyTEX; while(readytex) { rc_insert_instruction(before->Prev, readytex->Instruction); DBG("%i: commit TEX reads\n", readytex->Instruction->IP); /* All of the TEX instructions in the same TEX block have * their source registers read from before any of the * instructions in that block write to their destination * registers. This means that when we commit a TEX * instruction, any other TEX instruction that wants to write * to one of the committed instruction's source register can be * marked as ready and should be emitted in the same TEX * block. This prevents the following sequence from being * emitted in two different TEX blocks: * 0: TEX temp[0].xyz, temp[1].xy__, 2D[0]; * 1: TEX temp[1].xyz, temp[2].xy__, 2D[0]; */ commit_update_reads(s, readytex); readytex = readytex->NextReady; } readytex = s->ReadyTEX; s->ReadyTEX = 0; while(readytex){ DBG("%i: commit TEX writes\n", readytex->Instruction->IP); commit_update_writes(s, readytex); readytex = readytex->NextReady; } } /* This is a helper function for destructive_merge_instructions(). It helps * merge presubtract sources from two instructions and makes sure the * presubtract sources end up in the correct spot. This function assumes that * dst_full is an rgb instruction, meaning that it has a vector instruction(rgb) * but no scalar instruction (alpha). * @return 0 if merging the presubtract sources fails. * @retrun 1 if merging the presubtract sources succeeds. */ static int merge_presub_sources( struct rc_pair_instruction * dst_full, struct rc_pair_sub_instruction src, unsigned int type) { unsigned int srcp_src, srcp_regs, is_rgb, is_alpha; struct rc_pair_sub_instruction * dst_sub; const struct rc_opcode_info * info; assert(dst_full->Alpha.Opcode == RC_OPCODE_NOP); switch(type) { case RC_SOURCE_RGB: is_rgb = 1; is_alpha = 0; dst_sub = &dst_full->RGB; break; case RC_SOURCE_ALPHA: is_rgb = 0; is_alpha = 1; dst_sub = &dst_full->Alpha; break; default: assert(0); return 0; } info = rc_get_opcode_info(dst_full->RGB.Opcode); if (dst_sub->Src[RC_PAIR_PRESUB_SRC].Used) return 0; srcp_regs = rc_presubtract_src_reg_count( src.Src[RC_PAIR_PRESUB_SRC].Index); for(srcp_src = 0; srcp_src < srcp_regs; srcp_src++) { unsigned int arg; int free_source; unsigned int one_way = 0; struct rc_pair_instruction_source srcp = src.Src[srcp_src]; struct rc_pair_instruction_source temp; free_source = rc_pair_alloc_source(dst_full, is_rgb, is_alpha, srcp.File, srcp.Index); /* If free_source < 0 then there are no free source * slots. */ if (free_source < 0) return 0; temp = dst_sub->Src[srcp_src]; dst_sub->Src[srcp_src] = dst_sub->Src[free_source]; /* srcp needs src0 and src1 to be the same */ if (free_source < srcp_src) { if (!temp.Used) continue; free_source = rc_pair_alloc_source(dst_full, is_rgb, is_alpha, temp.File, temp.Index); if (free_source < 0) return 0; one_way = 1; } else { dst_sub->Src[free_source] = temp; } /* If free_source == srcp_src, then the presubtract * source is already in the correct place. */ if (free_source == srcp_src) continue; /* Shuffle the sources, so we can put the * presubtract source in the correct place. */ for(arg = 0; arg < info->NumSrcRegs; arg++) { /*If this arg does not read from an rgb source, * do nothing. */ if (!(rc_source_type_swz(dst_full->RGB.Arg[arg].Swizzle) & type)) { continue; } if (dst_full->RGB.Arg[arg].Source == srcp_src) dst_full->RGB.Arg[arg].Source = free_source; /* We need to do this just in case register * is one of the sources already, but in the * wrong spot. */ else if(dst_full->RGB.Arg[arg].Source == free_source && !one_way) { dst_full->RGB.Arg[arg].Source = srcp_src; } } } return 1; } /* This function assumes that rgb.Alpha and alpha.RGB are unused */ static int destructive_merge_instructions( struct rc_pair_instruction * rgb, struct rc_pair_instruction * alpha) { const struct rc_opcode_info * opcode; assert(rgb->Alpha.Opcode == RC_OPCODE_NOP); assert(alpha->RGB.Opcode == RC_OPCODE_NOP); /* Presubtract registers need to be merged first so that registers * needed by the presubtract operation can be placed in src0 and/or * src1. */ /* Merge the rgb presubtract registers. */ if (alpha->RGB.Src[RC_PAIR_PRESUB_SRC].Used) { if (!merge_presub_sources(rgb, alpha->RGB, RC_SOURCE_RGB)) { return 0; } } /* Merge the alpha presubtract registers */ if (alpha->Alpha.Src[RC_PAIR_PRESUB_SRC].Used) { if(!merge_presub_sources(rgb, alpha->Alpha, RC_SOURCE_ALPHA)){ return 0; } } /* Copy alpha args into rgb */ opcode = rc_get_opcode_info(alpha->Alpha.Opcode); for(unsigned int arg = 0; arg < opcode->NumSrcRegs; ++arg) { unsigned int srcrgb = 0; unsigned int srcalpha = 0; unsigned int oldsrc = alpha->Alpha.Arg[arg].Source; rc_register_file file = 0; unsigned int index = 0; int source; if (GET_SWZ(alpha->Alpha.Arg[arg].Swizzle, 0) < 3) { srcrgb = 1; file = alpha->RGB.Src[oldsrc].File; index = alpha->RGB.Src[oldsrc].Index; } else if (GET_SWZ(alpha->Alpha.Arg[arg].Swizzle, 0) < 4) { srcalpha = 1; file = alpha->Alpha.Src[oldsrc].File; index = alpha->Alpha.Src[oldsrc].Index; } source = rc_pair_alloc_source(rgb, srcrgb, srcalpha, file, index); if (source < 0) return 0; rgb->Alpha.Arg[arg].Source = source; rgb->Alpha.Arg[arg].Swizzle = alpha->Alpha.Arg[arg].Swizzle; rgb->Alpha.Arg[arg].Abs = alpha->Alpha.Arg[arg].Abs; rgb->Alpha.Arg[arg].Negate = alpha->Alpha.Arg[arg].Negate; } /* Copy alpha opcode into rgb */ rgb->Alpha.Opcode = alpha->Alpha.Opcode; rgb->Alpha.DestIndex = alpha->Alpha.DestIndex; rgb->Alpha.WriteMask = alpha->Alpha.WriteMask; rgb->Alpha.OutputWriteMask = alpha->Alpha.OutputWriteMask; rgb->Alpha.DepthWriteMask = alpha->Alpha.DepthWriteMask; rgb->Alpha.Saturate = alpha->Alpha.Saturate; /* Merge ALU result writing */ if (alpha->WriteALUResult) { if (rgb->WriteALUResult) return 0; rgb->WriteALUResult = alpha->WriteALUResult; rgb->ALUResultCompare = alpha->ALUResultCompare; } return 1; } /** * Try to merge the given instructions into the rgb instructions. * * Return true on success; on failure, return false, and keep * the instructions untouched. */ static int merge_instructions(struct rc_pair_instruction * rgb, struct rc_pair_instruction * alpha) { struct rc_pair_instruction backup; /*Instructions can't write output registers and ALU result at the * same time. */ if ((rgb->WriteALUResult && alpha->Alpha.OutputWriteMask) || (rgb->RGB.OutputWriteMask && alpha->WriteALUResult)) { return 0; } memcpy(&backup, rgb, sizeof(struct rc_pair_instruction)); if (destructive_merge_instructions(rgb, alpha)) return 1; memcpy(rgb, &backup, sizeof(struct rc_pair_instruction)); return 0; } static void presub_nop(struct rc_instruction * emitted) { int prev_rgb_index, prev_alpha_index, i, num_src; /* We don't need a nop if the previous instruction is a TEX. */ if (emitted->Prev->Type != RC_INSTRUCTION_PAIR) { return; } if (emitted->Prev->U.P.RGB.WriteMask) prev_rgb_index = emitted->Prev->U.P.RGB.DestIndex; else prev_rgb_index = -1; if (emitted->Prev->U.P.Alpha.WriteMask) prev_alpha_index = emitted->Prev->U.P.Alpha.DestIndex; else prev_alpha_index = 1; /* Check the previous rgb instruction */ if (emitted->U.P.RGB.Src[RC_PAIR_PRESUB_SRC].Used) { num_src = rc_presubtract_src_reg_count( emitted->U.P.RGB.Src[RC_PAIR_PRESUB_SRC].Index); for (i = 0; i < num_src; i++) { unsigned int index = emitted->U.P.RGB.Src[i].Index; if (emitted->U.P.RGB.Src[i].File == RC_FILE_TEMPORARY && (index == prev_rgb_index || index == prev_alpha_index)) { emitted->Prev->U.P.Nop = 1; return; } } } /* Check the previous alpha instruction. */ if (!emitted->U.P.Alpha.Src[RC_PAIR_PRESUB_SRC].Used) return; num_src = rc_presubtract_src_reg_count( emitted->U.P.Alpha.Src[RC_PAIR_PRESUB_SRC].Index); for (i = 0; i < num_src; i++) { unsigned int index = emitted->U.P.Alpha.Src[i].Index; if(emitted->U.P.Alpha.Src[i].File == RC_FILE_TEMPORARY && (index == prev_rgb_index || index == prev_alpha_index)) { emitted->Prev->U.P.Nop = 1; return; } } } static void rgb_to_alpha_remap ( struct rc_instruction * inst, struct rc_pair_instruction_arg * arg, rc_register_file old_file, rc_swizzle old_swz, unsigned int new_index) { int new_src_index; unsigned int i; for (i = 0; i < 3; i++) { if (get_swz(arg->Swizzle, i) == old_swz) { SET_SWZ(arg->Swizzle, i, RC_SWIZZLE_W); } } new_src_index = rc_pair_alloc_source(&inst->U.P, 0, 1, old_file, new_index); /* This conversion is not possible, we must have made a mistake in * is_rgb_to_alpha_possible. */ if (new_src_index < 0) { assert(0); return; } arg->Source = new_src_index; } static int can_remap(unsigned int opcode) { switch(opcode) { case RC_OPCODE_DDX: case RC_OPCODE_DDY: return 0; default: return 1; } } static int can_convert_opcode_to_alpha(unsigned int opcode) { switch(opcode) { case RC_OPCODE_DDX: case RC_OPCODE_DDY: case RC_OPCODE_DP2: case RC_OPCODE_DP3: case RC_OPCODE_DP4: case RC_OPCODE_DPH: return 0; default: return 1; } } static void is_rgb_to_alpha_possible( void * userdata, struct rc_instruction * inst, struct rc_pair_instruction_arg * arg, struct rc_pair_instruction_source * src) { unsigned int chan_count = 0; unsigned int alpha_sources = 0; unsigned int i; struct rc_reader_data * reader_data = userdata; if (!can_remap(inst->U.P.RGB.Opcode) || !can_remap(inst->U.P.Alpha.Opcode)) { reader_data->Abort = 1; return; } if (!src) return; /* XXX There are some cases where we can still do the conversion if * a reader reads from a presubtract source, but for now we'll prevent * it. */ if (arg->Source == RC_PAIR_PRESUB_SRC) { reader_data->Abort = 1; return; } /* Make sure the source only reads from one component. * XXX We should allow the source to read from the same component twice. * XXX If the index we will be converting to is the same as the * current index, then it is OK to read from more than one component. */ for (i = 0; i < 3; i++) { rc_swizzle swz = get_swz(arg->Swizzle, i); switch(swz) { case RC_SWIZZLE_X: case RC_SWIZZLE_Y: case RC_SWIZZLE_Z: case RC_SWIZZLE_W: chan_count++; break; default: break; } } if (chan_count > 1) { reader_data->Abort = 1; return; } /* Make sure there are enough alpha sources. * XXX If we know what register all the readers are going * to be remapped to, then in some situations we can still do * the subsitution, even if all 3 alpha sources are being used.*/ for (i = 0; i < 3; i++) { if (inst->U.P.Alpha.Src[i].Used) { alpha_sources++; } } if (alpha_sources > 2) { reader_data->Abort = 1; return; } } static int convert_rgb_to_alpha( struct schedule_state * s, struct schedule_instruction * sched_inst) { struct rc_pair_instruction * pair_inst = &sched_inst->Instruction->U.P; unsigned int old_mask = pair_inst->RGB.WriteMask; unsigned int old_swz = rc_mask_to_swizzle(old_mask); const struct rc_opcode_info * info = rc_get_opcode_info(pair_inst->RGB.Opcode); int new_index = -1; unsigned int i; if (sched_inst->GlobalReaders.Abort) return 0; if (!pair_inst->RGB.WriteMask) return 0; if (!can_convert_opcode_to_alpha(pair_inst->RGB.Opcode) || !can_convert_opcode_to_alpha(pair_inst->Alpha.Opcode)) { return 0; } assert(sched_inst->NumWriteValues == 1); if (!sched_inst->WriteValues[0]) { assert(0); return 0; } /* We start at the old index, because if we can reuse the same * register and just change the swizzle then it is more likely we * will be able to convert all the readers. */ for (i = pair_inst->RGB.DestIndex; i < RC_REGISTER_MAX_INDEX; i++) { struct reg_value ** new_regvalp = get_reg_valuep( s, RC_FILE_TEMPORARY, i, 3); if (!*new_regvalp) { struct reg_value ** old_regvalp = get_reg_valuep(s, RC_FILE_TEMPORARY, pair_inst->RGB.DestIndex, rc_mask_to_swizzle(old_mask)); new_index = i; *new_regvalp = *old_regvalp; *old_regvalp = NULL; new_regvalp = get_reg_valuep(s, RC_FILE_TEMPORARY, i, 3); break; } } if (new_index < 0) { return 0; } pair_inst->Alpha.Opcode = pair_inst->RGB.Opcode; pair_inst->Alpha.DestIndex = new_index; pair_inst->Alpha.WriteMask = 1; pair_inst->Alpha.Target = pair_inst->RGB.Target; pair_inst->Alpha.OutputWriteMask = pair_inst->RGB.OutputWriteMask; pair_inst->Alpha.DepthWriteMask = pair_inst->RGB.DepthWriteMask; pair_inst->Alpha.Saturate = pair_inst->RGB.Saturate; memcpy(pair_inst->Alpha.Arg, pair_inst->RGB.Arg, sizeof(pair_inst->Alpha.Arg)); /* Move the swizzles into the first chan */ for (i = 0; i < info->NumSrcRegs; i++) { unsigned int j; for (j = 0; j < 3; j++) { unsigned int swz = get_swz(pair_inst->Alpha.Arg[i].Swizzle, j); if (swz != RC_SWIZZLE_UNUSED) { pair_inst->Alpha.Arg[i].Swizzle = rc_init_swizzle(swz, 1); break; } } } pair_inst->RGB.Opcode = RC_OPCODE_NOP; pair_inst->RGB.DestIndex = 0; pair_inst->RGB.WriteMask = 0; pair_inst->RGB.Target = 0; pair_inst->RGB.OutputWriteMask = 0; pair_inst->RGB.DepthWriteMask = 0; pair_inst->RGB.Saturate = 0; memset(pair_inst->RGB.Arg, 0, sizeof(pair_inst->RGB.Arg)); for(i = 0; i < sched_inst->GlobalReaders.ReaderCount; i++) { struct rc_reader reader = sched_inst->GlobalReaders.Readers[i]; rgb_to_alpha_remap(reader.Inst, reader.U.P.Arg, RC_FILE_TEMPORARY, old_swz, new_index); } return 1; } /** * Find a good ALU instruction or pair of ALU instruction and emit it. * * Prefer emitting full ALU instructions, so that when we reach a point * where no full ALU instruction can be emitted, we have more candidates * for RGB/Alpha pairing. */ static void emit_one_alu(struct schedule_state *s, struct rc_instruction * before) { struct schedule_instruction * sinst; if (s->ReadyFullALU) { sinst = s->ReadyFullALU; s->ReadyFullALU = s->ReadyFullALU->NextReady; rc_insert_instruction(before->Prev, sinst->Instruction); commit_alu_instruction(s, sinst); } else { struct schedule_instruction **prgb; struct schedule_instruction **palpha; struct schedule_instruction *prev; pair: /* Some pairings might fail because they require too * many source slots; try all possible pairings if necessary */ for(prgb = &s->ReadyRGB; *prgb; prgb = &(*prgb)->NextReady) { for(palpha = &s->ReadyAlpha; *palpha; palpha = &(*palpha)->NextReady) { struct schedule_instruction * psirgb = *prgb; struct schedule_instruction * psialpha = *palpha; if (!merge_instructions(&psirgb->Instruction->U.P, &psialpha->Instruction->U.P)) continue; *prgb = (*prgb)->NextReady; *palpha = (*palpha)->NextReady; rc_insert_instruction(before->Prev, psirgb->Instruction); commit_alu_instruction(s, psirgb); commit_alu_instruction(s, psialpha); goto success; } } prev = NULL; /* No success in pairing, now try to convert one of the RGB * instructions to an Alpha so we can pair it with another RGB. */ if (s->ReadyRGB && s->ReadyRGB->NextReady) { for(prgb = &s->ReadyRGB; *prgb; prgb = &(*prgb)->NextReady) { if ((*prgb)->NumWriteValues == 1) { struct schedule_instruction * prgb_next; if (!convert_rgb_to_alpha(s, *prgb)) goto cont_loop; prgb_next = (*prgb)->NextReady; /* Add instruction to the Alpha ready list. */ (*prgb)->NextReady = s->ReadyAlpha; s->ReadyAlpha = *prgb; /* Remove instruction from the RGB ready list.*/ if (prev) prev->NextReady = prgb_next; else s->ReadyRGB = prgb_next; goto pair; } cont_loop: prev = *prgb; } } /* Still no success in pairing, just take the first RGB * or alpha instruction. */ if (s->ReadyRGB) { sinst = s->ReadyRGB; s->ReadyRGB = s->ReadyRGB->NextReady; } else if (s->ReadyAlpha) { sinst = s->ReadyAlpha; s->ReadyAlpha = s->ReadyAlpha->NextReady; } else { /*XXX Something real bad has happened. */ assert(0); } rc_insert_instruction(before->Prev, sinst->Instruction); commit_alu_instruction(s, sinst); success: ; } /* If the instruction we just emitted uses a presubtract value, and * the presubtract sources were written by the previous intstruction, * the previous instruction needs a nop. */ presub_nop(before->Prev); } static void scan_read(void * data, struct rc_instruction * inst, rc_register_file file, unsigned int index, unsigned int chan) { struct schedule_state * s = data; struct reg_value ** v = get_reg_valuep(s, file, index, chan); struct reg_value_reader * reader; if (!v) return; if (*v && (*v)->Writer == s->Current) { /* The instruction reads and writes to a register component. * In this case, we only want to increment dependencies by one. */ return; } DBG("%i: read %i[%i] chan %i\n", s->Current->Instruction->IP, file, index, chan); reader = memory_pool_malloc(&s->C->Pool, sizeof(*reader)); reader->Reader = s->Current; if (!*v) { /* In this situation, the instruction reads from a register * that hasn't been written to or read from in the current * block. */ *v = memory_pool_malloc(&s->C->Pool, sizeof(struct reg_value)); memset(*v, 0, sizeof(struct reg_value)); (*v)->Readers = reader; } else { reader->Next = (*v)->Readers; (*v)->Readers = reader; /* Only update the current instruction's dependencies if the * register it reads from has been written to in this block. */ if ((*v)->Writer) { s->Current->NumDependencies++; } } (*v)->NumReaders++; if (s->Current->NumReadValues >= 12) { rc_error(s->C, "%s: NumReadValues overflow\n", __FUNCTION__); } else { s->Current->ReadValues[s->Current->NumReadValues++] = *v; } } static void scan_write(void * data, struct rc_instruction * inst, rc_register_file file, unsigned int index, unsigned int chan) { struct schedule_state * s = data; struct reg_value ** pv = get_reg_valuep(s, file, index, chan); struct reg_value * newv; if (!pv) return; DBG("%i: write %i[%i] chan %i\n", s->Current->Instruction->IP, file, index, chan); newv = memory_pool_malloc(&s->C->Pool, sizeof(*newv)); memset(newv, 0, sizeof(*newv)); newv->Writer = s->Current; if (*pv) { (*pv)->Next = newv; s->Current->NumDependencies++; } *pv = newv; if (s->Current->NumWriteValues >= 4) { rc_error(s->C, "%s: NumWriteValues overflow\n", __FUNCTION__); } else { s->Current->WriteValues[s->Current->NumWriteValues++] = newv; } } static void is_rgb_to_alpha_possible_normal( void * userdata, struct rc_instruction * inst, struct rc_src_register * src) { struct rc_reader_data * reader_data = userdata; reader_data->Abort = 1; } static void schedule_block(struct r300_fragment_program_compiler * c, struct rc_instruction * begin, struct rc_instruction * end) { struct schedule_state s; unsigned int ip; memset(&s, 0, sizeof(s)); s.C = &c->Base; /* Scan instructions for data dependencies */ ip = 0; for(struct rc_instruction * inst = begin; inst != end; inst = inst->Next) { s.Current = memory_pool_malloc(&c->Base.Pool, sizeof(*s.Current)); memset(s.Current, 0, sizeof(struct schedule_instruction)); s.Current->Instruction = inst; inst->IP = ip++; DBG("%i: Scanning\n", inst->IP); /* The order of things here is subtle and maybe slightly * counter-intuitive, to account for the case where an * instruction writes to the same register as it reads * from. */ rc_for_all_writes_chan(inst, &scan_write, &s); rc_for_all_reads_chan(inst, &scan_read, &s); DBG("%i: Has %i dependencies\n", inst->IP, s.Current->NumDependencies); if (!s.Current->NumDependencies) instruction_ready(&s, s.Current); /* Get global readers for possible RGB->Alpha conversion. */ s.Current->GlobalReaders.ExitOnAbort = 1; rc_get_readers(s.C, inst, &s.Current->GlobalReaders, is_rgb_to_alpha_possible_normal, is_rgb_to_alpha_possible, NULL); } /* Temporarily unlink all instructions */ begin->Prev->Next = end; end->Prev = begin->Prev; /* Schedule instructions back */ while(!s.C->Error && (s.ReadyTEX || s.ReadyRGB || s.ReadyAlpha || s.ReadyFullALU)) { if (s.ReadyTEX) emit_all_tex(&s, end); while(!s.C->Error && (s.ReadyFullALU || s.ReadyRGB || s.ReadyAlpha)) emit_one_alu(&s, end); } } static int is_controlflow(struct rc_instruction * inst) { if (inst->Type == RC_INSTRUCTION_NORMAL) { const struct rc_opcode_info * opcode = rc_get_opcode_info(inst->U.I.Opcode); return opcode->IsFlowControl; } return 0; } void rc_pair_schedule(struct radeon_compiler *cc, void *user) { struct schedule_state s; struct r300_fragment_program_compiler *c = (struct r300_fragment_program_compiler*)cc; struct rc_instruction * inst = c->Base.Program.Instructions.Next; memset(&s, 0, sizeof(s)); s.C = &c->Base; while(inst != &c->Base.Program.Instructions) { struct rc_instruction * first; if (is_controlflow(inst)) { inst = inst->Next; continue; } first = inst; while(inst != &c->Base.Program.Instructions && !is_controlflow(inst)) inst = inst->Next; DBG("Schedule one block\n"); schedule_block(c, first, inst); } }