/* * Copyright 2010 Christoph Bumiller * * 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 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 AUTHORS 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 "nv50_pc.h" #define DESCEND_ARBITRARY(j, f) \ do { \ b->pass_seq = ctx->pc->pass_seq; \ \ for (j = 0; j < 2; ++j) \ if (b->out[j] && b->out[j]->pass_seq < ctx->pc->pass_seq) \ f(ctx, b->out[j]); \ } while (0) extern unsigned nv50_inst_min_size(struct nv_instruction *); struct nv_pc_pass { struct nv_pc *pc; }; static INLINE boolean values_equal(struct nv_value *a, struct nv_value *b) { /* XXX: sizes */ return (a->reg.file == b->reg.file && a->join->reg.id == b->join->reg.id); } static INLINE boolean inst_commutation_check(struct nv_instruction *a, struct nv_instruction *b) { int si, di; for (di = 0; di < 4; ++di) { if (!a->def[di]) break; for (si = 0; si < 5; ++si) { if (!b->src[si]) continue; if (values_equal(a->def[di], b->src[si]->value)) return FALSE; } } if (b->flags_src && b->flags_src->value == a->flags_def) return FALSE; return TRUE; } /* Check whether we can swap the order of the instructions, * where a & b may be either the earlier or the later one. */ static boolean inst_commutation_legal(struct nv_instruction *a, struct nv_instruction *b) { return inst_commutation_check(a, b) && inst_commutation_check(b, a); } static INLINE boolean inst_cullable(struct nv_instruction *nvi) { if (nvi->opcode == NV_OP_STA) return FALSE; return (!(nvi->is_terminator || nvi->is_join || nvi->target || nvi->fixed || nv_nvi_refcount(nvi))); } static INLINE boolean nvi_isnop(struct nv_instruction *nvi) { if (nvi->opcode == NV_OP_EXPORT || nvi->opcode == NV_OP_UNDEF) return TRUE; /* NOTE: 'fixed' now only means that it shouldn't be optimized away, * but we can still remove it if it is a no-op move. */ if (/* nvi->fixed || */ /* nvi->flags_src || */ /* cond. MOV to same register is still NOP */ nvi->flags_def || nvi->is_terminator || nvi->is_join) return FALSE; if (nvi->def[0] && nvi->def[0]->join->reg.id < 0) return TRUE; if (nvi->opcode != NV_OP_MOV && nvi->opcode != NV_OP_SELECT) return FALSE; if (nvi->def[0]->reg.file != nvi->src[0]->value->reg.file) return FALSE; if (nvi->src[0]->value->join->reg.id < 0) { NV50_DBGMSG(PROG_IR, "nvi_isnop: orphaned value detected\n"); return TRUE; } if (nvi->opcode == NV_OP_SELECT) if (!values_equal(nvi->def[0], nvi->src[1]->value)) return FALSE; return values_equal(nvi->def[0], nvi->src[0]->value); } struct nv_pass { struct nv_pc *pc; int n; void *priv; }; static int nv_pass_flatten(struct nv_pass *ctx, struct nv_basic_block *b); static void nv_pc_pass_pre_emission(void *priv, struct nv_basic_block *b) { struct nv_pc *pc = (struct nv_pc *)priv; struct nv_basic_block *in; struct nv_instruction *nvi, *next; int j; uint size, n32 = 0; /* find first non-empty block emitted before b */ for (j = pc->num_blocks - 1; j >= 0 && !pc->bb_list[j]->bin_size; --j); for (; j >= 0; --j) { in = pc->bb_list[j]; /* check for no-op branches (BRA $PC+8) */ if (in->exit && in->exit->opcode == NV_OP_BRA && in->exit->target == b) { in->bin_size -= 8; pc->bin_size -= 8; for (++j; j < pc->num_blocks; ++j) pc->bb_list[j]->bin_pos -= 8; nv_nvi_delete(in->exit); } b->bin_pos = in->bin_pos + in->bin_size; if (in->bin_size) /* no more no-op branches to b */ break; } pc->bb_list[pc->num_blocks++] = b; /* visit node */ for (nvi = b->entry; nvi; nvi = next) { next = nvi->next; if (nvi_isnop(nvi)) nv_nvi_delete(nvi); } for (nvi = b->entry; nvi; nvi = next) { next = nvi->next; size = nv50_inst_min_size(nvi); if (nvi->next && size < 8) ++n32; else if ((n32 & 1) && nvi->next && nv50_inst_min_size(nvi->next) == 4 && inst_commutation_legal(nvi, nvi->next)) { ++n32; nv_nvi_permute(nvi, nvi->next); next = nvi; } else { nvi->is_long = 1; b->bin_size += n32 & 1; if (n32 & 1) nvi->prev->is_long = 1; n32 = 0; } b->bin_size += 1 + nvi->is_long; } if (!b->entry) { NV50_DBGMSG(PROG_IR, "block %p is now empty\n", b); } else if (!b->exit->is_long) { assert(n32); b->exit->is_long = 1; b->bin_size += 1; /* might have del'd a hole tail of instructions */ if (!b->exit->prev->is_long && !(n32 & 1)) { b->bin_size += 1; b->exit->prev->is_long = 1; } } assert(!b->entry || (b->exit && b->exit->is_long)); pc->bin_size += b->bin_size *= 4; } static int nv_pc_pass2(struct nv_pc *pc, struct nv_basic_block *root) { struct nv_pass pass; pass.pc = pc; pc->pass_seq++; nv_pass_flatten(&pass, root); nv_pc_pass_in_order(root, nv_pc_pass_pre_emission, pc); return 0; } int nv_pc_exec_pass2(struct nv_pc *pc) { int i, ret; NV50_DBGMSG(PROG_IR, "preparing %u blocks for emission\n", pc->num_blocks); pc->num_blocks = 0; /* will reorder bb_list */ for (i = 0; i < pc->num_subroutines + 1; ++i) if (pc->root[i] && (ret = nv_pc_pass2(pc, pc->root[i]))) return ret; return 0; } static INLINE boolean is_cmem_load(struct nv_instruction *nvi) { return (nvi->opcode == NV_OP_LDA && nvi->src[0]->value->reg.file >= NV_FILE_MEM_C(0) && nvi->src[0]->value->reg.file <= NV_FILE_MEM_C(15)); } static INLINE boolean is_smem_load(struct nv_instruction *nvi) { return (nvi->opcode == NV_OP_LDA && (nvi->src[0]->value->reg.file == NV_FILE_MEM_S || nvi->src[0]->value->reg.file <= NV_FILE_MEM_P)); } static INLINE boolean is_immd_move(struct nv_instruction *nvi) { return (nvi->opcode == NV_OP_MOV && nvi->src[0]->value->reg.file == NV_FILE_IMM); } static INLINE void check_swap_src_0_1(struct nv_instruction *nvi) { static const ubyte cc_swapped[8] = { 0, 4, 2, 6, 1, 5, 3, 7 }; struct nv_ref *src0 = nvi->src[0], *src1 = nvi->src[1]; if (!nv_op_commutative(nvi->opcode)) return; assert(src0 && src1); if (src1->value->reg.file == NV_FILE_IMM) return; if (is_cmem_load(src0->value->insn)) { if (!is_cmem_load(src1->value->insn)) { nvi->src[0] = src1; nvi->src[1] = src0; /* debug_printf("swapping cmem load to 1\n"); */ } } else if (is_smem_load(src1->value->insn)) { if (!is_smem_load(src0->value->insn)) { nvi->src[0] = src1; nvi->src[1] = src0; /* debug_printf("swapping smem load to 0\n"); */ } } if (nvi->opcode == NV_OP_SET && nvi->src[0] != src0) nvi->set_cond = (nvi->set_cond & ~7) | cc_swapped[nvi->set_cond & 7]; } static int nv_pass_fold_stores(struct nv_pass *ctx, struct nv_basic_block *b) { struct nv_instruction *nvi, *sti, *next; int j; for (sti = b->entry; sti; sti = next) { next = sti->next; /* only handling MOV to $oX here */ if (!sti->def[0] || sti->def[0]->reg.file != NV_FILE_OUT) continue; if (sti->opcode != NV_OP_MOV && sti->opcode != NV_OP_STA) continue; nvi = sti->src[0]->value->insn; if (!nvi || nvi->opcode == NV_OP_PHI || nv_is_vector_op(nvi->opcode)) continue; assert(nvi->def[0] == sti->src[0]->value); if (nvi->opcode == NV_OP_SELECT) continue; if (nvi->def[0]->refc > 1) continue; /* cannot write to $oX when using immediate */ for (j = 0; j < 4 && nvi->src[j]; ++j) if (nvi->src[j]->value->reg.file == NV_FILE_IMM || nvi->src[j]->value->reg.file == NV_FILE_MEM_L) break; if (j < 4 && nvi->src[j]) continue; nvi->def[0] = sti->def[0]; nvi->def[0]->insn = nvi; nvi->fixed = sti->fixed; nv_nvi_delete(sti); } DESCEND_ARBITRARY(j, nv_pass_fold_stores); return 0; } static int nv_pass_fold_loads(struct nv_pass *ctx, struct nv_basic_block *b) { struct nv_instruction *nvi, *ld; int j; for (nvi = b->entry; nvi; nvi = nvi->next) { check_swap_src_0_1(nvi); for (j = 0; j < 3; ++j) { if (!nvi->src[j]) break; ld = nvi->src[j]->value->insn; if (!ld) continue; if (is_immd_move(ld) && nv50_nvi_can_use_imm(nvi, j)) { nv_reference(ctx->pc, &nvi->src[j], ld->src[0]->value); continue; } if (ld->opcode != NV_OP_LDA) continue; if (!nv50_nvi_can_load(nvi, j, ld->src[0]->value)) continue; if (j == 0 && ld->src[4]) /* can't load shared mem */ continue; /* fold it ! */ nv_reference(ctx->pc, &nvi->src[j], ld->src[0]->value); if (ld->src[4]) nv_reference(ctx->pc, &nvi->src[4], ld->src[4]->value); if (!nv_nvi_refcount(ld)) nv_nvi_delete(ld); } } DESCEND_ARBITRARY(j, nv_pass_fold_loads); return 0; } /* NOTE: Assumes loads have not yet been folded. */ static int nv_pass_lower_mods(struct nv_pass *ctx, struct nv_basic_block *b) { int j; struct nv_instruction *nvi, *mi, *next; ubyte mod; for (nvi = b->entry; nvi; nvi = next) { next = nvi->next; if (nvi->opcode == NV_OP_SUB) { nvi->opcode = NV_OP_ADD; nvi->src[1]->mod ^= NV_MOD_NEG; } for (j = 0; j < 4 && nvi->src[j]; ++j) { mi = nvi->src[j]->value->insn; if (!mi) continue; if (mi->def[0]->refc > 1) continue; if (mi->opcode == NV_OP_NEG) mod = NV_MOD_NEG; else if (mi->opcode == NV_OP_ABS) mod = NV_MOD_ABS; else continue; assert(!(mod & mi->src[0]->mod & NV_MOD_NEG)); mod |= mi->src[0]->mod; if (mi->flags_def || mi->flags_src) continue; if ((nvi->opcode == NV_OP_ABS) || (nvi->src[j]->mod & NV_MOD_ABS)) { /* abs neg [abs] = abs */ mod &= ~(NV_MOD_NEG | NV_MOD_ABS); } else if ((nvi->opcode == NV_OP_NEG) && (mod & NV_MOD_NEG)) { /* neg as opcode and modifier on same insn cannot occur */ /* neg neg abs = abs, neg neg = identity */ assert(j == 0); if (mod & NV_MOD_ABS) nvi->opcode = NV_OP_ABS; else if (nvi->flags_def) nvi->opcode = NV_OP_CVT; else nvi->opcode = NV_OP_MOV; mod = 0; } if ((nv50_supported_src_mods(nvi->opcode, j) & mod) != mod) continue; nv_reference(ctx->pc, &nvi->src[j], mi->src[0]->value); nvi->src[j]->mod ^= mod; } if (nvi->opcode == NV_OP_SAT) { mi = nvi->src[0]->value->insn; if (mi->opcode != NV_OP_ADD && mi->opcode != NV_OP_MAD) continue; if (mi->flags_def || mi->def[0]->refc > 1) continue; mi->saturate = 1; mi->def[0] = nvi->def[0]; mi->def[0]->insn = mi; nv_nvi_delete(nvi); } } DESCEND_ARBITRARY(j, nv_pass_lower_mods); return 0; } #define SRC_IS_MUL(s) ((s)->insn && (s)->insn->opcode == NV_OP_MUL) static void modifiers_apply(uint32_t *val, ubyte type, ubyte mod) { if (mod & NV_MOD_ABS) { if (type == NV_TYPE_F32) *val &= 0x7fffffff; else if ((*val) & (1 << 31)) *val = ~(*val) + 1; } if (mod & NV_MOD_NEG) { if (type == NV_TYPE_F32) *val ^= 0x80000000; else *val = ~(*val) + 1; } } static INLINE uint modifiers_opcode(ubyte mod) { switch (mod) { case NV_MOD_NEG: return NV_OP_NEG; case NV_MOD_ABS: return NV_OP_ABS; case 0: return NV_OP_MOV; default: return NV_OP_NOP; } } static void constant_expression(struct nv_pc *pc, struct nv_instruction *nvi, struct nv_value *src0, struct nv_value *src1) { struct nv_value *val; union { float f32; uint32_t u32; int32_t s32; } u0, u1, u; ubyte type; if (!nvi->def[0]) return; type = nvi->def[0]->reg.type; u.u32 = 0; u0.u32 = src0->reg.imm.u32; u1.u32 = src1->reg.imm.u32; modifiers_apply(&u0.u32, type, nvi->src[0]->mod); modifiers_apply(&u1.u32, type, nvi->src[1]->mod); switch (nvi->opcode) { case NV_OP_MAD: if (nvi->src[2]->value->reg.file != NV_FILE_GPR) return; /* fall through */ case NV_OP_MUL: switch (type) { case NV_TYPE_F32: u.f32 = u0.f32 * u1.f32; break; case NV_TYPE_U32: u.u32 = u0.u32 * u1.u32; break; case NV_TYPE_S32: u.s32 = u0.s32 * u1.s32; break; default: assert(0); break; } break; case NV_OP_ADD: switch (type) { case NV_TYPE_F32: u.f32 = u0.f32 + u1.f32; break; case NV_TYPE_U32: u.u32 = u0.u32 + u1.u32; break; case NV_TYPE_S32: u.s32 = u0.s32 + u1.s32; break; default: assert(0); break; } break; case NV_OP_SUB: switch (type) { case NV_TYPE_F32: u.f32 = u0.f32 - u1.f32; break; case NV_TYPE_U32: u.u32 = u0.u32 - u1.u32; break; case NV_TYPE_S32: u.s32 = u0.s32 - u1.s32; break; default: assert(0); break; } break; default: return; } nvi->opcode = NV_OP_MOV; val = new_value(pc, NV_FILE_IMM, type); val->reg.imm.u32 = u.u32; nv_reference(pc, &nvi->src[1], NULL); nv_reference(pc, &nvi->src[0], val); if (nvi->src[2]) { /* from MAD */ nvi->src[1] = nvi->src[0]; nvi->src[0] = nvi->src[2]; nvi->src[2] = NULL; nvi->opcode = NV_OP_ADD; if (val->reg.imm.u32 == 0) { nvi->src[1] = NULL; nvi->opcode = NV_OP_MOV; } } } static void constant_operand(struct nv_pc *pc, struct nv_instruction *nvi, struct nv_value *val, int s) { union { float f32; uint32_t u32; int32_t s32; } u; int t = s ? 0 : 1; uint op; ubyte type; if (!nvi->def[0]) return; type = nvi->def[0]->reg.type; u.u32 = val->reg.imm.u32; modifiers_apply(&u.u32, type, nvi->src[s]->mod); switch (nvi->opcode) { case NV_OP_MUL: if ((type == NV_TYPE_F32 && u.f32 == 1.0f) || (NV_TYPE_ISINT(type) && u.u32 == 1)) { if ((op = modifiers_opcode(nvi->src[t]->mod)) == NV_OP_NOP) break; nvi->opcode = op; nv_reference(pc, &nvi->src[s], NULL); nvi->src[0] = nvi->src[t]; nvi->src[1] = NULL; } else if ((type == NV_TYPE_F32 && u.f32 == 2.0f) || (NV_TYPE_ISINT(type) && u.u32 == 2)) { nvi->opcode = NV_OP_ADD; nv_reference(pc, &nvi->src[s], nvi->src[t]->value); nvi->src[s]->mod = nvi->src[t]->mod; } else if (type == NV_TYPE_F32 && u.f32 == -1.0f) { if (nvi->src[t]->mod & NV_MOD_NEG) nvi->opcode = NV_OP_MOV; else nvi->opcode = NV_OP_NEG; nv_reference(pc, &nvi->src[s], NULL); nvi->src[0] = nvi->src[t]; nvi->src[1] = NULL; } else if (type == NV_TYPE_F32 && u.f32 == -2.0f) { nvi->opcode = NV_OP_ADD; nv_reference(pc, &nvi->src[s], nvi->src[t]->value); nvi->src[s]->mod = (nvi->src[t]->mod ^= NV_MOD_NEG); } else if (u.u32 == 0) { nvi->opcode = NV_OP_MOV; nv_reference(pc, &nvi->src[t], NULL); if (s) { nvi->src[0] = nvi->src[1]; nvi->src[1] = NULL; } } break; case NV_OP_ADD: if (u.u32 == 0) { if ((op = modifiers_opcode(nvi->src[t]->mod)) == NV_OP_NOP) break; nvi->opcode = op; nv_reference(pc, &nvi->src[s], NULL); nvi->src[0] = nvi->src[t]; nvi->src[1] = NULL; } break; case NV_OP_RCP: u.f32 = 1.0f / u.f32; (val = new_value(pc, NV_FILE_IMM, NV_TYPE_F32))->reg.imm.f32 = u.f32; nvi->opcode = NV_OP_MOV; assert(s == 0); nv_reference(pc, &nvi->src[0], val); break; case NV_OP_RSQ: u.f32 = 1.0f / sqrtf(u.f32); (val = new_value(pc, NV_FILE_IMM, NV_TYPE_F32))->reg.imm.f32 = u.f32; nvi->opcode = NV_OP_MOV; assert(s == 0); nv_reference(pc, &nvi->src[0], val); break; default: break; } if (nvi->opcode == NV_OP_MOV && nvi->flags_def) { struct nv_instruction *cvt = new_instruction_at(pc, nvi, NV_OP_CVT); nv_reference(pc, &cvt->src[0], nvi->def[0]); cvt->flags_def = nvi->flags_def; nvi->flags_def = NULL; } } static int nv_pass_lower_arith(struct nv_pass *ctx, struct nv_basic_block *b) { struct nv_instruction *nvi, *next; int j; for (nvi = b->entry; nvi; nvi = next) { struct nv_value *src0, *src1, *src; int mod; next = nvi->next; src0 = nvcg_find_immediate(nvi->src[0]); src1 = nvcg_find_immediate(nvi->src[1]); if (src0 && src1) constant_expression(ctx->pc, nvi, src0, src1); else { if (src0) constant_operand(ctx->pc, nvi, src0, 0); else if (src1) constant_operand(ctx->pc, nvi, src1, 1); } /* try to combine MUL, ADD into MAD */ if (nvi->opcode != NV_OP_ADD) continue; src0 = nvi->src[0]->value; src1 = nvi->src[1]->value; if (SRC_IS_MUL(src0) && src0->refc == 1) src = src0; else if (SRC_IS_MUL(src1) && src1->refc == 1) src = src1; else continue; /* could have an immediate from above constant_* */ if (src0->reg.file != NV_FILE_GPR || src1->reg.file != NV_FILE_GPR) continue; nvi->opcode = NV_OP_MAD; mod = nvi->src[(src == src0) ? 0 : 1]->mod; nv_reference(ctx->pc, &nvi->src[(src == src0) ? 0 : 1], NULL); nvi->src[2] = nvi->src[(src == src0) ? 1 : 0]; assert(!(mod & ~NV_MOD_NEG)); nvi->src[0] = new_ref(ctx->pc, src->insn->src[0]->value); nvi->src[1] = new_ref(ctx->pc, src->insn->src[1]->value); nvi->src[0]->mod = src->insn->src[0]->mod ^ mod; nvi->src[1]->mod = src->insn->src[1]->mod; } DESCEND_ARBITRARY(j, nv_pass_lower_arith); return 0; } /* TODO: redundant store elimination */ struct load_record { struct load_record *next; uint64_t data[2]; struct nv_value *value; }; #define LOAD_RECORD_POOL_SIZE 1024 struct nv_pass_reld_elim { struct nv_pc *pc; struct load_record *imm; struct load_record *mem_s; struct load_record *mem_v; struct load_record *mem_c[16]; struct load_record *mem_l; struct load_record pool[LOAD_RECORD_POOL_SIZE]; int alloc; }; /* TODO: properly handle loads from l[] memory in the presence of stores */ static int nv_pass_reload_elim(struct nv_pass_reld_elim *ctx, struct nv_basic_block *b) { struct load_record **rec, *it; struct nv_instruction *ld, *next; uint64_t data[2]; struct nv_value *val; int j; for (ld = b->entry; ld; ld = next) { next = ld->next; if (!ld->src[0]) continue; val = ld->src[0]->value; rec = NULL; if (ld->opcode == NV_OP_LINTERP || ld->opcode == NV_OP_PINTERP) { data[0] = val->reg.id; data[1] = 0; rec = &ctx->mem_v; } else if (ld->opcode == NV_OP_LDA) { data[0] = val->reg.id; data[1] = ld->src[4] ? ld->src[4]->value->n : ~0ULL; if (val->reg.file >= NV_FILE_MEM_C(0) && val->reg.file <= NV_FILE_MEM_C(15)) rec = &ctx->mem_c[val->reg.file - NV_FILE_MEM_C(0)]; else if (val->reg.file == NV_FILE_MEM_S) rec = &ctx->mem_s; else if (val->reg.file == NV_FILE_MEM_L) rec = &ctx->mem_l; } else if ((ld->opcode == NV_OP_MOV) && (val->reg.file == NV_FILE_IMM)) { data[0] = val->reg.imm.u32; data[1] = 0; rec = &ctx->imm; } if (!rec || !ld->def[0]->refc) continue; for (it = *rec; it; it = it->next) if (it->data[0] == data[0] && it->data[1] == data[1]) break; if (it) { if (ld->def[0]->reg.id >= 0) it->value = ld->def[0]; else if (!ld->fixed) nvcg_replace_value(ctx->pc, ld->def[0], it->value); } else { if (ctx->alloc == LOAD_RECORD_POOL_SIZE) continue; it = &ctx->pool[ctx->alloc++]; it->next = *rec; it->data[0] = data[0]; it->data[1] = data[1]; it->value = ld->def[0]; *rec = it; } } ctx->imm = NULL; ctx->mem_s = NULL; ctx->mem_v = NULL; for (j = 0; j < 16; ++j) ctx->mem_c[j] = NULL; ctx->mem_l = NULL; ctx->alloc = 0; DESCEND_ARBITRARY(j, nv_pass_reload_elim); return 0; } static int nv_pass_tex_mask(struct nv_pass *ctx, struct nv_basic_block *b) { int i, c, j; for (i = 0; i < ctx->pc->num_instructions; ++i) { struct nv_instruction *nvi = &ctx->pc->instructions[i]; struct nv_value *def[4]; if (!nv_is_vector_op(nvi->opcode)) continue; nvi->tex_mask = 0; for (c = 0; c < 4; ++c) { if (nvi->def[c]->refc) nvi->tex_mask |= 1 << c; def[c] = nvi->def[c]; } j = 0; for (c = 0; c < 4; ++c) if (nvi->tex_mask & (1 << c)) nvi->def[j++] = def[c]; for (c = 0; c < 4; ++c) if (!(nvi->tex_mask & (1 << c))) nvi->def[j++] = def[c]; assert(j == 4); } return 0; } struct nv_pass_dce { struct nv_pc *pc; uint removed; }; static int nv_pass_dce(struct nv_pass_dce *ctx, struct nv_basic_block *b) { int j; struct nv_instruction *nvi, *next; for (nvi = b->phi ? b->phi : b->entry; nvi; nvi = next) { next = nvi->next; if (inst_cullable(nvi)) { nv_nvi_delete(nvi); ++ctx->removed; } } DESCEND_ARBITRARY(j, nv_pass_dce); return 0; } /* Register allocation inserted ELSE blocks for all IF/ENDIF without ELSE. * Returns TRUE if @bb initiates an IF/ELSE/ENDIF clause, or is an IF with * BREAK and dummy ELSE block. */ static INLINE boolean bb_is_if_else_endif(struct nv_basic_block *bb) { if (!bb->out[0] || !bb->out[1]) return FALSE; if (bb->out[0]->out_kind[0] == CFG_EDGE_LOOP_LEAVE) { return (bb->out[0]->out[1] == bb->out[1]->out[0] && !bb->out[1]->out[1]); } else { return (bb->out[0]->out[0] == bb->out[1]->out[0] && !bb->out[0]->out[1] && !bb->out[1]->out[1]); } } /* predicate instructions and remove branch at the end */ static void predicate_instructions(struct nv_pc *pc, struct nv_basic_block *b, struct nv_value *p, ubyte cc) { struct nv_instruction *nvi; if (!b->entry) return; for (nvi = b->entry; nvi->next; nvi = nvi->next) { if (!nvi_isnop(nvi)) { nvi->cc = cc; nv_reference(pc, &nvi->flags_src, p); } } if (nvi->opcode == NV_OP_BRA) nv_nvi_delete(nvi); else if (!nvi_isnop(nvi)) { nvi->cc = cc; nv_reference(pc, &nvi->flags_src, p); } } /* NOTE: Run this after register allocation, we can just cut out the cflow * instructions and hook the predicates to the conditional OPs if they are * not using immediates; better than inserting SELECT to join definitions. * * NOTE: Should adapt prior optimization to make this possible more often. */ static int nv_pass_flatten(struct nv_pass *ctx, struct nv_basic_block *b) { struct nv_instruction *nvi; struct nv_value *pred; int i; int n0 = 0, n1 = 0; if (bb_is_if_else_endif(b)) { NV50_DBGMSG(PROG_IR, "pass_flatten: IF/ELSE/ENDIF construct at BB:%i\n", b->id); for (n0 = 0, nvi = b->out[0]->entry; nvi; nvi = nvi->next, ++n0) if (!nv50_nvi_can_predicate(nvi)) break; if (!nvi) { for (n1 = 0, nvi = b->out[1]->entry; nvi; nvi = nvi->next, ++n1) if (!nv50_nvi_can_predicate(nvi)) break; #if NV50_DEBUG & NV50_DEBUG_PROG_IR if (nvi) { debug_printf("cannot predicate: "); nv_print_instruction(nvi); } } else { debug_printf("cannot predicate: "); nv_print_instruction(nvi); #endif } if (!nvi && n0 < 12 && n1 < 12) { /* 12 as arbitrary limit */ assert(b->exit && b->exit->flags_src); pred = b->exit->flags_src->value; predicate_instructions(ctx->pc, b->out[0], pred, NV_CC_NE | NV_CC_U); predicate_instructions(ctx->pc, b->out[1], pred, NV_CC_EQ); assert(b->exit && b->exit->opcode == NV_OP_BRA); nv_nvi_delete(b->exit); if (b->exit && b->exit->opcode == NV_OP_JOINAT) nv_nvi_delete(b->exit); i = (b->out[0]->out_kind[0] == CFG_EDGE_LOOP_LEAVE) ? 1 : 0; if ((nvi = b->out[0]->out[i]->entry)) { nvi->is_join = 0; if (nvi->opcode == NV_OP_JOIN) nv_nvi_delete(nvi); } } } DESCEND_ARBITRARY(i, nv_pass_flatten); return 0; } /* local common subexpression elimination, stupid O(n^2) implementation */ static int nv_pass_cse(struct nv_pass *ctx, struct nv_basic_block *b) { struct nv_instruction *ir, *ik, *next; struct nv_instruction *entry = b->phi ? b->phi : b->entry; int s; unsigned int reps; do { reps = 0; for (ir = entry; ir; ir = next) { next = ir->next; for (ik = entry; ik != ir; ik = ik->next) { if (ir->opcode != ik->opcode || ir->fixed) continue; if (!ir->def[0] || !ik->def[0] || ik->opcode == NV_OP_LDA || ik->opcode == NV_OP_STA || ik->opcode == NV_OP_MOV || nv_is_vector_op(ik->opcode)) continue; /* ignore loads, stores & moves */ if (ik->src[4] || ir->src[4]) continue; /* don't mess with address registers */ if (ik->flags_src || ir->flags_src || ik->flags_def || ir->flags_def) continue; /* and also not with flags, for now */ if (ik->def[0]->reg.file == NV_FILE_OUT || ir->def[0]->reg.file == NV_FILE_OUT || !values_equal(ik->def[0], ir->def[0])) continue; for (s = 0; s < 3; ++s) { struct nv_value *a, *b; if (!ik->src[s]) { if (ir->src[s]) break; continue; } if (ik->src[s]->mod != ir->src[s]->mod) break; a = ik->src[s]->value; b = ir->src[s]->value; if (a == b) continue; if (a->reg.file != b->reg.file || a->reg.id < 0 || a->reg.id != b->reg.id) break; } if (s == 3) { nv_nvi_delete(ir); ++reps; nvcg_replace_value(ctx->pc, ir->def[0], ik->def[0]); break; } } } } while(reps); DESCEND_ARBITRARY(s, nv_pass_cse); return 0; } static int nv_pc_pass0(struct nv_pc *pc, struct nv_basic_block *root) { struct nv_pass_reld_elim *reldelim; struct nv_pass pass; struct nv_pass_dce dce; int ret; pass.n = 0; pass.pc = pc; /* Do this first, so we don't have to pay attention * to whether sources are supported memory loads. */ pc->pass_seq++; ret = nv_pass_lower_arith(&pass, root); if (ret) return ret; pc->pass_seq++; ret = nv_pass_lower_mods(&pass, root); if (ret) return ret; pc->pass_seq++; ret = nv_pass_fold_loads(&pass, root); if (ret) return ret; pc->pass_seq++; ret = nv_pass_fold_stores(&pass, root); if (ret) return ret; if (pc->opt_reload_elim) { reldelim = CALLOC_STRUCT(nv_pass_reld_elim); reldelim->pc = pc; pc->pass_seq++; ret = nv_pass_reload_elim(reldelim, root); FREE(reldelim); if (ret) return ret; } pc->pass_seq++; ret = nv_pass_cse(&pass, root); if (ret) return ret; dce.pc = pc; do { dce.removed = 0; pc->pass_seq++; ret = nv_pass_dce(&dce, root); if (ret) return ret; } while (dce.removed); ret = nv_pass_tex_mask(&pass, root); if (ret) return ret; return ret; } int nv_pc_exec_pass0(struct nv_pc *pc) { int i, ret; for (i = 0; i < pc->num_subroutines + 1; ++i) if (pc->root[i] && (ret = nv_pc_pass0(pc, pc->root[i]))) return ret; return 0; }