/* * Copyright © 2014 Connor Abbott * * 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 AUTHORS OR COPYRIGHT HOLDERS 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 "nir_instr_set.h" #include "nir_vla.h" #include "util/half_float.h" static bool src_is_ssa(nir_src *src, void *data) { (void) data; return src->is_ssa; } static bool dest_is_ssa(nir_dest *dest, void *data) { (void) data; return dest->is_ssa; } static inline bool instr_each_src_and_dest_is_ssa(const nir_instr *instr) { if (!nir_foreach_dest((nir_instr *)instr, dest_is_ssa, NULL) || !nir_foreach_src((nir_instr *)instr, src_is_ssa, NULL)) return false; return true; } /* This function determines if uses of an instruction can safely be rewritten * to use another identical instruction instead. Note that this function must * be kept in sync with hash_instr() and nir_instrs_equal() -- only * instructions that pass this test will be handed on to those functions, and * conversely they must handle everything that this function returns true for. */ static bool instr_can_rewrite(const nir_instr *instr) { /* We only handle SSA. */ assert(instr_each_src_and_dest_is_ssa(instr)); switch (instr->type) { case nir_instr_type_alu: case nir_instr_type_deref: case nir_instr_type_tex: case nir_instr_type_load_const: case nir_instr_type_phi: return true; case nir_instr_type_intrinsic: return nir_intrinsic_can_reorder(nir_instr_as_intrinsic(instr)); case nir_instr_type_call: case nir_instr_type_jump: case nir_instr_type_ssa_undef: return false; case nir_instr_type_parallel_copy: default: unreachable("Invalid instruction type"); } return false; } #define HASH(hash, data) _mesa_fnv32_1a_accumulate((hash), (data)) static uint32_t hash_src(uint32_t hash, const nir_src *src) { assert(src->is_ssa); hash = HASH(hash, src->ssa); return hash; } static uint32_t hash_alu_src(uint32_t hash, const nir_alu_src *src, unsigned num_components) { hash = HASH(hash, src->abs); hash = HASH(hash, src->negate); for (unsigned i = 0; i < num_components; i++) hash = HASH(hash, src->swizzle[i]); hash = hash_src(hash, &src->src); return hash; } static uint32_t hash_alu(uint32_t hash, const nir_alu_instr *instr) { hash = HASH(hash, instr->op); /* We explicitly don't hash instr->exact. */ uint8_t flags = instr->no_signed_wrap | instr->no_unsigned_wrap << 1; hash = HASH(hash, flags); hash = HASH(hash, instr->dest.dest.ssa.num_components); hash = HASH(hash, instr->dest.dest.ssa.bit_size); if (nir_op_infos[instr->op].algebraic_properties & NIR_OP_IS_2SRC_COMMUTATIVE) { assert(nir_op_infos[instr->op].num_inputs >= 2); uint32_t hash0 = hash_alu_src(hash, &instr->src[0], nir_ssa_alu_instr_src_components(instr, 0)); uint32_t hash1 = hash_alu_src(hash, &instr->src[1], nir_ssa_alu_instr_src_components(instr, 1)); /* For commutative operations, we need some commutative way of * combining the hashes. One option would be to XOR them but that * means that anything with two identical sources will hash to 0 and * that's common enough we probably don't want the guaranteed * collision. Either addition or multiplication will also work. */ hash = hash0 * hash1; for (unsigned i = 2; i < nir_op_infos[instr->op].num_inputs; i++) { hash = hash_alu_src(hash, &instr->src[i], nir_ssa_alu_instr_src_components(instr, i)); } } else { for (unsigned i = 0; i < nir_op_infos[instr->op].num_inputs; i++) { hash = hash_alu_src(hash, &instr->src[i], nir_ssa_alu_instr_src_components(instr, i)); } } return hash; } static uint32_t hash_deref(uint32_t hash, const nir_deref_instr *instr) { hash = HASH(hash, instr->deref_type); hash = HASH(hash, instr->mode); hash = HASH(hash, instr->type); if (instr->deref_type == nir_deref_type_var) return HASH(hash, instr->var); hash = hash_src(hash, &instr->parent); switch (instr->deref_type) { case nir_deref_type_struct: hash = HASH(hash, instr->strct.index); break; case nir_deref_type_array: case nir_deref_type_ptr_as_array: hash = hash_src(hash, &instr->arr.index); break; case nir_deref_type_cast: hash = HASH(hash, instr->cast.ptr_stride); break; case nir_deref_type_var: case nir_deref_type_array_wildcard: /* Nothing to do */ break; default: unreachable("Invalid instruction deref type"); } return hash; } static uint32_t hash_load_const(uint32_t hash, const nir_load_const_instr *instr) { hash = HASH(hash, instr->def.num_components); if (instr->def.bit_size == 1) { for (unsigned i = 0; i < instr->def.num_components; i++) { uint8_t b = instr->value[i].b; hash = HASH(hash, b); } } else { unsigned size = instr->def.num_components * sizeof(*instr->value); hash = _mesa_fnv32_1a_accumulate_block(hash, instr->value, size); } return hash; } static int cmp_phi_src(const void *data1, const void *data2) { nir_phi_src *src1 = *(nir_phi_src **)data1; nir_phi_src *src2 = *(nir_phi_src **)data2; return src1->pred - src2->pred; } static uint32_t hash_phi(uint32_t hash, const nir_phi_instr *instr) { hash = HASH(hash, instr->instr.block); /* sort sources by predecessor, since the order shouldn't matter */ unsigned num_preds = instr->instr.block->predecessors->entries; NIR_VLA(nir_phi_src *, srcs, num_preds); unsigned i = 0; nir_foreach_phi_src(src, instr) { srcs[i++] = src; } qsort(srcs, num_preds, sizeof(nir_phi_src *), cmp_phi_src); for (i = 0; i < num_preds; i++) { hash = hash_src(hash, &srcs[i]->src); hash = HASH(hash, srcs[i]->pred); } return hash; } static uint32_t hash_intrinsic(uint32_t hash, const nir_intrinsic_instr *instr) { const nir_intrinsic_info *info = &nir_intrinsic_infos[instr->intrinsic]; hash = HASH(hash, instr->intrinsic); if (info->has_dest) { hash = HASH(hash, instr->dest.ssa.num_components); hash = HASH(hash, instr->dest.ssa.bit_size); } hash = _mesa_fnv32_1a_accumulate_block(hash, instr->const_index, info->num_indices * sizeof(instr->const_index[0])); return hash; } static uint32_t hash_tex(uint32_t hash, const nir_tex_instr *instr) { hash = HASH(hash, instr->op); hash = HASH(hash, instr->num_srcs); for (unsigned i = 0; i < instr->num_srcs; i++) { hash = HASH(hash, instr->src[i].src_type); hash = hash_src(hash, &instr->src[i].src); } hash = HASH(hash, instr->coord_components); hash = HASH(hash, instr->sampler_dim); hash = HASH(hash, instr->is_array); hash = HASH(hash, instr->is_shadow); hash = HASH(hash, instr->is_new_style_shadow); unsigned component = instr->component; hash = HASH(hash, component); for (unsigned i = 0; i < 4; ++i) for (unsigned j = 0; j < 2; ++j) hash = HASH(hash, instr->tg4_offsets[i][j]); hash = HASH(hash, instr->texture_index); hash = HASH(hash, instr->texture_array_size); hash = HASH(hash, instr->sampler_index); return hash; } /* Computes a hash of an instruction for use in a hash table. Note that this * will only work for instructions where instr_can_rewrite() returns true, and * it should return identical hashes for two instructions that are the same * according nir_instrs_equal(). */ static uint32_t hash_instr(const void *data) { const nir_instr *instr = data; uint32_t hash = _mesa_fnv32_1a_offset_bias; switch (instr->type) { case nir_instr_type_alu: hash = hash_alu(hash, nir_instr_as_alu(instr)); break; case nir_instr_type_deref: hash = hash_deref(hash, nir_instr_as_deref(instr)); break; case nir_instr_type_load_const: hash = hash_load_const(hash, nir_instr_as_load_const(instr)); break; case nir_instr_type_phi: hash = hash_phi(hash, nir_instr_as_phi(instr)); break; case nir_instr_type_intrinsic: hash = hash_intrinsic(hash, nir_instr_as_intrinsic(instr)); break; case nir_instr_type_tex: hash = hash_tex(hash, nir_instr_as_tex(instr)); break; default: unreachable("Invalid instruction type"); } return hash; } bool nir_srcs_equal(nir_src src1, nir_src src2) { if (src1.is_ssa) { if (src2.is_ssa) { return src1.ssa == src2.ssa; } else { return false; } } else { if (src2.is_ssa) { return false; } else { if ((src1.reg.indirect == NULL) != (src2.reg.indirect == NULL)) return false; if (src1.reg.indirect) { if (!nir_srcs_equal(*src1.reg.indirect, *src2.reg.indirect)) return false; } return src1.reg.reg == src2.reg.reg && src1.reg.base_offset == src2.reg.base_offset; } } } /** * If the \p s is an SSA value that was generated by a negation instruction, * that instruction is returned as a \c nir_alu_instr. Otherwise \c NULL is * returned. */ static nir_alu_instr * get_neg_instr(nir_src s) { nir_alu_instr *alu = nir_src_as_alu_instr(s); return alu != NULL && (alu->op == nir_op_fneg || alu->op == nir_op_ineg) ? alu : NULL; } bool nir_const_value_negative_equal(nir_const_value c1, nir_const_value c2, nir_alu_type full_type) { assert(nir_alu_type_get_base_type(full_type) != nir_type_invalid); assert(nir_alu_type_get_type_size(full_type) != 0); switch (full_type) { case nir_type_float16: return _mesa_half_to_float(c1.u16) == -_mesa_half_to_float(c2.u16); case nir_type_float32: return c1.f32 == -c2.f32; case nir_type_float64: return c1.f64 == -c2.f64; case nir_type_int8: case nir_type_uint8: return c1.i8 == -c2.i8; case nir_type_int16: case nir_type_uint16: return c1.i16 == -c2.i16; case nir_type_int32: case nir_type_uint32: return c1.i32 == -c2.i32; case nir_type_int64: case nir_type_uint64: return c1.i64 == -c2.i64; default: break; } return false; } /** * Shallow compare of ALU srcs to determine if one is the negation of the other * * This function detects cases where \p alu1 is a constant and \p alu2 is a * constant that is its negation. It will also detect cases where \p alu2 is * an SSA value that is a \c nir_op_fneg applied to \p alu1 (and vice versa). * * This function does not detect the general case when \p alu1 and \p alu2 are * SSA values that are the negations of each other (e.g., \p alu1 represents * (a * b) and \p alu2 represents (-a * b)). * * \warning * It is the responsibility of the caller to ensure that the component counts, * write masks, and base types of the sources being compared are compatible. */ bool nir_alu_srcs_negative_equal(const nir_alu_instr *alu1, const nir_alu_instr *alu2, unsigned src1, unsigned src2) { #ifndef NDEBUG for (unsigned i = 0; i < NIR_MAX_VEC_COMPONENTS; i++) { assert(nir_alu_instr_channel_used(alu1, src1, i) == nir_alu_instr_channel_used(alu2, src2, i)); } if (nir_op_infos[alu1->op].input_types[src1] == nir_type_float) { assert(nir_op_infos[alu1->op].input_types[src1] == nir_op_infos[alu2->op].input_types[src2]); } else { assert(nir_op_infos[alu1->op].input_types[src1] == nir_type_int); assert(nir_op_infos[alu2->op].input_types[src2] == nir_type_int); } #endif if (alu1->src[src1].abs != alu2->src[src2].abs) return false; bool parity = alu1->src[src1].negate != alu2->src[src2].negate; /* Handling load_const instructions is tricky. */ const nir_const_value *const const1 = nir_src_as_const_value(alu1->src[src1].src); if (const1 != NULL) { /* Assume that constant folding will eliminate source mods and unary * ops. */ if (parity) return false; const nir_const_value *const const2 = nir_src_as_const_value(alu2->src[src2].src); if (const2 == NULL) return false; if (nir_src_bit_size(alu1->src[src1].src) != nir_src_bit_size(alu2->src[src2].src)) return false; const nir_alu_type full_type = nir_op_infos[alu1->op].input_types[src1] | nir_src_bit_size(alu1->src[src1].src); for (unsigned i = 0; i < NIR_MAX_VEC_COMPONENTS; i++) { if (nir_alu_instr_channel_used(alu1, src1, i) && !nir_const_value_negative_equal(const1[alu1->src[src1].swizzle[i]], const2[alu2->src[src2].swizzle[i]], full_type)) return false; } return true; } uint8_t alu1_swizzle[4] = {0}; nir_src alu1_actual_src; nir_alu_instr *neg1 = get_neg_instr(alu1->src[src1].src); if (neg1) { parity = !parity; alu1_actual_src = neg1->src[0].src; for (unsigned i = 0; i < nir_ssa_alu_instr_src_components(neg1, 0); i++) alu1_swizzle[i] = neg1->src[0].swizzle[i]; } else { alu1_actual_src = alu1->src[src1].src; for (unsigned i = 0; i < nir_ssa_alu_instr_src_components(alu1, src1); i++) alu1_swizzle[i] = i; } uint8_t alu2_swizzle[4] = {0}; nir_src alu2_actual_src; nir_alu_instr *neg2 = get_neg_instr(alu2->src[src2].src); if (neg2) { parity = !parity; alu2_actual_src = neg2->src[0].src; for (unsigned i = 0; i < nir_ssa_alu_instr_src_components(neg2, 0); i++) alu2_swizzle[i] = neg2->src[0].swizzle[i]; } else { alu2_actual_src = alu2->src[src2].src; for (unsigned i = 0; i < nir_ssa_alu_instr_src_components(alu2, src2); i++) alu2_swizzle[i] = i; } for (unsigned i = 0; i < nir_ssa_alu_instr_src_components(alu1, src1); i++) { if (alu1_swizzle[alu1->src[src1].swizzle[i]] != alu2_swizzle[alu2->src[src2].swizzle[i]]) return false; } return parity && nir_srcs_equal(alu1_actual_src, alu2_actual_src); } bool nir_alu_srcs_equal(const nir_alu_instr *alu1, const nir_alu_instr *alu2, unsigned src1, unsigned src2) { if (alu1->src[src1].abs != alu2->src[src2].abs || alu1->src[src1].negate != alu2->src[src2].negate) return false; for (unsigned i = 0; i < nir_ssa_alu_instr_src_components(alu1, src1); i++) { if (alu1->src[src1].swizzle[i] != alu2->src[src2].swizzle[i]) return false; } return nir_srcs_equal(alu1->src[src1].src, alu2->src[src2].src); } /* Returns "true" if two instructions are equal. Note that this will only * work for the subset of instructions defined by instr_can_rewrite(). Also, * it should only return "true" for instructions that hash_instr() will return * the same hash for (ignoring collisions, of course). */ bool nir_instrs_equal(const nir_instr *instr1, const nir_instr *instr2) { assert(instr_can_rewrite(instr1) && instr_can_rewrite(instr2)); if (instr1->type != instr2->type) return false; switch (instr1->type) { case nir_instr_type_alu: { nir_alu_instr *alu1 = nir_instr_as_alu(instr1); nir_alu_instr *alu2 = nir_instr_as_alu(instr2); if (alu1->op != alu2->op) return false; /* We explicitly don't compare instr->exact. */ if (alu1->no_signed_wrap != alu2->no_signed_wrap) return false; if (alu1->no_unsigned_wrap != alu2->no_unsigned_wrap) return false; /* TODO: We can probably acutally do something more inteligent such * as allowing different numbers and taking a maximum or something * here */ if (alu1->dest.dest.ssa.num_components != alu2->dest.dest.ssa.num_components) return false; if (alu1->dest.dest.ssa.bit_size != alu2->dest.dest.ssa.bit_size) return false; if (nir_op_infos[alu1->op].algebraic_properties & NIR_OP_IS_2SRC_COMMUTATIVE) { if ((!nir_alu_srcs_equal(alu1, alu2, 0, 0) || !nir_alu_srcs_equal(alu1, alu2, 1, 1)) && (!nir_alu_srcs_equal(alu1, alu2, 0, 1) || !nir_alu_srcs_equal(alu1, alu2, 1, 0))) return false; for (unsigned i = 2; i < nir_op_infos[alu1->op].num_inputs; i++) { if (!nir_alu_srcs_equal(alu1, alu2, i, i)) return false; } } else { for (unsigned i = 0; i < nir_op_infos[alu1->op].num_inputs; i++) { if (!nir_alu_srcs_equal(alu1, alu2, i, i)) return false; } } return true; } case nir_instr_type_deref: { nir_deref_instr *deref1 = nir_instr_as_deref(instr1); nir_deref_instr *deref2 = nir_instr_as_deref(instr2); if (deref1->deref_type != deref2->deref_type || deref1->mode != deref2->mode || deref1->type != deref2->type) return false; if (deref1->deref_type == nir_deref_type_var) return deref1->var == deref2->var; if (!nir_srcs_equal(deref1->parent, deref2->parent)) return false; switch (deref1->deref_type) { case nir_deref_type_struct: if (deref1->strct.index != deref2->strct.index) return false; break; case nir_deref_type_array: case nir_deref_type_ptr_as_array: if (!nir_srcs_equal(deref1->arr.index, deref2->arr.index)) return false; break; case nir_deref_type_cast: if (deref1->cast.ptr_stride != deref2->cast.ptr_stride) return false; break; case nir_deref_type_var: case nir_deref_type_array_wildcard: /* Nothing to do */ break; default: unreachable("Invalid instruction deref type"); } return true; } case nir_instr_type_tex: { nir_tex_instr *tex1 = nir_instr_as_tex(instr1); nir_tex_instr *tex2 = nir_instr_as_tex(instr2); if (tex1->op != tex2->op) return false; if (tex1->num_srcs != tex2->num_srcs) return false; for (unsigned i = 0; i < tex1->num_srcs; i++) { if (tex1->src[i].src_type != tex2->src[i].src_type || !nir_srcs_equal(tex1->src[i].src, tex2->src[i].src)) { return false; } } if (tex1->coord_components != tex2->coord_components || tex1->sampler_dim != tex2->sampler_dim || tex1->is_array != tex2->is_array || tex1->is_shadow != tex2->is_shadow || tex1->is_new_style_shadow != tex2->is_new_style_shadow || tex1->component != tex2->component || tex1->texture_index != tex2->texture_index || tex1->texture_array_size != tex2->texture_array_size || tex1->sampler_index != tex2->sampler_index) { return false; } if (memcmp(tex1->tg4_offsets, tex2->tg4_offsets, sizeof(tex1->tg4_offsets))) return false; return true; } case nir_instr_type_load_const: { nir_load_const_instr *load1 = nir_instr_as_load_const(instr1); nir_load_const_instr *load2 = nir_instr_as_load_const(instr2); if (load1->def.num_components != load2->def.num_components) return false; if (load1->def.bit_size != load2->def.bit_size) return false; if (load1->def.bit_size == 1) { for (unsigned i = 0; i < load1->def.num_components; ++i) { if (load1->value[i].b != load2->value[i].b) return false; } } else { unsigned size = load1->def.num_components * sizeof(*load1->value); if (memcmp(load1->value, load2->value, size) != 0) return false; } return true; } case nir_instr_type_phi: { nir_phi_instr *phi1 = nir_instr_as_phi(instr1); nir_phi_instr *phi2 = nir_instr_as_phi(instr2); if (phi1->instr.block != phi2->instr.block) return false; nir_foreach_phi_src(src1, phi1) { nir_foreach_phi_src(src2, phi2) { if (src1->pred == src2->pred) { if (!nir_srcs_equal(src1->src, src2->src)) return false; break; } } } return true; } case nir_instr_type_intrinsic: { nir_intrinsic_instr *intrinsic1 = nir_instr_as_intrinsic(instr1); nir_intrinsic_instr *intrinsic2 = nir_instr_as_intrinsic(instr2); const nir_intrinsic_info *info = &nir_intrinsic_infos[intrinsic1->intrinsic]; if (intrinsic1->intrinsic != intrinsic2->intrinsic || intrinsic1->num_components != intrinsic2->num_components) return false; if (info->has_dest && intrinsic1->dest.ssa.num_components != intrinsic2->dest.ssa.num_components) return false; if (info->has_dest && intrinsic1->dest.ssa.bit_size != intrinsic2->dest.ssa.bit_size) return false; for (unsigned i = 0; i < info->num_srcs; i++) { if (!nir_srcs_equal(intrinsic1->src[i], intrinsic2->src[i])) return false; } for (unsigned i = 0; i < info->num_indices; i++) { if (intrinsic1->const_index[i] != intrinsic2->const_index[i]) return false; } return true; } case nir_instr_type_call: case nir_instr_type_jump: case nir_instr_type_ssa_undef: case nir_instr_type_parallel_copy: default: unreachable("Invalid instruction type"); } unreachable("All cases in the above switch should return"); } static nir_ssa_def * nir_instr_get_dest_ssa_def(nir_instr *instr) { switch (instr->type) { case nir_instr_type_alu: assert(nir_instr_as_alu(instr)->dest.dest.is_ssa); return &nir_instr_as_alu(instr)->dest.dest.ssa; case nir_instr_type_deref: assert(nir_instr_as_deref(instr)->dest.is_ssa); return &nir_instr_as_deref(instr)->dest.ssa; case nir_instr_type_load_const: return &nir_instr_as_load_const(instr)->def; case nir_instr_type_phi: assert(nir_instr_as_phi(instr)->dest.is_ssa); return &nir_instr_as_phi(instr)->dest.ssa; case nir_instr_type_intrinsic: assert(nir_instr_as_intrinsic(instr)->dest.is_ssa); return &nir_instr_as_intrinsic(instr)->dest.ssa; case nir_instr_type_tex: assert(nir_instr_as_tex(instr)->dest.is_ssa); return &nir_instr_as_tex(instr)->dest.ssa; default: unreachable("We never ask for any of these"); } } static bool cmp_func(const void *data1, const void *data2) { return nir_instrs_equal(data1, data2); } struct set * nir_instr_set_create(void *mem_ctx) { return _mesa_set_create(mem_ctx, hash_instr, cmp_func); } void nir_instr_set_destroy(struct set *instr_set) { _mesa_set_destroy(instr_set, NULL); } bool nir_instr_set_add_or_rewrite(struct set *instr_set, nir_instr *instr) { if (!instr_can_rewrite(instr)) return false; struct set_entry *e = _mesa_set_search_or_add(instr_set, instr); nir_instr *match = (nir_instr *) e->key; if (match != instr) { nir_ssa_def *def = nir_instr_get_dest_ssa_def(instr); nir_ssa_def *new_def = nir_instr_get_dest_ssa_def(match); /* It's safe to replace an exact instruction with an inexact one as * long as we make it exact. If we got here, the two instructions are * exactly identical in every other way so, once we've set the exact * bit, they are the same. */ if (instr->type == nir_instr_type_alu && nir_instr_as_alu(instr)->exact) nir_instr_as_alu(match)->exact = true; nir_ssa_def_rewrite_uses(def, nir_src_for_ssa(new_def)); return true; } return false; } void nir_instr_set_remove(struct set *instr_set, nir_instr *instr) { if (!instr_can_rewrite(instr)) return; struct set_entry *entry = _mesa_set_search(instr_set, instr); if (entry) _mesa_set_remove(instr_set, entry); }