/* * Copyright © 2014 Intel Corporation * * 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. * * Authors: * Connor Abbott (cwabbott0@gmail.com) * */ #include "nir.h" #include /* * Implements the classic to-SSA algorithm described by Cytron et. al. in * "Efficiently Computing Static Single Assignment Form and the Control * Dependence Graph." */ /* inserts a phi node of the form reg = phi(reg, reg, reg, ...) */ static void insert_trivial_phi(nir_register *reg, nir_block *block, void *mem_ctx) { nir_phi_instr *instr = nir_phi_instr_create(mem_ctx); instr->dest.reg.reg = reg; struct set_entry *entry; set_foreach(block->predecessors, entry) { nir_block *pred = (nir_block *) entry->key; nir_phi_src *src = ralloc(instr, nir_phi_src); src->pred = pred; src->src.is_ssa = false; src->src.reg.base_offset = 0; src->src.reg.indirect = NULL; src->src.reg.reg = reg; exec_list_push_tail(&instr->srcs, &src->node); } nir_instr_insert_before_block(block, &instr->instr); } static void insert_phi_nodes(nir_function_impl *impl) { void *mem_ctx = ralloc_parent(impl); unsigned *work = calloc(impl->num_blocks, sizeof(unsigned)); unsigned *has_already = calloc(impl->num_blocks, sizeof(unsigned)); /* * Since the work flags already prevent us from inserting a node that has * ever been inserted into W, we don't need to use a set to represent W. * Also, since no block can ever be inserted into W more than once, we know * that the maximum size of W is the number of basic blocks in the * function. So all we need to handle W is an array and a pointer to the * next element to be inserted and the next element to be removed. */ nir_block **W = malloc(impl->num_blocks * sizeof(nir_block *)); unsigned w_start, w_end; unsigned iter_count = 0; nir_index_blocks(impl); foreach_list_typed(nir_register, reg, node, &impl->registers) { if (reg->num_array_elems != 0) continue; w_start = w_end = 0; iter_count++; nir_foreach_def(reg, dest) { nir_instr *def = dest->reg.parent_instr; if (work[def->block->index] < iter_count) W[w_end++] = def->block; work[def->block->index] = iter_count; } while (w_start != w_end) { nir_block *cur = W[w_start++]; struct set_entry *entry; set_foreach(cur->dom_frontier, entry) { nir_block *next = (nir_block *) entry->key; /* * If there's more than one return statement, then the end block * can be a join point for some definitions. However, there are * no instructions in the end block, so nothing would use those * phi nodes. Of course, we couldn't place those phi nodes * anyways due to the restriction of having no instructions in the * end block... */ if (next == impl->end_block) continue; if (has_already[next->index] < iter_count) { insert_trivial_phi(reg, next, mem_ctx); has_already[next->index] = iter_count; if (work[next->index] < iter_count) { work[next->index] = iter_count; W[w_end++] = next; } } } } } free(work); free(has_already); free(W); } typedef struct { nir_ssa_def **stack; int index; unsigned num_defs; /** < used to add indices to debug names */ #ifndef NDEBUG unsigned stack_size; #endif } reg_state; typedef struct { reg_state *states; void *mem_ctx; nir_instr *parent_instr; nir_if *parent_if; nir_function_impl *impl; /* map from SSA value -> original register */ struct hash_table *ssa_map; } rewrite_state; static nir_ssa_def *get_ssa_src(nir_register *reg, rewrite_state *state) { unsigned index = reg->index; if (state->states[index].index == -1) { /* * We're using an undefined register, create a new undefined SSA value * to preserve the information that this source is undefined */ nir_ssa_undef_instr *instr = nir_ssa_undef_instr_create(state->mem_ctx, reg->num_components, reg->bit_size); /* * We could just insert the undefined instruction before the instruction * we're rewriting, but we could be rewriting a phi source in which case * we can't do that, so do the next easiest thing - insert it at the * beginning of the program. In the end, it doesn't really matter where * the undefined instructions are because they're going to be ignored * in the backend. */ nir_instr_insert_before_cf_list(&state->impl->body, &instr->instr); return &instr->def; } return state->states[index].stack[state->states[index].index]; } static bool rewrite_use(nir_src *src, void *_state) { rewrite_state *state = (rewrite_state *) _state; if (src->is_ssa) return true; unsigned index = src->reg.reg->index; if (state->states[index].stack == NULL) return true; nir_ssa_def *def = get_ssa_src(src->reg.reg, state); if (state->parent_instr) nir_instr_rewrite_src(state->parent_instr, src, nir_src_for_ssa(def)); else nir_if_rewrite_condition(state->parent_if, nir_src_for_ssa(def)); return true; } static bool rewrite_def_forwards(nir_dest *dest, void *_state) { rewrite_state *state = (rewrite_state *) _state; if (dest->is_ssa) return true; nir_register *reg = dest->reg.reg; unsigned index = reg->index; if (state->states[index].stack == NULL) return true; char *name = NULL; if (dest->reg.reg->name) name = ralloc_asprintf(state->mem_ctx, "%s_%u", dest->reg.reg->name, state->states[index].num_defs); list_del(&dest->reg.def_link); nir_ssa_dest_init(state->parent_instr, dest, reg->num_components, reg->bit_size, name); ralloc_free(name); /* push our SSA destination on the stack */ state->states[index].index++; assert(state->states[index].index < state->states[index].stack_size); state->states[index].stack[state->states[index].index] = &dest->ssa; state->states[index].num_defs++; _mesa_hash_table_insert(state->ssa_map, &dest->ssa, reg); return true; } static void rewrite_alu_instr_forward(nir_alu_instr *instr, rewrite_state *state) { state->parent_instr = &instr->instr; nir_foreach_src(&instr->instr, rewrite_use, state); if (instr->dest.dest.is_ssa) return; nir_register *reg = instr->dest.dest.reg.reg; unsigned index = reg->index; if (state->states[index].stack == NULL) return; unsigned write_mask = instr->dest.write_mask; if (write_mask != (1 << instr->dest.dest.reg.reg->num_components) - 1) { /* * Calculate the number of components the final instruction, which for * per-component things is the number of output components of the * instruction and non-per-component things is the number of enabled * channels in the write mask. */ unsigned num_components; if (nir_op_infos[instr->op].output_size == 0) { unsigned temp = (write_mask & 0x5) + ((write_mask >> 1) & 0x5); num_components = (temp & 0x3) + ((temp >> 2) & 0x3); } else { num_components = nir_op_infos[instr->op].output_size; } char *name = NULL; if (instr->dest.dest.reg.reg->name) name = ralloc_asprintf(state->mem_ctx, "%s_%u", reg->name, state->states[index].num_defs); instr->dest.write_mask = (1 << num_components) - 1; list_del(&instr->dest.dest.reg.def_link); nir_ssa_dest_init(&instr->instr, &instr->dest.dest, num_components, reg->bit_size, name); ralloc_free(name); if (nir_op_infos[instr->op].output_size == 0) { /* * When we change the output writemask, we need to change the * swizzles for per-component inputs too */ for (unsigned i = 0; i < nir_op_infos[instr->op].num_inputs; i++) { if (nir_op_infos[instr->op].input_sizes[i] != 0) continue; unsigned new_swizzle[4] = {0, 0, 0, 0}; /* * We keep two indices: * 1. The index of the original (non-SSA) component * 2. The index of the post-SSA, compacted, component * * We need to map the swizzle component at index 1 to the swizzle * component at index 2. */ unsigned ssa_index = 0; for (unsigned index = 0; index < 4; index++) { if (!((write_mask >> index) & 1)) continue; new_swizzle[ssa_index] = instr->src[i].swizzle[index]; ssa_index++; } for (unsigned j = 0; j < 4; j++) instr->src[i].swizzle[j] = new_swizzle[j]; } } nir_op op; switch (reg->num_components) { case 2: op = nir_op_vec2; break; case 3: op = nir_op_vec3; break; case 4: op = nir_op_vec4; break; default: unreachable("not reached"); } nir_alu_instr *vec = nir_alu_instr_create(state->mem_ctx, op); vec->dest.dest.reg.reg = reg; vec->dest.write_mask = (1 << reg->num_components) - 1; nir_ssa_def *old_src = get_ssa_src(reg, state); nir_ssa_def *new_src = &instr->dest.dest.ssa; unsigned ssa_index = 0; for (unsigned i = 0; i < reg->num_components; i++) { vec->src[i].src.is_ssa = true; if ((write_mask >> i) & 1) { vec->src[i].src.ssa = new_src; if (nir_op_infos[instr->op].output_size == 0) vec->src[i].swizzle[0] = ssa_index; else vec->src[i].swizzle[0] = i; ssa_index++; } else { vec->src[i].src.ssa = old_src; vec->src[i].swizzle[0] = i; } } nir_instr_insert_after(&instr->instr, &vec->instr); state->parent_instr = &vec->instr; rewrite_def_forwards(&vec->dest.dest, state); } else { rewrite_def_forwards(&instr->dest.dest, state); } } static void rewrite_phi_instr(nir_phi_instr *instr, rewrite_state *state) { state->parent_instr = &instr->instr; rewrite_def_forwards(&instr->dest, state); } static void rewrite_instr_forward(nir_instr *instr, rewrite_state *state) { if (instr->type == nir_instr_type_alu) { rewrite_alu_instr_forward(nir_instr_as_alu(instr), state); return; } if (instr->type == nir_instr_type_phi) { rewrite_phi_instr(nir_instr_as_phi(instr), state); return; } state->parent_instr = instr; nir_foreach_src(instr, rewrite_use, state); nir_foreach_dest(instr, rewrite_def_forwards, state); } static void rewrite_phi_sources(nir_block *block, nir_block *pred, rewrite_state *state) { nir_foreach_instr(instr, block) { if (instr->type != nir_instr_type_phi) break; nir_phi_instr *phi_instr = nir_instr_as_phi(instr); state->parent_instr = instr; nir_foreach_phi_src(src, phi_instr) { if (src->pred == pred) { rewrite_use(&src->src, state); break; } } } } static bool rewrite_def_backwards(nir_dest *dest, void *_state) { rewrite_state *state = (rewrite_state *) _state; if (!dest->is_ssa) return true; struct hash_entry *entry = _mesa_hash_table_search(state->ssa_map, &dest->ssa); if (!entry) return true; nir_register *reg = (nir_register *) entry->data; unsigned index = reg->index; state->states[index].index--; assert(state->states[index].index >= -1); return true; } static void rewrite_instr_backwards(nir_instr *instr, rewrite_state *state) { nir_foreach_dest(instr, rewrite_def_backwards, state); } static void rewrite_block(nir_block *block, rewrite_state *state) { /* This will skip over any instructions after the current one, which is * what we want because those instructions (vector gather, conditional * select) will already be in SSA form. */ nir_foreach_instr_safe(instr, block) { rewrite_instr_forward(instr, state); } if (block != state->impl->end_block && !nir_cf_node_is_last(&block->cf_node) && nir_cf_node_next(&block->cf_node)->type == nir_cf_node_if) { nir_if *if_stmt = nir_cf_node_as_if(nir_cf_node_next(&block->cf_node)); state->parent_instr = NULL; state->parent_if = if_stmt; rewrite_use(&if_stmt->condition, state); } if (block->successors[0]) rewrite_phi_sources(block->successors[0], block, state); if (block->successors[1]) rewrite_phi_sources(block->successors[1], block, state); for (unsigned i = 0; i < block->num_dom_children; i++) rewrite_block(block->dom_children[i], state); nir_foreach_instr_reverse(instr, block) { rewrite_instr_backwards(instr, state); } } static void remove_unused_regs(nir_function_impl *impl, rewrite_state *state) { foreach_list_typed_safe(nir_register, reg, node, &impl->registers) { if (state->states[reg->index].stack != NULL) exec_node_remove(®->node); } } static void init_rewrite_state(nir_function_impl *impl, rewrite_state *state) { state->impl = impl; state->mem_ctx = ralloc_parent(impl); state->ssa_map = _mesa_hash_table_create(NULL, _mesa_hash_pointer, _mesa_key_pointer_equal); state->states = ralloc_array(NULL, reg_state, impl->reg_alloc); foreach_list_typed(nir_register, reg, node, &impl->registers) { assert(reg->index < impl->reg_alloc); if (reg->num_array_elems > 0) { state->states[reg->index].stack = NULL; } else { /* * Calculate a conservative estimate of the stack size based on the * number of definitions there are. Note that this function *must* be * called after phi nodes are inserted so we can count phi node * definitions too. */ unsigned stack_size = list_length(®->defs); state->states[reg->index].stack = ralloc_array(state->states, nir_ssa_def *, stack_size); #ifndef NDEBUG state->states[reg->index].stack_size = stack_size; #endif state->states[reg->index].index = -1; state->states[reg->index].num_defs = 0; } } } static void destroy_rewrite_state(rewrite_state *state) { _mesa_hash_table_destroy(state->ssa_map, NULL); ralloc_free(state->states); } void nir_convert_to_ssa_impl(nir_function_impl *impl) { nir_metadata_require(impl, nir_metadata_dominance); insert_phi_nodes(impl); rewrite_state state; init_rewrite_state(impl, &state); rewrite_block(nir_start_block(impl), &state); remove_unused_regs(impl, &state); nir_metadata_preserve(impl, nir_metadata_block_index | nir_metadata_dominance); destroy_rewrite_state(&state); } void nir_convert_to_ssa(nir_shader *shader) { nir_foreach_function(shader, function) { if (function->impl) nir_convert_to_ssa_impl(function->impl); } }