/* * Copyright © 2015 Red Hat * * 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.h" #include "nir_control_flow.h" /* Secret Decoder Ring: * clone_foo(): * Allocate and clone a foo. * __clone_foo(): * Clone body of foo (ie. parent class, embedded struct, etc) */ typedef struct { /* True if we are cloning an entire shader. */ bool global_clone; /* If true allows the clone operation to fall back to the original pointer * if no clone pointer is found in the remap table. This allows us to * clone a loop body without having to add srcs from outside the loop to * the remap table. This is useful for loop unrolling. */ bool allow_remap_fallback; /* maps orig ptr -> cloned ptr: */ struct hash_table *remap_table; /* List of phi sources. */ struct list_head phi_srcs; /* new shader object, used as memctx for just about everything else: */ nir_shader *ns; } clone_state; static void init_clone_state(clone_state *state, struct hash_table *remap_table, bool global, bool allow_remap_fallback) { state->global_clone = global; state->allow_remap_fallback = allow_remap_fallback; if (remap_table) { state->remap_table = remap_table; } else { state->remap_table = _mesa_hash_table_create(NULL, _mesa_hash_pointer, _mesa_key_pointer_equal); } list_inithead(&state->phi_srcs); } static void free_clone_state(clone_state *state) { _mesa_hash_table_destroy(state->remap_table, NULL); } static inline void * _lookup_ptr(clone_state *state, const void *ptr, bool global) { struct hash_entry *entry; if (!ptr) return NULL; if (!state->global_clone && global) return (void *)ptr; entry = _mesa_hash_table_search(state->remap_table, ptr); if (!entry) { assert(state->allow_remap_fallback); return (void *)ptr; } return entry->data; } static void add_remap(clone_state *state, void *nptr, const void *ptr) { _mesa_hash_table_insert(state->remap_table, ptr, nptr); } static void * remap_local(clone_state *state, const void *ptr) { return _lookup_ptr(state, ptr, false); } static void * remap_global(clone_state *state, const void *ptr) { return _lookup_ptr(state, ptr, true); } static nir_register * remap_reg(clone_state *state, const nir_register *reg) { return _lookup_ptr(state, reg, reg->is_global); } static nir_variable * remap_var(clone_state *state, const nir_variable *var) { return _lookup_ptr(state, var, nir_variable_is_global(var)); } nir_constant * nir_constant_clone(const nir_constant *c, nir_variable *nvar) { nir_constant *nc = ralloc(nvar, nir_constant); memcpy(nc->values, c->values, sizeof(nc->values)); nc->num_elements = c->num_elements; nc->elements = ralloc_array(nvar, nir_constant *, c->num_elements); for (unsigned i = 0; i < c->num_elements; i++) { nc->elements[i] = nir_constant_clone(c->elements[i], nvar); } return nc; } /* NOTE: for cloning nir_variable's, bypass nir_variable_create to avoid * having to deal with locals and globals separately: */ nir_variable * nir_variable_clone(const nir_variable *var, nir_shader *shader) { nir_variable *nvar = rzalloc(shader, nir_variable); nvar->type = var->type; nvar->name = ralloc_strdup(nvar, var->name); nvar->data = var->data; nvar->num_state_slots = var->num_state_slots; nvar->state_slots = ralloc_array(nvar, nir_state_slot, var->num_state_slots); memcpy(nvar->state_slots, var->state_slots, var->num_state_slots * sizeof(nir_state_slot)); if (var->constant_initializer) { nvar->constant_initializer = nir_constant_clone(var->constant_initializer, nvar); } nvar->interface_type = var->interface_type; return nvar; } static nir_variable * clone_variable(clone_state *state, const nir_variable *var) { nir_variable *nvar = nir_variable_clone(var, state->ns); add_remap(state, nvar, var); return nvar; } /* clone list of nir_variable: */ static void clone_var_list(clone_state *state, struct exec_list *dst, const struct exec_list *list) { exec_list_make_empty(dst); foreach_list_typed(nir_variable, var, node, list) { nir_variable *nvar = clone_variable(state, var); exec_list_push_tail(dst, &nvar->node); } } /* NOTE: for cloning nir_register's, bypass nir_global/local_reg_create() * to avoid having to deal with locals and globals separately: */ static nir_register * clone_register(clone_state *state, const nir_register *reg) { nir_register *nreg = rzalloc(state->ns, nir_register); add_remap(state, nreg, reg); nreg->num_components = reg->num_components; nreg->bit_size = reg->bit_size; nreg->num_array_elems = reg->num_array_elems; nreg->index = reg->index; nreg->name = ralloc_strdup(nreg, reg->name); nreg->is_global = reg->is_global; nreg->is_packed = reg->is_packed; /* reconstructing uses/defs/if_uses handled by nir_instr_insert() */ list_inithead(&nreg->uses); list_inithead(&nreg->defs); list_inithead(&nreg->if_uses); return nreg; } /* clone list of nir_register: */ static void clone_reg_list(clone_state *state, struct exec_list *dst, const struct exec_list *list) { exec_list_make_empty(dst); foreach_list_typed(nir_register, reg, node, list) { nir_register *nreg = clone_register(state, reg); exec_list_push_tail(dst, &nreg->node); } } static void __clone_src(clone_state *state, void *ninstr_or_if, nir_src *nsrc, const nir_src *src) { nsrc->is_ssa = src->is_ssa; if (src->is_ssa) { nsrc->ssa = remap_local(state, src->ssa); } else { nsrc->reg.reg = remap_reg(state, src->reg.reg); if (src->reg.indirect) { nsrc->reg.indirect = ralloc(ninstr_or_if, nir_src); __clone_src(state, ninstr_or_if, nsrc->reg.indirect, src->reg.indirect); } nsrc->reg.base_offset = src->reg.base_offset; } } static void __clone_dst(clone_state *state, nir_instr *ninstr, nir_dest *ndst, const nir_dest *dst) { ndst->is_ssa = dst->is_ssa; if (dst->is_ssa) { nir_ssa_dest_init(ninstr, ndst, dst->ssa.num_components, dst->ssa.bit_size, dst->ssa.name); add_remap(state, &ndst->ssa, &dst->ssa); } else { ndst->reg.reg = remap_reg(state, dst->reg.reg); if (dst->reg.indirect) { ndst->reg.indirect = ralloc(ninstr, nir_src); __clone_src(state, ninstr, ndst->reg.indirect, dst->reg.indirect); } ndst->reg.base_offset = dst->reg.base_offset; } } static nir_deref *clone_deref(clone_state *state, const nir_deref *deref, nir_instr *ninstr, nir_deref *parent); static nir_deref_var * clone_deref_var(clone_state *state, const nir_deref_var *dvar, nir_instr *ninstr) { nir_variable *nvar = remap_var(state, dvar->var); nir_deref_var *ndvar = nir_deref_var_create(ninstr, nvar); if (dvar->deref.child) ndvar->deref.child = clone_deref(state, dvar->deref.child, ninstr, &ndvar->deref); return ndvar; } static nir_deref_array * clone_deref_array(clone_state *state, const nir_deref_array *darr, nir_instr *ninstr, nir_deref *parent) { nir_deref_array *ndarr = nir_deref_array_create(parent); ndarr->deref.type = darr->deref.type; if (darr->deref.child) ndarr->deref.child = clone_deref(state, darr->deref.child, ninstr, &ndarr->deref); ndarr->deref_array_type = darr->deref_array_type; ndarr->base_offset = darr->base_offset; if (ndarr->deref_array_type == nir_deref_array_type_indirect) __clone_src(state, ninstr, &ndarr->indirect, &darr->indirect); return ndarr; } static nir_deref_struct * clone_deref_struct(clone_state *state, const nir_deref_struct *dstr, nir_instr *ninstr, nir_deref *parent) { nir_deref_struct *ndstr = nir_deref_struct_create(parent, dstr->index); ndstr->deref.type = dstr->deref.type; if (dstr->deref.child) ndstr->deref.child = clone_deref(state, dstr->deref.child, ninstr, &ndstr->deref); return ndstr; } static nir_deref * clone_deref(clone_state *state, const nir_deref *dref, nir_instr *ninstr, nir_deref *parent) { switch (dref->deref_type) { case nir_deref_type_array: return &clone_deref_array(state, nir_deref_as_array(dref), ninstr, parent)->deref; case nir_deref_type_struct: return &clone_deref_struct(state, nir_deref_as_struct(dref), ninstr, parent)->deref; default: unreachable("bad deref type"); return NULL; } } static nir_alu_instr * clone_alu(clone_state *state, const nir_alu_instr *alu) { nir_alu_instr *nalu = nir_alu_instr_create(state->ns, alu->op); nalu->exact = alu->exact; __clone_dst(state, &nalu->instr, &nalu->dest.dest, &alu->dest.dest); nalu->dest.saturate = alu->dest.saturate; nalu->dest.write_mask = alu->dest.write_mask; for (unsigned i = 0; i < nir_op_infos[alu->op].num_inputs; i++) { __clone_src(state, &nalu->instr, &nalu->src[i].src, &alu->src[i].src); nalu->src[i].negate = alu->src[i].negate; nalu->src[i].abs = alu->src[i].abs; memcpy(nalu->src[i].swizzle, alu->src[i].swizzle, sizeof(nalu->src[i].swizzle)); } return nalu; } static nir_intrinsic_instr * clone_intrinsic(clone_state *state, const nir_intrinsic_instr *itr) { nir_intrinsic_instr *nitr = nir_intrinsic_instr_create(state->ns, itr->intrinsic); unsigned num_variables = nir_intrinsic_infos[itr->intrinsic].num_variables; unsigned num_srcs = nir_intrinsic_infos[itr->intrinsic].num_srcs; if (nir_intrinsic_infos[itr->intrinsic].has_dest) __clone_dst(state, &nitr->instr, &nitr->dest, &itr->dest); nitr->num_components = itr->num_components; memcpy(nitr->const_index, itr->const_index, sizeof(nitr->const_index)); for (unsigned i = 0; i < num_variables; i++) { nitr->variables[i] = clone_deref_var(state, itr->variables[i], &nitr->instr); } for (unsigned i = 0; i < num_srcs; i++) __clone_src(state, &nitr->instr, &nitr->src[i], &itr->src[i]); return nitr; } static nir_load_const_instr * clone_load_const(clone_state *state, const nir_load_const_instr *lc) { nir_load_const_instr *nlc = nir_load_const_instr_create(state->ns, lc->def.num_components, lc->def.bit_size); memcpy(&nlc->value, &lc->value, sizeof(nlc->value)); add_remap(state, &nlc->def, &lc->def); return nlc; } static nir_ssa_undef_instr * clone_ssa_undef(clone_state *state, const nir_ssa_undef_instr *sa) { nir_ssa_undef_instr *nsa = nir_ssa_undef_instr_create(state->ns, sa->def.num_components, sa->def.bit_size); add_remap(state, &nsa->def, &sa->def); return nsa; } static nir_tex_instr * clone_tex(clone_state *state, const nir_tex_instr *tex) { nir_tex_instr *ntex = nir_tex_instr_create(state->ns, tex->num_srcs); ntex->sampler_dim = tex->sampler_dim; ntex->dest_type = tex->dest_type; ntex->op = tex->op; __clone_dst(state, &ntex->instr, &ntex->dest, &tex->dest); for (unsigned i = 0; i < ntex->num_srcs; i++) { ntex->src[i].src_type = tex->src[i].src_type; __clone_src(state, &ntex->instr, &ntex->src[i].src, &tex->src[i].src); } ntex->coord_components = tex->coord_components; ntex->is_array = tex->is_array; ntex->is_shadow = tex->is_shadow; ntex->is_new_style_shadow = tex->is_new_style_shadow; ntex->component = tex->component; ntex->texture_index = tex->texture_index; if (tex->texture) ntex->texture = clone_deref_var(state, tex->texture, &ntex->instr); ntex->texture_array_size = tex->texture_array_size; ntex->sampler_index = tex->sampler_index; if (tex->sampler) ntex->sampler = clone_deref_var(state, tex->sampler, &ntex->instr); return ntex; } static nir_phi_instr * clone_phi(clone_state *state, const nir_phi_instr *phi, nir_block *nblk) { nir_phi_instr *nphi = nir_phi_instr_create(state->ns); __clone_dst(state, &nphi->instr, &nphi->dest, &phi->dest); /* Cloning a phi node is a bit different from other instructions. The * sources of phi instructions are the only time where we can use an SSA * def before it is defined. In order to handle this, we just copy over * the sources from the old phi instruction directly and then fix them up * in a second pass once all the instrutions in the function have been * properly cloned. * * In order to ensure that the copied sources (which are the same as the * old phi instruction's sources for now) don't get inserted into the old * shader's use-def lists, we have to add the phi instruction *before* we * set up its sources. */ nir_instr_insert_after_block(nblk, &nphi->instr); foreach_list_typed(nir_phi_src, src, node, &phi->srcs) { nir_phi_src *nsrc = ralloc(nphi, nir_phi_src); /* Just copy the old source for now. */ memcpy(nsrc, src, sizeof(*src)); /* Since we're not letting nir_insert_instr handle use/def stuff for us, * we have to set the parent_instr manually. It doesn't really matter * when we do it, so we might as well do it here. */ nsrc->src.parent_instr = &nphi->instr; /* Stash it in the list of phi sources. We'll walk this list and fix up * sources at the very end of clone_function_impl. */ list_add(&nsrc->src.use_link, &state->phi_srcs); exec_list_push_tail(&nphi->srcs, &nsrc->node); } return nphi; } static nir_jump_instr * clone_jump(clone_state *state, const nir_jump_instr *jmp) { nir_jump_instr *njmp = nir_jump_instr_create(state->ns, jmp->type); return njmp; } static nir_call_instr * clone_call(clone_state *state, const nir_call_instr *call) { nir_function *ncallee = remap_global(state, call->callee); nir_call_instr *ncall = nir_call_instr_create(state->ns, ncallee); for (unsigned i = 0; i < ncall->num_params; i++) ncall->params[i] = clone_deref_var(state, call->params[i], &ncall->instr); ncall->return_deref = clone_deref_var(state, call->return_deref, &ncall->instr); return ncall; } static nir_instr * clone_instr(clone_state *state, const nir_instr *instr) { switch (instr->type) { case nir_instr_type_alu: return &clone_alu(state, nir_instr_as_alu(instr))->instr; case nir_instr_type_intrinsic: return &clone_intrinsic(state, nir_instr_as_intrinsic(instr))->instr; case nir_instr_type_load_const: return &clone_load_const(state, nir_instr_as_load_const(instr))->instr; case nir_instr_type_ssa_undef: return &clone_ssa_undef(state, nir_instr_as_ssa_undef(instr))->instr; case nir_instr_type_tex: return &clone_tex(state, nir_instr_as_tex(instr))->instr; case nir_instr_type_phi: unreachable("Cannot clone phis with clone_instr"); case nir_instr_type_jump: return &clone_jump(state, nir_instr_as_jump(instr))->instr; case nir_instr_type_call: return &clone_call(state, nir_instr_as_call(instr))->instr; case nir_instr_type_parallel_copy: unreachable("Cannot clone parallel copies"); default: unreachable("bad instr type"); return NULL; } } static nir_block * clone_block(clone_state *state, struct exec_list *cf_list, const nir_block *blk) { /* Don't actually create a new block. Just use the one from the tail of * the list. NIR guarantees that the tail of the list is a block and that * no two blocks are side-by-side in the IR; It should be empty. */ nir_block *nblk = exec_node_data(nir_block, exec_list_get_tail(cf_list), cf_node.node); assert(nblk->cf_node.type == nir_cf_node_block); assert(exec_list_is_empty(&nblk->instr_list)); /* We need this for phi sources */ add_remap(state, nblk, blk); nir_foreach_instr(instr, blk) { if (instr->type == nir_instr_type_phi) { /* Phi instructions are a bit of a special case when cloning because * we don't want inserting the instruction to automatically handle * use/defs for us. Instead, we need to wait until all the * blocks/instructions are in so that we can set their sources up. */ clone_phi(state, nir_instr_as_phi(instr), nblk); } else { nir_instr *ninstr = clone_instr(state, instr); nir_instr_insert_after_block(nblk, ninstr); } } return nblk; } static void clone_cf_list(clone_state *state, struct exec_list *dst, const struct exec_list *list); static nir_if * clone_if(clone_state *state, struct exec_list *cf_list, const nir_if *i) { nir_if *ni = nir_if_create(state->ns); __clone_src(state, ni, &ni->condition, &i->condition); nir_cf_node_insert_end(cf_list, &ni->cf_node); clone_cf_list(state, &ni->then_list, &i->then_list); clone_cf_list(state, &ni->else_list, &i->else_list); return ni; } static nir_loop * clone_loop(clone_state *state, struct exec_list *cf_list, const nir_loop *loop) { nir_loop *nloop = nir_loop_create(state->ns); nir_cf_node_insert_end(cf_list, &nloop->cf_node); clone_cf_list(state, &nloop->body, &loop->body); return nloop; } /* clone list of nir_cf_node: */ static void clone_cf_list(clone_state *state, struct exec_list *dst, const struct exec_list *list) { foreach_list_typed(nir_cf_node, cf, node, list) { switch (cf->type) { case nir_cf_node_block: clone_block(state, dst, nir_cf_node_as_block(cf)); break; case nir_cf_node_if: clone_if(state, dst, nir_cf_node_as_if(cf)); break; case nir_cf_node_loop: clone_loop(state, dst, nir_cf_node_as_loop(cf)); break; default: unreachable("bad cf type"); } } } /* After we've cloned almost everything, we have to walk the list of phi * sources and fix them up. Thanks to loops, the block and SSA value for a * phi source may not be defined when we first encounter it. Instead, we * add it to the phi_srcs list and we fix it up here. */ static void fixup_phi_srcs(clone_state *state) { list_for_each_entry_safe(nir_phi_src, src, &state->phi_srcs, src.use_link) { src->pred = remap_local(state, src->pred); /* Remove from this list */ list_del(&src->src.use_link); if (src->src.is_ssa) { src->src.ssa = remap_local(state, src->src.ssa); list_addtail(&src->src.use_link, &src->src.ssa->uses); } else { src->src.reg.reg = remap_reg(state, src->src.reg.reg); list_addtail(&src->src.use_link, &src->src.reg.reg->uses); } } assert(list_empty(&state->phi_srcs)); } void nir_cf_list_clone(nir_cf_list *dst, nir_cf_list *src, nir_cf_node *parent, struct hash_table *remap_table) { exec_list_make_empty(&dst->list); dst->impl = src->impl; if (exec_list_is_empty(&src->list)) return; clone_state state; init_clone_state(&state, remap_table, false, true); /* We use the same shader */ state.ns = src->impl->function->shader; /* The control-flow code assumes that the list of cf_nodes always starts * and ends with a block. We start by adding an empty block. */ nir_block *nblk = nir_block_create(state.ns); nblk->cf_node.parent = parent; exec_list_push_tail(&dst->list, &nblk->cf_node.node); clone_cf_list(&state, &dst->list, &src->list); fixup_phi_srcs(&state); } static nir_function_impl * clone_function_impl(clone_state *state, const nir_function_impl *fi) { nir_function_impl *nfi = nir_function_impl_create_bare(state->ns); clone_var_list(state, &nfi->locals, &fi->locals); clone_reg_list(state, &nfi->registers, &fi->registers); nfi->reg_alloc = fi->reg_alloc; nfi->num_params = fi->num_params; nfi->params = ralloc_array(state->ns, nir_variable *, fi->num_params); for (unsigned i = 0; i < fi->num_params; i++) { nfi->params[i] = clone_variable(state, fi->params[i]); } if (fi->return_var) nfi->return_var = clone_variable(state, fi->return_var); assert(list_empty(&state->phi_srcs)); clone_cf_list(state, &nfi->body, &fi->body); fixup_phi_srcs(state); /* All metadata is invalidated in the cloning process */ nfi->valid_metadata = 0; return nfi; } nir_function_impl * nir_function_impl_clone(const nir_function_impl *fi) { clone_state state; init_clone_state(&state, NULL, false, false); /* We use the same shader */ state.ns = fi->function->shader; nir_function_impl *nfi = clone_function_impl(&state, fi); free_clone_state(&state); return nfi; } static nir_function * clone_function(clone_state *state, const nir_function *fxn, nir_shader *ns) { assert(ns == state->ns); nir_function *nfxn = nir_function_create(ns, fxn->name); /* Needed for call instructions */ add_remap(state, nfxn, fxn); nfxn->num_params = fxn->num_params; nfxn->params = ralloc_array(state->ns, nir_parameter, fxn->num_params); memcpy(nfxn->params, fxn->params, sizeof(nir_parameter) * fxn->num_params); nfxn->return_type = fxn->return_type; /* At first glance, it looks like we should clone the function_impl here. * However, call instructions need to be able to reference at least the * function and those will get processed as we clone the function_impl's. * We stop here and do function_impls as a second pass. */ return nfxn; } nir_shader * nir_shader_clone(void *mem_ctx, const nir_shader *s) { clone_state state; init_clone_state(&state, NULL, true, false); nir_shader *ns = nir_shader_create(mem_ctx, s->stage, s->options, NULL); state.ns = ns; clone_var_list(&state, &ns->uniforms, &s->uniforms); clone_var_list(&state, &ns->inputs, &s->inputs); clone_var_list(&state, &ns->outputs, &s->outputs); clone_var_list(&state, &ns->shared, &s->shared); clone_var_list(&state, &ns->globals, &s->globals); clone_var_list(&state, &ns->system_values, &s->system_values); /* Go through and clone functions */ foreach_list_typed(nir_function, fxn, node, &s->functions) clone_function(&state, fxn, ns); /* Only after all functions are cloned can we clone the actual function * implementations. This is because nir_call_instr's need to reference the * functions of other functions and we don't know what order the functions * will have in the list. */ nir_foreach_function(fxn, s) { nir_function *nfxn = remap_global(&state, fxn); nfxn->impl = clone_function_impl(&state, fxn->impl); nfxn->impl->function = nfxn; } clone_reg_list(&state, &ns->registers, &s->registers); ns->reg_alloc = s->reg_alloc; *ns->info = *s->info; ns->info->name = ralloc_strdup(ns, ns->info->name); if (ns->info->label) ns->info->label = ralloc_strdup(ns, ns->info->label); ns->num_inputs = s->num_inputs; ns->num_uniforms = s->num_uniforms; ns->num_outputs = s->num_outputs; ns->num_shared = s->num_shared; free_clone_state(&state); return ns; }