/* * Copyright © 2017 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_serialize.h" #include "nir_control_flow.h" #include "util/u_dynarray.h" typedef struct { size_t blob_offset; nir_ssa_def *src; nir_block *block; } write_phi_fixup; typedef struct { const nir_shader *nir; struct blob *blob; /* maps pointer to index */ struct hash_table *remap_table; /* the next index to assign to a NIR in-memory object */ uintptr_t next_idx; /* Array of write_phi_fixup structs representing phi sources that need to * be resolved in the second pass. */ struct util_dynarray phi_fixups; } write_ctx; typedef struct { nir_shader *nir; struct blob_reader *blob; /* the next index to assign to a NIR in-memory object */ uintptr_t next_idx; /* The length of the index -> object table */ uintptr_t idx_table_len; /* map from index to deserialized pointer */ void **idx_table; /* List of phi sources. */ struct list_head phi_srcs; } read_ctx; static void write_add_object(write_ctx *ctx, const void *obj) { uintptr_t index = ctx->next_idx++; _mesa_hash_table_insert(ctx->remap_table, obj, (void *) index); } static uintptr_t write_lookup_object(write_ctx *ctx, const void *obj) { struct hash_entry *entry = _mesa_hash_table_search(ctx->remap_table, obj); assert(entry); return (uintptr_t) entry->data; } static void write_object(write_ctx *ctx, const void *obj) { blob_write_intptr(ctx->blob, write_lookup_object(ctx, obj)); } static void read_add_object(read_ctx *ctx, void *obj) { assert(ctx->next_idx < ctx->idx_table_len); ctx->idx_table[ctx->next_idx++] = obj; } static void * read_lookup_object(read_ctx *ctx, uintptr_t idx) { assert(idx < ctx->idx_table_len); return ctx->idx_table[idx]; } static void * read_object(read_ctx *ctx) { return read_lookup_object(ctx, blob_read_intptr(ctx->blob)); } static void write_constant(write_ctx *ctx, const nir_constant *c) { blob_write_bytes(ctx->blob, c->values, sizeof(c->values)); blob_write_uint32(ctx->blob, c->num_elements); for (unsigned i = 0; i < c->num_elements; i++) write_constant(ctx, c->elements[i]); } static nir_constant * read_constant(read_ctx *ctx, nir_variable *nvar) { nir_constant *c = ralloc(nvar, nir_constant); blob_copy_bytes(ctx->blob, (uint8_t *)c->values, sizeof(c->values)); c->num_elements = blob_read_uint32(ctx->blob); c->elements = ralloc_array(nvar, nir_constant *, c->num_elements); for (unsigned i = 0; i < c->num_elements; i++) c->elements[i] = read_constant(ctx, nvar); return c; } static void write_variable(write_ctx *ctx, const nir_variable *var) { write_add_object(ctx, var); encode_type_to_blob(ctx->blob, var->type); blob_write_uint32(ctx->blob, !!(var->name)); if (var->name) blob_write_string(ctx->blob, var->name); blob_write_bytes(ctx->blob, (uint8_t *) &var->data, sizeof(var->data)); blob_write_uint32(ctx->blob, var->num_state_slots); for (unsigned i = 0; i < var->num_state_slots; i++) { for (unsigned j = 0; j < STATE_LENGTH; j++) blob_write_uint32(ctx->blob, var->state_slots[i].tokens[j]); blob_write_uint32(ctx->blob, var->state_slots[i].swizzle); } blob_write_uint32(ctx->blob, !!(var->constant_initializer)); if (var->constant_initializer) write_constant(ctx, var->constant_initializer); blob_write_uint32(ctx->blob, !!(var->interface_type)); if (var->interface_type) encode_type_to_blob(ctx->blob, var->interface_type); blob_write_uint32(ctx->blob, var->num_members); if (var->num_members > 0) { blob_write_bytes(ctx->blob, (uint8_t *) var->members, var->num_members * sizeof(*var->members)); } } static nir_variable * read_variable(read_ctx *ctx) { nir_variable *var = rzalloc(ctx->nir, nir_variable); read_add_object(ctx, var); var->type = decode_type_from_blob(ctx->blob); bool has_name = blob_read_uint32(ctx->blob); if (has_name) { const char *name = blob_read_string(ctx->blob); var->name = ralloc_strdup(var, name); } else { var->name = NULL; } blob_copy_bytes(ctx->blob, (uint8_t *) &var->data, sizeof(var->data)); var->num_state_slots = blob_read_uint32(ctx->blob); if (var->num_state_slots != 0) { var->state_slots = ralloc_array(var, nir_state_slot, var->num_state_slots); for (unsigned i = 0; i < var->num_state_slots; i++) { for (unsigned j = 0; j < STATE_LENGTH; j++) var->state_slots[i].tokens[j] = blob_read_uint32(ctx->blob); var->state_slots[i].swizzle = blob_read_uint32(ctx->blob); } } bool has_const_initializer = blob_read_uint32(ctx->blob); if (has_const_initializer) var->constant_initializer = read_constant(ctx, var); else var->constant_initializer = NULL; bool has_interface_type = blob_read_uint32(ctx->blob); if (has_interface_type) var->interface_type = decode_type_from_blob(ctx->blob); else var->interface_type = NULL; var->num_members = blob_read_uint32(ctx->blob); if (var->num_members > 0) { var->members = ralloc_array(var, struct nir_variable_data, var->num_members); blob_copy_bytes(ctx->blob, (uint8_t *) var->members, var->num_members * sizeof(*var->members)); } return var; } static void write_var_list(write_ctx *ctx, const struct exec_list *src) { blob_write_uint32(ctx->blob, exec_list_length(src)); foreach_list_typed(nir_variable, var, node, src) { write_variable(ctx, var); } } static void read_var_list(read_ctx *ctx, struct exec_list *dst) { exec_list_make_empty(dst); unsigned num_vars = blob_read_uint32(ctx->blob); for (unsigned i = 0; i < num_vars; i++) { nir_variable *var = read_variable(ctx); exec_list_push_tail(dst, &var->node); } } static void write_register(write_ctx *ctx, const nir_register *reg) { write_add_object(ctx, reg); blob_write_uint32(ctx->blob, reg->num_components); blob_write_uint32(ctx->blob, reg->bit_size); blob_write_uint32(ctx->blob, reg->num_array_elems); blob_write_uint32(ctx->blob, reg->index); blob_write_uint32(ctx->blob, !!(reg->name)); if (reg->name) blob_write_string(ctx->blob, reg->name); } static nir_register * read_register(read_ctx *ctx) { nir_register *reg = ralloc(ctx->nir, nir_register); read_add_object(ctx, reg); reg->num_components = blob_read_uint32(ctx->blob); reg->bit_size = blob_read_uint32(ctx->blob); reg->num_array_elems = blob_read_uint32(ctx->blob); reg->index = blob_read_uint32(ctx->blob); bool has_name = blob_read_uint32(ctx->blob); if (has_name) { const char *name = blob_read_string(ctx->blob); reg->name = ralloc_strdup(reg, name); } else { reg->name = NULL; } list_inithead(®->uses); list_inithead(®->defs); list_inithead(®->if_uses); return reg; } static void write_reg_list(write_ctx *ctx, const struct exec_list *src) { blob_write_uint32(ctx->blob, exec_list_length(src)); foreach_list_typed(nir_register, reg, node, src) write_register(ctx, reg); } static void read_reg_list(read_ctx *ctx, struct exec_list *dst) { exec_list_make_empty(dst); unsigned num_regs = blob_read_uint32(ctx->blob); for (unsigned i = 0; i < num_regs; i++) { nir_register *reg = read_register(ctx); exec_list_push_tail(dst, ®->node); } } static void write_src(write_ctx *ctx, const nir_src *src) { /* Since sources are very frequent, we try to save some space when storing * them. In particular, we store whether the source is a register and * whether the register has an indirect index in the low two bits. We can * assume that the high two bits of the index are zero, since otherwise our * address space would've been exhausted allocating the remap table! */ if (src->is_ssa) { uintptr_t idx = write_lookup_object(ctx, src->ssa) << 2; idx |= 1; blob_write_intptr(ctx->blob, idx); } else { uintptr_t idx = write_lookup_object(ctx, src->reg.reg) << 2; if (src->reg.indirect) idx |= 2; blob_write_intptr(ctx->blob, idx); blob_write_uint32(ctx->blob, src->reg.base_offset); if (src->reg.indirect) { write_src(ctx, src->reg.indirect); } } } static void read_src(read_ctx *ctx, nir_src *src, void *mem_ctx) { uintptr_t val = blob_read_intptr(ctx->blob); uintptr_t idx = val >> 2; src->is_ssa = val & 0x1; if (src->is_ssa) { src->ssa = read_lookup_object(ctx, idx); } else { bool is_indirect = val & 0x2; src->reg.reg = read_lookup_object(ctx, idx); src->reg.base_offset = blob_read_uint32(ctx->blob); if (is_indirect) { src->reg.indirect = ralloc(mem_ctx, nir_src); read_src(ctx, src->reg.indirect, mem_ctx); } else { src->reg.indirect = NULL; } } } static void write_dest(write_ctx *ctx, const nir_dest *dst) { uint32_t val = dst->is_ssa; if (dst->is_ssa) { val |= !!(dst->ssa.name) << 1; val |= dst->ssa.num_components << 2; val |= dst->ssa.bit_size << 5; } else { val |= !!(dst->reg.indirect) << 1; } blob_write_uint32(ctx->blob, val); if (dst->is_ssa) { write_add_object(ctx, &dst->ssa); if (dst->ssa.name) blob_write_string(ctx->blob, dst->ssa.name); } else { blob_write_intptr(ctx->blob, write_lookup_object(ctx, dst->reg.reg)); blob_write_uint32(ctx->blob, dst->reg.base_offset); if (dst->reg.indirect) write_src(ctx, dst->reg.indirect); } } static void read_dest(read_ctx *ctx, nir_dest *dst, nir_instr *instr) { uint32_t val = blob_read_uint32(ctx->blob); bool is_ssa = val & 0x1; if (is_ssa) { bool has_name = val & 0x2; unsigned num_components = (val >> 2) & 0x7; unsigned bit_size = val >> 5; char *name = has_name ? blob_read_string(ctx->blob) : NULL; nir_ssa_dest_init(instr, dst, num_components, bit_size, name); read_add_object(ctx, &dst->ssa); } else { bool is_indirect = val & 0x2; dst->reg.reg = read_object(ctx); dst->reg.base_offset = blob_read_uint32(ctx->blob); if (is_indirect) { dst->reg.indirect = ralloc(instr, nir_src); read_src(ctx, dst->reg.indirect, instr); } } } static void write_alu(write_ctx *ctx, const nir_alu_instr *alu) { blob_write_uint32(ctx->blob, alu->op); uint32_t flags = alu->exact; flags |= alu->dest.saturate << 1; flags |= alu->dest.write_mask << 2; blob_write_uint32(ctx->blob, flags); write_dest(ctx, &alu->dest.dest); for (unsigned i = 0; i < nir_op_infos[alu->op].num_inputs; i++) { write_src(ctx, &alu->src[i].src); flags = alu->src[i].negate; flags |= alu->src[i].abs << 1; for (unsigned j = 0; j < 4; j++) flags |= alu->src[i].swizzle[j] << (2 + 2 * j); blob_write_uint32(ctx->blob, flags); } } static nir_alu_instr * read_alu(read_ctx *ctx) { nir_op op = blob_read_uint32(ctx->blob); nir_alu_instr *alu = nir_alu_instr_create(ctx->nir, op); uint32_t flags = blob_read_uint32(ctx->blob); alu->exact = flags & 1; alu->dest.saturate = flags & 2; alu->dest.write_mask = flags >> 2; read_dest(ctx, &alu->dest.dest, &alu->instr); for (unsigned i = 0; i < nir_op_infos[op].num_inputs; i++) { read_src(ctx, &alu->src[i].src, &alu->instr); flags = blob_read_uint32(ctx->blob); alu->src[i].negate = flags & 1; alu->src[i].abs = flags & 2; for (unsigned j = 0; j < 4; j++) alu->src[i].swizzle[j] = (flags >> (2 * j + 2)) & 3; } return alu; } static void write_deref(write_ctx *ctx, const nir_deref_instr *deref) { blob_write_uint32(ctx->blob, deref->deref_type); blob_write_uint32(ctx->blob, deref->mode); encode_type_to_blob(ctx->blob, deref->type); write_dest(ctx, &deref->dest); if (deref->deref_type == nir_deref_type_var) { write_object(ctx, deref->var); return; } write_src(ctx, &deref->parent); switch (deref->deref_type) { case nir_deref_type_struct: blob_write_uint32(ctx->blob, deref->strct.index); break; case nir_deref_type_array: case nir_deref_type_ptr_as_array: write_src(ctx, &deref->arr.index); break; case nir_deref_type_cast: blob_write_uint32(ctx->blob, deref->cast.ptr_stride); break; case nir_deref_type_array_wildcard: /* Nothing to do */ break; default: unreachable("Invalid deref type"); } } static nir_deref_instr * read_deref(read_ctx *ctx) { nir_deref_type deref_type = blob_read_uint32(ctx->blob); nir_deref_instr *deref = nir_deref_instr_create(ctx->nir, deref_type); deref->mode = blob_read_uint32(ctx->blob); deref->type = decode_type_from_blob(ctx->blob); read_dest(ctx, &deref->dest, &deref->instr); if (deref_type == nir_deref_type_var) { deref->var = read_object(ctx); return deref; } read_src(ctx, &deref->parent, &deref->instr); switch (deref->deref_type) { case nir_deref_type_struct: deref->strct.index = blob_read_uint32(ctx->blob); break; case nir_deref_type_array: case nir_deref_type_ptr_as_array: read_src(ctx, &deref->arr.index, &deref->instr); break; case nir_deref_type_cast: deref->cast.ptr_stride = blob_read_uint32(ctx->blob); break; case nir_deref_type_array_wildcard: /* Nothing to do */ break; default: unreachable("Invalid deref type"); } return deref; } static void write_intrinsic(write_ctx *ctx, const nir_intrinsic_instr *intrin) { blob_write_uint32(ctx->blob, intrin->intrinsic); unsigned num_srcs = nir_intrinsic_infos[intrin->intrinsic].num_srcs; unsigned num_indices = nir_intrinsic_infos[intrin->intrinsic].num_indices; blob_write_uint32(ctx->blob, intrin->num_components); if (nir_intrinsic_infos[intrin->intrinsic].has_dest) write_dest(ctx, &intrin->dest); for (unsigned i = 0; i < num_srcs; i++) write_src(ctx, &intrin->src[i]); for (unsigned i = 0; i < num_indices; i++) blob_write_uint32(ctx->blob, intrin->const_index[i]); } static nir_intrinsic_instr * read_intrinsic(read_ctx *ctx) { nir_intrinsic_op op = blob_read_uint32(ctx->blob); nir_intrinsic_instr *intrin = nir_intrinsic_instr_create(ctx->nir, op); unsigned num_srcs = nir_intrinsic_infos[op].num_srcs; unsigned num_indices = nir_intrinsic_infos[op].num_indices; intrin->num_components = blob_read_uint32(ctx->blob); if (nir_intrinsic_infos[op].has_dest) read_dest(ctx, &intrin->dest, &intrin->instr); for (unsigned i = 0; i < num_srcs; i++) read_src(ctx, &intrin->src[i], &intrin->instr); for (unsigned i = 0; i < num_indices; i++) intrin->const_index[i] = blob_read_uint32(ctx->blob); return intrin; } static void write_load_const(write_ctx *ctx, const nir_load_const_instr *lc) { uint32_t val = lc->def.num_components; val |= lc->def.bit_size << 3; blob_write_uint32(ctx->blob, val); blob_write_bytes(ctx->blob, lc->value, sizeof(*lc->value) * lc->def.num_components); write_add_object(ctx, &lc->def); } static nir_load_const_instr * read_load_const(read_ctx *ctx) { uint32_t val = blob_read_uint32(ctx->blob); nir_load_const_instr *lc = nir_load_const_instr_create(ctx->nir, val & 0x7, val >> 3); blob_copy_bytes(ctx->blob, lc->value, sizeof(*lc->value) * lc->def.num_components); read_add_object(ctx, &lc->def); return lc; } static void write_ssa_undef(write_ctx *ctx, const nir_ssa_undef_instr *undef) { uint32_t val = undef->def.num_components; val |= undef->def.bit_size << 3; blob_write_uint32(ctx->blob, val); write_add_object(ctx, &undef->def); } static nir_ssa_undef_instr * read_ssa_undef(read_ctx *ctx) { uint32_t val = blob_read_uint32(ctx->blob); nir_ssa_undef_instr *undef = nir_ssa_undef_instr_create(ctx->nir, val & 0x7, val >> 3); read_add_object(ctx, &undef->def); return undef; } union packed_tex_data { uint32_t u32; struct { enum glsl_sampler_dim sampler_dim:4; nir_alu_type dest_type:8; unsigned coord_components:3; unsigned is_array:1; unsigned is_shadow:1; unsigned is_new_style_shadow:1; unsigned component:2; unsigned unused:10; /* Mark unused for valgrind. */ } u; }; static void write_tex(write_ctx *ctx, const nir_tex_instr *tex) { blob_write_uint32(ctx->blob, tex->num_srcs); blob_write_uint32(ctx->blob, tex->op); blob_write_uint32(ctx->blob, tex->texture_index); blob_write_uint32(ctx->blob, tex->texture_array_size); blob_write_uint32(ctx->blob, tex->sampler_index); blob_write_bytes(ctx->blob, tex->tg4_offsets, sizeof(tex->tg4_offsets)); STATIC_ASSERT(sizeof(union packed_tex_data) == sizeof(uint32_t)); union packed_tex_data packed = { .u.sampler_dim = tex->sampler_dim, .u.dest_type = tex->dest_type, .u.coord_components = tex->coord_components, .u.is_array = tex->is_array, .u.is_shadow = tex->is_shadow, .u.is_new_style_shadow = tex->is_new_style_shadow, .u.component = tex->component, }; blob_write_uint32(ctx->blob, packed.u32); write_dest(ctx, &tex->dest); for (unsigned i = 0; i < tex->num_srcs; i++) { blob_write_uint32(ctx->blob, tex->src[i].src_type); write_src(ctx, &tex->src[i].src); } } static nir_tex_instr * read_tex(read_ctx *ctx) { unsigned num_srcs = blob_read_uint32(ctx->blob); nir_tex_instr *tex = nir_tex_instr_create(ctx->nir, num_srcs); tex->op = blob_read_uint32(ctx->blob); tex->texture_index = blob_read_uint32(ctx->blob); tex->texture_array_size = blob_read_uint32(ctx->blob); tex->sampler_index = blob_read_uint32(ctx->blob); blob_copy_bytes(ctx->blob, tex->tg4_offsets, sizeof(tex->tg4_offsets)); union packed_tex_data packed; packed.u32 = blob_read_uint32(ctx->blob); tex->sampler_dim = packed.u.sampler_dim; tex->dest_type = packed.u.dest_type; tex->coord_components = packed.u.coord_components; tex->is_array = packed.u.is_array; tex->is_shadow = packed.u.is_shadow; tex->is_new_style_shadow = packed.u.is_new_style_shadow; tex->component = packed.u.component; read_dest(ctx, &tex->dest, &tex->instr); for (unsigned i = 0; i < tex->num_srcs; i++) { tex->src[i].src_type = blob_read_uint32(ctx->blob); read_src(ctx, &tex->src[i].src, &tex->instr); } return tex; } static void write_phi(write_ctx *ctx, const nir_phi_instr *phi) { /* Phi nodes are special, since they may reference SSA definitions and * basic blocks that don't exist yet. We leave two empty uintptr_t's here, * and then store enough information so that a later fixup pass can fill * them in correctly. */ write_dest(ctx, &phi->dest); blob_write_uint32(ctx->blob, exec_list_length(&phi->srcs)); nir_foreach_phi_src(src, phi) { assert(src->src.is_ssa); size_t blob_offset = blob_reserve_intptr(ctx->blob); MAYBE_UNUSED size_t blob_offset2 = blob_reserve_intptr(ctx->blob); assert(blob_offset + sizeof(uintptr_t) == blob_offset2); write_phi_fixup fixup = { .blob_offset = blob_offset, .src = src->src.ssa, .block = src->pred, }; util_dynarray_append(&ctx->phi_fixups, write_phi_fixup, fixup); } } static void write_fixup_phis(write_ctx *ctx) { util_dynarray_foreach(&ctx->phi_fixups, write_phi_fixup, fixup) { uintptr_t *blob_ptr = (uintptr_t *)(ctx->blob->data + fixup->blob_offset); blob_ptr[0] = write_lookup_object(ctx, fixup->src); blob_ptr[1] = write_lookup_object(ctx, fixup->block); } util_dynarray_clear(&ctx->phi_fixups); } static nir_phi_instr * read_phi(read_ctx *ctx, nir_block *blk) { nir_phi_instr *phi = nir_phi_instr_create(ctx->nir); read_dest(ctx, &phi->dest, &phi->instr); unsigned num_srcs = blob_read_uint32(ctx->blob); /* For similar reasons as before, we just store the index directly into the * pointer, and let a later pass resolve the phi sources. * * In order to ensure that the copied sources (which are just the indices * from the blob 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(blk, &phi->instr); for (unsigned i = 0; i < num_srcs; i++) { nir_phi_src *src = ralloc(phi, nir_phi_src); src->src.is_ssa = true; src->src.ssa = (nir_ssa_def *) blob_read_intptr(ctx->blob); src->pred = (nir_block *) blob_read_intptr(ctx->blob); /* 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. */ src->src.parent_instr = &phi->instr; /* Stash it in the list of phi sources. We'll walk this list and fix up * sources at the very end of read_function_impl. */ list_add(&src->src.use_link, &ctx->phi_srcs); exec_list_push_tail(&phi->srcs, &src->node); } return phi; } static void read_fixup_phis(read_ctx *ctx) { list_for_each_entry_safe(nir_phi_src, src, &ctx->phi_srcs, src.use_link) { src->pred = read_lookup_object(ctx, (uintptr_t)src->pred); src->src.ssa = read_lookup_object(ctx, (uintptr_t)src->src.ssa); /* Remove from this list */ list_del(&src->src.use_link); list_addtail(&src->src.use_link, &src->src.ssa->uses); } assert(list_empty(&ctx->phi_srcs)); } static void write_jump(write_ctx *ctx, const nir_jump_instr *jmp) { blob_write_uint32(ctx->blob, jmp->type); } static nir_jump_instr * read_jump(read_ctx *ctx) { nir_jump_type type = blob_read_uint32(ctx->blob); nir_jump_instr *jmp = nir_jump_instr_create(ctx->nir, type); return jmp; } static void write_call(write_ctx *ctx, const nir_call_instr *call) { blob_write_intptr(ctx->blob, write_lookup_object(ctx, call->callee)); for (unsigned i = 0; i < call->num_params; i++) write_src(ctx, &call->params[i]); } static nir_call_instr * read_call(read_ctx *ctx) { nir_function *callee = read_object(ctx); nir_call_instr *call = nir_call_instr_create(ctx->nir, callee); for (unsigned i = 0; i < call->num_params; i++) read_src(ctx, &call->params[i], call); return call; } static void write_instr(write_ctx *ctx, const nir_instr *instr) { blob_write_uint32(ctx->blob, instr->type); switch (instr->type) { case nir_instr_type_alu: write_alu(ctx, nir_instr_as_alu(instr)); break; case nir_instr_type_deref: write_deref(ctx, nir_instr_as_deref(instr)); break; case nir_instr_type_intrinsic: write_intrinsic(ctx, nir_instr_as_intrinsic(instr)); break; case nir_instr_type_load_const: write_load_const(ctx, nir_instr_as_load_const(instr)); break; case nir_instr_type_ssa_undef: write_ssa_undef(ctx, nir_instr_as_ssa_undef(instr)); break; case nir_instr_type_tex: write_tex(ctx, nir_instr_as_tex(instr)); break; case nir_instr_type_phi: write_phi(ctx, nir_instr_as_phi(instr)); break; case nir_instr_type_jump: write_jump(ctx, nir_instr_as_jump(instr)); break; case nir_instr_type_call: write_call(ctx, nir_instr_as_call(instr)); break; case nir_instr_type_parallel_copy: unreachable("Cannot write parallel copies"); default: unreachable("bad instr type"); } } static void read_instr(read_ctx *ctx, nir_block *block) { nir_instr_type type = blob_read_uint32(ctx->blob); nir_instr *instr; switch (type) { case nir_instr_type_alu: instr = &read_alu(ctx)->instr; break; case nir_instr_type_deref: instr = &read_deref(ctx)->instr; break; case nir_instr_type_intrinsic: instr = &read_intrinsic(ctx)->instr; break; case nir_instr_type_load_const: instr = &read_load_const(ctx)->instr; break; case nir_instr_type_ssa_undef: instr = &read_ssa_undef(ctx)->instr; break; case nir_instr_type_tex: instr = &read_tex(ctx)->instr; break; case nir_instr_type_phi: /* Phi instructions are a bit of a special case when reading 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 read so that we can set their sources up. */ read_phi(ctx, block); return; case nir_instr_type_jump: instr = &read_jump(ctx)->instr; break; case nir_instr_type_call: instr = &read_call(ctx)->instr; break; case nir_instr_type_parallel_copy: unreachable("Cannot read parallel copies"); default: unreachable("bad instr type"); } nir_instr_insert_after_block(block, instr); } static void write_block(write_ctx *ctx, const nir_block *block) { write_add_object(ctx, block); blob_write_uint32(ctx->blob, exec_list_length(&block->instr_list)); nir_foreach_instr(instr, block) write_instr(ctx, instr); } static void read_block(read_ctx *ctx, struct exec_list *cf_list) { /* 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 *block = exec_node_data(nir_block, exec_list_get_tail(cf_list), cf_node.node); read_add_object(ctx, block); unsigned num_instrs = blob_read_uint32(ctx->blob); for (unsigned i = 0; i < num_instrs; i++) { read_instr(ctx, block); } } static void write_cf_list(write_ctx *ctx, const struct exec_list *cf_list); static void read_cf_list(read_ctx *ctx, struct exec_list *cf_list); static void write_if(write_ctx *ctx, nir_if *nif) { write_src(ctx, &nif->condition); write_cf_list(ctx, &nif->then_list); write_cf_list(ctx, &nif->else_list); } static void read_if(read_ctx *ctx, struct exec_list *cf_list) { nir_if *nif = nir_if_create(ctx->nir); read_src(ctx, &nif->condition, nif); nir_cf_node_insert_end(cf_list, &nif->cf_node); read_cf_list(ctx, &nif->then_list); read_cf_list(ctx, &nif->else_list); } static void write_loop(write_ctx *ctx, nir_loop *loop) { write_cf_list(ctx, &loop->body); } static void read_loop(read_ctx *ctx, struct exec_list *cf_list) { nir_loop *loop = nir_loop_create(ctx->nir); nir_cf_node_insert_end(cf_list, &loop->cf_node); read_cf_list(ctx, &loop->body); } static void write_cf_node(write_ctx *ctx, nir_cf_node *cf) { blob_write_uint32(ctx->blob, cf->type); switch (cf->type) { case nir_cf_node_block: write_block(ctx, nir_cf_node_as_block(cf)); break; case nir_cf_node_if: write_if(ctx, nir_cf_node_as_if(cf)); break; case nir_cf_node_loop: write_loop(ctx, nir_cf_node_as_loop(cf)); break; default: unreachable("bad cf type"); } } static void read_cf_node(read_ctx *ctx, struct exec_list *list) { nir_cf_node_type type = blob_read_uint32(ctx->blob); switch (type) { case nir_cf_node_block: read_block(ctx, list); break; case nir_cf_node_if: read_if(ctx, list); break; case nir_cf_node_loop: read_loop(ctx, list); break; default: unreachable("bad cf type"); } } static void write_cf_list(write_ctx *ctx, const struct exec_list *cf_list) { blob_write_uint32(ctx->blob, exec_list_length(cf_list)); foreach_list_typed(nir_cf_node, cf, node, cf_list) { write_cf_node(ctx, cf); } } static void read_cf_list(read_ctx *ctx, struct exec_list *cf_list) { uint32_t num_cf_nodes = blob_read_uint32(ctx->blob); for (unsigned i = 0; i < num_cf_nodes; i++) read_cf_node(ctx, cf_list); } static void write_function_impl(write_ctx *ctx, const nir_function_impl *fi) { write_var_list(ctx, &fi->locals); write_reg_list(ctx, &fi->registers); blob_write_uint32(ctx->blob, fi->reg_alloc); write_cf_list(ctx, &fi->body); write_fixup_phis(ctx); } static nir_function_impl * read_function_impl(read_ctx *ctx, nir_function *fxn) { nir_function_impl *fi = nir_function_impl_create_bare(ctx->nir); fi->function = fxn; read_var_list(ctx, &fi->locals); read_reg_list(ctx, &fi->registers); fi->reg_alloc = blob_read_uint32(ctx->blob); read_cf_list(ctx, &fi->body); read_fixup_phis(ctx); fi->valid_metadata = 0; return fi; } static void write_function(write_ctx *ctx, const nir_function *fxn) { blob_write_uint32(ctx->blob, !!(fxn->name)); if (fxn->name) blob_write_string(ctx->blob, fxn->name); write_add_object(ctx, fxn); blob_write_uint32(ctx->blob, fxn->num_params); for (unsigned i = 0; i < fxn->num_params; i++) { uint32_t val = ((uint32_t)fxn->params[i].num_components) | ((uint32_t)fxn->params[i].bit_size) << 8; blob_write_uint32(ctx->blob, val); } blob_write_uint32(ctx->blob, fxn->is_entrypoint); /* At first glance, it looks like we should write the function_impl here. * However, call instructions need to be able to reference at least the * function and those will get processed as we write the function_impls. * We stop here and write function_impls as a second pass. */ } static void read_function(read_ctx *ctx) { bool has_name = blob_read_uint32(ctx->blob); char *name = has_name ? blob_read_string(ctx->blob) : NULL; nir_function *fxn = nir_function_create(ctx->nir, name); read_add_object(ctx, fxn); fxn->num_params = blob_read_uint32(ctx->blob); fxn->params = ralloc_array(fxn, nir_parameter, fxn->num_params); for (unsigned i = 0; i < fxn->num_params; i++) { uint32_t val = blob_read_uint32(ctx->blob); fxn->params[i].num_components = val & 0xff; fxn->params[i].bit_size = (val >> 8) & 0xff; } fxn->is_entrypoint = blob_read_uint32(ctx->blob); } void nir_serialize(struct blob *blob, const nir_shader *nir) { write_ctx ctx; ctx.remap_table = _mesa_pointer_hash_table_create(NULL); ctx.next_idx = 0; ctx.blob = blob; ctx.nir = nir; util_dynarray_init(&ctx.phi_fixups, NULL); size_t idx_size_offset = blob_reserve_intptr(blob); struct shader_info info = nir->info; uint32_t strings = 0; if (info.name) strings |= 0x1; if (info.label) strings |= 0x2; blob_write_uint32(blob, strings); if (info.name) blob_write_string(blob, info.name); if (info.label) blob_write_string(blob, info.label); info.name = info.label = NULL; blob_write_bytes(blob, (uint8_t *) &info, sizeof(info)); write_var_list(&ctx, &nir->uniforms); write_var_list(&ctx, &nir->inputs); write_var_list(&ctx, &nir->outputs); write_var_list(&ctx, &nir->shared); write_var_list(&ctx, &nir->globals); write_var_list(&ctx, &nir->system_values); blob_write_uint32(blob, nir->num_inputs); blob_write_uint32(blob, nir->num_uniforms); blob_write_uint32(blob, nir->num_outputs); blob_write_uint32(blob, nir->num_shared); blob_write_uint32(blob, nir->scratch_size); blob_write_uint32(blob, exec_list_length(&nir->functions)); nir_foreach_function(fxn, nir) { write_function(&ctx, fxn); } nir_foreach_function(fxn, nir) { write_function_impl(&ctx, fxn->impl); } blob_write_uint32(blob, nir->constant_data_size); if (nir->constant_data_size > 0) blob_write_bytes(blob, nir->constant_data, nir->constant_data_size); *(uintptr_t *)(blob->data + idx_size_offset) = ctx.next_idx; _mesa_hash_table_destroy(ctx.remap_table, NULL); util_dynarray_fini(&ctx.phi_fixups); } nir_shader * nir_deserialize(void *mem_ctx, const struct nir_shader_compiler_options *options, struct blob_reader *blob) { read_ctx ctx; ctx.blob = blob; list_inithead(&ctx.phi_srcs); ctx.idx_table_len = blob_read_intptr(blob); ctx.idx_table = calloc(ctx.idx_table_len, sizeof(uintptr_t)); ctx.next_idx = 0; uint32_t strings = blob_read_uint32(blob); char *name = (strings & 0x1) ? blob_read_string(blob) : NULL; char *label = (strings & 0x2) ? blob_read_string(blob) : NULL; struct shader_info info; blob_copy_bytes(blob, (uint8_t *) &info, sizeof(info)); ctx.nir = nir_shader_create(mem_ctx, info.stage, options, NULL); info.name = name ? ralloc_strdup(ctx.nir, name) : NULL; info.label = label ? ralloc_strdup(ctx.nir, label) : NULL; ctx.nir->info = info; read_var_list(&ctx, &ctx.nir->uniforms); read_var_list(&ctx, &ctx.nir->inputs); read_var_list(&ctx, &ctx.nir->outputs); read_var_list(&ctx, &ctx.nir->shared); read_var_list(&ctx, &ctx.nir->globals); read_var_list(&ctx, &ctx.nir->system_values); ctx.nir->num_inputs = blob_read_uint32(blob); ctx.nir->num_uniforms = blob_read_uint32(blob); ctx.nir->num_outputs = blob_read_uint32(blob); ctx.nir->num_shared = blob_read_uint32(blob); ctx.nir->scratch_size = blob_read_uint32(blob); unsigned num_functions = blob_read_uint32(blob); for (unsigned i = 0; i < num_functions; i++) read_function(&ctx); nir_foreach_function(fxn, ctx.nir) fxn->impl = read_function_impl(&ctx, fxn); ctx.nir->constant_data_size = blob_read_uint32(blob); if (ctx.nir->constant_data_size > 0) { ctx.nir->constant_data = ralloc_size(ctx.nir, ctx.nir->constant_data_size); blob_copy_bytes(blob, ctx.nir->constant_data, ctx.nir->constant_data_size); } free(ctx.idx_table); return ctx.nir; } void nir_shader_serialize_deserialize(nir_shader *shader) { const struct nir_shader_compiler_options *options = shader->options; struct blob writer; blob_init(&writer); nir_serialize(&writer, shader); /* Delete all of dest's ralloc children but leave dest alone */ void *dead_ctx = ralloc_context(NULL); ralloc_adopt(dead_ctx, shader); ralloc_free(dead_ctx); dead_ctx = ralloc_context(NULL); struct blob_reader reader; blob_reader_init(&reader, writer.data, writer.size); nir_shader *copy = nir_deserialize(dead_ctx, options, &reader); blob_finish(&writer); nir_shader_replace(shader, copy); ralloc_free(dead_ctx); }