/* * Copyright 2018 Collabora Ltd. * * 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 * on the rights to use, copy, modify, merge, publish, distribute, sub * license, 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 NON-INFRINGEMENT. IN NO EVENT SHALL * THE AUTHOR(S) AND/OR THEIR SUPPLIERS 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 "spirv_builder.h" #include "util/macros.h" #include "util/set.h" #include "util/ralloc.h" #include "util/u_bitcast.h" #include "util/u_memory.h" #include "util/half_float.h" #include "util/hash_table.h" #define XXH_INLINE_ALL #include "util/xxhash.h" #include #include #include static bool spirv_buffer_grow(struct spirv_buffer *b, void *mem_ctx, size_t needed) { size_t new_room = MAX3(64, (b->room * 3) / 2, needed); uint32_t *new_words = reralloc_size(mem_ctx, b->words, new_room * sizeof(uint32_t)); if (!new_words) return false; b->words = new_words; b->room = new_room; return true; } static inline bool spirv_buffer_prepare(struct spirv_buffer *b, void *mem_ctx, size_t needed) { needed += b->num_words; if (b->room >= b->num_words + needed) return true; return spirv_buffer_grow(b, mem_ctx, needed); } static inline void spirv_buffer_emit_word(struct spirv_buffer *b, uint32_t word) { assert(b->num_words < b->room); b->words[b->num_words++] = word; } static int spirv_buffer_emit_string(struct spirv_buffer *b, void *mem_ctx, const char *str) { int pos = 0; uint32_t word = 0; while (str[pos] != '\0') { word |= str[pos] << (8 * (pos % 4)); if (++pos % 4 == 0) { spirv_buffer_prepare(b, mem_ctx, 1); spirv_buffer_emit_word(b, word); word = 0; } } spirv_buffer_prepare(b, mem_ctx, 1); spirv_buffer_emit_word(b, word); return 1 + pos / 4; } void spirv_builder_emit_cap(struct spirv_builder *b, SpvCapability cap) { if (!b->caps) b->caps = _mesa_set_create_u32_keys(b->mem_ctx); assert(b->caps); _mesa_set_add(b->caps, (void*)(uintptr_t)cap); } void spirv_builder_emit_extension(struct spirv_builder *b, const char *name) { size_t pos = b->extensions.num_words; spirv_buffer_prepare(&b->extensions, b->mem_ctx, 1); spirv_buffer_emit_word(&b->extensions, SpvOpExtension); int len = spirv_buffer_emit_string(&b->extensions, b->mem_ctx, name); b->extensions.words[pos] |= (1 + len) << 16; } void spirv_builder_emit_source(struct spirv_builder *b, SpvSourceLanguage lang, uint32_t version) { spirv_buffer_prepare(&b->debug_names, b->mem_ctx, 3); spirv_buffer_emit_word(&b->debug_names, SpvOpSource | (3 << 16)); spirv_buffer_emit_word(&b->debug_names, lang); spirv_buffer_emit_word(&b->debug_names, version); } void spirv_builder_emit_mem_model(struct spirv_builder *b, SpvAddressingModel addr_model, SpvMemoryModel mem_model) { spirv_buffer_prepare(&b->memory_model, b->mem_ctx, 3); spirv_buffer_emit_word(&b->memory_model, SpvOpMemoryModel | (3 << 16)); spirv_buffer_emit_word(&b->memory_model, addr_model); spirv_buffer_emit_word(&b->memory_model, mem_model); } void spirv_builder_emit_entry_point(struct spirv_builder *b, SpvExecutionModel exec_model, SpvId entry_point, const char *name, const SpvId interfaces[], size_t num_interfaces) { size_t pos = b->entry_points.num_words; spirv_buffer_prepare(&b->entry_points, b->mem_ctx, 3); spirv_buffer_emit_word(&b->entry_points, SpvOpEntryPoint); spirv_buffer_emit_word(&b->entry_points, exec_model); spirv_buffer_emit_word(&b->entry_points, entry_point); int len = spirv_buffer_emit_string(&b->entry_points, b->mem_ctx, name); b->entry_points.words[pos] |= (3 + len + num_interfaces) << 16; spirv_buffer_prepare(&b->entry_points, b->mem_ctx, num_interfaces); for (int i = 0; i < num_interfaces; ++i) spirv_buffer_emit_word(&b->entry_points, interfaces[i]); } void spirv_builder_emit_exec_mode_literal(struct spirv_builder *b, SpvId entry_point, SpvExecutionMode exec_mode, uint32_t param) { spirv_buffer_prepare(&b->exec_modes, b->mem_ctx, 4); spirv_buffer_emit_word(&b->exec_modes, SpvOpExecutionMode | (4 << 16)); spirv_buffer_emit_word(&b->exec_modes, entry_point); spirv_buffer_emit_word(&b->exec_modes, exec_mode); spirv_buffer_emit_word(&b->exec_modes, param); } void spirv_builder_emit_exec_mode_literal3(struct spirv_builder *b, SpvId entry_point, SpvExecutionMode exec_mode, uint32_t param[3]) { spirv_buffer_prepare(&b->exec_modes, b->mem_ctx, 6); spirv_buffer_emit_word(&b->exec_modes, SpvOpExecutionMode | (6 << 16)); spirv_buffer_emit_word(&b->exec_modes, entry_point); spirv_buffer_emit_word(&b->exec_modes, exec_mode); for (unsigned i = 0; i < 3; i++) spirv_buffer_emit_word(&b->exec_modes, param[i]); } void spirv_builder_emit_exec_mode(struct spirv_builder *b, SpvId entry_point, SpvExecutionMode exec_mode) { spirv_buffer_prepare(&b->exec_modes, b->mem_ctx, 3); spirv_buffer_emit_word(&b->exec_modes, SpvOpExecutionMode | (3 << 16)); spirv_buffer_emit_word(&b->exec_modes, entry_point); spirv_buffer_emit_word(&b->exec_modes, exec_mode); } void spirv_builder_emit_name(struct spirv_builder *b, SpvId target, const char *name) { size_t pos = b->debug_names.num_words; spirv_buffer_prepare(&b->debug_names, b->mem_ctx, 2); spirv_buffer_emit_word(&b->debug_names, SpvOpName); spirv_buffer_emit_word(&b->debug_names, target); int len = spirv_buffer_emit_string(&b->debug_names, b->mem_ctx, name); b->debug_names.words[pos] |= (2 + len) << 16; } static void emit_decoration(struct spirv_builder *b, SpvId target, SpvDecoration decoration, const uint32_t extra_operands[], size_t num_extra_operands) { int words = 3 + num_extra_operands; spirv_buffer_prepare(&b->decorations, b->mem_ctx, words); spirv_buffer_emit_word(&b->decorations, SpvOpDecorate | (words << 16)); spirv_buffer_emit_word(&b->decorations, target); spirv_buffer_emit_word(&b->decorations, decoration); for (int i = 0; i < num_extra_operands; ++i) spirv_buffer_emit_word(&b->decorations, extra_operands[i]); } void spirv_builder_emit_decoration(struct spirv_builder *b, SpvId target, SpvDecoration decoration) { emit_decoration(b, target, decoration, NULL, 0); } void spirv_builder_emit_input_attachment_index(struct spirv_builder *b, SpvId target, uint32_t id) { uint32_t args[] = { id }; emit_decoration(b, target, SpvDecorationInputAttachmentIndex, args, ARRAY_SIZE(args)); } void spirv_builder_emit_specid(struct spirv_builder *b, SpvId target, uint32_t id) { uint32_t args[] = { id }; emit_decoration(b, target, SpvDecorationSpecId, args, ARRAY_SIZE(args)); } void spirv_builder_emit_location(struct spirv_builder *b, SpvId target, uint32_t location) { uint32_t args[] = { location }; emit_decoration(b, target, SpvDecorationLocation, args, ARRAY_SIZE(args)); } void spirv_builder_emit_component(struct spirv_builder *b, SpvId target, uint32_t component) { uint32_t args[] = { component }; emit_decoration(b, target, SpvDecorationComponent, args, ARRAY_SIZE(args)); } void spirv_builder_emit_builtin(struct spirv_builder *b, SpvId target, SpvBuiltIn builtin) { uint32_t args[] = { builtin }; emit_decoration(b, target, SpvDecorationBuiltIn, args, ARRAY_SIZE(args)); } void spirv_builder_emit_vertex(struct spirv_builder *b, uint32_t stream) { unsigned words = 1; SpvOp op = SpvOpEmitVertex; if (stream > 0) { op = SpvOpEmitStreamVertex; words++; } spirv_buffer_prepare(&b->instructions, b->mem_ctx, words); spirv_buffer_emit_word(&b->instructions, op | (words << 16)); if (stream) spirv_buffer_emit_word(&b->instructions, spirv_builder_const_uint(b, 32, stream)); } void spirv_builder_end_primitive(struct spirv_builder *b, uint32_t stream) { unsigned words = 1; SpvOp op = SpvOpEndPrimitive; if (stream > 0) { op = SpvOpEndStreamPrimitive; words++; } spirv_buffer_prepare(&b->instructions, b->mem_ctx, words); spirv_buffer_emit_word(&b->instructions, op | (words << 16)); if (stream) spirv_buffer_emit_word(&b->instructions, spirv_builder_const_uint(b, 32, stream)); } void spirv_builder_emit_descriptor_set(struct spirv_builder *b, SpvId target, uint32_t descriptor_set) { uint32_t args[] = { descriptor_set }; emit_decoration(b, target, SpvDecorationDescriptorSet, args, ARRAY_SIZE(args)); } void spirv_builder_emit_binding(struct spirv_builder *b, SpvId target, uint32_t binding) { uint32_t args[] = { binding }; emit_decoration(b, target, SpvDecorationBinding, args, ARRAY_SIZE(args)); } void spirv_builder_emit_array_stride(struct spirv_builder *b, SpvId target, uint32_t stride) { uint32_t args[] = { stride }; emit_decoration(b, target, SpvDecorationArrayStride, args, ARRAY_SIZE(args)); } void spirv_builder_emit_offset(struct spirv_builder *b, SpvId target, uint32_t offset) { uint32_t args[] = { offset }; emit_decoration(b, target, SpvDecorationOffset, args, ARRAY_SIZE(args)); } void spirv_builder_emit_xfb_buffer(struct spirv_builder *b, SpvId target, uint32_t buffer) { uint32_t args[] = { buffer }; emit_decoration(b, target, SpvDecorationXfbBuffer, args, ARRAY_SIZE(args)); } void spirv_builder_emit_xfb_stride(struct spirv_builder *b, SpvId target, uint32_t stride) { uint32_t args[] = { stride }; emit_decoration(b, target, SpvDecorationXfbStride, args, ARRAY_SIZE(args)); } void spirv_builder_emit_index(struct spirv_builder *b, SpvId target, int index) { uint32_t args[] = { index }; emit_decoration(b, target, SpvDecorationIndex, args, ARRAY_SIZE(args)); } void spirv_builder_emit_stream(struct spirv_builder *b, SpvId target, int stream) { uint32_t args[] = { stream }; emit_decoration(b, target, SpvDecorationStream, args, ARRAY_SIZE(args)); } static void emit_member_decoration(struct spirv_builder *b, SpvId target, uint32_t member, SpvDecoration decoration, const uint32_t extra_operands[], size_t num_extra_operands) { int words = 4 + num_extra_operands; spirv_buffer_prepare(&b->decorations, b->mem_ctx, words); spirv_buffer_emit_word(&b->decorations, SpvOpMemberDecorate | (words << 16)); spirv_buffer_emit_word(&b->decorations, target); spirv_buffer_emit_word(&b->decorations, member); spirv_buffer_emit_word(&b->decorations, decoration); for (int i = 0; i < num_extra_operands; ++i) spirv_buffer_emit_word(&b->decorations, extra_operands[i]); } void spirv_builder_emit_member_offset(struct spirv_builder *b, SpvId target, uint32_t member, uint32_t offset) { uint32_t args[] = { offset }; emit_member_decoration(b, target, member, SpvDecorationOffset, args, ARRAY_SIZE(args)); } SpvId spirv_builder_emit_undef(struct spirv_builder *b, SpvId result_type) { SpvId result = spirv_builder_new_id(b); spirv_buffer_prepare(&b->instructions, b->mem_ctx, 3); spirv_buffer_emit_word(&b->instructions, SpvOpUndef | (3 << 16)); spirv_buffer_emit_word(&b->instructions, result_type); spirv_buffer_emit_word(&b->instructions, result); return result; } void spirv_builder_function(struct spirv_builder *b, SpvId result, SpvId return_type, SpvFunctionControlMask function_control, SpvId function_type) { spirv_buffer_prepare(&b->instructions, b->mem_ctx, 5); spirv_buffer_emit_word(&b->instructions, SpvOpFunction | (5 << 16)); spirv_buffer_emit_word(&b->instructions, return_type); spirv_buffer_emit_word(&b->instructions, result); spirv_buffer_emit_word(&b->instructions, function_control); spirv_buffer_emit_word(&b->instructions, function_type); } void spirv_builder_function_end(struct spirv_builder *b) { spirv_buffer_prepare(&b->instructions, b->mem_ctx, 1); spirv_buffer_emit_word(&b->instructions, SpvOpFunctionEnd | (1 << 16)); } void spirv_builder_label(struct spirv_builder *b, SpvId label) { spirv_buffer_prepare(&b->instructions, b->mem_ctx, 2); spirv_buffer_emit_word(&b->instructions, SpvOpLabel | (2 << 16)); spirv_buffer_emit_word(&b->instructions, label); } void spirv_builder_return(struct spirv_builder *b) { spirv_buffer_prepare(&b->instructions, b->mem_ctx, 1); spirv_buffer_emit_word(&b->instructions, SpvOpReturn | (1 << 16)); } SpvId spirv_builder_emit_load(struct spirv_builder *b, SpvId result_type, SpvId pointer) { return spirv_builder_emit_unop(b, SpvOpLoad, result_type, pointer); } void spirv_builder_emit_store(struct spirv_builder *b, SpvId pointer, SpvId object) { spirv_buffer_prepare(&b->instructions, b->mem_ctx, 3); spirv_buffer_emit_word(&b->instructions, SpvOpStore | (3 << 16)); spirv_buffer_emit_word(&b->instructions, pointer); spirv_buffer_emit_word(&b->instructions, object); } void spirv_builder_emit_atomic_store(struct spirv_builder *b, SpvId pointer, SpvScope scope, SpvMemorySemanticsMask semantics, SpvId object) { spirv_buffer_prepare(&b->instructions, b->mem_ctx, 5); spirv_buffer_emit_word(&b->instructions, SpvOpAtomicStore | (5 << 16)); spirv_buffer_emit_word(&b->instructions, pointer); spirv_buffer_emit_word(&b->instructions, spirv_builder_const_uint(b, 32, scope)); spirv_buffer_emit_word(&b->instructions, spirv_builder_const_uint(b, 32, semantics)); spirv_buffer_emit_word(&b->instructions, object); } SpvId spirv_builder_emit_access_chain(struct spirv_builder *b, SpvId result_type, SpvId base, const SpvId indexes[], size_t num_indexes) { assert(base); assert(result_type); SpvId result = spirv_builder_new_id(b); int words = 4 + num_indexes; spirv_buffer_prepare(&b->instructions, b->mem_ctx, words); spirv_buffer_emit_word(&b->instructions, SpvOpAccessChain | (words << 16)); spirv_buffer_emit_word(&b->instructions, result_type); spirv_buffer_emit_word(&b->instructions, result); spirv_buffer_emit_word(&b->instructions, base); for (int i = 0; i < num_indexes; ++i) { assert(indexes[i]); spirv_buffer_emit_word(&b->instructions, indexes[i]); } return result; } void spirv_builder_emit_interlock(struct spirv_builder *b, bool end) { spirv_buffer_prepare(&b->instructions, b->mem_ctx, 1); spirv_buffer_emit_word(&b->instructions, (end ? SpvOpEndInvocationInterlockEXT : SpvOpBeginInvocationInterlockEXT) | (1 << 16)); } SpvId spirv_builder_emit_unop_const(struct spirv_builder *b, SpvOp op, SpvId result_type, uint64_t operand) { SpvId result = spirv_builder_new_id(b); spirv_buffer_prepare(&b->instructions, b->mem_ctx, 4); spirv_buffer_emit_word(&b->instructions, op | (4 << 16)); spirv_buffer_emit_word(&b->instructions, result_type); spirv_buffer_emit_word(&b->instructions, result); spirv_buffer_emit_word(&b->instructions, spirv_builder_const_uint(b, 32, operand)); return result; } SpvId spirv_builder_emit_unop(struct spirv_builder *b, SpvOp op, SpvId result_type, SpvId operand) { SpvId result = spirv_builder_new_id(b); spirv_buffer_prepare(&b->instructions, b->mem_ctx, 4); spirv_buffer_emit_word(&b->instructions, op | (4 << 16)); spirv_buffer_emit_word(&b->instructions, result_type); spirv_buffer_emit_word(&b->instructions, result); spirv_buffer_emit_word(&b->instructions, operand); return result; } SpvId spirv_builder_emit_binop(struct spirv_builder *b, SpvOp op, SpvId result_type, SpvId operand0, SpvId operand1) { SpvId result = spirv_builder_new_id(b); spirv_buffer_prepare(&b->instructions, b->mem_ctx, 5); spirv_buffer_emit_word(&b->instructions, op | (5 << 16)); spirv_buffer_emit_word(&b->instructions, result_type); spirv_buffer_emit_word(&b->instructions, result); spirv_buffer_emit_word(&b->instructions, operand0); spirv_buffer_emit_word(&b->instructions, operand1); return result; } SpvId spirv_builder_emit_triop(struct spirv_builder *b, SpvOp op, SpvId result_type, SpvId operand0, SpvId operand1, SpvId operand2) { SpvId result = spirv_builder_new_id(b); spirv_buffer_prepare(&b->instructions, b->mem_ctx, 6); spirv_buffer_emit_word(&b->instructions, op | (6 << 16)); spirv_buffer_emit_word(&b->instructions, result_type); spirv_buffer_emit_word(&b->instructions, result); spirv_buffer_emit_word(&b->instructions, operand0); spirv_buffer_emit_word(&b->instructions, operand1); spirv_buffer_emit_word(&b->instructions, operand2); return result; } SpvId spirv_builder_emit_quadop(struct spirv_builder *b, SpvOp op, SpvId result_type, SpvId operand0, SpvId operand1, SpvId operand2, SpvId operand3) { SpvId result = spirv_builder_new_id(b); spirv_buffer_prepare(&b->instructions, b->mem_ctx, 7); spirv_buffer_emit_word(&b->instructions, op | (7 << 16)); spirv_buffer_emit_word(&b->instructions, result_type); spirv_buffer_emit_word(&b->instructions, result); spirv_buffer_emit_word(&b->instructions, operand0); spirv_buffer_emit_word(&b->instructions, operand1); spirv_buffer_emit_word(&b->instructions, operand2); spirv_buffer_emit_word(&b->instructions, operand3); return result; } SpvId spirv_builder_emit_hexop(struct spirv_builder *b, SpvOp op, SpvId result_type, SpvId operand0, SpvId operand1, SpvId operand2, SpvId operand3, SpvId operand4, SpvId operand5) { SpvId result = spirv_builder_new_id(b); spirv_buffer_prepare(&b->instructions, b->mem_ctx, 9); spirv_buffer_emit_word(&b->instructions, op | (9 << 16)); spirv_buffer_emit_word(&b->instructions, result_type); spirv_buffer_emit_word(&b->instructions, result); spirv_buffer_emit_word(&b->instructions, operand0); spirv_buffer_emit_word(&b->instructions, operand1); spirv_buffer_emit_word(&b->instructions, operand2); spirv_buffer_emit_word(&b->instructions, operand3); spirv_buffer_emit_word(&b->instructions, operand4); spirv_buffer_emit_word(&b->instructions, operand5); return result; } SpvId spirv_builder_emit_composite_extract(struct spirv_builder *b, SpvId result_type, SpvId composite, const uint32_t indexes[], size_t num_indexes) { SpvId result = spirv_builder_new_id(b); assert(num_indexes > 0); int words = 4 + num_indexes; spirv_buffer_prepare(&b->instructions, b->mem_ctx, words); spirv_buffer_emit_word(&b->instructions, SpvOpCompositeExtract | (words << 16)); spirv_buffer_emit_word(&b->instructions, result_type); spirv_buffer_emit_word(&b->instructions, result); spirv_buffer_emit_word(&b->instructions, composite); for (int i = 0; i < num_indexes; ++i) spirv_buffer_emit_word(&b->instructions, indexes[i]); return result; } SpvId spirv_builder_emit_composite_construct(struct spirv_builder *b, SpvId result_type, const SpvId constituents[], size_t num_constituents) { SpvId result = spirv_builder_new_id(b); assert(num_constituents > 0); int words = 3 + num_constituents; spirv_buffer_prepare(&b->instructions, b->mem_ctx, words); spirv_buffer_emit_word(&b->instructions, SpvOpCompositeConstruct | (words << 16)); spirv_buffer_emit_word(&b->instructions, result_type); spirv_buffer_emit_word(&b->instructions, result); for (int i = 0; i < num_constituents; ++i) spirv_buffer_emit_word(&b->instructions, constituents[i]); return result; } SpvId spirv_builder_emit_vector_shuffle(struct spirv_builder *b, SpvId result_type, SpvId vector_1, SpvId vector_2, const uint32_t components[], size_t num_components) { SpvId result = spirv_builder_new_id(b); assert(num_components > 0); int words = 5 + num_components; spirv_buffer_prepare(&b->instructions, b->mem_ctx, words); spirv_buffer_emit_word(&b->instructions, SpvOpVectorShuffle | (words << 16)); spirv_buffer_emit_word(&b->instructions, result_type); spirv_buffer_emit_word(&b->instructions, result); spirv_buffer_emit_word(&b->instructions, vector_1); spirv_buffer_emit_word(&b->instructions, vector_2); for (int i = 0; i < num_components; ++i) spirv_buffer_emit_word(&b->instructions, components[i]); return result; } SpvId spirv_builder_emit_vector_extract(struct spirv_builder *b, SpvId result_type, SpvId vector_1, uint32_t component) { SpvId result = spirv_builder_new_id(b); int words = 5; spirv_buffer_prepare(&b->instructions, b->mem_ctx, words); spirv_buffer_emit_word(&b->instructions, SpvOpVectorExtractDynamic | (words << 16)); spirv_buffer_emit_word(&b->instructions, result_type); spirv_buffer_emit_word(&b->instructions, result); spirv_buffer_emit_word(&b->instructions, vector_1); spirv_buffer_emit_word(&b->instructions, spirv_builder_const_uint(b, 32, component)); return result; } SpvId spirv_builder_emit_vector_insert(struct spirv_builder *b, SpvId result_type, SpvId vector_1, SpvId component, uint32_t index) { SpvId result = spirv_builder_new_id(b); int words = 6; spirv_buffer_prepare(&b->instructions, b->mem_ctx, words); spirv_buffer_emit_word(&b->instructions, SpvOpVectorInsertDynamic | (words << 16)); spirv_buffer_emit_word(&b->instructions, result_type); spirv_buffer_emit_word(&b->instructions, result); spirv_buffer_emit_word(&b->instructions, vector_1); spirv_buffer_emit_word(&b->instructions, component); spirv_buffer_emit_word(&b->instructions, spirv_builder_const_uint(b, 32, index)); return result; } void spirv_builder_emit_branch(struct spirv_builder *b, SpvId label) { spirv_buffer_prepare(&b->instructions, b->mem_ctx, 2); spirv_buffer_emit_word(&b->instructions, SpvOpBranch | (2 << 16)); spirv_buffer_emit_word(&b->instructions, label); } void spirv_builder_emit_selection_merge(struct spirv_builder *b, SpvId merge_block, SpvSelectionControlMask selection_control) { spirv_buffer_prepare(&b->instructions, b->mem_ctx, 3); spirv_buffer_emit_word(&b->instructions, SpvOpSelectionMerge | (3 << 16)); spirv_buffer_emit_word(&b->instructions, merge_block); spirv_buffer_emit_word(&b->instructions, selection_control); } void spirv_builder_loop_merge(struct spirv_builder *b, SpvId merge_block, SpvId cont_target, SpvLoopControlMask loop_control) { spirv_buffer_prepare(&b->instructions, b->mem_ctx, 4); spirv_buffer_emit_word(&b->instructions, SpvOpLoopMerge | (4 << 16)); spirv_buffer_emit_word(&b->instructions, merge_block); spirv_buffer_emit_word(&b->instructions, cont_target); spirv_buffer_emit_word(&b->instructions, loop_control); } void spirv_builder_emit_branch_conditional(struct spirv_builder *b, SpvId condition, SpvId true_label, SpvId false_label) { spirv_buffer_prepare(&b->instructions, b->mem_ctx, 4); spirv_buffer_emit_word(&b->instructions, SpvOpBranchConditional | (4 << 16)); spirv_buffer_emit_word(&b->instructions, condition); spirv_buffer_emit_word(&b->instructions, true_label); spirv_buffer_emit_word(&b->instructions, false_label); } SpvId spirv_builder_emit_phi(struct spirv_builder *b, SpvId result_type, size_t num_vars, size_t *position) { SpvId result = spirv_builder_new_id(b); assert(num_vars > 0); int words = 3 + 2 * num_vars; spirv_buffer_prepare(&b->instructions, b->mem_ctx, words); spirv_buffer_emit_word(&b->instructions, SpvOpPhi | (words << 16)); spirv_buffer_emit_word(&b->instructions, result_type); spirv_buffer_emit_word(&b->instructions, result); *position = b->instructions.num_words; for (int i = 0; i < 2 * num_vars; ++i) spirv_buffer_emit_word(&b->instructions, 0); return result; } void spirv_builder_set_phi_operand(struct spirv_builder *b, size_t position, size_t index, SpvId variable, SpvId parent) { b->instructions.words[position + index * 2 + 0] = variable; b->instructions.words[position + index * 2 + 1] = parent; } void spirv_builder_emit_kill(struct spirv_builder *b) { spirv_buffer_prepare(&b->instructions, b->mem_ctx, 1); spirv_buffer_emit_word(&b->instructions, SpvOpKill | (1 << 16)); } SpvId spirv_builder_emit_vote(struct spirv_builder *b, SpvOp op, SpvId src) { return spirv_builder_emit_binop(b, op, spirv_builder_type_bool(b), spirv_builder_const_uint(b, 32, SpvScopeWorkgroup), src); } SpvId spirv_builder_emit_image_sample(struct spirv_builder *b, SpvId result_type, SpvId sampled_image, SpvId coordinate, bool proj, SpvId lod, SpvId bias, SpvId dref, SpvId dx, SpvId dy, SpvId const_offset, SpvId offset) { SpvId result = spirv_builder_new_id(b); int opcode = SpvOpImageSampleImplicitLod; int operands = 5; if (proj) opcode += SpvOpImageSampleProjImplicitLod - SpvOpImageSampleImplicitLod; if (lod || (dx && dy)) opcode += SpvOpImageSampleExplicitLod - SpvOpImageSampleImplicitLod; if (dref) { opcode += SpvOpImageSampleDrefImplicitLod - SpvOpImageSampleImplicitLod; operands++; } SpvImageOperandsMask operand_mask = SpvImageOperandsMaskNone; SpvId extra_operands[5]; int num_extra_operands = 1; if (bias) { extra_operands[num_extra_operands++] = bias; operand_mask |= SpvImageOperandsBiasMask; } if (lod) { extra_operands[num_extra_operands++] = lod; operand_mask |= SpvImageOperandsLodMask; } else if (dx && dy) { extra_operands[num_extra_operands++] = dx; extra_operands[num_extra_operands++] = dy; operand_mask |= SpvImageOperandsGradMask; } assert(!(const_offset && offset)); if (const_offset) { extra_operands[num_extra_operands++] = const_offset; operand_mask |= SpvImageOperandsConstOffsetMask; } else if (offset) { extra_operands[num_extra_operands++] = offset; operand_mask |= SpvImageOperandsOffsetMask; } /* finalize num_extra_operands / extra_operands */ extra_operands[0] = operand_mask; spirv_buffer_prepare(&b->instructions, b->mem_ctx, operands + num_extra_operands); spirv_buffer_emit_word(&b->instructions, opcode | ((operands + num_extra_operands) << 16)); spirv_buffer_emit_word(&b->instructions, result_type); spirv_buffer_emit_word(&b->instructions, result); spirv_buffer_emit_word(&b->instructions, sampled_image); spirv_buffer_emit_word(&b->instructions, coordinate); if (dref) spirv_buffer_emit_word(&b->instructions, dref); for (int i = 0; i < num_extra_operands; ++i) spirv_buffer_emit_word(&b->instructions, extra_operands[i]); return result; } SpvId spirv_builder_emit_image(struct spirv_builder *b, SpvId result_type, SpvId sampled_image) { SpvId result = spirv_builder_new_id(b); spirv_buffer_prepare(&b->instructions, b->mem_ctx, 4); spirv_buffer_emit_word(&b->instructions, SpvOpImage | (4 << 16)); spirv_buffer_emit_word(&b->instructions, result_type); spirv_buffer_emit_word(&b->instructions, result); spirv_buffer_emit_word(&b->instructions, sampled_image); return result; } SpvId spirv_builder_emit_image_texel_pointer(struct spirv_builder *b, SpvId result_type, SpvId image, SpvId coordinate, SpvId sample) { SpvId pointer_type = spirv_builder_type_pointer(b, SpvStorageClassImage, result_type); return spirv_builder_emit_triop(b, SpvOpImageTexelPointer, pointer_type, image, coordinate, sample); } SpvId spirv_builder_emit_image_read(struct spirv_builder *b, SpvId result_type, SpvId image, SpvId coordinate, SpvId lod, SpvId sample, SpvId offset) { SpvId result = spirv_builder_new_id(b); SpvImageOperandsMask operand_mask = SpvImageOperandsMaskNone; SpvId extra_operands[5]; int num_extra_operands = 1; if (lod) { extra_operands[num_extra_operands++] = lod; operand_mask |= SpvImageOperandsLodMask; } if (sample) { extra_operands[num_extra_operands++] = sample; operand_mask |= SpvImageOperandsSampleMask; } if (offset) { extra_operands[num_extra_operands++] = offset; operand_mask |= SpvImageOperandsOffsetMask; } /* finalize num_extra_operands / extra_operands */ extra_operands[0] = operand_mask; spirv_buffer_prepare(&b->instructions, b->mem_ctx, 5 + num_extra_operands); spirv_buffer_emit_word(&b->instructions, SpvOpImageRead | ((5 + num_extra_operands) << 16)); spirv_buffer_emit_word(&b->instructions, result_type); spirv_buffer_emit_word(&b->instructions, result); spirv_buffer_emit_word(&b->instructions, image); spirv_buffer_emit_word(&b->instructions, coordinate); for (int i = 0; i < num_extra_operands; ++i) spirv_buffer_emit_word(&b->instructions, extra_operands[i]); return result; } void spirv_builder_emit_image_write(struct spirv_builder *b, SpvId image, SpvId coordinate, SpvId texel, SpvId lod, SpvId sample, SpvId offset) { SpvImageOperandsMask operand_mask = SpvImageOperandsMaskNone; SpvId extra_operands[5]; int num_extra_operands = 1; if (lod) { extra_operands[num_extra_operands++] = lod; operand_mask |= SpvImageOperandsLodMask; } if (sample) { extra_operands[num_extra_operands++] = sample; operand_mask |= SpvImageOperandsSampleMask; } if (offset) { extra_operands[num_extra_operands++] = offset; operand_mask |= SpvImageOperandsOffsetMask; } /* finalize num_extra_operands / extra_operands */ extra_operands[0] = operand_mask; spirv_buffer_prepare(&b->instructions, b->mem_ctx, 4 + num_extra_operands); spirv_buffer_emit_word(&b->instructions, SpvOpImageWrite | ((4 + num_extra_operands) << 16)); spirv_buffer_emit_word(&b->instructions, image); spirv_buffer_emit_word(&b->instructions, coordinate); spirv_buffer_emit_word(&b->instructions, texel); for (int i = 0; i < num_extra_operands; ++i) spirv_buffer_emit_word(&b->instructions, extra_operands[i]); } SpvId spirv_builder_emit_image_gather(struct spirv_builder *b, SpvId result_type, SpvId image, SpvId coordinate, SpvId component, SpvId lod, SpvId sample, SpvId const_offset, SpvId offset, SpvId dref) { SpvId result = spirv_builder_new_id(b); SpvId op = SpvOpImageGather; SpvImageOperandsMask operand_mask = SpvImageOperandsMaskNone; SpvId extra_operands[4]; int num_extra_operands = 1; if (lod) { extra_operands[num_extra_operands++] = lod; operand_mask |= SpvImageOperandsLodMask; } if (sample) { extra_operands[num_extra_operands++] = sample; operand_mask |= SpvImageOperandsSampleMask; } assert(!(const_offset && offset)); if (const_offset) { extra_operands[num_extra_operands++] = const_offset; operand_mask |= SpvImageOperandsConstOffsetMask; } else if (offset) { extra_operands[num_extra_operands++] = offset; operand_mask |= SpvImageOperandsOffsetMask; } if (dref) op = SpvOpImageDrefGather; /* finalize num_extra_operands / extra_operands */ extra_operands[0] = operand_mask; spirv_buffer_prepare(&b->instructions, b->mem_ctx, 6 + num_extra_operands); spirv_buffer_emit_word(&b->instructions, op | ((6 + num_extra_operands) << 16)); spirv_buffer_emit_word(&b->instructions, result_type); spirv_buffer_emit_word(&b->instructions, result); spirv_buffer_emit_word(&b->instructions, image); spirv_buffer_emit_word(&b->instructions, coordinate); if (dref) spirv_buffer_emit_word(&b->instructions, dref); else spirv_buffer_emit_word(&b->instructions, component); for (int i = 0; i < num_extra_operands; ++i) spirv_buffer_emit_word(&b->instructions, extra_operands[i]); return result; } SpvId spirv_builder_emit_image_fetch(struct spirv_builder *b, SpvId result_type, SpvId image, SpvId coordinate, SpvId lod, SpvId sample, SpvId const_offset, SpvId offset) { SpvId result = spirv_builder_new_id(b); SpvImageOperandsMask operand_mask = SpvImageOperandsMaskNone; SpvId extra_operands[4]; int num_extra_operands = 1; if (lod) { extra_operands[num_extra_operands++] = lod; operand_mask |= SpvImageOperandsLodMask; } if (sample) { extra_operands[num_extra_operands++] = sample; operand_mask |= SpvImageOperandsSampleMask; } assert(!(const_offset && offset)); if (const_offset) { extra_operands[num_extra_operands++] = const_offset; operand_mask |= SpvImageOperandsConstOffsetMask; } else if (offset) { extra_operands[num_extra_operands++] = offset; operand_mask |= SpvImageOperandsOffsetMask; } /* finalize num_extra_operands / extra_operands */ extra_operands[0] = operand_mask; spirv_buffer_prepare(&b->instructions, b->mem_ctx, 5 + num_extra_operands); spirv_buffer_emit_word(&b->instructions, SpvOpImageFetch | ((5 + num_extra_operands) << 16)); spirv_buffer_emit_word(&b->instructions, result_type); spirv_buffer_emit_word(&b->instructions, result); spirv_buffer_emit_word(&b->instructions, image); spirv_buffer_emit_word(&b->instructions, coordinate); for (int i = 0; i < num_extra_operands; ++i) spirv_buffer_emit_word(&b->instructions, extra_operands[i]); return result; } SpvId spirv_builder_emit_image_query_size(struct spirv_builder *b, SpvId result_type, SpvId image, SpvId lod) { int opcode = SpvOpImageQuerySize; int words = 4; if (lod) { words++; opcode = SpvOpImageQuerySizeLod; } SpvId result = spirv_builder_new_id(b); spirv_buffer_prepare(&b->instructions, b->mem_ctx, words); spirv_buffer_emit_word(&b->instructions, opcode | (words << 16)); spirv_buffer_emit_word(&b->instructions, result_type); spirv_buffer_emit_word(&b->instructions, result); spirv_buffer_emit_word(&b->instructions, image); if (lod) spirv_buffer_emit_word(&b->instructions, lod); return result; } SpvId spirv_builder_emit_image_query_levels(struct spirv_builder *b, SpvId result_type, SpvId image) { return spirv_builder_emit_unop(b, SpvOpImageQueryLevels, result_type, image); } SpvId spirv_builder_emit_image_query_lod(struct spirv_builder *b, SpvId result_type, SpvId image, SpvId coords) { int opcode = SpvOpImageQueryLod; int words = 5; SpvId result = spirv_builder_new_id(b); spirv_buffer_prepare(&b->instructions, b->mem_ctx, words); spirv_buffer_emit_word(&b->instructions, opcode | (words << 16)); spirv_buffer_emit_word(&b->instructions, result_type); spirv_buffer_emit_word(&b->instructions, result); spirv_buffer_emit_word(&b->instructions, image); spirv_buffer_emit_word(&b->instructions, coords); return result; } SpvId spirv_builder_emit_ext_inst(struct spirv_builder *b, SpvId result_type, SpvId set, uint32_t instruction, const SpvId *args, size_t num_args) { SpvId result = spirv_builder_new_id(b); int words = 5 + num_args; spirv_buffer_prepare(&b->instructions, b->mem_ctx, words); spirv_buffer_emit_word(&b->instructions, SpvOpExtInst | (words << 16)); spirv_buffer_emit_word(&b->instructions, result_type); spirv_buffer_emit_word(&b->instructions, result); spirv_buffer_emit_word(&b->instructions, set); spirv_buffer_emit_word(&b->instructions, instruction); for (int i = 0; i < num_args; ++i) spirv_buffer_emit_word(&b->instructions, args[i]); return result; } struct spirv_type { SpvOp op; uint32_t args[8]; size_t num_args; SpvId type; }; static uint32_t non_aggregate_type_hash(const void *arg) { const struct spirv_type *type = arg; uint32_t hash = 0; hash = XXH32(&type->op, sizeof(type->op), hash); hash = XXH32(type->args, sizeof(uint32_t) * type->num_args, hash); return hash; } static bool non_aggregate_type_equals(const void *a, const void *b) { const struct spirv_type *ta = a, *tb = b; if (ta->op != tb->op) return false; assert(ta->num_args == tb->num_args); return memcmp(ta->args, tb->args, sizeof(uint32_t) * ta->num_args) == 0; } static SpvId get_type_def(struct spirv_builder *b, SpvOp op, const uint32_t args[], size_t num_args) { /* According to the SPIR-V specification: * * "Two different type s form, by definition, two different types. It * is valid to declare multiple aggregate type s having the same * opcode and operands. This is to allow multiple instances of aggregate * types with the same structure to be decorated differently. (Different * decorations are not required; two different aggregate type s are * allowed to have identical declarations and decorations, and will still * be two different types.) Non-aggregate types are different: It is * invalid to declare multiple type s for the same scalar, vector, or * matrix type. That is, non-aggregate type declarations must all have * different opcodes or operands. (Note that non-aggregate types cannot * be decorated in ways that affect their type.)" * * ..so, we need to prevent the same non-aggregate type to be re-defined * with a new . We do this by putting the definitions in a hash-map, so * we can easily look up and reuse them. */ struct spirv_type key; assert(num_args <= ARRAY_SIZE(key.args)); key.op = op; memcpy(&key.args, args, sizeof(uint32_t) * num_args); key.num_args = num_args; struct hash_entry *entry; if (b->types) { entry = _mesa_hash_table_search(b->types, &key); if (entry) return ((struct spirv_type *)entry->data)->type; } else { b->types = _mesa_hash_table_create(b->mem_ctx, non_aggregate_type_hash, non_aggregate_type_equals); assert(b->types); } struct spirv_type *type = rzalloc(b->mem_ctx, struct spirv_type); if (!type) return 0; type->op = op; memcpy(&type->args, args, sizeof(uint32_t) * num_args); type->num_args = num_args; type->type = spirv_builder_new_id(b); spirv_buffer_prepare(&b->types_const_defs, b->mem_ctx, 2 + num_args); spirv_buffer_emit_word(&b->types_const_defs, op | ((2 + num_args) << 16)); spirv_buffer_emit_word(&b->types_const_defs, type->type); for (int i = 0; i < num_args; ++i) spirv_buffer_emit_word(&b->types_const_defs, args[i]); entry = _mesa_hash_table_insert(b->types, type, type); assert(entry); return ((struct spirv_type *)entry->data)->type; } SpvId spirv_builder_type_void(struct spirv_builder *b) { return get_type_def(b, SpvOpTypeVoid, NULL, 0); } SpvId spirv_builder_type_bool(struct spirv_builder *b) { return get_type_def(b, SpvOpTypeBool, NULL, 0); } SpvId spirv_builder_type_int(struct spirv_builder *b, unsigned width) { uint32_t args[] = { width, 1 }; return get_type_def(b, SpvOpTypeInt, args, ARRAY_SIZE(args)); } SpvId spirv_builder_type_uint(struct spirv_builder *b, unsigned width) { uint32_t args[] = { width, 0 }; return get_type_def(b, SpvOpTypeInt, args, ARRAY_SIZE(args)); } SpvId spirv_builder_type_float(struct spirv_builder *b, unsigned width) { uint32_t args[] = { width }; return get_type_def(b, SpvOpTypeFloat, args, ARRAY_SIZE(args)); } SpvId spirv_builder_type_image(struct spirv_builder *b, SpvId sampled_type, SpvDim dim, bool depth, bool arrayed, bool ms, unsigned sampled, SpvImageFormat image_format) { assert(sampled < 3); uint32_t args[] = { sampled_type, dim, depth ? 1 : 0, arrayed ? 1 : 0, ms ? 1 : 0, sampled, image_format }; if (sampled == 2 && ms) spirv_builder_emit_cap(b, SpvCapabilityStorageImageMultisample); return get_type_def(b, SpvOpTypeImage, args, ARRAY_SIZE(args)); } SpvId spirv_builder_type_sampled_image(struct spirv_builder *b, SpvId image_type) { uint32_t args[] = { image_type }; return get_type_def(b, SpvOpTypeSampledImage, args, ARRAY_SIZE(args)); } SpvId spirv_builder_type_pointer(struct spirv_builder *b, SpvStorageClass storage_class, SpvId type) { uint32_t args[] = { storage_class, type }; return get_type_def(b, SpvOpTypePointer, args, ARRAY_SIZE(args)); } SpvId spirv_builder_type_vector(struct spirv_builder *b, SpvId component_type, unsigned component_count) { assert(component_count > 1); uint32_t args[] = { component_type, component_count }; return get_type_def(b, SpvOpTypeVector, args, ARRAY_SIZE(args)); } SpvId spirv_builder_type_matrix(struct spirv_builder *b, SpvId component_type, unsigned component_count) { assert(component_count > 1); uint32_t args[] = { component_type, component_count }; return get_type_def(b, SpvOpTypeMatrix, args, ARRAY_SIZE(args)); } SpvId spirv_builder_type_runtime_array(struct spirv_builder *b, SpvId component_type) { SpvId type = spirv_builder_new_id(b); spirv_buffer_prepare(&b->types_const_defs, b->mem_ctx, 3); spirv_buffer_emit_word(&b->types_const_defs, SpvOpTypeRuntimeArray | (3 << 16)); spirv_buffer_emit_word(&b->types_const_defs, type); spirv_buffer_emit_word(&b->types_const_defs, component_type); return type; } SpvId spirv_builder_type_array(struct spirv_builder *b, SpvId component_type, SpvId length) { SpvId type = spirv_builder_new_id(b); spirv_buffer_prepare(&b->types_const_defs, b->mem_ctx, 4); spirv_buffer_emit_word(&b->types_const_defs, SpvOpTypeArray | (4 << 16)); spirv_buffer_emit_word(&b->types_const_defs, type); spirv_buffer_emit_word(&b->types_const_defs, component_type); spirv_buffer_emit_word(&b->types_const_defs, length); return type; } SpvId spirv_builder_type_struct(struct spirv_builder *b, const SpvId member_types[], size_t num_member_types) { int words = 2 + num_member_types; SpvId type = spirv_builder_new_id(b); spirv_buffer_prepare(&b->types_const_defs, b->mem_ctx, words); spirv_buffer_emit_word(&b->types_const_defs, SpvOpTypeStruct | (words << 16)); spirv_buffer_emit_word(&b->types_const_defs, type); for (int i = 0; i < num_member_types; ++i) spirv_buffer_emit_word(&b->types_const_defs, member_types[i]); return type; } SpvId spirv_builder_type_function(struct spirv_builder *b, SpvId return_type, const SpvId parameter_types[], size_t num_parameter_types) { int words = 3 + num_parameter_types; SpvId type = spirv_builder_new_id(b); spirv_buffer_prepare(&b->types_const_defs, b->mem_ctx, words); spirv_buffer_emit_word(&b->types_const_defs, SpvOpTypeFunction | (words << 16)); spirv_buffer_emit_word(&b->types_const_defs, type); spirv_buffer_emit_word(&b->types_const_defs, return_type); for (int i = 0; i < num_parameter_types; ++i) spirv_buffer_emit_word(&b->types_const_defs, parameter_types[i]); return type; } struct spirv_const { SpvOp op, type; uint32_t args[8]; size_t num_args; SpvId result; }; static uint32_t const_hash(const void *arg) { const struct spirv_const *key = arg; uint32_t hash = 0; hash = XXH32(&key->op, sizeof(key->op), hash); hash = XXH32(&key->type, sizeof(key->type), hash); hash = XXH32(key->args, sizeof(uint32_t) * key->num_args, hash); return hash; } static bool const_equals(const void *a, const void *b) { const struct spirv_const *ca = a, *cb = b; if (ca->op != cb->op || ca->type != cb->type) return false; assert(ca->num_args == cb->num_args); return memcmp(ca->args, cb->args, sizeof(uint32_t) * ca->num_args) == 0; } static SpvId get_const_def(struct spirv_builder *b, SpvOp op, SpvId type, const uint32_t args[], size_t num_args) { struct spirv_const key; assert(num_args <= ARRAY_SIZE(key.args)); key.op = op; key.type = type; memcpy(&key.args, args, sizeof(uint32_t) * num_args); key.num_args = num_args; struct hash_entry *entry; if (b->consts) { entry = _mesa_hash_table_search(b->consts, &key); if (entry) return ((struct spirv_const *)entry->data)->result; } else { b->consts = _mesa_hash_table_create(b->mem_ctx, const_hash, const_equals); assert(b->consts); } struct spirv_const *cnst = rzalloc(b->mem_ctx, struct spirv_const); if (!cnst) return 0; cnst->op = op; cnst->type = type; memcpy(&cnst->args, args, sizeof(uint32_t) * num_args); cnst->num_args = num_args; cnst->result = spirv_builder_new_id(b); spirv_buffer_prepare(&b->types_const_defs, b->mem_ctx, 3 + num_args); spirv_buffer_emit_word(&b->types_const_defs, op | ((3 + num_args) << 16)); spirv_buffer_emit_word(&b->types_const_defs, type); spirv_buffer_emit_word(&b->types_const_defs, cnst->result); for (int i = 0; i < num_args; ++i) spirv_buffer_emit_word(&b->types_const_defs, args[i]); entry = _mesa_hash_table_insert(b->consts, cnst, cnst); assert(entry); return ((struct spirv_const *)entry->data)->result; } static SpvId emit_constant_32(struct spirv_builder *b, SpvId type, uint32_t val) { uint32_t args[] = { val }; return get_const_def(b, SpvOpConstant, type, args, ARRAY_SIZE(args)); } static SpvId emit_constant_64(struct spirv_builder *b, SpvId type, uint64_t val) { uint32_t args[] = { val & UINT32_MAX, val >> 32 }; return get_const_def(b, SpvOpConstant, type, args, ARRAY_SIZE(args)); } SpvId spirv_builder_const_bool(struct spirv_builder *b, bool val) { return get_const_def(b, val ? SpvOpConstantTrue : SpvOpConstantFalse, spirv_builder_type_bool(b), NULL, 0); } SpvId spirv_builder_const_int(struct spirv_builder *b, int width, int64_t val) { assert(width >= 16); SpvId type = spirv_builder_type_int(b, width); if (width <= 32) return emit_constant_32(b, type, val); else return emit_constant_64(b, type, val); } SpvId spirv_builder_const_uint(struct spirv_builder *b, int width, uint64_t val) { assert(width >= 8); SpvId type = spirv_builder_type_uint(b, width); if (width <= 32) return emit_constant_32(b, type, val); else return emit_constant_64(b, type, val); } SpvId spirv_builder_spec_const_uint(struct spirv_builder *b, int width) { assert(width <= 32); return spirv_builder_emit_unop(b, SpvOpSpecConstant, spirv_builder_type_uint(b, width), 0); } SpvId spirv_builder_const_float(struct spirv_builder *b, int width, double val) { assert(width >= 16); SpvId type = spirv_builder_type_float(b, width); if (width == 16) return emit_constant_32(b, type, _mesa_float_to_half(val)); else if (width == 32) return emit_constant_32(b, type, u_bitcast_f2u(val)); else if (width == 64) return emit_constant_64(b, type, u_bitcast_d2u(val)); unreachable("unhandled float-width"); } SpvId spirv_builder_const_composite(struct spirv_builder *b, SpvId result_type, const SpvId constituents[], size_t num_constituents) { return get_const_def(b, SpvOpConstantComposite, result_type, (const uint32_t *)constituents, num_constituents); } SpvId spirv_builder_spec_const_composite(struct spirv_builder *b, SpvId result_type, const SpvId constituents[], size_t num_constituents) { SpvId result = spirv_builder_new_id(b); assert(num_constituents > 0); int words = 3 + num_constituents; spirv_buffer_prepare(&b->instructions, b->mem_ctx, words); spirv_buffer_emit_word(&b->instructions, SpvOpSpecConstantComposite | (words << 16)); spirv_buffer_emit_word(&b->instructions, result_type); spirv_buffer_emit_word(&b->instructions, result); for (int i = 0; i < num_constituents; ++i) spirv_buffer_emit_word(&b->instructions, constituents[i]); return result; } SpvId spirv_builder_emit_var(struct spirv_builder *b, SpvId type, SpvStorageClass storage_class) { assert(storage_class != SpvStorageClassGeneric); struct spirv_buffer *buf = storage_class != SpvStorageClassFunction ? &b->types_const_defs : &b->instructions; SpvId ret = spirv_builder_new_id(b); spirv_buffer_prepare(buf, b->mem_ctx, 4); spirv_buffer_emit_word(buf, SpvOpVariable | (4 << 16)); spirv_buffer_emit_word(buf, type); spirv_buffer_emit_word(buf, ret); spirv_buffer_emit_word(buf, storage_class); return ret; } void spirv_builder_emit_memory_barrier(struct spirv_builder *b, SpvScope scope, SpvMemorySemanticsMask semantics) { spirv_buffer_prepare(&b->instructions, b->mem_ctx, 3); spirv_buffer_emit_word(&b->instructions, SpvOpMemoryBarrier | (3 << 16)); spirv_buffer_emit_word(&b->instructions, spirv_builder_const_uint(b, 32, scope)); spirv_buffer_emit_word(&b->instructions, spirv_builder_const_uint(b, 32, semantics)); } void spirv_builder_emit_control_barrier(struct spirv_builder *b, SpvScope scope, SpvScope mem_scope, SpvMemorySemanticsMask semantics) { spirv_buffer_prepare(&b->instructions, b->mem_ctx, 4); spirv_buffer_emit_word(&b->instructions, SpvOpControlBarrier | (4 << 16)); spirv_buffer_emit_word(&b->instructions, spirv_builder_const_uint(b, 32, scope)); spirv_buffer_emit_word(&b->instructions, spirv_builder_const_uint(b, 32, mem_scope)); spirv_buffer_emit_word(&b->instructions, spirv_builder_const_uint(b, 32, semantics)); } SpvId spirv_builder_import(struct spirv_builder *b, const char *name) { SpvId result = spirv_builder_new_id(b); size_t pos = b->imports.num_words; spirv_buffer_prepare(&b->imports, b->mem_ctx, 2); spirv_buffer_emit_word(&b->imports, SpvOpExtInstImport); spirv_buffer_emit_word(&b->imports, result); int len = spirv_buffer_emit_string(&b->imports, b->mem_ctx, name); b->imports.words[pos] |= (2 + len) << 16; return result; } size_t spirv_builder_get_num_words(struct spirv_builder *b) { const size_t header_size = 5; const size_t caps_size = b->caps ? b->caps->entries * 2 : 0; return header_size + caps_size + b->extensions.num_words + b->imports.num_words + b->memory_model.num_words + b->entry_points.num_words + b->exec_modes.num_words + b->debug_names.num_words + b->decorations.num_words + b->types_const_defs.num_words + b->instructions.num_words; } size_t spirv_builder_get_words(struct spirv_builder *b, uint32_t *words, size_t num_words, uint32_t spirv_version) { assert(num_words >= spirv_builder_get_num_words(b)); size_t written = 0; words[written++] = SpvMagicNumber; words[written++] = spirv_version; words[written++] = 0; words[written++] = b->prev_id + 1; words[written++] = 0; if (b->caps) { set_foreach(b->caps, entry) { words[written++] = SpvOpCapability | (2 << 16); words[written++] = (uintptr_t)entry->key; } } const struct spirv_buffer *buffers[] = { &b->extensions, &b->imports, &b->memory_model, &b->entry_points, &b->exec_modes, &b->debug_names, &b->decorations, &b->types_const_defs, &b->instructions }; for (int i = 0; i < ARRAY_SIZE(buffers); ++i) { const struct spirv_buffer *buffer = buffers[i]; for (int j = 0; j < buffer->num_words; ++j) words[written++] = buffer->words[j]; } assert(written == spirv_builder_get_num_words(b)); return written; }