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spirv_reflect.c
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spirv_reflect.c
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/*
Copyright 2017-2022 Google Inc.
Licensed under the Apache License, Version 2.0 (the "License");
you may not use this file except in compliance with the License.
You may obtain a copy of the License at
http://www.apache.org/licenses/LICENSE-2.0
Unless required by applicable law or agreed to in writing, software
distributed under the License is distributed on an "AS IS" BASIS,
WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
See the License for the specific language governing permissions and
limitations under the License.
*/
#include "spirv_reflect.h"
#include <assert.h>
#include <stdbool.h>
#include <string.h>
#if defined(WIN32)
#define _CRTDBG_MAP_ALLOC
#include <crtdbg.h>
#include <stdlib.h>
#else
#include <stdlib.h>
#endif
#if defined(__clang__) || (defined(__GNUC__) && __GNUC__ >= 7) || defined(__APPLE_CC__)
#define FALLTHROUGH __attribute__((fallthrough))
#else
#define FALLTHROUGH
#endif
#if defined(SPIRV_REFLECT_ENABLE_ASSERTS)
#define SPV_REFLECT_ASSERT(COND) assert(COND);
#else
#define SPV_REFLECT_ASSERT(COND)
#endif
// clang-format off
enum {
SPIRV_STARTING_WORD_INDEX = 5,
SPIRV_WORD_SIZE = sizeof(uint32_t),
SPIRV_BYTE_WIDTH = 8,
SPIRV_MINIMUM_FILE_SIZE = SPIRV_STARTING_WORD_INDEX * SPIRV_WORD_SIZE,
SPIRV_DATA_ALIGNMENT = 4 * SPIRV_WORD_SIZE, // 16
SPIRV_ACCESS_CHAIN_INDEX_OFFSET = 4,
SPIRV_PHYSICAL_STORAGE_POINTER_SIZE = 8, // Pointers are defined as 64-bit
};
enum {
INVALID_VALUE = 0xFFFFFFFF,
};
enum {
MAX_NODE_NAME_LENGTH = 1024,
// Number of unique PhysicalStorageBuffer structs tracked to detect recursion
MAX_RECURSIVE_PHYSICAL_POINTER_CHECK = 128,
};
enum {
IMAGE_SAMPLED = 1,
IMAGE_STORAGE = 2,
};
typedef struct SpvReflectPrvArrayTraits {
uint32_t element_type_id;
uint32_t length_id;
} SpvReflectPrvArrayTraits;
typedef struct SpvReflectPrvImageTraits {
uint32_t sampled_type_id;
SpvDim dim;
uint32_t depth;
uint32_t arrayed;
uint32_t ms;
uint32_t sampled;
SpvImageFormat image_format;
} SpvReflectPrvImageTraits;
typedef struct SpvReflectPrvNumberDecoration {
uint32_t word_offset;
uint32_t value;
} SpvReflectPrvNumberDecoration;
typedef struct SpvReflectPrvStringDecoration {
uint32_t word_offset;
const char* value;
} SpvReflectPrvStringDecoration;
typedef struct SpvReflectPrvDecorations {
bool is_relaxed_precision;
bool is_block;
bool is_buffer_block;
bool is_row_major;
bool is_column_major;
bool is_built_in;
bool is_noperspective;
bool is_flat;
bool is_non_writable;
bool is_non_readable;
bool is_patch;
bool is_per_vertex;
bool is_per_task;
bool is_weight_texture;
bool is_block_match_texture;
SpvReflectUserType user_type;
SpvReflectPrvNumberDecoration set;
SpvReflectPrvNumberDecoration binding;
SpvReflectPrvNumberDecoration input_attachment_index;
SpvReflectPrvNumberDecoration location;
SpvReflectPrvNumberDecoration component;
SpvReflectPrvNumberDecoration offset;
SpvReflectPrvNumberDecoration uav_counter_buffer;
SpvReflectPrvStringDecoration semantic;
uint32_t array_stride;
uint32_t matrix_stride;
uint32_t spec_id;
SpvBuiltIn built_in;
} SpvReflectPrvDecorations;
typedef struct SpvReflectPrvNode {
uint32_t result_id;
SpvOp op;
uint32_t result_type_id;
uint32_t type_id;
SpvCapability capability;
SpvStorageClass storage_class;
uint32_t word_offset;
uint32_t word_count;
bool is_type;
SpvReflectPrvArrayTraits array_traits;
SpvReflectPrvImageTraits image_traits;
uint32_t image_type_id;
const char* name;
SpvReflectPrvDecorations decorations;
uint32_t member_count;
const char** member_names;
SpvReflectPrvDecorations* member_decorations;
} SpvReflectPrvNode;
typedef struct SpvReflectPrvString {
uint32_t result_id;
const char* string;
} SpvReflectPrvString;
// There are a limit set of instructions that can touch an OpVariable,
// these are represented here with how it was accessed
// Examples:
// OpImageRead -> OpLoad -> OpVariable
// OpImageWrite -> OpLoad -> OpVariable
// OpStore -> OpAccessChain -> OpAccessChain -> OpVariable
// OpAtomicIAdd -> OpAccessChain -> OpVariable
// OpAtomicLoad -> OpImageTexelPointer -> OpVariable
typedef struct SpvReflectPrvAccessedVariable {
SpvReflectPrvNode* p_node;
uint32_t result_id;
uint32_t variable_ptr;
uint32_t function_id;
uint32_t function_parameter_index;
} SpvReflectPrvAccessedVariable;
typedef struct SpvReflectPrvFunction {
uint32_t id;
uint32_t parameter_count;
uint32_t* parameters;
uint32_t callee_count;
uint32_t* callees;
struct SpvReflectPrvFunction** callee_ptrs;
uint32_t accessed_variable_count;
SpvReflectPrvAccessedVariable* accessed_variables;
} SpvReflectPrvFunction;
typedef struct SpvReflectPrvAccessChain {
uint32_t result_id;
uint32_t result_type_id;
//
// Pointing to the base of a composite object.
// Generally the id of descriptor block variable
uint32_t base_id;
//
// From spec:
// The first index in Indexes will select the
// top-level member/element/component/element
// of the base composite
uint32_t index_count;
uint32_t* indexes;
//
// Block variable ac is pointing to (for block references)
SpvReflectBlockVariable* block_var;
} SpvReflectPrvAccessChain;
// To prevent infinite recursion, we never walk down a
// PhysicalStorageBuffer struct twice, but incase a 2nd variable
// needs to use that struct, save a copy
typedef struct SpvReflectPrvPhysicalPointerStruct {
uint32_t struct_id;
// first variable to see the PhysicalStorageBuffer struct
SpvReflectBlockVariable* p_var;
} SpvReflectPrvPhysicalPointerStruct;
typedef struct SpvReflectPrvParser {
size_t spirv_word_count;
uint32_t* spirv_code;
uint32_t string_count;
SpvReflectPrvString* strings;
SpvSourceLanguage source_language;
uint32_t source_language_version;
uint32_t source_file_id;
const char* source_embedded;
size_t node_count;
SpvReflectPrvNode* nodes;
uint32_t entry_point_count;
uint32_t capability_count;
uint32_t function_count;
SpvReflectPrvFunction* functions;
uint32_t access_chain_count;
SpvReflectPrvAccessChain* access_chains;
uint32_t type_count;
uint32_t descriptor_count;
uint32_t push_constant_count;
SpvReflectTypeDescription* physical_pointer_check[MAX_RECURSIVE_PHYSICAL_POINTER_CHECK];
uint32_t physical_pointer_count;
SpvReflectPrvPhysicalPointerStruct* physical_pointer_structs;
uint32_t physical_pointer_struct_count;
} SpvReflectPrvParser;
// clang-format on
static uint32_t Max(uint32_t a, uint32_t b) { return a > b ? a : b; }
static uint32_t Min(uint32_t a, uint32_t b) { return a < b ? a : b; }
static uint32_t RoundUp(uint32_t value, uint32_t multiple) {
assert(multiple && ((multiple & (multiple - 1)) == 0));
return (value + multiple - 1) & ~(multiple - 1);
}
#define IsNull(ptr) (ptr == NULL)
#define IsNotNull(ptr) (ptr != NULL)
#define SafeFree(ptr) \
{ \
free((void*)ptr); \
ptr = NULL; \
}
static int SortCompareUint32(const void* a, const void* b) {
const uint32_t* p_a = (const uint32_t*)a;
const uint32_t* p_b = (const uint32_t*)b;
return (int)*p_a - (int)*p_b;
}
static int SortCompareAccessedVariable(const void* a, const void* b) {
const SpvReflectPrvAccessedVariable* p_a = (const SpvReflectPrvAccessedVariable*)a;
const SpvReflectPrvAccessedVariable* p_b = (const SpvReflectPrvAccessedVariable*)b;
return (int)p_a->variable_ptr - (int)p_b->variable_ptr;
}
//
// De-duplicates a sorted array and returns the new size.
//
// Note: The array doesn't actually need to be sorted, just
// arranged into "runs" so that all the entries with one
// value are adjacent.
//
static size_t DedupSortedUint32(uint32_t* arr, size_t size) {
if (size == 0) {
return 0;
}
size_t dedup_idx = 0;
for (size_t i = 0; i < size; ++i) {
if (arr[dedup_idx] != arr[i]) {
++dedup_idx;
arr[dedup_idx] = arr[i];
}
}
return dedup_idx + 1;
}
static bool SearchSortedUint32(const uint32_t* arr, size_t size, uint32_t target) {
size_t lo = 0;
size_t hi = size;
while (lo < hi) {
size_t mid = (hi - lo) / 2 + lo;
if (arr[mid] == target) {
return true;
} else if (arr[mid] < target) {
lo = mid + 1;
} else {
hi = mid;
}
}
return false;
}
static SpvReflectResult IntersectSortedAccessedVariable(const SpvReflectPrvAccessedVariable* p_arr0, size_t arr0_size,
const uint32_t* p_arr1, size_t arr1_size, uint32_t** pp_res,
size_t* res_size) {
*pp_res = NULL;
*res_size = 0;
if (IsNull(p_arr0) || IsNull(p_arr1)) {
return SPV_REFLECT_RESULT_SUCCESS;
}
const SpvReflectPrvAccessedVariable* p_arr0_end = p_arr0 + arr0_size;
const uint32_t* p_arr1_end = p_arr1 + arr1_size;
const SpvReflectPrvAccessedVariable* p_idx0 = p_arr0;
const uint32_t* p_idx1 = p_arr1;
while (p_idx0 != p_arr0_end && p_idx1 != p_arr1_end) {
if (p_idx0->variable_ptr < *p_idx1) {
++p_idx0;
} else if (p_idx0->variable_ptr > *p_idx1) {
++p_idx1;
} else {
++*res_size;
++p_idx0;
++p_idx1;
}
}
if (*res_size > 0) {
*pp_res = (uint32_t*)calloc(*res_size, sizeof(**pp_res));
if (IsNull(*pp_res)) {
return SPV_REFLECT_RESULT_ERROR_ALLOC_FAILED;
}
uint32_t* p_idxr = *pp_res;
p_idx0 = p_arr0;
p_idx1 = p_arr1;
while (p_idx0 != p_arr0_end && p_idx1 != p_arr1_end) {
if (p_idx0->variable_ptr < *p_idx1) {
++p_idx0;
} else if (p_idx0->variable_ptr > *p_idx1) {
++p_idx1;
} else {
*(p_idxr++) = p_idx0->variable_ptr;
++p_idx0;
++p_idx1;
}
}
}
return SPV_REFLECT_RESULT_SUCCESS;
}
static bool InRange(const SpvReflectPrvParser* p_parser, uint32_t index) {
bool in_range = false;
if (IsNotNull(p_parser)) {
in_range = (index < p_parser->spirv_word_count);
}
return in_range;
}
static SpvReflectResult ReadU32(SpvReflectPrvParser* p_parser, uint32_t word_offset, uint32_t* p_value) {
assert(IsNotNull(p_parser));
assert(IsNotNull(p_parser->spirv_code));
assert(InRange(p_parser, word_offset));
SpvReflectResult result = SPV_REFLECT_RESULT_ERROR_SPIRV_UNEXPECTED_EOF;
if (IsNotNull(p_parser) && IsNotNull(p_parser->spirv_code) && InRange(p_parser, word_offset)) {
*p_value = *(p_parser->spirv_code + word_offset);
result = SPV_REFLECT_RESULT_SUCCESS;
}
return result;
}
#define UNCHECKED_READU32(parser, word_offset, value) \
{ (void)ReadU32(parser, word_offset, (uint32_t*)&(value)); }
#define CHECKED_READU32(parser, word_offset, value) \
{ \
SpvReflectResult checked_readu32_result = ReadU32(parser, word_offset, (uint32_t*)&(value)); \
if (checked_readu32_result != SPV_REFLECT_RESULT_SUCCESS) { \
return checked_readu32_result; \
} \
}
#define CHECKED_READU32_CAST(parser, word_offset, cast_to_type, value) \
{ \
uint32_t checked_readu32_cast_u32 = UINT32_MAX; \
SpvReflectResult checked_readu32_cast_result = ReadU32(parser, word_offset, (uint32_t*)&(checked_readu32_cast_u32)); \
if (checked_readu32_cast_result != SPV_REFLECT_RESULT_SUCCESS) { \
return checked_readu32_cast_result; \
} \
value = (cast_to_type)checked_readu32_cast_u32; \
}
#define IF_READU32(result, parser, word_offset, value) \
if ((result) == SPV_REFLECT_RESULT_SUCCESS) { \
result = ReadU32(parser, word_offset, (uint32_t*)&(value)); \
}
#define IF_READU32_CAST(result, parser, word_offset, cast_to_type, value) \
if ((result) == SPV_REFLECT_RESULT_SUCCESS) { \
uint32_t if_readu32_cast_u32 = UINT32_MAX; \
result = ReadU32(parser, word_offset, &if_readu32_cast_u32); \
if ((result) == SPV_REFLECT_RESULT_SUCCESS) { \
value = (cast_to_type)if_readu32_cast_u32; \
} \
}
static SpvReflectResult ReadStr(SpvReflectPrvParser* p_parser, uint32_t word_offset, uint32_t word_index, uint32_t word_count,
uint32_t* p_buf_size, char* p_buf) {
uint32_t limit = (word_offset + word_count);
assert(IsNotNull(p_parser));
assert(IsNotNull(p_parser->spirv_code));
assert(InRange(p_parser, limit));
SpvReflectResult result = SPV_REFLECT_RESULT_ERROR_SPIRV_UNEXPECTED_EOF;
if (IsNotNull(p_parser) && IsNotNull(p_parser->spirv_code) && InRange(p_parser, limit)) {
const char* c_str = (const char*)(p_parser->spirv_code + word_offset + word_index);
uint32_t n = word_count * SPIRV_WORD_SIZE;
uint32_t length_with_terminator = 0;
for (uint32_t i = 0; i < n; ++i) {
char c = *(c_str + i);
if (c == 0) {
length_with_terminator = i + 1;
break;
}
}
if (length_with_terminator > 0) {
result = SPV_REFLECT_RESULT_ERROR_NULL_POINTER;
if (IsNotNull(p_buf_size) && IsNotNull(p_buf)) {
result = SPV_REFLECT_RESULT_ERROR_RANGE_EXCEEDED;
if (length_with_terminator <= *p_buf_size) {
memset(p_buf, 0, *p_buf_size);
memcpy(p_buf, c_str, length_with_terminator);
result = SPV_REFLECT_RESULT_SUCCESS;
}
} else {
if (IsNotNull(p_buf_size)) {
*p_buf_size = length_with_terminator;
result = SPV_REFLECT_RESULT_SUCCESS;
}
}
}
}
return result;
}
static SpvReflectDecorationFlags ApplyDecorations(const SpvReflectPrvDecorations* p_decoration_fields) {
SpvReflectDecorationFlags decorations = SPV_REFLECT_DECORATION_NONE;
if (p_decoration_fields->is_relaxed_precision) {
decorations |= SPV_REFLECT_DECORATION_RELAXED_PRECISION;
}
if (p_decoration_fields->is_block) {
decorations |= SPV_REFLECT_DECORATION_BLOCK;
}
if (p_decoration_fields->is_buffer_block) {
decorations |= SPV_REFLECT_DECORATION_BUFFER_BLOCK;
}
if (p_decoration_fields->is_row_major) {
decorations |= SPV_REFLECT_DECORATION_ROW_MAJOR;
}
if (p_decoration_fields->is_column_major) {
decorations |= SPV_REFLECT_DECORATION_COLUMN_MAJOR;
}
if (p_decoration_fields->is_built_in) {
decorations |= SPV_REFLECT_DECORATION_BUILT_IN;
}
if (p_decoration_fields->is_noperspective) {
decorations |= SPV_REFLECT_DECORATION_NOPERSPECTIVE;
}
if (p_decoration_fields->is_flat) {
decorations |= SPV_REFLECT_DECORATION_FLAT;
}
if (p_decoration_fields->is_non_writable) {
decorations |= SPV_REFLECT_DECORATION_NON_WRITABLE;
}
if (p_decoration_fields->is_non_readable) {
decorations |= SPV_REFLECT_DECORATION_NON_READABLE;
}
if (p_decoration_fields->is_patch) {
decorations |= SPV_REFLECT_DECORATION_PATCH;
}
if (p_decoration_fields->is_per_vertex) {
decorations |= SPV_REFLECT_DECORATION_PER_VERTEX;
}
if (p_decoration_fields->is_per_task) {
decorations |= SPV_REFLECT_DECORATION_PER_TASK;
}
if (p_decoration_fields->is_weight_texture) {
decorations |= SPV_REFLECT_DECORATION_WEIGHT_TEXTURE;
}
if (p_decoration_fields->is_block_match_texture) {
decorations |= SPV_REFLECT_DECORATION_BLOCK_MATCH_TEXTURE;
}
return decorations;
}
static void ApplyNumericTraits(const SpvReflectTypeDescription* p_type, SpvReflectNumericTraits* p_numeric_traits) {
memcpy(p_numeric_traits, &p_type->traits.numeric, sizeof(p_type->traits.numeric));
}
static void ApplyArrayTraits(const SpvReflectTypeDescription* p_type, SpvReflectArrayTraits* p_array_traits) {
memcpy(p_array_traits, &p_type->traits.array, sizeof(p_type->traits.array));
}
static bool IsSpecConstant(const SpvReflectPrvNode* p_node) {
return (p_node->op == SpvOpSpecConstant || p_node->op == SpvOpSpecConstantOp || p_node->op == SpvOpSpecConstantTrue ||
p_node->op == SpvOpSpecConstantFalse);
}
static SpvReflectPrvNode* FindNode(SpvReflectPrvParser* p_parser, uint32_t result_id) {
SpvReflectPrvNode* p_node = NULL;
for (size_t i = 0; i < p_parser->node_count; ++i) {
SpvReflectPrvNode* p_elem = &(p_parser->nodes[i]);
if (p_elem->result_id == result_id) {
p_node = p_elem;
break;
}
}
return p_node;
}
static SpvReflectTypeDescription* FindType(SpvReflectShaderModule* p_module, uint32_t type_id) {
SpvReflectTypeDescription* p_type = NULL;
for (size_t i = 0; i < p_module->_internal->type_description_count; ++i) {
SpvReflectTypeDescription* p_elem = &(p_module->_internal->type_descriptions[i]);
if (p_elem->id == type_id) {
p_type = p_elem;
break;
}
}
return p_type;
}
static SpvReflectPrvAccessChain* FindAccessChain(SpvReflectPrvParser* p_parser, uint32_t id) {
const uint32_t ac_count = p_parser->access_chain_count;
for (uint32_t i = 0; i < ac_count; i++) {
if (p_parser->access_chains[i].result_id == id) {
return &p_parser->access_chains[i];
}
}
return 0;
}
// Access Chains mostly have their Base ID pointed directly to a OpVariable, but sometimes
// it will be through a load and this funciton handles the edge cases how to find that
static uint32_t FindAccessChainBaseVariable(SpvReflectPrvParser* p_parser, SpvReflectPrvAccessChain* p_access_chain) {
uint32_t base_id = p_access_chain->base_id;
SpvReflectPrvNode* base_node = FindNode(p_parser, base_id);
// TODO - This is just a band-aid to fix crashes.
// Need to understand why here and hopefully remove
// https://github.com/KhronosGroup/SPIRV-Reflect/pull/206
if (IsNull(base_node)) {
return 0;
}
while (base_node->op != SpvOpVariable) {
switch (base_node->op) {
case SpvOpLoad: {
UNCHECKED_READU32(p_parser, base_node->word_offset + 3, base_id);
} break;
case SpvOpFunctionParameter: {
UNCHECKED_READU32(p_parser, base_node->word_offset + 2, base_id);
} break;
case SpvOpBitcast:
// This can be caused by something like GL_EXT_buffer_reference_uvec2 trying to load a pointer.
// We currently call from a push constant, so no way to have a reference loop back into the PC block
return 0;
default: {
assert(false);
} break;
}
SpvReflectPrvAccessChain* base_ac = FindAccessChain(p_parser, base_id);
if (base_ac == 0) {
return 0;
}
base_id = base_ac->base_id;
base_node = FindNode(p_parser, base_id);
if (IsNull(base_node)) {
return 0;
}
}
return base_id;
}
static SpvReflectBlockVariable* GetRefBlkVar(SpvReflectPrvParser* p_parser, SpvReflectPrvAccessChain* p_access_chain) {
uint32_t base_id = p_access_chain->base_id;
SpvReflectPrvNode* base_node = FindNode(p_parser, base_id);
assert(base_node->op == SpvOpLoad);
UNCHECKED_READU32(p_parser, base_node->word_offset + 3, base_id);
SpvReflectPrvAccessChain* base_ac = FindAccessChain(p_parser, base_id);
assert(base_ac != 0);
SpvReflectBlockVariable* base_var = base_ac->block_var;
assert(base_var != 0);
return base_var;
}
bool IsPointerToPointer(SpvReflectPrvParser* p_parser, uint32_t type_id) {
SpvReflectPrvNode* ptr_node = FindNode(p_parser, type_id);
if (IsNull(ptr_node) || (ptr_node->op != SpvOpTypePointer)) {
return false;
}
uint32_t pte_id = 0;
UNCHECKED_READU32(p_parser, ptr_node->word_offset + 3, pte_id);
SpvReflectPrvNode* pte_node = FindNode(p_parser, pte_id);
if (IsNull(pte_node)) {
return false;
}
return pte_node->op == SpvOpTypePointer;
}
static SpvReflectResult CreateParser(size_t size, void* p_code, SpvReflectPrvParser* p_parser) {
if (p_code == NULL) {
return SPV_REFLECT_RESULT_ERROR_NULL_POINTER;
}
if (size < SPIRV_MINIMUM_FILE_SIZE) {
return SPV_REFLECT_RESULT_ERROR_SPIRV_INVALID_CODE_SIZE;
}
if ((size % 4) != 0) {
return SPV_REFLECT_RESULT_ERROR_SPIRV_INVALID_CODE_SIZE;
}
p_parser->spirv_word_count = size / SPIRV_WORD_SIZE;
p_parser->spirv_code = (uint32_t*)p_code;
if (p_parser->spirv_code[0] != SpvMagicNumber) {
return SPV_REFLECT_RESULT_ERROR_SPIRV_INVALID_MAGIC_NUMBER;
}
return SPV_REFLECT_RESULT_SUCCESS;
}
static void DestroyParser(SpvReflectPrvParser* p_parser) {
if (!IsNull(p_parser->nodes)) {
// Free nodes
for (size_t i = 0; i < p_parser->node_count; ++i) {
SpvReflectPrvNode* p_node = &(p_parser->nodes[i]);
if (IsNotNull(p_node->member_names)) {
SafeFree(p_node->member_names);
}
if (IsNotNull(p_node->member_decorations)) {
SafeFree(p_node->member_decorations);
}
}
// Free functions
for (size_t i = 0; i < p_parser->function_count; ++i) {
SafeFree(p_parser->functions[i].parameters);
SafeFree(p_parser->functions[i].callees);
SafeFree(p_parser->functions[i].callee_ptrs);
SafeFree(p_parser->functions[i].accessed_variables);
}
// Free access chains
for (uint32_t i = 0; i < p_parser->access_chain_count; ++i) {
SafeFree(p_parser->access_chains[i].indexes);
}
SafeFree(p_parser->nodes);
SafeFree(p_parser->strings);
SafeFree(p_parser->source_embedded);
SafeFree(p_parser->functions);
SafeFree(p_parser->access_chains);
if (IsNotNull(p_parser->physical_pointer_structs)) {
SafeFree(p_parser->physical_pointer_structs);
}
p_parser->node_count = 0;
}
}
static SpvReflectResult ParseNodes(SpvReflectPrvParser* p_parser) {
assert(IsNotNull(p_parser));
assert(IsNotNull(p_parser->spirv_code));
uint32_t* p_spirv = p_parser->spirv_code;
uint32_t spirv_word_index = SPIRV_STARTING_WORD_INDEX;
// Count nodes
uint32_t node_count = 0;
while (spirv_word_index < p_parser->spirv_word_count) {
uint32_t word = p_spirv[spirv_word_index];
SpvOp op = (SpvOp)(word & 0xFFFF);
uint32_t node_word_count = (word >> 16) & 0xFFFF;
if (node_word_count == 0) {
return SPV_REFLECT_RESULT_ERROR_SPIRV_INVALID_INSTRUCTION;
}
if (op == SpvOpAccessChain) {
++(p_parser->access_chain_count);
}
spirv_word_index += node_word_count;
++node_count;
}
if (node_count == 0) {
return SPV_REFLECT_RESULT_ERROR_SPIRV_UNEXPECTED_EOF;
}
// Allocate nodes
p_parser->node_count = node_count;
p_parser->nodes = (SpvReflectPrvNode*)calloc(p_parser->node_count, sizeof(*(p_parser->nodes)));
if (IsNull(p_parser->nodes)) {
return SPV_REFLECT_RESULT_ERROR_ALLOC_FAILED;
}
// Mark all nodes with an invalid state
for (uint32_t i = 0; i < node_count; ++i) {
p_parser->nodes[i].op = (SpvOp)INVALID_VALUE;
p_parser->nodes[i].storage_class = (SpvStorageClass)INVALID_VALUE;
p_parser->nodes[i].decorations.set.value = (uint32_t)INVALID_VALUE;
p_parser->nodes[i].decorations.binding.value = (uint32_t)INVALID_VALUE;
p_parser->nodes[i].decorations.location.value = (uint32_t)INVALID_VALUE;
p_parser->nodes[i].decorations.component.value = (uint32_t)INVALID_VALUE;
p_parser->nodes[i].decorations.offset.value = (uint32_t)INVALID_VALUE;
p_parser->nodes[i].decorations.uav_counter_buffer.value = (uint32_t)INVALID_VALUE;
p_parser->nodes[i].decorations.spec_id = (uint32_t)INVALID_VALUE;
p_parser->nodes[i].decorations.built_in = (SpvBuiltIn)INVALID_VALUE;
}
// Mark source file id node
p_parser->source_file_id = (uint32_t)INVALID_VALUE;
p_parser->source_embedded = NULL;
// Function node
uint32_t function_node = (uint32_t)INVALID_VALUE;
// Allocate access chain
if (p_parser->access_chain_count > 0) {
p_parser->access_chains = (SpvReflectPrvAccessChain*)calloc(p_parser->access_chain_count, sizeof(*(p_parser->access_chains)));
if (IsNull(p_parser->access_chains)) {
return SPV_REFLECT_RESULT_ERROR_ALLOC_FAILED;
}
}
// Parse nodes
uint32_t node_index = 0;
uint32_t access_chain_index = 0;
spirv_word_index = SPIRV_STARTING_WORD_INDEX;
while (spirv_word_index < p_parser->spirv_word_count) {
uint32_t word = p_spirv[spirv_word_index];
SpvOp op = (SpvOp)(word & 0xFFFF);
uint32_t node_word_count = (word >> 16) & 0xFFFF;
SpvReflectPrvNode* p_node = &(p_parser->nodes[node_index]);
p_node->op = op;
p_node->word_offset = spirv_word_index;
p_node->word_count = node_word_count;
switch (p_node->op) {
default:
break;
case SpvOpString: {
++(p_parser->string_count);
} break;
case SpvOpSource: {
CHECKED_READU32_CAST(p_parser, p_node->word_offset + 1, SpvSourceLanguage, p_parser->source_language);
CHECKED_READU32(p_parser, p_node->word_offset + 2, p_parser->source_language_version);
if (p_node->word_count >= 4) {
CHECKED_READU32(p_parser, p_node->word_offset + 3, p_parser->source_file_id);
}
if (p_node->word_count >= 5) {
const char* p_source = (const char*)(p_parser->spirv_code + p_node->word_offset + 4);
const size_t source_len = strlen(p_source);
char* p_source_temp = (char*)calloc(source_len + 1, sizeof(char));
if (IsNull(p_source_temp)) {
return SPV_REFLECT_RESULT_ERROR_ALLOC_FAILED;
}
#ifdef _WIN32
strcpy_s(p_source_temp, source_len + 1, p_source);
#else
strcpy(p_source_temp, p_source);
#endif
SafeFree(p_parser->source_embedded);
p_parser->source_embedded = p_source_temp;
}
} break;
case SpvOpSourceContinued: {
const char* p_source = (const char*)(p_parser->spirv_code + p_node->word_offset + 1);
const size_t source_len = strlen(p_source);
const size_t embedded_source_len = strlen(p_parser->source_embedded);
char* p_continued_source = (char*)calloc(source_len + embedded_source_len + 1, sizeof(char));
if (IsNull(p_continued_source)) {
return SPV_REFLECT_RESULT_ERROR_ALLOC_FAILED;
}
#ifdef _WIN32
strcpy_s(p_continued_source, embedded_source_len + 1, p_parser->source_embedded);
strcat_s(p_continued_source, embedded_source_len + source_len + 1, p_source);
#else
strcpy(p_continued_source, p_parser->source_embedded);
strcat(p_continued_source, p_source);
#endif
SafeFree(p_parser->source_embedded);
p_parser->source_embedded = p_continued_source;
} break;
case SpvOpEntryPoint: {
++(p_parser->entry_point_count);
} break;
case SpvOpCapability: {
CHECKED_READU32(p_parser, p_node->word_offset + 1, p_node->capability);
++(p_parser->capability_count);
} break;
case SpvOpName:
case SpvOpMemberName: {
uint32_t member_offset = (p_node->op == SpvOpMemberName) ? 1 : 0;
uint32_t name_start = p_node->word_offset + member_offset + 2;
p_node->name = (const char*)(p_parser->spirv_code + name_start);
} break;
case SpvOpTypeStruct: {
p_node->member_count = p_node->word_count - 2;
FALLTHROUGH;
} // Fall through
// This is all the rest of OpType* that need to be tracked
// Possible new extensions might expose new type, will need to be added
// here
case SpvOpTypeVoid:
case SpvOpTypeBool:
case SpvOpTypeInt:
case SpvOpTypeFloat:
case SpvOpTypeVector:
case SpvOpTypeMatrix:
case SpvOpTypeSampler:
case SpvOpTypeOpaque:
case SpvOpTypeFunction:
case SpvOpTypeEvent:
case SpvOpTypeDeviceEvent:
case SpvOpTypeReserveId:
case SpvOpTypeQueue:
case SpvOpTypePipe:
case SpvOpTypeAccelerationStructureKHR:
case SpvOpTypeRayQueryKHR:
case SpvOpTypeHitObjectNV:
case SpvOpTypeCooperativeMatrixNV:
case SpvOpTypeCooperativeMatrixKHR: {
CHECKED_READU32(p_parser, p_node->word_offset + 1, p_node->result_id);
p_node->is_type = true;
} break;
case SpvOpTypeImage: {
CHECKED_READU32(p_parser, p_node->word_offset + 1, p_node->result_id);
CHECKED_READU32(p_parser, p_node->word_offset + 2, p_node->image_traits.sampled_type_id);
CHECKED_READU32(p_parser, p_node->word_offset + 3, p_node->image_traits.dim);
CHECKED_READU32(p_parser, p_node->word_offset + 4, p_node->image_traits.depth);
CHECKED_READU32(p_parser, p_node->word_offset + 5, p_node->image_traits.arrayed);
CHECKED_READU32(p_parser, p_node->word_offset + 6, p_node->image_traits.ms);
CHECKED_READU32(p_parser, p_node->word_offset + 7, p_node->image_traits.sampled);
CHECKED_READU32(p_parser, p_node->word_offset + 8, p_node->image_traits.image_format);
p_node->is_type = true;
} break;
case SpvOpTypeSampledImage: {
CHECKED_READU32(p_parser, p_node->word_offset + 1, p_node->result_id);
CHECKED_READU32(p_parser, p_node->word_offset + 2, p_node->image_type_id);
p_node->is_type = true;
} break;
case SpvOpTypeArray: {
CHECKED_READU32(p_parser, p_node->word_offset + 1, p_node->result_id);
CHECKED_READU32(p_parser, p_node->word_offset + 2, p_node->array_traits.element_type_id);
CHECKED_READU32(p_parser, p_node->word_offset + 3, p_node->array_traits.length_id);
p_node->is_type = true;
} break;
case SpvOpTypeRuntimeArray: {
CHECKED_READU32(p_parser, p_node->word_offset + 1, p_node->result_id);
CHECKED_READU32(p_parser, p_node->word_offset + 2, p_node->array_traits.element_type_id);
p_node->is_type = true;
} break;
case SpvOpTypePointer: {
uint32_t result_id;
CHECKED_READU32(p_parser, p_node->word_offset + 1, result_id);
// Look for forward pointer. Clear result id if found
SpvReflectPrvNode* p_fwd_node = FindNode(p_parser, result_id);
if (p_fwd_node) {
p_fwd_node->result_id = 0;
}
// Register pointer type
p_node->result_id = result_id;
CHECKED_READU32(p_parser, p_node->word_offset + 2, p_node->storage_class);
CHECKED_READU32(p_parser, p_node->word_offset + 3, p_node->type_id);
p_node->is_type = true;
} break;
case SpvOpTypeForwardPointer: {
CHECKED_READU32(p_parser, p_node->word_offset + 1, p_node->result_id);
CHECKED_READU32(p_parser, p_node->word_offset + 2, p_node->storage_class);
p_node->is_type = true;
} break;
case SpvOpConstantTrue:
case SpvOpConstantFalse:
case SpvOpConstant:
case SpvOpConstantComposite:
case SpvOpConstantSampler:
case SpvOpConstantNull: {
CHECKED_READU32(p_parser, p_node->word_offset + 1, p_node->result_type_id);
CHECKED_READU32(p_parser, p_node->word_offset + 2, p_node->result_id);
} break;
case SpvOpSpecConstantTrue:
case SpvOpSpecConstantFalse:
case SpvOpSpecConstant:
case SpvOpSpecConstantComposite:
case SpvOpSpecConstantOp: {
CHECKED_READU32(p_parser, p_node->word_offset + 1, p_node->result_type_id);
CHECKED_READU32(p_parser, p_node->word_offset + 2, p_node->result_id);
} break;
case SpvOpVariable: {
CHECKED_READU32(p_parser, p_node->word_offset + 1, p_node->type_id);
CHECKED_READU32(p_parser, p_node->word_offset + 2, p_node->result_id);
CHECKED_READU32(p_parser, p_node->word_offset + 3, p_node->storage_class);
} break;
case SpvOpLoad: {
// Only load enough so OpDecorate can reference the node, skip the remaining operands.
CHECKED_READU32(p_parser, p_node->word_offset + 1, p_node->result_type_id);
CHECKED_READU32(p_parser, p_node->word_offset + 2, p_node->result_id);
} break;
case SpvOpAccessChain: {
SpvReflectPrvAccessChain* p_access_chain = &(p_parser->access_chains[access_chain_index]);
CHECKED_READU32(p_parser, p_node->word_offset + 1, p_access_chain->result_type_id);
CHECKED_READU32(p_parser, p_node->word_offset + 2, p_access_chain->result_id);
CHECKED_READU32(p_parser, p_node->word_offset + 3, p_access_chain->base_id);
//
// SPIRV_ACCESS_CHAIN_INDEX_OFFSET (4) is the number of words up until the first index:
// [Node, Result Type Id, Result Id, Base Id, <Indexes>]
//
p_access_chain->index_count = (node_word_count - SPIRV_ACCESS_CHAIN_INDEX_OFFSET);
if (p_access_chain->index_count > 0) {
p_access_chain->indexes = (uint32_t*)calloc(p_access_chain->index_count, sizeof(*(p_access_chain->indexes)));
if (IsNull(p_access_chain->indexes)) {
return SPV_REFLECT_RESULT_ERROR_ALLOC_FAILED;
}
// Parse any index values for access chain
for (uint32_t index_index = 0; index_index < p_access_chain->index_count; ++index_index) {
// Read index id
uint32_t index_id = 0;
CHECKED_READU32(p_parser, p_node->word_offset + SPIRV_ACCESS_CHAIN_INDEX_OFFSET + index_index, index_id);
// Find OpConstant node that contains index value
SpvReflectPrvNode* p_index_value_node = FindNode(p_parser, index_id);
if ((p_index_value_node != NULL) &&
(p_index_value_node->op == SpvOpConstant || p_index_value_node->op == SpvOpSpecConstant)) {
// Read index value
uint32_t index_value = UINT32_MAX;
CHECKED_READU32(p_parser, p_index_value_node->word_offset + 3, index_value);
assert(index_value != UINT32_MAX);
// Write index value to array
p_access_chain->indexes[index_index] = index_value;
}
}
}
++access_chain_index;
} break;
case SpvOpFunction: {
CHECKED_READU32(p_parser, p_node->word_offset + 2, p_node->result_id);
// Count function definitions, not function declarations. To determine
// the difference, set an in-function variable, and then if an OpLabel
// is reached before the end of the function increment the function
// count.
function_node = node_index;
} break;
case SpvOpLabel: {
if (function_node != (uint32_t)INVALID_VALUE) {
SpvReflectPrvNode* p_func_node = &(p_parser->nodes[function_node]);
CHECKED_READU32(p_parser, p_func_node->word_offset + 2, p_func_node->result_id);
++(p_parser->function_count);
}
FALLTHROUGH;
} // Fall through
case SpvOpFunctionEnd: {
function_node = (uint32_t)INVALID_VALUE;
} break;
case SpvOpFunctionParameter: {
CHECKED_READU32(p_parser, p_node->word_offset + 2, p_node->result_id);
} break;
case SpvOpBitcast:
case SpvOpShiftRightLogical:
case SpvOpIAdd:
case SpvOpISub: