/* * Copyright © 2015 Intel Corporation * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice (including the next * paragraph) shall be included in all copies or substantial portions of the * Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS * IN THE SOFTWARE. */ #pragma once #include #include #include #include #include #include #include #ifdef HAVE_VALGRIND #include #include #define VG(x) x #define __gen_validate_value(x) VALGRIND_CHECK_MEM_IS_DEFINED(&(x), sizeof(x)) #else #define VG(x) #endif #include "brw_device_info.h" #include "util/macros.h" #include "util/list.h" /* Pre-declarations needed for WSI entrypoints */ struct wl_surface; struct wl_display; typedef struct xcb_connection_t xcb_connection_t; typedef uint32_t xcb_visualid_t; typedef uint32_t xcb_window_t; #define VK_USE_PLATFORM_XCB_KHR #define VK_USE_PLATFORM_WAYLAND_KHR #define VK_PROTOTYPES #include #include #include #include "anv_entrypoints.h" #include "anv_gen_macros.h" #include "brw_context.h" #include "isl.h" #ifdef __cplusplus extern "C" { #endif #define MAX_VBS 32 #define MAX_SETS 8 #define MAX_RTS 8 #define MAX_VIEWPORTS 16 #define MAX_SCISSORS 16 #define MAX_PUSH_CONSTANTS_SIZE 128 #define MAX_DYNAMIC_BUFFERS 16 #define MAX_IMAGES 8 #define MAX_SAMPLES_LOG2 4 /* SKL supports 16 samples */ #define anv_noreturn __attribute__((__noreturn__)) #define anv_printflike(a, b) __attribute__((__format__(__printf__, a, b))) #define MIN(a, b) ((a) < (b) ? (a) : (b)) #define MAX(a, b) ((a) > (b) ? (a) : (b)) static inline uint32_t align_u32(uint32_t v, uint32_t a) { assert(a != 0 && a == (a & -a)); return (v + a - 1) & ~(a - 1); } static inline uint64_t align_u64(uint64_t v, uint64_t a) { assert(a != 0 && a == (a & -a)); return (v + a - 1) & ~(a - 1); } static inline int32_t align_i32(int32_t v, int32_t a) { assert(a != 0 && a == (a & -a)); return (v + a - 1) & ~(a - 1); } /** Alignment must be a power of 2. */ static inline bool anv_is_aligned(uintmax_t n, uintmax_t a) { assert(a == (a & -a)); return (n & (a - 1)) == 0; } static inline uint32_t anv_minify(uint32_t n, uint32_t levels) { if (unlikely(n == 0)) return 0; else return MAX(n >> levels, 1); } static inline float anv_clamp_f(float f, float min, float max) { assert(min < max); if (f > max) return max; else if (f < min) return min; else return f; } static inline bool anv_clear_mask(uint32_t *inout_mask, uint32_t clear_mask) { if (*inout_mask & clear_mask) { *inout_mask &= ~clear_mask; return true; } else { return false; } } #define for_each_bit(b, dword) \ for (uint32_t __dword = (dword); \ (b) = __builtin_ffs(__dword) - 1, __dword; \ __dword &= ~(1 << (b))) #define typed_memcpy(dest, src, count) ({ \ static_assert(sizeof(*src) == sizeof(*dest), ""); \ memcpy((dest), (src), (count) * sizeof(*(src))); \ }) #define zero(x) (memset(&(x), 0, sizeof(x))) /* Define no kernel as 1, since that's an illegal offset for a kernel */ #define NO_KERNEL 1 struct anv_common { VkStructureType sType; const void* pNext; }; /* Whenever we generate an error, pass it through this function. Useful for * debugging, where we can break on it. Only call at error site, not when * propagating errors. Might be useful to plug in a stack trace here. */ VkResult __vk_errorf(VkResult error, const char *file, int line, const char *format, ...); #ifdef DEBUG #define vk_error(error) __vk_errorf(error, __FILE__, __LINE__, NULL); #define vk_errorf(error, format, ...) __vk_errorf(error, __FILE__, __LINE__, format, ## __VA_ARGS__); #else #define vk_error(error) error #define vk_errorf(error, format, ...) error #endif void __anv_finishme(const char *file, int line, const char *format, ...) anv_printflike(3, 4); void anv_loge(const char *format, ...) anv_printflike(1, 2); void anv_loge_v(const char *format, va_list va); /** * Print a FINISHME message, including its source location. */ #define anv_finishme(format, ...) \ __anv_finishme(__FILE__, __LINE__, format, ##__VA_ARGS__); /* A non-fatal assert. Useful for debugging. */ #ifdef DEBUG #define anv_assert(x) ({ \ if (unlikely(!(x))) \ fprintf(stderr, "%s:%d ASSERT: %s\n", __FILE__, __LINE__, #x); \ }) #else #define anv_assert(x) #endif /** * If a block of code is annotated with anv_validate, then the block runs only * in debug builds. */ #ifdef DEBUG #define anv_validate if (1) #else #define anv_validate if (0) #endif void anv_abortf(const char *format, ...) anv_noreturn anv_printflike(1, 2); void anv_abortfv(const char *format, va_list va) anv_noreturn; #define stub_return(v) \ do { \ anv_finishme("stub %s", __func__); \ return (v); \ } while (0) #define stub() \ do { \ anv_finishme("stub %s", __func__); \ return; \ } while (0) /** * A dynamically growable, circular buffer. Elements are added at head and * removed from tail. head and tail are free-running uint32_t indices and we * only compute the modulo with size when accessing the array. This way, * number of bytes in the queue is always head - tail, even in case of * wraparound. */ struct anv_vector { uint32_t head; uint32_t tail; uint32_t element_size; uint32_t size; void *data; }; int anv_vector_init(struct anv_vector *queue, uint32_t element_size, uint32_t size); void *anv_vector_add(struct anv_vector *queue); void *anv_vector_remove(struct anv_vector *queue); static inline int anv_vector_length(struct anv_vector *queue) { return (queue->head - queue->tail) / queue->element_size; } static inline void * anv_vector_head(struct anv_vector *vector) { assert(vector->tail < vector->head); return (void *)((char *)vector->data + ((vector->head - vector->element_size) & (vector->size - 1))); } static inline void * anv_vector_tail(struct anv_vector *vector) { return (void *)((char *)vector->data + (vector->tail & (vector->size - 1))); } static inline void anv_vector_finish(struct anv_vector *queue) { free(queue->data); } #define anv_vector_foreach(elem, queue) \ static_assert(__builtin_types_compatible_p(__typeof__(queue), struct anv_vector *), ""); \ for (uint32_t __anv_vector_offset = (queue)->tail; \ elem = (queue)->data + (__anv_vector_offset & ((queue)->size - 1)), __anv_vector_offset < (queue)->head; \ __anv_vector_offset += (queue)->element_size) struct anv_bo { uint32_t gem_handle; /* Index into the current validation list. This is used by the * validation list building alrogithm to track which buffers are already * in the validation list so that we can ensure uniqueness. */ uint32_t index; /* Last known offset. This value is provided by the kernel when we * execbuf and is used as the presumed offset for the next bunch of * relocations. */ uint64_t offset; uint64_t size; void *map; /* We need to set the WRITE flag on winsys bos so GEM will know we're * writing to them and synchronize uses on other rings (eg if the display * server uses the blitter ring). */ bool is_winsys_bo; }; /* Represents a lock-free linked list of "free" things. This is used by * both the block pool and the state pools. Unfortunately, in order to * solve the ABA problem, we can't use a single uint32_t head. */ union anv_free_list { struct { int32_t offset; /* A simple count that is incremented every time the head changes. */ uint32_t count; }; uint64_t u64; }; #define ANV_FREE_LIST_EMPTY ((union anv_free_list) { { 1, 0 } }) struct anv_block_state { union { struct { uint32_t next; uint32_t end; }; uint64_t u64; }; }; struct anv_block_pool { struct anv_device *device; struct anv_bo bo; /* The offset from the start of the bo to the "center" of the block * pool. Pointers to allocated blocks are given by * bo.map + center_bo_offset + offsets. */ uint32_t center_bo_offset; /* Current memory map of the block pool. This pointer may or may not * point to the actual beginning of the block pool memory. If * anv_block_pool_alloc_back has ever been called, then this pointer * will point to the "center" position of the buffer and all offsets * (negative or positive) given out by the block pool alloc functions * will be valid relative to this pointer. * * In particular, map == bo.map + center_offset */ void *map; int fd; /** * Array of mmaps and gem handles owned by the block pool, reclaimed when * the block pool is destroyed. */ struct anv_vector mmap_cleanups; uint32_t block_size; union anv_free_list free_list; struct anv_block_state state; union anv_free_list back_free_list; struct anv_block_state back_state; }; /* Block pools are backed by a fixed-size 2GB memfd */ #define BLOCK_POOL_MEMFD_SIZE (1ull << 32) /* The center of the block pool is also the middle of the memfd. This may * change in the future if we decide differently for some reason. */ #define BLOCK_POOL_MEMFD_CENTER (BLOCK_POOL_MEMFD_SIZE / 2) static inline uint32_t anv_block_pool_size(struct anv_block_pool *pool) { return pool->state.end + pool->back_state.end; } struct anv_state { int32_t offset; uint32_t alloc_size; void *map; }; struct anv_fixed_size_state_pool { size_t state_size; union anv_free_list free_list; struct anv_block_state block; }; #define ANV_MIN_STATE_SIZE_LOG2 6 #define ANV_MAX_STATE_SIZE_LOG2 10 #define ANV_STATE_BUCKETS (ANV_MAX_STATE_SIZE_LOG2 - ANV_MIN_STATE_SIZE_LOG2) struct anv_state_pool { struct anv_block_pool *block_pool; struct anv_fixed_size_state_pool buckets[ANV_STATE_BUCKETS]; }; struct anv_state_stream_block; struct anv_state_stream { struct anv_block_pool *block_pool; /* The current working block */ struct anv_state_stream_block *block; /* Offset at which the current block starts */ uint32_t start; /* Offset at which to allocate the next state */ uint32_t next; /* Offset at which the current block ends */ uint32_t end; }; #define CACHELINE_SIZE 64 #define CACHELINE_MASK 63 static inline void anv_clflush_range(void *start, size_t size) { void *p = (void *) (((uintptr_t) start) & ~CACHELINE_MASK); void *end = start + size; __builtin_ia32_mfence(); while (p < end) { __builtin_ia32_clflush(p); p += CACHELINE_SIZE; } } static void inline anv_state_clflush(struct anv_state state) { anv_clflush_range(state.map, state.alloc_size); } void anv_block_pool_init(struct anv_block_pool *pool, struct anv_device *device, uint32_t block_size); void anv_block_pool_finish(struct anv_block_pool *pool); int32_t anv_block_pool_alloc(struct anv_block_pool *pool); int32_t anv_block_pool_alloc_back(struct anv_block_pool *pool); void anv_block_pool_free(struct anv_block_pool *pool, int32_t offset); void anv_state_pool_init(struct anv_state_pool *pool, struct anv_block_pool *block_pool); void anv_state_pool_finish(struct anv_state_pool *pool); struct anv_state anv_state_pool_alloc(struct anv_state_pool *pool, size_t state_size, size_t alignment); void anv_state_pool_free(struct anv_state_pool *pool, struct anv_state state); void anv_state_stream_init(struct anv_state_stream *stream, struct anv_block_pool *block_pool); void anv_state_stream_finish(struct anv_state_stream *stream); struct anv_state anv_state_stream_alloc(struct anv_state_stream *stream, uint32_t size, uint32_t alignment); /** * Implements a pool of re-usable BOs. The interface is identical to that * of block_pool except that each block is its own BO. */ struct anv_bo_pool { struct anv_device *device; uint32_t bo_size; void *free_list; }; void anv_bo_pool_init(struct anv_bo_pool *pool, struct anv_device *device, uint32_t block_size); void anv_bo_pool_finish(struct anv_bo_pool *pool); VkResult anv_bo_pool_alloc(struct anv_bo_pool *pool, struct anv_bo *bo); void anv_bo_pool_free(struct anv_bo_pool *pool, const struct anv_bo *bo); void *anv_resolve_entrypoint(uint32_t index); extern struct anv_dispatch_table dtable; #define ANV_CALL(func) ({ \ if (dtable.func == NULL) { \ size_t idx = offsetof(struct anv_dispatch_table, func) / sizeof(void *); \ dtable.entrypoints[idx] = anv_resolve_entrypoint(idx); \ } \ dtable.func; \ }) static inline void * anv_alloc(const VkAllocationCallbacks *alloc, size_t size, size_t align, VkSystemAllocationScope scope) { return alloc->pfnAllocation(alloc->pUserData, size, align, scope); } static inline void * anv_realloc(const VkAllocationCallbacks *alloc, void *ptr, size_t size, size_t align, VkSystemAllocationScope scope) { return alloc->pfnReallocation(alloc->pUserData, ptr, size, align, scope); } static inline void anv_free(const VkAllocationCallbacks *alloc, void *data) { alloc->pfnFree(alloc->pUserData, data); } static inline void * anv_alloc2(const VkAllocationCallbacks *parent_alloc, const VkAllocationCallbacks *alloc, size_t size, size_t align, VkSystemAllocationScope scope) { if (alloc) return anv_alloc(alloc, size, align, scope); else return anv_alloc(parent_alloc, size, align, scope); } static inline void anv_free2(const VkAllocationCallbacks *parent_alloc, const VkAllocationCallbacks *alloc, void *data) { if (alloc) anv_free(alloc, data); else anv_free(parent_alloc, data); } struct anv_physical_device { VK_LOADER_DATA _loader_data; struct anv_instance * instance; uint32_t chipset_id; const char * path; const char * name; const struct brw_device_info * info; uint64_t aperture_size; struct brw_compiler * compiler; struct isl_device isl_dev; }; struct anv_wsi_interaface; #define VK_ICD_WSI_PLATFORM_MAX 5 struct anv_instance { VK_LOADER_DATA _loader_data; VkAllocationCallbacks alloc; uint32_t apiVersion; int physicalDeviceCount; struct anv_physical_device physicalDevice; struct anv_wsi_interface * wsi[VK_ICD_WSI_PLATFORM_MAX]; }; VkResult anv_init_wsi(struct anv_instance *instance); void anv_finish_wsi(struct anv_instance *instance); struct anv_meta_state { VkAllocationCallbacks alloc; /** * Use array element `i` for images with `2^i` samples. */ struct { /** * Pipeline N is used to clear color attachment N of the current * subpass. * * HACK: We use one pipeline per color attachment to work around the * compiler's inability to dynamically set the render target index of * the render target write message. */ struct anv_pipeline *color_pipelines[MAX_RTS]; struct anv_pipeline *depth_only_pipeline; struct anv_pipeline *stencil_only_pipeline; struct anv_pipeline *depthstencil_pipeline; } clear[1 + MAX_SAMPLES_LOG2]; struct { VkRenderPass render_pass; /** Pipeline that blits from a 1D image. */ VkPipeline pipeline_1d_src; /** Pipeline that blits from a 2D image. */ VkPipeline pipeline_2d_src; /** Pipeline that blits from a 3D image. */ VkPipeline pipeline_3d_src; VkPipelineLayout pipeline_layout; VkDescriptorSetLayout ds_layout; } blit; struct { /** Pipeline [i] resolves an image with 2^(i+1) samples. */ VkPipeline pipelines[MAX_SAMPLES_LOG2]; VkRenderPass pass; VkPipelineLayout pipeline_layout; VkDescriptorSetLayout ds_layout; } resolve; }; struct anv_queue { VK_LOADER_DATA _loader_data; struct anv_device * device; struct anv_state_pool * pool; }; struct anv_pipeline_cache { struct anv_device * device; struct anv_state_stream program_stream; pthread_mutex_t mutex; uint32_t total_size; uint32_t table_size; uint32_t kernel_count; uint32_t *table; }; void anv_pipeline_cache_init(struct anv_pipeline_cache *cache, struct anv_device *device); void anv_pipeline_cache_finish(struct anv_pipeline_cache *cache); uint32_t anv_pipeline_cache_search(struct anv_pipeline_cache *cache, const unsigned char *sha1, void *prog_data); uint32_t anv_pipeline_cache_upload_kernel(struct anv_pipeline_cache *cache, const unsigned char *sha1, const void *kernel, size_t kernel_size, const void *prog_data, size_t prog_data_size); struct anv_device { VK_LOADER_DATA _loader_data; VkAllocationCallbacks alloc; struct anv_instance * instance; uint32_t chipset_id; struct brw_device_info info; struct isl_device isl_dev; int context_id; int fd; struct anv_bo_pool batch_bo_pool; struct anv_block_pool dynamic_state_block_pool; struct anv_state_pool dynamic_state_pool; struct anv_block_pool instruction_block_pool; struct anv_pipeline_cache default_pipeline_cache; struct anv_block_pool surface_state_block_pool; struct anv_state_pool surface_state_pool; struct anv_bo workaround_bo; struct anv_meta_state meta_state; struct anv_state border_colors; struct anv_queue queue; struct anv_block_pool scratch_block_pool; pthread_mutex_t mutex; }; VkResult gen7_init_device_state(struct anv_device *device); VkResult gen75_init_device_state(struct anv_device *device); VkResult gen8_init_device_state(struct anv_device *device); VkResult gen9_init_device_state(struct anv_device *device); void anv_device_get_cache_uuid(void *uuid); void* anv_gem_mmap(struct anv_device *device, uint32_t gem_handle, uint64_t offset, uint64_t size, uint32_t flags); void anv_gem_munmap(void *p, uint64_t size); uint32_t anv_gem_create(struct anv_device *device, size_t size); void anv_gem_close(struct anv_device *device, uint32_t gem_handle); uint32_t anv_gem_userptr(struct anv_device *device, void *mem, size_t size); int anv_gem_wait(struct anv_device *device, uint32_t gem_handle, int64_t *timeout_ns); int anv_gem_execbuffer(struct anv_device *device, struct drm_i915_gem_execbuffer2 *execbuf); int anv_gem_set_tiling(struct anv_device *device, uint32_t gem_handle, uint32_t stride, uint32_t tiling); int anv_gem_create_context(struct anv_device *device); int anv_gem_destroy_context(struct anv_device *device, int context); int anv_gem_get_param(int fd, uint32_t param); bool anv_gem_get_bit6_swizzle(int fd, uint32_t tiling); int anv_gem_get_aperture(int fd, uint64_t *size); int anv_gem_handle_to_fd(struct anv_device *device, uint32_t gem_handle); uint32_t anv_gem_fd_to_handle(struct anv_device *device, int fd); int anv_gem_set_caching(struct anv_device *device, uint32_t gem_handle, uint32_t caching); int anv_gem_set_domain(struct anv_device *device, uint32_t gem_handle, uint32_t read_domains, uint32_t write_domain); VkResult anv_bo_init_new(struct anv_bo *bo, struct anv_device *device, uint64_t size); struct anv_reloc_list { size_t num_relocs; size_t array_length; struct drm_i915_gem_relocation_entry * relocs; struct anv_bo ** reloc_bos; }; VkResult anv_reloc_list_init(struct anv_reloc_list *list, const VkAllocationCallbacks *alloc); void anv_reloc_list_finish(struct anv_reloc_list *list, const VkAllocationCallbacks *alloc); uint64_t anv_reloc_list_add(struct anv_reloc_list *list, const VkAllocationCallbacks *alloc, uint32_t offset, struct anv_bo *target_bo, uint32_t delta); struct anv_batch_bo { /* Link in the anv_cmd_buffer.owned_batch_bos list */ struct list_head link; struct anv_bo bo; /* Bytes actually consumed in this batch BO */ size_t length; /* Last seen surface state block pool bo offset */ uint32_t last_ss_pool_bo_offset; struct anv_reloc_list relocs; }; struct anv_batch { const VkAllocationCallbacks * alloc; void * start; void * end; void * next; struct anv_reloc_list * relocs; /* This callback is called (with the associated user data) in the event * that the batch runs out of space. */ VkResult (*extend_cb)(struct anv_batch *, void *); void * user_data; }; void *anv_batch_emit_dwords(struct anv_batch *batch, int num_dwords); void anv_batch_emit_batch(struct anv_batch *batch, struct anv_batch *other); uint64_t anv_batch_emit_reloc(struct anv_batch *batch, void *location, struct anv_bo *bo, uint32_t offset); VkResult anv_device_submit_simple_batch(struct anv_device *device, struct anv_batch *batch); struct anv_address { struct anv_bo *bo; uint32_t offset; }; #define __gen_address_type struct anv_address #define __gen_user_data struct anv_batch static inline uint64_t __gen_combine_address(struct anv_batch *batch, void *location, const struct anv_address address, uint32_t delta) { if (address.bo == NULL) { return address.offset + delta; } else { assert(batch->start <= location && location < batch->end); return anv_batch_emit_reloc(batch, location, address.bo, address.offset + delta); } } /* Wrapper macros needed to work around preprocessor argument issues. In * particular, arguments don't get pre-evaluated if they are concatenated. * This means that, if you pass GENX(3DSTATE_PS) into the emit macro, the * GENX macro won't get evaluated if the emit macro contains "cmd ## foo". * We can work around this easily enough with these helpers. */ #define __anv_cmd_length(cmd) cmd ## _length #define __anv_cmd_length_bias(cmd) cmd ## _length_bias #define __anv_cmd_header(cmd) cmd ## _header #define __anv_cmd_pack(cmd) cmd ## _pack #define anv_batch_emit(batch, cmd, ...) do { \ void *__dst = anv_batch_emit_dwords(batch, __anv_cmd_length(cmd)); \ struct cmd __template = { \ __anv_cmd_header(cmd), \ __VA_ARGS__ \ }; \ __anv_cmd_pack(cmd)(batch, __dst, &__template); \ VG(VALGRIND_CHECK_MEM_IS_DEFINED(__dst, __anv_cmd_length(cmd) * 4)); \ } while (0) #define anv_batch_emitn(batch, n, cmd, ...) ({ \ void *__dst = anv_batch_emit_dwords(batch, n); \ struct cmd __template = { \ __anv_cmd_header(cmd), \ .DWordLength = n - __anv_cmd_length_bias(cmd), \ __VA_ARGS__ \ }; \ __anv_cmd_pack(cmd)(batch, __dst, &__template); \ __dst; \ }) #define anv_batch_emit_merge(batch, dwords0, dwords1) \ do { \ uint32_t *dw; \ \ static_assert(ARRAY_SIZE(dwords0) == ARRAY_SIZE(dwords1), "mismatch merge"); \ dw = anv_batch_emit_dwords((batch), ARRAY_SIZE(dwords0)); \ for (uint32_t i = 0; i < ARRAY_SIZE(dwords0); i++) \ dw[i] = (dwords0)[i] | (dwords1)[i]; \ VG(VALGRIND_CHECK_MEM_IS_DEFINED(dw, ARRAY_SIZE(dwords0) * 4));\ } while (0) #define anv_state_pool_emit(pool, cmd, align, ...) ({ \ const uint32_t __size = __anv_cmd_length(cmd) * 4; \ struct anv_state __state = \ anv_state_pool_alloc((pool), __size, align); \ struct cmd __template = { \ __VA_ARGS__ \ }; \ __anv_cmd_pack(cmd)(NULL, __state.map, &__template); \ VG(VALGRIND_CHECK_MEM_IS_DEFINED(__state.map, __anv_cmd_length(cmd) * 4)); \ if (!(pool)->block_pool->device->info.has_llc) \ anv_state_clflush(__state); \ __state; \ }) #define GEN7_MOCS (struct GEN7_MEMORY_OBJECT_CONTROL_STATE) { \ .GraphicsDataTypeGFDT = 0, \ .LLCCacheabilityControlLLCCC = 0, \ .L3CacheabilityControlL3CC = 1, \ } #define GEN75_MOCS (struct GEN75_MEMORY_OBJECT_CONTROL_STATE) { \ .LLCeLLCCacheabilityControlLLCCC = 0, \ .L3CacheabilityControlL3CC = 1, \ } #define GEN8_MOCS { \ .MemoryTypeLLCeLLCCacheabilityControl = WB, \ .TargetCache = L3DefertoPATforLLCeLLCselection, \ .AgeforQUADLRU = 0 \ } /* Skylake: MOCS is now an index into an array of 62 different caching * configurations programmed by the kernel. */ #define GEN9_MOCS { \ /* TC=LLC/eLLC, LeCC=WB, LRUM=3, L3CC=WB */ \ .IndextoMOCSTables = 2 \ } #define GEN9_MOCS_PTE { \ /* TC=LLC/eLLC, LeCC=WB, LRUM=3, L3CC=WB */ \ .IndextoMOCSTables = 1 \ } struct anv_device_memory { struct anv_bo bo; uint32_t type_index; VkDeviceSize map_size; void * map; }; /** * Header for Vertex URB Entry (VUE) */ struct anv_vue_header { uint32_t Reserved; uint32_t RTAIndex; /* RenderTargetArrayIndex */ uint32_t ViewportIndex; float PointWidth; }; struct anv_descriptor_set_binding_layout { /* Number of array elements in this binding */ uint16_t array_size; /* Index into the flattend descriptor set */ uint16_t descriptor_index; /* Index into the dynamic state array for a dynamic buffer */ int16_t dynamic_offset_index; /* Index into the descriptor set buffer views */ int16_t buffer_index; struct { /* Index into the binding table for the associated surface */ int16_t surface_index; /* Index into the sampler table for the associated sampler */ int16_t sampler_index; /* Index into the image table for the associated image */ int16_t image_index; } stage[MESA_SHADER_STAGES]; /* Immutable samplers (or NULL if no immutable samplers) */ struct anv_sampler **immutable_samplers; }; struct anv_descriptor_set_layout { /* Number of bindings in this descriptor set */ uint16_t binding_count; /* Total size of the descriptor set with room for all array entries */ uint16_t size; /* Shader stages affected by this descriptor set */ uint16_t shader_stages; /* Number of buffers in this descriptor set */ uint16_t buffer_count; /* Number of dynamic offsets used by this descriptor set */ uint16_t dynamic_offset_count; /* Bindings in this descriptor set */ struct anv_descriptor_set_binding_layout binding[0]; }; struct anv_descriptor { VkDescriptorType type; union { struct { struct anv_image_view *image_view; struct anv_sampler *sampler; }; struct anv_buffer_view *buffer_view; }; }; struct anv_descriptor_set { const struct anv_descriptor_set_layout *layout; uint32_t buffer_count; struct anv_buffer_view *buffer_views; struct anv_descriptor descriptors[0]; }; VkResult anv_descriptor_set_create(struct anv_device *device, const struct anv_descriptor_set_layout *layout, struct anv_descriptor_set **out_set); void anv_descriptor_set_destroy(struct anv_device *device, struct anv_descriptor_set *set); struct anv_pipeline_binding { /* The descriptor set this surface corresponds to */ uint16_t set; /* Offset into the descriptor set */ uint16_t offset; }; struct anv_pipeline_layout { struct { struct anv_descriptor_set_layout *layout; uint32_t dynamic_offset_start; struct { uint32_t surface_start; uint32_t sampler_start; uint32_t image_start; } stage[MESA_SHADER_STAGES]; } set[MAX_SETS]; uint32_t num_sets; struct { bool has_dynamic_offsets; uint32_t surface_count; struct anv_pipeline_binding *surface_to_descriptor; uint32_t sampler_count; struct anv_pipeline_binding *sampler_to_descriptor; uint32_t image_count; } stage[MESA_SHADER_STAGES]; struct anv_pipeline_binding entries[0]; }; struct anv_buffer { struct anv_device * device; VkDeviceSize size; VkBufferUsageFlags usage; /* Set when bound */ struct anv_bo * bo; VkDeviceSize offset; }; enum anv_cmd_dirty_bits { ANV_CMD_DIRTY_DYNAMIC_VIEWPORT = 1 << 0, /* VK_DYNAMIC_STATE_VIEWPORT */ ANV_CMD_DIRTY_DYNAMIC_SCISSOR = 1 << 1, /* VK_DYNAMIC_STATE_SCISSOR */ ANV_CMD_DIRTY_DYNAMIC_LINE_WIDTH = 1 << 2, /* VK_DYNAMIC_STATE_LINE_WIDTH */ ANV_CMD_DIRTY_DYNAMIC_DEPTH_BIAS = 1 << 3, /* VK_DYNAMIC_STATE_DEPTH_BIAS */ ANV_CMD_DIRTY_DYNAMIC_BLEND_CONSTANTS = 1 << 4, /* VK_DYNAMIC_STATE_BLEND_CONSTANTS */ ANV_CMD_DIRTY_DYNAMIC_DEPTH_BOUNDS = 1 << 5, /* VK_DYNAMIC_STATE_DEPTH_BOUNDS */ ANV_CMD_DIRTY_DYNAMIC_STENCIL_COMPARE_MASK = 1 << 6, /* VK_DYNAMIC_STATE_STENCIL_COMPARE_MASK */ ANV_CMD_DIRTY_DYNAMIC_STENCIL_WRITE_MASK = 1 << 7, /* VK_DYNAMIC_STATE_STENCIL_WRITE_MASK */ ANV_CMD_DIRTY_DYNAMIC_STENCIL_REFERENCE = 1 << 8, /* VK_DYNAMIC_STATE_STENCIL_REFERENCE */ ANV_CMD_DIRTY_DYNAMIC_ALL = (1 << 9) - 1, ANV_CMD_DIRTY_PIPELINE = 1 << 9, ANV_CMD_DIRTY_INDEX_BUFFER = 1 << 10, ANV_CMD_DIRTY_RENDER_TARGETS = 1 << 11, }; typedef uint32_t anv_cmd_dirty_mask_t; struct anv_vertex_binding { struct anv_buffer * buffer; VkDeviceSize offset; }; struct anv_push_constants { /* Current allocated size of this push constants data structure. * Because a decent chunk of it may not be used (images on SKL, for * instance), we won't actually allocate the entire structure up-front. */ uint32_t size; /* Push constant data provided by the client through vkPushConstants */ uint8_t client_data[MAX_PUSH_CONSTANTS_SIZE]; /* Our hardware only provides zero-based vertex and instance id so, in * order to satisfy the vulkan requirements, we may have to push one or * both of these into the shader. */ uint32_t base_vertex; uint32_t base_instance; /* Offsets and ranges for dynamically bound buffers */ struct { uint32_t offset; uint32_t range; } dynamic[MAX_DYNAMIC_BUFFERS]; /* Image data for image_load_store on pre-SKL */ struct brw_image_param images[MAX_IMAGES]; }; struct anv_dynamic_state { struct { uint32_t count; VkViewport viewports[MAX_VIEWPORTS]; } viewport; struct { uint32_t count; VkRect2D scissors[MAX_SCISSORS]; } scissor; float line_width; struct { float bias; float clamp; float slope; } depth_bias; float blend_constants[4]; struct { float min; float max; } depth_bounds; struct { uint32_t front; uint32_t back; } stencil_compare_mask; struct { uint32_t front; uint32_t back; } stencil_write_mask; struct { uint32_t front; uint32_t back; } stencil_reference; }; extern const struct anv_dynamic_state default_dynamic_state; void anv_dynamic_state_copy(struct anv_dynamic_state *dest, const struct anv_dynamic_state *src, uint32_t copy_mask); /** * Attachment state when recording a renderpass instance. * * The clear value is valid only if there exists a pending clear. */ struct anv_attachment_state { VkImageAspectFlags pending_clear_aspects; VkClearValue clear_value; }; /** State required while building cmd buffer */ struct anv_cmd_state { /* PIPELINE_SELECT.PipelineSelection */ uint32_t current_pipeline; uint32_t current_l3_config; uint32_t vb_dirty; anv_cmd_dirty_mask_t dirty; anv_cmd_dirty_mask_t compute_dirty; uint32_t num_workgroups_offset; struct anv_bo *num_workgroups_bo; VkShaderStageFlags descriptors_dirty; VkShaderStageFlags push_constants_dirty; uint32_t scratch_size; struct anv_pipeline * pipeline; struct anv_pipeline * compute_pipeline; struct anv_framebuffer * framebuffer; struct anv_render_pass * pass; struct anv_subpass * subpass; uint32_t restart_index; struct anv_vertex_binding vertex_bindings[MAX_VBS]; struct anv_descriptor_set * descriptors[MAX_SETS]; struct anv_push_constants * push_constants[MESA_SHADER_STAGES]; struct anv_state binding_tables[MESA_SHADER_STAGES]; struct anv_state samplers[MESA_SHADER_STAGES]; struct anv_dynamic_state dynamic; bool need_query_wa; /** * Array length is anv_cmd_state::pass::attachment_count. Array content is * valid only when recording a render pass instance. */ struct anv_attachment_state * attachments; struct { struct anv_buffer * index_buffer; uint32_t index_type; /**< 3DSTATE_INDEX_BUFFER.IndexFormat */ uint32_t index_offset; } gen7; }; struct anv_cmd_pool { VkAllocationCallbacks alloc; struct list_head cmd_buffers; }; #define ANV_CMD_BUFFER_BATCH_SIZE 8192 enum anv_cmd_buffer_exec_mode { ANV_CMD_BUFFER_EXEC_MODE_PRIMARY, ANV_CMD_BUFFER_EXEC_MODE_EMIT, ANV_CMD_BUFFER_EXEC_MODE_CHAIN, ANV_CMD_BUFFER_EXEC_MODE_COPY_AND_CHAIN, }; struct anv_cmd_buffer { VK_LOADER_DATA _loader_data; struct anv_device * device; struct anv_cmd_pool * pool; struct list_head pool_link; struct anv_batch batch; /* Fields required for the actual chain of anv_batch_bo's. * * These fields are initialized by anv_cmd_buffer_init_batch_bo_chain(). */ struct list_head batch_bos; enum anv_cmd_buffer_exec_mode exec_mode; /* A vector of anv_batch_bo pointers for every batch or surface buffer * referenced by this command buffer * * initialized by anv_cmd_buffer_init_batch_bo_chain() */ struct anv_vector seen_bbos; /* A vector of int32_t's for every block of binding tables. * * initialized by anv_cmd_buffer_init_batch_bo_chain() */ struct anv_vector bt_blocks; uint32_t bt_next; struct anv_reloc_list surface_relocs; /* Information needed for execbuf * * These fields are generated by anv_cmd_buffer_prepare_execbuf(). */ struct { struct drm_i915_gem_execbuffer2 execbuf; struct drm_i915_gem_exec_object2 * objects; uint32_t bo_count; struct anv_bo ** bos; /* Allocated length of the 'objects' and 'bos' arrays */ uint32_t array_length; bool need_reloc; } execbuf2; /* Serial for tracking buffer completion */ uint32_t serial; /* Stream objects for storing temporary data */ struct anv_state_stream surface_state_stream; struct anv_state_stream dynamic_state_stream; VkCommandBufferUsageFlags usage_flags; VkCommandBufferLevel level; struct anv_cmd_state state; }; VkResult anv_cmd_buffer_init_batch_bo_chain(struct anv_cmd_buffer *cmd_buffer); void anv_cmd_buffer_fini_batch_bo_chain(struct anv_cmd_buffer *cmd_buffer); void anv_cmd_buffer_reset_batch_bo_chain(struct anv_cmd_buffer *cmd_buffer); void anv_cmd_buffer_end_batch_buffer(struct anv_cmd_buffer *cmd_buffer); void anv_cmd_buffer_add_secondary(struct anv_cmd_buffer *primary, struct anv_cmd_buffer *secondary); void anv_cmd_buffer_prepare_execbuf(struct anv_cmd_buffer *cmd_buffer); VkResult anv_cmd_buffer_emit_binding_table(struct anv_cmd_buffer *cmd_buffer, unsigned stage, struct anv_state *bt_state); VkResult anv_cmd_buffer_emit_samplers(struct anv_cmd_buffer *cmd_buffer, unsigned stage, struct anv_state *state); uint32_t gen7_cmd_buffer_flush_descriptor_sets(struct anv_cmd_buffer *cmd_buffer); void gen7_cmd_buffer_emit_descriptor_pointers(struct anv_cmd_buffer *cmd_buffer, uint32_t stages); struct anv_state anv_cmd_buffer_emit_dynamic(struct anv_cmd_buffer *cmd_buffer, const void *data, uint32_t size, uint32_t alignment); struct anv_state anv_cmd_buffer_merge_dynamic(struct anv_cmd_buffer *cmd_buffer, uint32_t *a, uint32_t *b, uint32_t dwords, uint32_t alignment); struct anv_address anv_cmd_buffer_surface_base_address(struct anv_cmd_buffer *cmd_buffer); struct anv_state anv_cmd_buffer_alloc_binding_table(struct anv_cmd_buffer *cmd_buffer, uint32_t entries, uint32_t *state_offset); struct anv_state anv_cmd_buffer_alloc_surface_state(struct anv_cmd_buffer *cmd_buffer); struct anv_state anv_cmd_buffer_alloc_dynamic_state(struct anv_cmd_buffer *cmd_buffer, uint32_t size, uint32_t alignment); VkResult anv_cmd_buffer_new_binding_table_block(struct anv_cmd_buffer *cmd_buffer); void gen8_cmd_buffer_emit_viewport(struct anv_cmd_buffer *cmd_buffer); void gen7_cmd_buffer_emit_scissor(struct anv_cmd_buffer *cmd_buffer); void gen7_cmd_buffer_emit_state_base_address(struct anv_cmd_buffer *cmd_buffer); void gen75_cmd_buffer_emit_state_base_address(struct anv_cmd_buffer *cmd_buffer); void gen8_cmd_buffer_emit_state_base_address(struct anv_cmd_buffer *cmd_buffer); void gen9_cmd_buffer_emit_state_base_address(struct anv_cmd_buffer *cmd_buffer); void anv_cmd_buffer_emit_state_base_address(struct anv_cmd_buffer *cmd_buffer); void anv_cmd_state_setup_attachments(struct anv_cmd_buffer *cmd_buffer, const VkRenderPassBeginInfo *info); void gen7_cmd_buffer_set_subpass(struct anv_cmd_buffer *cmd_buffer, struct anv_subpass *subpass); void gen75_cmd_buffer_set_subpass(struct anv_cmd_buffer *cmd_buffer, struct anv_subpass *subpass); void gen8_cmd_buffer_set_subpass(struct anv_cmd_buffer *cmd_buffer, struct anv_subpass *subpass); void gen9_cmd_buffer_set_subpass(struct anv_cmd_buffer *cmd_buffer, struct anv_subpass *subpass); void anv_cmd_buffer_set_subpass(struct anv_cmd_buffer *cmd_buffer, struct anv_subpass *subpass); void gen7_flush_pipeline_select_3d(struct anv_cmd_buffer *cmd_buffer); void gen75_flush_pipeline_select_3d(struct anv_cmd_buffer *cmd_buffer); void gen8_flush_pipeline_select_3d(struct anv_cmd_buffer *cmd_buffer); void gen9_flush_pipeline_select_3d(struct anv_cmd_buffer *cmd_buffer); void gen7_cmd_buffer_flush_state(struct anv_cmd_buffer *cmd_buffer); void gen75_cmd_buffer_flush_state(struct anv_cmd_buffer *cmd_buffer); void gen8_cmd_buffer_flush_state(struct anv_cmd_buffer *cmd_buffer); void gen9_cmd_buffer_flush_state(struct anv_cmd_buffer *cmd_buffer); void gen7_cmd_buffer_flush_compute_state(struct anv_cmd_buffer *cmd_buffer); void gen75_cmd_buffer_flush_compute_state(struct anv_cmd_buffer *cmd_buffer); void gen8_cmd_buffer_flush_compute_state(struct anv_cmd_buffer *cmd_buffer); void gen9_cmd_buffer_flush_compute_state(struct anv_cmd_buffer *cmd_buffer); struct anv_state anv_cmd_buffer_push_constants(struct anv_cmd_buffer *cmd_buffer, gl_shader_stage stage); struct anv_state anv_cmd_buffer_cs_push_constants(struct anv_cmd_buffer *cmd_buffer); void anv_cmd_buffer_clear_subpass(struct anv_cmd_buffer *cmd_buffer); void anv_cmd_buffer_resolve_subpass(struct anv_cmd_buffer *cmd_buffer); const struct anv_image_view * anv_cmd_buffer_get_depth_stencil_view(const struct anv_cmd_buffer *cmd_buffer); void anv_cmd_buffer_dump(struct anv_cmd_buffer *cmd_buffer); struct anv_fence { struct anv_bo bo; struct drm_i915_gem_execbuffer2 execbuf; struct drm_i915_gem_exec_object2 exec2_objects[1]; bool ready; }; struct anv_event { uint64_t semaphore; struct anv_state state; }; struct nir_shader; struct anv_shader_module { struct nir_shader * nir; unsigned char sha1[20]; uint32_t size; char data[0]; }; void anv_hash_shader(unsigned char *hash, const void *key, size_t key_size, struct anv_shader_module *module, const char *entrypoint, const VkSpecializationInfo *spec_info); static inline gl_shader_stage vk_to_mesa_shader_stage(VkShaderStageFlagBits vk_stage) { assert(__builtin_popcount(vk_stage) == 1); return ffs(vk_stage) - 1; } static inline VkShaderStageFlagBits mesa_to_vk_shader_stage(gl_shader_stage mesa_stage) { return (1 << mesa_stage); } #define ANV_STAGE_MASK ((1 << MESA_SHADER_STAGES) - 1) #define anv_foreach_stage(stage, stage_bits) \ for (gl_shader_stage stage, \ __tmp = (gl_shader_stage)((stage_bits) & ANV_STAGE_MASK); \ stage = __builtin_ffs(__tmp) - 1, __tmp; \ __tmp &= ~(1 << (stage))) struct anv_pipeline { struct anv_device * device; struct anv_batch batch; uint32_t batch_data[512]; struct anv_reloc_list batch_relocs; uint32_t dynamic_state_mask; struct anv_dynamic_state dynamic_state; struct anv_pipeline_layout * layout; bool use_repclear; struct brw_vs_prog_data vs_prog_data; struct brw_wm_prog_data wm_prog_data; struct brw_gs_prog_data gs_prog_data; struct brw_cs_prog_data cs_prog_data; bool writes_point_size; struct brw_stage_prog_data * prog_data[MESA_SHADER_STAGES]; uint32_t scratch_start[MESA_SHADER_STAGES]; uint32_t total_scratch; struct { uint32_t vs_start; uint32_t vs_size; uint32_t nr_vs_entries; uint32_t gs_start; uint32_t gs_size; uint32_t nr_gs_entries; } urb; VkShaderStageFlags active_stages; struct anv_state blend_state; uint32_t vs_simd8; uint32_t vs_vec4; uint32_t ps_simd8; uint32_t ps_simd16; uint32_t ps_ksp0; uint32_t ps_ksp2; uint32_t ps_grf_start0; uint32_t ps_grf_start2; uint32_t gs_kernel; uint32_t cs_simd; uint32_t vb_used; uint32_t binding_stride[MAX_VBS]; bool instancing_enable[MAX_VBS]; bool primitive_restart; uint32_t topology; uint32_t cs_thread_width_max; uint32_t cs_right_mask; struct { uint32_t sf[7]; uint32_t depth_stencil_state[3]; } gen7; struct { uint32_t sf[4]; uint32_t raster[5]; uint32_t wm_depth_stencil[3]; } gen8; struct { uint32_t wm_depth_stencil[4]; } gen9; }; struct anv_graphics_pipeline_create_info { /** * If non-negative, overrides the color attachment count of the pipeline's * subpass. */ int8_t color_attachment_count; bool use_repclear; bool disable_viewport; bool disable_scissor; bool disable_vs; bool use_rectlist; }; VkResult anv_pipeline_init(struct anv_pipeline *pipeline, struct anv_device *device, struct anv_pipeline_cache *cache, const VkGraphicsPipelineCreateInfo *pCreateInfo, const struct anv_graphics_pipeline_create_info *extra, const VkAllocationCallbacks *alloc); VkResult anv_pipeline_compile_cs(struct anv_pipeline *pipeline, struct anv_pipeline_cache *cache, const VkComputePipelineCreateInfo *info, struct anv_shader_module *module, const char *entrypoint, const VkSpecializationInfo *spec_info); VkResult anv_graphics_pipeline_create(VkDevice device, VkPipelineCache cache, const VkGraphicsPipelineCreateInfo *pCreateInfo, const struct anv_graphics_pipeline_create_info *extra, const VkAllocationCallbacks *alloc, VkPipeline *pPipeline); VkResult gen7_graphics_pipeline_create(VkDevice _device, struct anv_pipeline_cache *cache, const VkGraphicsPipelineCreateInfo *pCreateInfo, const struct anv_graphics_pipeline_create_info *extra, const VkAllocationCallbacks *alloc, VkPipeline *pPipeline); VkResult gen75_graphics_pipeline_create(VkDevice _device, struct anv_pipeline_cache *cache, const VkGraphicsPipelineCreateInfo *pCreateInfo, const struct anv_graphics_pipeline_create_info *extra, const VkAllocationCallbacks *alloc, VkPipeline *pPipeline); VkResult gen8_graphics_pipeline_create(VkDevice _device, struct anv_pipeline_cache *cache, const VkGraphicsPipelineCreateInfo *pCreateInfo, const struct anv_graphics_pipeline_create_info *extra, const VkAllocationCallbacks *alloc, VkPipeline *pPipeline); VkResult gen9_graphics_pipeline_create(VkDevice _device, struct anv_pipeline_cache *cache, const VkGraphicsPipelineCreateInfo *pCreateInfo, const struct anv_graphics_pipeline_create_info *extra, const VkAllocationCallbacks *alloc, VkPipeline *pPipeline); VkResult gen7_compute_pipeline_create(VkDevice _device, struct anv_pipeline_cache *cache, const VkComputePipelineCreateInfo *pCreateInfo, const VkAllocationCallbacks *alloc, VkPipeline *pPipeline); VkResult gen75_compute_pipeline_create(VkDevice _device, struct anv_pipeline_cache *cache, const VkComputePipelineCreateInfo *pCreateInfo, const VkAllocationCallbacks *alloc, VkPipeline *pPipeline); VkResult gen8_compute_pipeline_create(VkDevice _device, struct anv_pipeline_cache *cache, const VkComputePipelineCreateInfo *pCreateInfo, const VkAllocationCallbacks *alloc, VkPipeline *pPipeline); VkResult gen9_compute_pipeline_create(VkDevice _device, struct anv_pipeline_cache *cache, const VkComputePipelineCreateInfo *pCreateInfo, const VkAllocationCallbacks *alloc, VkPipeline *pPipeline); struct anv_format_swizzle { unsigned r:2; unsigned g:2; unsigned b:2; unsigned a:2; }; struct anv_format { const VkFormat vk_format; const char *name; enum isl_format isl_format; /**< RENDER_SURFACE_STATE.SurfaceFormat */ const struct isl_format_layout *isl_layout; struct anv_format_swizzle swizzle; bool has_depth; bool has_stencil; }; const struct anv_format * anv_format_for_vk_format(VkFormat format); enum isl_format anv_get_isl_format(VkFormat format, VkImageAspectFlags aspect, VkImageTiling tiling, struct anv_format_swizzle *swizzle); static inline bool anv_format_is_color(const struct anv_format *format) { return !format->has_depth && !format->has_stencil; } static inline bool anv_format_is_depth_or_stencil(const struct anv_format *format) { return format->has_depth || format->has_stencil; } /** * Subsurface of an anv_image. */ struct anv_surface { struct isl_surf isl; /** * Offset from VkImage's base address, as bound by vkBindImageMemory(). */ uint32_t offset; }; struct anv_image { VkImageType type; /* The original VkFormat provided by the client. This may not match any * of the actual surface formats. */ VkFormat vk_format; const struct anv_format *format; VkExtent3D extent; uint32_t levels; uint32_t array_size; uint32_t samples; /**< VkImageCreateInfo::samples */ VkImageUsageFlags usage; /**< Superset of VkImageCreateInfo::usage. */ VkImageTiling tiling; /** VkImageCreateInfo::tiling */ VkDeviceSize size; uint32_t alignment; /* Set when bound */ struct anv_bo *bo; VkDeviceSize offset; /** * Image subsurfaces * * For each foo, anv_image::foo_surface is valid if and only if * anv_image::format has a foo aspect. * * The hardware requires that the depth buffer and stencil buffer be * separate surfaces. From Vulkan's perspective, though, depth and stencil * reside in the same VkImage. To satisfy both the hardware and Vulkan, we * allocate the depth and stencil buffers as separate surfaces in the same * bo. */ union { struct anv_surface color_surface; struct { struct anv_surface depth_surface; struct anv_surface stencil_surface; }; }; }; struct anv_image_view { const struct anv_image *image; /**< VkImageViewCreateInfo::image */ struct anv_bo *bo; uint32_t offset; /**< Offset into bo. */ VkImageAspectFlags aspect_mask; VkFormat vk_format; VkComponentMapping swizzle; enum isl_format format; uint32_t base_layer; uint32_t base_mip; VkExtent3D level_0_extent; /**< Extent of ::image's level 0 adjusted for ::vk_format. */ VkExtent3D extent; /**< Extent of VkImageViewCreateInfo::baseMipLevel. */ /** RENDER_SURFACE_STATE when using image as a color render target. */ struct anv_state color_rt_surface_state; /** RENDER_SURFACE_STATE when using image as a sampler surface. */ struct anv_state sampler_surface_state; /** RENDER_SURFACE_STATE when using image as a storage image. */ struct anv_state storage_surface_state; }; struct anv_image_create_info { const VkImageCreateInfo *vk_info; isl_tiling_flags_t isl_tiling_flags; uint32_t stride; }; VkResult anv_image_create(VkDevice _device, const struct anv_image_create_info *info, const VkAllocationCallbacks* alloc, VkImage *pImage); struct anv_surface * anv_image_get_surface_for_aspect_mask(struct anv_image *image, VkImageAspectFlags aspect_mask); void anv_image_view_init(struct anv_image_view *view, struct anv_device *device, const VkImageViewCreateInfo* pCreateInfo, struct anv_cmd_buffer *cmd_buffer, uint32_t offset); void anv_fill_image_surface_state(struct anv_device *device, struct anv_state state, struct anv_image_view *iview, const VkImageViewCreateInfo *pCreateInfo, VkImageUsageFlagBits usage); void gen7_fill_image_surface_state(struct anv_device *device, void *state_map, struct anv_image_view *iview, const VkImageViewCreateInfo *pCreateInfo, VkImageUsageFlagBits usage); void gen75_fill_image_surface_state(struct anv_device *device, void *state_map, struct anv_image_view *iview, const VkImageViewCreateInfo *pCreateInfo, VkImageUsageFlagBits usage); void gen8_fill_image_surface_state(struct anv_device *device, void *state_map, struct anv_image_view *iview, const VkImageViewCreateInfo *pCreateInfo, VkImageUsageFlagBits usage); void gen9_fill_image_surface_state(struct anv_device *device, void *state_map, struct anv_image_view *iview, const VkImageViewCreateInfo *pCreateInfo, VkImageUsageFlagBits usage); struct anv_buffer_view { enum isl_format format; /**< VkBufferViewCreateInfo::format */ struct anv_bo *bo; uint32_t offset; /**< Offset into bo. */ uint64_t range; /**< VkBufferViewCreateInfo::range */ struct anv_state surface_state; struct anv_state storage_surface_state; }; const struct anv_format * anv_format_for_descriptor_type(VkDescriptorType type); void anv_fill_buffer_surface_state(struct anv_device *device, struct anv_state state, enum isl_format format, uint32_t offset, uint32_t range, uint32_t stride); void gen7_fill_buffer_surface_state(void *state, enum isl_format format, uint32_t offset, uint32_t range, uint32_t stride); void gen75_fill_buffer_surface_state(void *state, enum isl_format format, uint32_t offset, uint32_t range, uint32_t stride); void gen8_fill_buffer_surface_state(void *state, enum isl_format format, uint32_t offset, uint32_t range, uint32_t stride); void gen9_fill_buffer_surface_state(void *state, enum isl_format format, uint32_t offset, uint32_t range, uint32_t stride); void anv_image_view_fill_image_param(struct anv_device *device, struct anv_image_view *view, struct brw_image_param *param); void anv_buffer_view_fill_image_param(struct anv_device *device, struct anv_buffer_view *view, struct brw_image_param *param); struct anv_sampler { uint32_t state[4]; }; struct anv_framebuffer { uint32_t width; uint32_t height; uint32_t layers; uint32_t attachment_count; struct anv_image_view * attachments[0]; }; struct anv_subpass { uint32_t input_count; uint32_t * input_attachments; uint32_t color_count; uint32_t * color_attachments; uint32_t * resolve_attachments; uint32_t depth_stencil_attachment; /** Subpass has at least one resolve attachment */ bool has_resolve; }; struct anv_render_pass_attachment { const struct anv_format *format; uint32_t samples; VkAttachmentLoadOp load_op; VkAttachmentLoadOp stencil_load_op; }; struct anv_render_pass { uint32_t attachment_count; uint32_t subpass_count; uint32_t * subpass_attachments; struct anv_render_pass_attachment * attachments; struct anv_subpass subpasses[0]; }; extern struct anv_render_pass anv_meta_dummy_renderpass; struct anv_query_pool_slot { uint64_t begin; uint64_t end; uint64_t available; }; struct anv_query_pool { VkQueryType type; uint32_t slots; struct anv_bo bo; }; VkResult anv_device_init_meta(struct anv_device *device); void anv_device_finish_meta(struct anv_device *device); void *anv_lookup_entrypoint(const char *name); void anv_dump_image_to_ppm(struct anv_device *device, struct anv_image *image, unsigned miplevel, unsigned array_layer, const char *filename); #define ANV_DEFINE_HANDLE_CASTS(__anv_type, __VkType) \ \ static inline struct __anv_type * \ __anv_type ## _from_handle(__VkType _handle) \ { \ return (struct __anv_type *) _handle; \ } \ \ static inline __VkType \ __anv_type ## _to_handle(struct __anv_type *_obj) \ { \ return (__VkType) _obj; \ } #define ANV_DEFINE_NONDISP_HANDLE_CASTS(__anv_type, __VkType) \ \ static inline struct __anv_type * \ __anv_type ## _from_handle(__VkType _handle) \ { \ return (struct __anv_type *)(uintptr_t) _handle; \ } \ \ static inline __VkType \ __anv_type ## _to_handle(struct __anv_type *_obj) \ { \ return (__VkType)(uintptr_t) _obj; \ } #define ANV_FROM_HANDLE(__anv_type, __name, __handle) \ struct __anv_type *__name = __anv_type ## _from_handle(__handle) ANV_DEFINE_HANDLE_CASTS(anv_cmd_buffer, VkCommandBuffer) ANV_DEFINE_HANDLE_CASTS(anv_device, VkDevice) ANV_DEFINE_HANDLE_CASTS(anv_instance, VkInstance) ANV_DEFINE_HANDLE_CASTS(anv_physical_device, VkPhysicalDevice) ANV_DEFINE_HANDLE_CASTS(anv_queue, VkQueue) ANV_DEFINE_NONDISP_HANDLE_CASTS(anv_cmd_pool, VkCommandPool) ANV_DEFINE_NONDISP_HANDLE_CASTS(anv_buffer, VkBuffer) ANV_DEFINE_NONDISP_HANDLE_CASTS(anv_buffer_view, VkBufferView) ANV_DEFINE_NONDISP_HANDLE_CASTS(anv_descriptor_set, VkDescriptorSet) ANV_DEFINE_NONDISP_HANDLE_CASTS(anv_descriptor_set_layout, VkDescriptorSetLayout) ANV_DEFINE_NONDISP_HANDLE_CASTS(anv_device_memory, VkDeviceMemory) ANV_DEFINE_NONDISP_HANDLE_CASTS(anv_fence, VkFence) ANV_DEFINE_NONDISP_HANDLE_CASTS(anv_event, VkEvent) ANV_DEFINE_NONDISP_HANDLE_CASTS(anv_framebuffer, VkFramebuffer) ANV_DEFINE_NONDISP_HANDLE_CASTS(anv_image, VkImage) ANV_DEFINE_NONDISP_HANDLE_CASTS(anv_image_view, VkImageView); ANV_DEFINE_NONDISP_HANDLE_CASTS(anv_pipeline_cache, VkPipelineCache) ANV_DEFINE_NONDISP_HANDLE_CASTS(anv_pipeline, VkPipeline) ANV_DEFINE_NONDISP_HANDLE_CASTS(anv_pipeline_layout, VkPipelineLayout) ANV_DEFINE_NONDISP_HANDLE_CASTS(anv_query_pool, VkQueryPool) ANV_DEFINE_NONDISP_HANDLE_CASTS(anv_render_pass, VkRenderPass) ANV_DEFINE_NONDISP_HANDLE_CASTS(anv_sampler, VkSampler) ANV_DEFINE_NONDISP_HANDLE_CASTS(anv_shader_module, VkShaderModule) #define ANV_DEFINE_STRUCT_CASTS(__anv_type, __VkType) \ \ static inline const __VkType * \ __anv_type ## _to_ ## __VkType(const struct __anv_type *__anv_obj) \ { \ return (const __VkType *) __anv_obj; \ } #define ANV_COMMON_TO_STRUCT(__VkType, __vk_name, __common_name) \ const __VkType *__vk_name = anv_common_to_ ## __VkType(__common_name) ANV_DEFINE_STRUCT_CASTS(anv_common, VkMemoryBarrier) ANV_DEFINE_STRUCT_CASTS(anv_common, VkBufferMemoryBarrier) ANV_DEFINE_STRUCT_CASTS(anv_common, VkImageMemoryBarrier) #ifdef __cplusplus } #endif