#ifndef __NVC0_SCREEN_H__ #define __NVC0_SCREEN_H__ #include "nouveau/nouveau_screen.h" #include "nouveau/nouveau_mm.h" #include "nouveau/nouveau_fence.h" #include "nouveau/nouveau_heap.h" #include "nouveau/nv_object.xml.h" #include "nvc0_winsys.h" #include "nvc0_stateobj.h" #define NVC0_TIC_MAX_ENTRIES 2048 #define NVC0_TSC_MAX_ENTRIES 2048 /* doesn't count reserved slots (for auxiliary constants, immediates, etc.) */ #define NVC0_MAX_PIPE_CONSTBUFS 14 struct nvc0_context; struct nvc0_blitter; struct nvc0_screen { struct nouveau_screen base; struct nvc0_context *cur_ctx; int num_occlusion_queries_active; struct nouveau_bo *text; struct nouveau_bo *uniform_bo; struct nouveau_bo *tls; struct nouveau_bo *txc; /* TIC (offset 0) and TSC (65536) */ struct nouveau_bo *poly_cache; uint64_t tls_size; struct nouveau_heap *text_heap; struct nouveau_heap *lib_code; /* allocated from text_heap */ struct nvc0_blitter *blitter; struct { void **entries; int next; uint32_t lock[NVC0_TIC_MAX_ENTRIES / 32]; } tic; struct { void **entries; int next; uint32_t lock[NVC0_TSC_MAX_ENTRIES / 32]; } tsc; struct { struct nouveau_bo *bo; uint32_t *map; } fence; struct nouveau_mman *mm_VRAM_fe0; struct nouveau_object *eng3d; /* sqrt(1/2)|kepler> + sqrt(1/2)|fermi> */ struct nouveau_object *eng2d; struct nouveau_object *m2mf; struct nouveau_object *dijkstra; }; static INLINE struct nvc0_screen * nvc0_screen(struct pipe_screen *screen) { return (struct nvc0_screen *)screen; } boolean nvc0_blitter_create(struct nvc0_screen *); void nvc0_blitter_destroy(struct nvc0_screen *); void nvc0_screen_make_buffers_resident(struct nvc0_screen *); int nvc0_screen_tic_alloc(struct nvc0_screen *, void *); int nvc0_screen_tsc_alloc(struct nvc0_screen *, void *); static INLINE void nvc0_resource_fence(struct nv04_resource *res, uint32_t flags) { struct nvc0_screen *screen = nvc0_screen(res->base.screen); if (res->mm) { nouveau_fence_ref(screen->base.fence.current, &res->fence); if (flags & NOUVEAU_BO_WR) nouveau_fence_ref(screen->base.fence.current, &res->fence_wr); } } static INLINE void nvc0_resource_validate(struct nv04_resource *res, uint32_t flags) { if (likely(res->bo)) { if (flags & NOUVEAU_BO_WR) res->status |= NOUVEAU_BUFFER_STATUS_GPU_WRITING; if (flags & NOUVEAU_BO_RD) res->status |= NOUVEAU_BUFFER_STATUS_GPU_READING; nvc0_resource_fence(res, flags); } } struct nvc0_format { uint32_t rt; uint32_t tic; uint32_t vtx; uint32_t usage; }; extern const struct nvc0_format nvc0_format_table[]; static INLINE void nvc0_screen_tic_unlock(struct nvc0_screen *screen, struct nv50_tic_entry *tic) { if (tic->id >= 0) screen->tic.lock[tic->id / 32] &= ~(1 << (tic->id % 32)); } static INLINE void nvc0_screen_tsc_unlock(struct nvc0_screen *screen, struct nv50_tsc_entry *tsc) { if (tsc->id >= 0) screen->tsc.lock[tsc->id / 32] &= ~(1 << (tsc->id % 32)); } static INLINE void nvc0_screen_tic_free(struct nvc0_screen *screen, struct nv50_tic_entry *tic) { if (tic->id >= 0) { screen->tic.entries[tic->id] = NULL; screen->tic.lock[tic->id / 32] &= ~(1 << (tic->id % 32)); } } static INLINE void nvc0_screen_tsc_free(struct nvc0_screen *screen, struct nv50_tsc_entry *tsc) { if (tsc->id >= 0) { screen->tsc.entries[tsc->id] = NULL; screen->tsc.lock[tsc->id / 32] &= ~(1 << (tsc->id % 32)); } } #endif