/* * Copyright (c) 2011 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. * * Authors: * Chris Wilson * */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include "sna.h" #include "sna_reg.h" #include #include #include #include #include #include #include #include #include #ifdef HAVE_VALGRIND #include #include #endif #ifdef HAVE_STRUCT_SYSINFO_TOTALRAM #include #endif #include "sna_cpuid.h" static struct kgem_bo * search_linear_cache(struct kgem *kgem, unsigned int num_pages, unsigned flags); static struct kgem_bo * search_snoop_cache(struct kgem *kgem, unsigned int num_pages, unsigned flags); #define DBG_NO_HW 0 #define DBG_NO_EXEC 0 #define DBG_NO_TILING 0 #define DBG_NO_CACHE 0 #define DBG_NO_SNOOP_CACHE 0 #define DBG_NO_CACHE_LEVEL 0 #define DBG_NO_CPU 0 #define DBG_NO_CREATE2 0 #define DBG_NO_USERPTR 0 #define DBG_NO_UNSYNCHRONIZED_USERPTR 0 #define DBG_NO_COHERENT_MMAP_GTT 0 #define DBG_NO_LLC 0 #define DBG_NO_SEMAPHORES 0 #define DBG_NO_MADV 0 #define DBG_NO_UPLOAD_CACHE 0 #define DBG_NO_UPLOAD_ACTIVE 0 #define DBG_NO_MAP_UPLOAD 0 #define DBG_NO_RELAXED_FENCING 0 #define DBG_NO_SECURE_BATCHES 0 #define DBG_NO_PINNED_BATCHES 0 #define DBG_NO_SHRINK_BATCHES 0 #define DBG_NO_FAST_RELOC 0 #define DBG_NO_HANDLE_LUT 0 #define DBG_NO_WT 0 #define DBG_NO_WC_MMAP 0 #define DBG_NO_BLT_Y 0 #define DBG_NO_SCANOUT_Y 0 #define DBG_NO_DIRTYFB 0 #define DBG_NO_DETILING 0 #define DBG_DUMP 0 #define DBG_NO_MALLOC_CACHE 0 #define FORCE_MMAP_SYNC 0 /* ((1 << DOMAIN_CPU) | (1 << DOMAIN_GTT)) */ #ifndef DEBUG_SYNC #define DEBUG_SYNC 0 #endif #define SHOW_BATCH_BEFORE 0 #define SHOW_BATCH_AFTER 0 #if 0 #define ASSERT_IDLE(kgem__, handle__) assert(!__kgem_busy(kgem__, handle__)) #define ASSERT_MAYBE_IDLE(kgem__, handle__, expect__) assert(!(expect__) || !__kgem_busy(kgem__, handle__)) #else #define ASSERT_IDLE(kgem__, handle__) #define ASSERT_MAYBE_IDLE(kgem__, handle__, expect__) #endif /* Worst case seems to be 965gm where we cannot write within a cacheline that * is being simultaneously being read by the GPU, or within the sampler * prefetch. In general, the chipsets seem to have a requirement that sampler * offsets be aligned to a cacheline (64 bytes). * * Actually, it turns out the BLT color pattern (BR15) has the most severe * alignment restrictions, 64 bytes for 8-bpp, 128 bytes for 16-bpp and 256 * bytes for 32-bpp. */ #define UPLOAD_ALIGNMENT 256 #define PAGE_ALIGN(x) ALIGN(x, PAGE_SIZE) #define NUM_PAGES(x) (((x) + PAGE_SIZE-1) / PAGE_SIZE) #define MAX_GTT_VMA_CACHE 512 #define MAX_CPU_VMA_CACHE INT16_MAX #define MAP_PRESERVE_TIME 10 #define MAKE_USER_MAP(ptr) ((void*)((uintptr_t)(ptr) | 1)) #define IS_USER_MAP(ptr) ((uintptr_t)(ptr) & 1) #define LOCAL_I915_PARAM_HAS_BLT 11 #define LOCAL_I915_PARAM_HAS_RELAXED_FENCING 12 #define LOCAL_I915_PARAM_HAS_RELAXED_DELTA 15 #define LOCAL_I915_PARAM_HAS_LLC 17 #define LOCAL_I915_PARAM_HAS_SEMAPHORES 20 #define LOCAL_I915_PARAM_HAS_SECURE_BATCHES 23 #define LOCAL_I915_PARAM_HAS_PINNED_BATCHES 24 #define LOCAL_I915_PARAM_HAS_NO_RELOC 25 #define LOCAL_I915_PARAM_HAS_HANDLE_LUT 26 #define LOCAL_I915_PARAM_HAS_WT 27 #define LOCAL_I915_PARAM_MMAP_VERSION 30 #define LOCAL_I915_PARAM_MMAP_GTT_COHERENT 52 #define LOCAL_I915_EXEC_IS_PINNED (1<<10) #define LOCAL_I915_EXEC_NO_RELOC (1<<11) #define LOCAL_I915_EXEC_HANDLE_LUT (1<<12) #define LOCAL_I915_GEM_CREATE2 0x34 #define LOCAL_IOCTL_I915_GEM_CREATE2 DRM_IOWR (DRM_COMMAND_BASE + LOCAL_I915_GEM_CREATE2, struct local_i915_gem_create2) struct local_i915_gem_create2 { uint64_t size; uint32_t placement; #define LOCAL_I915_CREATE_PLACEMENT_SYSTEM 0 #define LOCAL_I915_CREATE_PLACEMENT_STOLEN 1 /* Cannot use CPU mmaps or pread/pwrite */ uint32_t domain; uint32_t caching; uint32_t tiling_mode; uint32_t stride; uint32_t flags; uint32_t pad; uint32_t handle; }; #define LOCAL_I915_GEM_USERPTR 0x33 #define LOCAL_IOCTL_I915_GEM_USERPTR DRM_IOWR (DRM_COMMAND_BASE + LOCAL_I915_GEM_USERPTR, struct local_i915_gem_userptr) struct local_i915_gem_userptr { uint64_t user_ptr; uint64_t user_size; uint32_t flags; #define I915_USERPTR_READ_ONLY 0x1 #define I915_USERPTR_UNSYNCHRONIZED 0x80000000 uint32_t handle; }; #define UNCACHED 0 #define SNOOPED 1 #define DISPLAY 2 struct local_i915_gem_caching { uint32_t handle; uint32_t caching; }; #define LOCAL_I915_GEM_SET_CACHING 0x2f #define LOCAL_I915_GEM_GET_CACHING 0x30 #define LOCAL_IOCTL_I915_GEM_SET_CACHING DRM_IOW(DRM_COMMAND_BASE + LOCAL_I915_GEM_SET_CACHING, struct local_i915_gem_caching) #define LOCAL_IOCTL_I915_GEM_GET_CACHING DRM_IOW(DRM_COMMAND_BASE + LOCAL_I915_GEM_GET_CACHING, struct local_i915_gem_caching) struct local_i915_gem_mmap { uint32_t handle; uint32_t pad; uint64_t offset; uint64_t size; uint64_t addr_ptr; }; #define LOCAL_IOCTL_I915_GEM_MMAP DRM_IOWR(DRM_COMMAND_BASE + DRM_I915_GEM_MMAP, struct local_i915_gem_mmap) struct local_i915_gem_mmap2 { uint32_t handle; uint32_t pad; uint64_t offset; uint64_t size; uint64_t addr_ptr; uint64_t flags; #define I915_MMAP_WC 0x1 }; #define LOCAL_IOCTL_I915_GEM_MMAP_v2 DRM_IOWR(DRM_COMMAND_BASE + DRM_I915_GEM_MMAP, struct local_i915_gem_mmap2) struct kgem_buffer { struct kgem_bo base; void *mem; uint32_t used; uint32_t need_io : 1; uint32_t write : 2; uint32_t mmapped : 2; }; enum { MMAPPED_NONE, MMAPPED_GTT, MMAPPED_CPU }; static struct kgem_bo *__kgem_freed_bo; static struct kgem_request *__kgem_freed_request; static struct drm_i915_gem_exec_object2 _kgem_dummy_exec; static inline struct sna *__to_sna(struct kgem *kgem) { /* minor layering violations */ return container_of(kgem, struct sna, kgem); } static inline int bytes(struct kgem_bo *bo) { return __kgem_bo_size(bo); } #define bucket(B) (B)->size.pages.bucket #define num_pages(B) (B)->size.pages.count static int __do_ioctl(int fd, unsigned long req, void *arg) { do { int err; switch ((err = errno)) { case EAGAIN: sched_yield(); case EINTR: break; default: return -err; } if (likely(ioctl(fd, req, arg) == 0)) return 0; } while (1); } inline static int do_ioctl(int fd, unsigned long req, void *arg) { if (likely(ioctl(fd, req, arg) == 0)) return 0; return __do_ioctl(fd, req, arg); } #ifdef DEBUG_MEMORY static void debug_alloc(struct kgem *kgem, size_t size) { kgem->debug_memory.bo_allocs++; kgem->debug_memory.bo_bytes += size; } static void debug_alloc__bo(struct kgem *kgem, struct kgem_bo *bo) { debug_alloc(kgem, bytes(bo)); } #else #define debug_alloc__bo(k, b) #endif #ifndef NDEBUG static void assert_tiling(struct kgem *kgem, struct kgem_bo *bo) { struct drm_i915_gem_get_tiling tiling; assert(bo); if (!kgem->can_fence && kgem->gen >= 040 && bo->tiling) return; /* lies */ VG_CLEAR(tiling); tiling.handle = bo->handle; tiling.tiling_mode = bo->tiling; (void)do_ioctl(kgem->fd, DRM_IOCTL_I915_GEM_GET_TILING, &tiling); assert(tiling.tiling_mode == bo->tiling); } static void assert_caching(struct kgem *kgem, struct kgem_bo *bo) { struct local_i915_gem_caching arg; int expect = kgem->has_llc ? SNOOPED : UNCACHED; VG_CLEAR(arg); arg.handle = bo->handle; arg.caching = expect; (void)do_ioctl(kgem->fd, LOCAL_IOCTL_I915_GEM_GET_CACHING, &arg); assert(arg.caching == expect); } static void assert_bo_retired(struct kgem_bo *bo) { DBG(("%s: handle=%d, domain: %d exec? %d, rq? %d\n", __FUNCTION__, bo->handle, bo->domain, bo->exec != NULL, bo->rq != NULL)); assert(bo->refcnt); assert(bo->rq == NULL); assert(bo->exec == NULL); assert(!bo->needs_flush); assert(list_is_empty(&bo->request)); } #else #define assert_tiling(kgem, bo) #define assert_caching(kgem, bo) #define assert_bo_retired(bo) #endif static int __find_debugfs(struct kgem *kgem) { int i; for (i = 0; i < DRM_MAX_MINOR; i++) { char path[80]; sprintf(path, "/sys/kernel/debug/dri/%d/i915_wedged", i); if (access(path, R_OK) == 0) return i; sprintf(path, "/debug/dri/%d/i915_wedged", i); if (access(path, R_OK) == 0) return i; } return -1; } static int kgem_get_minor(struct kgem *kgem) { struct stat st; if (fstat(kgem->fd, &st)) return __find_debugfs(kgem); if (!S_ISCHR(st.st_mode)) return __find_debugfs(kgem); return st.st_rdev & 0x63; } static bool find_hang_state(struct kgem *kgem, char *path, int maxlen) { int minor = kgem_get_minor(kgem); /* Search for our hang state in a few canonical locations. * In the unlikely event of having multiple devices, we * will need to check which minor actually corresponds to ours. */ snprintf(path, maxlen, "/sys/class/drm/card%d/error", minor); if (access(path, R_OK) == 0) return true; snprintf(path, maxlen, "/sys/kernel/debug/dri/%d/i915_error_state", minor); if (access(path, R_OK) == 0) return true; snprintf(path, maxlen, "/debug/dri/%d/i915_error_state", minor); if (access(path, R_OK) == 0) return true; path[0] = '\0'; return false; } static bool has_error_state(struct kgem *kgem, char *path) { bool ret = false; char no; int fd; fd = open(path, O_RDONLY); if (fd >= 0) { ret = read(fd, &no, 1) == 1 && no != 'N'; close(fd); } return ret; } static int kgem_get_screen_index(struct kgem *kgem) { return __to_sna(kgem)->scrn->scrnIndex; } static void __kgem_set_wedged(struct kgem *kgem) { static int once; char path[256]; if (kgem->wedged) return; if (!once && find_hang_state(kgem, path, sizeof(path)) && has_error_state(kgem, path)) { xf86DrvMsg(kgem_get_screen_index(kgem), X_ERROR, "When reporting this, please include %s and the full dmesg.\n", path); once = 1; } kgem->wedged = true; sna_render_mark_wedged(__to_sna(kgem)); } static void kgem_sna_reset(struct kgem *kgem) { struct sna *sna = __to_sna(kgem); sna->render.reset(sna); sna->blt_state.fill_bo = 0; } static void kgem_sna_flush(struct kgem *kgem) { struct sna *sna = __to_sna(kgem); sna->render.flush(sna); if (sna->render.solid_cache.dirty) sna_render_flush_solid(sna); } static bool kgem_bo_rmfb(struct kgem *kgem, struct kgem_bo *bo) { if (bo->scanout && bo->delta) { DBG(("%s: releasing fb=%d for handle=%d\n", __FUNCTION__, bo->delta, bo->handle)); /* XXX will leak if we are not DRM_MASTER. *shrug* */ do_ioctl(kgem->fd, DRM_IOCTL_MODE_RMFB, &bo->delta); bo->delta = 0; return true; } else return false; } static bool kgem_set_tiling(struct kgem *kgem, struct kgem_bo *bo, int tiling, int stride) { struct drm_i915_gem_set_tiling set_tiling; int err; if (tiling == bo->tiling) { if (tiling == I915_TILING_NONE) { bo->pitch = stride; return true; } if (stride == bo->pitch) return true; } if (DBG_NO_TILING) return false; VG_CLEAR(set_tiling); restart: set_tiling.handle = bo->handle; set_tiling.tiling_mode = tiling; set_tiling.stride = tiling ? stride : 0; if (ioctl(kgem->fd, DRM_IOCTL_I915_GEM_SET_TILING, &set_tiling) == 0) { bo->tiling = set_tiling.tiling_mode; bo->pitch = set_tiling.tiling_mode ? set_tiling.stride : stride; DBG(("%s: handle=%d, tiling=%d [%d], pitch=%d [%d]: %d\n", __FUNCTION__, bo->handle, bo->tiling, tiling, bo->pitch, stride, set_tiling.tiling_mode == tiling)); return set_tiling.tiling_mode == tiling && bo->pitch >= stride; } err = errno; if (err == EINTR) goto restart; if (err == EAGAIN) { sched_yield(); goto restart; } if (err == EBUSY && kgem_bo_rmfb(kgem, bo)) goto restart; ERR(("%s: failed to set-tiling(tiling=%d, pitch=%d) for handle=%d: %d\n", __FUNCTION__, tiling, stride, bo->handle, err)); return false; } static bool gem_set_caching(int fd, uint32_t handle, int caching) { struct local_i915_gem_caching arg; VG_CLEAR(arg); arg.handle = handle; arg.caching = caching; return do_ioctl(fd, LOCAL_IOCTL_I915_GEM_SET_CACHING, &arg) == 0; } static uint32_t gem_userptr(int fd, void *ptr, size_t size, int read_only) { struct local_i915_gem_userptr arg; VG_CLEAR(arg); arg.user_ptr = (uintptr_t)ptr; arg.user_size = size; arg.flags = I915_USERPTR_UNSYNCHRONIZED; if (read_only) arg.flags |= I915_USERPTR_READ_ONLY; if (DBG_NO_UNSYNCHRONIZED_USERPTR || do_ioctl(fd, LOCAL_IOCTL_I915_GEM_USERPTR, &arg)) { arg.flags &= ~I915_USERPTR_UNSYNCHRONIZED; if (do_ioctl(fd, LOCAL_IOCTL_I915_GEM_USERPTR, &arg)) { DBG(("%s: failed to map %p + %d bytes: %d\n", __FUNCTION__, ptr, size, errno)); return 0; } } return arg.handle; } static bool __kgem_throttle(struct kgem *kgem, bool harder) { /* Let this be woken up by sigtimer so that we don't block here * too much and completely starve X. We will sleep again shortly, * and so catch up or detect the hang. */ do { if (ioctl(kgem->fd, DRM_IOCTL_I915_GEM_THROTTLE) == 0) { kgem->need_throttle = 0; return false; } if (errno == EIO) return true; } while (harder); return false; } static bool __kgem_throttle_retire(struct kgem *kgem, unsigned flags) { if (flags & CREATE_NO_RETIRE || !kgem->need_retire) { DBG(("%s: not retiring\n", __FUNCTION__)); return false; } if (kgem_retire(kgem)) return true; if (flags & CREATE_NO_THROTTLE || !kgem->need_throttle) { DBG(("%s: not throttling\n", __FUNCTION__)); return false; } __kgem_throttle(kgem, false); return kgem_retire(kgem); } static void *__kgem_bo_map__gtt(struct kgem *kgem, struct kgem_bo *bo) { struct drm_i915_gem_mmap_gtt gtt; void *ptr; int err; DBG(("%s(handle=%d, size=%d)\n", __FUNCTION__, bo->handle, bytes(bo))); if (bo->tiling && !kgem->can_fence) return NULL; VG_CLEAR(gtt); retry_gtt: gtt.handle = bo->handle; if ((err = do_ioctl(kgem->fd, DRM_IOCTL_I915_GEM_MMAP_GTT, >t))) { DBG(("%s: failed %d, throttling/cleaning caches\n", __FUNCTION__, err)); assert(err != EINVAL); (void)__kgem_throttle_retire(kgem, 0); if (kgem_expire_cache(kgem)) goto retry_gtt; if (kgem_cleanup_cache(kgem)) goto retry_gtt; ERR(("%s: failed to retrieve GTT offset for handle=%d: %d\n", __FUNCTION__, bo->handle, -err)); return NULL; } retry_mmap: ptr = mmap(0, bytes(bo), PROT_READ | PROT_WRITE, MAP_SHARED, kgem->fd, gtt.offset); if (ptr == MAP_FAILED) { err = errno; DBG(("%s: failed %d, throttling/cleaning caches\n", __FUNCTION__, err)); assert(err != EINVAL); if (__kgem_throttle_retire(kgem, 0)) goto retry_mmap; if (kgem_cleanup_cache(kgem)) goto retry_mmap; ERR(("%s: failed to mmap handle=%d, %d bytes, into GTT domain: %d\n", __FUNCTION__, bo->handle, bytes(bo), err)); ptr = NULL; } /* Cache this mapping to avoid the overhead of an * excruciatingly slow GTT pagefault. This is more an * issue with compositing managers which need to * frequently flush CPU damage to their GPU bo. */ return bo->map__gtt = ptr; } static void *__kgem_bo_map__wc(struct kgem *kgem, struct kgem_bo *bo) { struct local_i915_gem_mmap2 wc; int err; DBG(("%s(handle=%d, size=%d)\n", __FUNCTION__, bo->handle, bytes(bo))); assert(kgem->has_wc_mmap); VG_CLEAR(wc); retry_wc: wc.handle = bo->handle; wc.offset = 0; wc.size = bytes(bo); wc.flags = I915_MMAP_WC; if ((err = do_ioctl(kgem->fd, LOCAL_IOCTL_I915_GEM_MMAP_v2, &wc))) { DBG(("%s: failed %d, throttling/cleaning caches\n", __FUNCTION__, err)); assert(err != EINVAL); if (__kgem_throttle_retire(kgem, 0)) goto retry_wc; if (kgem_cleanup_cache(kgem)) goto retry_wc; ERR(("%s: failed to mmap handle=%d, %d bytes, into CPU(wc) domain: %d\n", __FUNCTION__, bo->handle, bytes(bo), -err)); return NULL; } VG(VALGRIND_MAKE_MEM_DEFINED(wc.addr_ptr, bytes(bo))); DBG(("%s: caching CPU(wc) vma for %d\n", __FUNCTION__, bo->handle)); return bo->map__wc = (void *)(uintptr_t)wc.addr_ptr; } static void *__kgem_bo_map__cpu(struct kgem *kgem, struct kgem_bo *bo) { struct local_i915_gem_mmap arg; int err; VG_CLEAR(arg); arg.offset = 0; retry: arg.handle = bo->handle; arg.size = bytes(bo); if ((err = do_ioctl(kgem->fd, LOCAL_IOCTL_I915_GEM_MMAP, &arg))) { DBG(("%s: failed %d, throttling/cleaning caches\n", __FUNCTION__, err)); assert(err != -EINVAL || bo->prime); if (__kgem_throttle_retire(kgem, 0)) goto retry; if (kgem_cleanup_cache(kgem)) goto retry; ERR(("%s: failed to mmap handle=%d (prime? %d), %d bytes, into CPU domain: %d\n", __FUNCTION__, bo->handle, bo->prime, bytes(bo), -err)); bo->purged = 1; return NULL; } VG(VALGRIND_MAKE_MEM_DEFINED(arg.addr_ptr, bytes(bo))); DBG(("%s: caching CPU vma for %d\n", __FUNCTION__, bo->handle)); return bo->map__cpu = (void *)(uintptr_t)arg.addr_ptr; } static int gem_write(int fd, uint32_t handle, int offset, int length, const void *src) { struct drm_i915_gem_pwrite pwrite; DBG(("%s(handle=%d, offset=%d, len=%d)\n", __FUNCTION__, handle, offset, length)); VG_CLEAR(pwrite); pwrite.handle = handle; pwrite.offset = offset; pwrite.size = length; pwrite.data_ptr = (uintptr_t)src; return do_ioctl(fd, DRM_IOCTL_I915_GEM_PWRITE, &pwrite); } static int gem_write__cachealigned(int fd, uint32_t handle, int offset, int length, const void *src) { struct drm_i915_gem_pwrite pwrite; DBG(("%s(handle=%d, offset=%d, len=%d)\n", __FUNCTION__, handle, offset, length)); VG_CLEAR(pwrite); pwrite.handle = handle; /* align the transfer to cachelines; fortuitously this is safe! */ if ((offset | length) & 63) { pwrite.offset = offset & ~63; pwrite.size = ALIGN(offset+length, 64) - pwrite.offset; pwrite.data_ptr = (uintptr_t)src + pwrite.offset - offset; } else { pwrite.offset = offset; pwrite.size = length; pwrite.data_ptr = (uintptr_t)src; } return do_ioctl(fd, DRM_IOCTL_I915_GEM_PWRITE, &pwrite); } static int gem_read(int fd, uint32_t handle, const void *dst, int offset, int length) { struct drm_i915_gem_pread pread; int ret; DBG(("%s(handle=%d, len=%d)\n", __FUNCTION__, handle, length)); VG_CLEAR(pread); pread.handle = handle; pread.offset = offset; pread.size = length; pread.data_ptr = (uintptr_t)dst; ret = do_ioctl(fd, DRM_IOCTL_I915_GEM_PREAD, &pread); if (ret) { DBG(("%s: failed, errno=%d\n", __FUNCTION__, -ret)); return ret; } VG(VALGRIND_MAKE_MEM_DEFINED(dst, length)); return 0; } bool __kgem_busy(struct kgem *kgem, int handle) { struct drm_i915_gem_busy busy; VG_CLEAR(busy); busy.handle = handle; busy.busy = !kgem->wedged; (void)do_ioctl(kgem->fd, DRM_IOCTL_I915_GEM_BUSY, &busy); DBG(("%s: handle=%d, busy=%d, wedged=%d\n", __FUNCTION__, handle, busy.busy, kgem->wedged)); return busy.busy; } static void kgem_bo_retire(struct kgem *kgem, struct kgem_bo *bo) { DBG(("%s: retiring bo handle=%d (needed flush? %d), rq? %d [busy?=%d]\n", __FUNCTION__, bo->handle, bo->needs_flush, bo->rq != NULL, __kgem_busy(kgem, bo->handle))); assert(bo->exec == NULL); assert(list_is_empty(&bo->vma)); if (bo->rq) __kgem_retire_requests_upto(kgem, bo); ASSERT_IDLE(kgem, bo->handle); assert_bo_retired(bo); } static void kgem_bo_maybe_retire(struct kgem *kgem, struct kgem_bo *bo) { DBG(("%s: retiring bo handle=%d (needed flush? %d), rq? %d [busy?=%d]\n", __FUNCTION__, bo->handle, bo->needs_flush, bo->rq != NULL, __kgem_busy(kgem, bo->handle))); assert(bo->exec == NULL); assert(list_is_empty(&bo->vma)); if (bo->rq) { if (!__kgem_busy(kgem, bo->handle)) __kgem_retire_requests_upto(kgem, bo); } else { assert(!bo->needs_flush); ASSERT_IDLE(kgem, bo->handle); } } bool kgem_bo_write(struct kgem *kgem, struct kgem_bo *bo, const void *data, int length) { void *ptr; int err; assert(bo->refcnt); assert(bo->proxy == NULL); ASSERT_IDLE(kgem, bo->handle); assert(length <= bytes(bo)); retry: ptr = NULL; if (bo->domain == DOMAIN_CPU || (kgem->has_llc && !bo->scanout)) { ptr = bo->map__cpu; if (ptr == NULL) ptr = __kgem_bo_map__cpu(kgem, bo); } else if (kgem->has_wc_mmap) { ptr = bo->map__wc; if (ptr == NULL) ptr = __kgem_bo_map__wc(kgem, bo); } if (ptr) { /* XXX unsynchronized? */ memcpy(ptr, data, length); return true; } if ((err = gem_write(kgem->fd, bo->handle, 0, length, data))) { DBG(("%s: failed %d, throttling/cleaning caches\n", __FUNCTION__, err)); assert(err != EINVAL); (void)__kgem_throttle_retire(kgem, 0); if (kgem_expire_cache(kgem)) goto retry; if (kgem_cleanup_cache(kgem)) goto retry; ERR(("%s: failed to write %d bytes into BO handle=%d: %d\n", __FUNCTION__, length, bo->handle, -err)); return false; } DBG(("%s: flush=%d, domain=%d\n", __FUNCTION__, bo->flush, bo->domain)); if (bo->exec == NULL) kgem_bo_maybe_retire(kgem, bo); bo->domain = DOMAIN_NONE; bo->gtt_dirty = true; return true; } static uint32_t gem_create(int fd, int num_pages) { struct drm_i915_gem_create create; VG_CLEAR(create); create.handle = 0; create.size = PAGE_SIZE * num_pages; (void)do_ioctl(fd, DRM_IOCTL_I915_GEM_CREATE, &create); return create.handle; } static void kgem_bo_set_purgeable(struct kgem *kgem, struct kgem_bo *bo) { #if !DBG_NO_MADV struct drm_i915_gem_madvise madv; assert(bo->exec == NULL); VG_CLEAR(madv); madv.handle = bo->handle; madv.madv = I915_MADV_DONTNEED; if (do_ioctl(kgem->fd, DRM_IOCTL_I915_GEM_MADVISE, &madv) == 0) { bo->purged = true; kgem->need_purge |= !madv.retained && bo->domain != DOMAIN_CPU; } #endif } static bool kgem_bo_is_retained(struct kgem *kgem, struct kgem_bo *bo) { #if DBG_NO_MADV return true; #else struct drm_i915_gem_madvise madv; if (!bo->purged) return true; VG_CLEAR(madv); madv.handle = bo->handle; madv.madv = I915_MADV_DONTNEED; if (do_ioctl(kgem->fd, DRM_IOCTL_I915_GEM_MADVISE, &madv) == 0) return madv.retained; return false; #endif } static bool kgem_bo_clear_purgeable(struct kgem *kgem, struct kgem_bo *bo) { #if DBG_NO_MADV return true; #else struct drm_i915_gem_madvise madv; assert(bo->purged); VG_CLEAR(madv); madv.handle = bo->handle; madv.madv = I915_MADV_WILLNEED; if (do_ioctl(kgem->fd, DRM_IOCTL_I915_GEM_MADVISE, &madv) == 0) { bo->purged = !madv.retained; kgem->need_purge |= !madv.retained && bo->domain != DOMAIN_CPU; return madv.retained; } return false; #endif } static void gem_close(int fd, uint32_t handle) { struct drm_gem_close close; VG_CLEAR(close); close.handle = handle; (void)do_ioctl(fd, DRM_IOCTL_GEM_CLOSE, &close); } constant inline static unsigned long __fls(unsigned long word) { #if defined(__GNUC__) && (defined(__i386__) || defined(__x86__) || defined(__x86_64__)) asm("bsr %1,%0" : "=r" (word) : "rm" (word)); return word; #else unsigned int v = 0; while (word >>= 1) v++; return v; #endif } constant inline static int cache_bucket(int num_pages) { return __fls(num_pages); } static struct kgem_bo *__kgem_bo_init(struct kgem_bo *bo, int handle, int num_pages) { DBG(("%s(handle=%d, num_pages=%d)\n", __FUNCTION__, handle, num_pages)); assert(num_pages); memset(bo, 0, sizeof(*bo)); bo->refcnt = 1; bo->handle = handle; bo->target_handle = -1; num_pages(bo) = num_pages; bucket(bo) = cache_bucket(num_pages); bo->reusable = true; bo->domain = DOMAIN_CPU; list_init(&bo->request); list_init(&bo->list); list_init(&bo->vma); return bo; } static struct kgem_bo *__kgem_bo_alloc(int handle, int num_pages) { struct kgem_bo *bo; if (__kgem_freed_bo) { bo = __kgem_freed_bo; __kgem_freed_bo = *(struct kgem_bo **)bo; } else { bo = malloc(sizeof(*bo)); if (bo == NULL) return NULL; } return __kgem_bo_init(bo, handle, num_pages); } static struct kgem_request *__kgem_request_alloc(struct kgem *kgem) { struct kgem_request *rq; if (unlikely(kgem->wedged)) { rq = &kgem->static_request; } else { rq = __kgem_freed_request; if (rq) { __kgem_freed_request = *(struct kgem_request **)rq; } else { rq = malloc(sizeof(*rq)); if (rq == NULL) rq = &kgem->static_request; } } list_init(&rq->buffers); rq->bo = NULL; rq->ring = 0; return rq; } static void __kgem_request_free(struct kgem_request *rq) { _list_del(&rq->list); if (DBG_NO_MALLOC_CACHE) { free(rq); } else { *(struct kgem_request **)rq = __kgem_freed_request; __kgem_freed_request = rq; } } static struct list *inactive(struct kgem *kgem, int num_pages) { assert(num_pages < MAX_CACHE_SIZE / PAGE_SIZE); assert(cache_bucket(num_pages) < NUM_CACHE_BUCKETS); return &kgem->inactive[cache_bucket(num_pages)]; } static struct list *active(struct kgem *kgem, int num_pages, int tiling) { assert(num_pages < MAX_CACHE_SIZE / PAGE_SIZE); assert(cache_bucket(num_pages) < NUM_CACHE_BUCKETS); return &kgem->active[cache_bucket(num_pages)][tiling]; } static size_t agp_aperture_size(struct pci_device *dev, unsigned gen) { /* XXX assume that only future chipsets are unknown and follow * the post gen2 PCI layout. */ return dev->regions[gen < 030 ? 0 : 2].size; } static size_t total_ram_size(void) { #ifdef HAVE_STRUCT_SYSINFO_TOTALRAM struct sysinfo info; if (sysinfo(&info) == 0) return (size_t)info.totalram * info.mem_unit; #endif #ifdef _SC_PHYS_PAGES return (size_t)sysconf(_SC_PHYS_PAGES) * sysconf(_SC_PAGE_SIZE); #endif return 0; } static unsigned cpu_cache_size__cpuid4(void) { /* Deterministic Cache Parameters (Function 04h)": * When EAX is initialized to a value of 4, the CPUID instruction * returns deterministic cache information in the EAX, EBX, ECX * and EDX registers. This function requires ECX be initialized * with an index which indicates which cache to return information * about. The OS is expected to call this function (CPUID.4) with * ECX = 0, 1, 2, until EAX[4:0] == 0, indicating no more caches. * The order in which the caches are returned is not specified * and may change at Intel's discretion. * * Calculating the Cache Size in bytes: * = (Ways +1) * (Partitions +1) * (Line Size +1) * (Sets +1) */ unsigned int eax, ebx, ecx, edx; unsigned int llc_size = 0; int cnt; if (__get_cpuid_max(BASIC_CPUID, NULL) < 4) return 0; cnt = 0; do { unsigned associativity, line_partitions, line_size, sets; __cpuid_count(4, cnt++, eax, ebx, ecx, edx); if ((eax & 0x1f) == 0) break; associativity = ((ebx >> 22) & 0x3ff) + 1; line_partitions = ((ebx >> 12) & 0x3ff) + 1; line_size = (ebx & 0xfff) + 1; sets = ecx + 1; llc_size = associativity * line_partitions * line_size * sets; } while (1); return llc_size; } static unsigned cpu_cache_size(void) { unsigned size; FILE *file; size = cpu_cache_size__cpuid4(); if (size) return size; file = fopen("/proc/cpuinfo", "r"); if (file) { size_t len = 0; char *line = NULL; while (getline(&line, &len, file) != -1) { int kb; if (sscanf(line, "cache size : %d KB", &kb) == 1) { /* Paranoid check against gargantuan caches */ if (kb <= 1<<20) size = kb * 1024; break; } } free(line); fclose(file); } if (size == 0) size = 64 * 1024; return size; } static int gem_param(struct kgem *kgem, int name) { drm_i915_getparam_t gp; int v = -1; /* No param uses the sign bit, reserve it for errors */ VG_CLEAR(gp); gp.param = name; gp.value = &v; if (do_ioctl(kgem->fd, DRM_IOCTL_I915_GETPARAM, &gp)) return -1; VG(VALGRIND_MAKE_MEM_DEFINED(&v, sizeof(v))); return v; } static bool test_has_execbuffer2(struct kgem *kgem) { struct drm_i915_gem_execbuffer2 execbuf; memset(&execbuf, 0, sizeof(execbuf)); execbuf.buffer_count = 1; return do_ioctl(kgem->fd, DRM_IOCTL_I915_GEM_EXECBUFFER2, &execbuf) == -EFAULT; } static bool test_has_no_reloc(struct kgem *kgem) { if (DBG_NO_FAST_RELOC) return false; return gem_param(kgem, LOCAL_I915_PARAM_HAS_NO_RELOC) > 0; } static bool test_has_handle_lut(struct kgem *kgem) { if (DBG_NO_HANDLE_LUT) return false; return gem_param(kgem, LOCAL_I915_PARAM_HAS_HANDLE_LUT) > 0; } static bool test_has_wt(struct kgem *kgem) { if (DBG_NO_WT) return false; return gem_param(kgem, LOCAL_I915_PARAM_HAS_WT) > 0; } static bool test_has_semaphores_enabled(struct kgem *kgem) { FILE *file; bool detected = false; int ret; if (DBG_NO_SEMAPHORES) return false; ret = gem_param(kgem, LOCAL_I915_PARAM_HAS_SEMAPHORES); if (ret != -1) return ret > 0; file = fopen("/sys/module/i915/parameters/semaphores", "r"); if (file) { int value; if (fscanf(file, "%d", &value) == 1) detected = value != 0; fclose(file); } return detected; } static bool is_hw_supported(struct kgem *kgem, struct pci_device *dev) { if (DBG_NO_HW) return false; if (!test_has_execbuffer2(kgem)) return false; if (kgem->gen == (unsigned)-1) /* unknown chipset, assume future gen */ return kgem->has_blt; /* Although pre-855gm the GMCH is fubar, it works mostly. So * let the user decide through "NoAccel" whether or not to risk * hw acceleration. */ if (kgem->gen == 060 && dev && dev->revision < 8) { /* pre-production SNB with dysfunctional BLT */ return false; } if (kgem->gen >= 060) /* Only if the kernel supports the BLT ring */ return kgem->has_blt; return true; } static bool test_has_relaxed_fencing(struct kgem *kgem) { if (kgem->gen < 040) { if (DBG_NO_RELAXED_FENCING) return false; return gem_param(kgem, LOCAL_I915_PARAM_HAS_RELAXED_FENCING) > 0; } else return true; } static bool test_has_coherent_mmap_gtt(struct kgem *kgem) { if (DBG_NO_COHERENT_MMAP_GTT) return false; return gem_param(kgem, LOCAL_I915_PARAM_MMAP_GTT_COHERENT) > 0; } static bool test_has_llc(struct kgem *kgem) { int has_llc = -1; if (DBG_NO_LLC) return false; has_llc = gem_param(kgem, LOCAL_I915_PARAM_HAS_LLC); if (has_llc == -1) { DBG(("%s: no kernel/drm support for HAS_LLC, assuming support for LLC based on GPU generation\n", __FUNCTION__)); has_llc = kgem->gen >= 060; } return has_llc; } static bool test_has_wc_mmap(struct kgem *kgem) { struct local_i915_gem_mmap2 wc; bool ret; if (DBG_NO_WC_MMAP) return false; /* XXX See https://bugs.freedesktop.org/show_bug.cgi?id=90841 */ if (kgem->gen < 033) return false; if (gem_param(kgem, LOCAL_I915_PARAM_MMAP_VERSION) < 1) return false; VG_CLEAR(wc); wc.handle = gem_create(kgem->fd, 1); wc.offset = 0; wc.size = 4096; wc.flags = I915_MMAP_WC; ret = do_ioctl(kgem->fd, LOCAL_IOCTL_I915_GEM_MMAP_v2, &wc) == 0; gem_close(kgem->fd, wc.handle); return ret; } static bool test_has_caching(struct kgem *kgem) { uint32_t handle; bool ret; if (DBG_NO_CACHE_LEVEL) return false; /* Incoherent blt and sampler hangs the GPU */ if (kgem->gen == 040) return false; handle = gem_create(kgem->fd, 1); if (handle == 0) return false; ret = gem_set_caching(kgem->fd, handle, UNCACHED); gem_close(kgem->fd, handle); return ret; } static bool test_has_userptr(struct kgem *kgem) { struct local_i915_gem_userptr arg; void *ptr; if (DBG_NO_USERPTR) return false; /* Incoherent blt and sampler hangs the GPU */ if (kgem->gen == 040) return false; if (posix_memalign(&ptr, PAGE_SIZE, PAGE_SIZE)) return false; VG_CLEAR(arg); arg.user_ptr = (uintptr_t)ptr; arg.user_size = PAGE_SIZE; arg.flags = I915_USERPTR_UNSYNCHRONIZED; if (DBG_NO_UNSYNCHRONIZED_USERPTR || do_ioctl(kgem->fd, LOCAL_IOCTL_I915_GEM_USERPTR, &arg)) { arg.flags &= ~I915_USERPTR_UNSYNCHRONIZED; if (do_ioctl(kgem->fd, LOCAL_IOCTL_I915_GEM_USERPTR, &arg)) arg.handle = 0; /* Leak the userptr bo to keep the mmu_notifier alive */ } else { gem_close(kgem->fd, arg.handle); free(ptr); } return arg.handle != 0; } static bool test_has_create2(struct kgem *kgem) { #if defined(USE_CREATE2) struct local_i915_gem_create2 args; if (DBG_NO_CREATE2) return false; memset(&args, 0, sizeof(args)); args.size = PAGE_SIZE; args.caching = DISPLAY; if (do_ioctl(kgem->fd, LOCAL_IOCTL_I915_GEM_CREATE2, &args) == 0) gem_close(kgem->fd, args.handle); return args.handle != 0; #else return false; #endif } static bool test_can_blt_y(struct kgem *kgem) { struct drm_i915_gem_exec_object2 object; uint32_t batch[] = { #define MI_LOAD_REGISTER_IMM (0x22<<23 | (3-2)) #define BCS_SWCTRL 0x22200 #define BCS_SRC_Y (1 << 0) #define BCS_DST_Y (1 << 1) MI_LOAD_REGISTER_IMM, BCS_SWCTRL, (BCS_SRC_Y | BCS_DST_Y) << 16 | (BCS_SRC_Y | BCS_DST_Y), MI_LOAD_REGISTER_IMM, BCS_SWCTRL, (BCS_SRC_Y | BCS_DST_Y) << 16, MI_BATCH_BUFFER_END, 0, }; int ret; if (DBG_NO_BLT_Y) return false; if (kgem->gen < 060) return false; memset(&object, 0, sizeof(object)); object.handle = gem_create(kgem->fd, 1); ret = gem_write(kgem->fd, object.handle, 0, sizeof(batch), batch); if (ret == 0) { struct drm_i915_gem_execbuffer2 execbuf; memset(&execbuf, 0, sizeof(execbuf)); execbuf.buffers_ptr = (uintptr_t)&object; execbuf.buffer_count = 1; execbuf.flags = KGEM_BLT; ret = do_ioctl(kgem->fd, DRM_IOCTL_I915_GEM_EXECBUFFER2, &execbuf); } gem_close(kgem->fd, object.handle); return ret == 0; } static bool gem_set_tiling(int fd, uint32_t handle, int tiling, int stride) { struct drm_i915_gem_set_tiling set_tiling; if (DBG_NO_TILING) return false; VG_CLEAR(set_tiling); set_tiling.handle = handle; set_tiling.tiling_mode = tiling; set_tiling.stride = stride; if (ioctl(fd, DRM_IOCTL_I915_GEM_SET_TILING, &set_tiling) == 0) return set_tiling.tiling_mode == tiling; return false; } static bool test_can_scanout_y(struct kgem *kgem) { struct drm_mode_fb_cmd arg; bool ret = false; if (DBG_NO_SCANOUT_Y) return false; VG_CLEAR(arg); arg.width = 32; arg.height = 32; arg.pitch = 4*32; arg.bpp = 32; arg.depth = 24; arg.handle = gem_create(kgem->fd, 1); if (gem_set_tiling(kgem->fd, arg.handle, I915_TILING_Y, arg.pitch)) ret = do_ioctl(kgem->fd, DRM_IOCTL_MODE_ADDFB, &arg) == 0; if (!ret) { struct local_mode_fb_cmd2 { uint32_t fb_id; uint32_t width, height; uint32_t pixel_format; uint32_t flags; uint32_t handles[4]; uint32_t pitches[4]; uint32_t offsets[4]; uint64_t modifiers[4]; } f; #define LOCAL_IOCTL_MODE_ADDFB2 DRM_IOWR(0xb8, struct local_mode_fb_cmd2) memset(&f, 0, sizeof(f)); f.width = arg.width; f.height = arg.height; f.handles[0] = arg.handle; f.pitches[0] = arg.pitch; f.modifiers[0] = (uint64_t)1 << 56 | 2; /* MOD_Y_TILED */ f.pixel_format = 'X' | 'R' << 8 | '2' << 16 | '4' << 24; /* XRGB8888 */ f.flags = 1 << 1; /* + modifier */ if (drmIoctl(kgem->fd, LOCAL_IOCTL_MODE_ADDFB2, &f) == 0) { ret = true; arg.fb_id = f.fb_id; } } do_ioctl(kgem->fd, DRM_IOCTL_MODE_RMFB, &arg.fb_id); gem_close(kgem->fd, arg.handle); return ret; } static bool test_has_dirtyfb(struct kgem *kgem) { struct drm_mode_fb_cmd create; bool ret = false; if (DBG_NO_DIRTYFB) return false; VG_CLEAR(create); create.width = 32; create.height = 32; create.pitch = 4*32; create.bpp = 32; create.depth = 24; /* {bpp:32, depth:24} -> x8r8g8b8 */ create.handle = gem_create(kgem->fd, 1); if (create.handle == 0) return false; if (drmIoctl(kgem->fd, DRM_IOCTL_MODE_ADDFB, &create) == 0) { struct drm_mode_fb_dirty_cmd dirty; memset(&dirty, 0, sizeof(dirty)); dirty.fb_id = create.fb_id; ret = drmIoctl(kgem->fd, DRM_IOCTL_MODE_DIRTYFB, &dirty) == 0; /* XXX There may be multiple levels of DIRTYFB, depending on * whether the kernel thinks tracking dirty regions is * beneficial vs flagging the whole fb as dirty. */ drmIoctl(kgem->fd, DRM_IOCTL_MODE_RMFB, &create.fb_id); } gem_close(kgem->fd, create.handle); return ret; } static bool test_has_secure_batches(struct kgem *kgem) { if (DBG_NO_SECURE_BATCHES) return false; return gem_param(kgem, LOCAL_I915_PARAM_HAS_SECURE_BATCHES) > 0; } static bool test_has_pinned_batches(struct kgem *kgem) { if (DBG_NO_PINNED_BATCHES) return false; return gem_param(kgem, LOCAL_I915_PARAM_HAS_PINNED_BATCHES) > 0; } static bool kgem_init_pinned_batches(struct kgem *kgem) { int count[2] = { 16, 4 }; int size[2] = { 1, 4 }; int ret = 0; int n, i; if (unlikely(kgem->wedged)) return true; for (n = 0; n < ARRAY_SIZE(count); n++) { for (i = 0; i < count[n]; i++) { struct drm_i915_gem_pin pin; struct kgem_bo *bo; VG_CLEAR(pin); pin.handle = gem_create(kgem->fd, size[n]); if (pin.handle == 0) goto err; DBG(("%s: new handle=%d, num_pages=%d\n", __FUNCTION__, pin.handle, size[n])); bo = __kgem_bo_alloc(pin.handle, size[n]); if (bo == NULL) { gem_close(kgem->fd, pin.handle); goto err; } pin.alignment = 0; ret = do_ioctl(kgem->fd, DRM_IOCTL_I915_GEM_PIN, &pin); if (ret) { gem_close(kgem->fd, pin.handle); free(bo); goto err; } bo->presumed_offset = pin.offset; debug_alloc__bo(kgem, bo); list_add(&bo->list, &kgem->pinned_batches[n]); } } return true; err: for (n = 0; n < ARRAY_SIZE(kgem->pinned_batches); n++) { while (!list_is_empty(&kgem->pinned_batches[n])) { kgem_bo_destroy(kgem, list_first_entry(&kgem->pinned_batches[n], struct kgem_bo, list)); } } /* If we fail to pin some memory for 830gm/845g, we need to disable * acceleration as otherwise the machine will eventually fail. However, * the kernel started arbitrarily rejecting PIN, so hope for the best * if the ioctl no longer works. */ if (ret != -ENODEV && kgem->gen == 020) return false; kgem->has_pinned_batches = false; /* For simplicity populate the lists with a single unpinned bo */ for (n = 0; n < ARRAY_SIZE(count); n++) { struct kgem_bo *bo; uint32_t handle; handle = gem_create(kgem->fd, size[n]); if (handle == 0) return false; bo = __kgem_bo_alloc(handle, size[n]); if (bo == NULL) { gem_close(kgem->fd, handle); return false; } debug_alloc__bo(kgem, bo); list_add(&bo->list, &kgem->pinned_batches[n]); } return true; } static void kgem_init_swizzling(struct kgem *kgem) { struct local_i915_gem_get_tiling_v2 { uint32_t handle; uint32_t tiling_mode; uint32_t swizzle_mode; uint32_t phys_swizzle_mode; } tiling; #define LOCAL_IOCTL_I915_GEM_GET_TILING DRM_IOWR (DRM_COMMAND_BASE + DRM_I915_GEM_GET_TILING, struct local_i915_gem_get_tiling_v2) memset(&tiling, 0, sizeof(tiling)); tiling.handle = gem_create(kgem->fd, 1); if (!tiling.handle) return; if (!gem_set_tiling(kgem->fd, tiling.handle, I915_TILING_X, 512)) goto out; if (do_ioctl(kgem->fd, LOCAL_IOCTL_I915_GEM_GET_TILING, &tiling)) goto out; DBG(("%s: swizzle_mode=%d, phys_swizzle_mode=%d\n", __FUNCTION__, tiling.swizzle_mode, tiling.phys_swizzle_mode)); kgem->can_fence = !DBG_NO_TILING && tiling.swizzle_mode != I915_BIT_6_SWIZZLE_UNKNOWN; if (kgem->gen < 050 && tiling.phys_swizzle_mode != tiling.swizzle_mode) goto out; if (!DBG_NO_DETILING) choose_memcpy_tiled_x(kgem, tiling.swizzle_mode, __to_sna(kgem)->cpu_features); out: gem_close(kgem->fd, tiling.handle); DBG(("%s: can fence?=%d\n", __FUNCTION__, kgem->can_fence)); } static void kgem_fixup_relocs(struct kgem *kgem, struct kgem_bo *bo, int shrink) { int n; bo->target_handle = kgem->has_handle_lut ? kgem->nexec : bo->handle; assert(kgem->nreloc__self <= 256); if (kgem->nreloc__self == 0) return; DBG(("%s: fixing up %d%s self-relocations to handle=%p, presumed-offset=%llx\n", __FUNCTION__, kgem->nreloc__self, kgem->nreloc__self == 256 ? "+" : "", bo->handle, (long long)bo->presumed_offset)); for (n = 0; n < kgem->nreloc__self; n++) { int i = kgem->reloc__self[n]; uint64_t addr; assert(kgem->reloc[i].target_handle == ~0U); kgem->reloc[i].target_handle = bo->target_handle; kgem->reloc[i].presumed_offset = bo->presumed_offset; if (kgem->reloc[i].read_domains == I915_GEM_DOMAIN_INSTRUCTION) { DBG(("%s: moving base of self-reloc[%d:%d] %d -> %d\n", __FUNCTION__, n, i, kgem->reloc[i].delta, kgem->reloc[i].delta - shrink)); kgem->reloc[i].delta -= shrink; } addr = (int)kgem->reloc[i].delta + bo->presumed_offset; kgem->batch[kgem->reloc[i].offset/sizeof(uint32_t)] = addr; if (kgem->gen >= 0100) kgem->batch[kgem->reloc[i].offset/sizeof(uint32_t) + 1] = addr >> 32; } if (n == 256) { for (n = kgem->reloc__self[255]; n < kgem->nreloc; n++) { if (kgem->reloc[n].target_handle == ~0U) { uint64_t addr; kgem->reloc[n].target_handle = bo->target_handle; kgem->reloc[n].presumed_offset = bo->presumed_offset; if (kgem->reloc[n].read_domains == I915_GEM_DOMAIN_INSTRUCTION) { DBG(("%s: moving base of reloc[%d] %d -> %d\n", __FUNCTION__, n, kgem->reloc[n].delta, kgem->reloc[n].delta - shrink)); kgem->reloc[n].delta -= shrink; } addr = (int)kgem->reloc[n].delta + bo->presumed_offset; kgem->batch[kgem->reloc[n].offset/sizeof(uint32_t)] = addr; if (kgem->gen >= 0100) kgem->batch[kgem->reloc[n].offset/sizeof(uint32_t) + 1] = addr >> 32; } } } if (shrink) { DBG(("%s: shrinking by %d\n", __FUNCTION__, shrink)); for (n = 0; n < kgem->nreloc; n++) { if (kgem->reloc[n].offset >= sizeof(uint32_t)*kgem->nbatch) kgem->reloc[n].offset -= shrink; } } } static int kgem_bo_wait(struct kgem *kgem, struct kgem_bo *bo) { struct local_i915_gem_wait { uint32_t handle; uint32_t flags; int64_t timeout; } wait; #define LOCAL_I915_GEM_WAIT 0x2c #define LOCAL_IOCTL_I915_GEM_WAIT DRM_IOWR(DRM_COMMAND_BASE + LOCAL_I915_GEM_WAIT, struct local_i915_gem_wait) int ret; DBG(("%s: waiting for handle=%d\n", __FUNCTION__, bo->handle)); if (bo->rq == NULL) return 0; VG_CLEAR(wait); wait.handle = bo->handle; wait.flags = 0; wait.timeout = -1; ret = do_ioctl(kgem->fd, LOCAL_IOCTL_I915_GEM_WAIT, &wait); if (ret) { struct drm_i915_gem_set_domain set_domain; VG_CLEAR(set_domain); set_domain.handle = bo->handle; set_domain.read_domains = I915_GEM_DOMAIN_GTT; set_domain.write_domain = I915_GEM_DOMAIN_GTT; ret = do_ioctl(kgem->fd, DRM_IOCTL_I915_GEM_SET_DOMAIN, &set_domain); } if (ret == 0) __kgem_retire_requests_upto(kgem, bo); return ret; } static struct kgem_bo *kgem_new_batch(struct kgem *kgem) { struct kgem_bo *last; unsigned flags; last = kgem->batch_bo; if (last) { kgem_fixup_relocs(kgem, last, 0); kgem->batch = NULL; } if (kgem->batch) { assert(last == NULL); return NULL; } flags = CREATE_CPU_MAP | CREATE_NO_THROTTLE; if (!kgem->has_llc) flags |= CREATE_UNCACHED; restart: kgem->batch_bo = kgem_create_linear(kgem, sizeof(uint32_t)*kgem->batch_size, flags); if (kgem->batch_bo) kgem->batch = kgem_bo_map__cpu(kgem, kgem->batch_bo); if (kgem->batch == NULL) { int ring = kgem->ring == KGEM_BLT; assert(ring < ARRAY_SIZE(kgem->requests)); if (kgem->batch_bo) { kgem_bo_destroy(kgem, kgem->batch_bo); kgem->batch_bo = NULL; } if (!list_is_empty(&kgem->requests[ring])) { struct kgem_request *rq; rq = list_first_entry(&kgem->requests[ring], struct kgem_request, list); assert(rq->ring == ring); assert(rq->bo); assert(RQ(rq->bo->rq) == rq); if (kgem_bo_wait(kgem, rq->bo) == 0) goto restart; } if (flags & CREATE_NO_THROTTLE) { flags &= ~CREATE_NO_THROTTLE; if (kgem_cleanup_cache(kgem)) goto restart; } DBG(("%s: unable to map batch bo, mallocing(size=%d)\n", __FUNCTION__, sizeof(uint32_t)*kgem->batch_size)); if (posix_memalign((void **)&kgem->batch, PAGE_SIZE, ALIGN(sizeof(uint32_t) * kgem->batch_size, PAGE_SIZE))) { ERR(("%s: batch allocation failed, disabling acceleration\n", __FUNCTION__)); __kgem_set_wedged(kgem); } } else { DBG(("%s: allocated and mapped batch handle=%d [size=%d]\n", __FUNCTION__, kgem->batch_bo->handle, sizeof(uint32_t)*kgem->batch_size)); kgem_bo_sync__cpu(kgem, kgem->batch_bo); } DBG(("%s: using last batch handle=%d\n", __FUNCTION__, last ? last->handle : 0)); return last; } static void no_retire(struct kgem *kgem) { (void)kgem; } static void no_expire(struct kgem *kgem) { (void)kgem; } static void no_context_switch(struct kgem *kgem, int new_mode) { (void)kgem; (void)new_mode; } static uint64_t get_gtt_size(int fd) { struct drm_i915_gem_get_aperture aperture; struct local_i915_gem_context_param { uint32_t context; uint32_t size; uint64_t param; #define LOCAL_CONTEXT_PARAM_BAN_PERIOD 0x1 #define LOCAL_CONTEXT_PARAM_NO_ZEROMAP 0x2 #define LOCAL_CONTEXT_PARAM_GTT_SIZE 0x3 uint64_t value; } p; #define LOCAL_I915_GEM_CONTEXT_GETPARAM 0x34 #define LOCAL_IOCTL_I915_GEM_CONTEXT_GETPARAM DRM_IOWR (DRM_COMMAND_BASE + LOCAL_I915_GEM_CONTEXT_GETPARAM, struct local_i915_gem_context_param) memset(&aperture, 0, sizeof(aperture)); memset(&p, 0, sizeof(p)); p.param = LOCAL_CONTEXT_PARAM_GTT_SIZE; if (drmIoctl(fd, LOCAL_IOCTL_I915_GEM_CONTEXT_GETPARAM, &p) == 0) aperture.aper_size = p.value; if (aperture.aper_size == 0) (void)drmIoctl(fd, DRM_IOCTL_I915_GEM_GET_APERTURE, &aperture); if (aperture.aper_size == 0) aperture.aper_size = 64*1024*1024; DBG(("%s: aperture size %lld, available now %lld\n", __FUNCTION__, (long long)aperture.aper_size, (long long)aperture.aper_available_size)); /* clamp aperture to uint32_t for simplicity */ if (aperture.aper_size > 0xc0000000) aperture.aper_size = 0xc0000000; return aperture.aper_size; } static int get_gtt_type(int fd) { struct drm_i915_getparam p; int val = 0; memset(&p, 0, sizeof(p)); p.param = I915_PARAM_HAS_ALIASING_PPGTT; p.value = &val; drmIoctl(fd, DRM_IOCTL_I915_GETPARAM, &p); return val; } void kgem_init(struct kgem *kgem, int fd, struct pci_device *dev, unsigned gen) { size_t totalram; unsigned half_gpu_max; unsigned int i, j; uint64_t gtt_size; DBG(("%s: fd=%d, gen=%d\n", __FUNCTION__, fd, gen)); kgem->fd = fd; kgem->gen = gen; kgem->retire = no_retire; kgem->expire = no_expire; kgem->context_switch = no_context_switch; list_init(&kgem->requests[0]); list_init(&kgem->requests[1]); list_init(&kgem->batch_buffers); list_init(&kgem->active_buffers); list_init(&kgem->flushing); list_init(&kgem->large); list_init(&kgem->large_inactive); list_init(&kgem->snoop); list_init(&kgem->scanout); for (i = 0; i < ARRAY_SIZE(kgem->pinned_batches); i++) list_init(&kgem->pinned_batches[i]); for (i = 0; i < ARRAY_SIZE(kgem->inactive); i++) list_init(&kgem->inactive[i]); for (i = 0; i < ARRAY_SIZE(kgem->active); i++) { for (j = 0; j < ARRAY_SIZE(kgem->active[i]); j++) list_init(&kgem->active[i][j]); } for (i = 0; i < ARRAY_SIZE(kgem->vma); i++) { for (j = 0; j < ARRAY_SIZE(kgem->vma[i].inactive); j++) list_init(&kgem->vma[i].inactive[j]); } kgem->vma[MAP_GTT].count = -MAX_GTT_VMA_CACHE; kgem->vma[MAP_CPU].count = -MAX_CPU_VMA_CACHE; kgem->has_blt = gem_param(kgem, LOCAL_I915_PARAM_HAS_BLT) > 0; DBG(("%s: has BLT ring? %d\n", __FUNCTION__, kgem->has_blt)); kgem->has_relaxed_delta = gem_param(kgem, LOCAL_I915_PARAM_HAS_RELAXED_DELTA) > 0; DBG(("%s: has relaxed delta? %d\n", __FUNCTION__, kgem->has_relaxed_delta)); kgem->has_relaxed_fencing = test_has_relaxed_fencing(kgem); DBG(("%s: has relaxed fencing? %d\n", __FUNCTION__, kgem->has_relaxed_fencing)); kgem->has_coherent_mmap_gtt = test_has_coherent_mmap_gtt(kgem); DBG(("%s: has coherent writes into GTT maps? %d\n", __FUNCTION__, kgem->has_coherent_mmap_gtt)); kgem->has_llc = test_has_llc(kgem); DBG(("%s: has shared last-level-cache? %d\n", __FUNCTION__, kgem->has_llc)); kgem->has_wt = test_has_wt(kgem); DBG(("%s: has write-through caching for scanouts? %d\n", __FUNCTION__, kgem->has_wt)); kgem->has_wc_mmap = test_has_wc_mmap(kgem); DBG(("%s: has wc-mmapping? %d\n", __FUNCTION__, kgem->has_wc_mmap)); kgem->has_caching = test_has_caching(kgem); DBG(("%s: has set-cache-level? %d\n", __FUNCTION__, kgem->has_caching)); kgem->has_userptr = test_has_userptr(kgem); DBG(("%s: has userptr? %d\n", __FUNCTION__, kgem->has_userptr)); kgem->has_create2 = test_has_create2(kgem); DBG(("%s: has create2? %d\n", __FUNCTION__, kgem->has_create2)); kgem->has_no_reloc = test_has_no_reloc(kgem); DBG(("%s: has no-reloc? %d\n", __FUNCTION__, kgem->has_no_reloc)); kgem->has_handle_lut = test_has_handle_lut(kgem); DBG(("%s: has handle-lut? %d\n", __FUNCTION__, kgem->has_handle_lut)); kgem->has_semaphores = false; if (kgem->has_blt && test_has_semaphores_enabled(kgem)) kgem->has_semaphores = true; DBG(("%s: semaphores enabled? %d\n", __FUNCTION__, kgem->has_semaphores)); kgem->can_blt_cpu = gen >= 030; DBG(("%s: can blt to cpu? %d\n", __FUNCTION__, kgem->can_blt_cpu)); kgem->can_blt_y = test_can_blt_y(kgem); DBG(("%s: can blit to Y-tiled surfaces? %d\n", __FUNCTION__, kgem->can_blt_y)); kgem->can_render_y = gen != 021 && (gen >> 3) != 4; DBG(("%s: can render to Y-tiled surfaces? %d\n", __FUNCTION__, kgem->can_render_y)); kgem->can_scanout_y = test_can_scanout_y(kgem); DBG(("%s: can scanout Y-tiled surfaces? %d\n", __FUNCTION__, kgem->can_scanout_y)); kgem->has_dirtyfb = test_has_dirtyfb(kgem); DBG(("%s: has dirty fb? %d\n", __FUNCTION__, kgem->has_dirtyfb)); kgem->has_secure_batches = test_has_secure_batches(kgem); DBG(("%s: can use privileged batchbuffers? %d\n", __FUNCTION__, kgem->has_secure_batches)); kgem->has_pinned_batches = test_has_pinned_batches(kgem); DBG(("%s: can use pinned batchbuffers (to avoid CS w/a)? %d\n", __FUNCTION__, kgem->has_pinned_batches)); if (!is_hw_supported(kgem, dev)) { xf86DrvMsg(kgem_get_screen_index(kgem), X_WARNING, "Detected unsupported/dysfunctional hardware, disabling acceleration.\n"); __kgem_set_wedged(kgem); } else if (__kgem_throttle(kgem, false)) { xf86DrvMsg(kgem_get_screen_index(kgem), X_WARNING, "Detected a hung GPU, disabling acceleration.\n"); __kgem_set_wedged(kgem); } kgem->batch_size = UINT16_MAX & ~7; if (gen == 020 && !kgem->has_pinned_batches) /* Limited to what we can pin */ kgem->batch_size = 4*1024; if (gen == 022) /* 865g cannot handle a batch spanning multiple pages */ kgem->batch_size = PAGE_SIZE / sizeof(uint32_t); if (gen >= 070) kgem->batch_size = 16*1024; if (!kgem->has_relaxed_delta && kgem->batch_size > 4*1024) kgem->batch_size = 4*1024; if (!kgem_init_pinned_batches(kgem)) { xf86DrvMsg(kgem_get_screen_index(kgem), X_WARNING, "Unable to reserve memory for GPU, disabling acceleration.\n"); __kgem_set_wedged(kgem); } DBG(("%s: maximum batch size? %d\n", __FUNCTION__, kgem->batch_size)); kgem_new_batch(kgem); kgem->half_cpu_cache_pages = cpu_cache_size() >> 13; DBG(("%s: last-level cache size: %d bytes, threshold in pages: %d\n", __FUNCTION__, cpu_cache_size(), kgem->half_cpu_cache_pages)); kgem->next_request = __kgem_request_alloc(kgem); DBG(("%s: cpu bo enabled %d: llc? %d, set-cache-level? %d, userptr? %d\n", __FUNCTION__, !DBG_NO_CPU && (kgem->has_llc | kgem->has_userptr | kgem->has_caching), kgem->has_llc, kgem->has_caching, kgem->has_userptr)); kgem->has_full_ppgtt = get_gtt_type(fd) > 1; gtt_size = get_gtt_size(fd); kgem->aperture_total = gtt_size; kgem->aperture_high = gtt_size * 3/4; kgem->aperture_low = gtt_size * 1/3; if (gen < 033) { /* Severe alignment penalties */ kgem->aperture_high /= 2; kgem->aperture_low /= 2; } DBG(("%s: aperture low=%u [%u], high=%u [%u]\n", __FUNCTION__, kgem->aperture_low, kgem->aperture_low / (1024*1024), kgem->aperture_high, kgem->aperture_high / (1024*1024))); kgem->aperture_mappable = 256 * 1024 * 1024; if (dev != NULL) kgem->aperture_mappable = agp_aperture_size(dev, gen); if (kgem->aperture_mappable == 0 || kgem->aperture_mappable > gtt_size) kgem->aperture_mappable = gtt_size; DBG(("%s: aperture mappable=%d [%d MiB]\n", __FUNCTION__, kgem->aperture_mappable, kgem->aperture_mappable / (1024*1024))); kgem->aperture_fenceable = MIN(256*1024*1024, kgem->aperture_mappable); DBG(("%s: aperture fenceable=%d [%d MiB]\n", __FUNCTION__, kgem->aperture_fenceable, kgem->aperture_fenceable / (1024*1024))); kgem->buffer_size = 64 * 1024; while (kgem->buffer_size < kgem->aperture_mappable >> 10) kgem->buffer_size *= 2; if (kgem->buffer_size >> 12 > kgem->half_cpu_cache_pages) kgem->buffer_size = kgem->half_cpu_cache_pages << 12; kgem->buffer_size = 1 << __fls(kgem->buffer_size); DBG(("%s: buffer size=%d [%d KiB]\n", __FUNCTION__, kgem->buffer_size, kgem->buffer_size / 1024)); assert(kgem->buffer_size); kgem->max_object_size = 3 * (kgem->aperture_high >> 12) << 10; kgem->max_gpu_size = kgem->max_object_size; if (!kgem->has_llc && kgem->max_gpu_size > MAX_CACHE_SIZE) kgem->max_gpu_size = MAX_CACHE_SIZE; totalram = total_ram_size(); if (totalram == 0) { DBG(("%s: total ram size unknown, assuming maximum of total aperture\n", __FUNCTION__)); totalram = kgem->aperture_total; } DBG(("%s: total ram=%lld\n", __FUNCTION__, (long long)totalram)); if (kgem->max_object_size > totalram / 2) kgem->max_object_size = totalram / 2; if (kgem->max_gpu_size > totalram / 4) kgem->max_gpu_size = totalram / 4; if (kgem->aperture_high > totalram / 2) { kgem->aperture_high = totalram / 2; kgem->aperture_low = kgem->aperture_high / 4; DBG(("%s: reduced aperture watermaks to fit into ram; low=%d [%d], high=%d [%d]\n", __FUNCTION__, kgem->aperture_low, kgem->aperture_low / (1024*1024), kgem->aperture_high, kgem->aperture_high / (1024*1024))); } kgem->max_cpu_size = kgem->max_object_size; half_gpu_max = kgem->max_gpu_size / 2; kgem->max_copy_tile_size = (MAX_CACHE_SIZE + 1)/2; if (kgem->max_copy_tile_size > half_gpu_max) kgem->max_copy_tile_size = half_gpu_max; if (kgem->has_llc) kgem->max_upload_tile_size = kgem->max_copy_tile_size; else kgem->max_upload_tile_size = kgem->aperture_fenceable / 4; if (kgem->max_upload_tile_size > half_gpu_max) kgem->max_upload_tile_size = half_gpu_max; if (kgem->max_upload_tile_size > kgem->aperture_high/2) kgem->max_upload_tile_size = kgem->aperture_high/2; if (kgem->max_upload_tile_size > kgem->aperture_low) kgem->max_upload_tile_size = kgem->aperture_low; if (kgem->max_upload_tile_size < 16*PAGE_SIZE) kgem->max_upload_tile_size = 16*PAGE_SIZE; kgem->large_object_size = MAX_CACHE_SIZE; if (kgem->large_object_size > half_gpu_max) kgem->large_object_size = half_gpu_max; if (kgem->max_copy_tile_size > kgem->aperture_high/2) kgem->max_copy_tile_size = kgem->aperture_high/2; if (kgem->max_copy_tile_size > kgem->aperture_low) kgem->max_copy_tile_size = kgem->aperture_low; if (kgem->max_copy_tile_size < 16*PAGE_SIZE) kgem->max_copy_tile_size = 16*PAGE_SIZE; if (kgem->has_llc | kgem->has_caching | kgem->has_userptr) { if (kgem->large_object_size > kgem->max_cpu_size) kgem->large_object_size = kgem->max_cpu_size; } else kgem->max_cpu_size = 0; if (DBG_NO_CPU) kgem->max_cpu_size = 0; DBG(("%s: maximum object size=%u\n", __FUNCTION__, kgem->max_object_size)); DBG(("%s: large object thresold=%u\n", __FUNCTION__, kgem->large_object_size)); DBG(("%s: max object sizes (gpu=%u, cpu=%u, tile upload=%u, copy=%u)\n", __FUNCTION__, kgem->max_gpu_size, kgem->max_cpu_size, kgem->max_upload_tile_size, kgem->max_copy_tile_size)); /* Convert the aperture thresholds to pages */ kgem->aperture_mappable /= PAGE_SIZE; kgem->aperture_fenceable /= PAGE_SIZE; kgem->aperture_low /= PAGE_SIZE; kgem->aperture_high /= PAGE_SIZE; kgem->aperture_total /= PAGE_SIZE; kgem->fence_max = gem_param(kgem, I915_PARAM_NUM_FENCES_AVAIL) - 2; if ((int)kgem->fence_max < 0) kgem->fence_max = 5; /* minimum safe value for all hw */ DBG(("%s: max fences=%d\n", __FUNCTION__, kgem->fence_max)); kgem->batch_flags_base = 0; if (kgem->has_no_reloc) kgem->batch_flags_base |= LOCAL_I915_EXEC_NO_RELOC; if (kgem->has_handle_lut) kgem->batch_flags_base |= LOCAL_I915_EXEC_HANDLE_LUT; if (kgem->has_pinned_batches) kgem->batch_flags_base |= LOCAL_I915_EXEC_IS_PINNED; kgem_init_swizzling(kgem); } /* XXX hopefully a good approximation */ static uint32_t kgem_get_unique_id(struct kgem *kgem) { uint32_t id; id = ++kgem->unique_id; if (id == 0) id = ++kgem->unique_id; return id; } inline static uint32_t kgem_pitch_alignment(struct kgem *kgem, unsigned flags) { if (flags & CREATE_PRIME) return 256; if (flags & CREATE_SCANOUT) return 64; if (kgem->gen >= 0100) return 32; return 8; } void kgem_get_tile_size(struct kgem *kgem, int tiling, int pitch, int *tile_width, int *tile_height, int *tile_size) { if (kgem->gen <= 030) { if (tiling) { if (kgem->gen < 030) { *tile_width = 128; *tile_height = 16; *tile_size = 2048; } else { *tile_width = 512; *tile_height = 8; *tile_size = 4096; } } else { *tile_width = 1; *tile_height = 1; *tile_size = 1; } } else switch (tiling) { default: case I915_TILING_NONE: *tile_width = 1; *tile_height = 1; *tile_size = 1; break; case I915_TILING_X: *tile_width = 512; *tile_height = 8; *tile_size = 4096; break; case I915_TILING_Y: *tile_width = 128; *tile_height = 32; *tile_size = 4096; break; } /* Force offset alignment to tile-row */ if (tiling && kgem->gen < 033) *tile_width = pitch; } static uint32_t kgem_surface_size(struct kgem *kgem, bool relaxed_fencing, unsigned flags, uint32_t width, uint32_t height, uint32_t bpp, uint32_t tiling, uint32_t *pitch) { uint32_t tile_width, tile_height; uint32_t size; assert(width <= MAXSHORT); assert(height <= MAXSHORT); assert(bpp >= 8); if (kgem->gen <= 030) { if (tiling) { if (kgem->gen < 030) { tile_width = 128; tile_height = 16; } else { tile_width = 512; tile_height = 8; } } else { tile_width = 2 * bpp >> 3; tile_width = ALIGN(tile_width, kgem_pitch_alignment(kgem, flags)); tile_height = 1; } } else switch (tiling) { default: case I915_TILING_NONE: tile_width = 2 * bpp >> 3; tile_width = ALIGN(tile_width, kgem_pitch_alignment(kgem, flags)); tile_height = 1; break; case I915_TILING_X: tile_width = 512; tile_height = 8; break; case I915_TILING_Y: tile_width = 128; tile_height = 32; break; } /* XXX align to an even tile row */ if (!kgem->has_relaxed_fencing) tile_height *= 2; *pitch = ALIGN(width * bpp / 8, tile_width); height = ALIGN(height, tile_height); DBG(("%s: tile_width=%d, tile_height=%d => aligned pitch=%d, height=%d\n", __FUNCTION__, tile_width, tile_height, *pitch, height)); if (kgem->gen >= 040) return PAGE_ALIGN(*pitch * height); /* If it is too wide for the blitter, don't even bother. */ if (tiling != I915_TILING_NONE) { if (*pitch > 8192) { DBG(("%s: too wide for tiled surface (pitch=%d, limit=%d)\n", __FUNCTION__, *pitch, 8192)); return 0; } for (size = tile_width; size < *pitch; size <<= 1) ; *pitch = size; } else { if (*pitch >= 32768) { DBG(("%s: too wide for linear surface (pitch=%d, limit=%d)\n", __FUNCTION__, *pitch, 32767)); return 0; } } size = *pitch * height; if (relaxed_fencing || tiling == I915_TILING_NONE) return PAGE_ALIGN(size); /* We need to allocate a pot fence region for a tiled buffer. */ if (kgem->gen < 030) tile_width = 512 * 1024; else tile_width = 1024 * 1024; while (tile_width < size) tile_width *= 2; return tile_width; } bool kgem_check_surface_size(struct kgem *kgem, uint32_t width, uint32_t height, uint32_t bpp, uint32_t tiling, uint32_t pitch, uint32_t size) { uint32_t min_size, min_pitch; int tile_width, tile_height, tile_size; DBG(("%s(width=%d, height=%d, bpp=%d, tiling=%d, pitch=%d, size=%d)\n", __FUNCTION__, width, height, bpp, tiling, pitch, size)); if (pitch & 3) return false; min_size = kgem_surface_size(kgem, kgem->has_relaxed_fencing, 0, width, height, bpp, tiling, &min_pitch); DBG(("%s: min_pitch=%d, min_size=%d\n", __FUNCTION__, min_pitch, min_size)); if (size < min_size) return false; if (pitch < min_pitch) return false; kgem_get_tile_size(kgem, tiling, min_pitch, &tile_width, &tile_height, &tile_size); DBG(("%s: tile_width=%d, tile_size=%d\n", __FUNCTION__, tile_width, tile_size)); if (pitch & (tile_width - 1)) return false; if (size & (tile_size - 1)) return false; return true; } static uint32_t kgem_aligned_height(struct kgem *kgem, uint32_t height, uint32_t tiling) { uint32_t tile_height; if (kgem->gen <= 030) { tile_height = tiling ? kgem->gen < 030 ? 16 : 8 : 1; } else switch (tiling) { /* XXX align to an even tile row */ default: case I915_TILING_NONE: tile_height = 1; break; case I915_TILING_X: tile_height = 8; break; case I915_TILING_Y: tile_height = 32; break; } /* XXX align to an even tile row */ if (!kgem->has_relaxed_fencing) tile_height *= 2; return ALIGN(height, tile_height); } static struct drm_i915_gem_exec_object2 * kgem_add_handle(struct kgem *kgem, struct kgem_bo *bo) { struct drm_i915_gem_exec_object2 *exec; DBG(("%s: handle=%d, index=%d\n", __FUNCTION__, bo->handle, kgem->nexec)); assert(kgem->nexec < ARRAY_SIZE(kgem->exec)); bo->target_handle = kgem->has_handle_lut ? kgem->nexec : bo->handle; exec = memset(&kgem->exec[kgem->nexec++], 0, sizeof(*exec)); exec->handle = bo->handle; exec->offset = bo->presumed_offset; kgem->aperture += num_pages(bo); return exec; } static void kgem_add_bo(struct kgem *kgem, struct kgem_bo *bo) { assert(bo->refcnt); assert(bo->proxy == NULL); bo->exec = kgem_add_handle(kgem, bo); bo->rq = MAKE_REQUEST(kgem->next_request, kgem->ring); list_move_tail(&bo->request, &kgem->next_request->buffers); if (bo->io && !list_is_empty(&bo->list)) list_move(&bo->list, &kgem->batch_buffers); /* XXX is it worth working around gcc here? */ kgem->flush |= bo->flush; } static void kgem_clear_swctrl(struct kgem *kgem) { uint32_t *b; if (kgem->bcs_state == 0) return; DBG(("%s: clearin SWCTRL LRI from %x\n", __FUNCTION__, kgem->bcs_state)); b = kgem->batch + kgem->nbatch; kgem->nbatch += 7; *b++ = MI_FLUSH_DW; *b++ = 0; *b++ = 0; *b++ = 0; *b++ = MI_LOAD_REGISTER_IMM; *b++ = BCS_SWCTRL; *b++ = (BCS_SRC_Y | BCS_DST_Y) << 16; kgem->bcs_state = 0; } static uint32_t kgem_end_batch(struct kgem *kgem) { kgem_clear_swctrl(kgem); kgem->batch[kgem->nbatch++] = MI_BATCH_BUFFER_END; if (kgem->nbatch & 1) kgem->batch[kgem->nbatch++] = MI_NOOP; return kgem->nbatch; } static void kgem_bo_binding_free(struct kgem *kgem, struct kgem_bo *bo) { struct kgem_bo_binding *b; b = bo->binding.next; while (b) { struct kgem_bo_binding *next = b->next; free(b); b = next; } } static void kgem_bo_free(struct kgem *kgem, struct kgem_bo *bo) { DBG(("%s: handle=%d, size=%d\n", __FUNCTION__, bo->handle, bytes(bo))); assert(bo->refcnt == 0); assert(bo->proxy == NULL); assert(bo->exec == NULL); assert(!bo->snoop || bo->rq == NULL); #ifdef DEBUG_MEMORY kgem->debug_memory.bo_allocs--; kgem->debug_memory.bo_bytes -= bytes(bo); #endif kgem_bo_binding_free(kgem, bo); kgem_bo_rmfb(kgem, bo); if (IS_USER_MAP(bo->map__cpu)) { assert(bo->rq == NULL); assert(!__kgem_busy(kgem, bo->handle)); assert(MAP(bo->map__cpu) != bo || bo->io || bo->flush); if (!(bo->io || bo->flush)) { DBG(("%s: freeing snooped base\n", __FUNCTION__)); assert(bo != MAP(bo->map__cpu)); free(MAP(bo->map__cpu)); } bo->map__cpu = NULL; } DBG(("%s: releasing %p:%p vma for handle=%d, count=%d\n", __FUNCTION__, bo->map__gtt, bo->map__cpu, bo->handle, list_is_empty(&bo->vma) ? 0 : kgem->vma[bo->map__gtt == NULL && bo->map__wc == NULL].count)); if (!list_is_empty(&bo->vma)) { _list_del(&bo->vma); kgem->vma[bo->map__gtt == NULL && bo->map__wc == NULL].count--; } if (bo->map__gtt) munmap(bo->map__gtt, bytes(bo)); if (bo->map__wc) { VG(VALGRIND_MAKE_MEM_NOACCESS(bo->map__wc, bytes(bo))); munmap(bo->map__wc, bytes(bo)); } if (bo->map__cpu) { VG(VALGRIND_MAKE_MEM_NOACCESS(MAP(bo->map__cpu), bytes(bo))); munmap(MAP(bo->map__cpu), bytes(bo)); } _list_del(&bo->list); _list_del(&bo->request); gem_close(kgem->fd, bo->handle); if (!bo->io && !DBG_NO_MALLOC_CACHE) { *(struct kgem_bo **)bo = __kgem_freed_bo; __kgem_freed_bo = bo; } else free(bo); } inline static void kgem_bo_move_to_inactive(struct kgem *kgem, struct kgem_bo *bo) { DBG(("%s: moving handle=%d to inactive\n", __FUNCTION__, bo->handle)); assert(bo->refcnt == 0); assert(bo->reusable); assert(bo->rq == NULL); assert(bo->exec == NULL); assert(bo->domain != DOMAIN_GPU); assert(!bo->proxy); assert(!bo->io); assert(!bo->scanout); assert(!bo->snoop); assert(!bo->flush); assert(!bo->needs_flush); assert(!bo->delta); assert(list_is_empty(&bo->vma)); assert_tiling(kgem, bo); assert_caching(kgem, bo); ASSERT_IDLE(kgem, bo->handle); if (bucket(bo) >= NUM_CACHE_BUCKETS) { if (bo->map__gtt) { DBG(("%s: relinquishing large GTT mapping for handle=%d\n", __FUNCTION__, bo->handle)); munmap(bo->map__gtt, bytes(bo)); bo->map__gtt = NULL; } list_move(&bo->list, &kgem->large_inactive); } else { assert(bo->flush == false); assert(list_is_empty(&bo->vma)); list_move(&bo->list, &kgem->inactive[bucket(bo)]); if (bo->map__gtt && !kgem_bo_can_map(kgem, bo)) { DBG(("%s: relinquishing old GTT mapping for handle=%d\n", __FUNCTION__, bo->handle)); munmap(bo->map__gtt, bytes(bo)); bo->map__gtt = NULL; } if (bo->map__gtt || (bo->map__wc && !bo->tiling)) { list_add(&bo->vma, &kgem->vma[0].inactive[bucket(bo)]); kgem->vma[0].count++; } if (bo->map__cpu && list_is_empty(&bo->vma)) { list_add(&bo->vma, &kgem->vma[1].inactive[bucket(bo)]); kgem->vma[1].count++; } } kgem->need_expire = true; } static struct kgem_bo *kgem_bo_replace_io(struct kgem_bo *bo) { struct kgem_bo *base; if (!bo->io) return bo; assert(!bo->snoop); assert(!bo->purged); assert(!bo->scanout); assert(!bo->delta); if (__kgem_freed_bo) { base = __kgem_freed_bo; __kgem_freed_bo = *(struct kgem_bo **)base; } else base = malloc(sizeof(*base)); if (base) { DBG(("%s: transferring io handle=%d to bo\n", __FUNCTION__, bo->handle)); /* transfer the handle to a minimum bo */ memcpy(base, bo, sizeof(*base)); base->io = false; list_init(&base->list); list_replace(&bo->request, &base->request); list_replace(&bo->vma, &base->vma); free(bo); bo = base; } else bo->reusable = false; return bo; } inline static void kgem_bo_remove_from_inactive(struct kgem *kgem, struct kgem_bo *bo) { DBG(("%s: removing handle=%d from inactive\n", __FUNCTION__, bo->handle)); list_del(&bo->list); assert(bo->rq == NULL); assert(bo->exec == NULL); assert(!bo->purged); if (!list_is_empty(&bo->vma)) { assert(bo->map__gtt || bo->map__wc || bo->map__cpu); list_del(&bo->vma); kgem->vma[bo->map__gtt == NULL && bo->map__wc == NULL].count--; } } inline static void kgem_bo_remove_from_active(struct kgem *kgem, struct kgem_bo *bo) { DBG(("%s: removing handle=%d from active\n", __FUNCTION__, bo->handle)); list_del(&bo->list); assert(bo->rq != NULL); if (RQ(bo->rq) == (void *)kgem) { assert(bo->exec == NULL); list_del(&bo->request); } assert(list_is_empty(&bo->vma)); } static void _kgem_bo_delete_buffer(struct kgem *kgem, struct kgem_bo *bo) { struct kgem_buffer *io = (struct kgem_buffer *)bo->proxy; DBG(("%s: size=%d, offset=%d, parent used=%d\n", __FUNCTION__, bo->size.bytes, bo->delta, io->used)); if (ALIGN(bo->delta + bo->size.bytes, UPLOAD_ALIGNMENT) == io->used) io->used = bo->delta; } static bool check_scanout_size(struct kgem *kgem, struct kgem_bo *bo, int width, int height) { struct drm_mode_fb_cmd info; assert(bo->scanout); VG_CLEAR(info); info.fb_id = bo->delta; if (do_ioctl(kgem->fd, DRM_IOCTL_MODE_GETFB, &info)) return false; gem_close(kgem->fd, info.handle); if (width > info.width || height > info.height) { DBG(("%s: not using scanout %d (%dx%d), want (%dx%d)\n", __FUNCTION__, info.fb_id, info.width, info.height, width, height)); return false; } return true; } static void kgem_bo_move_to_scanout(struct kgem *kgem, struct kgem_bo *bo) { assert(bo->refcnt == 0); assert(bo->scanout); assert(!bo->flush); assert(!bo->snoop); assert(!bo->io); if (bo->purged) { /* for stolen fb */ if (!bo->exec) { DBG(("%s: discarding purged scanout - stolen?\n", __FUNCTION__)); kgem_bo_free(kgem, bo); } return; } DBG(("%s: moving %d [fb %d] to scanout cache, active? %d\n", __FUNCTION__, bo->handle, bo->delta, bo->rq != NULL)); if (bo->rq) list_move_tail(&bo->list, &kgem->scanout); else list_move(&bo->list, &kgem->scanout); kgem->need_expire = true; } static void kgem_bo_move_to_snoop(struct kgem *kgem, struct kgem_bo *bo) { assert(bo->reusable); assert(!bo->scanout); assert(!bo->flush); assert(!bo->needs_flush); assert(bo->refcnt == 0); assert(bo->exec == NULL); assert(!bo->purged); assert(!bo->delta); if (DBG_NO_SNOOP_CACHE) { kgem_bo_free(kgem, bo); return; } if (num_pages(bo) > kgem->max_cpu_size >> 13) { DBG(("%s handle=%d discarding large CPU buffer (%d >%d pages)\n", __FUNCTION__, bo->handle, num_pages(bo), kgem->max_cpu_size >> 13)); kgem_bo_free(kgem, bo); return; } assert(bo->tiling == I915_TILING_NONE); assert(bo->rq == NULL); DBG(("%s: moving %d to snoop cachee\n", __FUNCTION__, bo->handle)); list_add(&bo->list, &kgem->snoop); kgem->need_expire = true; } static bool kgem_bo_move_to_cache(struct kgem *kgem, struct kgem_bo *bo) { bool retired = false; DBG(("%s: release handle=%d\n", __FUNCTION__, bo->handle)); if (bo->prime) { DBG(("%s: discarding imported prime handle=%d\n", __FUNCTION__, bo->handle)); kgem_bo_free(kgem, bo); } else if (bo->snoop) { kgem_bo_move_to_snoop(kgem, bo); } else if (bo->scanout) { kgem_bo_move_to_scanout(kgem, bo); } else if ((bo = kgem_bo_replace_io(bo))->reusable) { kgem_bo_move_to_inactive(kgem, bo); retired = true; } else kgem_bo_free(kgem, bo); return retired; } static struct kgem_bo * search_snoop_cache(struct kgem *kgem, unsigned int num_pages, unsigned flags) { struct kgem_bo *bo, *first = NULL; DBG(("%s: num_pages=%d, flags=%x\n", __FUNCTION__, num_pages, flags)); if ((kgem->has_caching | kgem->has_userptr) == 0) return NULL; if (list_is_empty(&kgem->snoop)) { DBG(("%s: inactive and cache empty\n", __FUNCTION__)); if (!__kgem_throttle_retire(kgem, flags)) { DBG(("%s: nothing retired\n", __FUNCTION__)); return NULL; } } list_for_each_entry(bo, &kgem->snoop, list) { assert(bo->refcnt == 0); assert(bo->snoop); assert(!bo->scanout); assert(!bo->purged); assert(bo->proxy == NULL); assert(bo->tiling == I915_TILING_NONE); assert(bo->rq == NULL); assert(bo->exec == NULL); if (num_pages > num_pages(bo)) continue; if (num_pages(bo) > 2*num_pages) { if (first == NULL) first = bo; continue; } list_del(&bo->list); bo->pitch = 0; bo->delta = 0; DBG((" %s: found handle=%d (num_pages=%d) in snoop cache\n", __FUNCTION__, bo->handle, num_pages(bo))); return bo; } if (first) { list_del(&first->list); first->pitch = 0; first->delta = 0; DBG((" %s: found handle=%d (num_pages=%d) in snoop cache\n", __FUNCTION__, first->handle, num_pages(first))); return first; } return NULL; } void kgem_bo_undo(struct kgem *kgem, struct kgem_bo *bo) { if (kgem->nexec != 1 || bo->exec == NULL) return; assert(bo); DBG(("%s: only handle in batch, discarding last operations for handle=%d\n", __FUNCTION__, bo->handle)); assert(bo->exec == &_kgem_dummy_exec || bo->exec == &kgem->exec[0]); assert(kgem->exec[0].handle == bo->handle); assert(RQ(bo->rq) == kgem->next_request); bo->refcnt++; kgem_reset(kgem); bo->refcnt--; assert(kgem->nreloc == 0); assert(kgem->nexec == 0); assert(bo->exec == NULL); } void kgem_bo_pair_undo(struct kgem *kgem, struct kgem_bo *a, struct kgem_bo *b) { if (kgem->nexec > 2) return; if (kgem->nexec == 1) { if (a) kgem_bo_undo(kgem, a); if (b) kgem_bo_undo(kgem, b); return; } if (a == NULL || b == NULL) return; assert(a != b); if (a->exec == NULL || b->exec == NULL) return; DBG(("%s: only handles in batch, discarding last operations for handle=%d (index=%d) and handle=%d (index=%d)\n", __FUNCTION__, a->handle, a->proxy ? -1 : a->exec - kgem->exec, b->handle, b->proxy ? -1 : b->exec - kgem->exec)); assert(a->exec == &_kgem_dummy_exec || a->exec == &kgem->exec[0] || a->exec == &kgem->exec[1]); assert(a->handle == kgem->exec[0].handle || a->handle == kgem->exec[1].handle); assert(RQ(a->rq) == kgem->next_request); assert(b->exec == &_kgem_dummy_exec || b->exec == &kgem->exec[0] || b->exec == &kgem->exec[1]); assert(b->handle == kgem->exec[0].handle || b->handle == kgem->exec[1].handle); assert(RQ(b->rq) == kgem->next_request); a->refcnt++; b->refcnt++; kgem_reset(kgem); b->refcnt--; a->refcnt--; assert(kgem->nreloc == 0); assert(kgem->nexec == 0); assert(a->exec == NULL); assert(b->exec == NULL); } static void __kgem_bo_destroy(struct kgem *kgem, struct kgem_bo *bo) { DBG(("%s: handle=%d, size=%d\n", __FUNCTION__, bo->handle, bytes(bo))); assert(list_is_empty(&bo->list)); assert(list_is_empty(&bo->vma)); assert(bo->refcnt == 0); assert(bo->proxy == NULL); assert(bo->active_scanout == 0); assert_tiling(kgem, bo); bo->binding.offset = 0; if (DBG_NO_CACHE) goto destroy; if (bo->prime) goto destroy; if (bo->snoop && !bo->flush) { DBG(("%s: handle=%d is snooped\n", __FUNCTION__, bo->handle)); assert(bo->reusable); assert(list_is_empty(&bo->list)); if (bo->exec == NULL && bo->rq && !__kgem_busy(kgem, bo->handle)) __kgem_bo_clear_busy(bo); if (bo->rq == NULL) kgem_bo_move_to_snoop(kgem, bo); return; } if (!IS_USER_MAP(bo->map__cpu)) bo->flush = false; if (bo->scanout) { kgem_bo_move_to_scanout(kgem, bo); return; } if (bo->io) bo = kgem_bo_replace_io(bo); if (!bo->reusable) { DBG(("%s: handle=%d, not reusable\n", __FUNCTION__, bo->handle)); goto destroy; } assert(list_is_empty(&bo->vma)); assert(list_is_empty(&bo->list)); assert(bo->flush == false); assert(bo->snoop == false); assert(bo->io == false); assert(bo->scanout == false); assert_caching(kgem, bo); kgem_bo_undo(kgem, bo); assert(bo->refcnt == 0); if (bo->rq && bo->exec == NULL && !__kgem_busy(kgem, bo->handle)) __kgem_bo_clear_busy(bo); if (bo->rq) { struct list *cache; DBG(("%s: handle=%d -> active\n", __FUNCTION__, bo->handle)); if (bucket(bo) < NUM_CACHE_BUCKETS) cache = &kgem->active[bucket(bo)][bo->tiling]; else cache = &kgem->large; list_add(&bo->list, cache); return; } assert(bo->exec == NULL); assert(list_is_empty(&bo->request)); if (bo->map__cpu == NULL || bucket(bo) >= NUM_CACHE_BUCKETS) { if (!kgem->has_llc && bo->domain == DOMAIN_CPU) goto destroy; DBG(("%s: handle=%d, purged\n", __FUNCTION__, bo->handle)); } kgem_bo_move_to_inactive(kgem, bo); return; destroy: if (!bo->exec) kgem_bo_free(kgem, bo); } static void kgem_bo_unref(struct kgem *kgem, struct kgem_bo *bo) { assert(bo->refcnt); if (--bo->refcnt == 0) __kgem_bo_destroy(kgem, bo); } static void kgem_buffer_release(struct kgem *kgem, struct kgem_buffer *bo) { assert(bo->base.io); while (!list_is_empty(&bo->base.vma)) { struct kgem_bo *cached; cached = list_first_entry(&bo->base.vma, struct kgem_bo, vma); assert(cached->proxy == &bo->base); assert(cached != &bo->base); list_del(&cached->vma); assert(*(struct kgem_bo **)cached->map__gtt == cached); *(struct kgem_bo **)cached->map__gtt = NULL; cached->map__gtt = NULL; kgem_bo_destroy(kgem, cached); } } void kgem_retire__buffers(struct kgem *kgem) { while (!list_is_empty(&kgem->active_buffers)) { struct kgem_buffer *bo = list_last_entry(&kgem->active_buffers, struct kgem_buffer, base.list); DBG(("%s: handle=%d, busy? %d [%d]\n", __FUNCTION__, bo->base.handle, bo->base.rq != NULL, bo->base.exec != NULL)); assert(bo->base.exec == NULL || RQ(bo->base.rq) == kgem->next_request); if (bo->base.rq) break; DBG(("%s: releasing upload cache for handle=%d? %d\n", __FUNCTION__, bo->base.handle, !list_is_empty(&bo->base.vma))); list_del(&bo->base.list); kgem_buffer_release(kgem, bo); kgem_bo_unref(kgem, &bo->base); } } static bool kgem_retire__flushing(struct kgem *kgem) { struct kgem_bo *bo, *next; bool retired = false; list_for_each_entry_safe(bo, next, &kgem->flushing, request) { assert(RQ(bo->rq) == (void *)kgem); assert(bo->exec == NULL); if (__kgem_busy(kgem, bo->handle)) break; __kgem_bo_clear_busy(bo); if (bo->refcnt) continue; retired |= kgem_bo_move_to_cache(kgem, bo); } #if HAS_DEBUG_FULL { int count = 0; list_for_each_entry(bo, &kgem->flushing, request) count++; DBG(("%s: %d bo on flushing list, retired? %d\n", __FUNCTION__, count, retired)); } #endif kgem->need_retire |= !list_is_empty(&kgem->flushing); return retired; } static bool __kgem_bo_flush(struct kgem *kgem, struct kgem_bo *bo) { struct drm_i915_gem_busy busy; if (!bo->needs_flush) return false; bo->needs_flush = false; VG_CLEAR(busy); busy.handle = bo->handle; busy.busy = !kgem->wedged; (void)do_ioctl(kgem->fd, DRM_IOCTL_I915_GEM_BUSY, &busy); DBG(("%s: handle=%d, busy=%d, wedged=%d\n", __FUNCTION__, bo->handle, busy.busy, kgem->wedged)); if (busy.busy == 0) return false; DBG(("%s: moving %d to flushing\n", __FUNCTION__, bo->handle)); list_add(&bo->request, &kgem->flushing); bo->rq = MAKE_REQUEST(kgem, !!(busy.busy & ~0x1ffff)); bo->needs_flush = busy.busy & 0xffff; kgem->need_retire = true; return true; } static bool __kgem_retire_rq(struct kgem *kgem, struct kgem_request *rq) { bool retired = false; DBG(("%s: request %d complete\n", __FUNCTION__, rq->bo->handle)); assert(RQ(rq->bo->rq) == rq); assert(rq != (struct kgem_request *)kgem); assert(rq != &kgem->static_request); if (rq == kgem->fence[rq->ring]) kgem->fence[rq->ring] = NULL; while (!list_is_empty(&rq->buffers)) { struct kgem_bo *bo; bo = list_first_entry(&rq->buffers, struct kgem_bo, request); assert(RQ(bo->rq) == rq); assert(bo->exec == NULL); assert(bo->domain == DOMAIN_GPU || bo->domain == DOMAIN_NONE); list_del(&bo->request); if (unlikely(__kgem_bo_flush(kgem, bo))) { assert(bo != rq->bo); DBG(("%s: movied %d to flushing\n", __FUNCTION__, bo->handle)); continue; } bo->domain = DOMAIN_NONE; bo->rq = NULL; if (bo->refcnt) continue; retired |= kgem_bo_move_to_cache(kgem, bo); } assert(rq->bo->rq == NULL); assert(rq->bo->exec == NULL); assert(list_is_empty(&rq->bo->request)); assert(rq->bo->refcnt > 0); if (--rq->bo->refcnt == 0) { kgem_bo_move_to_inactive(kgem, rq->bo); retired = true; } __kgem_request_free(rq); return retired; } static bool kgem_retire__requests_ring(struct kgem *kgem, int ring) { bool retired = false; assert(ring < ARRAY_SIZE(kgem->requests)); while (!list_is_empty(&kgem->requests[ring])) { struct kgem_request *rq; DBG(("%s: retiring ring %d\n", __FUNCTION__, ring)); rq = list_first_entry(&kgem->requests[ring], struct kgem_request, list); assert(rq->ring == ring); assert(rq->bo); assert(RQ(rq->bo->rq) == rq); if (__kgem_busy(kgem, rq->bo->handle)) break; retired |= __kgem_retire_rq(kgem, rq); } #if HAS_DEBUG_FULL { struct kgem_bo *bo; int count = 0; list_for_each_entry(bo, &kgem->requests[ring], request) count++; bo = NULL; if (!list_is_empty(&kgem->requests[ring])) bo = list_first_entry(&kgem->requests[ring], struct kgem_request, list)->bo; DBG(("%s: ring=%d, %d outstanding requests, oldest=%d, retired? %d\n", __FUNCTION__, ring, count, bo ? bo->handle : 0, retired)); } #endif return retired; } static bool kgem_retire__requests(struct kgem *kgem) { bool retired = false; int n; for (n = 0; n < ARRAY_SIZE(kgem->requests); n++) { retired |= kgem_retire__requests_ring(kgem, n); kgem->need_retire |= !list_is_empty(&kgem->requests[n]); } return retired; } bool kgem_retire(struct kgem *kgem) { bool retired = false; DBG(("%s, need_retire?=%d\n", __FUNCTION__, kgem->need_retire)); kgem->need_retire = false; retired |= kgem_retire__flushing(kgem); retired |= kgem_retire__requests(kgem); DBG(("%s -- retired=%d, need_retire=%d\n", __FUNCTION__, retired, kgem->need_retire)); kgem->retire(kgem); return retired; } bool __kgem_ring_is_idle(struct kgem *kgem, int ring) { struct kgem_request *rq; assert(ring < ARRAY_SIZE(kgem->requests)); assert(!list_is_empty(&kgem->requests[ring])); rq = kgem->fence[ring]; if (rq) { struct kgem_request *tmp; if (__kgem_busy(kgem, rq->bo->handle)) { DBG(("%s: last fence handle=%d still busy\n", __FUNCTION__, rq->bo->handle)); return false; } do { tmp = list_first_entry(&kgem->requests[ring], struct kgem_request, list); assert(tmp->ring == ring); __kgem_retire_rq(kgem, tmp); } while (tmp != rq); assert(kgem->fence[ring] == NULL); if (list_is_empty(&kgem->requests[ring])) return true; } rq = list_last_entry(&kgem->requests[ring], struct kgem_request, list); assert(rq->ring == ring); assert(rq->bo); assert(RQ(rq->bo->rq) == rq); if (__kgem_busy(kgem, rq->bo->handle)) { DBG(("%s: last requests handle=%d still busy\n", __FUNCTION__, rq->bo->handle)); kgem->fence[ring] = rq; return false; } DBG(("%s: ring=%d idle (handle=%d)\n", __FUNCTION__, ring, rq->bo->handle)); while (!list_is_empty(&kgem->requests[ring])) { rq = list_first_entry(&kgem->requests[ring], struct kgem_request, list); assert(rq->ring == ring); __kgem_retire_rq(kgem, rq); } return true; } bool __kgem_retire_requests_upto(struct kgem *kgem, struct kgem_bo *bo) { struct kgem_request * const rq = RQ(bo->rq), *tmp; struct list *requests = &kgem->requests[rq->ring]; DBG(("%s(handle=%d, ring=%d)\n", __FUNCTION__, bo->handle, rq->ring)); assert(rq != &kgem->static_request); if (rq == (struct kgem_request *)kgem) { __kgem_bo_clear_busy(bo); return false; } assert(rq->ring < ARRAY_SIZE(kgem->requests)); do { tmp = list_first_entry(requests, struct kgem_request, list); assert(tmp->ring == rq->ring); __kgem_retire_rq(kgem, tmp); } while (tmp != rq); assert(bo->needs_flush || bo->rq == NULL); assert(bo->needs_flush || list_is_empty(&bo->request)); assert(bo->needs_flush || bo->domain == DOMAIN_NONE); return bo->rq; } #if 0 static void kgem_commit__check_reloc(struct kgem *kgem) { struct kgem_request *rq = kgem->next_request; struct kgem_bo *bo; bool has_64bit = kgem->gen >= 0100; int i; for (i = 0; i < kgem->nreloc; i++) { list_for_each_entry(bo, &rq->buffers, request) { if (bo->target_handle == kgem->reloc[i].target_handle) { uint64_t value = 0; gem_read(kgem->fd, rq->bo->handle, &value, kgem->reloc[i].offset, has_64bit ? 8 : 4); assert(bo->exec->offset == -1 || value == bo->exec->offset + (int)kgem->reloc[i].delta); break; } } } } #else #define kgem_commit__check_reloc(kgem) #endif #ifndef NDEBUG static void kgem_commit__check_buffers(struct kgem *kgem) { struct kgem_buffer *bo; list_for_each_entry(bo, &kgem->active_buffers, base.list) assert(bo->base.exec == NULL); } #else #define kgem_commit__check_buffers(kgem) #endif static void kgem_commit(struct kgem *kgem) { struct kgem_request *rq = kgem->next_request; struct kgem_bo *bo, *next; kgem_commit__check_reloc(kgem); list_for_each_entry_safe(bo, next, &rq->buffers, request) { assert(next->request.prev == &bo->request); DBG(("%s: release handle=%d (proxy? %d), dirty? %d flush? %d, snoop? %d -> offset=%x\n", __FUNCTION__, bo->handle, bo->proxy != NULL, bo->gpu_dirty, bo->needs_flush, bo->snoop, (unsigned)bo->exec->offset)); assert(bo->exec); assert(bo->proxy == NULL || bo->exec == &_kgem_dummy_exec); assert(RQ(bo->rq) == rq || (RQ(bo->proxy->rq) == rq)); bo->presumed_offset = bo->exec->offset; bo->exec = NULL; bo->target_handle = -1; if (!bo->refcnt && !bo->reusable) { assert(!bo->snoop); assert(!bo->proxy); kgem_bo_free(kgem, bo); continue; } bo->binding.offset = 0; bo->domain = DOMAIN_GPU; bo->gpu_dirty = false; bo->gtt_dirty = false; if (bo->proxy) { /* proxies are not used for domain tracking */ __kgem_bo_clear_busy(bo); } kgem->scanout_busy |= bo->scanout && bo->needs_flush; } if (rq == &kgem->static_request) { struct drm_i915_gem_set_domain set_domain; DBG(("%s: syncing due to allocation failure\n", __FUNCTION__)); VG_CLEAR(set_domain); set_domain.handle = rq->bo->handle; set_domain.read_domains = I915_GEM_DOMAIN_GTT; set_domain.write_domain = I915_GEM_DOMAIN_GTT; if (do_ioctl(kgem->fd, DRM_IOCTL_I915_GEM_SET_DOMAIN, &set_domain)) { DBG(("%s: sync: GPU hang detected\n", __FUNCTION__)); kgem_throttle(kgem); } while (!list_is_empty(&rq->buffers)) { bo = list_first_entry(&rq->buffers, struct kgem_bo, request); assert(RQ(bo->rq) == rq); assert(bo->exec == NULL); assert(bo->domain == DOMAIN_GPU); list_del(&bo->request); bo->domain = DOMAIN_NONE; bo->rq = NULL; if (bo->refcnt == 0) _kgem_bo_destroy(kgem, bo); } kgem_retire(kgem); assert(list_is_empty(&rq->buffers)); assert(rq->bo->map__gtt == NULL); assert(rq->bo->map__wc == NULL); assert(rq->bo->map__cpu == NULL); gem_close(kgem->fd, rq->bo->handle); kgem_cleanup_cache(kgem); } else { assert(rq != (struct kgem_request *)kgem); assert(rq->ring < ARRAY_SIZE(kgem->requests)); assert(rq->bo); list_add_tail(&rq->list, &kgem->requests[rq->ring]); kgem->need_throttle = kgem->need_retire = 1; if (kgem->fence[rq->ring] == NULL && __kgem_busy(kgem, rq->bo->handle)) kgem->fence[rq->ring] = rq; } kgem->next_request = NULL; kgem_commit__check_buffers(kgem); } static void kgem_close_list(struct kgem *kgem, struct list *head) { while (!list_is_empty(head)) kgem_bo_free(kgem, list_first_entry(head, struct kgem_bo, list)); } static void kgem_close_inactive(struct kgem *kgem) { unsigned int i; for (i = 0; i < ARRAY_SIZE(kgem->inactive); i++) { kgem_close_list(kgem, &kgem->inactive[i]); assert(list_is_empty(&kgem->inactive[i])); } } static void kgem_finish_buffers(struct kgem *kgem) { struct kgem_buffer *bo, *next; list_for_each_entry_safe(bo, next, &kgem->batch_buffers, base.list) { DBG(("%s: buffer handle=%d, used=%d, exec?=%d, write=%d, mmapped=%s, refcnt=%d\n", __FUNCTION__, bo->base.handle, bo->used, bo->base.exec!=NULL, bo->write, bo->mmapped == MMAPPED_CPU ? "cpu" : bo->mmapped == MMAPPED_GTT ? "gtt" : "no", bo->base.refcnt)); assert(next->base.list.prev == &bo->base.list); assert(bo->base.io); assert(bo->base.refcnt >= 1); if (bo->base.refcnt > 1 && !bo->base.exec) { DBG(("%s: skipping unattached handle=%d, used=%d, refcnt=%d\n", __FUNCTION__, bo->base.handle, bo->used, bo->base.refcnt)); continue; } if (!bo->write) { assert(bo->base.exec || bo->base.refcnt > 1); goto decouple; } if (bo->mmapped) { uint32_t used; assert(!bo->need_io); used = ALIGN(bo->used, PAGE_SIZE); if (!DBG_NO_UPLOAD_ACTIVE && used + PAGE_SIZE <= bytes(&bo->base) && (kgem->has_llc || bo->mmapped == MMAPPED_GTT || bo->base.snoop)) { DBG(("%s: retaining upload buffer (%d/%d): used=%d, refcnt=%d\n", __FUNCTION__, bo->used, bytes(&bo->base), used, bo->base.refcnt)); bo->used = used; list_move(&bo->base.list, &kgem->active_buffers); kgem->need_retire = true; continue; } DBG(("%s: discarding mmapped buffer, used=%d, map type=%d\n", __FUNCTION__, bo->used, bo->mmapped)); goto decouple; } if (!bo->used || !bo->base.exec) { /* Unless we replace the handle in the execbuffer, * then this bo will become active. So decouple it * from the buffer list and track it in the normal * manner. */ goto decouple; } assert(bo->need_io); assert(bo->base.rq == MAKE_REQUEST(kgem->next_request, kgem->ring)); assert(bo->base.domain != DOMAIN_GPU); if (bo->base.refcnt == 1 && bo->base.size.pages.count > 1 && bo->used < bytes(&bo->base) / 2) { struct kgem_bo *shrink; unsigned alloc = NUM_PAGES(bo->used); shrink = search_snoop_cache(kgem, alloc, CREATE_INACTIVE | CREATE_NO_RETIRE); if (shrink) { void *map; int n; DBG(("%s: used=%d, shrinking %d to %d, handle %d to %d\n", __FUNCTION__, bo->used, bytes(&bo->base), bytes(shrink), bo->base.handle, shrink->handle)); assert(bo->used <= bytes(shrink)); map = kgem_bo_map__cpu(kgem, shrink); if (map) { memcpy(map, bo->mem, bo->used); shrink->target_handle = kgem->has_handle_lut ? bo->base.target_handle : shrink->handle; for (n = 0; n < kgem->nreloc; n++) { if (kgem->reloc[n].target_handle == bo->base.target_handle) { uint64_t addr = (int)kgem->reloc[n].delta + shrink->presumed_offset; kgem->batch[kgem->reloc[n].offset/sizeof(kgem->batch[0])] = addr; if (kgem->gen >= 0100) kgem->batch[kgem->reloc[n].offset/sizeof(kgem->batch[0]) + 1] = addr >> 32; kgem->reloc[n].target_handle = shrink->target_handle; kgem->reloc[n].presumed_offset = shrink->presumed_offset; } } bo->base.exec->handle = shrink->handle; bo->base.exec->offset = shrink->presumed_offset; shrink->exec = bo->base.exec; shrink->rq = bo->base.rq; list_replace(&bo->base.request, &shrink->request); list_init(&bo->base.request); shrink->needs_flush = bo->base.gpu_dirty; bo->base.exec = NULL; bo->base.rq = NULL; bo->base.gpu_dirty = false; bo->base.needs_flush = false; bo->used = 0; goto decouple; } __kgem_bo_destroy(kgem, shrink); } shrink = search_linear_cache(kgem, alloc, CREATE_INACTIVE | CREATE_NO_RETIRE); if (shrink) { int n; DBG(("%s: used=%d, shrinking %d to %d, handle %d to %d\n", __FUNCTION__, bo->used, bytes(&bo->base), bytes(shrink), bo->base.handle, shrink->handle)); assert(bo->used <= bytes(shrink)); if (gem_write__cachealigned(kgem->fd, shrink->handle, 0, bo->used, bo->mem) == 0) { shrink->target_handle = kgem->has_handle_lut ? bo->base.target_handle : shrink->handle; for (n = 0; n < kgem->nreloc; n++) { if (kgem->reloc[n].target_handle == bo->base.target_handle) { uint64_t addr = (int)kgem->reloc[n].delta + shrink->presumed_offset; kgem->batch[kgem->reloc[n].offset/sizeof(kgem->batch[0])] = addr; if (kgem->gen >= 0100) kgem->batch[kgem->reloc[n].offset/sizeof(kgem->batch[0]) + 1] = addr >> 32; kgem->reloc[n].target_handle = shrink->target_handle; kgem->reloc[n].presumed_offset = shrink->presumed_offset; } } bo->base.exec->handle = shrink->handle; bo->base.exec->offset = shrink->presumed_offset; shrink->exec = bo->base.exec; shrink->rq = bo->base.rq; list_replace(&bo->base.request, &shrink->request); list_init(&bo->base.request); shrink->needs_flush = bo->base.gpu_dirty; bo->base.exec = NULL; bo->base.rq = NULL; bo->base.gpu_dirty = false; bo->base.needs_flush = false; bo->used = 0; goto decouple; } __kgem_bo_destroy(kgem, shrink); } } DBG(("%s: handle=%d, uploading %d/%d\n", __FUNCTION__, bo->base.handle, bo->used, bytes(&bo->base))); ASSERT_IDLE(kgem, bo->base.handle); assert(bo->used <= bytes(&bo->base)); gem_write__cachealigned(kgem->fd, bo->base.handle, 0, bo->used, bo->mem); bo->need_io = 0; decouple: DBG(("%s: releasing handle=%d\n", __FUNCTION__, bo->base.handle)); list_del(&bo->base.list); kgem_bo_unref(kgem, &bo->base); } } static void kgem_cleanup(struct kgem *kgem) { int n; for (n = 0; n < ARRAY_SIZE(kgem->requests); n++) { while (!list_is_empty(&kgem->requests[n])) { struct kgem_request *rq; rq = list_first_entry(&kgem->requests[n], struct kgem_request, list); assert(rq->ring == n); while (!list_is_empty(&rq->buffers)) { struct kgem_bo *bo; bo = list_first_entry(&rq->buffers, struct kgem_bo, request); bo->exec = NULL; bo->gpu_dirty = false; __kgem_bo_clear_busy(bo); if (bo->refcnt == 0) kgem_bo_free(kgem, bo); } if (--rq->bo->refcnt == 0) kgem_bo_free(kgem, rq->bo); __kgem_request_free(rq); } } kgem_close_inactive(kgem); } static int kgem_batch_write(struct kgem *kgem, struct kgem_bo *bo, uint32_t size) { char *ptr; int ret; assert(bo->exec == NULL); assert(bo->rq == NULL); assert(!__kgem_busy(kgem, bo->handle)); #if DBG_NO_EXEC { uint32_t batch[] = { MI_BATCH_BUFFER_END, 0}; return gem_write(kgem->fd, bo->handle, 0, sizeof(batch), batch); } #endif assert(!bo->scanout); retry: ptr = NULL; if (bo->domain == DOMAIN_CPU || kgem->has_llc) { ptr = bo->map__cpu; if (ptr == NULL) ptr = __kgem_bo_map__cpu(kgem, bo); } else if (kgem->has_wc_mmap) { ptr = bo->map__wc; if (ptr == NULL) ptr = __kgem_bo_map__wc(kgem, bo); } if (ptr) { memcpy(ptr, kgem->batch, sizeof(uint32_t)*kgem->nbatch); if (kgem->surface != kgem->batch_size) { ret = PAGE_ALIGN(sizeof(uint32_t) * kgem->batch_size); ret -= sizeof(uint32_t) * kgem->surface; ptr += size - ret; memcpy(ptr, kgem->batch + kgem->surface, (kgem->batch_size - kgem->surface)*sizeof(uint32_t)); } return 0; } /* If there is no surface data, just upload the batch */ if (kgem->surface == kgem->batch_size) { if ((ret = gem_write__cachealigned(kgem->fd, bo->handle, 0, sizeof(uint32_t)*kgem->nbatch, kgem->batch)) == 0) return 0; goto expire; } /* Are the batch pages conjoint with the surface pages? */ if (kgem->surface < kgem->nbatch + PAGE_SIZE/sizeof(uint32_t)) { assert(size == PAGE_ALIGN(kgem->batch_size*sizeof(uint32_t))); if ((ret = gem_write__cachealigned(kgem->fd, bo->handle, 0, kgem->batch_size*sizeof(uint32_t), kgem->batch)) == 0) return 0; goto expire; } /* Disjoint surface/batch, upload separately */ if ((ret = gem_write__cachealigned(kgem->fd, bo->handle, 0, sizeof(uint32_t)*kgem->nbatch, kgem->batch))) goto expire; ret = PAGE_ALIGN(sizeof(uint32_t) * kgem->batch_size); ret -= sizeof(uint32_t) * kgem->surface; assert(size-ret >= kgem->nbatch*sizeof(uint32_t)); if (gem_write(kgem->fd, bo->handle, size - ret, (kgem->batch_size - kgem->surface)*sizeof(uint32_t), kgem->batch + kgem->surface)) goto expire; return 0; expire: assert(ret != EINVAL); (void)__kgem_throttle_retire(kgem, 0); if (kgem_expire_cache(kgem)) goto retry; if (kgem_cleanup_cache(kgem)) goto retry; ERR(("%s: failed to write batch (handle=%d): %d\n", __FUNCTION__, bo->handle, -ret)); return ret; } void kgem_reset(struct kgem *kgem) { if (kgem->next_request) { struct kgem_request *rq = kgem->next_request; while (!list_is_empty(&rq->buffers)) { struct kgem_bo *bo = list_first_entry(&rq->buffers, struct kgem_bo, request); list_del(&bo->request); assert(RQ(bo->rq) == rq); bo->binding.offset = 0; bo->exec = NULL; bo->target_handle = -1; bo->gpu_dirty = false; if (bo->needs_flush && __kgem_busy(kgem, bo->handle)) { assert(bo->domain == DOMAIN_GPU || bo->domain == DOMAIN_NONE); list_add(&bo->request, &kgem->flushing); bo->rq = (void *)kgem; kgem->need_retire = true; } else __kgem_bo_clear_busy(bo); if (bo->refcnt || bo->rq) continue; kgem_bo_move_to_cache(kgem, bo); } if (rq != &kgem->static_request) { list_init(&rq->list); __kgem_request_free(rq); } } kgem->nfence = 0; kgem->nexec = 0; kgem->nreloc = 0; kgem->nreloc__self = 0; kgem->aperture = 0; kgem->aperture_fenced = 0; kgem->aperture_max_fence = 0; kgem->nbatch = 0; kgem->surface = kgem->batch_size; kgem->mode = KGEM_NONE; kgem->needs_semaphore = false; kgem->needs_reservation = false; kgem->flush = 0; kgem->batch_flags = kgem->batch_flags_base; assert(kgem->batch); kgem->next_request = __kgem_request_alloc(kgem); kgem_sna_reset(kgem); } static int compact_batch_surface(struct kgem *kgem, int *shrink) { int size, n; if (!kgem->has_relaxed_delta) return kgem->batch_size * sizeof(uint32_t); /* See if we can pack the contents into one or two pages */ n = ALIGN(kgem->batch_size, 1024); size = n - kgem->surface + kgem->nbatch; size = ALIGN(size, 1024); *shrink = (n - size) * sizeof(uint32_t); return size * sizeof(uint32_t); } static struct kgem_bo *first_available(struct kgem *kgem, struct list *list) { struct kgem_bo *bo; list_for_each_entry(bo, list, list) { assert(bo->refcnt > 0); if (bo->rq) { assert(RQ(bo->rq)->bo == bo); if (__kgem_busy(kgem, bo->handle)) break; __kgem_retire_rq(kgem, RQ(bo->rq)); assert(bo->rq == NULL); } if (bo->refcnt > 1) continue; list_move_tail(&bo->list, list); return kgem_bo_reference(bo); } return NULL; } static struct kgem_bo * kgem_create_batch(struct kgem *kgem) { struct kgem_bo *bo; int size, shrink = 0; #if !DBG_NO_SHRINK_BATCHES if (kgem->surface != kgem->batch_size) size = compact_batch_surface(kgem, &shrink); else size = kgem->nbatch * sizeof(uint32_t); if (size <= 4096) { bo = first_available(kgem, &kgem->pinned_batches[0]); if (bo) goto write; } if (size <= 16384) { bo = first_available(kgem, &kgem->pinned_batches[1]); if (bo) goto write; } if (kgem->gen == 020) { bo = kgem_create_linear(kgem, size, CREATE_CACHED | CREATE_TEMPORARY); if (bo) goto write; /* Nothing available for reuse, rely on the kernel wa */ if (kgem->has_pinned_batches) { bo = kgem_create_linear(kgem, size, CREATE_CACHED | CREATE_TEMPORARY); if (bo) { kgem->batch_flags &= ~LOCAL_I915_EXEC_IS_PINNED; goto write; } } if (size < 16384) { bo = list_first_entry(&kgem->pinned_batches[size > 4096], struct kgem_bo, list); list_move_tail(&bo->list, &kgem->pinned_batches[size > 4096]); DBG(("%s: syncing due to busy batches\n", __FUNCTION__)); if (kgem_bo_wait(kgem, bo)) return NULL; kgem_retire(kgem); assert(bo->rq == NULL); bo = kgem_bo_reference(bo); goto write; } } #else if (kgem->surface != kgem->batch_size) size = kgem->batch_size * sizeof(uint32_t); else size = kgem->nbatch * sizeof(uint32_t); #endif if (!kgem->batch_bo || !kgem->has_llc) { bo = kgem_create_linear(kgem, size, CREATE_NO_THROTTLE); if (bo) { write: kgem_fixup_relocs(kgem, bo, shrink); if (kgem_batch_write(kgem, bo, size)) { kgem_bo_destroy(kgem, bo); return NULL; } return bo; } } return kgem_new_batch(kgem); } #if !NDEBUG static bool dump_file(const char *path) { FILE *file; size_t len = 0; char *line = NULL; file = fopen(path, "r"); if (file == NULL) return false; while (getline(&line, &len, file) != -1) ErrorF("%s", line); free(line); fclose(file); return true; } static void dump_debugfs(struct kgem *kgem, const char *name) { char path[80]; int minor = kgem_get_minor(kgem); if (minor < 0) return; sprintf(path, "/sys/kernel/debug/dri/%d/%s", minor, name); if (dump_file(path)) return; sprintf(path, "/debug/dri/%d/%s", minor, name); if (dump_file(path)) return; } static void dump_gtt_info(struct kgem *kgem) { dump_debugfs(kgem, "i915_gem_gtt"); } static void dump_fence_regs(struct kgem *kgem) { dump_debugfs(kgem, "i915_gem_fence_regs"); } #endif static int do_execbuf(struct kgem *kgem, struct drm_i915_gem_execbuffer2 *execbuf) { int ret; retry: ret = do_ioctl(kgem->fd, DRM_IOCTL_I915_GEM_EXECBUFFER2, execbuf); if (ret == 0) return 0; DBG(("%s: failed ret=%d, throttling and discarding cache\n", __FUNCTION__, ret)); (void)__kgem_throttle_retire(kgem, 0); if (kgem_expire_cache(kgem)) goto retry; if (kgem_cleanup_cache(kgem)) goto retry; /* last gasp */ ret = do_ioctl(kgem->fd, DRM_IOCTL_I915_GEM_EXECBUFFER2, execbuf); if (ret != -ENOSPC) return ret; /* One final trick up our sleeve for when we run out of space. * We turn everything off to free up our pinned framebuffers, * sprites and cursors, and try just one more time. */ xf86DrvMsg(kgem_get_screen_index(kgem), X_WARNING, "Failed to submit rendering commands, trying again with outputs disabled.\n"); if (sna_mode_disable(__to_sna(kgem))) { kgem_cleanup_cache(kgem); ret = do_ioctl(kgem->fd, DRM_IOCTL_I915_GEM_EXECBUFFER2, execbuf); DBG(("%s: last_gasp ret=%d\n", __FUNCTION__, ret)); sna_mode_enable(__to_sna(kgem)); } return ret; } void _kgem_submit(struct kgem *kgem) { struct kgem_request *rq; uint32_t batch_end; int i, ret; assert(!DBG_NO_HW); assert(!kgem->wedged); assert(kgem->nbatch); assert(kgem->nbatch <= KGEM_BATCH_SIZE(kgem)); assert(kgem->nbatch <= kgem->surface); batch_end = kgem_end_batch(kgem); kgem_sna_flush(kgem); DBG(("batch[%d/%d, flags=%x]: %d %d %d %d, nreloc=%d, nexec=%d, nfence=%d, aperture=%d [fenced=%d]\n", kgem->mode, kgem->ring, kgem->batch_flags, batch_end, kgem->nbatch, kgem->surface, kgem->batch_size, kgem->nreloc, kgem->nexec, kgem->nfence, kgem->aperture, kgem->aperture_fenced)); assert(kgem->nbatch <= kgem->batch_size); assert(kgem->nbatch <= kgem->surface); assert(kgem->nreloc <= ARRAY_SIZE(kgem->reloc)); assert(kgem->nexec < ARRAY_SIZE(kgem->exec)); assert(kgem->nfence <= kgem->fence_max); kgem_finish_buffers(kgem); #if SHOW_BATCH_BEFORE __kgem_batch_debug(kgem, batch_end); #endif rq = kgem->next_request; assert(rq->bo == NULL); rq->bo = kgem_create_batch(kgem); if (rq->bo) { struct drm_i915_gem_execbuffer2 execbuf; assert(!rq->bo->needs_flush); i = kgem->nexec++; kgem->exec[i].handle = rq->bo->handle; kgem->exec[i].relocation_count = kgem->nreloc; kgem->exec[i].relocs_ptr = (uintptr_t)kgem->reloc; kgem->exec[i].alignment = 0; kgem->exec[i].offset = rq->bo->presumed_offset; /* Make sure the kernel releases any fence, ignored if gen4+ */ kgem->exec[i].flags = EXEC_OBJECT_NEEDS_FENCE; kgem->exec[i].rsvd1 = 0; kgem->exec[i].rsvd2 = 0; rq->bo->exec = &kgem->exec[i]; rq->bo->rq = MAKE_REQUEST(rq, kgem->ring); /* useful sanity check */ list_add(&rq->bo->request, &rq->buffers); rq->ring = kgem->ring == KGEM_BLT; memset(&execbuf, 0, sizeof(execbuf)); execbuf.buffers_ptr = (uintptr_t)kgem->exec; execbuf.buffer_count = kgem->nexec; if (kgem->gen < 030) execbuf.batch_len = batch_end*sizeof(uint32_t); execbuf.flags = kgem->ring | kgem->batch_flags; if (DBG_DUMP) { int fd = open("/tmp/i915-batchbuffers.dump", O_WRONLY | O_CREAT | O_APPEND, 0666); if (fd != -1) { ret = write(fd, kgem->batch, batch_end*sizeof(uint32_t)); fd = close(fd); } } ret = do_execbuf(kgem, &execbuf); } else ret = -ENOMEM; if (ret < 0) { kgem_throttle(kgem); if (!kgem->wedged) { xf86DrvMsg(kgem_get_screen_index(kgem), X_ERROR, "Failed to submit rendering commands (%s), disabling acceleration.\n", strerror(-ret)); __kgem_set_wedged(kgem); } #if !NDEBUG ErrorF("batch[%d/%d]: %d %d %d, nreloc=%d, nexec=%d, nfence=%d, aperture=%d, fenced=%d, high=%d,%d: errno=%d\n", kgem->mode, kgem->ring, batch_end, kgem->nbatch, kgem->surface, kgem->nreloc, kgem->nexec, kgem->nfence, kgem->aperture, kgem->aperture_fenced, kgem->aperture_high, kgem->aperture_total, -ret); for (i = 0; i < kgem->nexec; i++) { struct kgem_bo *bo, *found = NULL; list_for_each_entry(bo, &kgem->next_request->buffers, request) { if (bo->handle == kgem->exec[i].handle) { found = bo; break; } } ErrorF("exec[%d] = handle:%d, presumed offset: %x, size: %d, tiling %d, fenced %d, snooped %d, deleted %d\n", i, kgem->exec[i].handle, (int)kgem->exec[i].offset, found ? kgem_bo_size(found) : -1, found ? found->tiling : -1, (int)(kgem->exec[i].flags & EXEC_OBJECT_NEEDS_FENCE), found ? found->snoop : -1, found ? found->purged : -1); } for (i = 0; i < kgem->nreloc; i++) { ErrorF("reloc[%d] = pos:%d, target:%d, delta:%d, read:%x, write:%x, offset:%x\n", i, (int)kgem->reloc[i].offset, kgem->reloc[i].target_handle, kgem->reloc[i].delta, kgem->reloc[i].read_domains, kgem->reloc[i].write_domain, (int)kgem->reloc[i].presumed_offset); } { struct drm_i915_gem_get_aperture aperture; if (do_ioctl(kgem->fd, DRM_IOCTL_I915_GEM_GET_APERTURE, &aperture) == 0) ErrorF("Aperture size %lld, available %lld\n", (long long)aperture.aper_size, (long long)aperture.aper_available_size); } if (ret == -ENOSPC) dump_gtt_info(kgem); if (ret == -EDEADLK) dump_fence_regs(kgem); if (DEBUG_SYNC) { int fd = open("/tmp/batchbuffer", O_WRONLY | O_CREAT | O_APPEND, 0666); if (fd != -1) { int ignored = write(fd, kgem->batch, batch_end*sizeof(uint32_t)); assert(ignored == batch_end*sizeof(uint32_t)); close(fd); } FatalError("SNA: failed to submit batchbuffer, errno=%d\n", -ret); } #endif } else { if (DEBUG_SYNC) { struct drm_i915_gem_set_domain set_domain; VG_CLEAR(set_domain); set_domain.handle = rq->bo->handle; set_domain.read_domains = I915_GEM_DOMAIN_GTT; set_domain.write_domain = I915_GEM_DOMAIN_GTT; ret = do_ioctl(kgem->fd, DRM_IOCTL_I915_GEM_SET_DOMAIN, &set_domain); } #if SHOW_BATCH_AFTER if (gem_read(kgem->fd, rq->bo->handle, kgem->batch, 0, batch_end*sizeof(uint32_t)) == 0) __kgem_batch_debug(kgem, batch_end); #endif kgem_commit(kgem); } if (unlikely(kgem->wedged)) kgem_cleanup(kgem); kgem_reset(kgem); assert(kgem->next_request != NULL); } void kgem_throttle(struct kgem *kgem) { if (unlikely(kgem->wedged)) return; if (__kgem_throttle(kgem, true)) { xf86DrvMsg(kgem_get_screen_index(kgem), X_ERROR, "Detected a hung GPU, disabling acceleration.\n"); __kgem_set_wedged(kgem); kgem->need_throttle = false; } } int kgem_is_wedged(struct kgem *kgem) { return __kgem_throttle(kgem, true); } static void kgem_purge_cache(struct kgem *kgem) { struct kgem_bo *bo, *next; int i; for (i = 0; i < ARRAY_SIZE(kgem->inactive); i++) { list_for_each_entry_safe(bo, next, &kgem->inactive[i], list) { if (!kgem_bo_is_retained(kgem, bo)) { DBG(("%s: purging %d\n", __FUNCTION__, bo->handle)); kgem_bo_free(kgem, bo); } } } kgem->need_purge = false; } void kgem_clean_scanout_cache(struct kgem *kgem) { while (!list_is_empty(&kgem->scanout)) { struct kgem_bo *bo; bo = list_first_entry(&kgem->scanout, struct kgem_bo, list); assert(bo->scanout); assert(!bo->refcnt); assert(!bo->prime); assert(bo->proxy == NULL); if (bo->exec || __kgem_busy(kgem, bo->handle)) break; DBG(("%s: handle=%d, fb=%d (reusable=%d)\n", __FUNCTION__, bo->handle, bo->delta, bo->reusable)); list_del(&bo->list); kgem_bo_rmfb(kgem, bo); bo->scanout = false; if (!bo->purged) { bo->reusable = true; if (kgem->has_llc && !gem_set_caching(kgem->fd, bo->handle, SNOOPED)) bo->reusable = false; } __kgem_bo_destroy(kgem, bo); } } void kgem_clean_large_cache(struct kgem *kgem) { while (!list_is_empty(&kgem->large_inactive)) { kgem_bo_free(kgem, list_first_entry(&kgem->large_inactive, struct kgem_bo, list)); } } bool kgem_expire_cache(struct kgem *kgem) { time_t now, expire; struct kgem_bo *bo; unsigned int size = 0, count = 0; bool idle; unsigned int i; if (!time(&now)) return false; while (__kgem_freed_bo) { bo = __kgem_freed_bo; __kgem_freed_bo = *(struct kgem_bo **)bo; free(bo); } while (__kgem_freed_request) { struct kgem_request *rq = __kgem_freed_request; __kgem_freed_request = *(struct kgem_request **)rq; free(rq); } kgem_clean_large_cache(kgem); if (__to_sna(kgem)->scrn->vtSema) kgem_clean_scanout_cache(kgem); expire = 0; list_for_each_entry(bo, &kgem->snoop, list) { if (bo->delta) { expire = now - MAX_INACTIVE_TIME/2; break; } assert(now); bo->delta = now; } if (expire) { while (!list_is_empty(&kgem->snoop)) { bo = list_last_entry(&kgem->snoop, struct kgem_bo, list); if (bo->delta > expire) break; kgem_bo_free(kgem, bo); } } #ifdef DEBUG_MEMORY { long snoop_size = 0; int snoop_count = 0; list_for_each_entry(bo, &kgem->snoop, list) snoop_count++, snoop_size += bytes(bo); DBG(("%s: still allocated %d bo, %ld bytes, in snoop cache\n", __FUNCTION__, snoop_count, snoop_size)); } #endif kgem_retire(kgem); if (unlikely(kgem->wedged)) kgem_cleanup(kgem); kgem->expire(kgem); if (kgem->need_purge) kgem_purge_cache(kgem); if (kgem->need_retire) kgem_retire(kgem); expire = 0; idle = true; for (i = 0; i < ARRAY_SIZE(kgem->inactive); i++) { idle &= list_is_empty(&kgem->inactive[i]); list_for_each_entry(bo, &kgem->inactive[i], list) { if (bo->delta) { expire = now - MAX_INACTIVE_TIME; break; } assert(now); kgem_bo_set_purgeable(kgem, bo); bo->delta = now; } } if (expire == 0) { DBG(("%s: idle? %d\n", __FUNCTION__, idle)); kgem->need_expire = !idle; return false; } idle = true; for (i = 0; i < ARRAY_SIZE(kgem->inactive); i++) { struct list preserve; list_init(&preserve); while (!list_is_empty(&kgem->inactive[i])) { bo = list_last_entry(&kgem->inactive[i], struct kgem_bo, list); if (bo->delta > expire) { idle = false; break; } if (bo->map__cpu && bo->delta + MAP_PRESERVE_TIME > expire) { idle = false; list_move_tail(&bo->list, &preserve); } else { count++; size += bytes(bo); kgem_bo_free(kgem, bo); DBG(("%s: expiring handle=%d\n", __FUNCTION__, bo->handle)); } } list_splice_tail(&preserve, &kgem->inactive[i]); } #ifdef DEBUG_MEMORY { long inactive_size = 0; int inactive_count = 0; for (i = 0; i < ARRAY_SIZE(kgem->inactive); i++) list_for_each_entry(bo, &kgem->inactive[i], list) inactive_count++, inactive_size += bytes(bo); DBG(("%s: still allocated %d bo, %ld bytes, in inactive cache\n", __FUNCTION__, inactive_count, inactive_size)); } #endif DBG(("%s: expired %d objects, %d bytes, idle? %d\n", __FUNCTION__, count, size, idle)); kgem->need_expire = !idle; return count; (void)count; (void)size; } bool kgem_cleanup_cache(struct kgem *kgem) { unsigned int i; int n; DBG(("%s\n", __FUNCTION__)); /* sync to the most recent request */ for (n = 0; n < ARRAY_SIZE(kgem->requests); n++) { if (!list_is_empty(&kgem->requests[n])) { struct kgem_request *rq; rq = list_last_entry(&kgem->requests[n], struct kgem_request, list); DBG(("%s: sync on cleanup\n", __FUNCTION__)); assert(rq->ring == n); assert(rq->bo); assert(RQ(rq->bo->rq) == rq); kgem_bo_wait(kgem, rq->bo); } assert(list_is_empty(&kgem->requests[n])); } kgem_retire(kgem); kgem_cleanup(kgem); DBG(("%s: need_expire?=%d\n", __FUNCTION__, kgem->need_expire)); if (!kgem->need_expire) return false; for (i = 0; i < ARRAY_SIZE(kgem->inactive); i++) { while (!list_is_empty(&kgem->inactive[i])) kgem_bo_free(kgem, list_last_entry(&kgem->inactive[i], struct kgem_bo, list)); } kgem_clean_large_cache(kgem); kgem_clean_scanout_cache(kgem); while (!list_is_empty(&kgem->snoop)) kgem_bo_free(kgem, list_last_entry(&kgem->snoop, struct kgem_bo, list)); while (__kgem_freed_bo) { struct kgem_bo *bo = __kgem_freed_bo; __kgem_freed_bo = *(struct kgem_bo **)bo; free(bo); } kgem->need_purge = false; kgem->need_expire = false; DBG(("%s: complete\n", __FUNCTION__)); return true; } static struct kgem_bo * search_linear_cache(struct kgem *kgem, unsigned int num_pages, unsigned flags) { struct kgem_bo *bo, *first = NULL; bool use_active = (flags & CREATE_INACTIVE) == 0; struct list *cache; DBG(("%s: num_pages=%d, flags=%x, use_active? %d, use_large=%d [max=%d]\n", __FUNCTION__, num_pages, flags, use_active, num_pages >= MAX_CACHE_SIZE / PAGE_SIZE, MAX_CACHE_SIZE / PAGE_SIZE)); assert(num_pages); if (num_pages >= MAX_CACHE_SIZE / PAGE_SIZE) { DBG(("%s: searching large buffers\n", __FUNCTION__)); retry_large: cache = use_active ? &kgem->large : &kgem->large_inactive; list_for_each_entry_safe(bo, first, cache, list) { assert(bo->refcnt == 0); assert(bo->reusable); assert(!bo->scanout); if (num_pages > num_pages(bo)) goto discard; if (bo->tiling != I915_TILING_NONE) { if (use_active && kgem->gen < 040) goto discard; if (!kgem_set_tiling(kgem, bo, I915_TILING_NONE, 0)) goto discard; } assert(bo->tiling == I915_TILING_NONE); bo->pitch = 0; if (bo->purged && !kgem_bo_clear_purgeable(kgem, bo)) goto discard; list_del(&bo->list); if (RQ(bo->rq) == (void *)kgem) { assert(bo->exec == NULL); list_del(&bo->request); } bo->delta = 0; assert_tiling(kgem, bo); return bo; discard: if (!use_active) kgem_bo_free(kgem, bo); } if (use_active) { use_active = false; goto retry_large; } if (__kgem_throttle_retire(kgem, flags)) goto retry_large; return NULL; } if (!use_active && list_is_empty(inactive(kgem, num_pages))) { DBG(("%s: inactive and cache bucket empty\n", __FUNCTION__)); if (flags & CREATE_NO_RETIRE) { DBG(("%s: can not retire\n", __FUNCTION__)); return NULL; } if (list_is_empty(active(kgem, num_pages, I915_TILING_NONE))) { DBG(("%s: active cache bucket empty\n", __FUNCTION__)); return NULL; } if (!__kgem_throttle_retire(kgem, flags)) { DBG(("%s: nothing retired\n", __FUNCTION__)); return NULL; } if (list_is_empty(inactive(kgem, num_pages))) { DBG(("%s: active cache bucket still empty after retire\n", __FUNCTION__)); return NULL; } } if (!use_active && flags & (CREATE_CPU_MAP | CREATE_GTT_MAP)) { int for_cpu = !!(flags & CREATE_CPU_MAP); DBG(("%s: searching for inactive %s map\n", __FUNCTION__, for_cpu ? "cpu" : "gtt")); cache = &kgem->vma[for_cpu].inactive[cache_bucket(num_pages)]; list_for_each_entry(bo, cache, vma) { assert(for_cpu ? !!bo->map__cpu : (bo->map__gtt || bo->map__wc)); assert(bucket(bo) == cache_bucket(num_pages)); assert(bo->proxy == NULL); assert(bo->rq == NULL); assert(bo->exec == NULL); assert(!bo->scanout); if (num_pages > num_pages(bo)) { DBG(("inactive too small: %d < %d\n", num_pages(bo), num_pages)); continue; } if (bo->purged && !kgem_bo_clear_purgeable(kgem, bo)) { kgem_bo_free(kgem, bo); break; } if (!kgem_set_tiling(kgem, bo, I915_TILING_NONE, 0)) { kgem_bo_free(kgem, bo); break; } kgem_bo_remove_from_inactive(kgem, bo); assert(list_is_empty(&bo->vma)); assert(list_is_empty(&bo->list)); assert(bo->tiling == I915_TILING_NONE); assert(bo->pitch == 0); bo->delta = 0; DBG((" %s: found handle=%d (num_pages=%d) in linear vma cache\n", __FUNCTION__, bo->handle, num_pages(bo))); assert(use_active || bo->domain != DOMAIN_GPU); assert(!bo->needs_flush); assert_tiling(kgem, bo); ASSERT_MAYBE_IDLE(kgem, bo->handle, !use_active); return bo; } if (flags & CREATE_EXACT) return NULL; if (flags & CREATE_CPU_MAP && !kgem->has_llc) return NULL; } cache = use_active ? active(kgem, num_pages, I915_TILING_NONE) : inactive(kgem, num_pages); list_for_each_entry(bo, cache, list) { assert(bo->refcnt == 0); assert(bo->reusable); assert(!!bo->rq == !!use_active); assert(bo->proxy == NULL); assert(!bo->scanout); if (num_pages > num_pages(bo)) continue; if (use_active && kgem->gen <= 040 && bo->tiling != I915_TILING_NONE) continue; if (bo->purged && !kgem_bo_clear_purgeable(kgem, bo)) { kgem_bo_free(kgem, bo); break; } if (I915_TILING_NONE != bo->tiling) { if (flags & (CREATE_CPU_MAP | CREATE_GTT_MAP)) continue; if (first) continue; if (!kgem_set_tiling(kgem, bo, I915_TILING_NONE, 0)) continue; } assert(bo->tiling == I915_TILING_NONE); bo->pitch = 0; if (bo->map__gtt || bo->map__wc || bo->map__cpu) { if (flags & (CREATE_CPU_MAP | CREATE_GTT_MAP)) { int for_cpu = !!(flags & CREATE_CPU_MAP); if (for_cpu ? !!bo->map__cpu : (bo->map__gtt || bo->map__wc)){ if (first != NULL) break; first = bo; continue; } } else { if (first != NULL) break; first = bo; continue; } } else { if (flags & CREATE_GTT_MAP && !kgem_bo_can_map(kgem, bo)) continue; if (flags & (CREATE_CPU_MAP | CREATE_GTT_MAP)) { if (first != NULL) break; first = bo; continue; } } if (use_active) kgem_bo_remove_from_active(kgem, bo); else kgem_bo_remove_from_inactive(kgem, bo); assert(bo->tiling == I915_TILING_NONE); assert(bo->pitch == 0); bo->delta = 0; DBG((" %s: found handle=%d (num_pages=%d) in linear %s cache\n", __FUNCTION__, bo->handle, num_pages(bo), use_active ? "active" : "inactive")); assert(list_is_empty(&bo->list)); assert(list_is_empty(&bo->vma)); assert(use_active || bo->domain != DOMAIN_GPU); assert(!bo->needs_flush || use_active); assert_tiling(kgem, bo); ASSERT_MAYBE_IDLE(kgem, bo->handle, !use_active); return bo; } if (first) { assert(first->tiling == I915_TILING_NONE); if (use_active) kgem_bo_remove_from_active(kgem, first); else kgem_bo_remove_from_inactive(kgem, first); first->pitch = 0; first->delta = 0; DBG((" %s: found handle=%d (near-miss) (num_pages=%d) in linear %s cache\n", __FUNCTION__, first->handle, num_pages(first), use_active ? "active" : "inactive")); assert(list_is_empty(&first->list)); assert(list_is_empty(&first->vma)); assert(use_active || first->domain != DOMAIN_GPU); assert(!first->needs_flush || use_active); ASSERT_MAYBE_IDLE(kgem, first->handle, !use_active); return first; } return NULL; } struct kgem_bo *kgem_create_for_name(struct kgem *kgem, uint32_t name) { struct drm_gem_open open_arg; struct drm_i915_gem_get_tiling tiling; struct kgem_bo *bo; DBG(("%s(name=%d)\n", __FUNCTION__, name)); VG_CLEAR(open_arg); open_arg.name = name; if (do_ioctl(kgem->fd, DRM_IOCTL_GEM_OPEN, &open_arg)) return NULL; DBG(("%s: new handle=%d\n", __FUNCTION__, open_arg.handle)); VG_CLEAR(tiling); tiling.handle = open_arg.handle; if (do_ioctl(kgem->fd, DRM_IOCTL_I915_GEM_GET_TILING, &tiling)) { DBG(("%s(name=%d) get-tiling failed, ret=%d\n", __FUNCTION__, name, errno)); gem_close(kgem->fd, open_arg.handle); return NULL; } DBG(("%s: handle=%d, tiling=%d\n", __FUNCTION__, tiling.handle, tiling.tiling_mode)); bo = __kgem_bo_alloc(open_arg.handle, open_arg.size / PAGE_SIZE); if (bo == NULL) { gem_close(kgem->fd, open_arg.handle); return NULL; } bo->unique_id = kgem_get_unique_id(kgem); bo->tiling = tiling.tiling_mode; bo->prime = true; bo->reusable = false; kgem_bo_unclean(kgem, bo); debug_alloc__bo(kgem, bo); return bo; } struct kgem_bo *kgem_create_for_prime(struct kgem *kgem, int name, uint32_t size) { #ifdef DRM_IOCTL_PRIME_FD_TO_HANDLE struct drm_prime_handle args; struct drm_i915_gem_get_tiling tiling; struct local_i915_gem_caching caching; struct kgem_bo *bo; off_t seek; DBG(("%s(name=%d)\n", __FUNCTION__, name)); VG_CLEAR(args); args.fd = name; args.flags = 0; if (do_ioctl(kgem->fd, DRM_IOCTL_PRIME_FD_TO_HANDLE, &args)) { DBG(("%s(name=%d) fd-to-handle failed, ret=%d\n", __FUNCTION__, name, errno)); return NULL; } VG_CLEAR(tiling); tiling.handle = args.handle; if (do_ioctl(kgem->fd, DRM_IOCTL_I915_GEM_GET_TILING, &tiling)) { DBG(("%s(name=%d) get-tiling failed, ret=%d\n", __FUNCTION__, name, errno)); gem_close(kgem->fd, args.handle); return NULL; } /* Query actual size, overriding specified if available */ seek = lseek(args.fd, 0, SEEK_END); DBG(("%s: estimated size=%ld, actual=%lld\n", __FUNCTION__, (long)size, (long long)seek)); if (seek != -1) { if (size > seek) { DBG(("%s(name=%d) estimated required size [%d] is larger than actual [%ld]\n", __FUNCTION__, name, size, (long)seek)); gem_close(kgem->fd, args.handle); return NULL; } size = seek; } DBG(("%s: new handle=%d, tiling=%d\n", __FUNCTION__, args.handle, tiling.tiling_mode)); bo = __kgem_bo_alloc(args.handle, NUM_PAGES(size)); if (bo == NULL) { gem_close(kgem->fd, args.handle); return NULL; } bo->unique_id = kgem_get_unique_id(kgem); bo->tiling = tiling.tiling_mode; bo->reusable = false; bo->prime = true; bo->domain = DOMAIN_NONE; /* is this a special bo (e.g. scanout or CPU coherent)? */ VG_CLEAR(caching); caching.handle = args.handle; caching.caching = kgem->has_llc; (void)drmIoctl(kgem->fd, LOCAL_IOCTL_I915_GEM_GET_CACHING, &caching); DBG(("%s: imported handle=%d has caching %d\n", __FUNCTION__, args.handle, caching.caching)); switch (caching.caching) { case 0: if (kgem->has_llc) { DBG(("%s: interpreting handle=%d as a foreign scanout\n", __FUNCTION__, args.handle)); bo->scanout = true; } break; case 1: if (!kgem->has_llc) { DBG(("%s: interpreting handle=%d as a foreign snooped buffer\n", __FUNCTION__, args.handle)); bo->snoop = true; if (bo->tiling) { DBG(("%s: illegal snooped tiled buffer\n", __FUNCTION__)); kgem_bo_free(kgem, bo); return NULL; } } break; case 2: DBG(("%s: interpreting handle=%d as a foreign scanout\n", __FUNCTION__, args.handle)); bo->scanout = true; break; } debug_alloc__bo(kgem, bo); return bo; #else return NULL; #endif } int kgem_bo_export_to_prime(struct kgem *kgem, struct kgem_bo *bo) { #if defined(DRM_IOCTL_PRIME_HANDLE_TO_FD) && defined(O_CLOEXEC) struct drm_prime_handle args; assert(kgem_bo_is_fenced(kgem, bo)); VG_CLEAR(args); args.handle = bo->handle; args.flags = O_CLOEXEC; if (do_ioctl(kgem->fd, DRM_IOCTL_PRIME_HANDLE_TO_FD, &args)) return -1; bo->reusable = false; return args.fd; #else return -1; #endif } struct kgem_bo *kgem_create_linear(struct kgem *kgem, int size, unsigned flags) { struct kgem_bo *bo; uint32_t handle; DBG(("%s(%d)\n", __FUNCTION__, size)); assert(size); if (flags & CREATE_GTT_MAP && kgem->has_llc) { flags &= ~CREATE_GTT_MAP; flags |= CREATE_CPU_MAP; } size = NUM_PAGES(size); if ((flags & CREATE_UNCACHED) == 0) { bo = search_linear_cache(kgem, size, CREATE_INACTIVE | flags); if (bo) { assert(!bo->purged); assert(!bo->delta); assert(bo->domain != DOMAIN_GPU); ASSERT_IDLE(kgem, bo->handle); bo->refcnt = 1; return bo; } if (flags & CREATE_CACHED) return NULL; } handle = gem_create(kgem->fd, size); if (handle == 0) return NULL; DBG(("%s: new handle=%d, num_pages=%d\n", __FUNCTION__, handle, size)); bo = __kgem_bo_alloc(handle, size); if (bo == NULL) { gem_close(kgem->fd, handle); return NULL; } debug_alloc__bo(kgem, bo); return bo; } int kgem_choose_tiling(struct kgem *kgem, int tiling, int width, int height, int bpp) { if (DBG_NO_TILING) return tiling < 0 ? tiling : I915_TILING_NONE; if (kgem->gen < 040) { if (tiling && width * bpp > 8192 * 8) { DBG(("%s: pitch too large for tliing [%d]\n", __FUNCTION__, width*bpp/8)); tiling = I915_TILING_NONE; goto done; } } else { if (width*bpp > (MAXSHORT-512) * 8) { if (tiling > 0) tiling = -tiling; else if (tiling == 0) tiling = -I915_TILING_X; DBG(("%s: large pitch [%d], forcing TILING [%d]\n", __FUNCTION__, width*bpp/8, tiling)); } else if (tiling && (width|height) > 8192) { DBG(("%s: large tiled buffer [%dx%d], forcing TILING_X\n", __FUNCTION__, width, height)); tiling = -I915_TILING_X; } /* fences limited to 128k (256k on ivb) */ assert(width * bpp <= 128 * 1024 * 8); } if (tiling < 0) return tiling; if (tiling == I915_TILING_Y && !kgem->can_render_y) tiling = I915_TILING_X; if (tiling && (height == 1 || width == 1)) { DBG(("%s: disabling tiling [%dx%d] for single row/col\n", __FUNCTION__,width, height)); tiling = I915_TILING_NONE; goto done; } if (tiling == I915_TILING_Y && height <= 16) { DBG(("%s: too short [%d] for TILING_Y\n", __FUNCTION__,height)); tiling = I915_TILING_X; } if (tiling && width * bpp > 8 * (4096 - 64)) { DBG(("%s: TLB miss between lines %dx%d (pitch=%d), forcing tiling %d\n", __FUNCTION__, width, height, width*bpp/8, tiling)); return -tiling; } if (tiling == I915_TILING_X && height < 4) { DBG(("%s: too short [%d] for TILING_X\n", __FUNCTION__, height)); tiling = I915_TILING_NONE; goto done; } if (tiling == I915_TILING_X && width * bpp <= 8*512) { DBG(("%s: too thin [width %d, %d bpp] for TILING_X\n", __FUNCTION__, width, bpp)); tiling = I915_TILING_NONE; goto done; } if (tiling == I915_TILING_Y && width * bpp < 8*128) { DBG(("%s: too thin [%d] for TILING_Y\n", __FUNCTION__, width)); tiling = I915_TILING_NONE; goto done; } if (tiling && ALIGN(height, 2) * ALIGN(width*bpp, 8*64) <= 4096 * 8) { DBG(("%s: too small [%d bytes] for TILING_%c\n", __FUNCTION__, ALIGN(height, 2) * ALIGN(width*bpp, 8*64) / 8, tiling == I915_TILING_X ? 'X' : 'Y')); tiling = I915_TILING_NONE; goto done; } if (tiling && width * bpp >= 8 * 4096 / 2) { DBG(("%s: TLB near-miss between lines %dx%d (pitch=%d), forcing tiling %d\n", __FUNCTION__, width, height, width*bpp/8, tiling)); return -tiling; } done: DBG(("%s: %dx%d -> %d\n", __FUNCTION__, width, height, tiling)); return tiling; } static int bits_per_pixel(int depth) { switch (depth) { case 8: return 8; case 15: case 16: return 16; case 24: case 30: case 32: return 32; default: return 0; } } unsigned kgem_can_create_2d(struct kgem *kgem, int width, int height, int depth) { uint32_t pitch, size; unsigned flags = 0; int tiling; int bpp; DBG(("%s: %dx%d @ %d\n", __FUNCTION__, width, height, depth)); bpp = bits_per_pixel(depth); if (bpp == 0) { DBG(("%s: unhandled depth %d\n", __FUNCTION__, depth)); return 0; } if (width > MAXSHORT || height > MAXSHORT) { DBG(("%s: unhandled size %dx%d\n", __FUNCTION__, width, height)); return 0; } size = kgem_surface_size(kgem, false, 0, width, height, bpp, I915_TILING_NONE, &pitch); DBG(("%s: untiled size=%d\n", __FUNCTION__, size)); if (size > 0) { if (size <= kgem->max_cpu_size) flags |= KGEM_CAN_CREATE_CPU; if (size > 4096 && size <= kgem->max_gpu_size) flags |= KGEM_CAN_CREATE_GPU; if (size <= PAGE_SIZE*kgem->aperture_mappable/4 || kgem->has_wc_mmap) flags |= KGEM_CAN_CREATE_GTT; if (size > kgem->large_object_size) flags |= KGEM_CAN_CREATE_LARGE; if (size > kgem->max_object_size) { DBG(("%s: too large (untiled) %d > %d\n", __FUNCTION__, size, kgem->max_object_size)); return 0; } } tiling = kgem_choose_tiling(kgem, I915_TILING_X, width, height, bpp); if (tiling != I915_TILING_NONE) { size = kgem_surface_size(kgem, false, 0, width, height, bpp, tiling, &pitch); DBG(("%s: tiled[%d] size=%d\n", __FUNCTION__, tiling, size)); if (size > 0 && size <= kgem->max_gpu_size) flags |= KGEM_CAN_CREATE_GPU | KGEM_CAN_CREATE_TILED; if (size > 0 && size <= PAGE_SIZE*kgem->aperture_mappable/4) flags |= KGEM_CAN_CREATE_GTT; if (size > PAGE_SIZE*kgem->aperture_mappable/4) flags &= ~KGEM_CAN_CREATE_GTT; if (size > kgem->large_object_size) flags |= KGEM_CAN_CREATE_LARGE; if (size > kgem->max_object_size) { DBG(("%s: too large (tiled) %d > %d\n", __FUNCTION__, size, kgem->max_object_size)); return 0; } if (kgem->gen < 040) { int fence_size = 1024 * 1024; while (fence_size < size) fence_size <<= 1; if (fence_size > kgem->max_gpu_size) flags &= ~KGEM_CAN_CREATE_GPU | KGEM_CAN_CREATE_TILED; if (fence_size > PAGE_SIZE*kgem->aperture_fenceable/4) flags &= ~KGEM_CAN_CREATE_GTT; } } return flags; } inline int kgem_bo_fenced_size(struct kgem *kgem, struct kgem_bo *bo) { unsigned int size; assert(bo->tiling); assert_tiling(kgem, bo); assert(kgem->gen < 040); if (kgem->gen < 030) size = 512 * 1024 / PAGE_SIZE; else size = 1024 * 1024 / PAGE_SIZE; while (size < num_pages(bo)) size <<= 1; return size; } static struct kgem_bo * __kgem_bo_create_as_display(struct kgem *kgem, int size, int tiling, int pitch) { struct local_i915_gem_create2 args; struct kgem_bo *bo; if (!kgem->has_create2) return NULL; memset(&args, 0, sizeof(args)); args.size = size * PAGE_SIZE; args.placement = LOCAL_I915_CREATE_PLACEMENT_STOLEN; args.caching = DISPLAY; args.tiling_mode = tiling; args.stride = pitch; if (do_ioctl(kgem->fd, LOCAL_IOCTL_I915_GEM_CREATE2, &args)) { args.placement = LOCAL_I915_CREATE_PLACEMENT_SYSTEM; if (do_ioctl(kgem->fd, LOCAL_IOCTL_I915_GEM_CREATE2, &args)) return NULL; } bo = __kgem_bo_alloc(args.handle, size); if (bo == NULL) { gem_close(kgem->fd, args.handle); return NULL; } bo->unique_id = kgem_get_unique_id(kgem); bo->tiling = tiling; bo->pitch = pitch; if (args.placement == LOCAL_I915_CREATE_PLACEMENT_STOLEN) { bo->purged = true; /* for asserts against CPU access */ } bo->reusable = false; /* so that unclaimed scanouts are freed */ bo->domain = DOMAIN_NONE; if (__kgem_busy(kgem, bo->handle)) { assert(bo->exec == NULL); list_add(&bo->request, &kgem->flushing); bo->rq = (void *)kgem; kgem->need_retire = true; } assert_tiling(kgem, bo); debug_alloc__bo(kgem, bo); return bo; } static void __kgem_bo_make_scanout(struct kgem *kgem, struct kgem_bo *bo, int width, int height) { ScrnInfoPtr scrn = __to_sna(kgem)->scrn; struct drm_mode_fb_cmd arg; assert(bo->proxy == NULL); if (!scrn->vtSema) return; DBG(("%s: create fb %dx%d@%d/%d\n", __FUNCTION__, width, height, scrn->depth, scrn->bitsPerPixel)); VG_CLEAR(arg); arg.width = width; arg.height = height; arg.pitch = bo->pitch; arg.bpp = scrn->bitsPerPixel; arg.depth = scrn->depth; arg.handle = bo->handle; /* First move the scanout out of cached memory */ if (kgem->has_llc) { if (!gem_set_caching(kgem->fd, bo->handle, DISPLAY) && !gem_set_caching(kgem->fd, bo->handle, UNCACHED)) return; } bo->scanout = true; /* Then pre-emptively move the object into the mappable * portion to avoid rebinding later when busy. */ if (bo->map__gtt == NULL) bo->map__gtt = __kgem_bo_map__gtt(kgem, bo); if (bo->map__gtt) { if (sigtrap_get() == 0) { *(uint32_t *)bo->map__gtt = 0; sigtrap_put(); } bo->domain = DOMAIN_GTT; } if (do_ioctl(kgem->fd, DRM_IOCTL_MODE_ADDFB, &arg) == 0) { DBG(("%s: attached fb=%d to handle=%d\n", __FUNCTION__, arg.fb_id, arg.handle)); bo->delta = arg.fb_id; } } static bool tiling_changed(struct kgem_bo *bo, int tiling, int pitch) { if (tiling != bo->tiling) return true; return tiling != I915_TILING_NONE && pitch != bo->pitch; } static void set_gpu_tiling(struct kgem *kgem, struct kgem_bo *bo, int tiling, int pitch) { DBG(("%s: handle=%d, tiling=%d, pitch=%d\n", __FUNCTION__, bo->handle, tiling, pitch)); if (tiling_changed(bo, tiling, pitch) && bo->map__gtt) { if (!list_is_empty(&bo->vma)) { list_del(&bo->vma); kgem->vma[0].count--; } munmap(bo->map__gtt, bytes(bo)); bo->map__gtt = NULL; } bo->tiling = tiling; bo->pitch = pitch; } bool kgem_bo_is_fenced(struct kgem *kgem, struct kgem_bo *bo) { struct drm_i915_gem_get_tiling tiling; assert(kgem); assert(bo); VG_CLEAR(tiling); tiling.handle = bo->handle; tiling.tiling_mode = bo->tiling; (void)do_ioctl(kgem->fd, DRM_IOCTL_I915_GEM_GET_TILING, &tiling); return tiling.tiling_mode == bo->tiling; /* assume pitch is fine! */ } struct kgem_bo *kgem_create_2d(struct kgem *kgem, int width, int height, int bpp, int tiling, uint32_t flags) { struct list *cache; struct kgem_bo *bo; uint32_t pitch, tiled_height, size; uint32_t handle; int i, bucket, retry; bool exact = flags & (CREATE_EXACT | CREATE_SCANOUT); if (tiling < 0) exact = true, tiling = -tiling; DBG(("%s(%dx%d, bpp=%d, tiling=%d, exact=%d, inactive=%d, cpu-mapping=%d, gtt-mapping=%d, scanout?=%d, prime?=%d, temp?=%d)\n", __FUNCTION__, width, height, bpp, tiling, exact, !!(flags & CREATE_INACTIVE), !!(flags & CREATE_CPU_MAP), !!(flags & CREATE_GTT_MAP), !!(flags & CREATE_SCANOUT), !!(flags & CREATE_PRIME), !!(flags & CREATE_TEMPORARY))); size = kgem_surface_size(kgem, kgem->has_relaxed_fencing, flags, width, height, bpp, tiling, &pitch); if (size == 0) { DBG(("%s: invalid surface size (too large?)\n", __FUNCTION__)); return NULL; } size /= PAGE_SIZE; bucket = cache_bucket(size); if (flags & CREATE_SCANOUT) { struct kgem_bo *last = NULL; list_for_each_entry_reverse(bo, &kgem->scanout, list) { assert(bo->scanout); assert(!bo->flush); assert(!bo->refcnt); assert_tiling(kgem, bo); if (size > num_pages(bo) || num_pages(bo) > 2*size) continue; if (bo->tiling != tiling || bo->pitch != pitch) /* No tiling/pitch without recreating fb */ continue; if (bo->delta && !check_scanout_size(kgem, bo, width, height)) kgem_bo_rmfb(kgem, bo); if (flags & CREATE_INACTIVE && bo->rq) { last = bo; continue; } list_del(&bo->list); bo->unique_id = kgem_get_unique_id(kgem); DBG((" 1:from scanout: pitch=%d, tiling=%d, handle=%d, id=%d\n", bo->pitch, bo->tiling, bo->handle, bo->unique_id)); assert(bo->pitch*kgem_aligned_height(kgem, height, bo->tiling) <= kgem_bo_size(bo)); assert_tiling(kgem, bo); bo->refcnt = 1; return bo; } if (last) { list_del(&last->list); last->unique_id = kgem_get_unique_id(kgem); DBG((" 1:from scanout: pitch=%d, tiling=%d, handle=%d, id=%d\n", last->pitch, last->tiling, last->handle, last->unique_id)); assert(last->pitch*kgem_aligned_height(kgem, height, last->tiling) <= kgem_bo_size(last)); assert_tiling(kgem, last); last->refcnt = 1; return last; } if (__to_sna(kgem)->scrn->vtSema) { ScrnInfoPtr scrn = __to_sna(kgem)->scrn; list_for_each_entry_reverse(bo, &kgem->scanout, list) { struct drm_mode_fb_cmd arg; assert(bo->scanout); assert(!bo->refcnt); if (size > num_pages(bo) || num_pages(bo) > 2*size) continue; if (flags & CREATE_INACTIVE && bo->rq) continue; list_del(&bo->list); if (bo->tiling != tiling || bo->pitch != pitch) { if (bo->delta) { kgem_bo_rmfb(kgem, bo); bo->delta = 0; } if (!kgem_set_tiling(kgem, bo, tiling, pitch)) { bo->scanout = false; __kgem_bo_destroy(kgem, bo); break; } } VG_CLEAR(arg); arg.width = width; arg.height = height; arg.pitch = bo->pitch; arg.bpp = scrn->bitsPerPixel; arg.depth = scrn->depth; arg.handle = bo->handle; if (do_ioctl(kgem->fd, DRM_IOCTL_MODE_ADDFB, &arg)) { bo->scanout = false; __kgem_bo_destroy(kgem, bo); break; } bo->delta = arg.fb_id; bo->unique_id = kgem_get_unique_id(kgem); DBG((" 2:from scanout: pitch=%d, tiling=%d, handle=%d, id=%d\n", bo->pitch, bo->tiling, bo->handle, bo->unique_id)); assert(bo->pitch*kgem_aligned_height(kgem, height, bo->tiling) <= kgem_bo_size(bo)); assert_tiling(kgem, bo); bo->refcnt = 1; return bo; } } if (flags & CREATE_CACHED) return NULL; bo = __kgem_bo_create_as_display(kgem, size, tiling, pitch); if (bo) return bo; flags |= CREATE_INACTIVE; } if (bucket >= NUM_CACHE_BUCKETS) { DBG(("%s: large bo num pages=%d, bucket=%d\n", __FUNCTION__, size, bucket)); if (flags & CREATE_INACTIVE) goto large_inactive; tiled_height = kgem_aligned_height(kgem, height, tiling); list_for_each_entry(bo, &kgem->large, list) { assert(!bo->purged); assert(!bo->scanout); assert(bo->refcnt == 0); assert(bo->reusable); assert_tiling(kgem, bo); if (kgem->gen < 040) { if (bo->pitch < pitch) { DBG(("tiled and pitch too small: tiling=%d, (want %d), pitch=%d, need %d\n", bo->tiling, tiling, bo->pitch, pitch)); continue; } if (bo->pitch * tiled_height > bytes(bo)) continue; } else { if (num_pages(bo) < size) continue; if (!kgem_set_tiling(kgem, bo, tiling, pitch)) { if (exact) { DBG(("tiled and pitch not exact: tiling=%d, (want %d), pitch=%d, need %d\n", bo->tiling, tiling, bo->pitch, pitch)); continue; } set_gpu_tiling(kgem, bo, tiling, pitch); } } kgem_bo_remove_from_active(kgem, bo); bo->unique_id = kgem_get_unique_id(kgem); bo->delta = 0; DBG((" 1:from active: pitch=%d, tiling=%d, handle=%d, id=%d\n", bo->pitch, bo->tiling, bo->handle, bo->unique_id)); assert(bo->pitch*kgem_aligned_height(kgem, height, bo->tiling) <= kgem_bo_size(bo)); assert_tiling(kgem, bo); bo->refcnt = 1; return bo; } large_inactive: __kgem_throttle_retire(kgem, flags); list_for_each_entry(bo, &kgem->large_inactive, list) { assert(bo->refcnt == 0); assert(bo->reusable); assert(!bo->scanout); assert_tiling(kgem, bo); if (size > num_pages(bo)) continue; if (!kgem_set_tiling(kgem, bo, tiling, pitch)) { if (kgem->gen >= 040 && !exact) set_gpu_tiling(kgem, bo, tiling, pitch); else continue; } if (bo->purged && !kgem_bo_clear_purgeable(kgem, bo)) { kgem_bo_free(kgem, bo); break; } list_del(&bo->list); assert(bo->domain != DOMAIN_GPU); bo->unique_id = kgem_get_unique_id(kgem); bo->delta = 0; DBG((" 1:from large inactive: pitch=%d, tiling=%d, handle=%d, id=%d\n", bo->pitch, bo->tiling, bo->handle, bo->unique_id)); assert(bo->pitch*kgem_aligned_height(kgem, height, bo->tiling) <= kgem_bo_size(bo)); assert_tiling(kgem, bo); bo->refcnt = 1; if (flags & CREATE_SCANOUT) __kgem_bo_make_scanout(kgem, bo, width, height); return bo; } goto create; } if (flags & (CREATE_CPU_MAP | CREATE_GTT_MAP)) { int for_cpu = !!(flags & CREATE_CPU_MAP); if (kgem->has_llc && tiling == I915_TILING_NONE) for_cpu = 1; /* We presume that we will need to upload to this bo, * and so would prefer to have an active VMA. */ cache = &kgem->vma[for_cpu].inactive[bucket]; do { list_for_each_entry(bo, cache, vma) { assert(bucket(bo) == bucket); assert(bo->refcnt == 0); assert(!bo->scanout); assert(for_cpu ? !!bo->map__cpu : (bo->map__gtt || bo->map__wc)); assert(bo->rq == NULL); assert(bo->exec == NULL); assert(list_is_empty(&bo->request)); assert(bo->flush == false); assert_tiling(kgem, bo); if (size > num_pages(bo)) { DBG(("inactive too small: %d < %d\n", num_pages(bo), size)); continue; } if (flags & UNCACHED && !kgem->has_llc && bo->domain != DOMAIN_CPU) continue; if (bo->tiling != tiling || (tiling != I915_TILING_NONE && bo->pitch != pitch)) { if (bo->map__gtt || !kgem_set_tiling(kgem, bo, tiling, pitch)) { DBG(("inactive GTT vma with wrong tiling: %d < %d\n", bo->tiling, tiling)); kgem_bo_free(kgem, bo); break; } } if (bo->purged && !kgem_bo_clear_purgeable(kgem, bo)) { kgem_bo_free(kgem, bo); break; } if (tiling == I915_TILING_NONE) bo->pitch = pitch; assert(bo->tiling == tiling); assert(bo->pitch >= pitch); bo->delta = 0; bo->unique_id = kgem_get_unique_id(kgem); kgem_bo_remove_from_inactive(kgem, bo); assert(list_is_empty(&bo->list)); assert(list_is_empty(&bo->vma)); DBG((" from inactive vma: pitch=%d, tiling=%d: handle=%d, id=%d\n", bo->pitch, bo->tiling, bo->handle, bo->unique_id)); assert(bo->reusable); assert(bo->domain != DOMAIN_GPU); ASSERT_IDLE(kgem, bo->handle); assert(bo->pitch*kgem_aligned_height(kgem, height, bo->tiling) <= kgem_bo_size(bo)); assert_tiling(kgem, bo); bo->refcnt = 1; return bo; } } while (!list_is_empty(cache) && __kgem_throttle_retire(kgem, flags)); if (flags & CREATE_CPU_MAP && !kgem->has_llc) { if (list_is_empty(&kgem->active[bucket][tiling]) && list_is_empty(&kgem->inactive[bucket])) flags &= ~CREATE_CACHED; goto create; } } if (flags & CREATE_INACTIVE) goto skip_active_search; /* Best active match */ retry = NUM_CACHE_BUCKETS - bucket; if (retry > 3 && (flags & CREATE_TEMPORARY) == 0) retry = 3; search_active: assert(bucket < NUM_CACHE_BUCKETS); cache = &kgem->active[bucket][tiling]; if (tiling) { tiled_height = kgem_aligned_height(kgem, height, tiling); list_for_each_entry(bo, cache, list) { assert(!bo->purged); assert(bo->refcnt == 0); assert(bucket(bo) == bucket); assert(bo->reusable); assert(bo->tiling == tiling); assert(bo->flush == false); assert(!bo->scanout); assert_tiling(kgem, bo); if (kgem->gen < 040) { if (bo->pitch < pitch) { DBG(("tiled and pitch too small: tiling=%d, (want %d), pitch=%d, need %d\n", bo->tiling, tiling, bo->pitch, pitch)); continue; } if (bo->pitch * tiled_height > bytes(bo)) continue; } else { if (num_pages(bo) < size) continue; if (!kgem_set_tiling(kgem, bo, tiling, pitch)) { if (exact) { DBG(("tiled and pitch not exact: tiling=%d, (want %d), pitch=%d, need %d\n", bo->tiling, tiling, bo->pitch, pitch)); continue; } set_gpu_tiling(kgem, bo, tiling, pitch); } } assert(bo->tiling == tiling); assert(bo->pitch >= pitch); kgem_bo_remove_from_active(kgem, bo); bo->unique_id = kgem_get_unique_id(kgem); bo->delta = 0; DBG((" 1:from active: pitch=%d, tiling=%d, handle=%d, id=%d\n", bo->pitch, bo->tiling, bo->handle, bo->unique_id)); assert(bo->pitch*kgem_aligned_height(kgem, height, bo->tiling) <= kgem_bo_size(bo)); assert_tiling(kgem, bo); bo->refcnt = 1; return bo; } } else { list_for_each_entry(bo, cache, list) { assert(bucket(bo) == bucket); assert(!bo->purged); assert(bo->refcnt == 0); assert(bo->reusable); assert(!bo->scanout); assert(bo->tiling == tiling); assert(bo->flush == false); assert_tiling(kgem, bo); if (num_pages(bo) < size) continue; kgem_bo_remove_from_active(kgem, bo); bo->pitch = pitch; bo->unique_id = kgem_get_unique_id(kgem); bo->delta = 0; DBG((" 1:from active: pitch=%d, tiling=%d, handle=%d, id=%d\n", bo->pitch, bo->tiling, bo->handle, bo->unique_id)); assert(bo->pitch*kgem_aligned_height(kgem, height, bo->tiling) <= kgem_bo_size(bo)); assert_tiling(kgem, bo); bo->refcnt = 1; return bo; } } if (kgem->gen >= 040) { for (i = I915_TILING_Y; i >= I915_TILING_NONE; i--) { cache = &kgem->active[bucket][i]; list_for_each_entry(bo, cache, list) { assert(!bo->purged); assert(bo->refcnt == 0); assert(bo->reusable); assert(!bo->scanout); assert(bo->flush == false); assert_tiling(kgem, bo); if (num_pages(bo) < size) continue; if (!kgem_set_tiling(kgem, bo, tiling, pitch)) { if (exact || kgem->gen < 040) continue; set_gpu_tiling(kgem, bo, tiling, pitch); } assert(bo->tiling == tiling); assert(bo->pitch >= pitch); kgem_bo_remove_from_active(kgem, bo); bo->unique_id = kgem_get_unique_id(kgem); bo->delta = 0; DBG((" 1:from active: pitch=%d, tiling=%d, handle=%d, id=%d\n", bo->pitch, bo->tiling, bo->handle, bo->unique_id)); assert(bo->pitch*kgem_aligned_height(kgem, height, bo->tiling) <= kgem_bo_size(bo)); assert_tiling(kgem, bo); bo->refcnt = 1; return bo; } } } else if (!exact) { /* allow an active near-miss? */ for (i = tiling; i >= I915_TILING_NONE; i--) { tiled_height = kgem_surface_size(kgem, kgem->has_relaxed_fencing, flags, width, height, bpp, tiling, &pitch); cache = active(kgem, tiled_height / PAGE_SIZE, i); tiled_height = kgem_aligned_height(kgem, height, i); list_for_each_entry(bo, cache, list) { assert(!bo->purged); assert(bo->refcnt == 0); assert(bo->reusable); assert(!bo->scanout); assert(bo->flush == false); assert_tiling(kgem, bo); if (bo->tiling) { if (bo->pitch < pitch) { DBG(("tiled and pitch too small: tiling=%d, (want %d), pitch=%d, need %d\n", bo->tiling, tiling, bo->pitch, pitch)); continue; } } else bo->pitch = pitch; if (bo->pitch * tiled_height > bytes(bo)) continue; kgem_bo_remove_from_active(kgem, bo); bo->unique_id = kgem_get_unique_id(kgem); bo->delta = 0; DBG((" 1:from active: pitch=%d, tiling=%d, handle=%d, id=%d\n", bo->pitch, bo->tiling, bo->handle, bo->unique_id)); assert(bo->pitch*kgem_aligned_height(kgem, height, bo->tiling) <= kgem_bo_size(bo)); assert_tiling(kgem, bo); bo->refcnt = 1; return bo; } } } if (--retry) { bucket++; goto search_active; } skip_active_search: bucket = cache_bucket(size); retry = NUM_CACHE_BUCKETS - bucket; if (retry > 3) retry = 3; search_inactive: /* Now just look for a close match and prefer any currently active */ assert(bucket < NUM_CACHE_BUCKETS); cache = &kgem->inactive[bucket]; list_for_each_entry(bo, cache, list) { assert(bucket(bo) == bucket); assert(bo->reusable); assert(!bo->scanout); assert(bo->flush == false); assert_tiling(kgem, bo); if (size > num_pages(bo)) { DBG(("inactive too small: %d < %d\n", num_pages(bo), size)); continue; } if (!kgem_set_tiling(kgem, bo, tiling, pitch)) { if (exact || kgem->gen < 040) { kgem_bo_free(kgem, bo); break; } set_gpu_tiling(kgem, bo, tiling, pitch); } if (bo->purged && !kgem_bo_clear_purgeable(kgem, bo)) { kgem_bo_free(kgem, bo); break; } kgem_bo_remove_from_inactive(kgem, bo); assert(list_is_empty(&bo->list)); assert(list_is_empty(&bo->vma)); assert(bo->tiling == tiling); assert(bo->pitch >= pitch); bo->delta = 0; bo->unique_id = kgem_get_unique_id(kgem); assert(bo->pitch); DBG((" from inactive: pitch=%d, tiling=%d: handle=%d, id=%d\n", bo->pitch, bo->tiling, bo->handle, bo->unique_id)); assert(bo->refcnt == 0); assert(bo->reusable); assert((flags & CREATE_INACTIVE) == 0 || bo->domain != DOMAIN_GPU); ASSERT_MAYBE_IDLE(kgem, bo->handle, flags & CREATE_INACTIVE); assert(bo->pitch*kgem_aligned_height(kgem, height, bo->tiling) <= kgem_bo_size(bo)); assert_tiling(kgem, bo); bo->refcnt = 1; if (flags & CREATE_SCANOUT) __kgem_bo_make_scanout(kgem, bo, width, height); return bo; } if ((flags & CREATE_NO_RETIRE) == 0) { list_for_each_entry_reverse(bo, &kgem->active[bucket][tiling], list) { if (bo->exec) break; if (size > num_pages(bo)) continue; if (__kgem_busy(kgem, bo->handle)) { if (flags & CREATE_NO_THROTTLE) goto no_retire; do { if (!kgem->need_throttle) { DBG(("%s: not throttling for active handle=%d\n", __FUNCTION__, bo->handle)); goto no_retire; } __kgem_throttle(kgem, false); } while (__kgem_busy(kgem, bo->handle)); } DBG(("%s: flushed active handle=%d\n", __FUNCTION__, bo->handle)); kgem_bo_remove_from_active(kgem, bo); __kgem_bo_clear_busy(bo); if (!kgem_set_tiling(kgem, bo, tiling, pitch)) { if (exact || kgem->gen < 040) goto no_retire; set_gpu_tiling(kgem, bo, tiling, pitch); } assert(bo->tiling == tiling); assert(bo->pitch >= pitch); bo->unique_id = kgem_get_unique_id(kgem); bo->delta = 0; DBG((" 2:from active: pitch=%d, tiling=%d, handle=%d, id=%d\n", bo->pitch, bo->tiling, bo->handle, bo->unique_id)); assert(bo->pitch*kgem_aligned_height(kgem, height, bo->tiling) <= kgem_bo_size(bo)); assert_tiling(kgem, bo); bo->refcnt = 1; if (flags & CREATE_SCANOUT) __kgem_bo_make_scanout(kgem, bo, width, height); return bo; } no_retire: flags |= CREATE_NO_RETIRE; } if (--retry) { bucket++; goto search_inactive; } create: if (flags & CREATE_CACHED) { DBG(("%s: no cached bo found, requested not to create a new bo\n", __FUNCTION__)); return NULL; } if (bucket >= NUM_CACHE_BUCKETS) size = ALIGN(size, 1024); handle = gem_create(kgem->fd, size); if (handle == 0) { DBG(("%s: kernel allocation (gem_create) failure\n", __FUNCTION__)); return NULL; } bo = __kgem_bo_alloc(handle, size); if (!bo) { DBG(("%s: malloc failed\n", __FUNCTION__)); gem_close(kgem->fd, handle); return NULL; } bo->unique_id = kgem_get_unique_id(kgem); if (kgem_set_tiling(kgem, bo, tiling, pitch)) { if (flags & CREATE_SCANOUT) __kgem_bo_make_scanout(kgem, bo, width, height); } else { if (kgem->gen >= 040) { assert(!kgem->can_fence); bo->tiling = tiling; bo->pitch = pitch; } else { if (flags & CREATE_EXACT) { DBG(("%s: failed to set exact tiling (gem_set_tiling)\n", __FUNCTION__)); gem_close(kgem->fd, handle); free(bo); return NULL; } } } assert(bytes(bo) >= bo->pitch * kgem_aligned_height(kgem, height, bo->tiling)); assert_tiling(kgem, bo); debug_alloc__bo(kgem, bo); DBG((" new pitch=%d, tiling=%d, handle=%d, id=%d, num_pages=%d [%d], bucket=%d\n", bo->pitch, bo->tiling, bo->handle, bo->unique_id, size, num_pages(bo), bucket(bo))); return bo; } struct kgem_bo *kgem_create_cpu_2d(struct kgem *kgem, int width, int height, int bpp, uint32_t flags) { struct kgem_bo *bo; int stride, size; if (DBG_NO_CPU) return NULL; DBG(("%s(%dx%d, bpp=%d)\n", __FUNCTION__, width, height, bpp)); if (kgem->has_llc) { bo = kgem_create_2d(kgem, width, height, bpp, I915_TILING_NONE, flags); if (bo == NULL) return bo; assert(bo->tiling == I915_TILING_NONE); assert_tiling(kgem, bo); if (kgem_bo_map__cpu(kgem, bo) == NULL) { kgem_bo_destroy(kgem, bo); return NULL; } return bo; } assert(width > 0 && height > 0); stride = ALIGN(width, 2) * bpp >> 3; stride = ALIGN(stride, 4); size = stride * ALIGN(height, 2); assert(size >= PAGE_SIZE); DBG(("%s: %dx%d, %d bpp, stride=%d\n", __FUNCTION__, width, height, bpp, stride)); bo = search_snoop_cache(kgem, NUM_PAGES(size), 0); if (bo) { assert(bo->tiling == I915_TILING_NONE); assert_tiling(kgem, bo); assert(bo->snoop); bo->refcnt = 1; bo->pitch = stride; bo->unique_id = kgem_get_unique_id(kgem); return bo; } if (kgem->has_caching) { bo = kgem_create_linear(kgem, size, flags); if (bo == NULL) return NULL; assert(bo->tiling == I915_TILING_NONE); assert_tiling(kgem, bo); assert(!__kgem_busy(kgem, bo->handle)); if (!gem_set_caching(kgem->fd, bo->handle, SNOOPED)) { kgem_bo_destroy(kgem, bo); return NULL; } bo->snoop = true; if (kgem_bo_map__cpu(kgem, bo) == NULL) { kgem_bo_destroy(kgem, bo); return NULL; } bo->pitch = stride; bo->unique_id = kgem_get_unique_id(kgem); return bo; } if (kgem->has_userptr) { void *ptr; /* XXX */ //if (posix_memalign(&ptr, 64, ALIGN(size, 64))) if (posix_memalign(&ptr, PAGE_SIZE, ALIGN(size, PAGE_SIZE))) return NULL; bo = kgem_create_map(kgem, ptr, size, false); if (bo == NULL) { free(ptr); return NULL; } bo->pitch = stride; bo->unique_id = kgem_get_unique_id(kgem); return bo; } return NULL; } void _kgem_bo_destroy(struct kgem *kgem, struct kgem_bo *bo) { DBG(("%s: handle=%d, proxy? %d\n", __FUNCTION__, bo->handle, bo->proxy != NULL)); if (bo->proxy) { assert(!bo->reusable); kgem_bo_binding_free(kgem, bo); assert(list_is_empty(&bo->list)); _list_del(&bo->vma); _list_del(&bo->request); if (bo->io && bo->domain == DOMAIN_CPU) _kgem_bo_delete_buffer(kgem, bo); kgem_bo_unref(kgem, bo->proxy); if (DBG_NO_MALLOC_CACHE) { free(bo); } else { *(struct kgem_bo **)bo = __kgem_freed_bo; __kgem_freed_bo = bo; } } else __kgem_bo_destroy(kgem, bo); } static void __kgem_flush(struct kgem *kgem, struct kgem_bo *bo) { assert(bo->rq); assert(bo->exec == NULL); assert(bo->needs_flush); /* The kernel will emit a flush *and* update its own flushing lists. */ if (!__kgem_busy(kgem, bo->handle)) __kgem_bo_clear_busy(bo); DBG(("%s: handle=%d, busy?=%d\n", __FUNCTION__, bo->handle, bo->rq != NULL)); } void kgem_scanout_flush(struct kgem *kgem, struct kgem_bo *bo) { if (!bo->needs_flush && !bo->gtt_dirty) return; kgem_bo_submit(kgem, bo); /* If the kernel fails to emit the flush, then it will be forced when * we assume direct access. And as the usual failure is EIO, we do * not actually care. */ assert(bo->exec == NULL); if (bo->rq) __kgem_flush(kgem, bo); if (bo->scanout && kgem->needs_dirtyfb) { struct drm_mode_fb_dirty_cmd cmd; memset(&cmd, 0, sizeof(cmd)); cmd.fb_id = bo->delta; (void)drmIoctl(kgem->fd, DRM_IOCTL_MODE_DIRTYFB, &cmd); } /* Whatever actually happens, we can regard the GTT write domain * as being flushed. */ __kgem_bo_clear_dirty(bo); } inline static bool nearly_idle(struct kgem *kgem) { int ring = kgem->ring == KGEM_BLT; assert(ring < ARRAY_SIZE(kgem->requests)); if (list_is_singular(&kgem->requests[ring])) return true; return __kgem_ring_is_idle(kgem, ring); } inline static bool needs_semaphore(struct kgem *kgem, struct kgem_bo *bo) { if (kgem->needs_semaphore) return false; if (bo->rq == NULL || RQ_RING(bo->rq) == kgem->ring) return false; kgem->needs_semaphore = true; return true; } inline static bool needs_reservation(struct kgem *kgem, struct kgem_bo *bo) { if (kgem->needs_reservation) return false; if (bo->presumed_offset) return false; kgem->needs_reservation = true; return nearly_idle(kgem); } inline static bool needs_batch_flush(struct kgem *kgem, struct kgem_bo *bo) { bool flush = false; if (needs_semaphore(kgem, bo)) { DBG(("%s: flushing before handle=%d for required semaphore\n", __FUNCTION__, bo->handle)); flush = true; } if (needs_reservation(kgem, bo)) { DBG(("%s: flushing before handle=%d for new reservation\n", __FUNCTION__, bo->handle)); flush = true; } return kgem->nreloc ? flush : false; } static bool aperture_check(struct kgem *kgem, unsigned num_pages) { struct drm_i915_gem_get_aperture aperture; int reserve; if (kgem->aperture) return false; /* Leave some space in case of alignment issues */ reserve = kgem->aperture_mappable / 2; if (kgem->gen < 033 && reserve < kgem->aperture_max_fence) reserve = kgem->aperture_max_fence; if (!kgem->has_llc) reserve += kgem->nexec * PAGE_SIZE * 2; DBG(("%s: num_pages=%d, holding %d pages in reserve, total aperture %d\n", __FUNCTION__, num_pages, reserve, kgem->aperture_total)); num_pages += reserve; VG_CLEAR(aperture); aperture.aper_available_size = kgem->aperture_total; aperture.aper_available_size *= PAGE_SIZE; (void)do_ioctl(kgem->fd, DRM_IOCTL_I915_GEM_GET_APERTURE, &aperture); DBG(("%s: aperture required %ld bytes, available %ld bytes\n", __FUNCTION__, (long)num_pages * PAGE_SIZE, (long)aperture.aper_available_size)); return num_pages <= aperture.aper_available_size / PAGE_SIZE; } static inline bool kgem_flush(struct kgem *kgem, bool flush) { if (unlikely(kgem->wedged)) return false; if (kgem->nreloc == 0) return true; if (__to_sna(kgem)->flags & SNA_POWERSAVE) return true; if (kgem->flush == flush && kgem->aperture < kgem->aperture_low) return true; DBG(("%s: opportunistic flushing? flush=%d,%d, aperture=%d/%d, idle?=%d\n", __FUNCTION__, kgem->flush, flush, kgem->aperture, kgem->aperture_low, kgem_ring_is_idle(kgem, kgem->ring))); return !kgem_ring_is_idle(kgem, kgem->ring); } bool kgem_check_bo(struct kgem *kgem, ...) { va_list ap; struct kgem_bo *bo; int num_exec = 0; int num_pages = 0; bool flush = false; bool busy = true; va_start(ap, kgem); while ((bo = va_arg(ap, struct kgem_bo *))) { while (bo->proxy) bo = bo->proxy; if (bo->exec) continue; if (needs_batch_flush(kgem, bo)) { va_end(ap); return false; } num_pages += num_pages(bo); num_exec++; flush |= bo->flush; busy &= bo->rq != NULL; } va_end(ap); DBG(("%s: num_pages=+%d, num_exec=+%d\n", __FUNCTION__, num_pages, num_exec)); if (!num_pages) return true; if (kgem->nexec + num_exec >= KGEM_EXEC_SIZE(kgem)) { DBG(("%s: out of exec slots (%d + %d / %d)\n", __FUNCTION__, kgem->nexec, num_exec, KGEM_EXEC_SIZE(kgem))); return false; } if (num_pages + kgem->aperture > kgem->aperture_high) { DBG(("%s: final aperture usage (%d + %d) is greater than high water mark (%d)\n", __FUNCTION__, kgem->aperture, num_pages, kgem->aperture_high)); return aperture_check(kgem, num_pages); } if (busy) return true; return kgem_flush(kgem, flush); } bool kgem_check_bo_fenced(struct kgem *kgem, struct kgem_bo *bo) { assert(bo->refcnt); while (bo->proxy) bo = bo->proxy; assert(bo->refcnt); if (bo->exec) { if (kgem->gen < 040 && bo->tiling != I915_TILING_NONE && (bo->exec->flags & EXEC_OBJECT_NEEDS_FENCE) == 0) { uint32_t size; assert(bo->tiling == I915_TILING_X); if (kgem->nfence >= kgem->fence_max) return false; if (kgem->aperture_fenced) { size = 3*kgem->aperture_fenced; if (kgem->aperture_total == kgem->aperture_mappable) size += kgem->aperture; if (size > kgem->aperture_fenceable && kgem_ring_is_idle(kgem, kgem->ring)) { DBG(("%s: opportunistic fence flush\n", __FUNCTION__)); return false; } } size = kgem_bo_fenced_size(kgem, bo); if (size > kgem->aperture_max_fence) kgem->aperture_max_fence = size; size += kgem->aperture_fenced; if (kgem->gen < 033 && size < 2 * kgem->aperture_max_fence) size = 2 * kgem->aperture_max_fence; if (kgem->aperture_total == kgem->aperture_mappable) size += kgem->aperture; if (size > kgem->aperture_fenceable) { DBG(("%s: estimated fence space required %d (fenced=%d, max_fence=%d, aperture=%d) exceeds fenceable aperture %d\n", __FUNCTION__, size, kgem->aperture_fenced, kgem->aperture_max_fence, kgem->aperture, kgem->aperture_fenceable)); return false; } } return true; } if (kgem->nexec >= KGEM_EXEC_SIZE(kgem) - 1) return false; if (needs_batch_flush(kgem, bo)) return false; assert_tiling(kgem, bo); if (kgem->gen < 040 && bo->tiling != I915_TILING_NONE) { uint32_t size; assert(bo->tiling == I915_TILING_X); if (kgem->nfence >= kgem->fence_max) return false; if (kgem->aperture_fenced) { size = 3*kgem->aperture_fenced; if (kgem->aperture_total == kgem->aperture_mappable) size += kgem->aperture; if (size > kgem->aperture_fenceable && kgem_ring_is_idle(kgem, kgem->ring)) { DBG(("%s: opportunistic fence flush\n", __FUNCTION__)); return false; } } size = kgem_bo_fenced_size(kgem, bo); if (size > kgem->aperture_max_fence) kgem->aperture_max_fence = size; size += kgem->aperture_fenced; if (kgem->gen < 033 && size < 2 * kgem->aperture_max_fence) size = 2 * kgem->aperture_max_fence; if (kgem->aperture_total == kgem->aperture_mappable) size += kgem->aperture; if (size > kgem->aperture_fenceable) { DBG(("%s: estimated fence space required %d (fenced=%d, max_fence=%d, aperture=%d) exceeds fenceable aperture %d\n", __FUNCTION__, size, kgem->aperture_fenced, kgem->aperture_max_fence, kgem->aperture, kgem->aperture_fenceable)); return false; } } if (kgem->aperture + kgem->aperture_fenced + num_pages(bo) > kgem->aperture_high) { DBG(("%s: final aperture usage (%d + %d) is greater than high water mark (%d)\n", __FUNCTION__, kgem->aperture, num_pages(bo), kgem->aperture_high)); return aperture_check(kgem, num_pages(bo)); } if (bo->rq) return true; return kgem_flush(kgem, bo->flush); } bool kgem_check_many_bo_fenced(struct kgem *kgem, ...) { va_list ap; struct kgem_bo *bo; int num_fence = 0; int num_exec = 0; int num_pages = 0; int fenced_size = 0; bool flush = false; bool busy = true; va_start(ap, kgem); while ((bo = va_arg(ap, struct kgem_bo *))) { assert(bo->refcnt); while (bo->proxy) bo = bo->proxy; assert(bo->refcnt); if (bo->exec) { if (kgem->gen >= 040 || bo->tiling == I915_TILING_NONE) continue; if ((bo->exec->flags & EXEC_OBJECT_NEEDS_FENCE) == 0) { fenced_size += kgem_bo_fenced_size(kgem, bo); num_fence++; } continue; } if (needs_batch_flush(kgem, bo)) { va_end(ap); return false; } assert_tiling(kgem, bo); num_pages += num_pages(bo); num_exec++; if (kgem->gen < 040 && bo->tiling) { uint32_t size = kgem_bo_fenced_size(kgem, bo); if (size > kgem->aperture_max_fence) kgem->aperture_max_fence = size; fenced_size += size; num_fence++; } flush |= bo->flush; busy &= bo->rq != NULL; } va_end(ap); if (num_fence) { uint32_t size; if (kgem->nfence + num_fence > kgem->fence_max) return false; if (kgem->aperture_fenced) { size = 3*kgem->aperture_fenced; if (kgem->aperture_total == kgem->aperture_mappable) size += kgem->aperture; if (size > kgem->aperture_fenceable && kgem_ring_is_idle(kgem, kgem->ring)) { DBG(("%s: opportunistic fence flush\n", __FUNCTION__)); return false; } } size = kgem->aperture_fenced; size += fenced_size; if (kgem->gen < 033 && size < 2 * kgem->aperture_max_fence) size = 2 * kgem->aperture_max_fence; if (kgem->aperture_total == kgem->aperture_mappable) size += kgem->aperture; if (size > kgem->aperture_fenceable) { DBG(("%s: estimated fence space required %d (fenced=%d, max_fence=%d, aperture=%d) exceeds fenceable aperture %d\n", __FUNCTION__, size, kgem->aperture_fenced, kgem->aperture_max_fence, kgem->aperture, kgem->aperture_fenceable)); return false; } } if (num_pages == 0) return true; if (kgem->nexec + num_exec >= KGEM_EXEC_SIZE(kgem)) return false; if (num_pages + kgem->aperture > kgem->aperture_high - kgem->aperture_fenced) { DBG(("%s: final aperture usage (%d + %d + %d) is greater than high water mark (%d)\n", __FUNCTION__, kgem->aperture, kgem->aperture_fenced, num_pages, kgem->aperture_high)); return aperture_check(kgem, num_pages); } if (busy) return true; return kgem_flush(kgem, flush); } void __kgem_bcs_set_tiling(struct kgem *kgem, struct kgem_bo *src, struct kgem_bo *dst) { uint32_t state, *b; DBG(("%s: src handle=%d:tiling=%d, dst handle=%d:tiling=%d\n", __FUNCTION__, src ? src->handle : 0, src ? src->tiling : 0, dst ? dst->handle : 0, dst ? dst->tiling : 0)); assert(kgem->mode == KGEM_BLT); assert(dst == NULL || kgem_bo_can_blt(kgem, dst)); assert(src == NULL || kgem_bo_can_blt(kgem, src)); state = 0; if (dst && dst->tiling == I915_TILING_Y) state |= BCS_DST_Y; if (src && src->tiling == I915_TILING_Y) state |= BCS_SRC_Y; if (kgem->bcs_state == state) return; DBG(("%s: updating SWCTRL %x -> %x\n", __FUNCTION__, kgem->bcs_state, state)); /* Over-estimate space in case we need to re-emit the cmd packet */ if (!kgem_check_batch(kgem, 24)) { _kgem_submit(kgem); _kgem_set_mode(kgem, KGEM_BLT); if (state == 0) return; } b = kgem->batch + kgem->nbatch; if (kgem->nbatch) { *b++ = MI_FLUSH_DW; *b++ = 0; *b++ = 0; *b++ = 0; } *b++ = MI_LOAD_REGISTER_IMM; *b++ = BCS_SWCTRL; *b++ = (BCS_SRC_Y | BCS_DST_Y) << 16 | state; kgem->nbatch = b - kgem->batch; kgem->bcs_state = state; } uint32_t kgem_add_reloc(struct kgem *kgem, uint32_t pos, struct kgem_bo *bo, uint32_t read_write_domain, uint32_t delta) { int index; DBG(("%s: handle=%d, pos=%d, delta=%d, domains=%08x\n", __FUNCTION__, bo ? bo->handle : 0, pos, delta, read_write_domain)); assert(kgem->gen < 0100); assert((read_write_domain & 0x7fff) == 0 || bo != NULL); index = kgem->nreloc++; assert(index < ARRAY_SIZE(kgem->reloc)); kgem->reloc[index].offset = pos * sizeof(kgem->batch[0]); if (bo) { assert(kgem->mode != KGEM_NONE); assert(bo->refcnt); while (bo->proxy) { DBG(("%s: adding proxy [delta=%d] for handle=%d\n", __FUNCTION__, bo->delta, bo->handle)); delta += bo->delta; assert(bo->handle == bo->proxy->handle); /* need to release the cache upon batch submit */ if (bo->exec == NULL) { list_move_tail(&bo->request, &kgem->next_request->buffers); bo->rq = MAKE_REQUEST(kgem->next_request, kgem->ring); bo->exec = &_kgem_dummy_exec; bo->domain = DOMAIN_GPU; } if (read_write_domain & 0x7fff && !bo->gpu_dirty) __kgem_bo_mark_dirty(bo); bo = bo->proxy; assert(bo->refcnt); } assert(bo->refcnt); if (bo->exec == NULL) kgem_add_bo(kgem, bo); assert(bo->rq == MAKE_REQUEST(kgem->next_request, kgem->ring)); assert(RQ_RING(bo->rq) == kgem->ring); if (kgem->gen < 040 && read_write_domain & KGEM_RELOC_FENCED) { if (bo->tiling && (bo->exec->flags & EXEC_OBJECT_NEEDS_FENCE) == 0) { assert(bo->tiling == I915_TILING_X); assert(kgem->nfence < kgem->fence_max); kgem->aperture_fenced += kgem_bo_fenced_size(kgem, bo); kgem->nfence++; } bo->exec->flags |= EXEC_OBJECT_NEEDS_FENCE; } kgem->reloc[index].delta = delta; kgem->reloc[index].target_handle = bo->target_handle; kgem->reloc[index].presumed_offset = bo->presumed_offset; if (read_write_domain & 0x7fff && !bo->gpu_dirty) { assert(!bo->snoop || kgem->can_blt_cpu); __kgem_bo_mark_dirty(bo); } delta += bo->presumed_offset; } else { kgem->reloc[index].delta = delta; kgem->reloc[index].target_handle = ~0U; kgem->reloc[index].presumed_offset = 0; if (kgem->nreloc__self < 256) kgem->reloc__self[kgem->nreloc__self++] = index; } kgem->reloc[index].read_domains = read_write_domain >> 16; kgem->reloc[index].write_domain = read_write_domain & 0x7fff; return delta; } uint64_t kgem_add_reloc64(struct kgem *kgem, uint32_t pos, struct kgem_bo *bo, uint32_t read_write_domain, uint64_t delta) { int index; DBG(("%s: handle=%d, pos=%d, delta=%ld, domains=%08x\n", __FUNCTION__, bo ? bo->handle : 0, pos, (long)delta, read_write_domain)); assert(kgem->gen >= 0100); assert((read_write_domain & 0x7fff) == 0 || bo != NULL); index = kgem->nreloc++; assert(index < ARRAY_SIZE(kgem->reloc)); kgem->reloc[index].offset = pos * sizeof(kgem->batch[0]); if (bo) { assert(kgem->mode != KGEM_NONE); assert(bo->refcnt); while (bo->proxy) { DBG(("%s: adding proxy [delta=%ld] for handle=%d\n", __FUNCTION__, (long)bo->delta, bo->handle)); delta += bo->delta; assert(bo->handle == bo->proxy->handle); /* need to release the cache upon batch submit */ if (bo->exec == NULL) { list_move_tail(&bo->request, &kgem->next_request->buffers); bo->rq = MAKE_REQUEST(kgem->next_request, kgem->ring); bo->exec = &_kgem_dummy_exec; bo->domain = DOMAIN_GPU; } if (read_write_domain & 0x7fff && !bo->gpu_dirty) __kgem_bo_mark_dirty(bo); bo = bo->proxy; assert(bo->refcnt); } assert(bo->refcnt); if (bo->exec == NULL) kgem_add_bo(kgem, bo); assert(bo->rq == MAKE_REQUEST(kgem->next_request, kgem->ring)); assert(RQ_RING(bo->rq) == kgem->ring); DBG(("%s[%d] = (delta=%d, target handle=%d, presumed=%llx)\n", __FUNCTION__, index, delta, bo->target_handle, (long long)bo->presumed_offset)); kgem->reloc[index].delta = delta; kgem->reloc[index].target_handle = bo->target_handle; kgem->reloc[index].presumed_offset = bo->presumed_offset; if (read_write_domain & 0x7fff && !bo->gpu_dirty) { assert(!bo->snoop || kgem->can_blt_cpu); __kgem_bo_mark_dirty(bo); } delta += bo->presumed_offset; } else { DBG(("%s[%d] = (delta=%d, target handle=batch)\n", __FUNCTION__, index, delta)); kgem->reloc[index].delta = delta; kgem->reloc[index].target_handle = ~0U; kgem->reloc[index].presumed_offset = 0; if (kgem->nreloc__self < 256) kgem->reloc__self[kgem->nreloc__self++] = index; } kgem->reloc[index].read_domains = read_write_domain >> 16; kgem->reloc[index].write_domain = read_write_domain & 0x7fff; return delta; } static void kgem_trim_vma_cache(struct kgem *kgem, int type, int bucket) { int i, j; DBG(("%s: type=%d, count=%d (bucket: %d)\n", __FUNCTION__, type, kgem->vma[type].count, bucket)); if (kgem->vma[type].count <= 0) return; if (kgem->need_purge) kgem_purge_cache(kgem); /* vma are limited on a per-process basis to around 64k. * This includes all malloc arenas as well as other file * mappings. In order to be fair and not hog the cache, * and more importantly not to exhaust that limit and to * start failing mappings, we keep our own number of open * vma to within a conservative value. */ i = 0; while (kgem->vma[type].count > 0) { struct kgem_bo *bo = NULL; for (j = 0; bo == NULL && j < ARRAY_SIZE(kgem->vma[type].inactive); j++) { struct list *head = &kgem->vma[type].inactive[i++%ARRAY_SIZE(kgem->vma[type].inactive)]; if (!list_is_empty(head)) bo = list_last_entry(head, struct kgem_bo, vma); } if (bo == NULL) break; DBG(("%s: discarding inactive %s vma cache for %d\n", __FUNCTION__, type ? "CPU" : "GTT", bo->handle)); assert(bo->rq == NULL); if (type) { VG(VALGRIND_MAKE_MEM_NOACCESS(MAP(bo->map__cpu), bytes(bo))); munmap(MAP(bo->map__cpu), bytes(bo)); bo->map__cpu = NULL; } else { if (bo->map__wc) { VG(VALGRIND_MAKE_MEM_NOACCESS(bo->map__wc, bytes(bo))); munmap(bo->map__wc, bytes(bo)); bo->map__wc = NULL; } if (bo->map__gtt) { munmap(bo->map__gtt, bytes(bo)); bo->map__gtt = NULL; } } list_del(&bo->vma); kgem->vma[type].count--; } } static void *__kgem_bo_map__gtt_or_wc(struct kgem *kgem, struct kgem_bo *bo) { void *ptr; DBG(("%s: handle=%d\n", __FUNCTION__, bo->handle)); assert(bo->proxy == NULL); assert(!bo->snoop); kgem_trim_vma_cache(kgem, MAP_GTT, bucket(bo)); if (bo->tiling || !kgem->has_wc_mmap) { assert(kgem->gen != 021 || bo->tiling != I915_TILING_Y); warn_unless(num_pages(bo) <= kgem->aperture_mappable / 2); ptr = bo->map__gtt; if (ptr == NULL) ptr = __kgem_bo_map__gtt(kgem, bo); } else { ptr = bo->map__wc; if (ptr == NULL) ptr = __kgem_bo_map__wc(kgem, bo); } return ptr; } void *kgem_bo_map__async(struct kgem *kgem, struct kgem_bo *bo) { DBG(("%s: handle=%d, offset=%ld, tiling=%d, map=%p:%p, domain=%d\n", __FUNCTION__, bo->handle, (long)bo->presumed_offset, bo->tiling, bo->map__gtt, bo->map__cpu, bo->domain)); assert(bo->proxy == NULL); assert(list_is_empty(&bo->list)); assert_tiling(kgem, bo); assert(!bo->purged || bo->reusable); if (bo->tiling == I915_TILING_NONE && !bo->scanout && kgem->has_llc) { DBG(("%s: converting request for GTT map into CPU map\n", __FUNCTION__)); return kgem_bo_map__cpu(kgem, bo); } return __kgem_bo_map__gtt_or_wc(kgem, bo); } void *kgem_bo_map(struct kgem *kgem, struct kgem_bo *bo) { void *ptr; DBG(("%s: handle=%d, offset=%ld, tiling=%d, map=%p:%p, domain=%d\n", __FUNCTION__, bo->handle, (long)bo->presumed_offset, bo->tiling, bo->map__gtt, bo->map__cpu, bo->domain)); assert(bo->proxy == NULL); assert(list_is_empty(&bo->list)); assert(bo->exec == NULL); assert_tiling(kgem, bo); assert(!bo->purged || bo->reusable); if (bo->tiling == I915_TILING_NONE && !bo->scanout && (kgem->has_llc || bo->domain == DOMAIN_CPU)) { DBG(("%s: converting request for GTT map into CPU map\n", __FUNCTION__)); ptr = kgem_bo_map__cpu(kgem, bo); if (ptr) kgem_bo_sync__cpu(kgem, bo); return ptr; } ptr = __kgem_bo_map__gtt_or_wc(kgem, bo); if (bo->domain != DOMAIN_GTT || FORCE_MMAP_SYNC & (1 << DOMAIN_GTT)) { struct drm_i915_gem_set_domain set_domain; DBG(("%s: sync: needs_flush? %d, domain? %d, busy? %d\n", __FUNCTION__, bo->needs_flush, bo->domain, __kgem_busy(kgem, bo->handle))); /* XXX use PROT_READ to avoid the write flush? */ VG_CLEAR(set_domain); set_domain.handle = bo->handle; set_domain.read_domains = I915_GEM_DOMAIN_GTT; set_domain.write_domain = I915_GEM_DOMAIN_GTT; if (do_ioctl(kgem->fd, DRM_IOCTL_I915_GEM_SET_DOMAIN, &set_domain)) { DBG(("%s: sync: GPU hang detected\n", __FUNCTION__)); kgem_throttle(kgem); } bo->needs_flush = false; kgem_bo_retire(kgem, bo); bo->domain = DOMAIN_GTT; bo->gtt_dirty = true; } return ptr; } void *kgem_bo_map__gtt(struct kgem *kgem, struct kgem_bo *bo) { DBG(("%s: handle=%d, offset=%ld, tiling=%d, map=%p:%p, domain=%d\n", __FUNCTION__, bo->handle, (long)bo->presumed_offset, bo->tiling, bo->map__gtt, bo->map__cpu, bo->domain)); assert(bo->proxy == NULL); assert(bo->exec == NULL); assert(list_is_empty(&bo->list)); assert_tiling(kgem, bo); assert(!bo->purged || bo->reusable); return __kgem_bo_map__gtt_or_wc(kgem, bo); } void *kgem_bo_map__wc(struct kgem *kgem, struct kgem_bo *bo) { DBG(("%s: handle=%d, offset=%ld, tiling=%d, map=%p:%p, domain=%d\n", __FUNCTION__, bo->handle, (long)bo->presumed_offset, bo->tiling, bo->map__gtt, bo->map__cpu, bo->domain)); assert(bo->proxy == NULL); assert(list_is_empty(&bo->list)); assert_tiling(kgem, bo); assert(!bo->purged || bo->reusable); if (bo->map__wc) return bo->map__wc; if (!kgem->has_wc_mmap) return NULL; kgem_trim_vma_cache(kgem, MAP_GTT, bucket(bo)); return __kgem_bo_map__wc(kgem, bo); } void *kgem_bo_map__cpu(struct kgem *kgem, struct kgem_bo *bo) { DBG(("%s(handle=%d, size=%d, map=%p:%p)\n", __FUNCTION__, bo->handle, bytes(bo), bo->map__gtt, bo->map__cpu)); assert(!bo->purged); assert(list_is_empty(&bo->list)); assert(bo->proxy == NULL); assert_tiling(kgem, bo); if (bo->map__cpu) return MAP(bo->map__cpu); kgem_trim_vma_cache(kgem, MAP_CPU, bucket(bo)); return __kgem_bo_map__cpu(kgem, bo); } void *kgem_bo_map__debug(struct kgem *kgem, struct kgem_bo *bo) { void *ptr; if (bo->tiling == I915_TILING_NONE && kgem->has_llc) { ptr = MAP(bo->map__cpu); if (ptr == NULL) ptr = __kgem_bo_map__cpu(kgem, bo); } else if (bo->tiling || !kgem->has_wc_mmap) { ptr = bo->map__gtt; if (ptr == NULL) ptr = __kgem_bo_map__gtt(kgem, bo); } else { ptr = bo->map__wc; if (ptr == NULL) ptr = __kgem_bo_map__wc(kgem, bo); } return ptr; } uint32_t kgem_bo_flink(struct kgem *kgem, struct kgem_bo *bo) { struct drm_gem_flink flink; assert(kgem_bo_is_fenced(kgem, bo)); VG_CLEAR(flink); flink.handle = bo->handle; if (do_ioctl(kgem->fd, DRM_IOCTL_GEM_FLINK, &flink)) return 0; DBG(("%s: flinked handle=%d to name=%d, marking non-reusable\n", __FUNCTION__, flink.handle, flink.name)); /* Ordinarily giving the name aware makes the buffer non-reusable. * However, we track the lifetime of all clients and their hold * on the buffer, and *presuming* they do not pass it on to a third * party, we track the lifetime accurately. */ bo->reusable = false; kgem_bo_unclean(kgem, bo); return flink.name; } static bool probe(struct kgem *kgem, uint32_t handle) { struct drm_i915_gem_set_domain arg = { .handle = handle, .read_domains = I915_GEM_DOMAIN_CPU, }; return do_ioctl(kgem->fd, DRM_IOCTL_I915_GEM_SET_DOMAIN, &arg) == 0; } static uint32_t probe_userptr(struct kgem *kgem, void *ptr, size_t size, int read_only) { uint32_t handle; handle = gem_userptr(kgem->fd, ptr, size, read_only); if (handle && !probe(kgem, handle)) { gem_close(kgem->fd, handle); handle = 0; } return handle; } struct kgem_bo *kgem_create_map(struct kgem *kgem, void *ptr, uint32_t size, bool read_only) { struct kgem_bo *bo; uintptr_t first_page, last_page; uint32_t handle; assert(MAP(ptr) == ptr); DBG(("%s(%p size=%d, read-only?=%d) - has_userptr?=%d\n", __FUNCTION__, ptr, size, read_only, kgem->has_userptr)); if (!kgem->has_userptr) return NULL; first_page = (uintptr_t)ptr; last_page = first_page + size + PAGE_SIZE - 1; first_page &= ~(uintptr_t)(PAGE_SIZE-1); last_page &= ~(uintptr_t)(PAGE_SIZE-1); assert(last_page > first_page); handle = probe_userptr(kgem, (void *)first_page, last_page-first_page, read_only); if (handle == 0 && read_only && kgem->has_wc_mmap) handle = probe_userptr(kgem, (void *)first_page, last_page-first_page, false); if (handle == 0) { DBG(("%s: import failed, errno=%d\n", __FUNCTION__, errno)); return NULL; } bo = __kgem_bo_alloc(handle, (last_page - first_page) / PAGE_SIZE); if (bo == NULL) { gem_close(kgem->fd, handle); return NULL; } bo->unique_id = kgem_get_unique_id(kgem); bo->snoop = !kgem->has_llc; debug_alloc__bo(kgem, bo); if (first_page != (uintptr_t)ptr) { struct kgem_bo *proxy; proxy = kgem_create_proxy(kgem, bo, (uintptr_t)ptr - first_page, size); kgem_bo_destroy(kgem, bo); if (proxy == NULL) return NULL; bo = proxy; } bo->map__cpu = MAKE_USER_MAP(ptr); DBG(("%s(ptr=%p, size=%d, pages=%d, read_only=%d) => handle=%d (proxy? %d)\n", __FUNCTION__, ptr, size, NUM_PAGES(size), read_only, handle, bo->proxy != NULL)); return bo; } void kgem_bo_sync__cpu(struct kgem *kgem, struct kgem_bo *bo) { DBG(("%s: handle=%d\n", __FUNCTION__, bo->handle)); assert(!bo->scanout); assert_tiling(kgem, bo); kgem_bo_submit(kgem, bo); /* SHM pixmaps use proxies for subpage offsets */ assert(!bo->purged); while (bo->proxy) bo = bo->proxy; assert(!bo->purged); if (bo->domain != DOMAIN_CPU || FORCE_MMAP_SYNC & (1 << DOMAIN_CPU)) { struct drm_i915_gem_set_domain set_domain; DBG(("%s: SYNC: handle=%d, needs_flush? %d, domain? %d, busy? %d\n", __FUNCTION__, bo->handle, bo->needs_flush, bo->domain, __kgem_busy(kgem, bo->handle))); VG_CLEAR(set_domain); set_domain.handle = bo->handle; set_domain.read_domains = I915_GEM_DOMAIN_CPU; set_domain.write_domain = I915_GEM_DOMAIN_CPU; if (do_ioctl(kgem->fd, DRM_IOCTL_I915_GEM_SET_DOMAIN, &set_domain)) { DBG(("%s: sync: GPU hang detected\n", __FUNCTION__)); kgem_throttle(kgem); } bo->needs_flush = false; kgem_bo_retire(kgem, bo); bo->domain = DOMAIN_CPU; bo->gtt_dirty = true; } } void kgem_bo_sync__cpu_full(struct kgem *kgem, struct kgem_bo *bo, bool write) { DBG(("%s: handle=%d\n", __FUNCTION__, bo->handle)); assert(!bo->scanout || !write); assert_tiling(kgem, bo); if (write || bo->needs_flush) kgem_bo_submit(kgem, bo); /* SHM pixmaps use proxies for subpage offsets */ assert(!bo->purged); assert(bo->refcnt); while (bo->proxy) bo = bo->proxy; assert(bo->refcnt); assert(!bo->purged); if (bo->rq == NULL && (kgem->has_llc || bo->snoop) && !write) return; if (bo->domain != DOMAIN_CPU || FORCE_MMAP_SYNC & (1 << DOMAIN_CPU)) { struct drm_i915_gem_set_domain set_domain; DBG(("%s: SYNC: handle=%d, needs_flush? %d, domain? %d, busy? %d\n", __FUNCTION__, bo->handle, bo->needs_flush, bo->domain, __kgem_busy(kgem, bo->handle))); VG_CLEAR(set_domain); set_domain.handle = bo->handle; set_domain.read_domains = I915_GEM_DOMAIN_CPU; set_domain.write_domain = write ? I915_GEM_DOMAIN_CPU : 0; if (do_ioctl(kgem->fd, DRM_IOCTL_I915_GEM_SET_DOMAIN, &set_domain)) { DBG(("%s: sync: GPU hang detected\n", __FUNCTION__)); kgem_throttle(kgem); } bo->needs_flush = false; if (write) { kgem_bo_retire(kgem, bo); bo->domain = DOMAIN_CPU; bo->gtt_dirty = true; } else { if (bo->exec == NULL) kgem_bo_maybe_retire(kgem, bo); bo->domain = DOMAIN_NONE; } } } void kgem_bo_sync__gtt(struct kgem *kgem, struct kgem_bo *bo) { DBG(("%s: handle=%d\n", __FUNCTION__, bo->handle)); assert(bo->refcnt); assert(bo->proxy == NULL); assert_tiling(kgem, bo); assert(!bo->snoop); kgem_bo_submit(kgem, bo); if (bo->domain != DOMAIN_GTT || !kgem->has_coherent_mmap_gtt || FORCE_MMAP_SYNC & (1 << DOMAIN_GTT)) { struct drm_i915_gem_set_domain set_domain; DBG(("%s: SYNC: handle=%d, needs_flush? %d, domain? %d, busy? %d\n", __FUNCTION__, bo->handle, bo->needs_flush, bo->domain, __kgem_busy(kgem, bo->handle))); VG_CLEAR(set_domain); set_domain.handle = bo->handle; set_domain.read_domains = I915_GEM_DOMAIN_GTT; set_domain.write_domain = I915_GEM_DOMAIN_GTT; if (do_ioctl(kgem->fd, DRM_IOCTL_I915_GEM_SET_DOMAIN, &set_domain)) { DBG(("%s: sync: GPU hang detected\n", __FUNCTION__)); kgem_throttle(kgem); } bo->needs_flush = false; kgem_bo_retire(kgem, bo); bo->domain = DOMAIN_GTT; bo->gtt_dirty = true; } } void kgem_clear_dirty(struct kgem *kgem) { struct list * const buffers = &kgem->next_request->buffers; struct kgem_bo *bo; list_for_each_entry(bo, buffers, request) { if (!bo->gpu_dirty) break; bo->gpu_dirty = false; } } struct kgem_bo *kgem_create_proxy(struct kgem *kgem, struct kgem_bo *target, int offset, int length) { struct kgem_bo *bo; DBG(("%s: target handle=%d [proxy? %d], offset=%d, length=%d, io=%d\n", __FUNCTION__, target->handle, target->proxy ? target->proxy->delta : -1, offset, length, target->io)); bo = __kgem_bo_alloc(target->handle, length); if (bo == NULL) return NULL; bo->unique_id = kgem_get_unique_id(kgem); bo->reusable = false; bo->size.bytes = length; bo->io = target->io && target->proxy == NULL; bo->gpu_dirty = target->gpu_dirty; bo->tiling = target->tiling; bo->pitch = target->pitch; bo->flush = target->flush; bo->snoop = target->snoop; assert(!bo->scanout); bo->proxy = kgem_bo_reference(target); bo->delta = offset; /* Proxies are only tracked for busyness on the current rq */ if (target->exec && !bo->io) { assert(RQ(target->rq) == kgem->next_request); list_move_tail(&bo->request, &kgem->next_request->buffers); bo->exec = &_kgem_dummy_exec; bo->rq = target->rq; } return bo; } static struct kgem_buffer * buffer_alloc(void) { struct kgem_buffer *bo; bo = malloc(sizeof(*bo)); if (bo == NULL) return NULL; bo->mem = NULL; bo->need_io = false; bo->mmapped = MMAPPED_CPU; return bo; } static struct kgem_buffer * buffer_alloc_with_data(int num_pages) { struct kgem_buffer *bo; bo = malloc(sizeof(*bo) + 2*UPLOAD_ALIGNMENT + num_pages * PAGE_SIZE); if (bo == NULL) return NULL; bo->mem = (void *)ALIGN((uintptr_t)bo + sizeof(*bo), UPLOAD_ALIGNMENT); bo->mmapped = false; return bo; } static inline bool use_snoopable_buffer(struct kgem *kgem, uint32_t flags) { if ((flags & KGEM_BUFFER_WRITE) == 0) return kgem->gen >= 030; return true; } static void init_buffer_from_bo(struct kgem_buffer *bo, struct kgem_bo *old) { DBG(("%s: reusing handle=%d for buffer\n", __FUNCTION__, old->handle)); assert(old->proxy == NULL); assert(list_is_empty(&old->list)); memcpy(&bo->base, old, sizeof(*old)); if (old->rq) list_replace(&old->request, &bo->base.request); else list_init(&bo->base.request); list_replace(&old->vma, &bo->base.vma); list_init(&bo->base.list); free(old); assert(bo->base.tiling == I915_TILING_NONE); bo->base.refcnt = 1; } static struct kgem_buffer * search_snoopable_buffer(struct kgem *kgem, unsigned alloc) { struct kgem_buffer *bo; struct kgem_bo *old; old = search_snoop_cache(kgem, alloc, 0); if (old) { if (!old->io) { bo = buffer_alloc(); if (bo == NULL) return NULL; init_buffer_from_bo(bo, old); } else { bo = (struct kgem_buffer *)old; bo->base.refcnt = 1; } DBG(("%s: created CPU handle=%d for buffer, size %d\n", __FUNCTION__, bo->base.handle, num_pages(&bo->base))); assert(bo->base.snoop); assert(bo->base.tiling == I915_TILING_NONE); assert(num_pages(&bo->base) >= alloc); assert(bo->mmapped == MMAPPED_CPU); assert(bo->need_io == false); bo->mem = kgem_bo_map__cpu(kgem, &bo->base); if (bo->mem == NULL) { bo->base.refcnt = 0; kgem_bo_free(kgem, &bo->base); bo = NULL; } return bo; } return NULL; } static struct kgem_buffer * create_snoopable_buffer(struct kgem *kgem, unsigned alloc) { struct kgem_buffer *bo; uint32_t handle; if (kgem->has_llc) { struct kgem_bo *old; bo = buffer_alloc(); if (bo == NULL) return NULL; old = search_linear_cache(kgem, alloc, CREATE_INACTIVE | CREATE_CPU_MAP | CREATE_EXACT); if (old) { init_buffer_from_bo(bo, old); } else { handle = gem_create(kgem->fd, alloc); if (handle == 0) { free(bo); return NULL; } __kgem_bo_init(&bo->base, handle, alloc); debug_alloc__bo(kgem, &bo->base); DBG(("%s: created CPU (LLC) handle=%d for buffer, size %d\n", __FUNCTION__, bo->base.handle, alloc)); } assert(bo->base.refcnt == 1); assert(bo->mmapped == MMAPPED_CPU); assert(bo->need_io == false); bo->mem = kgem_bo_map__cpu(kgem, &bo->base); if (bo->mem != NULL) return bo; bo->base.refcnt = 0; /* for valgrind */ kgem_bo_free(kgem, &bo->base); } if (kgem->has_caching) { struct kgem_bo *old; bo = buffer_alloc(); if (bo == NULL) return NULL; old = search_linear_cache(kgem, alloc, CREATE_INACTIVE | CREATE_CPU_MAP | CREATE_EXACT); if (old) { init_buffer_from_bo(bo, old); } else { handle = gem_create(kgem->fd, alloc); if (handle == 0) { free(bo); return NULL; } __kgem_bo_init(&bo->base, handle, alloc); debug_alloc__bo(kgem, &bo->base); DBG(("%s: created CPU handle=%d for buffer, size %d\n", __FUNCTION__, bo->base.handle, alloc)); } assert(bo->base.refcnt == 1); assert(bo->mmapped == MMAPPED_CPU); assert(bo->need_io == false); assert(!__kgem_busy(kgem, bo->base.handle)); if (!gem_set_caching(kgem->fd, bo->base.handle, SNOOPED)) goto free_caching; bo->base.snoop = true; bo->mem = kgem_bo_map__cpu(kgem, &bo->base); if (bo->mem == NULL) goto free_caching; return bo; free_caching: bo->base.refcnt = 0; /* for valgrind */ kgem_bo_free(kgem, &bo->base); } if (kgem->has_userptr) { bo = buffer_alloc(); if (bo == NULL) return NULL; //if (posix_memalign(&ptr, 64, ALIGN(size, 64))) if (posix_memalign(&bo->mem, PAGE_SIZE, alloc * PAGE_SIZE)) { free(bo); return NULL; } handle = gem_userptr(kgem->fd, bo->mem, alloc * PAGE_SIZE, false); if (handle == 0) { free(bo->mem); free(bo); return NULL; } __kgem_bo_init(&bo->base, handle, alloc); debug_alloc__bo(kgem, &bo->base); DBG(("%s: created snoop handle=%d for buffer\n", __FUNCTION__, bo->base.handle)); assert(bo->mmapped == MMAPPED_CPU); assert(bo->need_io == false); bo->base.refcnt = 1; bo->base.snoop = true; bo->base.map__cpu = MAKE_USER_MAP(bo->mem); return bo; } return NULL; } struct kgem_bo *kgem_create_buffer(struct kgem *kgem, uint32_t size, uint32_t flags, void **ret) { struct kgem_buffer *bo; unsigned offset, alloc; struct kgem_bo *old; DBG(("%s: size=%d, flags=%x [write?=%d, inplace?=%d, last?=%d]\n", __FUNCTION__, size, flags, !!(flags & KGEM_BUFFER_WRITE), !!(flags & KGEM_BUFFER_INPLACE), !!(flags & KGEM_BUFFER_LAST))); assert(size); /* we should never be asked to create anything TOO large */ assert(size <= kgem->max_object_size); #if !DBG_NO_UPLOAD_CACHE list_for_each_entry(bo, &kgem->batch_buffers, base.list) { assert(bo->base.io); assert(bo->base.refcnt >= 1); /* We can reuse any write buffer which we can fit */ if (flags == KGEM_BUFFER_LAST && bo->write == KGEM_BUFFER_WRITE && bo->base.refcnt == 1 && bo->mmapped == MMAPPED_NONE && size <= bytes(&bo->base)) { DBG(("%s: reusing write buffer for read of %d bytes? used=%d, total=%d\n", __FUNCTION__, size, bo->used, bytes(&bo->base))); gem_write__cachealigned(kgem->fd, bo->base.handle, 0, bo->used, bo->mem); assert(list_is_empty(&bo->base.vma)); bo->need_io = 0; bo->write = 0; offset = 0; bo->used = size; goto done; } if (flags & KGEM_BUFFER_WRITE) { if ((bo->write & KGEM_BUFFER_WRITE) == 0 || (((bo->write & ~flags) & KGEM_BUFFER_INPLACE) && !bo->base.snoop)) { DBG(("%s: skip write %x buffer, need %x\n", __FUNCTION__, bo->write, flags)); continue; } assert(bo->mmapped || bo->need_io); } else { if (bo->write & KGEM_BUFFER_WRITE) { DBG(("%s: skip write %x buffer, need %x\n", __FUNCTION__, bo->write, flags)); continue; } } if (bo->used + size <= bytes(&bo->base)) { DBG(("%s: reusing buffer? used=%d + size=%d, total=%d\n", __FUNCTION__, bo->used, size, bytes(&bo->base))); offset = bo->used; bo->used += size; goto done; } } if (flags & KGEM_BUFFER_WRITE) { list_for_each_entry(bo, &kgem->active_buffers, base.list) { assert(bo->base.io); assert(bo->base.refcnt >= 1); assert(bo->base.exec == NULL); assert(bo->mmapped); assert(bo->mmapped == MMAPPED_GTT || kgem->has_llc || bo->base.snoop); if ((bo->write & ~flags) & KGEM_BUFFER_INPLACE && !bo->base.snoop) { DBG(("%s: skip write %x buffer, need %x\n", __FUNCTION__, bo->write, flags)); continue; } if (bo->used + size <= bytes(&bo->base)) { DBG(("%s: reusing buffer? used=%d + size=%d, total=%d\n", __FUNCTION__, bo->used, size, bytes(&bo->base))); offset = bo->used; bo->used += size; list_move(&bo->base.list, &kgem->batch_buffers); goto done; } if (bo->base.refcnt == 1 && size <= bytes(&bo->base) && (bo->base.rq == NULL || !__kgem_busy(kgem, bo->base.handle))) { DBG(("%s: reusing whole buffer? size=%d, total=%d\n", __FUNCTION__, size, bytes(&bo->base))); __kgem_bo_clear_busy(&bo->base); assert(list_is_empty(&bo->base.vma)); switch (bo->mmapped) { case MMAPPED_CPU: kgem_bo_sync__cpu(kgem, &bo->base); break; case MMAPPED_GTT: kgem_bo_sync__gtt(kgem, &bo->base); break; } offset = 0; bo->used = size; list_move(&bo->base.list, &kgem->batch_buffers); goto done; } } } #endif #if !DBG_NO_MAP_UPLOAD /* Be a little more generous and hope to hold fewer mmappings */ alloc = ALIGN(2*size, kgem->buffer_size); if (alloc > MAX_CACHE_SIZE) alloc = ALIGN(size, kgem->buffer_size); if (alloc > MAX_CACHE_SIZE) alloc = PAGE_ALIGN(size); assert(alloc); alloc /= PAGE_SIZE; if (alloc > kgem->aperture_mappable / 4 && !kgem->has_wc_mmap) flags &= ~KGEM_BUFFER_INPLACE; if (kgem->has_llc && (flags & KGEM_BUFFER_WRITE_INPLACE) != KGEM_BUFFER_WRITE_INPLACE) { bo = buffer_alloc(); if (bo == NULL) goto skip_llc; old = NULL; if ((flags & KGEM_BUFFER_WRITE) == 0) old = search_linear_cache(kgem, alloc, CREATE_CPU_MAP); if (old == NULL) old = search_linear_cache(kgem, alloc, CREATE_INACTIVE | CREATE_CPU_MAP); if (old == NULL) old = search_linear_cache(kgem, NUM_PAGES(size), CREATE_INACTIVE | CREATE_CPU_MAP); if (old) { DBG(("%s: found LLC handle=%d for buffer\n", __FUNCTION__, old->handle)); init_buffer_from_bo(bo, old); } else { uint32_t handle = gem_create(kgem->fd, alloc); if (handle == 0) { free(bo); goto skip_llc; } __kgem_bo_init(&bo->base, handle, alloc); debug_alloc__bo(kgem, &bo->base); DBG(("%s: created LLC handle=%d for buffer\n", __FUNCTION__, bo->base.handle)); } assert(bo->mmapped); assert(!bo->need_io); bo->mem = kgem_bo_map__cpu(kgem, &bo->base); if (bo->mem) { if (flags & KGEM_BUFFER_WRITE) kgem_bo_sync__cpu(kgem, &bo->base); flags &= ~KGEM_BUFFER_INPLACE; goto init; } else { bo->base.refcnt = 0; /* for valgrind */ kgem_bo_free(kgem, &bo->base); } } skip_llc: if ((flags & KGEM_BUFFER_WRITE_INPLACE) == KGEM_BUFFER_WRITE_INPLACE) { /* The issue with using a GTT upload buffer is that we may * cause eviction-stalls in order to free up some GTT space. * An is-mappable? ioctl could help us detect when we are * about to block, or some per-page magic in the kernel. * * XXX This is especially noticeable on memory constrained * devices like gen2 or with relatively slow gpu like i3. */ DBG(("%s: searching for an inactive GTT map for upload\n", __FUNCTION__)); old = search_linear_cache(kgem, alloc, CREATE_EXACT | CREATE_INACTIVE | CREATE_GTT_MAP); #if HAVE_I915_GEM_BUFFER_INFO if (old) { struct drm_i915_gem_buffer_info info; /* An example of such a non-blocking ioctl might work */ VG_CLEAR(info); info.handle = handle; if (do_ioctl(kgem->fd, DRM_IOCTL_I915_GEM_BUFFER_INFO, &fino) == 0) { old->presumed_offset = info.addr; if ((info.flags & I915_GEM_MAPPABLE) == 0) { kgem_bo_move_to_inactive(kgem, old); old = NULL; } } } #endif if (old == NULL) old = search_linear_cache(kgem, NUM_PAGES(size), CREATE_EXACT | CREATE_INACTIVE | CREATE_GTT_MAP); if (old == NULL) { old = search_linear_cache(kgem, alloc, CREATE_INACTIVE); if (old && !kgem_bo_can_map(kgem, old)) { _kgem_bo_destroy(kgem, old); old = NULL; } } if (old) { DBG(("%s: reusing handle=%d for buffer\n", __FUNCTION__, old->handle)); assert(kgem_bo_can_map(kgem, old)); assert(!old->snoop); assert(old->rq == NULL); bo = buffer_alloc(); if (bo == NULL) return NULL; init_buffer_from_bo(bo, old); assert(num_pages(&bo->base) >= NUM_PAGES(size)); assert(bo->mmapped); assert(bo->base.refcnt == 1); bo->mem = kgem_bo_map(kgem, &bo->base); if (bo->mem) { if (bo->mem == MAP(bo->base.map__cpu)) flags &= ~KGEM_BUFFER_INPLACE; else bo->mmapped = MMAPPED_GTT; goto init; } else { bo->base.refcnt = 0; kgem_bo_free(kgem, &bo->base); } } } #else flags &= ~KGEM_BUFFER_INPLACE; #endif /* Be more parsimonious with pwrite/pread/cacheable buffers */ if ((flags & KGEM_BUFFER_INPLACE) == 0) alloc = NUM_PAGES(size); if (use_snoopable_buffer(kgem, flags)) { bo = search_snoopable_buffer(kgem, alloc); if (bo) { if (flags & KGEM_BUFFER_WRITE) kgem_bo_sync__cpu(kgem, &bo->base); flags &= ~KGEM_BUFFER_INPLACE; goto init; } if ((flags & KGEM_BUFFER_INPLACE) == 0) { bo = create_snoopable_buffer(kgem, alloc); if (bo) goto init; } } flags &= ~KGEM_BUFFER_INPLACE; old = NULL; if ((flags & KGEM_BUFFER_WRITE) == 0) old = search_linear_cache(kgem, alloc, 0); if (old == NULL) old = search_linear_cache(kgem, alloc, CREATE_INACTIVE); if (old) { DBG(("%s: reusing ordinary handle %d for io\n", __FUNCTION__, old->handle)); bo = buffer_alloc_with_data(num_pages(old)); if (bo == NULL) return NULL; init_buffer_from_bo(bo, old); bo->need_io = flags & KGEM_BUFFER_WRITE; } else { unsigned hint; if (use_snoopable_buffer(kgem, flags)) { bo = create_snoopable_buffer(kgem, alloc); if (bo) goto init; } bo = buffer_alloc(); if (bo == NULL) return NULL; hint = CREATE_INACTIVE; if (flags & KGEM_BUFFER_WRITE) hint |= CREATE_CPU_MAP; old = search_linear_cache(kgem, alloc, hint); if (old) { DBG(("%s: reusing handle=%d for buffer\n", __FUNCTION__, old->handle)); init_buffer_from_bo(bo, old); } else { uint32_t handle = gem_create(kgem->fd, alloc); if (handle == 0) { free(bo); return NULL; } DBG(("%s: created handle=%d for buffer\n", __FUNCTION__, handle)); __kgem_bo_init(&bo->base, handle, alloc); debug_alloc__bo(kgem, &bo->base); } assert(bo->mmapped); assert(!bo->need_io); assert(bo->base.refcnt == 1); if (flags & KGEM_BUFFER_WRITE) { bo->mem = kgem_bo_map__cpu(kgem, &bo->base); if (bo->mem != NULL) { kgem_bo_sync__cpu(kgem, &bo->base); goto init; } } DBG(("%s: failing back to new pwrite buffer\n", __FUNCTION__)); old = &bo->base; bo = buffer_alloc_with_data(num_pages(old)); if (bo == NULL) { old->refcnt= 0; kgem_bo_free(kgem, old); return NULL; } init_buffer_from_bo(bo, old); assert(bo->mem); assert(!bo->mmapped); assert(bo->base.refcnt == 1); bo->need_io = flags & KGEM_BUFFER_WRITE; } init: bo->base.io = true; assert(bo->base.refcnt == 1); assert(num_pages(&bo->base) >= NUM_PAGES(size)); assert(!bo->need_io || !bo->base.needs_flush); assert(!bo->need_io || bo->base.domain != DOMAIN_GPU); assert(bo->mem); assert(bo->mmapped != MMAPPED_GTT || bo->base.map__gtt == bo->mem || bo->base.map__wc == bo->mem); assert(bo->mmapped != MMAPPED_CPU || MAP(bo->base.map__cpu) == bo->mem); bo->used = size; bo->write = flags & KGEM_BUFFER_WRITE_INPLACE; offset = 0; assert(list_is_empty(&bo->base.list)); list_add(&bo->base.list, &kgem->batch_buffers); DBG(("%s(pages=%d [%d]) new handle=%d, used=%d, write=%d\n", __FUNCTION__, num_pages(&bo->base), alloc, bo->base.handle, bo->used, bo->write)); done: bo->used = ALIGN(bo->used, UPLOAD_ALIGNMENT); assert(bo->used && bo->used <= bytes(&bo->base)); assert(bo->mem); *ret = (char *)bo->mem + offset; return kgem_create_proxy(kgem, &bo->base, offset, size); } bool kgem_buffer_is_inplace(struct kgem_bo *_bo) { struct kgem_buffer *bo = (struct kgem_buffer *)_bo->proxy; return bo->write & KGEM_BUFFER_WRITE_INPLACE; } struct kgem_bo *kgem_create_buffer_2d(struct kgem *kgem, int width, int height, int bpp, uint32_t flags, void **ret) { struct kgem_bo *bo; int stride; assert(width > 0 && height > 0); assert(ret != NULL); stride = ALIGN(width, 2) * bpp >> 3; stride = ALIGN(stride, kgem->gen >= 0100 ? 32 : 4); DBG(("%s: %dx%d, %d bpp, stride=%d\n", __FUNCTION__, width, height, bpp, stride)); bo = kgem_create_buffer(kgem, stride * ALIGN(height, 2), flags, ret); if (bo == NULL) { DBG(("%s: allocation failure for upload buffer\n", __FUNCTION__)); return NULL; } assert(*ret != NULL); assert(bo->proxy != NULL); if (height & 1) { struct kgem_buffer *io = (struct kgem_buffer *)bo->proxy; int min; assert(io->used); /* Having padded this surface to ensure that accesses to * the last pair of rows is valid, remove the padding so * that it can be allocated to other pixmaps. */ min = bo->delta + height * stride; min = ALIGN(min, UPLOAD_ALIGNMENT); if (io->used != min) { DBG(("%s: trimming buffer from %d to %d\n", __FUNCTION__, io->used, min)); io->used = min; } bo->size.bytes -= stride; } bo->map__cpu = *ret; bo->pitch = stride; bo->unique_id = kgem_get_unique_id(kgem); return bo; } struct kgem_bo *kgem_upload_source_image(struct kgem *kgem, const void *data, const BoxRec *box, int stride, int bpp) { int width = box->x2 - box->x1; int height = box->y2 - box->y1; struct kgem_bo *bo; void *dst; if (!kgem_can_create_2d(kgem, width, height, bpp)) return NULL; DBG(("%s : (%d, %d), (%d, %d), stride=%d, bpp=%d\n", __FUNCTION__, box->x1, box->y1, box->x2, box->y2, stride, bpp)); assert(data); assert(width > 0); assert(height > 0); assert(stride); assert(bpp); bo = kgem_create_buffer_2d(kgem, width, height, bpp, KGEM_BUFFER_WRITE_INPLACE, &dst); if (bo == NULL) return NULL; if (sigtrap_get()) { kgem_bo_destroy(kgem, bo); return NULL; } memcpy_blt(data, dst, bpp, stride, bo->pitch, box->x1, box->y1, 0, 0, width, height); sigtrap_put(); return bo; } void kgem_proxy_bo_attach(struct kgem_bo *bo, struct kgem_bo **ptr) { DBG(("%s: handle=%d\n", __FUNCTION__, bo->handle)); assert(bo->map__gtt == NULL); assert(bo->proxy); list_add(&bo->vma, &bo->proxy->vma); bo->map__gtt = ptr; *ptr = kgem_bo_reference(bo); } void kgem_buffer_read_sync(struct kgem *kgem, struct kgem_bo *_bo) { struct kgem_buffer *bo; uint32_t offset = _bo->delta, length = _bo->size.bytes; /* We expect the caller to have already submitted the batch */ assert(_bo->io); assert(_bo->exec == NULL); assert(_bo->rq == NULL); assert(_bo->proxy); _bo = _bo->proxy; assert(_bo->proxy == NULL); assert(_bo->exec == NULL); bo = (struct kgem_buffer *)_bo; DBG(("%s(offset=%d, length=%d, snooped=%d)\n", __FUNCTION__, offset, length, bo->base.snoop)); if (bo->mmapped) { struct drm_i915_gem_set_domain set_domain; DBG(("%s: sync: needs_flush? %d, domain? %d, busy? %d\n", __FUNCTION__, bo->base.needs_flush, bo->base.domain, __kgem_busy(kgem, bo->base.handle))); assert(bo->mmapped == MMAPPED_GTT || bo->base.snoop || kgem->has_llc); VG_CLEAR(set_domain); set_domain.handle = bo->base.handle; set_domain.write_domain = 0; set_domain.read_domains = bo->mmapped == MMAPPED_CPU ? I915_GEM_DOMAIN_CPU : I915_GEM_DOMAIN_GTT; if (do_ioctl(kgem->fd, DRM_IOCTL_I915_GEM_SET_DOMAIN, &set_domain)) { DBG(("%s: sync: GPU hang detected\n", __FUNCTION__)); kgem_throttle(kgem); } } else { if (gem_read(kgem->fd, bo->base.handle, (char *)bo->mem+offset, offset, length)) return; } kgem_bo_maybe_retire(kgem, &bo->base); bo->base.domain = DOMAIN_NONE; } uint32_t kgem_bo_get_binding(struct kgem_bo *bo, uint32_t format) { struct kgem_bo_binding *b; assert(bo->refcnt); for (b = &bo->binding; b && b->offset; b = b->next) if (format == b->format) return b->offset; return 0; } void kgem_bo_set_binding(struct kgem_bo *bo, uint32_t format, uint16_t offset) { struct kgem_bo_binding *b; assert(bo->refcnt); for (b = &bo->binding; b; b = b->next) { if (b->offset) continue; b->offset = offset; b->format = format; if (b->next) b->next->offset = 0; return; } b = malloc(sizeof(*b)); if (b) { b->next = bo->binding.next; b->format = format; b->offset = offset; bo->binding.next = b; } } struct kgem_bo * kgem_replace_bo(struct kgem *kgem, struct kgem_bo *src, uint32_t width, uint32_t height, uint32_t pitch, uint32_t bpp) { struct kgem_bo *dst; uint32_t br00, br13; uint32_t handle; uint32_t size; uint32_t *b; DBG(("%s: replacing bo handle=%d, size=%dx%d pitch=%d, with pitch=%d\n", __FUNCTION__, src->handle, width, height, src->pitch, pitch)); /* We only expect to be called to fixup small buffers, hence why * we only attempt to allocate a linear bo. */ assert(src->tiling == I915_TILING_NONE); assert(kgem_bo_can_blt(kgem, src)); size = height * pitch; size = NUM_PAGES(size); dst = search_linear_cache(kgem, size, 0); if (dst == NULL) dst = search_linear_cache(kgem, size, CREATE_INACTIVE); if (dst == NULL) { handle = gem_create(kgem->fd, size); if (handle == 0) return NULL; dst = __kgem_bo_alloc(handle, size); if (dst == NULL) { gem_close(kgem->fd, handle); return NULL; } debug_alloc__bo(kgem, dst); } dst->pitch = pitch; dst->unique_id = kgem_get_unique_id(kgem); dst->refcnt = 1; assert(dst->tiling == I915_TILING_NONE); assert(kgem_bo_can_blt(kgem, dst)); kgem_set_mode(kgem, KGEM_BLT, dst); if (!kgem_check_batch(kgem, 10) || !kgem_check_reloc(kgem, 2) || !kgem_check_many_bo_fenced(kgem, src, dst, NULL)) { kgem_submit(kgem); if (!kgem_check_many_bo_fenced(kgem, src, dst, NULL)) { kgem_bo_destroy(kgem, dst); return NULL; } _kgem_set_mode(kgem, KGEM_BLT); } kgem_bcs_set_tiling(kgem, src, dst); br00 = XY_SRC_COPY_BLT_CMD; br13 = pitch; pitch = src->pitch; if (kgem->gen >= 040 && src->tiling) { br00 |= BLT_SRC_TILED; pitch >>= 2; } br13 |= 0xcc << 16; br13 |= sna_br13_color_depth(bpp); if (bpp == 32) br00 |= BLT_WRITE_ALPHA | BLT_WRITE_RGB; b = kgem->batch + kgem->nbatch; if (kgem->gen >= 0100) { b[0] = br00 | 8; b[1] = br13; b[2] = 0; b[3] = height << 16 | width; *(uint64_t *)(b+4) = kgem_add_reloc64(kgem, kgem->nbatch + 4, dst, I915_GEM_DOMAIN_RENDER << 16 | I915_GEM_DOMAIN_RENDER | KGEM_RELOC_FENCED, 0); b[6] = 0; b[7] = pitch; *(uint64_t *)(b+8) = kgem_add_reloc64(kgem, kgem->nbatch + 8, src, I915_GEM_DOMAIN_RENDER << 16 | KGEM_RELOC_FENCED, 0); kgem->nbatch += 10; } else { b[0] = br00 | 6; b[1] = br13; b[2] = 0; b[3] = height << 16 | width; b[4] = kgem_add_reloc(kgem, kgem->nbatch + 4, dst, I915_GEM_DOMAIN_RENDER << 16 | I915_GEM_DOMAIN_RENDER | KGEM_RELOC_FENCED, 0); b[5] = 0; b[6] = pitch; b[7] = kgem_add_reloc(kgem, kgem->nbatch + 7, src, I915_GEM_DOMAIN_RENDER << 16 | KGEM_RELOC_FENCED, 0); kgem->nbatch += 8; } return dst; } bool kgem_bo_convert_to_gpu(struct kgem *kgem, struct kgem_bo *bo, unsigned flags) { DBG(("%s: converting handle=%d from CPU to GPU, flags=%x, busy?=%d\n", __FUNCTION__, bo->handle, flags, __kgem_bo_is_busy(kgem, bo))); assert(bo->tiling == I915_TILING_NONE); if (flags & (__MOVE_PRIME | __MOVE_SCANOUT)) return false; if (kgem->has_llc) return true; if (flags & MOVE_ASYNC_HINT && __kgem_bo_is_busy(kgem, bo)) return false; assert(bo->snoop); kgem_bo_submit(kgem, bo); if (!gem_set_caching(kgem->fd, bo->handle, UNCACHED)) return false; bo->snoop = false; return true; }