/* * Copyright (C) 2012-2018 Rob Clark * * 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: * Rob Clark */ #include "os/os_mman.h" #include "freedreno_drmif.h" #include "freedreno_priv.h" simple_mtx_t table_lock = _SIMPLE_MTX_INITIALIZER_NP; void bo_del(struct fd_bo *bo); /* set buffer name, and add to table, call w/ table_lock held: */ static void set_name(struct fd_bo *bo, uint32_t name) { bo->name = name; /* add ourself into the handle table: */ _mesa_hash_table_insert(bo->dev->name_table, &bo->name, bo); } /* lookup a buffer, call w/ table_lock held: */ static struct fd_bo * lookup_bo(struct hash_table *tbl, uint32_t key) { struct fd_bo *bo = NULL; struct hash_entry *entry = _mesa_hash_table_search(tbl, &key); if (entry) { /* found, incr refcnt and return: */ bo = fd_bo_ref(entry->data); /* don't break the bucket if this bo was found in one */ list_delinit(&bo->list); } return bo; } /* allocate a new buffer object, call w/ table_lock held */ static struct fd_bo * bo_from_handle(struct fd_device *dev, uint32_t size, uint32_t handle) { struct fd_bo *bo; simple_mtx_assert_locked(&table_lock); bo = dev->funcs->bo_from_handle(dev, size, handle); if (!bo) { struct drm_gem_close req = { .handle = handle, }; drmIoctl(dev->fd, DRM_IOCTL_GEM_CLOSE, &req); return NULL; } bo->dev = dev; bo->size = size; bo->handle = handle; bo->iova = bo->funcs->iova(bo); bo->reloc_flags = FD_RELOC_FLAGS_INIT; p_atomic_set(&bo->refcnt, 1); list_inithead(&bo->list); /* add ourself into the handle table: */ _mesa_hash_table_insert(dev->handle_table, &bo->handle, bo); return bo; } static struct fd_bo * bo_new(struct fd_device *dev, uint32_t size, uint32_t flags, struct fd_bo_cache *cache) { struct fd_bo *bo = NULL; uint32_t handle; int ret; /* demote cached-coherent to WC if not supported: */ if ((flags & FD_BO_CACHED_COHERENT) && !dev->has_cached_coherent) flags &= ~FD_BO_CACHED_COHERENT; bo = fd_bo_cache_alloc(cache, &size, flags); if (bo) return bo; ret = dev->funcs->bo_new_handle(dev, size, flags, &handle); if (ret) return NULL; simple_mtx_lock(&table_lock); bo = bo_from_handle(dev, size, handle); simple_mtx_unlock(&table_lock); bo->alloc_flags = flags; bo->max_fences = 1; bo->fences = &bo->_inline_fence; VG_BO_ALLOC(bo); return bo; } struct fd_bo * _fd_bo_new(struct fd_device *dev, uint32_t size, uint32_t flags) { struct fd_bo *bo = bo_new(dev, size, flags, &dev->bo_cache); if (bo) bo->bo_reuse = BO_CACHE; return bo; } void _fd_bo_set_name(struct fd_bo *bo, const char *fmt, va_list ap) { bo->funcs->set_name(bo, fmt, ap); } /* internal function to allocate bo's that use the ringbuffer cache * instead of the normal bo_cache. The purpose is, because cmdstream * bo's get vmap'd on the kernel side, and that is expensive, we want * to re-use cmdstream bo's for cmdstream and not unrelated purposes. */ struct fd_bo * fd_bo_new_ring(struct fd_device *dev, uint32_t size) { uint32_t flags = FD_BO_GPUREADONLY | FD_BO_CACHED_COHERENT; struct fd_bo *bo = bo_new(dev, size, flags, &dev->ring_cache); if (bo) { bo->bo_reuse = RING_CACHE; bo->reloc_flags |= FD_RELOC_DUMP; fd_bo_set_name(bo, "cmdstream"); } return bo; } struct fd_bo * fd_bo_from_handle(struct fd_device *dev, uint32_t handle, uint32_t size) { struct fd_bo *bo = NULL; simple_mtx_lock(&table_lock); bo = lookup_bo(dev->handle_table, handle); if (bo) goto out_unlock; bo = bo_from_handle(dev, size, handle); VG_BO_ALLOC(bo); out_unlock: simple_mtx_unlock(&table_lock); return bo; } struct fd_bo * fd_bo_from_dmabuf(struct fd_device *dev, int fd) { int ret, size; uint32_t handle; struct fd_bo *bo; simple_mtx_lock(&table_lock); ret = drmPrimeFDToHandle(dev->fd, fd, &handle); if (ret) { simple_mtx_unlock(&table_lock); return NULL; } bo = lookup_bo(dev->handle_table, handle); if (bo) goto out_unlock; /* lseek() to get bo size */ size = lseek(fd, 0, SEEK_END); lseek(fd, 0, SEEK_CUR); bo = bo_from_handle(dev, size, handle); VG_BO_ALLOC(bo); out_unlock: simple_mtx_unlock(&table_lock); return bo; } struct fd_bo * fd_bo_from_name(struct fd_device *dev, uint32_t name) { struct drm_gem_open req = { .name = name, }; struct fd_bo *bo; simple_mtx_lock(&table_lock); /* check name table first, to see if bo is already open: */ bo = lookup_bo(dev->name_table, name); if (bo) goto out_unlock; if (drmIoctl(dev->fd, DRM_IOCTL_GEM_OPEN, &req)) { ERROR_MSG("gem-open failed: %s", strerror(errno)); goto out_unlock; } bo = lookup_bo(dev->handle_table, req.handle); if (bo) goto out_unlock; bo = bo_from_handle(dev, req.size, req.handle); if (bo) { set_name(bo, name); VG_BO_ALLOC(bo); } out_unlock: simple_mtx_unlock(&table_lock); return bo; } void fd_bo_mark_for_dump(struct fd_bo *bo) { bo->reloc_flags |= FD_RELOC_DUMP; } uint64_t fd_bo_get_iova(struct fd_bo *bo) { /* ancient kernels did not support this */ assert(bo->iova != 0); return bo->iova; } struct fd_bo * fd_bo_ref(struct fd_bo *bo) { p_atomic_inc(&bo->refcnt); return bo; } static void bo_del_or_recycle(struct fd_bo *bo) { struct fd_device *dev = bo->dev; simple_mtx_assert_locked(&table_lock); if ((bo->bo_reuse == BO_CACHE) && (fd_bo_cache_free(&dev->bo_cache, bo) == 0)) return; if ((bo->bo_reuse == RING_CACHE) && (fd_bo_cache_free(&dev->ring_cache, bo) == 0)) return; bo_del(bo); } void fd_bo_del_locked(struct fd_bo *bo) { simple_mtx_assert_locked(&table_lock); if (!p_atomic_dec_zero(&bo->refcnt)) return; bo_del_or_recycle(bo); } void fd_bo_del(struct fd_bo *bo) { if (!p_atomic_dec_zero(&bo->refcnt)) return; simple_mtx_lock(&table_lock); bo_del_or_recycle(bo); simple_mtx_unlock(&table_lock); } /** * Cleanup fences, dropping pipe references. If 'expired' is true, only * cleanup expired fences. * * Normally we expect at most a single fence, the exception being bo's * shared between contexts */ static void cleanup_fences(struct fd_bo *bo, bool expired) { simple_mtx_assert_locked(&table_lock); for (int i = 0; i < bo->nr_fences; i++) { struct fd_bo_fence *f = &bo->fences[i]; if (expired && fd_fence_before(f->pipe->control->fence, f->fence)) continue; struct fd_pipe *pipe = f->pipe; bo->nr_fences--; if (bo->nr_fences > 0) { /* Shuffle up the last entry to replace the current slot: */ bo->fences[i] = bo->fences[bo->nr_fences]; i--; } fd_pipe_del_locked(pipe); } } /* Called under table_lock */ void bo_del(struct fd_bo *bo) { VG_BO_FREE(bo); simple_mtx_assert_locked(&table_lock); cleanup_fences(bo, false); if (bo->fences != &bo->_inline_fence) free(bo->fences); if (bo->map) os_munmap(bo->map, bo->size); /* TODO probably bo's in bucket list get removed from * handle table?? */ if (bo->handle) { struct drm_gem_close req = { .handle = bo->handle, }; _mesa_hash_table_remove_key(bo->dev->handle_table, &bo->handle); if (bo->name) _mesa_hash_table_remove_key(bo->dev->name_table, &bo->name); drmIoctl(bo->dev->fd, DRM_IOCTL_GEM_CLOSE, &req); } bo->funcs->destroy(bo); } static void bo_flush(struct fd_bo *bo) { for (int i = 0; i < bo->nr_fences; i++) { struct fd_bo_fence *f = &bo->fences[i]; fd_pipe_flush(f->pipe, f->fence); } } int fd_bo_get_name(struct fd_bo *bo, uint32_t *name) { if (!bo->name) { struct drm_gem_flink req = { .handle = bo->handle, }; int ret; ret = drmIoctl(bo->dev->fd, DRM_IOCTL_GEM_FLINK, &req); if (ret) { return ret; } simple_mtx_lock(&table_lock); set_name(bo, req.name); simple_mtx_unlock(&table_lock); bo->bo_reuse = NO_CACHE; bo->shared = true; bo_flush(bo); } *name = bo->name; return 0; } uint32_t fd_bo_handle(struct fd_bo *bo) { bo->bo_reuse = NO_CACHE; bo->shared = true; bo_flush(bo); return bo->handle; } int fd_bo_dmabuf(struct fd_bo *bo) { int ret, prime_fd; ret = drmPrimeHandleToFD(bo->dev->fd, bo->handle, DRM_CLOEXEC, &prime_fd); if (ret) { ERROR_MSG("failed to get dmabuf fd: %d", ret); return ret; } bo->bo_reuse = NO_CACHE; bo->shared = true; bo_flush(bo); return prime_fd; } uint32_t fd_bo_size(struct fd_bo *bo) { return bo->size; } bool fd_bo_is_cached(struct fd_bo *bo) { return !!(bo->alloc_flags & FD_BO_CACHED_COHERENT); } void * fd_bo_map(struct fd_bo *bo) { if (!bo->map) { uint64_t offset; int ret; ret = bo->funcs->offset(bo, &offset); if (ret) { return NULL; } bo->map = os_mmap(0, bo->size, PROT_READ | PROT_WRITE, MAP_SHARED, bo->dev->fd, offset); if (bo->map == MAP_FAILED) { ERROR_MSG("mmap failed: %s", strerror(errno)); bo->map = NULL; } } return bo->map; } /* a bit odd to take the pipe as an arg, but it's a, umm, quirk of kgsl.. */ int fd_bo_cpu_prep(struct fd_bo *bo, struct fd_pipe *pipe, uint32_t op) { if (op & (FD_BO_PREP_NOSYNC | FD_BO_PREP_FLUSH)) { simple_mtx_lock(&table_lock); enum fd_bo_state state = fd_bo_state(bo); simple_mtx_unlock(&table_lock); if (state == FD_BO_STATE_IDLE) return 0; if (op & FD_BO_PREP_FLUSH) bo_flush(bo); /* If we have *only* been asked to flush, then we aren't really * interested about whether shared buffers are busy, so avoid * the kernel ioctl. */ if ((state == FD_BO_STATE_BUSY) || (op == FD_BO_PREP_FLUSH)) return -EBUSY; } /* In case the bo is referenced by a deferred submit, flush up to the * required fence now: */ bo_flush(bo); /* FD_BO_PREP_FLUSH is purely a frontend flag, and is not seen/handled * by backend or kernel: */ return bo->funcs->cpu_prep(bo, pipe, op & ~FD_BO_PREP_FLUSH); } void fd_bo_cpu_fini(struct fd_bo *bo) { // TODO until we have cached buffers, the kernel side ioctl does nothing, // so just skip it. When we have cached buffers, we can make the // ioctl conditional // bo->funcs->cpu_fini(bo); } void fd_bo_add_fence(struct fd_bo *bo, struct fd_pipe *pipe, uint32_t fence) { simple_mtx_assert_locked(&table_lock); if (bo->nosync) return; /* The common case is bo re-used on the same pipe it had previously * been used on: */ for (int i = 0; i < bo->nr_fences; i++) { struct fd_bo_fence *f = &bo->fences[i]; if (f->pipe == pipe) { assert(fd_fence_before(f->fence, fence)); f->fence = fence; return; } } cleanup_fences(bo, true); /* The first time we grow past a single fence, we need some special * handling, as we've been using the embedded _inline_fence to avoid * a separate allocation: */ if (unlikely((bo->nr_fences == 1) && (bo->fences == &bo->_inline_fence))) { bo->nr_fences = bo->max_fences = 0; bo->fences = NULL; APPEND(bo, fences, bo->_inline_fence); } APPEND(bo, fences, (struct fd_bo_fence){ .pipe = fd_pipe_ref_locked(pipe), .fence = fence, }); } enum fd_bo_state fd_bo_state(struct fd_bo *bo) { simple_mtx_assert_locked(&table_lock); cleanup_fences(bo, true); if (bo->shared || bo->nosync) return FD_BO_STATE_UNKNOWN; if (!bo->nr_fences) return FD_BO_STATE_IDLE; return FD_BO_STATE_BUSY; }