From: Kenneth Graunke Date: Fri, 26 Apr 2019 01:30:57 +0000 (-0700) Subject: iris: Delete bucketing allocators X-Git-Tag: upstream/19.3.0~6591 X-Git-Url: http://review.tizen.org/git/?a=commitdiff_plain;h=694d1a08d3e5883d97d5352895f8431f76596cb8;p=platform%2Fupstream%2Fmesa.git iris: Delete bucketing allocators These add a lot of complexity, and I currently can't measure any performance benefit from having them. In the past, I seem to recall seeing a benefit in drawoverhead scores, but currently it looks like dropping them is either a wash or 1-2% faster. Drop them to simplify allocations. --- diff --git a/src/gallium/drivers/iris/iris_bufmgr.c b/src/gallium/drivers/iris/iris_bufmgr.c index 11b3885..5b807e0 100644 --- a/src/gallium/drivers/iris/iris_bufmgr.c +++ b/src/gallium/drivers/iris/iris_bufmgr.c @@ -132,41 +132,12 @@ memzone_name(enum iris_memory_zone memzone) return names[memzone]; } -/** - * Iris fixed-size bucketing VMA allocator. - * - * The BO cache maintains "cache buckets" for buffers of various sizes. - * All buffers in a given bucket are identically sized - when allocating, - * we always round up to the bucket size. This means that virtually all - * allocations are fixed-size; only buffers which are too large to fit in - * a bucket can be variably-sized. - * - * We create an allocator for each bucket. Each contains a free-list, where - * each node contains a pair. Each bit - * represents a bucket-sized block of memory. (At the first level, each - * bit corresponds to a page. For the second bucket, bits correspond to - * two pages, and so on.) 1 means a block is free, and 0 means it's in-use. - * The lowest bit in the bitmap is for the first block. - * - * This makes allocations cheap - any bit of any node will do. We can pick - * the head of the list and use ffs() to find a free block. If there are - * none, we allocate 64 blocks from a larger allocator - either a bigger - * bucketing allocator, or a fallback top-level allocator for large objects. - */ -struct vma_bucket_node { - uint64_t start_address; - uint64_t bitmap; -}; - struct bo_cache_bucket { /** List of cached BOs. */ struct list_head head; /** Size of this bucket, in bytes. */ uint64_t size; - - /** List of vma_bucket_nodes. */ - struct util_dynarray vma_list[IRIS_MEMZONE_COUNT]; }; struct iris_bufmgr { @@ -283,121 +254,6 @@ iris_memzone_for_address(uint64_t address) return IRIS_MEMZONE_SHADER; } -static uint64_t -bucket_vma_alloc(struct iris_bufmgr *bufmgr, - struct bo_cache_bucket *bucket, - enum iris_memory_zone memzone) -{ - struct util_dynarray *vma_list = &bucket->vma_list[memzone]; - struct vma_bucket_node *node; - - if (vma_list->size == 0) { - /* This bucket allocator is out of space - allocate a new block of - * memory for 64 blocks from a larger allocator (either a larger - * bucket or util_vma). - * - * We align the address to the node size (64 blocks) so that - * bucket_vma_free can easily compute the starting address of this - * block by rounding any address we return down to the node size. - * - * Set the first bit used, and return the start address. - */ - const uint64_t node_size = 64ull * bucket->size; - node = util_dynarray_grow(vma_list, sizeof(struct vma_bucket_node)); - - if (unlikely(!node)) - return 0ull; - - uint64_t addr = vma_alloc(bufmgr, memzone, node_size, node_size); - node->start_address = gen_48b_address(addr); - node->bitmap = ~1ull; - return node->start_address; - } - - /* Pick any bit from any node - they're all the right size and free. */ - node = util_dynarray_top_ptr(vma_list, struct vma_bucket_node); - int bit = ffsll(node->bitmap) - 1; - assert(bit >= 0 && bit <= 63); - - /* Reserve the memory by clearing the bit. */ - assert((node->bitmap & (1ull << bit)) != 0ull); - node->bitmap &= ~(1ull << bit); - - uint64_t addr = node->start_address + bit * bucket->size; - - /* If this node is now completely full, remove it from the free list. */ - if (node->bitmap == 0ull) { - (void) util_dynarray_pop(vma_list, struct vma_bucket_node); - } - - return addr; -} - -static void -bucket_vma_free(struct bo_cache_bucket *bucket, uint64_t address) -{ - enum iris_memory_zone memzone = iris_memzone_for_address(address); - struct util_dynarray *vma_list = &bucket->vma_list[memzone]; - const uint64_t node_bytes = 64ull * bucket->size; - struct vma_bucket_node *node = NULL; - - /* bucket_vma_alloc allocates 64 blocks at a time, and aligns it to - * that 64 block size. So, we can round down to get the starting address. - */ - uint64_t start = (address / node_bytes) * node_bytes; - - /* Dividing the offset from start by bucket size gives us the bit index. */ - int bit = (address - start) / bucket->size; - - assert(start + bit * bucket->size == address); - - util_dynarray_foreach(vma_list, struct vma_bucket_node, cur) { - if (cur->start_address == start) { - node = cur; - break; - } - } - - if (!node) { - /* No node - the whole group of 64 blocks must have been in-use. */ - node = util_dynarray_grow(vma_list, sizeof(struct vma_bucket_node)); - - if (unlikely(!node)) - return; /* bogus, leaks some GPU VMA, but nothing we can do... */ - - node->start_address = start; - node->bitmap = 0ull; - } - - /* Set the bit to return the memory. */ - assert((node->bitmap & (1ull << bit)) == 0ull); - node->bitmap |= 1ull << bit; - - /* The block might be entirely free now, and if so, we could return it - * to the larger allocator. But we may as well hang on to it, in case - * we get more allocations at this block size. - */ -} - -static struct bo_cache_bucket * -get_bucket_allocator(struct iris_bufmgr *bufmgr, - enum iris_memory_zone memzone, - uint64_t size) -{ - /* Skip using the bucket allocator for very large sizes, as it allocates - * 64 of them and this can balloon rather quickly. - */ - if (size > 1024 * PAGE_SIZE) - return NULL; - - struct bo_cache_bucket *bucket = bucket_for_size(bufmgr, size); - - if (bucket && bucket->size == size) - return bucket; - - return NULL; -} - /** * Allocate a section of virtual memory for a buffer, assigning an address. * @@ -420,16 +276,8 @@ vma_alloc(struct iris_bufmgr *bufmgr, if (memzone == IRIS_MEMZONE_BINDER) return IRIS_MEMZONE_BINDER_START; - struct bo_cache_bucket *bucket = - get_bucket_allocator(bufmgr, memzone, size); - uint64_t addr; - - if (bucket) { - addr = bucket_vma_alloc(bufmgr, bucket, memzone); - } else { - addr = util_vma_heap_alloc(&bufmgr->vma_allocator[memzone], size, - alignment); - } + uint64_t addr = + util_vma_heap_alloc(&bufmgr->vma_allocator[memzone], size, alignment); assert((addr >> 48ull) == 0); assert((addr % alignment) == 0); @@ -457,14 +305,7 @@ vma_free(struct iris_bufmgr *bufmgr, if (memzone == IRIS_MEMZONE_BINDER) return; - struct bo_cache_bucket *bucket = - get_bucket_allocator(bufmgr, memzone, size); - - if (bucket) { - bucket_vma_free(bucket, address); - } else { - util_vma_heap_free(&bufmgr->vma_allocator[memzone], address, size); - } + util_vma_heap_free(&bufmgr->vma_allocator[memzone], address, size); } int @@ -1321,9 +1162,6 @@ iris_bufmgr_destroy(struct iris_bufmgr *bufmgr) bo_free(bo); } - - for (int z = 0; z < IRIS_MEMZONE_COUNT; z++) - util_dynarray_fini(&bucket->vma_list[z]); } _mesa_hash_table_destroy(bufmgr->name_table, NULL); @@ -1529,8 +1367,6 @@ add_bucket(struct iris_bufmgr *bufmgr, int size) assert(i < ARRAY_SIZE(bufmgr->cache_bucket)); list_inithead(&bufmgr->cache_bucket[i].head); - for (int z = 0; z < IRIS_MEMZONE_COUNT; z++) - util_dynarray_init(&bufmgr->cache_bucket[i].vma_list[z], NULL); bufmgr->cache_bucket[i].size = size; bufmgr->num_buckets++;