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|
/*
* Copyright © 2017 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.
*/
#ifdef HAVE_CONFIG_H
#include "config.h"
#endif
#include <xf86drm.h>
#include <util/u_atomic.h>
#include <fcntl.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <unistd.h>
#include <assert.h>
#include <sys/ioctl.h>
#include <sys/mman.h>
#include <sys/stat.h>
#include <sys/types.h>
#include <stdbool.h>
#include <time.h>
#include "errno.h"
#ifndef ETIME
#define ETIME ETIMEDOUT
#endif
#include "common/gen_clflush.h"
#include "common/gen_debug.h"
#include "dev/gen_device_info.h"
#include "main/macros.h"
#include "util/debug.h"
#include "util/macros.h"
#include "util/hash_table.h"
#include "util/list.h"
#include "util/u_dynarray.h"
#include "util/vma.h"
#include "iris_bufmgr.h"
#include "iris_context.h"
#include "string.h"
#include "drm-uapi/i915_drm.h"
#ifdef HAVE_VALGRIND
#include <valgrind.h>
#include <memcheck.h>
#define VG(x) x
#else
#define VG(x)
#endif
/* VALGRIND_FREELIKE_BLOCK unfortunately does not actually undo the earlier
* VALGRIND_MALLOCLIKE_BLOCK but instead leaves vg convinced the memory is
* leaked. All because it does not call VG(cli_free) from its
* VG_USERREQ__FREELIKE_BLOCK handler. Instead of treating the memory like
* and allocation, we mark it available for use upon mmapping and remove
* it upon unmapping.
*/
#define VG_DEFINED(ptr, size) VG(VALGRIND_MAKE_MEM_DEFINED(ptr, size))
#define VG_NOACCESS(ptr, size) VG(VALGRIND_MAKE_MEM_NOACCESS(ptr, size))
#define PAGE_SIZE 4096
#define FILE_DEBUG_FLAG DEBUG_BUFMGR
/**
* Call ioctl, restarting if it is interupted
*/
int
drm_ioctl(int fd, unsigned long request, void *arg)
{
int ret;
do {
ret = ioctl(fd, request, arg);
} while (ret == -1 && (errno == EINTR || errno == EAGAIN));
return ret;
}
static inline int
atomic_add_unless(int *v, int add, int unless)
{
int c, old;
c = p_atomic_read(v);
while (c != unless && (old = p_atomic_cmpxchg(v, c, c + add)) != c)
c = old;
return c == unless;
}
/*
* Idea:
*
* Have a bitmap-allocator for each BO cache bucket size. Because bo_alloc
* rounds up allocations to the bucket size anyway, we can make 1 bit in the
* bitmap represent N pages of memory, where N = <bucket size / page size>.
* Allocations and frees always set/unset a single bit. Because ffsll only
* works on uint64_t, use a tree(?) of those.
*
* Nodes contain a starting address and a uint64_t bitmap. (pair-of-uint64_t)
* Bitmap uses 1 for a free block, 0 for in-use.
*
* Bucket contains...
*
* Dynamic array of nodes. (pointer, two ints)
*/
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 {
int fd;
mtx_t lock;
/** Array of lists of cached gem objects of power-of-two sizes */
struct bo_cache_bucket cache_bucket[14 * 4];
int num_buckets;
time_t time;
struct hash_table *name_table;
struct hash_table *handle_table;
struct util_vma_heap vma_allocator[IRIS_MEMZONE_COUNT];
bool has_llc:1;
bool bo_reuse:1;
};
static int bo_set_tiling_internal(struct iris_bo *bo, uint32_t tiling_mode,
uint32_t stride);
static void bo_free(struct iris_bo *bo);
static uint64_t __vma_alloc(struct iris_bufmgr *bufmgr,
enum iris_memory_zone memzone,
uint64_t size, uint64_t alignment);
static uint32_t
key_hash_uint(const void *key)
{
return _mesa_hash_data(key, 4);
}
static bool
key_uint_equal(const void *a, const void *b)
{
return *((unsigned *) a) == *((unsigned *) b);
}
static struct iris_bo *
hash_find_bo(struct hash_table *ht, unsigned int key)
{
struct hash_entry *entry = _mesa_hash_table_search(ht, &key);
return entry ? (struct iris_bo *) entry->data : NULL;
}
/**
* This function finds the correct bucket fit for the input size.
* The function works with O(1) complexity when the requested size
* was queried instead of iterating the size through all the buckets.
*/
static struct bo_cache_bucket *
bucket_for_size(struct iris_bufmgr *bufmgr, uint64_t size)
{
/* Calculating the pages and rounding up to the page size. */
const unsigned pages = (size + PAGE_SIZE - 1) / PAGE_SIZE;
/* Row Bucket sizes clz((x-1) | 3) Row Column
* in pages stride size
* 0: 1 2 3 4 -> 30 30 30 30 4 1
* 1: 5 6 7 8 -> 29 29 29 29 4 1
* 2: 10 12 14 16 -> 28 28 28 28 8 2
* 3: 20 24 28 32 -> 27 27 27 27 16 4
*/
const unsigned row = 30 - __builtin_clz((pages - 1) | 3);
const unsigned row_max_pages = 4 << row;
/* The '& ~2' is the special case for row 1. In row 1, max pages /
* 2 is 2, but the previous row maximum is zero (because there is
* no previous row). All row maximum sizes are power of 2, so that
* is the only case where that bit will be set.
*/
const unsigned prev_row_max_pages = (row_max_pages / 2) & ~2;
int col_size_log2 = row - 1;
col_size_log2 += (col_size_log2 < 0);
const unsigned col = (pages - prev_row_max_pages +
((1 << col_size_log2) - 1)) >> col_size_log2;
/* Calculating the index based on the row and column. */
const unsigned index = (row * 4) + (col - 1);
return (index < bufmgr->num_buckets) ?
&bufmgr->cache_bucket[index] : NULL;
}
static enum iris_memory_zone
memzone_for_address(uint64_t address)
{
const uint64_t _4GB = 1ull << 32;
if (address >= 3 * _4GB)
return IRIS_MEMZONE_OTHER;
if (address >= 2 * _4GB)
return IRIS_MEMZONE_DYNAMIC;
if (address > 1 * _4GB)
return IRIS_MEMZONE_SURFACE;
/* The binder isn't in any memory zone. */
if (address == 1 * _4GB)
return IRIS_MEMZONE_BINDER;
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));
node->start_address = __vma_alloc(bufmgr, memzone, node_size, node_size);
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);
/* 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 node->start_address + bit * bucket->size;
}
static void
bucket_vma_free(struct bo_cache_bucket *bucket,
uint64_t address,
uint64_t size)
{
enum iris_memory_zone memzone = 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));
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, 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;
}
/** Like vma_alloc, but returns a non-canonicalized address. */
static uint64_t
__vma_alloc(struct iris_bufmgr *bufmgr,
enum iris_memory_zone memzone,
uint64_t size,
uint64_t alignment)
{
if (memzone == IRIS_MEMZONE_BINDER)
return IRIS_BINDER_ADDRESS;
struct bo_cache_bucket *bucket = get_bucket_allocator(bufmgr, 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);
}
assert((addr >> 48ull) == 0);
assert((addr % alignment) == 0);
return addr;
}
/**
* Allocate a section of virtual memory for a buffer, assigning an address.
*
* This uses either the bucket allocator for the given size, or the large
* object allocator (util_vma).
*/
static uint64_t
vma_alloc(struct iris_bufmgr *bufmgr,
enum iris_memory_zone memzone,
uint64_t size,
uint64_t alignment)
{
uint64_t addr = __vma_alloc(bufmgr, memzone, size, alignment);
/* Canonicalize the address.
*
* The Broadwell PRM Vol. 2a, MI_LOAD_REGISTER_MEM::MemoryAddress says:
*
* "This field specifies the address of the memory location where the
* register value specified in the DWord above will read from. The
* address specifies the DWord location of the data. Range =
* GraphicsVirtualAddress[63:2] for a DWord register GraphicsAddress
* [63:48] are ignored by the HW and assumed to be in correct
* canonical form [63:48] == [47]."
*/
const int shift = 63 - 47;
addr = (((int64_t) addr) << shift) >> shift;
return addr;
}
static void
vma_free(struct iris_bufmgr *bufmgr,
uint64_t address,
uint64_t size)
{
if (address == IRIS_BINDER_ADDRESS)
return;
/* Un-canonicalize the address; our allocators expect 0 in the high bits */
address &= (1ull << 48) - 1;
struct bo_cache_bucket *bucket = get_bucket_allocator(bufmgr, size);
if (bucket) {
bucket_vma_free(bucket, address, size);
} else {
enum iris_memory_zone memzone = memzone_for_address(address);
util_vma_heap_free(&bufmgr->vma_allocator[memzone], address, size);
}
}
int
iris_bo_busy(struct iris_bo *bo)
{
struct iris_bufmgr *bufmgr = bo->bufmgr;
struct drm_i915_gem_busy busy = { .handle = bo->gem_handle };
int ret = drm_ioctl(bufmgr->fd, DRM_IOCTL_I915_GEM_BUSY, &busy);
if (ret == 0) {
bo->idle = !busy.busy;
return busy.busy;
}
return false;
}
int
iris_bo_madvise(struct iris_bo *bo, int state)
{
struct drm_i915_gem_madvise madv = {
.handle = bo->gem_handle,
.madv = state,
.retained = 1,
};
drm_ioctl(bo->bufmgr->fd, DRM_IOCTL_I915_GEM_MADVISE, &madv);
return madv.retained;
}
/* drop the oldest entries that have been purged by the kernel */
static void
iris_bo_cache_purge_bucket(struct iris_bufmgr *bufmgr,
struct bo_cache_bucket *bucket)
{
list_for_each_entry_safe(struct iris_bo, bo, &bucket->head, head) {
if (iris_bo_madvise(bo, I915_MADV_DONTNEED))
break;
list_del(&bo->head);
bo_free(bo);
}
}
static struct iris_bo *
bo_alloc_internal(struct iris_bufmgr *bufmgr,
const char *name,
uint64_t size,
enum iris_memory_zone memzone,
unsigned flags,
uint32_t tiling_mode,
uint32_t stride)
{
struct iris_bo *bo;
unsigned int page_size = getpagesize();
int ret;
struct bo_cache_bucket *bucket;
bool alloc_from_cache;
uint64_t bo_size;
bool zeroed = false;
if (flags & BO_ALLOC_ZEROED)
zeroed = true;
/* Round the allocated size up to a power of two number of pages. */
bucket = bucket_for_size(bufmgr, size);
/* If we don't have caching at this size, don't actually round the
* allocation up.
*/
if (bucket == NULL) {
bo_size = size;
if (bo_size < page_size)
bo_size = page_size;
} else {
bo_size = bucket->size;
}
mtx_lock(&bufmgr->lock);
/* Get a buffer out of the cache if available */
retry:
alloc_from_cache = false;
if (bucket != NULL && !list_empty(&bucket->head)) {
/* If the last BO in the cache is idle, then reuse it. Otherwise,
* allocate a fresh buffer to avoid stalling.
*/
bo = LIST_ENTRY(struct iris_bo, bucket->head.next, head);
if (!iris_bo_busy(bo)) {
alloc_from_cache = true;
list_del(&bo->head);
}
if (alloc_from_cache) {
if (!iris_bo_madvise(bo, I915_MADV_WILLNEED)) {
bo_free(bo);
iris_bo_cache_purge_bucket(bufmgr, bucket);
goto retry;
}
if (bo_set_tiling_internal(bo, tiling_mode, stride)) {
bo_free(bo);
goto retry;
}
if (zeroed) {
void *map = iris_bo_map(NULL, bo, MAP_WRITE | MAP_RAW);
if (!map) {
bo_free(bo);
goto retry;
}
memset(map, 0, bo_size);
}
}
}
if (alloc_from_cache) {
/* If the cached BO isn't in the right memory zone, free the old
* memory and assign it a new address.
*/
if (memzone != memzone_for_address(bo->gtt_offset)) {
vma_free(bufmgr, bo->gtt_offset, bo_size);
bo->gtt_offset = 0ull;
}
} else {
bo = calloc(1, sizeof(*bo));
if (!bo)
goto err;
bo->size = bo_size;
bo->idle = true;
struct drm_i915_gem_create create = { .size = bo_size };
/* All new BOs we get from the kernel are zeroed, so we don't need to
* worry about that here.
*/
ret = drm_ioctl(bufmgr->fd, DRM_IOCTL_I915_GEM_CREATE, &create);
if (ret != 0) {
free(bo);
goto err;
}
bo->gem_handle = create.handle;
bo->bufmgr = bufmgr;
bo->kflags = EXEC_OBJECT_SUPPORTS_48B_ADDRESS | EXEC_OBJECT_PINNED;
bo->tiling_mode = I915_TILING_NONE;
bo->swizzle_mode = I915_BIT_6_SWIZZLE_NONE;
bo->stride = 0;
if (bo_set_tiling_internal(bo, tiling_mode, stride))
goto err_free;
/* Calling set_domain() will allocate pages for the BO outside of the
* struct mutex lock in the kernel, which is more efficient than waiting
* to create them during the first execbuf that uses the BO.
*/
struct drm_i915_gem_set_domain sd = {
.handle = bo->gem_handle,
.read_domains = I915_GEM_DOMAIN_CPU,
.write_domain = 0,
};
if (drm_ioctl(bo->bufmgr->fd, DRM_IOCTL_I915_GEM_SET_DOMAIN, &sd) != 0)
goto err_free;
}
if (bo->gtt_offset == 0ull) {
bo->gtt_offset = vma_alloc(bufmgr, memzone, bo->size, 1);
if (bo->gtt_offset == 0ull)
goto err_free;
}
bo->name = name;
p_atomic_set(&bo->refcount, 1);
bo->reusable = true;
bo->cache_coherent = bufmgr->has_llc;
bo->index = -1;
mtx_unlock(&bufmgr->lock);
DBG("bo_create: buf %d (%s) %llub\n", bo->gem_handle, bo->name,
(unsigned long long) size);
return bo;
err_free:
bo_free(bo);
err:
mtx_unlock(&bufmgr->lock);
return NULL;
}
struct iris_bo *
iris_bo_alloc(struct iris_bufmgr *bufmgr,
const char *name,
uint64_t size,
enum iris_memory_zone memzone)
{
return bo_alloc_internal(bufmgr, name, size, memzone,
0, I915_TILING_NONE, 0);
}
struct iris_bo *
iris_bo_alloc_tiled(struct iris_bufmgr *bufmgr, const char *name,
uint64_t size, enum iris_memory_zone memzone,
uint32_t tiling_mode, uint32_t pitch, unsigned flags)
{
return bo_alloc_internal(bufmgr, name, size, memzone,
flags, tiling_mode, pitch);
}
/**
* Returns a iris_bo wrapping the given buffer object handle.
*
* This can be used when one application needs to pass a buffer object
* to another.
*/
struct iris_bo *
iris_bo_gem_create_from_name(struct iris_bufmgr *bufmgr,
const char *name, unsigned int handle)
{
struct iris_bo *bo;
/* At the moment most applications only have a few named bo.
* For instance, in a DRI client only the render buffers passed
* between X and the client are named. And since X returns the
* alternating names for the front/back buffer a linear search
* provides a sufficiently fast match.
*/
mtx_lock(&bufmgr->lock);
bo = hash_find_bo(bufmgr->name_table, handle);
if (bo) {
iris_bo_reference(bo);
goto out;
}
struct drm_gem_open open_arg = { .name = handle };
int ret = drm_ioctl(bufmgr->fd, DRM_IOCTL_GEM_OPEN, &open_arg);
if (ret != 0) {
DBG("Couldn't reference %s handle 0x%08x: %s\n",
name, handle, strerror(errno));
bo = NULL;
goto out;
}
/* Now see if someone has used a prime handle to get this
* object from the kernel before by looking through the list
* again for a matching gem_handle
*/
bo = hash_find_bo(bufmgr->handle_table, open_arg.handle);
if (bo) {
iris_bo_reference(bo);
goto out;
}
bo = calloc(1, sizeof(*bo));
if (!bo)
goto out;
p_atomic_set(&bo->refcount, 1);
bo->size = open_arg.size;
bo->gtt_offset = 0;
bo->bufmgr = bufmgr;
bo->kflags = EXEC_OBJECT_SUPPORTS_48B_ADDRESS | EXEC_OBJECT_PINNED;
bo->gem_handle = open_arg.handle;
bo->name = name;
bo->global_name = handle;
bo->reusable = false;
bo->external = true;
bo->gtt_offset = vma_alloc(bufmgr, IRIS_MEMZONE_OTHER, bo->size, 1);
_mesa_hash_table_insert(bufmgr->handle_table, &bo->gem_handle, bo);
_mesa_hash_table_insert(bufmgr->name_table, &bo->global_name, bo);
struct drm_i915_gem_get_tiling get_tiling = { .handle = bo->gem_handle };
ret = drm_ioctl(bufmgr->fd, DRM_IOCTL_I915_GEM_GET_TILING, &get_tiling);
if (ret != 0)
goto err_unref;
bo->tiling_mode = get_tiling.tiling_mode;
bo->swizzle_mode = get_tiling.swizzle_mode;
/* XXX stride is unknown */
DBG("bo_create_from_handle: %d (%s)\n", handle, bo->name);
out:
mtx_unlock(&bufmgr->lock);
return bo;
err_unref:
bo_free(bo);
mtx_unlock(&bufmgr->lock);
return NULL;
}
static void
bo_free(struct iris_bo *bo)
{
struct iris_bufmgr *bufmgr = bo->bufmgr;
if (bo->map_cpu) {
VG_NOACCESS(bo->map_cpu, bo->size);
munmap(bo->map_cpu, bo->size);
}
if (bo->map_wc) {
VG_NOACCESS(bo->map_wc, bo->size);
munmap(bo->map_wc, bo->size);
}
if (bo->map_gtt) {
VG_NOACCESS(bo->map_gtt, bo->size);
munmap(bo->map_gtt, bo->size);
}
if (bo->external) {
struct hash_entry *entry;
if (bo->global_name) {
entry = _mesa_hash_table_search(bufmgr->name_table, &bo->global_name);
_mesa_hash_table_remove(bufmgr->name_table, entry);
}
entry = _mesa_hash_table_search(bufmgr->handle_table, &bo->gem_handle);
_mesa_hash_table_remove(bufmgr->handle_table, entry);
}
vma_free(bo->bufmgr, bo->gtt_offset, bo->size);
/* Close this object */
struct drm_gem_close close = { .handle = bo->gem_handle };
int ret = drm_ioctl(bufmgr->fd, DRM_IOCTL_GEM_CLOSE, &close);
if (ret != 0) {
DBG("DRM_IOCTL_GEM_CLOSE %d failed (%s): %s\n",
bo->gem_handle, bo->name, strerror(errno));
}
free(bo);
}
/** Frees all cached buffers significantly older than @time. */
static void
cleanup_bo_cache(struct iris_bufmgr *bufmgr, time_t time)
{
int i;
if (bufmgr->time == time)
return;
for (i = 0; i < bufmgr->num_buckets; i++) {
struct bo_cache_bucket *bucket = &bufmgr->cache_bucket[i];
list_for_each_entry_safe(struct iris_bo, bo, &bucket->head, head) {
if (time - bo->free_time <= 1)
break;
list_del(&bo->head);
bo_free(bo);
}
}
bufmgr->time = time;
}
static void
bo_unreference_final(struct iris_bo *bo, time_t time)
{
struct iris_bufmgr *bufmgr = bo->bufmgr;
struct bo_cache_bucket *bucket;
DBG("bo_unreference final: %d (%s)\n", bo->gem_handle, bo->name);
bucket = bucket_for_size(bufmgr, bo->size);
/* Put the buffer into our internal cache for reuse if we can. */
if (bufmgr->bo_reuse && bo->reusable && bucket != NULL &&
iris_bo_madvise(bo, I915_MADV_DONTNEED)) {
bo->free_time = time;
bo->name = NULL;
list_addtail(&bo->head, &bucket->head);
} else {
bo_free(bo);
}
}
void
iris_bo_unreference(struct iris_bo *bo)
{
if (bo == NULL)
return;
assert(p_atomic_read(&bo->refcount) > 0);
if (atomic_add_unless(&bo->refcount, -1, 1)) {
struct iris_bufmgr *bufmgr = bo->bufmgr;
struct timespec time;
clock_gettime(CLOCK_MONOTONIC, &time);
mtx_lock(&bufmgr->lock);
if (p_atomic_dec_zero(&bo->refcount)) {
bo_unreference_final(bo, time.tv_sec);
cleanup_bo_cache(bufmgr, time.tv_sec);
}
mtx_unlock(&bufmgr->lock);
}
}
static void
bo_wait_with_stall_warning(struct pipe_debug_callback *dbg,
struct iris_bo *bo,
const char *action)
{
bool busy = dbg && !bo->idle;
double elapsed = unlikely(busy) ? -get_time() : 0.0;
iris_bo_wait_rendering(bo);
if (unlikely(busy)) {
elapsed += get_time();
if (elapsed > 1e-5) /* 0.01ms */ {
perf_debug(dbg, "%s a busy \"%s\" BO stalled and took %.03f ms.\n",
action, bo->name, elapsed * 1000);
}
}
}
static void
print_flags(unsigned flags)
{
if (flags & MAP_READ)
DBG("READ ");
if (flags & MAP_WRITE)
DBG("WRITE ");
if (flags & MAP_ASYNC)
DBG("ASYNC ");
if (flags & MAP_PERSISTENT)
DBG("PERSISTENT ");
if (flags & MAP_COHERENT)
DBG("COHERENT ");
if (flags & MAP_RAW)
DBG("RAW ");
DBG("\n");
}
static void *
iris_bo_map_cpu(struct pipe_debug_callback *dbg,
struct iris_bo *bo, unsigned flags)
{
struct iris_bufmgr *bufmgr = bo->bufmgr;
/* We disallow CPU maps for writing to non-coherent buffers, as the
* CPU map can become invalidated when a batch is flushed out, which
* can happen at unpredictable times. You should use WC maps instead.
*/
assert(bo->cache_coherent || !(flags & MAP_WRITE));
if (!bo->map_cpu) {
DBG("iris_bo_map_cpu: %d (%s)\n", bo->gem_handle, bo->name);
struct drm_i915_gem_mmap mmap_arg = {
.handle = bo->gem_handle,
.size = bo->size,
};
int ret = drm_ioctl(bufmgr->fd, DRM_IOCTL_I915_GEM_MMAP, &mmap_arg);
if (ret != 0) {
ret = -errno;
DBG("%s:%d: Error mapping buffer %d (%s): %s .\n",
__FILE__, __LINE__, bo->gem_handle, bo->name, strerror(errno));
return NULL;
}
void *map = (void *) (uintptr_t) mmap_arg.addr_ptr;
VG_DEFINED(map, bo->size);
if (p_atomic_cmpxchg(&bo->map_cpu, NULL, map)) {
VG_NOACCESS(map, bo->size);
munmap(map, bo->size);
}
}
assert(bo->map_cpu);
DBG("iris_bo_map_cpu: %d (%s) -> %p, ", bo->gem_handle, bo->name,
bo->map_cpu);
print_flags(flags);
if (!(flags & MAP_ASYNC)) {
bo_wait_with_stall_warning(dbg, bo, "CPU mapping");
}
if (!bo->cache_coherent && !bo->bufmgr->has_llc) {
/* If we're reusing an existing CPU mapping, the CPU caches may
* contain stale data from the last time we read from that mapping.
* (With the BO cache, it might even be data from a previous buffer!)
* Even if it's a brand new mapping, the kernel may have zeroed the
* buffer via CPU writes.
*
* We need to invalidate those cachelines so that we see the latest
* contents, and so long as we only read from the CPU mmap we do not
* need to write those cachelines back afterwards.
*
* On LLC, the emprical evidence suggests that writes from the GPU
* that bypass the LLC (i.e. for scanout) do *invalidate* the CPU
* cachelines. (Other reads, such as the display engine, bypass the
* LLC entirely requiring us to keep dirty pixels for the scanout
* out of any cache.)
*/
gen_invalidate_range(bo->map_cpu, bo->size);
}
return bo->map_cpu;
}
static void *
iris_bo_map_wc(struct pipe_debug_callback *dbg,
struct iris_bo *bo, unsigned flags)
{
struct iris_bufmgr *bufmgr = bo->bufmgr;
if (!bo->map_wc) {
DBG("iris_bo_map_wc: %d (%s)\n", bo->gem_handle, bo->name);
struct drm_i915_gem_mmap mmap_arg = {
.handle = bo->gem_handle,
.size = bo->size,
.flags = I915_MMAP_WC,
};
int ret = drm_ioctl(bufmgr->fd, DRM_IOCTL_I915_GEM_MMAP, &mmap_arg);
if (ret != 0) {
ret = -errno;
DBG("%s:%d: Error mapping buffer %d (%s): %s .\n",
__FILE__, __LINE__, bo->gem_handle, bo->name, strerror(errno));
return NULL;
}
void *map = (void *) (uintptr_t) mmap_arg.addr_ptr;
VG_DEFINED(map, bo->size);
if (p_atomic_cmpxchg(&bo->map_wc, NULL, map)) {
VG_NOACCESS(map, bo->size);
munmap(map, bo->size);
}
}
assert(bo->map_wc);
DBG("iris_bo_map_wc: %d (%s) -> %p\n", bo->gem_handle, bo->name, bo->map_wc);
print_flags(flags);
if (!(flags & MAP_ASYNC)) {
bo_wait_with_stall_warning(dbg, bo, "WC mapping");
}
return bo->map_wc;
}
/**
* Perform an uncached mapping via the GTT.
*
* Write access through the GTT is not quite fully coherent. On low power
* systems especially, like modern Atoms, we can observe reads from RAM before
* the write via GTT has landed. A write memory barrier that flushes the Write
* Combining Buffer (i.e. sfence/mfence) is not sufficient to order the later
* read after the write as the GTT write suffers a small delay through the GTT
* indirection. The kernel uses an uncached mmio read to ensure the GTT write
* is ordered with reads (either by the GPU, WB or WC) and unconditionally
* flushes prior to execbuf submission. However, if we are not informing the
* kernel about our GTT writes, it will not flush before earlier access, such
* as when using the cmdparser. Similarly, we need to be careful if we should
* ever issue a CPU read immediately following a GTT write.
*
* Telling the kernel about write access also has one more important
* side-effect. Upon receiving notification about the write, it cancels any
* scanout buffering for FBC/PSR and friends. Later FBC/PSR is then flushed by
* either SW_FINISH or DIRTYFB. The presumption is that we never write to the
* actual scanout via a mmaping, only to a backbuffer and so all the FBC/PSR
* tracking is handled on the buffer exchange instead.
*/
static void *
iris_bo_map_gtt(struct pipe_debug_callback *dbg,
struct iris_bo *bo, unsigned flags)
{
struct iris_bufmgr *bufmgr = bo->bufmgr;
/* Get a mapping of the buffer if we haven't before. */
if (bo->map_gtt == NULL) {
DBG("bo_map_gtt: mmap %d (%s)\n", bo->gem_handle, bo->name);
struct drm_i915_gem_mmap_gtt mmap_arg = { .handle = bo->gem_handle };
/* Get the fake offset back... */
int ret = drm_ioctl(bufmgr->fd, DRM_IOCTL_I915_GEM_MMAP_GTT, &mmap_arg);
if (ret != 0) {
DBG("%s:%d: Error preparing buffer map %d (%s): %s .\n",
__FILE__, __LINE__, bo->gem_handle, bo->name, strerror(errno));
return NULL;
}
/* and mmap it. */
void *map = mmap(0, bo->size, PROT_READ | PROT_WRITE,
MAP_SHARED, bufmgr->fd, mmap_arg.offset);
if (map == MAP_FAILED) {
DBG("%s:%d: Error mapping buffer %d (%s): %s .\n",
__FILE__, __LINE__, bo->gem_handle, bo->name, strerror(errno));
return NULL;
}
/* We don't need to use VALGRIND_MALLOCLIKE_BLOCK because Valgrind will
* already intercept this mmap call. However, for consistency between
* all the mmap paths, we mark the pointer as defined now and mark it
* as inaccessible afterwards.
*/
VG_DEFINED(map, bo->size);
if (p_atomic_cmpxchg(&bo->map_gtt, NULL, map)) {
VG_NOACCESS(map, bo->size);
munmap(map, bo->size);
}
}
assert(bo->map_gtt);
DBG("bo_map_gtt: %d (%s) -> %p, ", bo->gem_handle, bo->name, bo->map_gtt);
print_flags(flags);
if (!(flags & MAP_ASYNC)) {
bo_wait_with_stall_warning(dbg, bo, "GTT mapping");
}
return bo->map_gtt;
}
static bool
can_map_cpu(struct iris_bo *bo, unsigned flags)
{
if (bo->cache_coherent)
return true;
/* Even if the buffer itself is not cache-coherent (such as a scanout), on
* an LLC platform reads always are coherent (as they are performed via the
* central system agent). It is just the writes that we need to take special
* care to ensure that land in main memory and not stick in the CPU cache.
*/
if (!(flags & MAP_WRITE) && bo->bufmgr->has_llc)
return true;
/* If PERSISTENT or COHERENT are set, the mmapping needs to remain valid
* across batch flushes where the kernel will change cache domains of the
* bo, invalidating continued access to the CPU mmap on non-LLC device.
*
* Similarly, ASYNC typically means that the buffer will be accessed via
* both the CPU and the GPU simultaneously. Batches may be executed that
* use the BO even while it is mapped. While OpenGL technically disallows
* most drawing while non-persistent mappings are active, we may still use
* the GPU for blits or other operations, causing batches to happen at
* inconvenient times.
*/
if (flags & (MAP_PERSISTENT | MAP_COHERENT | MAP_ASYNC))
return false;
return !(flags & MAP_WRITE);
}
void *
iris_bo_map(struct pipe_debug_callback *dbg,
struct iris_bo *bo, unsigned flags)
{
if (bo->tiling_mode != I915_TILING_NONE && !(flags & MAP_RAW))
return iris_bo_map_gtt(dbg, bo, flags);
void *map;
if (can_map_cpu(bo, flags))
map = iris_bo_map_cpu(dbg, bo, flags);
else
map = iris_bo_map_wc(dbg, bo, flags);
/* Allow the attempt to fail by falling back to the GTT where necessary.
*
* Not every buffer can be mmaped directly using the CPU (or WC), for
* example buffers that wrap stolen memory or are imported from other
* devices. For those, we have little choice but to use a GTT mmapping.
* However, if we use a slow GTT mmapping for reads where we expected fast
* access, that order of magnitude difference in throughput will be clearly
* expressed by angry users.
*
* We skip MAP_RAW because we want to avoid map_gtt's fence detiling.
*/
if (!map && !(flags & MAP_RAW)) {
perf_debug(dbg, "Fallback GTT mapping for %s with access flags %x\n",
bo->name, flags);
map = iris_bo_map_gtt(dbg, bo, flags);
}
return map;
}
int
iris_bo_subdata(struct iris_bo *bo, uint64_t offset,
uint64_t size, const void *data)
{
struct iris_bufmgr *bufmgr = bo->bufmgr;
struct drm_i915_gem_pwrite pwrite = {
.handle = bo->gem_handle,
.offset = offset,
.size = size,
.data_ptr = (uint64_t) (uintptr_t) data,
};
int ret = drm_ioctl(bufmgr->fd, DRM_IOCTL_I915_GEM_PWRITE, &pwrite);
if (ret != 0) {
ret = -errno;
DBG("%s:%d: Error writing data to buffer %d: "
"(%"PRIu64" %"PRIu64") %s .\n",
__FILE__, __LINE__, bo->gem_handle, offset, size, strerror(errno));
}
return ret;
}
/** Waits for all GPU rendering with the object to have completed. */
void
iris_bo_wait_rendering(struct iris_bo *bo)
{
/* We require a kernel recent enough for WAIT_IOCTL support.
* See intel_init_bufmgr()
*/
iris_bo_wait(bo, -1);
}
/**
* Waits on a BO for the given amount of time.
*
* @bo: buffer object to wait for
* @timeout_ns: amount of time to wait in nanoseconds.
* If value is less than 0, an infinite wait will occur.
*
* Returns 0 if the wait was successful ie. the last batch referencing the
* object has completed within the allotted time. Otherwise some negative return
* value describes the error. Of particular interest is -ETIME when the wait has
* failed to yield the desired result.
*
* Similar to iris_bo_wait_rendering except a timeout parameter allows
* the operation to give up after a certain amount of time. Another subtle
* difference is the internal locking semantics are different (this variant does
* not hold the lock for the duration of the wait). This makes the wait subject
* to a larger userspace race window.
*
* The implementation shall wait until the object is no longer actively
* referenced within a batch buffer at the time of the call. The wait will
* not guarantee that the buffer is re-issued via another thread, or an flinked
* handle. Userspace must make sure this race does not occur if such precision
* is important.
*
* Note that some kernels have broken the inifite wait for negative values
* promise, upgrade to latest stable kernels if this is the case.
*/
int
iris_bo_wait(struct iris_bo *bo, int64_t timeout_ns)
{
struct iris_bufmgr *bufmgr = bo->bufmgr;
/* If we know it's idle, don't bother with the kernel round trip */
if (bo->idle && !bo->external)
return 0;
struct drm_i915_gem_wait wait = {
.bo_handle = bo->gem_handle,
.timeout_ns = timeout_ns,
};
int ret = drm_ioctl(bufmgr->fd, DRM_IOCTL_I915_GEM_WAIT, &wait);
if (ret == -1)
return -errno;
bo->idle = true;
return ret;
}
void
iris_bufmgr_destroy(struct iris_bufmgr *bufmgr)
{
mtx_destroy(&bufmgr->lock);
/* Free any cached buffer objects we were going to reuse */
for (int i = 0; i < bufmgr->num_buckets; i++) {
struct bo_cache_bucket *bucket = &bufmgr->cache_bucket[i];
list_for_each_entry_safe(struct iris_bo, bo, &bucket->head, head) {
list_del(&bo->head);
bo_free(bo);
}
for (int i = 0; i < IRIS_MEMZONE_COUNT; i++)
util_dynarray_fini(&bucket->vma_list[i]);
}
_mesa_hash_table_destroy(bufmgr->name_table, NULL);
_mesa_hash_table_destroy(bufmgr->handle_table, NULL);
free(bufmgr);
}
static int
bo_set_tiling_internal(struct iris_bo *bo, uint32_t tiling_mode,
uint32_t stride)
{
struct iris_bufmgr *bufmgr = bo->bufmgr;
struct drm_i915_gem_set_tiling set_tiling;
int ret;
if (bo->global_name == 0 &&
tiling_mode == bo->tiling_mode && stride == bo->stride)
return 0;
memset(&set_tiling, 0, sizeof(set_tiling));
do {
/* set_tiling is slightly broken and overwrites the
* input on the error path, so we have to open code
* drm_ioctl.
*/
set_tiling.handle = bo->gem_handle;
set_tiling.tiling_mode = tiling_mode;
set_tiling.stride = stride;
ret = ioctl(bufmgr->fd, DRM_IOCTL_I915_GEM_SET_TILING, &set_tiling);
} while (ret == -1 && (errno == EINTR || errno == EAGAIN));
if (ret == -1)
return -errno;
bo->tiling_mode = set_tiling.tiling_mode;
bo->swizzle_mode = set_tiling.swizzle_mode;
bo->stride = set_tiling.stride;
return 0;
}
int
iris_bo_get_tiling(struct iris_bo *bo, uint32_t *tiling_mode,
uint32_t *swizzle_mode)
{
*tiling_mode = bo->tiling_mode;
*swizzle_mode = bo->swizzle_mode;
return 0;
}
struct iris_bo *
iris_bo_import_dmabuf(struct iris_bufmgr *bufmgr, int prime_fd)
{
uint32_t handle;
struct iris_bo *bo;
mtx_lock(&bufmgr->lock);
int ret = drmPrimeFDToHandle(bufmgr->fd, prime_fd, &handle);
if (ret) {
DBG("import_dmabuf: failed to obtain handle from fd: %s\n",
strerror(errno));
mtx_unlock(&bufmgr->lock);
return NULL;
}
/*
* See if the kernel has already returned this buffer to us. Just as
* for named buffers, we must not create two bo's pointing at the same
* kernel object
*/
bo = hash_find_bo(bufmgr->handle_table, handle);
if (bo) {
iris_bo_reference(bo);
goto out;
}
bo = calloc(1, sizeof(*bo));
if (!bo)
goto out;
p_atomic_set(&bo->refcount, 1);
/* Determine size of bo. The fd-to-handle ioctl really should
* return the size, but it doesn't. If we have kernel 3.12 or
* later, we can lseek on the prime fd to get the size. Older
* kernels will just fail, in which case we fall back to the
* provided (estimated or guess size). */
ret = lseek(prime_fd, 0, SEEK_END);
if (ret != -1)
bo->size = ret;
bo->bufmgr = bufmgr;
bo->kflags = EXEC_OBJECT_SUPPORTS_48B_ADDRESS | EXEC_OBJECT_PINNED;
bo->gem_handle = handle;
_mesa_hash_table_insert(bufmgr->handle_table, &bo->gem_handle, bo);
bo->name = "prime";
bo->reusable = false;
bo->external = true;
bo->gtt_offset = vma_alloc(bufmgr, IRIS_MEMZONE_OTHER, bo->size, 1);
struct drm_i915_gem_get_tiling get_tiling = { .handle = bo->gem_handle };
if (drm_ioctl(bufmgr->fd, DRM_IOCTL_I915_GEM_GET_TILING, &get_tiling))
goto err;
bo->tiling_mode = get_tiling.tiling_mode;
bo->swizzle_mode = get_tiling.swizzle_mode;
/* XXX stride is unknown */
out:
mtx_unlock(&bufmgr->lock);
return bo;
err:
bo_free(bo);
mtx_unlock(&bufmgr->lock);
return NULL;
}
static void
iris_bo_make_external(struct iris_bo *bo)
{
struct iris_bufmgr *bufmgr = bo->bufmgr;
if (!bo->external) {
mtx_lock(&bufmgr->lock);
if (!bo->external) {
_mesa_hash_table_insert(bufmgr->handle_table, &bo->gem_handle, bo);
bo->external = true;
}
mtx_unlock(&bufmgr->lock);
}
}
int
iris_bo_export_dmabuf(struct iris_bo *bo, int *prime_fd)
{
struct iris_bufmgr *bufmgr = bo->bufmgr;
iris_bo_make_external(bo);
if (drmPrimeHandleToFD(bufmgr->fd, bo->gem_handle,
DRM_CLOEXEC, prime_fd) != 0)
return -errno;
bo->reusable = false;
return 0;
}
uint32_t
iris_bo_export_gem_handle(struct iris_bo *bo)
{
iris_bo_make_external(bo);
return bo->gem_handle;
}
int
iris_bo_flink(struct iris_bo *bo, uint32_t *name)
{
struct iris_bufmgr *bufmgr = bo->bufmgr;
if (!bo->global_name) {
struct drm_gem_flink flink = { .handle = bo->gem_handle };
if (drm_ioctl(bufmgr->fd, DRM_IOCTL_GEM_FLINK, &flink))
return -errno;
iris_bo_make_external(bo);
mtx_lock(&bufmgr->lock);
if (!bo->global_name) {
bo->global_name = flink.name;
_mesa_hash_table_insert(bufmgr->name_table, &bo->global_name, bo);
}
mtx_unlock(&bufmgr->lock);
bo->reusable = false;
}
*name = bo->global_name;
return 0;
}
static void
add_bucket(struct iris_bufmgr *bufmgr, int size)
{
unsigned int i = bufmgr->num_buckets;
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++;
assert(bucket_for_size(bufmgr, size) == &bufmgr->cache_bucket[i]);
assert(bucket_for_size(bufmgr, size - 2048) == &bufmgr->cache_bucket[i]);
assert(bucket_for_size(bufmgr, size + 1) != &bufmgr->cache_bucket[i]);
}
static void
init_cache_buckets(struct iris_bufmgr *bufmgr)
{
uint64_t size, cache_max_size = 64 * 1024 * 1024;
/* OK, so power of two buckets was too wasteful of memory.
* Give 3 other sizes between each power of two, to hopefully
* cover things accurately enough. (The alternative is
* probably to just go for exact matching of sizes, and assume
* that for things like composited window resize the tiled
* width/height alignment and rounding of sizes to pages will
* get us useful cache hit rates anyway)
*/
add_bucket(bufmgr, PAGE_SIZE);
add_bucket(bufmgr, PAGE_SIZE * 2);
add_bucket(bufmgr, PAGE_SIZE * 3);
/* Initialize the linked lists for BO reuse cache. */
for (size = 4 * PAGE_SIZE; size <= cache_max_size; size *= 2) {
add_bucket(bufmgr, size);
add_bucket(bufmgr, size + size * 1 / 4);
add_bucket(bufmgr, size + size * 2 / 4);
add_bucket(bufmgr, size + size * 3 / 4);
}
}
uint32_t
iris_create_hw_context(struct iris_bufmgr *bufmgr)
{
struct drm_i915_gem_context_create create = { };
int ret = drm_ioctl(bufmgr->fd, DRM_IOCTL_I915_GEM_CONTEXT_CREATE, &create);
if (ret != 0) {
DBG("DRM_IOCTL_I915_GEM_CONTEXT_CREATE failed: %s\n", strerror(errno));
return 0;
}
return create.ctx_id;
}
int
iris_hw_context_set_priority(struct iris_bufmgr *bufmgr,
uint32_t ctx_id,
int priority)
{
struct drm_i915_gem_context_param p = {
.ctx_id = ctx_id,
.param = I915_CONTEXT_PARAM_PRIORITY,
.value = priority,
};
int err;
err = 0;
if (drm_ioctl(bufmgr->fd, DRM_IOCTL_I915_GEM_CONTEXT_SETPARAM, &p))
err = -errno;
return err;
}
void
iris_destroy_hw_context(struct iris_bufmgr *bufmgr, uint32_t ctx_id)
{
struct drm_i915_gem_context_destroy d = { .ctx_id = ctx_id };
if (ctx_id != 0 &&
drm_ioctl(bufmgr->fd, DRM_IOCTL_I915_GEM_CONTEXT_DESTROY, &d) != 0) {
fprintf(stderr, "DRM_IOCTL_I915_GEM_CONTEXT_DESTROY failed: %s\n",
strerror(errno));
}
}
int
iris_reg_read(struct iris_bufmgr *bufmgr, uint32_t offset, uint64_t *result)
{
struct drm_i915_reg_read reg_read = { .offset = offset };
int ret = drm_ioctl(bufmgr->fd, DRM_IOCTL_I915_REG_READ, ®_read);
*result = reg_read.val;
return ret;
}
/**
* Initializes the GEM buffer manager, which uses the kernel to allocate, map,
* and manage map buffer objections.
*
* \param fd File descriptor of the opened DRM device.
*/
struct iris_bufmgr *
iris_bufmgr_init(struct gen_device_info *devinfo, int fd)
{
struct iris_bufmgr *bufmgr = calloc(1, sizeof(*bufmgr));
if (bufmgr == NULL)
return NULL;
/* Handles to buffer objects belong to the device fd and are not
* reference counted by the kernel. If the same fd is used by
* multiple parties (threads sharing the same screen bufmgr, or
* even worse the same device fd passed to multiple libraries)
* ownership of those handles is shared by those independent parties.
*
* Don't do this! Ensure that each library/bufmgr has its own device
* fd so that its namespace does not clash with another.
*/
bufmgr->fd = fd;
if (mtx_init(&bufmgr->lock, mtx_plain) != 0) {
free(bufmgr);
return NULL;
}
bufmgr->has_llc = devinfo->has_llc;
const uint64_t _4GB = 1ull << 32;
util_vma_heap_init(&bufmgr->vma_allocator[IRIS_MEMZONE_SHADER],
PAGE_SIZE, _4GB);
util_vma_heap_init(&bufmgr->vma_allocator[IRIS_MEMZONE_SURFACE],
1 * _4GB, _4GB);
util_vma_heap_init(&bufmgr->vma_allocator[IRIS_MEMZONE_DYNAMIC],
2 * _4GB, _4GB);
util_vma_heap_init(&bufmgr->vma_allocator[IRIS_MEMZONE_OTHER],
3 * _4GB, (1ull << 48) - 3 * _4GB);
// XXX: driconf
bufmgr->bo_reuse = env_var_as_boolean("bo_reuse", true);
init_cache_buckets(bufmgr);
bufmgr->name_table =
_mesa_hash_table_create(NULL, key_hash_uint, key_uint_equal);
bufmgr->handle_table =
_mesa_hash_table_create(NULL, key_hash_uint, key_uint_equal);
return bufmgr;
}
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