kolibrios/contrib/sdk/sources/libdrm/intel/intel_bufmgr_gem.c
Sergey Semyonov (Serge) 6df0ab430f libdrm-2.4.50
git-svn-id: svn://kolibrios.org@4363 a494cfbc-eb01-0410-851d-a64ba20cac60
2013-12-15 13:26:11 +00:00

3247 lines
91 KiB
C

/**************************************************************************
*
* Copyright © 2007 Red Hat Inc.
* Copyright © 2007-2012 Intel Corporation
* Copyright 2006 Tungsten Graphics, Inc., Bismarck, ND., USA
* All Rights Reserved.
*
* 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, sub license, 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 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 NON-INFRINGEMENT. IN NO EVENT SHALL
* THE COPYRIGHT HOLDERS, AUTHORS AND/OR ITS SUPPLIERS 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.
*
* The above copyright notice and this permission notice (including the
* next paragraph) shall be included in all copies or substantial portions
* of the Software.
*
*
**************************************************************************/
/*
* Authors: Thomas Hellström <thomas-at-tungstengraphics-dot-com>
* Keith Whitwell <keithw-at-tungstengraphics-dot-com>
* Eric Anholt <eric@anholt.net>
* Dave Airlie <airlied@linux.ie>
*/
#ifdef HAVE_CONFIG_H
#include "config.h"
#endif
#include <xf86drm.h>
#include <xf86atomic.h>
#include <fcntl.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <unistd.h>
#include <assert.h>
//#include <pthread.h>
#include <stdbool.h>
#include "errno.h"
#ifndef ETIME
#define ETIME ETIMEDOUT
#endif
#include "libdrm_lists.h"
#include "intel_bufmgr.h"
#include "intel_bufmgr_priv.h"
#include "intel_chipset.h"
#include "intel_aub.h"
#include "string.h"
#include "i915_drm.h"
#ifdef HAVE_VALGRIND
#include <valgrind.h>
#include <memcheck.h>
#define VG(x) x
#else
#define VG(x)
#endif
#define VG_CLEAR(s) VG(memset(&s, 0, sizeof(s)))
#if 0
#define DBG(...) do { \
if (bufmgr_gem->bufmgr.debug) \
fprintf(stderr, __VA_ARGS__); \
} while (0)
#endif
//#define DBG(...) fprintf(stderr, __VA_ARGS__)
#define DBG(...)
#define ARRAY_SIZE(x) (sizeof(x) / sizeof((x)[0]))
typedef struct _drm_intel_bo_gem drm_intel_bo_gem;
struct drm_intel_gem_bo_bucket {
drmMMListHead head;
unsigned long size;
};
typedef struct _drm_intel_bufmgr_gem {
drm_intel_bufmgr bufmgr;
int fd;
int max_relocs;
// pthread_mutex_t lock;
struct drm_i915_gem_exec_object *exec_objects;
struct drm_i915_gem_exec_object2 *exec2_objects;
drm_intel_bo **exec_bos;
int exec_size;
int exec_count;
/** Array of lists of cached gem objects of power-of-two sizes */
struct drm_intel_gem_bo_bucket cache_bucket[14 * 4];
int num_buckets;
time_t time;
drmMMListHead named;
drmMMListHead vma_cache;
int vma_count, vma_open, vma_max;
uint64_t gtt_size;
int available_fences;
int pci_device;
int gen;
unsigned int has_bsd : 1;
unsigned int has_blt : 1;
unsigned int has_relaxed_fencing : 1;
unsigned int has_llc : 1;
unsigned int has_wait_timeout : 1;
unsigned int bo_reuse : 1;
unsigned int no_exec : 1;
unsigned int has_vebox : 1;
bool fenced_relocs;
char *aub_filename;
FILE *aub_file;
uint32_t aub_offset;
} drm_intel_bufmgr_gem;
#define DRM_INTEL_RELOC_FENCE (1<<0)
typedef struct _drm_intel_reloc_target_info {
drm_intel_bo *bo;
int flags;
} drm_intel_reloc_target;
struct _drm_intel_bo_gem {
drm_intel_bo bo;
atomic_t refcount;
uint32_t gem_handle;
const char *name;
/**
* Kenel-assigned global name for this object
*
* List contains both flink named and prime fd'd objects
*/
unsigned int global_name;
drmMMListHead name_list;
/**
* Index of the buffer within the validation list while preparing a
* batchbuffer execution.
*/
int validate_index;
/**
* Current tiling mode
*/
uint32_t tiling_mode;
uint32_t swizzle_mode;
unsigned long stride;
time_t free_time;
/** Array passed to the DRM containing relocation information. */
struct drm_i915_gem_relocation_entry *relocs;
/**
* Array of info structs corresponding to relocs[i].target_handle etc
*/
drm_intel_reloc_target *reloc_target_info;
/** Number of entries in relocs */
int reloc_count;
/** Mapped address for the buffer, saved across map/unmap cycles */
void *mem_virtual;
/** GTT virtual address for the buffer, saved across map/unmap cycles */
void *gtt_virtual;
int map_count;
drmMMListHead vma_list;
/** BO cache list */
drmMMListHead head;
/**
* Boolean of whether this BO and its children have been included in
* the current drm_intel_bufmgr_check_aperture_space() total.
*/
bool included_in_check_aperture;
/**
* Boolean of whether this buffer has been used as a relocation
* target and had its size accounted for, and thus can't have any
* further relocations added to it.
*/
bool used_as_reloc_target;
/**
* Boolean of whether we have encountered an error whilst building the relocation tree.
*/
bool has_error;
/**
* Boolean of whether this buffer can be re-used
*/
bool reusable;
/**
* Size in bytes of this buffer and its relocation descendents.
*
* Used to avoid costly tree walking in
* drm_intel_bufmgr_check_aperture in the common case.
*/
int reloc_tree_size;
/**
* Number of potential fence registers required by this buffer and its
* relocations.
*/
int reloc_tree_fences;
/** Flags that we may need to do the SW_FINSIH ioctl on unmap. */
bool mapped_cpu_write;
uint32_t aub_offset;
drm_intel_aub_annotation *aub_annotations;
unsigned aub_annotation_count;
};
static unsigned int
drm_intel_gem_estimate_batch_space(drm_intel_bo ** bo_array, int count);
static unsigned int
drm_intel_gem_compute_batch_space(drm_intel_bo ** bo_array, int count);
static int
drm_intel_gem_bo_get_tiling(drm_intel_bo *bo, uint32_t * tiling_mode,
uint32_t * swizzle_mode);
static int
drm_intel_gem_bo_set_tiling_internal(drm_intel_bo *bo,
uint32_t tiling_mode,
uint32_t stride);
static void drm_intel_gem_bo_unreference_locked_timed(drm_intel_bo *bo,
time_t time);
static void drm_intel_gem_bo_unreference(drm_intel_bo *bo);
static void drm_intel_gem_bo_free(drm_intel_bo *bo);
static unsigned long
drm_intel_gem_bo_tile_size(drm_intel_bufmgr_gem *bufmgr_gem, unsigned long size,
uint32_t *tiling_mode)
{
unsigned long min_size, max_size;
unsigned long i;
if (*tiling_mode == I915_TILING_NONE)
return size;
/* 965+ just need multiples of page size for tiling */
if (bufmgr_gem->gen >= 4)
return ROUND_UP_TO(size, 4096);
/* Older chips need powers of two, of at least 512k or 1M */
if (bufmgr_gem->gen == 3) {
min_size = 1024*1024;
max_size = 128*1024*1024;
} else {
min_size = 512*1024;
max_size = 64*1024*1024;
}
if (size > max_size) {
*tiling_mode = I915_TILING_NONE;
return size;
}
/* Do we need to allocate every page for the fence? */
if (bufmgr_gem->has_relaxed_fencing)
return ROUND_UP_TO(size, 4096);
for (i = min_size; i < size; i <<= 1)
;
return i;
}
/*
* Round a given pitch up to the minimum required for X tiling on a
* given chip. We use 512 as the minimum to allow for a later tiling
* change.
*/
static unsigned long
drm_intel_gem_bo_tile_pitch(drm_intel_bufmgr_gem *bufmgr_gem,
unsigned long pitch, uint32_t *tiling_mode)
{
unsigned long tile_width;
unsigned long i;
/* If untiled, then just align it so that we can do rendering
* to it with the 3D engine.
*/
if (*tiling_mode == I915_TILING_NONE)
return ALIGN(pitch, 64);
if (*tiling_mode == I915_TILING_X
|| (IS_915(bufmgr_gem->pci_device)
&& *tiling_mode == I915_TILING_Y))
tile_width = 512;
else
tile_width = 128;
/* 965 is flexible */
if (bufmgr_gem->gen >= 4)
return ROUND_UP_TO(pitch, tile_width);
/* The older hardware has a maximum pitch of 8192 with tiled
* surfaces, so fallback to untiled if it's too large.
*/
if (pitch > 8192) {
*tiling_mode = I915_TILING_NONE;
return ALIGN(pitch, 64);
}
/* Pre-965 needs power of two tile width */
for (i = tile_width; i < pitch; i <<= 1)
;
return i;
}
static struct drm_intel_gem_bo_bucket *
drm_intel_gem_bo_bucket_for_size(drm_intel_bufmgr_gem *bufmgr_gem,
unsigned long size)
{
int i;
for (i = 0; i < bufmgr_gem->num_buckets; i++) {
struct drm_intel_gem_bo_bucket *bucket =
&bufmgr_gem->cache_bucket[i];
if (bucket->size >= size) {
return bucket;
}
}
return NULL;
}
static void
drm_intel_gem_dump_validation_list(drm_intel_bufmgr_gem *bufmgr_gem)
{
int i, j;
for (i = 0; i < bufmgr_gem->exec_count; i++) {
drm_intel_bo *bo = bufmgr_gem->exec_bos[i];
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
if (bo_gem->relocs == NULL) {
DBG("%2d: %d (%s)\n", i, bo_gem->gem_handle,
bo_gem->name);
continue;
}
for (j = 0; j < bo_gem->reloc_count; j++) {
drm_intel_bo *target_bo = bo_gem->reloc_target_info[j].bo;
drm_intel_bo_gem *target_gem =
(drm_intel_bo_gem *) target_bo;
DBG("%2d: %d (%s)@0x%08llx -> "
"%d (%s)@0x%08lx + 0x%08x\n",
i,
bo_gem->gem_handle, bo_gem->name,
(unsigned long long)bo_gem->relocs[j].offset,
target_gem->gem_handle,
target_gem->name,
target_bo->offset,
bo_gem->relocs[j].delta);
}
}
}
static inline void
drm_intel_gem_bo_reference(drm_intel_bo *bo)
{
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
atomic_inc(&bo_gem->refcount);
}
/**
* Adds the given buffer to the list of buffers to be validated (moved into the
* appropriate memory type) with the next batch submission.
*
* If a buffer is validated multiple times in a batch submission, it ends up
* with the intersection of the memory type flags and the union of the
* access flags.
*/
static void
drm_intel_add_validate_buffer(drm_intel_bo *bo)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *) bo->bufmgr;
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
int index;
if (bo_gem->validate_index != -1)
return;
/* Extend the array of validation entries as necessary. */
if (bufmgr_gem->exec_count == bufmgr_gem->exec_size) {
int new_size = bufmgr_gem->exec_size * 2;
if (new_size == 0)
new_size = 5;
bufmgr_gem->exec_objects =
realloc(bufmgr_gem->exec_objects,
sizeof(*bufmgr_gem->exec_objects) * new_size);
bufmgr_gem->exec_bos =
realloc(bufmgr_gem->exec_bos,
sizeof(*bufmgr_gem->exec_bos) * new_size);
bufmgr_gem->exec_size = new_size;
}
index = bufmgr_gem->exec_count;
bo_gem->validate_index = index;
/* Fill in array entry */
bufmgr_gem->exec_objects[index].handle = bo_gem->gem_handle;
bufmgr_gem->exec_objects[index].relocation_count = bo_gem->reloc_count;
bufmgr_gem->exec_objects[index].relocs_ptr = (uintptr_t) bo_gem->relocs;
bufmgr_gem->exec_objects[index].alignment = 0;
bufmgr_gem->exec_objects[index].offset = 0;
bufmgr_gem->exec_bos[index] = bo;
bufmgr_gem->exec_count++;
}
static void
drm_intel_add_validate_buffer2(drm_intel_bo *bo, int need_fence)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *)bo->bufmgr;
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *)bo;
int index;
if (bo_gem->validate_index != -1) {
if (need_fence)
bufmgr_gem->exec2_objects[bo_gem->validate_index].flags |=
EXEC_OBJECT_NEEDS_FENCE;
return;
}
/* Extend the array of validation entries as necessary. */
if (bufmgr_gem->exec_count == bufmgr_gem->exec_size) {
int new_size = bufmgr_gem->exec_size * 2;
if (new_size == 0)
new_size = 5;
bufmgr_gem->exec2_objects =
realloc(bufmgr_gem->exec2_objects,
sizeof(*bufmgr_gem->exec2_objects) * new_size);
bufmgr_gem->exec_bos =
realloc(bufmgr_gem->exec_bos,
sizeof(*bufmgr_gem->exec_bos) * new_size);
bufmgr_gem->exec_size = new_size;
}
index = bufmgr_gem->exec_count;
bo_gem->validate_index = index;
/* Fill in array entry */
bufmgr_gem->exec2_objects[index].handle = bo_gem->gem_handle;
bufmgr_gem->exec2_objects[index].relocation_count = bo_gem->reloc_count;
bufmgr_gem->exec2_objects[index].relocs_ptr = (uintptr_t)bo_gem->relocs;
bufmgr_gem->exec2_objects[index].alignment = 0;
bufmgr_gem->exec2_objects[index].offset = 0;
bufmgr_gem->exec_bos[index] = bo;
bufmgr_gem->exec2_objects[index].flags = 0;
bufmgr_gem->exec2_objects[index].rsvd1 = 0;
bufmgr_gem->exec2_objects[index].rsvd2 = 0;
if (need_fence) {
bufmgr_gem->exec2_objects[index].flags |=
EXEC_OBJECT_NEEDS_FENCE;
}
bufmgr_gem->exec_count++;
}
#define RELOC_BUF_SIZE(x) ((I915_RELOC_HEADER + x * I915_RELOC0_STRIDE) * \
sizeof(uint32_t))
static void
drm_intel_bo_gem_set_in_aperture_size(drm_intel_bufmgr_gem *bufmgr_gem,
drm_intel_bo_gem *bo_gem)
{
int size;
assert(!bo_gem->used_as_reloc_target);
/* The older chipsets are far-less flexible in terms of tiling,
* and require tiled buffer to be size aligned in the aperture.
* This means that in the worst possible case we will need a hole
* twice as large as the object in order for it to fit into the
* aperture. Optimal packing is for wimps.
*/
size = bo_gem->bo.size;
if (bufmgr_gem->gen < 4 && bo_gem->tiling_mode != I915_TILING_NONE) {
int min_size;
if (bufmgr_gem->has_relaxed_fencing) {
if (bufmgr_gem->gen == 3)
min_size = 1024*1024;
else
min_size = 512*1024;
while (min_size < size)
min_size *= 2;
} else
min_size = size;
/* Account for worst-case alignment. */
size = 2 * min_size;
}
bo_gem->reloc_tree_size = size;
}
static int
drm_intel_setup_reloc_list(drm_intel_bo *bo)
{
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *) bo->bufmgr;
unsigned int max_relocs = bufmgr_gem->max_relocs;
if (bo->size / 4 < max_relocs)
max_relocs = bo->size / 4;
bo_gem->relocs = malloc(max_relocs *
sizeof(struct drm_i915_gem_relocation_entry));
bo_gem->reloc_target_info = malloc(max_relocs *
sizeof(drm_intel_reloc_target));
if (bo_gem->relocs == NULL || bo_gem->reloc_target_info == NULL) {
bo_gem->has_error = true;
free (bo_gem->relocs);
bo_gem->relocs = NULL;
free (bo_gem->reloc_target_info);
bo_gem->reloc_target_info = NULL;
return 1;
}
return 0;
}
static int
drm_intel_gem_bo_busy(drm_intel_bo *bo)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *) bo->bufmgr;
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
struct drm_i915_gem_busy busy;
int ret;
VG_CLEAR(busy);
busy.handle = bo_gem->gem_handle;
ret = drmIoctl(bufmgr_gem->fd, DRM_IOCTL_I915_GEM_BUSY, &busy);
return (ret == 0 && busy.busy);
}
static int
drm_intel_gem_bo_madvise_internal(drm_intel_bufmgr_gem *bufmgr_gem,
drm_intel_bo_gem *bo_gem, int state)
{
struct drm_i915_gem_madvise madv;
VG_CLEAR(madv);
madv.handle = bo_gem->gem_handle;
madv.madv = state;
madv.retained = 1;
// drmIoctl(bufmgr_gem->fd, DRM_IOCTL_I915_GEM_MADVISE, &madv);
return madv.retained;
}
static int
drm_intel_gem_bo_madvise(drm_intel_bo *bo, int madv)
{
return drm_intel_gem_bo_madvise_internal
((drm_intel_bufmgr_gem *) bo->bufmgr,
(drm_intel_bo_gem *) bo,
madv);
}
/* drop the oldest entries that have been purged by the kernel */
static void
drm_intel_gem_bo_cache_purge_bucket(drm_intel_bufmgr_gem *bufmgr_gem,
struct drm_intel_gem_bo_bucket *bucket)
{
while (!DRMLISTEMPTY(&bucket->head)) {
drm_intel_bo_gem *bo_gem;
bo_gem = DRMLISTENTRY(drm_intel_bo_gem,
bucket->head.next, head);
if (drm_intel_gem_bo_madvise_internal
(bufmgr_gem, bo_gem, I915_MADV_DONTNEED))
break;
DRMLISTDEL(&bo_gem->head);
drm_intel_gem_bo_free(&bo_gem->bo);
}
}
static drm_intel_bo *
drm_intel_gem_bo_alloc_internal(drm_intel_bufmgr *bufmgr,
const char *name,
unsigned long size,
unsigned long flags,
uint32_t tiling_mode,
unsigned long stride)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *) bufmgr;
drm_intel_bo_gem *bo_gem;
unsigned int page_size = 4096;
int ret;
struct drm_intel_gem_bo_bucket *bucket;
bool alloc_from_cache;
unsigned long bo_size;
bool for_render = false;
if (flags & BO_ALLOC_FOR_RENDER)
for_render = true;
/* Round the allocated size up to a power of two number of pages. */
bucket = drm_intel_gem_bo_bucket_for_size(bufmgr_gem, 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;
}
// pthread_mutex_lock(&bufmgr_gem->lock);
/* Get a buffer out of the cache if available */
retry:
alloc_from_cache = false;
if (bucket != NULL && !DRMLISTEMPTY(&bucket->head)) {
if (for_render) {
/* Allocate new render-target BOs from the tail (MRU)
* of the list, as it will likely be hot in the GPU
* cache and in the aperture for us.
*/
bo_gem = DRMLISTENTRY(drm_intel_bo_gem,
bucket->head.prev, head);
DRMLISTDEL(&bo_gem->head);
alloc_from_cache = true;
} else {
/* For non-render-target BOs (where we're probably
* going to map it first thing in order to fill it
* with data), check if the last BO in the cache is
* unbusy, and only reuse in that case. Otherwise,
* allocating a new buffer is probably faster than
* waiting for the GPU to finish.
*/
bo_gem = DRMLISTENTRY(drm_intel_bo_gem,
bucket->head.next, head);
if (!drm_intel_gem_bo_busy(&bo_gem->bo)) {
alloc_from_cache = true;
DRMLISTDEL(&bo_gem->head);
}
}
if (alloc_from_cache) {
if (!drm_intel_gem_bo_madvise_internal
(bufmgr_gem, bo_gem, I915_MADV_WILLNEED)) {
drm_intel_gem_bo_free(&bo_gem->bo);
drm_intel_gem_bo_cache_purge_bucket(bufmgr_gem,
bucket);
goto retry;
}
if (drm_intel_gem_bo_set_tiling_internal(&bo_gem->bo,
tiling_mode,
stride)) {
drm_intel_gem_bo_free(&bo_gem->bo);
goto retry;
}
}
}
// pthread_mutex_unlock(&bufmgr_gem->lock);
if (!alloc_from_cache) {
struct drm_i915_gem_create create;
bo_gem = calloc(1, sizeof(*bo_gem));
if (!bo_gem)
return NULL;
bo_gem->bo.size = bo_size;
VG_CLEAR(create);
create.size = bo_size;
ret = drmIoctl(bufmgr_gem->fd,
DRM_IOCTL_I915_GEM_CREATE,
&create);
bo_gem->gem_handle = create.handle;
bo_gem->bo.handle = bo_gem->gem_handle;
if (ret != 0) {
free(bo_gem);
return NULL;
}
bo_gem->bo.bufmgr = bufmgr;
bo_gem->tiling_mode = I915_TILING_NONE;
bo_gem->swizzle_mode = I915_BIT_6_SWIZZLE_NONE;
bo_gem->stride = 0;
if (drm_intel_gem_bo_set_tiling_internal(&bo_gem->bo,
tiling_mode,
stride)) {
drm_intel_gem_bo_free(&bo_gem->bo);
return NULL;
}
DRMINITLISTHEAD(&bo_gem->name_list);
DRMINITLISTHEAD(&bo_gem->vma_list);
}
bo_gem->name = name;
atomic_set(&bo_gem->refcount, 1);
bo_gem->validate_index = -1;
bo_gem->reloc_tree_fences = 0;
bo_gem->used_as_reloc_target = false;
bo_gem->has_error = false;
bo_gem->reusable = true;
bo_gem->aub_annotations = NULL;
bo_gem->aub_annotation_count = 0;
drm_intel_bo_gem_set_in_aperture_size(bufmgr_gem, bo_gem);
DBG("bo_create: buf %d (%s) %ldb\n",
bo_gem->gem_handle, bo_gem->name, size);
return &bo_gem->bo;
}
static drm_intel_bo *
drm_intel_gem_bo_alloc_for_render(drm_intel_bufmgr *bufmgr,
const char *name,
unsigned long size,
unsigned int alignment)
{
return drm_intel_gem_bo_alloc_internal(bufmgr, name, size,
BO_ALLOC_FOR_RENDER,
I915_TILING_NONE, 0);
}
static drm_intel_bo *
drm_intel_gem_bo_alloc(drm_intel_bufmgr *bufmgr,
const char *name,
unsigned long size,
unsigned int alignment)
{
return drm_intel_gem_bo_alloc_internal(bufmgr, name, size, 0,
I915_TILING_NONE, 0);
}
static drm_intel_bo *
drm_intel_gem_bo_alloc_tiled(drm_intel_bufmgr *bufmgr, const char *name,
int x, int y, int cpp, uint32_t *tiling_mode,
unsigned long *pitch, unsigned long flags)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *)bufmgr;
unsigned long size, stride;
uint32_t tiling;
do {
unsigned long aligned_y, height_alignment;
tiling = *tiling_mode;
/* If we're tiled, our allocations are in 8 or 32-row blocks,
* so failure to align our height means that we won't allocate
* enough pages.
*
* If we're untiled, we still have to align to 2 rows high
* because the data port accesses 2x2 blocks even if the
* bottom row isn't to be rendered, so failure to align means
* we could walk off the end of the GTT and fault. This is
* documented on 965, and may be the case on older chipsets
* too so we try to be careful.
*/
aligned_y = y;
height_alignment = 2;
if ((bufmgr_gem->gen == 2) && tiling != I915_TILING_NONE)
height_alignment = 16;
else if (tiling == I915_TILING_X
|| (IS_915(bufmgr_gem->pci_device)
&& tiling == I915_TILING_Y))
height_alignment = 8;
else if (tiling == I915_TILING_Y)
height_alignment = 32;
aligned_y = ALIGN(y, height_alignment);
stride = x * cpp;
stride = drm_intel_gem_bo_tile_pitch(bufmgr_gem, stride, tiling_mode);
size = stride * aligned_y;
size = drm_intel_gem_bo_tile_size(bufmgr_gem, size, tiling_mode);
} while (*tiling_mode != tiling);
*pitch = stride;
if (tiling == I915_TILING_NONE)
stride = 0;
return drm_intel_gem_bo_alloc_internal(bufmgr, name, size, flags,
tiling, stride);
}
/**
* Returns a drm_intel_bo wrapping the given buffer object handle.
*
* This can be used when one application needs to pass a buffer object
* to another.
*/
drm_intel_bo *
drm_intel_bo_gem_create_from_name(drm_intel_bufmgr *bufmgr,
const char *name,
unsigned int handle)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *) bufmgr;
drm_intel_bo_gem *bo_gem;
int ret;
struct drm_gem_open open_arg;
struct drm_i915_gem_get_tiling get_tiling;
drmMMListHead *list;
/* 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.
*/
for (list = bufmgr_gem->named.next;
list != &bufmgr_gem->named;
list = list->next) {
bo_gem = DRMLISTENTRY(drm_intel_bo_gem, list, name_list);
if (bo_gem->global_name == handle) {
drm_intel_gem_bo_reference(&bo_gem->bo);
return &bo_gem->bo;
}
}
bo_gem = calloc(1, sizeof(*bo_gem));
if (!bo_gem)
return NULL;
VG_CLEAR(open_arg);
open_arg.name = handle;
ret = drmIoctl(bufmgr_gem->fd,
DRM_IOCTL_GEM_OPEN,
&open_arg);
if (ret != 0) {
DBG("Couldn't reference %s handle 0x%08x: %s\n",
name, handle, strerror(errno));
free(bo_gem);
return NULL;
}
bo_gem->bo.size = open_arg.size;
bo_gem->bo.offset = 0;
bo_gem->bo.virtual = NULL;
bo_gem->bo.bufmgr = bufmgr;
bo_gem->name = name;
atomic_set(&bo_gem->refcount, 1);
bo_gem->validate_index = -1;
bo_gem->gem_handle = open_arg.handle;
bo_gem->bo.handle = open_arg.handle;
bo_gem->global_name = handle;
bo_gem->reusable = false;
VG_CLEAR(get_tiling);
get_tiling.handle = bo_gem->gem_handle;
ret = drmIoctl(bufmgr_gem->fd,
DRM_IOCTL_I915_GEM_GET_TILING,
&get_tiling);
if (ret != 0) {
drm_intel_gem_bo_unreference(&bo_gem->bo);
return NULL;
}
bo_gem->tiling_mode = get_tiling.tiling_mode;
bo_gem->swizzle_mode = get_tiling.swizzle_mode;
/* XXX stride is unknown */
drm_intel_bo_gem_set_in_aperture_size(bufmgr_gem, bo_gem);
DRMINITLISTHEAD(&bo_gem->vma_list);
DRMLISTADDTAIL(&bo_gem->name_list, &bufmgr_gem->named);
DBG("bo_create_from_handle: %d (%s)\n", handle, bo_gem->name);
return &bo_gem->bo;
}
static void
drm_intel_gem_bo_free(drm_intel_bo *bo)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *) bo->bufmgr;
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
struct drm_gem_close close;
int ret;
DRMLISTDEL(&bo_gem->vma_list);
if (bo_gem->mem_virtual) {
VG(VALGRIND_FREELIKE_BLOCK(bo_gem->mem_virtual, 0));
bufmgr_gem->vma_count--;
}
if (bo_gem->gtt_virtual) {
bufmgr_gem->vma_count--;
}
/* Close this object */
VG_CLEAR(close);
close.handle = bo_gem->gem_handle;
ret = drmIoctl(bufmgr_gem->fd, DRM_IOCTL_GEM_CLOSE, &close);
if (ret != 0) {
DBG("DRM_IOCTL_GEM_CLOSE %d failed (%s): %s\n",
bo_gem->gem_handle, bo_gem->name, strerror(errno));
}
free(bo_gem->aub_annotations);
free(bo);
}
static void
drm_intel_gem_bo_mark_mmaps_incoherent(drm_intel_bo *bo)
{
#if HAVE_VALGRIND
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
if (bo_gem->mem_virtual)
VALGRIND_MAKE_MEM_NOACCESS(bo_gem->mem_virtual, bo->size);
if (bo_gem->gtt_virtual)
VALGRIND_MAKE_MEM_NOACCESS(bo_gem->gtt_virtual, bo->size);
#endif
}
/** Frees all cached buffers significantly older than @time. */
static void
drm_intel_gem_cleanup_bo_cache(drm_intel_bufmgr_gem *bufmgr_gem, time_t time)
{
int i;
if (bufmgr_gem->time == time)
return;
for (i = 0; i < bufmgr_gem->num_buckets; i++) {
struct drm_intel_gem_bo_bucket *bucket =
&bufmgr_gem->cache_bucket[i];
while (!DRMLISTEMPTY(&bucket->head)) {
drm_intel_bo_gem *bo_gem;
bo_gem = DRMLISTENTRY(drm_intel_bo_gem,
bucket->head.next, head);
if (time - bo_gem->free_time <= 1)
break;
DRMLISTDEL(&bo_gem->head);
drm_intel_gem_bo_free(&bo_gem->bo);
}
}
bufmgr_gem->time = time;
}
static void drm_intel_gem_bo_purge_vma_cache(drm_intel_bufmgr_gem *bufmgr_gem)
{
int limit;
DBG("%s: cached=%d, open=%d, limit=%d\n", __FUNCTION__,
bufmgr_gem->vma_count, bufmgr_gem->vma_open, bufmgr_gem->vma_max);
if (bufmgr_gem->vma_max < 0)
return;
/* We may need to evict a few entries in order to create new mmaps */
limit = bufmgr_gem->vma_max - 2*bufmgr_gem->vma_open;
if (limit < 0)
limit = 0;
while (bufmgr_gem->vma_count > limit) {
drm_intel_bo_gem *bo_gem;
bo_gem = DRMLISTENTRY(drm_intel_bo_gem,
bufmgr_gem->vma_cache.next,
vma_list);
assert(bo_gem->map_count == 0);
DRMLISTDELINIT(&bo_gem->vma_list);
if (bo_gem->mem_virtual) {
// munmap(bo_gem->mem_virtual, bo_gem->bo.size);
bo_gem->mem_virtual = NULL;
bufmgr_gem->vma_count--;
}
if (bo_gem->gtt_virtual) {
// munmap(bo_gem->gtt_virtual, bo_gem->bo.size);
bo_gem->gtt_virtual = NULL;
bufmgr_gem->vma_count--;
}
}
}
static void drm_intel_gem_bo_close_vma(drm_intel_bufmgr_gem *bufmgr_gem,
drm_intel_bo_gem *bo_gem)
{
bufmgr_gem->vma_open--;
DRMLISTADDTAIL(&bo_gem->vma_list, &bufmgr_gem->vma_cache);
if (bo_gem->mem_virtual)
bufmgr_gem->vma_count++;
if (bo_gem->gtt_virtual)
bufmgr_gem->vma_count++;
drm_intel_gem_bo_purge_vma_cache(bufmgr_gem);
}
static void drm_intel_gem_bo_open_vma(drm_intel_bufmgr_gem *bufmgr_gem,
drm_intel_bo_gem *bo_gem)
{
bufmgr_gem->vma_open++;
DRMLISTDEL(&bo_gem->vma_list);
if (bo_gem->mem_virtual)
bufmgr_gem->vma_count--;
if (bo_gem->gtt_virtual)
bufmgr_gem->vma_count--;
drm_intel_gem_bo_purge_vma_cache(bufmgr_gem);
}
static void
drm_intel_gem_bo_unreference_final(drm_intel_bo *bo, time_t time)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *) bo->bufmgr;
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
struct drm_intel_gem_bo_bucket *bucket;
int i;
/* Unreference all the target buffers */
for (i = 0; i < bo_gem->reloc_count; i++) {
if (bo_gem->reloc_target_info[i].bo != bo) {
drm_intel_gem_bo_unreference_locked_timed(bo_gem->
reloc_target_info[i].bo,
time);
}
}
bo_gem->reloc_count = 0;
bo_gem->used_as_reloc_target = false;
DBG("bo_unreference final: %d (%s)\n",
bo_gem->gem_handle, bo_gem->name);
/* release memory associated with this object */
if (bo_gem->reloc_target_info) {
free(bo_gem->reloc_target_info);
bo_gem->reloc_target_info = NULL;
}
if (bo_gem->relocs) {
free(bo_gem->relocs);
bo_gem->relocs = NULL;
}
/* Clear any left-over mappings */
if (bo_gem->map_count) {
DBG("bo freed with non-zero map-count %d\n", bo_gem->map_count);
bo_gem->map_count = 0;
drm_intel_gem_bo_close_vma(bufmgr_gem, bo_gem);
drm_intel_gem_bo_mark_mmaps_incoherent(bo);
}
DRMLISTDEL(&bo_gem->name_list);
bucket = drm_intel_gem_bo_bucket_for_size(bufmgr_gem, bo->size);
/* Put the buffer into our internal cache for reuse if we can. */
if (bufmgr_gem->bo_reuse && bo_gem->reusable && bucket != NULL &&
drm_intel_gem_bo_madvise_internal(bufmgr_gem, bo_gem,
I915_MADV_DONTNEED)) {
bo_gem->free_time = time;
bo_gem->name = NULL;
bo_gem->validate_index = -1;
DRMLISTADDTAIL(&bo_gem->head, &bucket->head);
} else {
drm_intel_gem_bo_free(bo);
}
}
static void drm_intel_gem_bo_unreference_locked_timed(drm_intel_bo *bo,
time_t time)
{
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
assert(atomic_read(&bo_gem->refcount) > 0);
if (atomic_dec_and_test(&bo_gem->refcount))
drm_intel_gem_bo_unreference_final(bo, time);
}
static void drm_intel_gem_bo_unreference(drm_intel_bo *bo)
{
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
assert(atomic_read(&bo_gem->refcount) > 0);
if (atomic_dec_and_test(&bo_gem->refcount)) {
drm_intel_bufmgr_gem *bufmgr_gem =
(drm_intel_bufmgr_gem *) bo->bufmgr;
// struct timespec time;
// clock_gettime(CLOCK_MONOTONIC, &time);
// pthread_mutex_lock(&bufmgr_gem->lock);
drm_intel_gem_bo_unreference_final(bo, 0);
drm_intel_gem_cleanup_bo_cache(bufmgr_gem, 0);
// pthread_mutex_unlock(&bufmgr_gem->lock);
}
}
static int drm_intel_gem_bo_map(drm_intel_bo *bo, int write_enable)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *) bo->bufmgr;
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
struct drm_i915_gem_set_domain set_domain;
int ret;
// pthread_mutex_lock(&bufmgr_gem->lock);
if (bo_gem->map_count++ == 0)
drm_intel_gem_bo_open_vma(bufmgr_gem, bo_gem);
if (!bo_gem->mem_virtual) {
struct drm_i915_gem_mmap mmap_arg;
DBG("bo_map: %d (%s), map_count=%d\n",
bo_gem->gem_handle, bo_gem->name, bo_gem->map_count);
VG_CLEAR(mmap_arg);
mmap_arg.handle = bo_gem->gem_handle;
mmap_arg.offset = 0;
mmap_arg.size = bo->size;
ret = drmIoctl(bufmgr_gem->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->gem_handle,
bo_gem->name, strerror(errno));
if (--bo_gem->map_count == 0)
drm_intel_gem_bo_close_vma(bufmgr_gem, bo_gem);
// pthread_mutex_unlock(&bufmgr_gem->lock);
return ret;
}
VG(VALGRIND_MALLOCLIKE_BLOCK(mmap_arg.addr_ptr, mmap_arg.size, 0, 1));
bo_gem->mem_virtual = (void *)(uintptr_t) mmap_arg.addr_ptr;
}
DBG("bo_map: %d (%s) -> %p\n", bo_gem->gem_handle, bo_gem->name,
bo_gem->mem_virtual);
bo->virtual = bo_gem->mem_virtual;
VG_CLEAR(set_domain);
set_domain.handle = bo_gem->gem_handle;
set_domain.read_domains = I915_GEM_DOMAIN_CPU;
if (write_enable)
set_domain.write_domain = I915_GEM_DOMAIN_CPU;
else
set_domain.write_domain = 0;
ret = drmIoctl(bufmgr_gem->fd,
DRM_IOCTL_I915_GEM_SET_DOMAIN,
&set_domain);
if (ret != 0) {
DBG("%s:%d: Error setting to CPU domain %d: %s\n",
__FILE__, __LINE__, bo_gem->gem_handle,
strerror(errno));
}
if (write_enable)
bo_gem->mapped_cpu_write = true;
drm_intel_gem_bo_mark_mmaps_incoherent(bo);
VG(VALGRIND_MAKE_MEM_DEFINED(bo_gem->mem_virtual, bo->size));
// pthread_mutex_unlock(&bufmgr_gem->lock);
return 0;
}
static int
map_gtt(drm_intel_bo *bo)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *) bo->bufmgr;
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
int ret;
if (bo_gem->map_count++ == 0)
drm_intel_gem_bo_open_vma(bufmgr_gem, bo_gem);
/* Get a mapping of the buffer if we haven't before. */
if (bo_gem->gtt_virtual == NULL) {
struct drm_i915_gem_mmap_gtt mmap_arg;
DBG("bo_map_gtt: mmap %d (%s), map_count=%d\n",
bo_gem->gem_handle, bo_gem->name, bo_gem->map_count);
VG_CLEAR(mmap_arg);
mmap_arg.handle = bo_gem->gem_handle;
mmap_arg.offset = 0;
/* Get the fake offset back... */
ret = drmIoctl(bufmgr_gem->fd,
DRM_IOCTL_I915_GEM_MMAP_GTT,
&mmap_arg);
if (ret != 0) {
ret = -errno;
DBG("%s:%d: Error preparing buffer map %d (%s): %s .\n",
__FILE__, __LINE__,
bo_gem->gem_handle, bo_gem->name,
strerror(errno));
if (--bo_gem->map_count == 0)
drm_intel_gem_bo_close_vma(bufmgr_gem, bo_gem);
return ret;
}
/* and mmap it */
bo_gem->gtt_virtual = mmap_arg.offset;
if (bo_gem->gtt_virtual == 0) {
bo_gem->gtt_virtual = NULL;
ret = -errno;
DBG("%s:%d: Error mapping buffer %d (%s): %s .\n",
__FILE__, __LINE__,
bo_gem->gem_handle, bo_gem->name,
strerror(errno));
if (--bo_gem->map_count == 0)
drm_intel_gem_bo_close_vma(bufmgr_gem, bo_gem);
return ret;
}
}
bo->virtual = bo_gem->gtt_virtual;
DBG("bo_map_gtt: %d (%s) -> %p\n", bo_gem->gem_handle, bo_gem->name,
bo_gem->gtt_virtual);
return 0;
}
int drm_intel_gem_bo_map_gtt(drm_intel_bo *bo)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *) bo->bufmgr;
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
struct drm_i915_gem_set_domain set_domain;
int ret;
// pthread_mutex_lock(&bufmgr_gem->lock);
ret = map_gtt(bo);
if (ret) {
// pthread_mutex_unlock(&bufmgr_gem->lock);
return ret;
}
/* Now move it to the GTT domain so that the GPU and CPU
* caches are flushed and the GPU isn't actively using the
* buffer.
*
* The pagefault handler does this domain change for us when
* it has unbound the BO from the GTT, but it's up to us to
* tell it when we're about to use things if we had done
* rendering and it still happens to be bound to the GTT.
*/
VG_CLEAR(set_domain);
set_domain.handle = bo_gem->gem_handle;
set_domain.read_domains = I915_GEM_DOMAIN_GTT;
set_domain.write_domain = I915_GEM_DOMAIN_GTT;
ret = drmIoctl(bufmgr_gem->fd,
DRM_IOCTL_I915_GEM_SET_DOMAIN,
&set_domain);
if (ret != 0) {
DBG("%s:%d: Error setting domain %d: %s\n",
__FILE__, __LINE__, bo_gem->gem_handle,
strerror(errno));
}
drm_intel_gem_bo_mark_mmaps_incoherent(bo);
VG(VALGRIND_MAKE_MEM_DEFINED(bo_gem->gtt_virtual, bo->size));
// pthread_mutex_unlock(&bufmgr_gem->lock);
return 0;
}
/**
* Performs a mapping of the buffer object like the normal GTT
* mapping, but avoids waiting for the GPU to be done reading from or
* rendering to the buffer.
*
* This is used in the implementation of GL_ARB_map_buffer_range: The
* user asks to create a buffer, then does a mapping, fills some
* space, runs a drawing command, then asks to map it again without
* synchronizing because it guarantees that it won't write over the
* data that the GPU is busy using (or, more specifically, that if it
* does write over the data, it acknowledges that rendering is
* undefined).
*/
int drm_intel_gem_bo_map_unsynchronized(drm_intel_bo *bo)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *) bo->bufmgr;
int ret;
/* If the CPU cache isn't coherent with the GTT, then use a
* regular synchronized mapping. The problem is that we don't
* track where the buffer was last used on the CPU side in
* terms of drm_intel_bo_map vs drm_intel_gem_bo_map_gtt, so
* we would potentially corrupt the buffer even when the user
* does reasonable things.
*/
if (!bufmgr_gem->has_llc)
return drm_intel_gem_bo_map_gtt(bo);
// pthread_mutex_lock(&bufmgr_gem->lock);
ret = map_gtt(bo);
// pthread_mutex_unlock(&bufmgr_gem->lock);
return ret;
}
static int drm_intel_gem_bo_unmap(drm_intel_bo *bo)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *) bo->bufmgr;
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
int ret = 0;
if (bo == NULL)
return 0;
// pthread_mutex_lock(&bufmgr_gem->lock);
if (bo_gem->map_count <= 0) {
DBG("attempted to unmap an unmapped bo\n");
// pthread_mutex_unlock(&bufmgr_gem->lock);
/* Preserve the old behaviour of just treating this as a
* no-op rather than reporting the error.
*/
return 0;
}
if (bo_gem->mapped_cpu_write) {
struct drm_i915_gem_sw_finish sw_finish;
/* Cause a flush to happen if the buffer's pinned for
* scanout, so the results show up in a timely manner.
* Unlike GTT set domains, this only does work if the
* buffer should be scanout-related.
*/
bo_gem->mapped_cpu_write = false;
}
/* We need to unmap after every innovation as we cannot track
* an open vma for every bo as that will exhaasut the system
* limits and cause later failures.
*/
if (--bo_gem->map_count == 0) {
drm_intel_gem_bo_close_vma(bufmgr_gem, bo_gem);
drm_intel_gem_bo_mark_mmaps_incoherent(bo);
bo->virtual = NULL;
}
// pthread_mutex_unlock(&bufmgr_gem->lock);
return ret;
}
int drm_intel_gem_bo_unmap_gtt(drm_intel_bo *bo)
{
return drm_intel_gem_bo_unmap(bo);
}
static int
drm_intel_gem_bo_subdata(drm_intel_bo *bo, unsigned long offset,
unsigned long size, const void *data)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *) bo->bufmgr;
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
struct drm_i915_gem_pwrite pwrite;
int ret;
VG_CLEAR(pwrite);
pwrite.handle = bo_gem->gem_handle;
pwrite.offset = offset;
pwrite.size = size;
pwrite.data_ptr = (uint64_t) (uintptr_t) data;
ret = drmIoctl(bufmgr_gem->fd,
DRM_IOCTL_I915_GEM_PWRITE,
&pwrite);
if (ret != 0) {
ret = -errno;
DBG("%s:%d: Error writing data to buffer %d: (%d %d) %s .\n",
__FILE__, __LINE__, bo_gem->gem_handle, (int)offset,
(int)size, strerror(errno));
}
return ret;
}
#if 0
static int
drm_intel_gem_get_pipe_from_crtc_id(drm_intel_bufmgr *bufmgr, int crtc_id)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *) bufmgr;
struct drm_i915_get_pipe_from_crtc_id get_pipe_from_crtc_id;
int ret;
VG_CLEAR(get_pipe_from_crtc_id);
get_pipe_from_crtc_id.crtc_id = crtc_id;
ret = drmIoctl(bufmgr_gem->fd,
DRM_IOCTL_I915_GET_PIPE_FROM_CRTC_ID,
&get_pipe_from_crtc_id);
if (ret != 0) {
/* We return -1 here to signal that we don't
* know which pipe is associated with this crtc.
* This lets the caller know that this information
* isn't available; using the wrong pipe for
* vblank waiting can cause the chipset to lock up
*/
return -1;
}
return get_pipe_from_crtc_id.pipe;
}
static int
drm_intel_gem_bo_get_subdata(drm_intel_bo *bo, unsigned long offset,
unsigned long size, void *data)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *) bo->bufmgr;
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
struct drm_i915_gem_pread pread;
int ret;
VG_CLEAR(pread);
pread.handle = bo_gem->gem_handle;
pread.offset = offset;
pread.size = size;
pread.data_ptr = (uint64_t) (uintptr_t) data;
ret = drmIoctl(bufmgr_gem->fd,
DRM_IOCTL_I915_GEM_PREAD,
&pread);
if (ret != 0) {
ret = -errno;
DBG("%s:%d: Error reading data from buffer %d: (%d %d) %s .\n",
__FILE__, __LINE__, bo_gem->gem_handle, (int)offset,
(int)size, strerror(errno));
}
return ret;
}
#endif
/** Waits for all GPU rendering with the object to have completed. */
static void
drm_intel_gem_bo_wait_rendering(drm_intel_bo *bo)
{
drm_intel_gem_bo_start_gtt_access(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 drm_intel_gem_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.
*/
int drm_intel_gem_bo_wait(drm_intel_bo *bo, int64_t timeout_ns)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *) bo->bufmgr;
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
struct drm_i915_gem_wait wait;
int ret;
if (!bufmgr_gem->has_wait_timeout) {
DBG("%s:%d: Timed wait is not supported. Falling back to "
"infinite wait\n", __FILE__, __LINE__);
if (timeout_ns) {
drm_intel_gem_bo_wait_rendering(bo);
return 0;
} else {
return drm_intel_gem_bo_busy(bo) ? -1 : 0;
}
}
wait.bo_handle = bo_gem->gem_handle;
wait.timeout_ns = timeout_ns;
wait.flags = 0;
ret = drmIoctl(bufmgr_gem->fd, DRM_IOCTL_I915_GEM_WAIT, &wait);
if (ret == -1)
return -errno;
return ret;
}
/**
* Sets the object to the GTT read and possibly write domain, used by the X
* 2D driver in the absence of kernel support to do drm_intel_gem_bo_map_gtt().
*
* In combination with drm_intel_gem_bo_pin() and manual fence management, we
* can do tiled pixmaps this way.
*/
void
drm_intel_gem_bo_start_gtt_access(drm_intel_bo *bo, int write_enable)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *) bo->bufmgr;
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
struct drm_i915_gem_set_domain set_domain;
int ret;
VG_CLEAR(set_domain);
set_domain.handle = bo_gem->gem_handle;
set_domain.read_domains = I915_GEM_DOMAIN_GTT;
set_domain.write_domain = write_enable ? I915_GEM_DOMAIN_GTT : 0;
ret = drmIoctl(bufmgr_gem->fd,
DRM_IOCTL_I915_GEM_SET_DOMAIN,
&set_domain);
if (ret != 0) {
DBG("%s:%d: Error setting memory domains %d (%08x %08x): %s .\n",
__FILE__, __LINE__, bo_gem->gem_handle,
set_domain.read_domains, set_domain.write_domain,
strerror(errno));
}
}
static void
drm_intel_bufmgr_gem_destroy(drm_intel_bufmgr *bufmgr)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *) bufmgr;
int i;
free(bufmgr_gem->exec2_objects);
free(bufmgr_gem->exec_objects);
free(bufmgr_gem->exec_bos);
free(bufmgr_gem->aub_filename);
// pthread_mutex_destroy(&bufmgr_gem->lock);
/* Free any cached buffer objects we were going to reuse */
for (i = 0; i < bufmgr_gem->num_buckets; i++) {
struct drm_intel_gem_bo_bucket *bucket =
&bufmgr_gem->cache_bucket[i];
drm_intel_bo_gem *bo_gem;
while (!DRMLISTEMPTY(&bucket->head)) {
bo_gem = DRMLISTENTRY(drm_intel_bo_gem,
bucket->head.next, head);
DRMLISTDEL(&bo_gem->head);
drm_intel_gem_bo_free(&bo_gem->bo);
}
}
free(bufmgr);
}
/**
* Adds the target buffer to the validation list and adds the relocation
* to the reloc_buffer's relocation list.
*
* The relocation entry at the given offset must already contain the
* precomputed relocation value, because the kernel will optimize out
* the relocation entry write when the buffer hasn't moved from the
* last known offset in target_bo.
*/
static int
do_bo_emit_reloc(drm_intel_bo *bo, uint32_t offset,
drm_intel_bo *target_bo, uint32_t target_offset,
uint32_t read_domains, uint32_t write_domain,
bool need_fence)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *) bo->bufmgr;
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
drm_intel_bo_gem *target_bo_gem = (drm_intel_bo_gem *) target_bo;
bool fenced_command;
if (bo_gem->has_error)
return -ENOMEM;
if (target_bo_gem->has_error) {
bo_gem->has_error = true;
return -ENOMEM;
}
/* We never use HW fences for rendering on 965+ */
if (bufmgr_gem->gen >= 4)
need_fence = false;
fenced_command = need_fence;
if (target_bo_gem->tiling_mode == I915_TILING_NONE)
need_fence = false;
/* Create a new relocation list if needed */
if (bo_gem->relocs == NULL && drm_intel_setup_reloc_list(bo))
return -ENOMEM;
/* Check overflow */
assert(bo_gem->reloc_count < bufmgr_gem->max_relocs);
/* Check args */
assert(offset <= bo->size - 4);
assert((write_domain & (write_domain - 1)) == 0);
/* Make sure that we're not adding a reloc to something whose size has
* already been accounted for.
*/
assert(!bo_gem->used_as_reloc_target);
if (target_bo_gem != bo_gem) {
target_bo_gem->used_as_reloc_target = true;
bo_gem->reloc_tree_size += target_bo_gem->reloc_tree_size;
}
/* An object needing a fence is a tiled buffer, so it won't have
* relocs to other buffers.
*/
if (need_fence)
target_bo_gem->reloc_tree_fences = 1;
bo_gem->reloc_tree_fences += target_bo_gem->reloc_tree_fences;
bo_gem->relocs[bo_gem->reloc_count].offset = offset;
bo_gem->relocs[bo_gem->reloc_count].delta = target_offset;
bo_gem->relocs[bo_gem->reloc_count].target_handle =
target_bo_gem->gem_handle;
bo_gem->relocs[bo_gem->reloc_count].read_domains = read_domains;
bo_gem->relocs[bo_gem->reloc_count].write_domain = write_domain;
bo_gem->relocs[bo_gem->reloc_count].presumed_offset = target_bo->offset;
bo_gem->reloc_target_info[bo_gem->reloc_count].bo = target_bo;
if (target_bo != bo)
drm_intel_gem_bo_reference(target_bo);
if (fenced_command)
bo_gem->reloc_target_info[bo_gem->reloc_count].flags =
DRM_INTEL_RELOC_FENCE;
else
bo_gem->reloc_target_info[bo_gem->reloc_count].flags = 0;
bo_gem->reloc_count++;
return 0;
}
static int
drm_intel_gem_bo_emit_reloc(drm_intel_bo *bo, uint32_t offset,
drm_intel_bo *target_bo, uint32_t target_offset,
uint32_t read_domains, uint32_t write_domain)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *)bo->bufmgr;
return do_bo_emit_reloc(bo, offset, target_bo, target_offset,
read_domains, write_domain,
!bufmgr_gem->fenced_relocs);
}
static int
drm_intel_gem_bo_emit_reloc_fence(drm_intel_bo *bo, uint32_t offset,
drm_intel_bo *target_bo,
uint32_t target_offset,
uint32_t read_domains, uint32_t write_domain)
{
return do_bo_emit_reloc(bo, offset, target_bo, target_offset,
read_domains, write_domain, true);
}
int
drm_intel_gem_bo_get_reloc_count(drm_intel_bo *bo)
{
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
return bo_gem->reloc_count;
}
/**
* Removes existing relocation entries in the BO after "start".
*
* This allows a user to avoid a two-step process for state setup with
* counting up all the buffer objects and doing a
* drm_intel_bufmgr_check_aperture_space() before emitting any of the
* relocations for the state setup. Instead, save the state of the
* batchbuffer including drm_intel_gem_get_reloc_count(), emit all the
* state, and then check if it still fits in the aperture.
*
* Any further drm_intel_bufmgr_check_aperture_space() queries
* involving this buffer in the tree are undefined after this call.
*/
void
drm_intel_gem_bo_clear_relocs(drm_intel_bo *bo, int start)
{
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
int i;
// struct timespec time;
// clock_gettime(CLOCK_MONOTONIC, &time);
assert(bo_gem->reloc_count >= start);
/* Unreference the cleared target buffers */
for (i = start; i < bo_gem->reloc_count; i++) {
drm_intel_bo_gem *target_bo_gem = (drm_intel_bo_gem *) bo_gem->reloc_target_info[i].bo;
if (&target_bo_gem->bo != bo) {
bo_gem->reloc_tree_fences -= target_bo_gem->reloc_tree_fences;
drm_intel_gem_bo_unreference_locked_timed(&target_bo_gem->bo,
0);
}
}
bo_gem->reloc_count = start;
}
/**
* Walk the tree of relocations rooted at BO and accumulate the list of
* validations to be performed and update the relocation buffers with
* index values into the validation list.
*/
static void
drm_intel_gem_bo_process_reloc(drm_intel_bo *bo)
{
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
int i;
if (bo_gem->relocs == NULL)
return;
for (i = 0; i < bo_gem->reloc_count; i++) {
drm_intel_bo *target_bo = bo_gem->reloc_target_info[i].bo;
if (target_bo == bo)
continue;
drm_intel_gem_bo_mark_mmaps_incoherent(bo);
/* Continue walking the tree depth-first. */
drm_intel_gem_bo_process_reloc(target_bo);
/* Add the target to the validate list */
drm_intel_add_validate_buffer(target_bo);
}
}
static void
drm_intel_gem_bo_process_reloc2(drm_intel_bo *bo)
{
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *)bo;
int i;
if (bo_gem->relocs == NULL)
return;
for (i = 0; i < bo_gem->reloc_count; i++) {
drm_intel_bo *target_bo = bo_gem->reloc_target_info[i].bo;
int need_fence;
if (target_bo == bo)
continue;
drm_intel_gem_bo_mark_mmaps_incoherent(bo);
/* Continue walking the tree depth-first. */
drm_intel_gem_bo_process_reloc2(target_bo);
need_fence = (bo_gem->reloc_target_info[i].flags &
DRM_INTEL_RELOC_FENCE);
/* Add the target to the validate list */
drm_intel_add_validate_buffer2(target_bo, need_fence);
}
}
static void
drm_intel_update_buffer_offsets(drm_intel_bufmgr_gem *bufmgr_gem)
{
int i;
for (i = 0; i < bufmgr_gem->exec_count; i++) {
drm_intel_bo *bo = bufmgr_gem->exec_bos[i];
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
/* Update the buffer offset */
if (bufmgr_gem->exec_objects[i].offset != bo->offset) {
DBG("BO %d (%s) migrated: 0x%08lx -> 0x%08llx\n",
bo_gem->gem_handle, bo_gem->name, bo->offset,
(unsigned long long)bufmgr_gem->exec_objects[i].
offset);
bo->offset = bufmgr_gem->exec_objects[i].offset;
}
}
}
static void
drm_intel_update_buffer_offsets2 (drm_intel_bufmgr_gem *bufmgr_gem)
{
int i;
for (i = 0; i < bufmgr_gem->exec_count; i++) {
drm_intel_bo *bo = bufmgr_gem->exec_bos[i];
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *)bo;
/* Update the buffer offset */
if (bufmgr_gem->exec2_objects[i].offset != bo->offset) {
DBG("BO %d (%s) migrated: 0x%08lx -> 0x%08llx\n",
bo_gem->gem_handle, bo_gem->name, bo->offset,
(unsigned long long)bufmgr_gem->exec2_objects[i].offset);
bo->offset = bufmgr_gem->exec2_objects[i].offset;
}
}
}
static void
aub_out(drm_intel_bufmgr_gem *bufmgr_gem, uint32_t data)
{
fwrite(&data, 1, 4, bufmgr_gem->aub_file);
}
static void
aub_out_data(drm_intel_bufmgr_gem *bufmgr_gem, void *data, size_t size)
{
fwrite(data, 1, size, bufmgr_gem->aub_file);
}
static void
aub_write_bo_data(drm_intel_bo *bo, uint32_t offset, uint32_t size)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *) bo->bufmgr;
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
uint32_t *data;
unsigned int i;
data = malloc(bo->size);
drm_intel_bo_get_subdata(bo, offset, size, data);
/* Easy mode: write out bo with no relocations */
if (!bo_gem->reloc_count) {
aub_out_data(bufmgr_gem, data, size);
free(data);
return;
}
/* Otherwise, handle the relocations while writing. */
for (i = 0; i < size / 4; i++) {
int r;
for (r = 0; r < bo_gem->reloc_count; r++) {
struct drm_i915_gem_relocation_entry *reloc;
drm_intel_reloc_target *info;
reloc = &bo_gem->relocs[r];
info = &bo_gem->reloc_target_info[r];
if (reloc->offset == offset + i * 4) {
drm_intel_bo_gem *target_gem;
uint32_t val;
target_gem = (drm_intel_bo_gem *)info->bo;
val = reloc->delta;
val += target_gem->aub_offset;
aub_out(bufmgr_gem, val);
data[i] = val;
break;
}
}
if (r == bo_gem->reloc_count) {
/* no relocation, just the data */
aub_out(bufmgr_gem, data[i]);
}
}
free(data);
}
static void
aub_bo_get_address(drm_intel_bo *bo)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *) bo->bufmgr;
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
/* Give the object a graphics address in the AUB file. We
* don't just use the GEM object address because we do AUB
* dumping before execution -- we want to successfully log
* when the hardware might hang, and we might even want to aub
* capture for a driver trying to execute on a different
* generation of hardware by disabling the actual kernel exec
* call.
*/
bo_gem->aub_offset = bufmgr_gem->aub_offset;
bufmgr_gem->aub_offset += bo->size;
/* XXX: Handle aperture overflow. */
assert(bufmgr_gem->aub_offset < 256 * 1024 * 1024);
}
static void
aub_write_trace_block(drm_intel_bo *bo, uint32_t type, uint32_t subtype,
uint32_t offset, uint32_t size)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *) bo->bufmgr;
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
aub_out(bufmgr_gem,
CMD_AUB_TRACE_HEADER_BLOCK |
((bufmgr_gem->gen >= 8 ? 6 : 5) - 2));
aub_out(bufmgr_gem,
AUB_TRACE_MEMTYPE_GTT | type | AUB_TRACE_OP_DATA_WRITE);
aub_out(bufmgr_gem, subtype);
aub_out(bufmgr_gem, bo_gem->aub_offset + offset);
aub_out(bufmgr_gem, size);
if (bufmgr_gem->gen >= 8)
aub_out(bufmgr_gem, 0);
aub_write_bo_data(bo, offset, size);
}
/**
* Break up large objects into multiple writes. Otherwise a 128kb VBO
* would overflow the 16 bits of size field in the packet header and
* everything goes badly after that.
*/
static void
aub_write_large_trace_block(drm_intel_bo *bo, uint32_t type, uint32_t subtype,
uint32_t offset, uint32_t size)
{
uint32_t block_size;
uint32_t sub_offset;
for (sub_offset = 0; sub_offset < size; sub_offset += block_size) {
block_size = size - sub_offset;
if (block_size > 8 * 4096)
block_size = 8 * 4096;
aub_write_trace_block(bo, type, subtype, offset + sub_offset,
block_size);
}
}
static void
aub_write_bo(drm_intel_bo *bo)
{
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
uint32_t offset = 0;
unsigned i;
aub_bo_get_address(bo);
/* Write out each annotated section separately. */
for (i = 0; i < bo_gem->aub_annotation_count; ++i) {
drm_intel_aub_annotation *annotation =
&bo_gem->aub_annotations[i];
uint32_t ending_offset = annotation->ending_offset;
if (ending_offset > bo->size)
ending_offset = bo->size;
if (ending_offset > offset) {
aub_write_large_trace_block(bo, annotation->type,
annotation->subtype,
offset,
ending_offset - offset);
offset = ending_offset;
}
}
/* Write out any remaining unannotated data */
if (offset < bo->size) {
aub_write_large_trace_block(bo, AUB_TRACE_TYPE_NOTYPE, 0,
offset, bo->size - offset);
}
}
/*
* Make a ringbuffer on fly and dump it
*/
static void
aub_build_dump_ringbuffer(drm_intel_bufmgr_gem *bufmgr_gem,
uint32_t batch_buffer, int ring_flag)
{
uint32_t ringbuffer[4096];
int ring = AUB_TRACE_TYPE_RING_PRB0; /* The default ring */
int ring_count = 0;
if (ring_flag == I915_EXEC_BSD)
ring = AUB_TRACE_TYPE_RING_PRB1;
else if (ring_flag == I915_EXEC_BLT)
ring = AUB_TRACE_TYPE_RING_PRB2;
/* Make a ring buffer to execute our batchbuffer. */
memset(ringbuffer, 0, sizeof(ringbuffer));
if (bufmgr_gem->gen >= 8) {
ringbuffer[ring_count++] = AUB_MI_BATCH_BUFFER_START | (3 - 2);
ringbuffer[ring_count++] = batch_buffer;
ringbuffer[ring_count++] = 0;
} else {
ringbuffer[ring_count++] = AUB_MI_BATCH_BUFFER_START;
ringbuffer[ring_count++] = batch_buffer;
}
/* Write out the ring. This appears to trigger execution of
* the ring in the simulator.
*/
aub_out(bufmgr_gem,
CMD_AUB_TRACE_HEADER_BLOCK |
((bufmgr_gem->gen >= 8 ? 6 : 5) - 2));
aub_out(bufmgr_gem,
AUB_TRACE_MEMTYPE_GTT | ring | AUB_TRACE_OP_COMMAND_WRITE);
aub_out(bufmgr_gem, 0); /* general/surface subtype */
aub_out(bufmgr_gem, bufmgr_gem->aub_offset);
aub_out(bufmgr_gem, ring_count * 4);
if (bufmgr_gem->gen >= 8)
aub_out(bufmgr_gem, 0);
/* FIXME: Need some flush operations here? */
aub_out_data(bufmgr_gem, ringbuffer, ring_count * 4);
/* Update offset pointer */
bufmgr_gem->aub_offset += 4096;
}
void
drm_intel_gem_bo_aub_dump_bmp(drm_intel_bo *bo,
int x1, int y1, int width, int height,
enum aub_dump_bmp_format format,
int pitch, int offset)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *) bo->bufmgr;
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *)bo;
uint32_t cpp;
switch (format) {
case AUB_DUMP_BMP_FORMAT_8BIT:
cpp = 1;
break;
case AUB_DUMP_BMP_FORMAT_ARGB_4444:
cpp = 2;
break;
case AUB_DUMP_BMP_FORMAT_ARGB_0888:
case AUB_DUMP_BMP_FORMAT_ARGB_8888:
cpp = 4;
break;
default:
printf("Unknown AUB dump format %d\n", format);
return;
}
if (!bufmgr_gem->aub_file)
return;
aub_out(bufmgr_gem, CMD_AUB_DUMP_BMP | 4);
aub_out(bufmgr_gem, (y1 << 16) | x1);
aub_out(bufmgr_gem,
(format << 24) |
(cpp << 19) |
pitch / 4);
aub_out(bufmgr_gem, (height << 16) | width);
aub_out(bufmgr_gem, bo_gem->aub_offset + offset);
aub_out(bufmgr_gem,
((bo_gem->tiling_mode != I915_TILING_NONE) ? (1 << 2) : 0) |
((bo_gem->tiling_mode == I915_TILING_Y) ? (1 << 3) : 0));
}
static void
aub_exec(drm_intel_bo *bo, int ring_flag, int used)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *) bo->bufmgr;
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
int i;
bool batch_buffer_needs_annotations;
if (!bufmgr_gem->aub_file)
return;
/* If batch buffer is not annotated, annotate it the best we
* can.
*/
batch_buffer_needs_annotations = bo_gem->aub_annotation_count == 0;
if (batch_buffer_needs_annotations) {
drm_intel_aub_annotation annotations[2] = {
{ AUB_TRACE_TYPE_BATCH, 0, used },
{ AUB_TRACE_TYPE_NOTYPE, 0, bo->size }
};
drm_intel_bufmgr_gem_set_aub_annotations(bo, annotations, 2);
}
/* Write out all buffers to AUB memory */
for (i = 0; i < bufmgr_gem->exec_count; i++) {
aub_write_bo(bufmgr_gem->exec_bos[i]);
}
/* Remove any annotations we added */
if (batch_buffer_needs_annotations)
drm_intel_bufmgr_gem_set_aub_annotations(bo, NULL, 0);
/* Dump ring buffer */
aub_build_dump_ringbuffer(bufmgr_gem, bo_gem->aub_offset, ring_flag);
fflush(bufmgr_gem->aub_file);
/*
* One frame has been dumped. So reset the aub_offset for the next frame.
*
* FIXME: Can we do this?
*/
bufmgr_gem->aub_offset = 0x10000;
}
static int
do_exec2(drm_intel_bo *bo, int used, drm_intel_context *ctx,
drm_clip_rect_t *cliprects, int num_cliprects, int DR4,
unsigned int flags)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *)bo->bufmgr;
struct drm_i915_gem_execbuffer2 execbuf;
int ret = 0;
int i;
switch (flags & 0x7) {
default:
return -EINVAL;
case I915_EXEC_BLT:
if (!bufmgr_gem->has_blt)
return -EINVAL;
break;
case I915_EXEC_BSD:
if (!bufmgr_gem->has_bsd)
return -EINVAL;
break;
case I915_EXEC_VEBOX:
if (!bufmgr_gem->has_vebox)
return -EINVAL;
break;
case I915_EXEC_RENDER:
case I915_EXEC_DEFAULT:
break;
}
// pthread_mutex_lock(&bufmgr_gem->lock);
/* Update indices and set up the validate list. */
drm_intel_gem_bo_process_reloc2(bo);
/* Add the batch buffer to the validation list. There are no relocations
* pointing to it.
*/
drm_intel_add_validate_buffer2(bo, 0);
VG_CLEAR(execbuf);
execbuf.buffers_ptr = (uintptr_t)bufmgr_gem->exec2_objects;
execbuf.buffer_count = bufmgr_gem->exec_count;
execbuf.batch_start_offset = 0;
execbuf.batch_len = used;
execbuf.cliprects_ptr = (uintptr_t)cliprects;
execbuf.num_cliprects = num_cliprects;
execbuf.DR1 = 0;
execbuf.DR4 = DR4;
execbuf.flags = flags;
if (ctx == NULL)
i915_execbuffer2_set_context_id(execbuf, 0);
else
i915_execbuffer2_set_context_id(execbuf, ctx->ctx_id);
execbuf.rsvd2 = 0;
aub_exec(bo, flags, used);
if (bufmgr_gem->no_exec)
goto skip_execution;
ret = drmIoctl(bufmgr_gem->fd,
DRM_IOCTL_I915_GEM_EXECBUFFER2,
&execbuf);
if (ret != 0) {
ret = -errno;
if (ret == -ENOSPC) {
DBG("Execbuffer fails to pin. "
"Estimate: %u. Actual: %u. Available: %u\n",
drm_intel_gem_estimate_batch_space(bufmgr_gem->exec_bos,
bufmgr_gem->exec_count),
drm_intel_gem_compute_batch_space(bufmgr_gem->exec_bos,
bufmgr_gem->exec_count),
(unsigned int) bufmgr_gem->gtt_size);
}
}
drm_intel_update_buffer_offsets2(bufmgr_gem);
skip_execution:
if (bufmgr_gem->bufmgr.debug)
drm_intel_gem_dump_validation_list(bufmgr_gem);
for (i = 0; i < bufmgr_gem->exec_count; i++) {
drm_intel_bo *bo = bufmgr_gem->exec_bos[i];
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *)bo;
/* Disconnect the buffer from the validate list */
bo_gem->validate_index = -1;
bufmgr_gem->exec_bos[i] = NULL;
}
bufmgr_gem->exec_count = 0;
// pthread_mutex_unlock(&bufmgr_gem->lock);
return ret;
}
static int
drm_intel_gem_bo_exec2(drm_intel_bo *bo, int used,
drm_clip_rect_t *cliprects, int num_cliprects,
int DR4)
{
return do_exec2(bo, used, NULL, cliprects, num_cliprects, DR4,
I915_EXEC_RENDER);
}
static int
drm_intel_gem_bo_mrb_exec2(drm_intel_bo *bo, int used,
drm_clip_rect_t *cliprects, int num_cliprects, int DR4,
unsigned int flags)
{
return do_exec2(bo, used, NULL, cliprects, num_cliprects, DR4,
flags);
}
int
drm_intel_gem_bo_context_exec(drm_intel_bo *bo, drm_intel_context *ctx,
int used, unsigned int flags)
{
return do_exec2(bo, used, ctx, NULL, 0, 0, flags);
}
static int
drm_intel_gem_bo_pin(drm_intel_bo *bo, uint32_t alignment)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *) bo->bufmgr;
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
struct drm_i915_gem_pin pin;
int ret;
VG_CLEAR(pin);
pin.handle = bo_gem->gem_handle;
pin.alignment = alignment;
ret = drmIoctl(bufmgr_gem->fd,
DRM_IOCTL_I915_GEM_PIN,
&pin);
if (ret != 0)
return -errno;
bo->offset = pin.offset;
return 0;
}
static int
drm_intel_gem_bo_unpin(drm_intel_bo *bo)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *) bo->bufmgr;
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
struct drm_i915_gem_unpin unpin;
int ret;
VG_CLEAR(unpin);
unpin.handle = bo_gem->gem_handle;
ret = drmIoctl(bufmgr_gem->fd, DRM_IOCTL_I915_GEM_UNPIN, &unpin);
if (ret != 0)
return -errno;
return 0;
}
static int
drm_intel_gem_bo_set_tiling_internal(drm_intel_bo *bo,
uint32_t tiling_mode,
uint32_t stride)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *) bo->bufmgr;
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
struct drm_i915_gem_set_tiling set_tiling;
int ret;
if (bo_gem->global_name == 0 &&
tiling_mode == bo_gem->tiling_mode &&
stride == bo_gem->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
* rmIoctl.
*/
set_tiling.handle = bo_gem->gem_handle;
set_tiling.tiling_mode = tiling_mode;
set_tiling.stride = stride;
ret = drmIoctl(bufmgr_gem->fd,
DRM_IOCTL_I915_GEM_SET_TILING,
&set_tiling);
// } while (ret == -1 && (errno == EINTR || errno == EAGAIN));
if (ret == -1)
return -errno;
bo_gem->tiling_mode = set_tiling.tiling_mode;
bo_gem->swizzle_mode = set_tiling.swizzle_mode;
bo_gem->stride = set_tiling.stride;
return 0;
}
static int
drm_intel_gem_bo_set_tiling(drm_intel_bo *bo, uint32_t * tiling_mode,
uint32_t stride)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *) bo->bufmgr;
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
int ret;
/* Linear buffers have no stride. By ensuring that we only ever use
* stride 0 with linear buffers, we simplify our code.
*/
if (*tiling_mode == I915_TILING_NONE)
stride = 0;
ret = drm_intel_gem_bo_set_tiling_internal(bo, *tiling_mode, stride);
if (ret == 0)
drm_intel_bo_gem_set_in_aperture_size(bufmgr_gem, bo_gem);
*tiling_mode = bo_gem->tiling_mode;
return ret;
}
static int
drm_intel_gem_bo_get_tiling(drm_intel_bo *bo, uint32_t * tiling_mode,
uint32_t * swizzle_mode)
{
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
*tiling_mode = bo_gem->tiling_mode;
*swizzle_mode = bo_gem->swizzle_mode;
return 0;
}
#if 0
drm_intel_bo *
drm_intel_bo_gem_create_from_prime(drm_intel_bufmgr *bufmgr, int prime_fd, int size)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *) bufmgr;
int ret;
uint32_t handle;
drm_intel_bo_gem *bo_gem;
struct drm_i915_gem_get_tiling get_tiling;
drmMMListHead *list;
ret = drmPrimeFDToHandle(bufmgr_gem->fd, prime_fd, &handle);
/*
* 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
*/
for (list = bufmgr_gem->named.next;
list != &bufmgr_gem->named;
list = list->next) {
bo_gem = DRMLISTENTRY(drm_intel_bo_gem, list, name_list);
if (bo_gem->gem_handle == handle) {
drm_intel_gem_bo_reference(&bo_gem->bo);
return &bo_gem->bo;
}
}
if (ret) {
fprintf(stderr,"ret is %d %d\n", ret, errno);
return NULL;
}
bo_gem = calloc(1, sizeof(*bo_gem));
if (!bo_gem)
return NULL;
/* 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_gem->bo.size = ret;
else
bo_gem->bo.size = size;
bo_gem->bo.handle = handle;
bo_gem->bo.bufmgr = bufmgr;
bo_gem->gem_handle = handle;
atomic_set(&bo_gem->refcount, 1);
bo_gem->name = "prime";
bo_gem->validate_index = -1;
bo_gem->reloc_tree_fences = 0;
bo_gem->used_as_reloc_target = false;
bo_gem->has_error = false;
bo_gem->reusable = false;
DRMINITLISTHEAD(&bo_gem->vma_list);
DRMLISTADDTAIL(&bo_gem->name_list, &bufmgr_gem->named);
VG_CLEAR(get_tiling);
get_tiling.handle = bo_gem->gem_handle;
ret = drmIoctl(bufmgr_gem->fd,
DRM_IOCTL_I915_GEM_GET_TILING,
&get_tiling);
if (ret != 0) {
drm_intel_gem_bo_unreference(&bo_gem->bo);
return NULL;
}
bo_gem->tiling_mode = get_tiling.tiling_mode;
bo_gem->swizzle_mode = get_tiling.swizzle_mode;
/* XXX stride is unknown */
drm_intel_bo_gem_set_in_aperture_size(bufmgr_gem, bo_gem);
return &bo_gem->bo;
}
int
drm_intel_bo_gem_export_to_prime(drm_intel_bo *bo, int *prime_fd)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *) bo->bufmgr;
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
if (DRMLISTEMPTY(&bo_gem->name_list))
DRMLISTADDTAIL(&bo_gem->name_list, &bufmgr_gem->named);
if (drmPrimeHandleToFD(bufmgr_gem->fd, bo_gem->gem_handle,
DRM_CLOEXEC, prime_fd) != 0)
return -errno;
bo_gem->reusable = false;
return 0;
}
#endif
static int
drm_intel_gem_bo_flink(drm_intel_bo *bo, uint32_t * name)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *) bo->bufmgr;
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
int ret;
if (!bo_gem->global_name) {
struct drm_gem_flink flink;
VG_CLEAR(flink);
flink.handle = bo_gem->gem_handle;
ret = drmIoctl(bufmgr_gem->fd, DRM_IOCTL_GEM_FLINK, &flink);
if (ret != 0)
return -errno;
bo_gem->global_name = flink.name;
bo_gem->reusable = false;
DRMLISTADDTAIL(&bo_gem->name_list, &bufmgr_gem->named);
}
*name = bo_gem->global_name;
return 0;
}
/**
* Enables unlimited caching of buffer objects for reuse.
*
* This is potentially very memory expensive, as the cache at each bucket
* size is only bounded by how many buffers of that size we've managed to have
* in flight at once.
*/
void
drm_intel_bufmgr_gem_enable_reuse(drm_intel_bufmgr *bufmgr)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *) bufmgr;
bufmgr_gem->bo_reuse = true;
}
/**
* Enable use of fenced reloc type.
*
* New code should enable this to avoid unnecessary fence register
* allocation. If this option is not enabled, all relocs will have fence
* register allocated.
*/
void
drm_intel_bufmgr_gem_enable_fenced_relocs(drm_intel_bufmgr *bufmgr)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *)bufmgr;
if (bufmgr_gem->bufmgr.bo_exec == drm_intel_gem_bo_exec2)
bufmgr_gem->fenced_relocs = true;
}
/**
* Return the additional aperture space required by the tree of buffer objects
* rooted at bo.
*/
static int
drm_intel_gem_bo_get_aperture_space(drm_intel_bo *bo)
{
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
int i;
int total = 0;
if (bo == NULL || bo_gem->included_in_check_aperture)
return 0;
total += bo->size;
bo_gem->included_in_check_aperture = true;
for (i = 0; i < bo_gem->reloc_count; i++)
total +=
drm_intel_gem_bo_get_aperture_space(bo_gem->
reloc_target_info[i].bo);
return total;
}
/**
* Count the number of buffers in this list that need a fence reg
*
* If the count is greater than the number of available regs, we'll have
* to ask the caller to resubmit a batch with fewer tiled buffers.
*
* This function over-counts if the same buffer is used multiple times.
*/
static unsigned int
drm_intel_gem_total_fences(drm_intel_bo ** bo_array, int count)
{
int i;
unsigned int total = 0;
for (i = 0; i < count; i++) {
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo_array[i];
if (bo_gem == NULL)
continue;
total += bo_gem->reloc_tree_fences;
}
return total;
}
/**
* Clear the flag set by drm_intel_gem_bo_get_aperture_space() so we're ready
* for the next drm_intel_bufmgr_check_aperture_space() call.
*/
static void
drm_intel_gem_bo_clear_aperture_space_flag(drm_intel_bo *bo)
{
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
int i;
if (bo == NULL || !bo_gem->included_in_check_aperture)
return;
bo_gem->included_in_check_aperture = false;
for (i = 0; i < bo_gem->reloc_count; i++)
drm_intel_gem_bo_clear_aperture_space_flag(bo_gem->
reloc_target_info[i].bo);
}
/**
* Return a conservative estimate for the amount of aperture required
* for a collection of buffers. This may double-count some buffers.
*/
static unsigned int
drm_intel_gem_estimate_batch_space(drm_intel_bo **bo_array, int count)
{
int i;
unsigned int total = 0;
for (i = 0; i < count; i++) {
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo_array[i];
if (bo_gem != NULL)
total += bo_gem->reloc_tree_size;
}
return total;
}
/**
* Return the amount of aperture needed for a collection of buffers.
* This avoids double counting any buffers, at the cost of looking
* at every buffer in the set.
*/
static unsigned int
drm_intel_gem_compute_batch_space(drm_intel_bo **bo_array, int count)
{
int i;
unsigned int total = 0;
for (i = 0; i < count; i++) {
total += drm_intel_gem_bo_get_aperture_space(bo_array[i]);
/* For the first buffer object in the array, we get an
* accurate count back for its reloc_tree size (since nothing
* had been flagged as being counted yet). We can save that
* value out as a more conservative reloc_tree_size that
* avoids double-counting target buffers. Since the first
* buffer happens to usually be the batch buffer in our
* callers, this can pull us back from doing the tree
* walk on every new batch emit.
*/
if (i == 0) {
drm_intel_bo_gem *bo_gem =
(drm_intel_bo_gem *) bo_array[i];
bo_gem->reloc_tree_size = total;
}
}
for (i = 0; i < count; i++)
drm_intel_gem_bo_clear_aperture_space_flag(bo_array[i]);
return total;
}
/**
* Return -1 if the batchbuffer should be flushed before attempting to
* emit rendering referencing the buffers pointed to by bo_array.
*
* This is required because if we try to emit a batchbuffer with relocations
* to a tree of buffers that won't simultaneously fit in the aperture,
* the rendering will return an error at a point where the software is not
* prepared to recover from it.
*
* However, we also want to emit the batchbuffer significantly before we reach
* the limit, as a series of batchbuffers each of which references buffers
* covering almost all of the aperture means that at each emit we end up
* waiting to evict a buffer from the last rendering, and we get synchronous
* performance. By emitting smaller batchbuffers, we eat some CPU overhead to
* get better parallelism.
*/
static int
drm_intel_gem_check_aperture_space(drm_intel_bo **bo_array, int count)
{
drm_intel_bufmgr_gem *bufmgr_gem =
(drm_intel_bufmgr_gem *) bo_array[0]->bufmgr;
unsigned int total = 0;
unsigned int threshold = bufmgr_gem->gtt_size * 3 / 4;
int total_fences;
/* Check for fence reg constraints if necessary */
if (bufmgr_gem->available_fences) {
total_fences = drm_intel_gem_total_fences(bo_array, count);
if (total_fences > bufmgr_gem->available_fences)
return -ENOSPC;
}
total = drm_intel_gem_estimate_batch_space(bo_array, count);
if (total > threshold)
total = drm_intel_gem_compute_batch_space(bo_array, count);
if (total > threshold) {
DBG("check_space: overflowed available aperture, "
"%dkb vs %dkb\n",
total / 1024, (int)bufmgr_gem->gtt_size / 1024);
return -ENOSPC;
} else {
DBG("drm_check_space: total %dkb vs bufgr %dkb\n", total / 1024,
(int)bufmgr_gem->gtt_size / 1024);
return 0;
}
}
/*
* Disable buffer reuse for objects which are shared with the kernel
* as scanout buffers
*/
static int
drm_intel_gem_bo_disable_reuse(drm_intel_bo *bo)
{
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
bo_gem->reusable = false;
return 0;
}
static int
drm_intel_gem_bo_is_reusable(drm_intel_bo *bo)
{
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
return bo_gem->reusable;
}
static int
_drm_intel_gem_bo_references(drm_intel_bo *bo, drm_intel_bo *target_bo)
{
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
int i;
for (i = 0; i < bo_gem->reloc_count; i++) {
if (bo_gem->reloc_target_info[i].bo == target_bo)
return 1;
if (bo == bo_gem->reloc_target_info[i].bo)
continue;
if (_drm_intel_gem_bo_references(bo_gem->reloc_target_info[i].bo,
target_bo))
return 1;
}
return 0;
}
/** Return true if target_bo is referenced by bo's relocation tree. */
static int
drm_intel_gem_bo_references(drm_intel_bo *bo, drm_intel_bo *target_bo)
{
drm_intel_bo_gem *target_bo_gem = (drm_intel_bo_gem *) target_bo;
if (bo == NULL || target_bo == NULL)
return 0;
if (target_bo_gem->used_as_reloc_target)
return _drm_intel_gem_bo_references(bo, target_bo);
return 0;
}
static void
add_bucket(drm_intel_bufmgr_gem *bufmgr_gem, int size)
{
unsigned int i = bufmgr_gem->num_buckets;
assert(i < ARRAY_SIZE(bufmgr_gem->cache_bucket));
DRMINITLISTHEAD(&bufmgr_gem->cache_bucket[i].head);
bufmgr_gem->cache_bucket[i].size = size;
bufmgr_gem->num_buckets++;
}
static void
init_cache_buckets(drm_intel_bufmgr_gem *bufmgr_gem)
{
unsigned long 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_gem, 4096);
add_bucket(bufmgr_gem, 4096 * 2);
add_bucket(bufmgr_gem, 4096 * 3);
/* Initialize the linked lists for BO reuse cache. */
for (size = 4 * 4096; size <= cache_max_size; size *= 2) {
add_bucket(bufmgr_gem, size);
add_bucket(bufmgr_gem, size + size * 1 / 4);
add_bucket(bufmgr_gem, size + size * 2 / 4);
add_bucket(bufmgr_gem, size + size * 3 / 4);
}
}
void
drm_intel_bufmgr_gem_set_vma_cache_size(drm_intel_bufmgr *bufmgr, int limit)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *)bufmgr;
bufmgr_gem->vma_max = limit;
drm_intel_gem_bo_purge_vma_cache(bufmgr_gem);
}
/**
* Get the PCI ID for the device. This can be overridden by setting the
* INTEL_DEVID_OVERRIDE environment variable to the desired ID.
*/
static int
get_pci_device_id(drm_intel_bufmgr_gem *bufmgr_gem)
{
char *devid_override;
int devid;
int ret;
drm_i915_getparam_t gp;
VG_CLEAR(devid);
VG_CLEAR(gp);
gp.param = I915_PARAM_CHIPSET_ID;
gp.value = &devid;
ret = drmIoctl(bufmgr_gem->fd, DRM_IOCTL_I915_GETPARAM, &gp);
if (ret) {
fprintf(stderr, "get chip id failed: %d [%d]\n", ret, errno);
fprintf(stderr, "param: %d, val: %d\n", gp.param, *gp.value);
}
return devid;
}
int
drm_intel_bufmgr_gem_get_devid(drm_intel_bufmgr *bufmgr)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *)bufmgr;
return bufmgr_gem->pci_device;
}
/**
* Sets up AUB dumping.
*
* This is a trace file format that can be used with the simulator.
* Packets are emitted in a format somewhat like GPU command packets.
* You can set up a GTT and upload your objects into the referenced
* space, then send off batchbuffers and get BMPs out the other end.
*/
void
drm_intel_bufmgr_gem_set_aub_dump(drm_intel_bufmgr *bufmgr, int enable)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *)bufmgr;
int entry = 0x200003;
int i;
int gtt_size = 0x10000;
const char *filename;
if (!enable) {
if (bufmgr_gem->aub_file) {
fclose(bufmgr_gem->aub_file);
bufmgr_gem->aub_file = NULL;
}
return;
}
bufmgr_gem->aub_file = fopen("intel.aub", "w+");
if (!bufmgr_gem->aub_file)
return;
/* Start allocating objects from just after the GTT. */
bufmgr_gem->aub_offset = gtt_size;
/* Start with a (required) version packet. */
aub_out(bufmgr_gem, CMD_AUB_HEADER | (13 - 2));
aub_out(bufmgr_gem,
(4 << AUB_HEADER_MAJOR_SHIFT) |
(0 << AUB_HEADER_MINOR_SHIFT));
for (i = 0; i < 8; i++) {
aub_out(bufmgr_gem, 0); /* app name */
}
aub_out(bufmgr_gem, 0); /* timestamp */
aub_out(bufmgr_gem, 0); /* timestamp */
aub_out(bufmgr_gem, 0); /* comment len */
/* Set up the GTT. The max we can handle is 256M */
aub_out(bufmgr_gem, CMD_AUB_TRACE_HEADER_BLOCK | (5 - 2));
aub_out(bufmgr_gem, AUB_TRACE_MEMTYPE_NONLOCAL | 0 | AUB_TRACE_OP_DATA_WRITE);
aub_out(bufmgr_gem, 0); /* subtype */
aub_out(bufmgr_gem, 0); /* offset */
aub_out(bufmgr_gem, gtt_size); /* size */
for (i = 0x000; i < gtt_size; i += 4, entry += 0x1000) {
aub_out(bufmgr_gem, entry);
}
}
drm_intel_context *
drm_intel_gem_context_create(drm_intel_bufmgr *bufmgr)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *)bufmgr;
struct drm_i915_gem_context_create create;
drm_intel_context *context = NULL;
int ret;
VG_CLEAR(create);
ret = drmIoctl(bufmgr_gem->fd, DRM_IOCTL_I915_GEM_CONTEXT_CREATE, &create);
if (ret != 0) {
DBG("DRM_IOCTL_I915_GEM_CONTEXT_CREATE failed: %s\n",
strerror(errno));
return NULL;
}
context = calloc(1, sizeof(*context));
context->ctx_id = create.ctx_id;
context->bufmgr = bufmgr;
return context;
}
void
drm_intel_gem_context_destroy(drm_intel_context *ctx)
{
drm_intel_bufmgr_gem *bufmgr_gem;
struct drm_i915_gem_context_destroy destroy;
int ret;
if (ctx == NULL)
return;
VG_CLEAR(destroy);
bufmgr_gem = (drm_intel_bufmgr_gem *)ctx->bufmgr;
destroy.ctx_id = ctx->ctx_id;
ret = drmIoctl(bufmgr_gem->fd, DRM_IOCTL_I915_GEM_CONTEXT_DESTROY,
&destroy);
if (ret != 0)
fprintf(stderr, "DRM_IOCTL_I915_GEM_CONTEXT_DESTROY failed: %s\n",
strerror(errno));
free(ctx);
}
int
drm_intel_reg_read(drm_intel_bufmgr *bufmgr,
uint32_t offset,
uint64_t *result)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *)bufmgr;
struct drm_i915_reg_read reg_read;
int ret;
VG_CLEAR(reg_read);
reg_read.offset = offset;
ret = drmIoctl(bufmgr_gem->fd, DRM_IOCTL_I915_REG_READ, &reg_read);
*result = reg_read.val;
return ret;
}
/**
* Annotate the given bo for use in aub dumping.
*
* \param annotations is an array of drm_intel_aub_annotation objects
* describing the type of data in various sections of the bo. Each
* element of the array specifies the type and subtype of a section of
* the bo, and the past-the-end offset of that section. The elements
* of \c annotations must be sorted so that ending_offset is
* increasing.
*
* \param count is the number of elements in the \c annotations array.
* If \c count is zero, then \c annotations will not be dereferenced.
*
* Annotations are copied into a private data structure, so caller may
* re-use the memory pointed to by \c annotations after the call
* returns.
*
* Annotations are stored for the lifetime of the bo; to reset to the
* default state (no annotations), call this function with a \c count
* of zero.
*/
void
drm_intel_bufmgr_gem_set_aub_annotations(drm_intel_bo *bo,
drm_intel_aub_annotation *annotations,
unsigned count)
{
drm_intel_bo_gem *bo_gem = (drm_intel_bo_gem *) bo;
unsigned size = sizeof(*annotations) * count;
drm_intel_aub_annotation *new_annotations =
count > 0 ? realloc(bo_gem->aub_annotations, size) : NULL;
if (new_annotations == NULL) {
free(bo_gem->aub_annotations);
bo_gem->aub_annotations = NULL;
bo_gem->aub_annotation_count = 0;
return;
}
memcpy(new_annotations, annotations, size);
bo_gem->aub_annotations = new_annotations;
bo_gem->aub_annotation_count = count;
}
/**
* 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.
*/
drm_intel_bufmgr *
drm_intel_bufmgr_gem_init(int fd, int batch_size)
{
drm_intel_bufmgr_gem *bufmgr_gem;
struct drm_i915_gem_get_aperture aperture;
drm_i915_getparam_t gp;
int ret, tmp;
bool exec2 = false;
bufmgr_gem = calloc(1, sizeof(*bufmgr_gem));
if (bufmgr_gem == NULL)
return NULL;
bufmgr_gem->fd = fd;
// if (pthread_mutex_init(&bufmgr_gem->lock, NULL) != 0) {
// free(bufmgr_gem);
// return NULL;
// }
ret = drmIoctl(bufmgr_gem->fd,
DRM_IOCTL_I915_GEM_GET_APERTURE,
&aperture);
if (ret == 0)
bufmgr_gem->gtt_size = aperture.aper_available_size;
else {
printf("DRM_IOCTL_I915_GEM_APERTURE failed: %s\n",
strerror(errno));
bufmgr_gem->gtt_size = 128 * 1024 * 1024;
printf("Assuming %dkB available aperture size.\n"
"May lead to reduced performance or incorrect "
"rendering.\n",
(int)bufmgr_gem->gtt_size / 1024);
}
bufmgr_gem->pci_device = get_pci_device_id(bufmgr_gem);
if (IS_GEN2(bufmgr_gem->pci_device))
bufmgr_gem->gen = 2;
else if (IS_GEN3(bufmgr_gem->pci_device))
bufmgr_gem->gen = 3;
else if (IS_GEN4(bufmgr_gem->pci_device))
bufmgr_gem->gen = 4;
else if (IS_GEN5(bufmgr_gem->pci_device))
bufmgr_gem->gen = 5;
else if (IS_GEN6(bufmgr_gem->pci_device))
bufmgr_gem->gen = 6;
else if (IS_GEN7(bufmgr_gem->pci_device))
bufmgr_gem->gen = 7;
else {
free(bufmgr_gem);
return NULL;
}
// printf("gen %d\n", bufmgr_gem->gen);
if (IS_GEN3(bufmgr_gem->pci_device) &&
bufmgr_gem->gtt_size > 256*1024*1024) {
/* The unmappable part of gtt on gen 3 (i.e. above 256MB) can't
* be used for tiled blits. To simplify the accounting, just
* substract the unmappable part (fixed to 256MB on all known
* gen3 devices) if the kernel advertises it. */
bufmgr_gem->gtt_size -= 256*1024*1024;
}
VG_CLEAR(gp);
gp.value = &tmp;
gp.param = I915_PARAM_HAS_EXECBUF2;
ret = drmIoctl(bufmgr_gem->fd, DRM_IOCTL_I915_GETPARAM, &gp);
if (!ret)
exec2 = true;
gp.param = I915_PARAM_HAS_BSD;
ret = drmIoctl(bufmgr_gem->fd, DRM_IOCTL_I915_GETPARAM, &gp);
bufmgr_gem->has_bsd = ret == 0;
gp.param = I915_PARAM_HAS_BLT;
ret = drmIoctl(bufmgr_gem->fd, DRM_IOCTL_I915_GETPARAM, &gp);
bufmgr_gem->has_blt = ret == 0;
gp.param = I915_PARAM_HAS_RELAXED_FENCING;
ret = drmIoctl(bufmgr_gem->fd, DRM_IOCTL_I915_GETPARAM, &gp);
bufmgr_gem->has_relaxed_fencing = ret == 0;
gp.param = I915_PARAM_HAS_WAIT_TIMEOUT;
ret = drmIoctl(bufmgr_gem->fd, DRM_IOCTL_I915_GETPARAM, &gp);
bufmgr_gem->has_wait_timeout = ret == 0;
gp.param = I915_PARAM_HAS_LLC;
ret = drmIoctl(bufmgr_gem->fd, DRM_IOCTL_I915_GETPARAM, &gp);
if (ret != 0) {
/* Kernel does not supports HAS_LLC query, fallback to GPU
* generation detection and assume that we have LLC on GEN6/7
*/
bufmgr_gem->has_llc = (IS_GEN6(bufmgr_gem->pci_device) |
IS_GEN7(bufmgr_gem->pci_device));
} else
bufmgr_gem->has_llc = *gp.value;
gp.param = I915_PARAM_HAS_VEBOX;
ret = drmIoctl(bufmgr_gem->fd, DRM_IOCTL_I915_GETPARAM, &gp);
bufmgr_gem->has_vebox = (ret == 0) & (*gp.value > 0);
if (bufmgr_gem->gen < 4) {
gp.param = I915_PARAM_NUM_FENCES_AVAIL;
gp.value = &bufmgr_gem->available_fences;
ret = drmIoctl(bufmgr_gem->fd, DRM_IOCTL_I915_GETPARAM, &gp);
if (ret) {
fprintf(stderr, "get fences failed: %d [%d]\n", ret,
errno);
fprintf(stderr, "param: %d, val: %d\n", gp.param,
*gp.value);
bufmgr_gem->available_fences = 0;
} else {
/* XXX The kernel reports the total number of fences,
* including any that may be pinned.
*
* We presume that there will be at least one pinned
* fence for the scanout buffer, but there may be more
* than one scanout and the user may be manually
* pinning buffers. Let's move to execbuffer2 and
* thereby forget the insanity of using fences...
*/
bufmgr_gem->available_fences -= 2;
if (bufmgr_gem->available_fences < 0)
bufmgr_gem->available_fences = 0;
}
}
/* Let's go with one relocation per every 2 dwords (but round down a bit
* since a power of two will mean an extra page allocation for the reloc
* buffer).
*
* Every 4 was too few for the blender benchmark.
*/
bufmgr_gem->max_relocs = batch_size / sizeof(uint32_t) / 2 - 2;
bufmgr_gem->bufmgr.bo_alloc = drm_intel_gem_bo_alloc;
// bufmgr_gem->bufmgr.bo_alloc_for_render =
// drm_intel_gem_bo_alloc_for_render;
bufmgr_gem->bufmgr.bo_alloc_tiled = drm_intel_gem_bo_alloc_tiled;
bufmgr_gem->bufmgr.bo_reference = drm_intel_gem_bo_reference;
bufmgr_gem->bufmgr.bo_unreference = drm_intel_gem_bo_unreference;
bufmgr_gem->bufmgr.bo_map = drm_intel_gem_bo_map;
bufmgr_gem->bufmgr.bo_unmap = drm_intel_gem_bo_unmap;
bufmgr_gem->bufmgr.bo_subdata = drm_intel_gem_bo_subdata;
// bufmgr_gem->bufmgr.bo_get_subdata = drm_intel_gem_bo_get_subdata;
bufmgr_gem->bufmgr.bo_wait_rendering = drm_intel_gem_bo_wait_rendering;
bufmgr_gem->bufmgr.bo_emit_reloc = drm_intel_gem_bo_emit_reloc;
bufmgr_gem->bufmgr.bo_emit_reloc_fence = drm_intel_gem_bo_emit_reloc_fence;
bufmgr_gem->bufmgr.bo_pin = drm_intel_gem_bo_pin;
bufmgr_gem->bufmgr.bo_unpin = drm_intel_gem_bo_unpin;
bufmgr_gem->bufmgr.bo_get_tiling = drm_intel_gem_bo_get_tiling;
bufmgr_gem->bufmgr.bo_set_tiling = drm_intel_gem_bo_set_tiling;
bufmgr_gem->bufmgr.bo_flink = drm_intel_gem_bo_flink;
/* Use the new one if available */
// if (exec2) {
bufmgr_gem->bufmgr.bo_exec = drm_intel_gem_bo_exec2;
bufmgr_gem->bufmgr.bo_mrb_exec = drm_intel_gem_bo_mrb_exec2;
// } else
// bufmgr_gem->bufmgr.bo_exec = drm_intel_gem_bo_exec;
bufmgr_gem->bufmgr.bo_busy = drm_intel_gem_bo_busy;
bufmgr_gem->bufmgr.bo_madvise = drm_intel_gem_bo_madvise;
bufmgr_gem->bufmgr.destroy = drm_intel_bufmgr_gem_destroy;
bufmgr_gem->bufmgr.debug = 0;
bufmgr_gem->bufmgr.check_aperture_space =
drm_intel_gem_check_aperture_space;
bufmgr_gem->bufmgr.bo_disable_reuse = drm_intel_gem_bo_disable_reuse;
bufmgr_gem->bufmgr.bo_is_reusable = drm_intel_gem_bo_is_reusable;
// bufmgr_gem->bufmgr.get_pipe_from_crtc_id =
// drm_intel_gem_get_pipe_from_crtc_id;
bufmgr_gem->bufmgr.bo_references = drm_intel_gem_bo_references;
DRMINITLISTHEAD(&bufmgr_gem->named);
init_cache_buckets(bufmgr_gem);
DRMINITLISTHEAD(&bufmgr_gem->vma_cache);
bufmgr_gem->vma_max = -1; /* unlimited by default */
return &bufmgr_gem->bufmgr;
}
drm_intel_bo *
bo_create_from_gem_handle(drm_intel_bufmgr *bufmgr,
unsigned int size, unsigned int handle)
{
drm_intel_bufmgr_gem *bufmgr_gem = (drm_intel_bufmgr_gem *) bufmgr;
drm_intel_bo_gem *bo_gem;
int ret;
struct drm_i915_gem_get_tiling get_tiling;
drmMMListHead *list;
/* 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.
*/
for (list = bufmgr_gem->named.next;
list != &bufmgr_gem->named;
list = list->next) {
bo_gem = DRMLISTENTRY(drm_intel_bo_gem, list, name_list);
if (bo_gem->gem_handle == handle) {
return &bo_gem->bo;
}
}
bo_gem = calloc(1, sizeof(*bo_gem));
if (!bo_gem)
return NULL;
bo_gem->bo.size = size;
bo_gem->bo.offset = 0;
bo_gem->bo.virtual = NULL;
bo_gem->bo.bufmgr = bufmgr;
bo_gem->name = NULL;
atomic_set(&bo_gem->refcount, 1);
bo_gem->validate_index = -1;
bo_gem->gem_handle = handle;
bo_gem->bo.handle = handle;
bo_gem->global_name = 0;
bo_gem->reusable = false;
VG_CLEAR(get_tiling);
get_tiling.handle = bo_gem->gem_handle;
ret = drmIoctl(bufmgr_gem->fd,
DRM_IOCTL_I915_GEM_GET_TILING,
&get_tiling);
if (ret != 0) {
drm_intel_gem_bo_unreference(&bo_gem->bo);
return NULL;
}
bo_gem->tiling_mode = get_tiling.tiling_mode;
bo_gem->swizzle_mode = get_tiling.swizzle_mode;
/* XXX stride is unknown */
drm_intel_bo_gem_set_in_aperture_size(bufmgr_gem, bo_gem);
DRMINITLISTHEAD(&bo_gem->vma_list);
DRMLISTADDTAIL(&bo_gem->name_list, &bufmgr_gem->named);
printf("bo_create_from_handle: %d\n", handle);
return &bo_gem->bo;
}