linux_dsm_epyc7002/drivers/gpu/drm/i915/i915_gem_execbuffer.c
Christian König 0b258ed1a2 drm: revert "expand replace_fence to support timeline point v2"
This reverts commit 9a09a42369.

The whole interface isn't thought through. Since this function can't
fail we actually can't allocate an object to store the sync point.

Sorry, I should have taken the lead on this from the very beginning and
reviewed it more thoughtfully. Going to propose a new interface as a
follow up change.

Signed-off-by: Christian König <christian.koenig@amd.com>
Reviewed-by: Chunming Zhou <david1.zhou@amd.com>
Link: https://patchwork.freedesktop.org/patch/265580/
2018-12-05 11:01:11 +01:00

2633 lines
70 KiB
C

/*
* Copyright © 2008,2010 Intel Corporation
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the "Software"),
* to deal in the Software without restriction, including without limitation
* the rights to use, copy, modify, merge, publish, distribute, sublicense,
* and/or sell copies of the Software, and to permit persons to whom the
* Software is furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice (including the next
* paragraph) shall be included in all copies or substantial portions of the
* Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
* THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
* FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS
* IN THE SOFTWARE.
*
* Authors:
* Eric Anholt <eric@anholt.net>
* Chris Wilson <chris@chris-wilson.co.uk>
*
*/
#include <linux/dma_remapping.h>
#include <linux/reservation.h>
#include <linux/sync_file.h>
#include <linux/uaccess.h>
#include <drm/drmP.h>
#include <drm/drm_syncobj.h>
#include <drm/i915_drm.h>
#include "i915_drv.h"
#include "i915_gem_clflush.h"
#include "i915_trace.h"
#include "intel_drv.h"
#include "intel_frontbuffer.h"
enum {
FORCE_CPU_RELOC = 1,
FORCE_GTT_RELOC,
FORCE_GPU_RELOC,
#define DBG_FORCE_RELOC 0 /* choose one of the above! */
};
#define __EXEC_OBJECT_HAS_REF BIT(31)
#define __EXEC_OBJECT_HAS_PIN BIT(30)
#define __EXEC_OBJECT_HAS_FENCE BIT(29)
#define __EXEC_OBJECT_NEEDS_MAP BIT(28)
#define __EXEC_OBJECT_NEEDS_BIAS BIT(27)
#define __EXEC_OBJECT_INTERNAL_FLAGS (~0u << 27) /* all of the above */
#define __EXEC_OBJECT_RESERVED (__EXEC_OBJECT_HAS_PIN | __EXEC_OBJECT_HAS_FENCE)
#define __EXEC_HAS_RELOC BIT(31)
#define __EXEC_VALIDATED BIT(30)
#define __EXEC_INTERNAL_FLAGS (~0u << 30)
#define UPDATE PIN_OFFSET_FIXED
#define BATCH_OFFSET_BIAS (256*1024)
#define __I915_EXEC_ILLEGAL_FLAGS \
(__I915_EXEC_UNKNOWN_FLAGS | \
I915_EXEC_CONSTANTS_MASK | \
I915_EXEC_RESOURCE_STREAMER)
/* Catch emission of unexpected errors for CI! */
#if IS_ENABLED(CONFIG_DRM_I915_DEBUG_GEM)
#undef EINVAL
#define EINVAL ({ \
DRM_DEBUG_DRIVER("EINVAL at %s:%d\n", __func__, __LINE__); \
22; \
})
#endif
/**
* DOC: User command execution
*
* Userspace submits commands to be executed on the GPU as an instruction
* stream within a GEM object we call a batchbuffer. This instructions may
* refer to other GEM objects containing auxiliary state such as kernels,
* samplers, render targets and even secondary batchbuffers. Userspace does
* not know where in the GPU memory these objects reside and so before the
* batchbuffer is passed to the GPU for execution, those addresses in the
* batchbuffer and auxiliary objects are updated. This is known as relocation,
* or patching. To try and avoid having to relocate each object on the next
* execution, userspace is told the location of those objects in this pass,
* but this remains just a hint as the kernel may choose a new location for
* any object in the future.
*
* At the level of talking to the hardware, submitting a batchbuffer for the
* GPU to execute is to add content to a buffer from which the HW
* command streamer is reading.
*
* 1. Add a command to load the HW context. For Logical Ring Contexts, i.e.
* Execlists, this command is not placed on the same buffer as the
* remaining items.
*
* 2. Add a command to invalidate caches to the buffer.
*
* 3. Add a batchbuffer start command to the buffer; the start command is
* essentially a token together with the GPU address of the batchbuffer
* to be executed.
*
* 4. Add a pipeline flush to the buffer.
*
* 5. Add a memory write command to the buffer to record when the GPU
* is done executing the batchbuffer. The memory write writes the
* global sequence number of the request, ``i915_request::global_seqno``;
* the i915 driver uses the current value in the register to determine
* if the GPU has completed the batchbuffer.
*
* 6. Add a user interrupt command to the buffer. This command instructs
* the GPU to issue an interrupt when the command, pipeline flush and
* memory write are completed.
*
* 7. Inform the hardware of the additional commands added to the buffer
* (by updating the tail pointer).
*
* Processing an execbuf ioctl is conceptually split up into a few phases.
*
* 1. Validation - Ensure all the pointers, handles and flags are valid.
* 2. Reservation - Assign GPU address space for every object
* 3. Relocation - Update any addresses to point to the final locations
* 4. Serialisation - Order the request with respect to its dependencies
* 5. Construction - Construct a request to execute the batchbuffer
* 6. Submission (at some point in the future execution)
*
* Reserving resources for the execbuf is the most complicated phase. We
* neither want to have to migrate the object in the address space, nor do
* we want to have to update any relocations pointing to this object. Ideally,
* we want to leave the object where it is and for all the existing relocations
* to match. If the object is given a new address, or if userspace thinks the
* object is elsewhere, we have to parse all the relocation entries and update
* the addresses. Userspace can set the I915_EXEC_NORELOC flag to hint that
* all the target addresses in all of its objects match the value in the
* relocation entries and that they all match the presumed offsets given by the
* list of execbuffer objects. Using this knowledge, we know that if we haven't
* moved any buffers, all the relocation entries are valid and we can skip
* the update. (If userspace is wrong, the likely outcome is an impromptu GPU
* hang.) The requirement for using I915_EXEC_NO_RELOC are:
*
* The addresses written in the objects must match the corresponding
* reloc.presumed_offset which in turn must match the corresponding
* execobject.offset.
*
* Any render targets written to in the batch must be flagged with
* EXEC_OBJECT_WRITE.
*
* To avoid stalling, execobject.offset should match the current
* address of that object within the active context.
*
* The reservation is done is multiple phases. First we try and keep any
* object already bound in its current location - so as long as meets the
* constraints imposed by the new execbuffer. Any object left unbound after the
* first pass is then fitted into any available idle space. If an object does
* not fit, all objects are removed from the reservation and the process rerun
* after sorting the objects into a priority order (more difficult to fit
* objects are tried first). Failing that, the entire VM is cleared and we try
* to fit the execbuf once last time before concluding that it simply will not
* fit.
*
* A small complication to all of this is that we allow userspace not only to
* specify an alignment and a size for the object in the address space, but
* we also allow userspace to specify the exact offset. This objects are
* simpler to place (the location is known a priori) all we have to do is make
* sure the space is available.
*
* Once all the objects are in place, patching up the buried pointers to point
* to the final locations is a fairly simple job of walking over the relocation
* entry arrays, looking up the right address and rewriting the value into
* the object. Simple! ... The relocation entries are stored in user memory
* and so to access them we have to copy them into a local buffer. That copy
* has to avoid taking any pagefaults as they may lead back to a GEM object
* requiring the struct_mutex (i.e. recursive deadlock). So once again we split
* the relocation into multiple passes. First we try to do everything within an
* atomic context (avoid the pagefaults) which requires that we never wait. If
* we detect that we may wait, or if we need to fault, then we have to fallback
* to a slower path. The slowpath has to drop the mutex. (Can you hear alarm
* bells yet?) Dropping the mutex means that we lose all the state we have
* built up so far for the execbuf and we must reset any global data. However,
* we do leave the objects pinned in their final locations - which is a
* potential issue for concurrent execbufs. Once we have left the mutex, we can
* allocate and copy all the relocation entries into a large array at our
* leisure, reacquire the mutex, reclaim all the objects and other state and
* then proceed to update any incorrect addresses with the objects.
*
* As we process the relocation entries, we maintain a record of whether the
* object is being written to. Using NORELOC, we expect userspace to provide
* this information instead. We also check whether we can skip the relocation
* by comparing the expected value inside the relocation entry with the target's
* final address. If they differ, we have to map the current object and rewrite
* the 4 or 8 byte pointer within.
*
* Serialising an execbuf is quite simple according to the rules of the GEM
* ABI. Execution within each context is ordered by the order of submission.
* Writes to any GEM object are in order of submission and are exclusive. Reads
* from a GEM object are unordered with respect to other reads, but ordered by
* writes. A write submitted after a read cannot occur before the read, and
* similarly any read submitted after a write cannot occur before the write.
* Writes are ordered between engines such that only one write occurs at any
* time (completing any reads beforehand) - using semaphores where available
* and CPU serialisation otherwise. Other GEM access obey the same rules, any
* write (either via mmaps using set-domain, or via pwrite) must flush all GPU
* reads before starting, and any read (either using set-domain or pread) must
* flush all GPU writes before starting. (Note we only employ a barrier before,
* we currently rely on userspace not concurrently starting a new execution
* whilst reading or writing to an object. This may be an advantage or not
* depending on how much you trust userspace not to shoot themselves in the
* foot.) Serialisation may just result in the request being inserted into
* a DAG awaiting its turn, but most simple is to wait on the CPU until
* all dependencies are resolved.
*
* After all of that, is just a matter of closing the request and handing it to
* the hardware (well, leaving it in a queue to be executed). However, we also
* offer the ability for batchbuffers to be run with elevated privileges so
* that they access otherwise hidden registers. (Used to adjust L3 cache etc.)
* Before any batch is given extra privileges we first must check that it
* contains no nefarious instructions, we check that each instruction is from
* our whitelist and all registers are also from an allowed list. We first
* copy the user's batchbuffer to a shadow (so that the user doesn't have
* access to it, either by the CPU or GPU as we scan it) and then parse each
* instruction. If everything is ok, we set a flag telling the hardware to run
* the batchbuffer in trusted mode, otherwise the ioctl is rejected.
*/
struct i915_execbuffer {
struct drm_i915_private *i915; /** i915 backpointer */
struct drm_file *file; /** per-file lookup tables and limits */
struct drm_i915_gem_execbuffer2 *args; /** ioctl parameters */
struct drm_i915_gem_exec_object2 *exec; /** ioctl execobj[] */
struct i915_vma **vma;
unsigned int *flags;
struct intel_engine_cs *engine; /** engine to queue the request to */
struct i915_gem_context *ctx; /** context for building the request */
struct i915_address_space *vm; /** GTT and vma for the request */
struct i915_request *request; /** our request to build */
struct i915_vma *batch; /** identity of the batch obj/vma */
/** actual size of execobj[] as we may extend it for the cmdparser */
unsigned int buffer_count;
/** list of vma not yet bound during reservation phase */
struct list_head unbound;
/** list of vma that have execobj.relocation_count */
struct list_head relocs;
/**
* Track the most recently used object for relocations, as we
* frequently have to perform multiple relocations within the same
* obj/page
*/
struct reloc_cache {
struct drm_mm_node node; /** temporary GTT binding */
unsigned long vaddr; /** Current kmap address */
unsigned long page; /** Currently mapped page index */
unsigned int gen; /** Cached value of INTEL_GEN */
bool use_64bit_reloc : 1;
bool has_llc : 1;
bool has_fence : 1;
bool needs_unfenced : 1;
struct i915_request *rq;
u32 *rq_cmd;
unsigned int rq_size;
} reloc_cache;
u64 invalid_flags; /** Set of execobj.flags that are invalid */
u32 context_flags; /** Set of execobj.flags to insert from the ctx */
u32 batch_start_offset; /** Location within object of batch */
u32 batch_len; /** Length of batch within object */
u32 batch_flags; /** Flags composed for emit_bb_start() */
/**
* Indicate either the size of the hastable used to resolve
* relocation handles, or if negative that we are using a direct
* index into the execobj[].
*/
int lut_size;
struct hlist_head *buckets; /** ht for relocation handles */
};
#define exec_entry(EB, VMA) (&(EB)->exec[(VMA)->exec_flags - (EB)->flags])
/*
* Used to convert any address to canonical form.
* Starting from gen8, some commands (e.g. STATE_BASE_ADDRESS,
* MI_LOAD_REGISTER_MEM and others, see Broadwell PRM Vol2a) require the
* addresses to be in a canonical form:
* "GraphicsAddress[63:48] are ignored by the HW and assumed to be in correct
* canonical form [63:48] == [47]."
*/
#define GEN8_HIGH_ADDRESS_BIT 47
static inline u64 gen8_canonical_addr(u64 address)
{
return sign_extend64(address, GEN8_HIGH_ADDRESS_BIT);
}
static inline u64 gen8_noncanonical_addr(u64 address)
{
return address & GENMASK_ULL(GEN8_HIGH_ADDRESS_BIT, 0);
}
static inline bool eb_use_cmdparser(const struct i915_execbuffer *eb)
{
return intel_engine_needs_cmd_parser(eb->engine) && eb->batch_len;
}
static int eb_create(struct i915_execbuffer *eb)
{
if (!(eb->args->flags & I915_EXEC_HANDLE_LUT)) {
unsigned int size = 1 + ilog2(eb->buffer_count);
/*
* Without a 1:1 association between relocation handles and
* the execobject[] index, we instead create a hashtable.
* We size it dynamically based on available memory, starting
* first with 1:1 assocative hash and scaling back until
* the allocation succeeds.
*
* Later on we use a positive lut_size to indicate we are
* using this hashtable, and a negative value to indicate a
* direct lookup.
*/
do {
gfp_t flags;
/* While we can still reduce the allocation size, don't
* raise a warning and allow the allocation to fail.
* On the last pass though, we want to try as hard
* as possible to perform the allocation and warn
* if it fails.
*/
flags = GFP_KERNEL;
if (size > 1)
flags |= __GFP_NORETRY | __GFP_NOWARN;
eb->buckets = kzalloc(sizeof(struct hlist_head) << size,
flags);
if (eb->buckets)
break;
} while (--size);
if (unlikely(!size))
return -ENOMEM;
eb->lut_size = size;
} else {
eb->lut_size = -eb->buffer_count;
}
return 0;
}
static bool
eb_vma_misplaced(const struct drm_i915_gem_exec_object2 *entry,
const struct i915_vma *vma,
unsigned int flags)
{
if (vma->node.size < entry->pad_to_size)
return true;
if (entry->alignment && !IS_ALIGNED(vma->node.start, entry->alignment))
return true;
if (flags & EXEC_OBJECT_PINNED &&
vma->node.start != entry->offset)
return true;
if (flags & __EXEC_OBJECT_NEEDS_BIAS &&
vma->node.start < BATCH_OFFSET_BIAS)
return true;
if (!(flags & EXEC_OBJECT_SUPPORTS_48B_ADDRESS) &&
(vma->node.start + vma->node.size - 1) >> 32)
return true;
if (flags & __EXEC_OBJECT_NEEDS_MAP &&
!i915_vma_is_map_and_fenceable(vma))
return true;
return false;
}
static inline bool
eb_pin_vma(struct i915_execbuffer *eb,
const struct drm_i915_gem_exec_object2 *entry,
struct i915_vma *vma)
{
unsigned int exec_flags = *vma->exec_flags;
u64 pin_flags;
if (vma->node.size)
pin_flags = vma->node.start;
else
pin_flags = entry->offset & PIN_OFFSET_MASK;
pin_flags |= PIN_USER | PIN_NOEVICT | PIN_OFFSET_FIXED;
if (unlikely(exec_flags & EXEC_OBJECT_NEEDS_GTT))
pin_flags |= PIN_GLOBAL;
if (unlikely(i915_vma_pin(vma, 0, 0, pin_flags)))
return false;
if (unlikely(exec_flags & EXEC_OBJECT_NEEDS_FENCE)) {
if (unlikely(i915_vma_pin_fence(vma))) {
i915_vma_unpin(vma);
return false;
}
if (vma->fence)
exec_flags |= __EXEC_OBJECT_HAS_FENCE;
}
*vma->exec_flags = exec_flags | __EXEC_OBJECT_HAS_PIN;
return !eb_vma_misplaced(entry, vma, exec_flags);
}
static inline void __eb_unreserve_vma(struct i915_vma *vma, unsigned int flags)
{
GEM_BUG_ON(!(flags & __EXEC_OBJECT_HAS_PIN));
if (unlikely(flags & __EXEC_OBJECT_HAS_FENCE))
__i915_vma_unpin_fence(vma);
__i915_vma_unpin(vma);
}
static inline void
eb_unreserve_vma(struct i915_vma *vma, unsigned int *flags)
{
if (!(*flags & __EXEC_OBJECT_HAS_PIN))
return;
__eb_unreserve_vma(vma, *flags);
*flags &= ~__EXEC_OBJECT_RESERVED;
}
static int
eb_validate_vma(struct i915_execbuffer *eb,
struct drm_i915_gem_exec_object2 *entry,
struct i915_vma *vma)
{
if (unlikely(entry->flags & eb->invalid_flags))
return -EINVAL;
if (unlikely(entry->alignment && !is_power_of_2(entry->alignment)))
return -EINVAL;
/*
* Offset can be used as input (EXEC_OBJECT_PINNED), reject
* any non-page-aligned or non-canonical addresses.
*/
if (unlikely(entry->flags & EXEC_OBJECT_PINNED &&
entry->offset != gen8_canonical_addr(entry->offset & I915_GTT_PAGE_MASK)))
return -EINVAL;
/* pad_to_size was once a reserved field, so sanitize it */
if (entry->flags & EXEC_OBJECT_PAD_TO_SIZE) {
if (unlikely(offset_in_page(entry->pad_to_size)))
return -EINVAL;
} else {
entry->pad_to_size = 0;
}
if (unlikely(vma->exec_flags)) {
DRM_DEBUG("Object [handle %d, index %d] appears more than once in object list\n",
entry->handle, (int)(entry - eb->exec));
return -EINVAL;
}
/*
* From drm_mm perspective address space is continuous,
* so from this point we're always using non-canonical
* form internally.
*/
entry->offset = gen8_noncanonical_addr(entry->offset);
if (!eb->reloc_cache.has_fence) {
entry->flags &= ~EXEC_OBJECT_NEEDS_FENCE;
} else {
if ((entry->flags & EXEC_OBJECT_NEEDS_FENCE ||
eb->reloc_cache.needs_unfenced) &&
i915_gem_object_is_tiled(vma->obj))
entry->flags |= EXEC_OBJECT_NEEDS_GTT | __EXEC_OBJECT_NEEDS_MAP;
}
if (!(entry->flags & EXEC_OBJECT_PINNED))
entry->flags |= eb->context_flags;
return 0;
}
static int
eb_add_vma(struct i915_execbuffer *eb,
unsigned int i, unsigned batch_idx,
struct i915_vma *vma)
{
struct drm_i915_gem_exec_object2 *entry = &eb->exec[i];
int err;
GEM_BUG_ON(i915_vma_is_closed(vma));
if (!(eb->args->flags & __EXEC_VALIDATED)) {
err = eb_validate_vma(eb, entry, vma);
if (unlikely(err))
return err;
}
if (eb->lut_size > 0) {
vma->exec_handle = entry->handle;
hlist_add_head(&vma->exec_node,
&eb->buckets[hash_32(entry->handle,
eb->lut_size)]);
}
if (entry->relocation_count)
list_add_tail(&vma->reloc_link, &eb->relocs);
/*
* Stash a pointer from the vma to execobj, so we can query its flags,
* size, alignment etc as provided by the user. Also we stash a pointer
* to the vma inside the execobj so that we can use a direct lookup
* to find the right target VMA when doing relocations.
*/
eb->vma[i] = vma;
eb->flags[i] = entry->flags;
vma->exec_flags = &eb->flags[i];
/*
* SNA is doing fancy tricks with compressing batch buffers, which leads
* to negative relocation deltas. Usually that works out ok since the
* relocate address is still positive, except when the batch is placed
* very low in the GTT. Ensure this doesn't happen.
*
* Note that actual hangs have only been observed on gen7, but for
* paranoia do it everywhere.
*/
if (i == batch_idx) {
if (entry->relocation_count &&
!(eb->flags[i] & EXEC_OBJECT_PINNED))
eb->flags[i] |= __EXEC_OBJECT_NEEDS_BIAS;
if (eb->reloc_cache.has_fence)
eb->flags[i] |= EXEC_OBJECT_NEEDS_FENCE;
eb->batch = vma;
}
err = 0;
if (eb_pin_vma(eb, entry, vma)) {
if (entry->offset != vma->node.start) {
entry->offset = vma->node.start | UPDATE;
eb->args->flags |= __EXEC_HAS_RELOC;
}
} else {
eb_unreserve_vma(vma, vma->exec_flags);
list_add_tail(&vma->exec_link, &eb->unbound);
if (drm_mm_node_allocated(&vma->node))
err = i915_vma_unbind(vma);
if (unlikely(err))
vma->exec_flags = NULL;
}
return err;
}
static inline int use_cpu_reloc(const struct reloc_cache *cache,
const struct drm_i915_gem_object *obj)
{
if (!i915_gem_object_has_struct_page(obj))
return false;
if (DBG_FORCE_RELOC == FORCE_CPU_RELOC)
return true;
if (DBG_FORCE_RELOC == FORCE_GTT_RELOC)
return false;
return (cache->has_llc ||
obj->cache_dirty ||
obj->cache_level != I915_CACHE_NONE);
}
static int eb_reserve_vma(const struct i915_execbuffer *eb,
struct i915_vma *vma)
{
struct drm_i915_gem_exec_object2 *entry = exec_entry(eb, vma);
unsigned int exec_flags = *vma->exec_flags;
u64 pin_flags;
int err;
pin_flags = PIN_USER | PIN_NONBLOCK;
if (exec_flags & EXEC_OBJECT_NEEDS_GTT)
pin_flags |= PIN_GLOBAL;
/*
* Wa32bitGeneralStateOffset & Wa32bitInstructionBaseOffset,
* limit address to the first 4GBs for unflagged objects.
*/
if (!(exec_flags & EXEC_OBJECT_SUPPORTS_48B_ADDRESS))
pin_flags |= PIN_ZONE_4G;
if (exec_flags & __EXEC_OBJECT_NEEDS_MAP)
pin_flags |= PIN_MAPPABLE;
if (exec_flags & EXEC_OBJECT_PINNED) {
pin_flags |= entry->offset | PIN_OFFSET_FIXED;
pin_flags &= ~PIN_NONBLOCK; /* force overlapping checks */
} else if (exec_flags & __EXEC_OBJECT_NEEDS_BIAS) {
pin_flags |= BATCH_OFFSET_BIAS | PIN_OFFSET_BIAS;
}
err = i915_vma_pin(vma,
entry->pad_to_size, entry->alignment,
pin_flags);
if (err)
return err;
if (entry->offset != vma->node.start) {
entry->offset = vma->node.start | UPDATE;
eb->args->flags |= __EXEC_HAS_RELOC;
}
if (unlikely(exec_flags & EXEC_OBJECT_NEEDS_FENCE)) {
err = i915_vma_pin_fence(vma);
if (unlikely(err)) {
i915_vma_unpin(vma);
return err;
}
if (vma->fence)
exec_flags |= __EXEC_OBJECT_HAS_FENCE;
}
*vma->exec_flags = exec_flags | __EXEC_OBJECT_HAS_PIN;
GEM_BUG_ON(eb_vma_misplaced(entry, vma, exec_flags));
return 0;
}
static int eb_reserve(struct i915_execbuffer *eb)
{
const unsigned int count = eb->buffer_count;
struct list_head last;
struct i915_vma *vma;
unsigned int i, pass;
int err;
/*
* Attempt to pin all of the buffers into the GTT.
* This is done in 3 phases:
*
* 1a. Unbind all objects that do not match the GTT constraints for
* the execbuffer (fenceable, mappable, alignment etc).
* 1b. Increment pin count for already bound objects.
* 2. Bind new objects.
* 3. Decrement pin count.
*
* This avoid unnecessary unbinding of later objects in order to make
* room for the earlier objects *unless* we need to defragment.
*/
pass = 0;
err = 0;
do {
list_for_each_entry(vma, &eb->unbound, exec_link) {
err = eb_reserve_vma(eb, vma);
if (err)
break;
}
if (err != -ENOSPC)
return err;
/* Resort *all* the objects into priority order */
INIT_LIST_HEAD(&eb->unbound);
INIT_LIST_HEAD(&last);
for (i = 0; i < count; i++) {
unsigned int flags = eb->flags[i];
struct i915_vma *vma = eb->vma[i];
if (flags & EXEC_OBJECT_PINNED &&
flags & __EXEC_OBJECT_HAS_PIN)
continue;
eb_unreserve_vma(vma, &eb->flags[i]);
if (flags & EXEC_OBJECT_PINNED)
/* Pinned must have their slot */
list_add(&vma->exec_link, &eb->unbound);
else if (flags & __EXEC_OBJECT_NEEDS_MAP)
/* Map require the lowest 256MiB (aperture) */
list_add_tail(&vma->exec_link, &eb->unbound);
else if (!(flags & EXEC_OBJECT_SUPPORTS_48B_ADDRESS))
/* Prioritise 4GiB region for restricted bo */
list_add(&vma->exec_link, &last);
else
list_add_tail(&vma->exec_link, &last);
}
list_splice_tail(&last, &eb->unbound);
switch (pass++) {
case 0:
break;
case 1:
/* Too fragmented, unbind everything and retry */
err = i915_gem_evict_vm(eb->vm);
if (err)
return err;
break;
default:
return -ENOSPC;
}
} while (1);
}
static unsigned int eb_batch_index(const struct i915_execbuffer *eb)
{
if (eb->args->flags & I915_EXEC_BATCH_FIRST)
return 0;
else
return eb->buffer_count - 1;
}
static int eb_select_context(struct i915_execbuffer *eb)
{
struct i915_gem_context *ctx;
ctx = i915_gem_context_lookup(eb->file->driver_priv, eb->args->rsvd1);
if (unlikely(!ctx))
return -ENOENT;
eb->ctx = ctx;
if (ctx->ppgtt) {
eb->vm = &ctx->ppgtt->vm;
eb->invalid_flags |= EXEC_OBJECT_NEEDS_GTT;
} else {
eb->vm = &eb->i915->ggtt.vm;
}
eb->context_flags = 0;
if (test_bit(UCONTEXT_NO_ZEROMAP, &ctx->user_flags))
eb->context_flags |= __EXEC_OBJECT_NEEDS_BIAS;
return 0;
}
static int eb_lookup_vmas(struct i915_execbuffer *eb)
{
struct radix_tree_root *handles_vma = &eb->ctx->handles_vma;
struct drm_i915_gem_object *obj;
unsigned int i, batch;
int err;
if (unlikely(i915_gem_context_is_closed(eb->ctx)))
return -ENOENT;
if (unlikely(i915_gem_context_is_banned(eb->ctx)))
return -EIO;
INIT_LIST_HEAD(&eb->relocs);
INIT_LIST_HEAD(&eb->unbound);
batch = eb_batch_index(eb);
for (i = 0; i < eb->buffer_count; i++) {
u32 handle = eb->exec[i].handle;
struct i915_lut_handle *lut;
struct i915_vma *vma;
vma = radix_tree_lookup(handles_vma, handle);
if (likely(vma))
goto add_vma;
obj = i915_gem_object_lookup(eb->file, handle);
if (unlikely(!obj)) {
err = -ENOENT;
goto err_vma;
}
vma = i915_vma_instance(obj, eb->vm, NULL);
if (unlikely(IS_ERR(vma))) {
err = PTR_ERR(vma);
goto err_obj;
}
lut = kmem_cache_alloc(eb->i915->luts, GFP_KERNEL);
if (unlikely(!lut)) {
err = -ENOMEM;
goto err_obj;
}
err = radix_tree_insert(handles_vma, handle, vma);
if (unlikely(err)) {
kmem_cache_free(eb->i915->luts, lut);
goto err_obj;
}
/* transfer ref to ctx */
if (!vma->open_count++)
i915_vma_reopen(vma);
list_add(&lut->obj_link, &obj->lut_list);
list_add(&lut->ctx_link, &eb->ctx->handles_list);
lut->ctx = eb->ctx;
lut->handle = handle;
add_vma:
err = eb_add_vma(eb, i, batch, vma);
if (unlikely(err))
goto err_vma;
GEM_BUG_ON(vma != eb->vma[i]);
GEM_BUG_ON(vma->exec_flags != &eb->flags[i]);
GEM_BUG_ON(drm_mm_node_allocated(&vma->node) &&
eb_vma_misplaced(&eb->exec[i], vma, eb->flags[i]));
}
eb->args->flags |= __EXEC_VALIDATED;
return eb_reserve(eb);
err_obj:
i915_gem_object_put(obj);
err_vma:
eb->vma[i] = NULL;
return err;
}
static struct i915_vma *
eb_get_vma(const struct i915_execbuffer *eb, unsigned long handle)
{
if (eb->lut_size < 0) {
if (handle >= -eb->lut_size)
return NULL;
return eb->vma[handle];
} else {
struct hlist_head *head;
struct i915_vma *vma;
head = &eb->buckets[hash_32(handle, eb->lut_size)];
hlist_for_each_entry(vma, head, exec_node) {
if (vma->exec_handle == handle)
return vma;
}
return NULL;
}
}
static void eb_release_vmas(const struct i915_execbuffer *eb)
{
const unsigned int count = eb->buffer_count;
unsigned int i;
for (i = 0; i < count; i++) {
struct i915_vma *vma = eb->vma[i];
unsigned int flags = eb->flags[i];
if (!vma)
break;
GEM_BUG_ON(vma->exec_flags != &eb->flags[i]);
vma->exec_flags = NULL;
eb->vma[i] = NULL;
if (flags & __EXEC_OBJECT_HAS_PIN)
__eb_unreserve_vma(vma, flags);
if (flags & __EXEC_OBJECT_HAS_REF)
i915_vma_put(vma);
}
}
static void eb_reset_vmas(const struct i915_execbuffer *eb)
{
eb_release_vmas(eb);
if (eb->lut_size > 0)
memset(eb->buckets, 0,
sizeof(struct hlist_head) << eb->lut_size);
}
static void eb_destroy(const struct i915_execbuffer *eb)
{
GEM_BUG_ON(eb->reloc_cache.rq);
if (eb->lut_size > 0)
kfree(eb->buckets);
}
static inline u64
relocation_target(const struct drm_i915_gem_relocation_entry *reloc,
const struct i915_vma *target)
{
return gen8_canonical_addr((int)reloc->delta + target->node.start);
}
static void reloc_cache_init(struct reloc_cache *cache,
struct drm_i915_private *i915)
{
cache->page = -1;
cache->vaddr = 0;
/* Must be a variable in the struct to allow GCC to unroll. */
cache->gen = INTEL_GEN(i915);
cache->has_llc = HAS_LLC(i915);
cache->use_64bit_reloc = HAS_64BIT_RELOC(i915);
cache->has_fence = cache->gen < 4;
cache->needs_unfenced = INTEL_INFO(i915)->unfenced_needs_alignment;
cache->node.allocated = false;
cache->rq = NULL;
cache->rq_size = 0;
}
static inline void *unmask_page(unsigned long p)
{
return (void *)(uintptr_t)(p & PAGE_MASK);
}
static inline unsigned int unmask_flags(unsigned long p)
{
return p & ~PAGE_MASK;
}
#define KMAP 0x4 /* after CLFLUSH_FLAGS */
static inline struct i915_ggtt *cache_to_ggtt(struct reloc_cache *cache)
{
struct drm_i915_private *i915 =
container_of(cache, struct i915_execbuffer, reloc_cache)->i915;
return &i915->ggtt;
}
static void reloc_gpu_flush(struct reloc_cache *cache)
{
GEM_BUG_ON(cache->rq_size >= cache->rq->batch->obj->base.size / sizeof(u32));
cache->rq_cmd[cache->rq_size] = MI_BATCH_BUFFER_END;
i915_gem_object_unpin_map(cache->rq->batch->obj);
i915_gem_chipset_flush(cache->rq->i915);
i915_request_add(cache->rq);
cache->rq = NULL;
}
static void reloc_cache_reset(struct reloc_cache *cache)
{
void *vaddr;
if (cache->rq)
reloc_gpu_flush(cache);
if (!cache->vaddr)
return;
vaddr = unmask_page(cache->vaddr);
if (cache->vaddr & KMAP) {
if (cache->vaddr & CLFLUSH_AFTER)
mb();
kunmap_atomic(vaddr);
i915_gem_obj_finish_shmem_access((struct drm_i915_gem_object *)cache->node.mm);
} else {
wmb();
io_mapping_unmap_atomic((void __iomem *)vaddr);
if (cache->node.allocated) {
struct i915_ggtt *ggtt = cache_to_ggtt(cache);
ggtt->vm.clear_range(&ggtt->vm,
cache->node.start,
cache->node.size);
drm_mm_remove_node(&cache->node);
} else {
i915_vma_unpin((struct i915_vma *)cache->node.mm);
}
}
cache->vaddr = 0;
cache->page = -1;
}
static void *reloc_kmap(struct drm_i915_gem_object *obj,
struct reloc_cache *cache,
unsigned long page)
{
void *vaddr;
if (cache->vaddr) {
kunmap_atomic(unmask_page(cache->vaddr));
} else {
unsigned int flushes;
int err;
err = i915_gem_obj_prepare_shmem_write(obj, &flushes);
if (err)
return ERR_PTR(err);
BUILD_BUG_ON(KMAP & CLFLUSH_FLAGS);
BUILD_BUG_ON((KMAP | CLFLUSH_FLAGS) & PAGE_MASK);
cache->vaddr = flushes | KMAP;
cache->node.mm = (void *)obj;
if (flushes)
mb();
}
vaddr = kmap_atomic(i915_gem_object_get_dirty_page(obj, page));
cache->vaddr = unmask_flags(cache->vaddr) | (unsigned long)vaddr;
cache->page = page;
return vaddr;
}
static void *reloc_iomap(struct drm_i915_gem_object *obj,
struct reloc_cache *cache,
unsigned long page)
{
struct i915_ggtt *ggtt = cache_to_ggtt(cache);
unsigned long offset;
void *vaddr;
if (cache->vaddr) {
io_mapping_unmap_atomic((void __force __iomem *) unmask_page(cache->vaddr));
} else {
struct i915_vma *vma;
int err;
if (use_cpu_reloc(cache, obj))
return NULL;
err = i915_gem_object_set_to_gtt_domain(obj, true);
if (err)
return ERR_PTR(err);
vma = i915_gem_object_ggtt_pin(obj, NULL, 0, 0,
PIN_MAPPABLE |
PIN_NONBLOCK |
PIN_NONFAULT);
if (IS_ERR(vma)) {
memset(&cache->node, 0, sizeof(cache->node));
err = drm_mm_insert_node_in_range
(&ggtt->vm.mm, &cache->node,
PAGE_SIZE, 0, I915_COLOR_UNEVICTABLE,
0, ggtt->mappable_end,
DRM_MM_INSERT_LOW);
if (err) /* no inactive aperture space, use cpu reloc */
return NULL;
} else {
err = i915_vma_put_fence(vma);
if (err) {
i915_vma_unpin(vma);
return ERR_PTR(err);
}
cache->node.start = vma->node.start;
cache->node.mm = (void *)vma;
}
}
offset = cache->node.start;
if (cache->node.allocated) {
wmb();
ggtt->vm.insert_page(&ggtt->vm,
i915_gem_object_get_dma_address(obj, page),
offset, I915_CACHE_NONE, 0);
} else {
offset += page << PAGE_SHIFT;
}
vaddr = (void __force *)io_mapping_map_atomic_wc(&ggtt->iomap,
offset);
cache->page = page;
cache->vaddr = (unsigned long)vaddr;
return vaddr;
}
static void *reloc_vaddr(struct drm_i915_gem_object *obj,
struct reloc_cache *cache,
unsigned long page)
{
void *vaddr;
if (cache->page == page) {
vaddr = unmask_page(cache->vaddr);
} else {
vaddr = NULL;
if ((cache->vaddr & KMAP) == 0)
vaddr = reloc_iomap(obj, cache, page);
if (!vaddr)
vaddr = reloc_kmap(obj, cache, page);
}
return vaddr;
}
static void clflush_write32(u32 *addr, u32 value, unsigned int flushes)
{
if (unlikely(flushes & (CLFLUSH_BEFORE | CLFLUSH_AFTER))) {
if (flushes & CLFLUSH_BEFORE) {
clflushopt(addr);
mb();
}
*addr = value;
/*
* Writes to the same cacheline are serialised by the CPU
* (including clflush). On the write path, we only require
* that it hits memory in an orderly fashion and place
* mb barriers at the start and end of the relocation phase
* to ensure ordering of clflush wrt to the system.
*/
if (flushes & CLFLUSH_AFTER)
clflushopt(addr);
} else
*addr = value;
}
static int __reloc_gpu_alloc(struct i915_execbuffer *eb,
struct i915_vma *vma,
unsigned int len)
{
struct reloc_cache *cache = &eb->reloc_cache;
struct drm_i915_gem_object *obj;
struct i915_request *rq;
struct i915_vma *batch;
u32 *cmd;
int err;
if (DBG_FORCE_RELOC == FORCE_GPU_RELOC) {
obj = vma->obj;
if (obj->cache_dirty & ~obj->cache_coherent)
i915_gem_clflush_object(obj, 0);
obj->write_domain = 0;
}
GEM_BUG_ON(vma->obj->write_domain & I915_GEM_DOMAIN_CPU);
obj = i915_gem_batch_pool_get(&eb->engine->batch_pool, PAGE_SIZE);
if (IS_ERR(obj))
return PTR_ERR(obj);
cmd = i915_gem_object_pin_map(obj,
cache->has_llc ?
I915_MAP_FORCE_WB :
I915_MAP_FORCE_WC);
i915_gem_object_unpin_pages(obj);
if (IS_ERR(cmd))
return PTR_ERR(cmd);
err = i915_gem_object_set_to_wc_domain(obj, false);
if (err)
goto err_unmap;
batch = i915_vma_instance(obj, vma->vm, NULL);
if (IS_ERR(batch)) {
err = PTR_ERR(batch);
goto err_unmap;
}
err = i915_vma_pin(batch, 0, 0, PIN_USER | PIN_NONBLOCK);
if (err)
goto err_unmap;
rq = i915_request_alloc(eb->engine, eb->ctx);
if (IS_ERR(rq)) {
err = PTR_ERR(rq);
goto err_unpin;
}
err = i915_request_await_object(rq, vma->obj, true);
if (err)
goto err_request;
err = eb->engine->emit_bb_start(rq,
batch->node.start, PAGE_SIZE,
cache->gen > 5 ? 0 : I915_DISPATCH_SECURE);
if (err)
goto err_request;
GEM_BUG_ON(!reservation_object_test_signaled_rcu(batch->resv, true));
err = i915_vma_move_to_active(batch, rq, 0);
if (err)
goto skip_request;
err = i915_vma_move_to_active(vma, rq, EXEC_OBJECT_WRITE);
if (err)
goto skip_request;
rq->batch = batch;
i915_vma_unpin(batch);
cache->rq = rq;
cache->rq_cmd = cmd;
cache->rq_size = 0;
/* Return with batch mapping (cmd) still pinned */
return 0;
skip_request:
i915_request_skip(rq, err);
err_request:
i915_request_add(rq);
err_unpin:
i915_vma_unpin(batch);
err_unmap:
i915_gem_object_unpin_map(obj);
return err;
}
static u32 *reloc_gpu(struct i915_execbuffer *eb,
struct i915_vma *vma,
unsigned int len)
{
struct reloc_cache *cache = &eb->reloc_cache;
u32 *cmd;
if (cache->rq_size > PAGE_SIZE/sizeof(u32) - (len + 1))
reloc_gpu_flush(cache);
if (unlikely(!cache->rq)) {
int err;
/* If we need to copy for the cmdparser, we will stall anyway */
if (eb_use_cmdparser(eb))
return ERR_PTR(-EWOULDBLOCK);
if (!intel_engine_can_store_dword(eb->engine))
return ERR_PTR(-ENODEV);
err = __reloc_gpu_alloc(eb, vma, len);
if (unlikely(err))
return ERR_PTR(err);
}
cmd = cache->rq_cmd + cache->rq_size;
cache->rq_size += len;
return cmd;
}
static u64
relocate_entry(struct i915_vma *vma,
const struct drm_i915_gem_relocation_entry *reloc,
struct i915_execbuffer *eb,
const struct i915_vma *target)
{
u64 offset = reloc->offset;
u64 target_offset = relocation_target(reloc, target);
bool wide = eb->reloc_cache.use_64bit_reloc;
void *vaddr;
if (!eb->reloc_cache.vaddr &&
(DBG_FORCE_RELOC == FORCE_GPU_RELOC ||
!reservation_object_test_signaled_rcu(vma->resv, true))) {
const unsigned int gen = eb->reloc_cache.gen;
unsigned int len;
u32 *batch;
u64 addr;
if (wide)
len = offset & 7 ? 8 : 5;
else if (gen >= 4)
len = 4;
else
len = 6;
batch = reloc_gpu(eb, vma, len);
if (IS_ERR(batch))
goto repeat;
addr = gen8_canonical_addr(vma->node.start + offset);
if (wide) {
if (offset & 7) {
*batch++ = MI_STORE_DWORD_IMM_GEN4;
*batch++ = lower_32_bits(addr);
*batch++ = upper_32_bits(addr);
*batch++ = lower_32_bits(target_offset);
addr = gen8_canonical_addr(addr + 4);
*batch++ = MI_STORE_DWORD_IMM_GEN4;
*batch++ = lower_32_bits(addr);
*batch++ = upper_32_bits(addr);
*batch++ = upper_32_bits(target_offset);
} else {
*batch++ = (MI_STORE_DWORD_IMM_GEN4 | (1 << 21)) + 1;
*batch++ = lower_32_bits(addr);
*batch++ = upper_32_bits(addr);
*batch++ = lower_32_bits(target_offset);
*batch++ = upper_32_bits(target_offset);
}
} else if (gen >= 6) {
*batch++ = MI_STORE_DWORD_IMM_GEN4;
*batch++ = 0;
*batch++ = addr;
*batch++ = target_offset;
} else if (gen >= 4) {
*batch++ = MI_STORE_DWORD_IMM_GEN4 | MI_USE_GGTT;
*batch++ = 0;
*batch++ = addr;
*batch++ = target_offset;
} else {
*batch++ = MI_STORE_DWORD_IMM | MI_MEM_VIRTUAL;
*batch++ = addr;
*batch++ = target_offset;
/* And again for good measure (blb/pnv) */
*batch++ = MI_STORE_DWORD_IMM | MI_MEM_VIRTUAL;
*batch++ = addr;
*batch++ = target_offset;
}
goto out;
}
repeat:
vaddr = reloc_vaddr(vma->obj, &eb->reloc_cache, offset >> PAGE_SHIFT);
if (IS_ERR(vaddr))
return PTR_ERR(vaddr);
clflush_write32(vaddr + offset_in_page(offset),
lower_32_bits(target_offset),
eb->reloc_cache.vaddr);
if (wide) {
offset += sizeof(u32);
target_offset >>= 32;
wide = false;
goto repeat;
}
out:
return target->node.start | UPDATE;
}
static u64
eb_relocate_entry(struct i915_execbuffer *eb,
struct i915_vma *vma,
const struct drm_i915_gem_relocation_entry *reloc)
{
struct i915_vma *target;
int err;
/* we've already hold a reference to all valid objects */
target = eb_get_vma(eb, reloc->target_handle);
if (unlikely(!target))
return -ENOENT;
/* Validate that the target is in a valid r/w GPU domain */
if (unlikely(reloc->write_domain & (reloc->write_domain - 1))) {
DRM_DEBUG("reloc with multiple write domains: "
"target %d offset %d "
"read %08x write %08x",
reloc->target_handle,
(int) reloc->offset,
reloc->read_domains,
reloc->write_domain);
return -EINVAL;
}
if (unlikely((reloc->write_domain | reloc->read_domains)
& ~I915_GEM_GPU_DOMAINS)) {
DRM_DEBUG("reloc with read/write non-GPU domains: "
"target %d offset %d "
"read %08x write %08x",
reloc->target_handle,
(int) reloc->offset,
reloc->read_domains,
reloc->write_domain);
return -EINVAL;
}
if (reloc->write_domain) {
*target->exec_flags |= EXEC_OBJECT_WRITE;
/*
* Sandybridge PPGTT errata: We need a global gtt mapping
* for MI and pipe_control writes because the gpu doesn't
* properly redirect them through the ppgtt for non_secure
* batchbuffers.
*/
if (reloc->write_domain == I915_GEM_DOMAIN_INSTRUCTION &&
IS_GEN6(eb->i915)) {
err = i915_vma_bind(target, target->obj->cache_level,
PIN_GLOBAL);
if (WARN_ONCE(err,
"Unexpected failure to bind target VMA!"))
return err;
}
}
/*
* If the relocation already has the right value in it, no
* more work needs to be done.
*/
if (!DBG_FORCE_RELOC &&
gen8_canonical_addr(target->node.start) == reloc->presumed_offset)
return 0;
/* Check that the relocation address is valid... */
if (unlikely(reloc->offset >
vma->size - (eb->reloc_cache.use_64bit_reloc ? 8 : 4))) {
DRM_DEBUG("Relocation beyond object bounds: "
"target %d offset %d size %d.\n",
reloc->target_handle,
(int)reloc->offset,
(int)vma->size);
return -EINVAL;
}
if (unlikely(reloc->offset & 3)) {
DRM_DEBUG("Relocation not 4-byte aligned: "
"target %d offset %d.\n",
reloc->target_handle,
(int)reloc->offset);
return -EINVAL;
}
/*
* If we write into the object, we need to force the synchronisation
* barrier, either with an asynchronous clflush or if we executed the
* patching using the GPU (though that should be serialised by the
* timeline). To be completely sure, and since we are required to
* do relocations we are already stalling, disable the user's opt
* out of our synchronisation.
*/
*vma->exec_flags &= ~EXEC_OBJECT_ASYNC;
/* and update the user's relocation entry */
return relocate_entry(vma, reloc, eb, target);
}
static int eb_relocate_vma(struct i915_execbuffer *eb, struct i915_vma *vma)
{
#define N_RELOC(x) ((x) / sizeof(struct drm_i915_gem_relocation_entry))
struct drm_i915_gem_relocation_entry stack[N_RELOC(512)];
struct drm_i915_gem_relocation_entry __user *urelocs;
const struct drm_i915_gem_exec_object2 *entry = exec_entry(eb, vma);
unsigned int remain;
urelocs = u64_to_user_ptr(entry->relocs_ptr);
remain = entry->relocation_count;
if (unlikely(remain > N_RELOC(ULONG_MAX)))
return -EINVAL;
/*
* We must check that the entire relocation array is safe
* to read. However, if the array is not writable the user loses
* the updated relocation values.
*/
if (unlikely(!access_ok(VERIFY_READ, urelocs, remain*sizeof(*urelocs))))
return -EFAULT;
do {
struct drm_i915_gem_relocation_entry *r = stack;
unsigned int count =
min_t(unsigned int, remain, ARRAY_SIZE(stack));
unsigned int copied;
/*
* This is the fast path and we cannot handle a pagefault
* whilst holding the struct mutex lest the user pass in the
* relocations contained within a mmaped bo. For in such a case
* we, the page fault handler would call i915_gem_fault() and
* we would try to acquire the struct mutex again. Obviously
* this is bad and so lockdep complains vehemently.
*/
pagefault_disable();
copied = __copy_from_user_inatomic(r, urelocs, count * sizeof(r[0]));
pagefault_enable();
if (unlikely(copied)) {
remain = -EFAULT;
goto out;
}
remain -= count;
do {
u64 offset = eb_relocate_entry(eb, vma, r);
if (likely(offset == 0)) {
} else if ((s64)offset < 0) {
remain = (int)offset;
goto out;
} else {
/*
* Note that reporting an error now
* leaves everything in an inconsistent
* state as we have *already* changed
* the relocation value inside the
* object. As we have not changed the
* reloc.presumed_offset or will not
* change the execobject.offset, on the
* call we may not rewrite the value
* inside the object, leaving it
* dangling and causing a GPU hang. Unless
* userspace dynamically rebuilds the
* relocations on each execbuf rather than
* presume a static tree.
*
* We did previously check if the relocations
* were writable (access_ok), an error now
* would be a strange race with mprotect,
* having already demonstrated that we
* can read from this userspace address.
*/
offset = gen8_canonical_addr(offset & ~UPDATE);
if (unlikely(__put_user(offset, &urelocs[r-stack].presumed_offset))) {
remain = -EFAULT;
goto out;
}
}
} while (r++, --count);
urelocs += ARRAY_SIZE(stack);
} while (remain);
out:
reloc_cache_reset(&eb->reloc_cache);
return remain;
}
static int
eb_relocate_vma_slow(struct i915_execbuffer *eb, struct i915_vma *vma)
{
const struct drm_i915_gem_exec_object2 *entry = exec_entry(eb, vma);
struct drm_i915_gem_relocation_entry *relocs =
u64_to_ptr(typeof(*relocs), entry->relocs_ptr);
unsigned int i;
int err;
for (i = 0; i < entry->relocation_count; i++) {
u64 offset = eb_relocate_entry(eb, vma, &relocs[i]);
if ((s64)offset < 0) {
err = (int)offset;
goto err;
}
}
err = 0;
err:
reloc_cache_reset(&eb->reloc_cache);
return err;
}
static int check_relocations(const struct drm_i915_gem_exec_object2 *entry)
{
const char __user *addr, *end;
unsigned long size;
char __maybe_unused c;
size = entry->relocation_count;
if (size == 0)
return 0;
if (size > N_RELOC(ULONG_MAX))
return -EINVAL;
addr = u64_to_user_ptr(entry->relocs_ptr);
size *= sizeof(struct drm_i915_gem_relocation_entry);
if (!access_ok(VERIFY_READ, addr, size))
return -EFAULT;
end = addr + size;
for (; addr < end; addr += PAGE_SIZE) {
int err = __get_user(c, addr);
if (err)
return err;
}
return __get_user(c, end - 1);
}
static int eb_copy_relocations(const struct i915_execbuffer *eb)
{
const unsigned int count = eb->buffer_count;
unsigned int i;
int err;
for (i = 0; i < count; i++) {
const unsigned int nreloc = eb->exec[i].relocation_count;
struct drm_i915_gem_relocation_entry __user *urelocs;
struct drm_i915_gem_relocation_entry *relocs;
unsigned long size;
unsigned long copied;
if (nreloc == 0)
continue;
err = check_relocations(&eb->exec[i]);
if (err)
goto err;
urelocs = u64_to_user_ptr(eb->exec[i].relocs_ptr);
size = nreloc * sizeof(*relocs);
relocs = kvmalloc_array(size, 1, GFP_KERNEL);
if (!relocs) {
err = -ENOMEM;
goto err;
}
/* copy_from_user is limited to < 4GiB */
copied = 0;
do {
unsigned int len =
min_t(u64, BIT_ULL(31), size - copied);
if (__copy_from_user((char *)relocs + copied,
(char __user *)urelocs + copied,
len)) {
end_user:
kvfree(relocs);
err = -EFAULT;
goto err;
}
copied += len;
} while (copied < size);
/*
* As we do not update the known relocation offsets after
* relocating (due to the complexities in lock handling),
* we need to mark them as invalid now so that we force the
* relocation processing next time. Just in case the target
* object is evicted and then rebound into its old
* presumed_offset before the next execbuffer - if that
* happened we would make the mistake of assuming that the
* relocations were valid.
*/
user_access_begin();
for (copied = 0; copied < nreloc; copied++)
unsafe_put_user(-1,
&urelocs[copied].presumed_offset,
end_user);
user_access_end();
eb->exec[i].relocs_ptr = (uintptr_t)relocs;
}
return 0;
err:
while (i--) {
struct drm_i915_gem_relocation_entry *relocs =
u64_to_ptr(typeof(*relocs), eb->exec[i].relocs_ptr);
if (eb->exec[i].relocation_count)
kvfree(relocs);
}
return err;
}
static int eb_prefault_relocations(const struct i915_execbuffer *eb)
{
const unsigned int count = eb->buffer_count;
unsigned int i;
if (unlikely(i915_modparams.prefault_disable))
return 0;
for (i = 0; i < count; i++) {
int err;
err = check_relocations(&eb->exec[i]);
if (err)
return err;
}
return 0;
}
static noinline int eb_relocate_slow(struct i915_execbuffer *eb)
{
struct drm_device *dev = &eb->i915->drm;
bool have_copy = false;
struct i915_vma *vma;
int err = 0;
repeat:
if (signal_pending(current)) {
err = -ERESTARTSYS;
goto out;
}
/* We may process another execbuffer during the unlock... */
eb_reset_vmas(eb);
mutex_unlock(&dev->struct_mutex);
/*
* We take 3 passes through the slowpatch.
*
* 1 - we try to just prefault all the user relocation entries and
* then attempt to reuse the atomic pagefault disabled fast path again.
*
* 2 - we copy the user entries to a local buffer here outside of the
* local and allow ourselves to wait upon any rendering before
* relocations
*
* 3 - we already have a local copy of the relocation entries, but
* were interrupted (EAGAIN) whilst waiting for the objects, try again.
*/
if (!err) {
err = eb_prefault_relocations(eb);
} else if (!have_copy) {
err = eb_copy_relocations(eb);
have_copy = err == 0;
} else {
cond_resched();
err = 0;
}
if (err) {
mutex_lock(&dev->struct_mutex);
goto out;
}
/* A frequent cause for EAGAIN are currently unavailable client pages */
flush_workqueue(eb->i915->mm.userptr_wq);
err = i915_mutex_lock_interruptible(dev);
if (err) {
mutex_lock(&dev->struct_mutex);
goto out;
}
/* reacquire the objects */
err = eb_lookup_vmas(eb);
if (err)
goto err;
GEM_BUG_ON(!eb->batch);
list_for_each_entry(vma, &eb->relocs, reloc_link) {
if (!have_copy) {
pagefault_disable();
err = eb_relocate_vma(eb, vma);
pagefault_enable();
if (err)
goto repeat;
} else {
err = eb_relocate_vma_slow(eb, vma);
if (err)
goto err;
}
}
/*
* Leave the user relocations as are, this is the painfully slow path,
* and we want to avoid the complication of dropping the lock whilst
* having buffers reserved in the aperture and so causing spurious
* ENOSPC for random operations.
*/
err:
if (err == -EAGAIN)
goto repeat;
out:
if (have_copy) {
const unsigned int count = eb->buffer_count;
unsigned int i;
for (i = 0; i < count; i++) {
const struct drm_i915_gem_exec_object2 *entry =
&eb->exec[i];
struct drm_i915_gem_relocation_entry *relocs;
if (!entry->relocation_count)
continue;
relocs = u64_to_ptr(typeof(*relocs), entry->relocs_ptr);
kvfree(relocs);
}
}
return err;
}
static int eb_relocate(struct i915_execbuffer *eb)
{
if (eb_lookup_vmas(eb))
goto slow;
/* The objects are in their final locations, apply the relocations. */
if (eb->args->flags & __EXEC_HAS_RELOC) {
struct i915_vma *vma;
list_for_each_entry(vma, &eb->relocs, reloc_link) {
if (eb_relocate_vma(eb, vma))
goto slow;
}
}
return 0;
slow:
return eb_relocate_slow(eb);
}
static int eb_move_to_gpu(struct i915_execbuffer *eb)
{
const unsigned int count = eb->buffer_count;
unsigned int i;
int err;
for (i = 0; i < count; i++) {
unsigned int flags = eb->flags[i];
struct i915_vma *vma = eb->vma[i];
struct drm_i915_gem_object *obj = vma->obj;
if (flags & EXEC_OBJECT_CAPTURE) {
struct i915_capture_list *capture;
capture = kmalloc(sizeof(*capture), GFP_KERNEL);
if (unlikely(!capture))
return -ENOMEM;
capture->next = eb->request->capture_list;
capture->vma = eb->vma[i];
eb->request->capture_list = capture;
}
/*
* If the GPU is not _reading_ through the CPU cache, we need
* to make sure that any writes (both previous GPU writes from
* before a change in snooping levels and normal CPU writes)
* caught in that cache are flushed to main memory.
*
* We want to say
* obj->cache_dirty &&
* !(obj->cache_coherent & I915_BO_CACHE_COHERENT_FOR_READ)
* but gcc's optimiser doesn't handle that as well and emits
* two jumps instead of one. Maybe one day...
*/
if (unlikely(obj->cache_dirty & ~obj->cache_coherent)) {
if (i915_gem_clflush_object(obj, 0))
flags &= ~EXEC_OBJECT_ASYNC;
}
if (flags & EXEC_OBJECT_ASYNC)
continue;
err = i915_request_await_object
(eb->request, obj, flags & EXEC_OBJECT_WRITE);
if (err)
return err;
}
for (i = 0; i < count; i++) {
unsigned int flags = eb->flags[i];
struct i915_vma *vma = eb->vma[i];
err = i915_vma_move_to_active(vma, eb->request, flags);
if (unlikely(err)) {
i915_request_skip(eb->request, err);
return err;
}
__eb_unreserve_vma(vma, flags);
vma->exec_flags = NULL;
if (unlikely(flags & __EXEC_OBJECT_HAS_REF))
i915_vma_put(vma);
}
eb->exec = NULL;
/* Unconditionally flush any chipset caches (for streaming writes). */
i915_gem_chipset_flush(eb->i915);
return 0;
}
static bool i915_gem_check_execbuffer(struct drm_i915_gem_execbuffer2 *exec)
{
if (exec->flags & __I915_EXEC_ILLEGAL_FLAGS)
return false;
/* Kernel clipping was a DRI1 misfeature */
if (!(exec->flags & I915_EXEC_FENCE_ARRAY)) {
if (exec->num_cliprects || exec->cliprects_ptr)
return false;
}
if (exec->DR4 == 0xffffffff) {
DRM_DEBUG("UXA submitting garbage DR4, fixing up\n");
exec->DR4 = 0;
}
if (exec->DR1 || exec->DR4)
return false;
if ((exec->batch_start_offset | exec->batch_len) & 0x7)
return false;
return true;
}
static int i915_reset_gen7_sol_offsets(struct i915_request *rq)
{
u32 *cs;
int i;
if (!IS_GEN7(rq->i915) || rq->engine->id != RCS) {
DRM_DEBUG("sol reset is gen7/rcs only\n");
return -EINVAL;
}
cs = intel_ring_begin(rq, 4 * 2 + 2);
if (IS_ERR(cs))
return PTR_ERR(cs);
*cs++ = MI_LOAD_REGISTER_IMM(4);
for (i = 0; i < 4; i++) {
*cs++ = i915_mmio_reg_offset(GEN7_SO_WRITE_OFFSET(i));
*cs++ = 0;
}
*cs++ = MI_NOOP;
intel_ring_advance(rq, cs);
return 0;
}
static struct i915_vma *eb_parse(struct i915_execbuffer *eb, bool is_master)
{
struct drm_i915_gem_object *shadow_batch_obj;
struct i915_vma *vma;
int err;
shadow_batch_obj = i915_gem_batch_pool_get(&eb->engine->batch_pool,
PAGE_ALIGN(eb->batch_len));
if (IS_ERR(shadow_batch_obj))
return ERR_CAST(shadow_batch_obj);
err = intel_engine_cmd_parser(eb->engine,
eb->batch->obj,
shadow_batch_obj,
eb->batch_start_offset,
eb->batch_len,
is_master);
if (err) {
if (err == -EACCES) /* unhandled chained batch */
vma = NULL;
else
vma = ERR_PTR(err);
goto out;
}
vma = i915_gem_object_ggtt_pin(shadow_batch_obj, NULL, 0, 0, 0);
if (IS_ERR(vma))
goto out;
eb->vma[eb->buffer_count] = i915_vma_get(vma);
eb->flags[eb->buffer_count] =
__EXEC_OBJECT_HAS_PIN | __EXEC_OBJECT_HAS_REF;
vma->exec_flags = &eb->flags[eb->buffer_count];
eb->buffer_count++;
out:
i915_gem_object_unpin_pages(shadow_batch_obj);
return vma;
}
static void
add_to_client(struct i915_request *rq, struct drm_file *file)
{
rq->file_priv = file->driver_priv;
list_add_tail(&rq->client_link, &rq->file_priv->mm.request_list);
}
static int eb_submit(struct i915_execbuffer *eb)
{
int err;
err = eb_move_to_gpu(eb);
if (err)
return err;
if (eb->args->flags & I915_EXEC_GEN7_SOL_RESET) {
err = i915_reset_gen7_sol_offsets(eb->request);
if (err)
return err;
}
err = eb->engine->emit_bb_start(eb->request,
eb->batch->node.start +
eb->batch_start_offset,
eb->batch_len,
eb->batch_flags);
if (err)
return err;
return 0;
}
/*
* Find one BSD ring to dispatch the corresponding BSD command.
* The engine index is returned.
*/
static unsigned int
gen8_dispatch_bsd_engine(struct drm_i915_private *dev_priv,
struct drm_file *file)
{
struct drm_i915_file_private *file_priv = file->driver_priv;
/* Check whether the file_priv has already selected one ring. */
if ((int)file_priv->bsd_engine < 0)
file_priv->bsd_engine = atomic_fetch_xor(1,
&dev_priv->mm.bsd_engine_dispatch_index);
return file_priv->bsd_engine;
}
#define I915_USER_RINGS (4)
static const enum intel_engine_id user_ring_map[I915_USER_RINGS + 1] = {
[I915_EXEC_DEFAULT] = RCS,
[I915_EXEC_RENDER] = RCS,
[I915_EXEC_BLT] = BCS,
[I915_EXEC_BSD] = VCS,
[I915_EXEC_VEBOX] = VECS
};
static struct intel_engine_cs *
eb_select_engine(struct drm_i915_private *dev_priv,
struct drm_file *file,
struct drm_i915_gem_execbuffer2 *args)
{
unsigned int user_ring_id = args->flags & I915_EXEC_RING_MASK;
struct intel_engine_cs *engine;
if (user_ring_id > I915_USER_RINGS) {
DRM_DEBUG("execbuf with unknown ring: %u\n", user_ring_id);
return NULL;
}
if ((user_ring_id != I915_EXEC_BSD) &&
((args->flags & I915_EXEC_BSD_MASK) != 0)) {
DRM_DEBUG("execbuf with non bsd ring but with invalid "
"bsd dispatch flags: %d\n", (int)(args->flags));
return NULL;
}
if (user_ring_id == I915_EXEC_BSD && HAS_BSD2(dev_priv)) {
unsigned int bsd_idx = args->flags & I915_EXEC_BSD_MASK;
if (bsd_idx == I915_EXEC_BSD_DEFAULT) {
bsd_idx = gen8_dispatch_bsd_engine(dev_priv, file);
} else if (bsd_idx >= I915_EXEC_BSD_RING1 &&
bsd_idx <= I915_EXEC_BSD_RING2) {
bsd_idx >>= I915_EXEC_BSD_SHIFT;
bsd_idx--;
} else {
DRM_DEBUG("execbuf with unknown bsd ring: %u\n",
bsd_idx);
return NULL;
}
engine = dev_priv->engine[_VCS(bsd_idx)];
} else {
engine = dev_priv->engine[user_ring_map[user_ring_id]];
}
if (!engine) {
DRM_DEBUG("execbuf with invalid ring: %u\n", user_ring_id);
return NULL;
}
return engine;
}
static void
__free_fence_array(struct drm_syncobj **fences, unsigned int n)
{
while (n--)
drm_syncobj_put(ptr_mask_bits(fences[n], 2));
kvfree(fences);
}
static struct drm_syncobj **
get_fence_array(struct drm_i915_gem_execbuffer2 *args,
struct drm_file *file)
{
const unsigned long nfences = args->num_cliprects;
struct drm_i915_gem_exec_fence __user *user;
struct drm_syncobj **fences;
unsigned long n;
int err;
if (!(args->flags & I915_EXEC_FENCE_ARRAY))
return NULL;
/* Check multiplication overflow for access_ok() and kvmalloc_array() */
BUILD_BUG_ON(sizeof(size_t) > sizeof(unsigned long));
if (nfences > min_t(unsigned long,
ULONG_MAX / sizeof(*user),
SIZE_MAX / sizeof(*fences)))
return ERR_PTR(-EINVAL);
user = u64_to_user_ptr(args->cliprects_ptr);
if (!access_ok(VERIFY_READ, user, nfences * sizeof(*user)))
return ERR_PTR(-EFAULT);
fences = kvmalloc_array(nfences, sizeof(*fences),
__GFP_NOWARN | GFP_KERNEL);
if (!fences)
return ERR_PTR(-ENOMEM);
for (n = 0; n < nfences; n++) {
struct drm_i915_gem_exec_fence fence;
struct drm_syncobj *syncobj;
if (__copy_from_user(&fence, user++, sizeof(fence))) {
err = -EFAULT;
goto err;
}
if (fence.flags & __I915_EXEC_FENCE_UNKNOWN_FLAGS) {
err = -EINVAL;
goto err;
}
syncobj = drm_syncobj_find(file, fence.handle);
if (!syncobj) {
DRM_DEBUG("Invalid syncobj handle provided\n");
err = -ENOENT;
goto err;
}
BUILD_BUG_ON(~(ARCH_KMALLOC_MINALIGN - 1) &
~__I915_EXEC_FENCE_UNKNOWN_FLAGS);
fences[n] = ptr_pack_bits(syncobj, fence.flags, 2);
}
return fences;
err:
__free_fence_array(fences, n);
return ERR_PTR(err);
}
static void
put_fence_array(struct drm_i915_gem_execbuffer2 *args,
struct drm_syncobj **fences)
{
if (fences)
__free_fence_array(fences, args->num_cliprects);
}
static int
await_fence_array(struct i915_execbuffer *eb,
struct drm_syncobj **fences)
{
const unsigned int nfences = eb->args->num_cliprects;
unsigned int n;
int err;
for (n = 0; n < nfences; n++) {
struct drm_syncobj *syncobj;
struct dma_fence *fence;
unsigned int flags;
syncobj = ptr_unpack_bits(fences[n], &flags, 2);
if (!(flags & I915_EXEC_FENCE_WAIT))
continue;
fence = drm_syncobj_fence_get(syncobj);
if (!fence)
return -EINVAL;
err = i915_request_await_dma_fence(eb->request, fence);
dma_fence_put(fence);
if (err < 0)
return err;
}
return 0;
}
static void
signal_fence_array(struct i915_execbuffer *eb,
struct drm_syncobj **fences)
{
const unsigned int nfences = eb->args->num_cliprects;
struct dma_fence * const fence = &eb->request->fence;
unsigned int n;
for (n = 0; n < nfences; n++) {
struct drm_syncobj *syncobj;
unsigned int flags;
syncobj = ptr_unpack_bits(fences[n], &flags, 2);
if (!(flags & I915_EXEC_FENCE_SIGNAL))
continue;
drm_syncobj_replace_fence(syncobj, fence);
}
}
static int
i915_gem_do_execbuffer(struct drm_device *dev,
struct drm_file *file,
struct drm_i915_gem_execbuffer2 *args,
struct drm_i915_gem_exec_object2 *exec,
struct drm_syncobj **fences)
{
struct i915_execbuffer eb;
struct dma_fence *in_fence = NULL;
struct sync_file *out_fence = NULL;
int out_fence_fd = -1;
int err;
BUILD_BUG_ON(__EXEC_INTERNAL_FLAGS & ~__I915_EXEC_ILLEGAL_FLAGS);
BUILD_BUG_ON(__EXEC_OBJECT_INTERNAL_FLAGS &
~__EXEC_OBJECT_UNKNOWN_FLAGS);
eb.i915 = to_i915(dev);
eb.file = file;
eb.args = args;
if (DBG_FORCE_RELOC || !(args->flags & I915_EXEC_NO_RELOC))
args->flags |= __EXEC_HAS_RELOC;
eb.exec = exec;
eb.vma = (struct i915_vma **)(exec + args->buffer_count + 1);
eb.vma[0] = NULL;
eb.flags = (unsigned int *)(eb.vma + args->buffer_count + 1);
eb.invalid_flags = __EXEC_OBJECT_UNKNOWN_FLAGS;
reloc_cache_init(&eb.reloc_cache, eb.i915);
eb.buffer_count = args->buffer_count;
eb.batch_start_offset = args->batch_start_offset;
eb.batch_len = args->batch_len;
eb.batch_flags = 0;
if (args->flags & I915_EXEC_SECURE) {
if (!drm_is_current_master(file) || !capable(CAP_SYS_ADMIN))
return -EPERM;
eb.batch_flags |= I915_DISPATCH_SECURE;
}
if (args->flags & I915_EXEC_IS_PINNED)
eb.batch_flags |= I915_DISPATCH_PINNED;
eb.engine = eb_select_engine(eb.i915, file, args);
if (!eb.engine)
return -EINVAL;
if (args->flags & I915_EXEC_FENCE_IN) {
in_fence = sync_file_get_fence(lower_32_bits(args->rsvd2));
if (!in_fence)
return -EINVAL;
}
if (args->flags & I915_EXEC_FENCE_OUT) {
out_fence_fd = get_unused_fd_flags(O_CLOEXEC);
if (out_fence_fd < 0) {
err = out_fence_fd;
goto err_in_fence;
}
}
err = eb_create(&eb);
if (err)
goto err_out_fence;
GEM_BUG_ON(!eb.lut_size);
err = eb_select_context(&eb);
if (unlikely(err))
goto err_destroy;
/*
* Take a local wakeref for preparing to dispatch the execbuf as
* we expect to access the hardware fairly frequently in the
* process. Upon first dispatch, we acquire another prolonged
* wakeref that we hold until the GPU has been idle for at least
* 100ms.
*/
intel_runtime_pm_get(eb.i915);
err = i915_mutex_lock_interruptible(dev);
if (err)
goto err_rpm;
err = eb_relocate(&eb);
if (err) {
/*
* If the user expects the execobject.offset and
* reloc.presumed_offset to be an exact match,
* as for using NO_RELOC, then we cannot update
* the execobject.offset until we have completed
* relocation.
*/
args->flags &= ~__EXEC_HAS_RELOC;
goto err_vma;
}
if (unlikely(*eb.batch->exec_flags & EXEC_OBJECT_WRITE)) {
DRM_DEBUG("Attempting to use self-modifying batch buffer\n");
err = -EINVAL;
goto err_vma;
}
if (eb.batch_start_offset > eb.batch->size ||
eb.batch_len > eb.batch->size - eb.batch_start_offset) {
DRM_DEBUG("Attempting to use out-of-bounds batch\n");
err = -EINVAL;
goto err_vma;
}
if (eb_use_cmdparser(&eb)) {
struct i915_vma *vma;
vma = eb_parse(&eb, drm_is_current_master(file));
if (IS_ERR(vma)) {
err = PTR_ERR(vma);
goto err_vma;
}
if (vma) {
/*
* Batch parsed and accepted:
*
* Set the DISPATCH_SECURE bit to remove the NON_SECURE
* bit from MI_BATCH_BUFFER_START commands issued in
* the dispatch_execbuffer implementations. We
* specifically don't want that set on batches the
* command parser has accepted.
*/
eb.batch_flags |= I915_DISPATCH_SECURE;
eb.batch_start_offset = 0;
eb.batch = vma;
}
}
if (eb.batch_len == 0)
eb.batch_len = eb.batch->size - eb.batch_start_offset;
/*
* snb/ivb/vlv conflate the "batch in ppgtt" bit with the "non-secure
* batch" bit. Hence we need to pin secure batches into the global gtt.
* hsw should have this fixed, but bdw mucks it up again. */
if (eb.batch_flags & I915_DISPATCH_SECURE) {
struct i915_vma *vma;
/*
* So on first glance it looks freaky that we pin the batch here
* outside of the reservation loop. But:
* - The batch is already pinned into the relevant ppgtt, so we
* already have the backing storage fully allocated.
* - No other BO uses the global gtt (well contexts, but meh),
* so we don't really have issues with multiple objects not
* fitting due to fragmentation.
* So this is actually safe.
*/
vma = i915_gem_object_ggtt_pin(eb.batch->obj, NULL, 0, 0, 0);
if (IS_ERR(vma)) {
err = PTR_ERR(vma);
goto err_vma;
}
eb.batch = vma;
}
/* All GPU relocation batches must be submitted prior to the user rq */
GEM_BUG_ON(eb.reloc_cache.rq);
/* Allocate a request for this batch buffer nice and early. */
eb.request = i915_request_alloc(eb.engine, eb.ctx);
if (IS_ERR(eb.request)) {
err = PTR_ERR(eb.request);
goto err_batch_unpin;
}
if (in_fence) {
err = i915_request_await_dma_fence(eb.request, in_fence);
if (err < 0)
goto err_request;
}
if (fences) {
err = await_fence_array(&eb, fences);
if (err)
goto err_request;
}
if (out_fence_fd != -1) {
out_fence = sync_file_create(&eb.request->fence);
if (!out_fence) {
err = -ENOMEM;
goto err_request;
}
}
/*
* Whilst this request exists, batch_obj will be on the
* active_list, and so will hold the active reference. Only when this
* request is retired will the the batch_obj be moved onto the
* inactive_list and lose its active reference. Hence we do not need
* to explicitly hold another reference here.
*/
eb.request->batch = eb.batch;
trace_i915_request_queue(eb.request, eb.batch_flags);
err = eb_submit(&eb);
err_request:
i915_request_add(eb.request);
add_to_client(eb.request, file);
if (fences)
signal_fence_array(&eb, fences);
if (out_fence) {
if (err == 0) {
fd_install(out_fence_fd, out_fence->file);
args->rsvd2 &= GENMASK_ULL(31, 0); /* keep in-fence */
args->rsvd2 |= (u64)out_fence_fd << 32;
out_fence_fd = -1;
} else {
fput(out_fence->file);
}
}
err_batch_unpin:
if (eb.batch_flags & I915_DISPATCH_SECURE)
i915_vma_unpin(eb.batch);
err_vma:
if (eb.exec)
eb_release_vmas(&eb);
mutex_unlock(&dev->struct_mutex);
err_rpm:
intel_runtime_pm_put(eb.i915);
i915_gem_context_put(eb.ctx);
err_destroy:
eb_destroy(&eb);
err_out_fence:
if (out_fence_fd != -1)
put_unused_fd(out_fence_fd);
err_in_fence:
dma_fence_put(in_fence);
return err;
}
static size_t eb_element_size(void)
{
return (sizeof(struct drm_i915_gem_exec_object2) +
sizeof(struct i915_vma *) +
sizeof(unsigned int));
}
static bool check_buffer_count(size_t count)
{
const size_t sz = eb_element_size();
/*
* When using LUT_HANDLE, we impose a limit of INT_MAX for the lookup
* array size (see eb_create()). Otherwise, we can accept an array as
* large as can be addressed (though use large arrays at your peril)!
*/
return !(count < 1 || count > INT_MAX || count > SIZE_MAX / sz - 1);
}
/*
* Legacy execbuffer just creates an exec2 list from the original exec object
* list array and passes it to the real function.
*/
int
i915_gem_execbuffer_ioctl(struct drm_device *dev, void *data,
struct drm_file *file)
{
struct drm_i915_gem_execbuffer *args = data;
struct drm_i915_gem_execbuffer2 exec2;
struct drm_i915_gem_exec_object *exec_list = NULL;
struct drm_i915_gem_exec_object2 *exec2_list = NULL;
const size_t count = args->buffer_count;
unsigned int i;
int err;
if (!check_buffer_count(count)) {
DRM_DEBUG("execbuf2 with %zd buffers\n", count);
return -EINVAL;
}
exec2.buffers_ptr = args->buffers_ptr;
exec2.buffer_count = args->buffer_count;
exec2.batch_start_offset = args->batch_start_offset;
exec2.batch_len = args->batch_len;
exec2.DR1 = args->DR1;
exec2.DR4 = args->DR4;
exec2.num_cliprects = args->num_cliprects;
exec2.cliprects_ptr = args->cliprects_ptr;
exec2.flags = I915_EXEC_RENDER;
i915_execbuffer2_set_context_id(exec2, 0);
if (!i915_gem_check_execbuffer(&exec2))
return -EINVAL;
/* Copy in the exec list from userland */
exec_list = kvmalloc_array(count, sizeof(*exec_list),
__GFP_NOWARN | GFP_KERNEL);
exec2_list = kvmalloc_array(count + 1, eb_element_size(),
__GFP_NOWARN | GFP_KERNEL);
if (exec_list == NULL || exec2_list == NULL) {
DRM_DEBUG("Failed to allocate exec list for %d buffers\n",
args->buffer_count);
kvfree(exec_list);
kvfree(exec2_list);
return -ENOMEM;
}
err = copy_from_user(exec_list,
u64_to_user_ptr(args->buffers_ptr),
sizeof(*exec_list) * count);
if (err) {
DRM_DEBUG("copy %d exec entries failed %d\n",
args->buffer_count, err);
kvfree(exec_list);
kvfree(exec2_list);
return -EFAULT;
}
for (i = 0; i < args->buffer_count; i++) {
exec2_list[i].handle = exec_list[i].handle;
exec2_list[i].relocation_count = exec_list[i].relocation_count;
exec2_list[i].relocs_ptr = exec_list[i].relocs_ptr;
exec2_list[i].alignment = exec_list[i].alignment;
exec2_list[i].offset = exec_list[i].offset;
if (INTEL_GEN(to_i915(dev)) < 4)
exec2_list[i].flags = EXEC_OBJECT_NEEDS_FENCE;
else
exec2_list[i].flags = 0;
}
err = i915_gem_do_execbuffer(dev, file, &exec2, exec2_list, NULL);
if (exec2.flags & __EXEC_HAS_RELOC) {
struct drm_i915_gem_exec_object __user *user_exec_list =
u64_to_user_ptr(args->buffers_ptr);
/* Copy the new buffer offsets back to the user's exec list. */
for (i = 0; i < args->buffer_count; i++) {
if (!(exec2_list[i].offset & UPDATE))
continue;
exec2_list[i].offset =
gen8_canonical_addr(exec2_list[i].offset & PIN_OFFSET_MASK);
exec2_list[i].offset &= PIN_OFFSET_MASK;
if (__copy_to_user(&user_exec_list[i].offset,
&exec2_list[i].offset,
sizeof(user_exec_list[i].offset)))
break;
}
}
kvfree(exec_list);
kvfree(exec2_list);
return err;
}
int
i915_gem_execbuffer2_ioctl(struct drm_device *dev, void *data,
struct drm_file *file)
{
struct drm_i915_gem_execbuffer2 *args = data;
struct drm_i915_gem_exec_object2 *exec2_list;
struct drm_syncobj **fences = NULL;
const size_t count = args->buffer_count;
int err;
if (!check_buffer_count(count)) {
DRM_DEBUG("execbuf2 with %zd buffers\n", count);
return -EINVAL;
}
if (!i915_gem_check_execbuffer(args))
return -EINVAL;
/* Allocate an extra slot for use by the command parser */
exec2_list = kvmalloc_array(count + 1, eb_element_size(),
__GFP_NOWARN | GFP_KERNEL);
if (exec2_list == NULL) {
DRM_DEBUG("Failed to allocate exec list for %zd buffers\n",
count);
return -ENOMEM;
}
if (copy_from_user(exec2_list,
u64_to_user_ptr(args->buffers_ptr),
sizeof(*exec2_list) * count)) {
DRM_DEBUG("copy %zd exec entries failed\n", count);
kvfree(exec2_list);
return -EFAULT;
}
if (args->flags & I915_EXEC_FENCE_ARRAY) {
fences = get_fence_array(args, file);
if (IS_ERR(fences)) {
kvfree(exec2_list);
return PTR_ERR(fences);
}
}
err = i915_gem_do_execbuffer(dev, file, args, exec2_list, fences);
/*
* Now that we have begun execution of the batchbuffer, we ignore
* any new error after this point. Also given that we have already
* updated the associated relocations, we try to write out the current
* object locations irrespective of any error.
*/
if (args->flags & __EXEC_HAS_RELOC) {
struct drm_i915_gem_exec_object2 __user *user_exec_list =
u64_to_user_ptr(args->buffers_ptr);
unsigned int i;
/* Copy the new buffer offsets back to the user's exec list. */
user_access_begin();
for (i = 0; i < args->buffer_count; i++) {
if (!(exec2_list[i].offset & UPDATE))
continue;
exec2_list[i].offset =
gen8_canonical_addr(exec2_list[i].offset & PIN_OFFSET_MASK);
unsafe_put_user(exec2_list[i].offset,
&user_exec_list[i].offset,
end_user);
}
end_user:
user_access_end();
}
args->flags &= ~__I915_EXEC_UNKNOWN_FLAGS;
put_fence_array(args, fences);
kvfree(exec2_list);
return err;
}