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240 lines
11 KiB
C
240 lines
11 KiB
C
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/*******************************************************************************
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Copyright (c) 2015 NVIDIA Corporation
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Permission is hereby granted, free of charge, to any person obtaining a copy
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of this software and associated documentation files (the "Software"), to
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deal in the Software without restriction, including without limitation the
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rights to use, copy, modify, merge, publish, distribute, sublicense, and/or
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sell copies of the Software, and to permit persons to whom the Software is
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furnished to do so, subject to the following conditions:
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The above copyright notice and this permission notice shall be
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included in all copies or substantial portions of the Software.
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THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
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IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
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FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
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THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
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LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
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FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER
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DEALINGS IN THE SOFTWARE.
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*******************************************************************************/
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#ifndef __UVM_PUSHBUFFER_H__
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#define __UVM_PUSHBUFFER_H__
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#include "uvm_forward_decl.h"
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#include "uvm_lock.h"
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#include "uvm_linux.h"
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#include "nvtypes.h"
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//
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// UVM pushbuffer
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//
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// The UVM pushbuffer is a memory allocator specialized for managing allocations
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// used as the backing store for methods sent to the GPU (pushes, abstracted by
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// uvm_push_t). Each pushbuffer is usable only with a specific channel manager
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// and hence a specific GPU as that allows for greater flexibility down the road
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// (e.g. moving the pushbuffer allocation to GPU memory in some cases).
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//
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// The usage of the pushbuffer always follows the same pattern:
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// 1) The CPU requests a new allocation to do a push in. The allocation is
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// always initially of UVM_MAX_PUSH_SIZE and its usage is tracked by the
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// UVM push abstraction (uvm_push_t).
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// 2) The CPU writes some GPU methods
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// 3) The CPU finishes and reports how much of the UVM_MAX_PUSH_SIZE space was used
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// 4) The methods are queued to be read by the GPU (by referencing them in a GPFIFO entry)
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// 5) At some later time the CPU notices the methods have been completed and
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// reports that the allocation can now be reused.
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//
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// Notably 1) could happen concurrently from multiple CPU threads and in 4) the
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// GPU has multiple independent queues of execution (UVM channels).
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//
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// With the above in mind, we can go through the implementation details of the
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// current solution.
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// The pushbuffer backing store is a single big allocation logically divided
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// into largely independent parts called chunks.
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// Each chunk is roughly a ringbuffer tracking multiple pending pushes being
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// processed by the GPU. The pushbuffer maintains two bitmaps, one tracking
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// completely idle (with no pending pushes) chunks and a second one tracking
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// available (with pending pushes, but still enough space for a new push)
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// chunks. When a new allocation is requested, idle chunks are always used
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// first and after that available chunks are consulted. If none are available,
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// the CPU spin waits on the GPU to complete some of the pending pushes making
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// space for a new one.
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//
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// To explain how chunks track pending pushes we will go through an example
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// modifying a chunk's state. Let's start with a few pending pushes in the
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// chunk:
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//
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// [ [push P1][push P2][free unusable space][push P3][push P4] ]
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// ^ gpu_get ^ cpu_put
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//
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// The beginning of the first pending push is called the GPU get and the end of the
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// last push is called the CPU put. This follows the HW GPFIFO naming that's a true
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// ringbuffer (always completing in order and supporting transparent
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// wrap-around). All the memory between gpu_get and cpu_put is considered
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// unusable. Pushes within a chunk can finish out of order as each chunk can
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// service pushes from multiple channels. And hence there can be some space
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// between the first and last push that's already free, but unusable. The space
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// after cpu_put and before gpu_get is available to be allocated to a new push,
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// and if that happens the chunk above could change to:
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//
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// [ [push P1][push P2][free unusable space][push P3][push P4][push P5] ]
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// ^ gpu_get ^ cpu_put
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//
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// Then, say push P2 completes:
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//
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// [ [push P1][free unusable space ][push P3][push P4][push P5] ]
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// ^ gpu_get ^ cpu_put
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//
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// We can see that P2 completing only expands the unusable free space, but if P1
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// finishes we get:
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//
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// [ [push P3][push P4][push P5] ]
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// ^ gpu_get ^ cpu_put
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//
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// This shows that some cases cause waste, but on the other hand allow for
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// tracking of pending pushes and free space to be trivial. Each pending push of
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// a chunk is in a doubly linked list with its head in the chunk. Each new push
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// is added at the tail and when a push completes it's removed from the list.
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// The gpu_get and/or cpu_put only change when the last/first push in the
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// list finishes or a new push is added. The pending pushes are represented by
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// the software state tracking GPFIFO entries (uvm_gpfifo_entry_t in
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// uvm_channel.h) that are all allocated at channel creation (a HW channel has
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// a fixed limit of GPFIFO entries it supports that's chosen at channel creation
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// and we allocate all the SW state for them at channel creation as well). This
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// allows all the operations of the pushbuffer to be free of any memory
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// allocation.
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//
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// To illustrate that a chunk is only roughly a ringbuffer, let's see what
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// happens when another push is added to the chunk above, but there is not
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// enough space between cpu_put and the end of the chunk to fit UVM_MAX_PUSH_SIZE:
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// [[push P6][free space ][push P3][push P4][push P5] ]
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// ^ cpu_put ^ gpu_get
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//
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// The GPU reading the pushbuffer expects it to be in a consecutive VA and hence
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// the pending pushes cannot wrap around in the chunk leading to some potential
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// waste at the end.
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//
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// The pushbuffer implementation is configurable through a few defines below,
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// but careful tweaking of them is yet to be done.
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//
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// TODO: Bug 1764958: Calculate/measure the maximum push size and tweak the
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// number of chunks and size of each after benchmarks.
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//
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// Below are the measurements borrowed from uvm_channel_mgmt.h. They will need
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// to be adjusted and verified once all the operations are implemented in this
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// driver, but for now we will set the MAX_PUSH to 128K as that seems pretty
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// safe.
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//
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// A pushbuffer needs to accomodate all possible operations on a 2 Mb Va region
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// per gpu. The longest sequence of operations would be:
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// Acquire 3 + 32 trackers:
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// replay tracker, instancePtr tracker, 2Mb descriptor tracker and 32 trackers
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// one each for 64Kb of phys mem.
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// Each tracker can have ~64 tracker items (35 x 64 x 20 bytes acquire = 45k)
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// Unmap 4k ptes for 2Mb va (Inline pte data + header = ~4k)
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// Invalidate for every 4k (512 * 20 bytes = 10k)
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// Migrate data worth 2 Mb (512 * 48 bytes to do copy = 24k)
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// Map 4k ptes for 2Mb va (4k inline pte data + header = ~4k)
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// Invalidate for every 4k (512 * 20 bytes = 10k)
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// Total Total= ~100k
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//
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#define UVM_MAX_PUSH_SIZE (128 * 1024)
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#define UVM_PUSHBUFFER_CHUNK_SIZE (8 * UVM_MAX_PUSH_SIZE)
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#define UVM_PUSHBUFFER_CHUNKS 16
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// Total size of the pushbuffer
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#define UVM_PUSHBUFFER_SIZE (UVM_PUSHBUFFER_CHUNK_SIZE * UVM_PUSHBUFFER_CHUNKS)
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// The max number of concurrent pushes that can be happening at the same time.
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// Concurrent pushes are ones that are after uvm_push_begin*(), but before
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// uvm_push_end().
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#define UVM_PUSH_MAX_CONCURRENT_PUSHES UVM_PUSHBUFFER_CHUNKS
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typedef struct
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{
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// Offset within the chunk of where a next push should begin if there is
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// space for one. Updated in update_chunk().
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NvU32 next_push_start;
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// List of uvm_gpfifo_entry_t that are pending and used this chunk. New
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// entries are always added at the tail of the list.
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struct list_head pending_gpfifos;
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// Currently on-going push in the chunk. There can be only one at a time.
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uvm_push_t *current_push;
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} uvm_pushbuffer_chunk_t;
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struct uvm_pushbuffer_struct
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{
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uvm_channel_manager_t *channel_manager;
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// Memory allocation backing the pushbuffer
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uvm_rm_mem_t *memory;
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// Array of the pushbuffer chunks
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uvm_pushbuffer_chunk_t chunks[UVM_PUSHBUFFER_CHUNKS];
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// Chunks that do not have an on-going push and have at least
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// UVM_MAX_PUSH_SIZE space free.
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DECLARE_BITMAP(available_chunks, UVM_PUSHBUFFER_CHUNKS);
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// Chunks that do not have an on-going push nor any pending pushes.
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DECLARE_BITMAP(idle_chunks, UVM_PUSHBUFFER_CHUNKS);
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// Lock protecting chunk state and the bitmaps.
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uvm_spinlock_t lock;
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// Semaphore enforcing a limited number of concurrent pushes.
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// Decremented in uvm_pushbuffer_begin_push(), incremented in
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// uvm_pushbuffer_end_push().
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// Initialized to the number of chunks as that's how many concurrent pushes
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// are supported.
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uvm_semaphore_t concurrent_pushes_sema;
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struct
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{
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struct proc_dir_entry *info_file;
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} procfs;
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};
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// Create a pushbuffer
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NV_STATUS uvm_pushbuffer_create(uvm_channel_manager_t *channel_manager, uvm_pushbuffer_t **pushbuffer_out);
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// Destroy the pushbuffer
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void uvm_pushbuffer_destroy(uvm_pushbuffer_t *pushbuffer);
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// Get an allocation for a push from the pushbuffer
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// Waits until a chunk is available and claims it for the push. The chunk used
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// for the push will be unavailable for any new pushes until
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// uvm_pushbuffer_end_push() for the push is called.
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NV_STATUS uvm_pushbuffer_begin_push(uvm_pushbuffer_t *pushbuffer, uvm_push_t *push);
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// Complete a pending push
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// Updates the chunk state the pending push used
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void uvm_pushbuffer_mark_completed(uvm_pushbuffer_t *pushbuffer, uvm_gpfifo_entry_t *gpfifo);
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// Get the GPU VA for an ongoing push
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NvU64 uvm_pushbuffer_get_gpu_va_for_push(uvm_pushbuffer_t *pushbuffer, uvm_push_t *push);
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// Get the offset of the beginning of the push from the base of the pushbuffer allocation
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NvU32 uvm_pushbuffer_get_offset_for_push(uvm_pushbuffer_t *pushbuffer, uvm_push_t *push);
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// End an on-going push
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// Updates the state of the chunk making it available for new pushes if it has
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// enough space left.
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void uvm_pushbuffer_end_push(uvm_pushbuffer_t *pushbuffer, uvm_push_t *push, uvm_gpfifo_entry_t *gpfifo);
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// Query whether the pushbuffer has space for another push
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// Mostly useful in pushbuffer tests
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bool uvm_pushbuffer_has_space(uvm_pushbuffer_t *pushbuffer);
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// Helper to print pushbuffer state for debugging
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void uvm_pushbuffer_print(uvm_pushbuffer_t *pushbuffer);
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#endif // __UVM_PUSHBUFFER_H__
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