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linux/drivers/gpu/drm/nouveau/nvkm/subdev/mmu/base.c
Linus Torvalds bf4afc53b7 Convert 'alloc_obj' family to use the new default GFP_KERNEL argument 
This was done entirely with mindless brute force, using

    git grep -l '\<k[vmz]*alloc_objs*(.*, GFP_KERNEL)' |
        xargs sed -i 's/\(alloc_objs*(.*\), GFP_KERNEL)/\1)/'

to convert the new alloc_obj() users that had a simple GFP_KERNEL
argument to just drop that argument.

Note that due to the extreme simplicity of the scripting, any slightly
more complex cases spread over multiple lines would not be triggered:
they definitely exist, but this covers the vast bulk of the cases, and
the resulting diff is also then easier to check automatically.

For the same reason the 'flex' versions will be done as a separate
conversion.

Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
2026-02-21 17:09:51 -08:00

442 lines
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/*
* Copyright 2010 Red Hat Inc.
*
* 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 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 COPYRIGHT HOLDER(S) OR AUTHOR(S) 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: Ben Skeggs
*/
#include "ummu.h"
#include "vmm.h"
#include <subdev/bar.h>
#include <subdev/fb.h>
#include <nvif/if500d.h>
#include <nvif/if900d.h>
struct nvkm_mmu_ptp {
struct nvkm_mmu_pt *pt;
struct list_head head;
u8 shift;
u16 mask;
u16 free;
};
static void
nvkm_mmu_ptp_put(struct nvkm_mmu *mmu, bool force, struct nvkm_mmu_pt *pt)
{
const int slot = pt->base >> pt->ptp->shift;
struct nvkm_mmu_ptp *ptp = pt->ptp;
/* If there were no free slots in the parent allocation before,
* there will be now, so return PTP to the cache.
*/
if (!ptp->free)
list_add(&ptp->head, &mmu->ptp.list);
ptp->free |= BIT(slot);
/* If there's no more sub-allocations, destroy PTP. */
if (ptp->free == ptp->mask) {
nvkm_mmu_ptc_put(mmu, force, &ptp->pt);
list_del(&ptp->head);
kfree(ptp);
}
kfree(pt);
}
static struct nvkm_mmu_pt *
nvkm_mmu_ptp_get(struct nvkm_mmu *mmu, u32 size, bool zero)
{
struct nvkm_mmu_pt *pt;
struct nvkm_mmu_ptp *ptp;
int slot;
if (!(pt = kzalloc_obj(*pt)))
return NULL;
ptp = list_first_entry_or_null(&mmu->ptp.list, typeof(*ptp), head);
if (!ptp) {
/* Need to allocate a new parent to sub-allocate from. */
if (!(ptp = kmalloc_obj(*ptp))) {
kfree(pt);
return NULL;
}
ptp->pt = nvkm_mmu_ptc_get(mmu, 0x1000, 0x1000, false);
if (!ptp->pt) {
kfree(ptp);
kfree(pt);
return NULL;
}
ptp->shift = order_base_2(size);
slot = nvkm_memory_size(ptp->pt->memory) >> ptp->shift;
ptp->mask = (1 << slot) - 1;
ptp->free = ptp->mask;
list_add(&ptp->head, &mmu->ptp.list);
}
pt->ptp = ptp;
pt->sub = true;
/* Sub-allocate from parent object, removing PTP from cache
* if there's no more free slots left.
*/
slot = __ffs(ptp->free);
ptp->free &= ~BIT(slot);
if (!ptp->free)
list_del(&ptp->head);
pt->memory = pt->ptp->pt->memory;
pt->base = slot << ptp->shift;
pt->addr = pt->ptp->pt->addr + pt->base;
return pt;
}
struct nvkm_mmu_ptc {
struct list_head head;
struct list_head item;
u32 size;
u32 refs;
};
static inline struct nvkm_mmu_ptc *
nvkm_mmu_ptc_find(struct nvkm_mmu *mmu, u32 size)
{
struct nvkm_mmu_ptc *ptc;
list_for_each_entry(ptc, &mmu->ptc.list, head) {
if (ptc->size == size)
return ptc;
}
ptc = kmalloc_obj(*ptc);
if (ptc) {
INIT_LIST_HEAD(&ptc->item);
ptc->size = size;
ptc->refs = 0;
list_add(&ptc->head, &mmu->ptc.list);
}
return ptc;
}
void
nvkm_mmu_ptc_put(struct nvkm_mmu *mmu, bool force, struct nvkm_mmu_pt **ppt)
{
struct nvkm_mmu_pt *pt = *ppt;
if (pt) {
/* Handle sub-allocated page tables. */
if (pt->sub) {
mutex_lock(&mmu->ptp.mutex);
nvkm_mmu_ptp_put(mmu, force, pt);
mutex_unlock(&mmu->ptp.mutex);
return;
}
/* Either cache or free the object. */
mutex_lock(&mmu->ptc.mutex);
if (pt->ptc->refs < 8 /* Heuristic. */ && !force) {
list_add_tail(&pt->head, &pt->ptc->item);
pt->ptc->refs++;
} else {
nvkm_memory_unref(&pt->memory);
kfree(pt);
}
mutex_unlock(&mmu->ptc.mutex);
}
}
struct nvkm_mmu_pt *
nvkm_mmu_ptc_get(struct nvkm_mmu *mmu, u32 size, u32 align, bool zero)
{
struct nvkm_mmu_ptc *ptc;
struct nvkm_mmu_pt *pt;
int ret;
/* Sub-allocated page table (ie. GP100 LPT). */
if (align < 0x1000) {
mutex_lock(&mmu->ptp.mutex);
pt = nvkm_mmu_ptp_get(mmu, align, zero);
mutex_unlock(&mmu->ptp.mutex);
return pt;
}
/* Lookup cache for this page table size. */
mutex_lock(&mmu->ptc.mutex);
ptc = nvkm_mmu_ptc_find(mmu, size);
if (!ptc) {
mutex_unlock(&mmu->ptc.mutex);
return NULL;
}
/* If there's a free PT in the cache, reuse it. */
pt = list_first_entry_or_null(&ptc->item, typeof(*pt), head);
if (pt) {
if (zero)
nvkm_fo64(pt->memory, 0, 0, size >> 3);
list_del(&pt->head);
ptc->refs--;
mutex_unlock(&mmu->ptc.mutex);
return pt;
}
mutex_unlock(&mmu->ptc.mutex);
/* No such luck, we need to allocate. */
if (!(pt = kmalloc_obj(*pt)))
return NULL;
pt->ptc = ptc;
pt->sub = false;
ret = nvkm_memory_new(mmu->subdev.device, NVKM_MEM_TARGET_INST,
size, align, zero, &pt->memory);
if (ret) {
kfree(pt);
return NULL;
}
pt->base = 0;
pt->addr = nvkm_memory_addr(pt->memory);
return pt;
}
void
nvkm_mmu_ptc_dump(struct nvkm_mmu *mmu)
{
struct nvkm_mmu_ptc *ptc;
list_for_each_entry(ptc, &mmu->ptc.list, head) {
struct nvkm_mmu_pt *pt, *tt;
list_for_each_entry_safe(pt, tt, &ptc->item, head) {
nvkm_memory_unref(&pt->memory);
list_del(&pt->head);
kfree(pt);
}
}
}
static void
nvkm_mmu_ptc_fini(struct nvkm_mmu *mmu)
{
struct nvkm_mmu_ptc *ptc, *ptct;
list_for_each_entry_safe(ptc, ptct, &mmu->ptc.list, head) {
WARN_ON(!list_empty(&ptc->item));
list_del(&ptc->head);
kfree(ptc);
}
}
static void
nvkm_mmu_ptc_init(struct nvkm_mmu *mmu)
{
mutex_init(&mmu->ptc.mutex);
INIT_LIST_HEAD(&mmu->ptc.list);
mutex_init(&mmu->ptp.mutex);
INIT_LIST_HEAD(&mmu->ptp.list);
}
static void
nvkm_mmu_type(struct nvkm_mmu *mmu, int heap, u8 type)
{
if (heap >= 0 && !WARN_ON(mmu->type_nr == ARRAY_SIZE(mmu->type))) {
mmu->type[mmu->type_nr].type = type | mmu->heap[heap].type;
mmu->type[mmu->type_nr].heap = heap;
mmu->type_nr++;
}
}
static int
nvkm_mmu_heap(struct nvkm_mmu *mmu, u8 type, u64 size)
{
if (size) {
if (!WARN_ON(mmu->heap_nr == ARRAY_SIZE(mmu->heap))) {
mmu->heap[mmu->heap_nr].type = type;
mmu->heap[mmu->heap_nr].size = size;
return mmu->heap_nr++;
}
}
return -EINVAL;
}
static void
nvkm_mmu_host(struct nvkm_mmu *mmu)
{
struct nvkm_device *device = mmu->subdev.device;
u8 type = NVKM_MEM_KIND * !!mmu->func->kind_sys;
int heap;
/* Non-mappable system memory. */
heap = nvkm_mmu_heap(mmu, NVKM_MEM_HOST, ~0ULL);
nvkm_mmu_type(mmu, heap, type);
/* Non-coherent, cached, system memory.
*
* Block-linear mappings of system memory must be done through
* BAR1, and cannot be supported on systems where we're unable
* to map BAR1 with write-combining.
*/
type |= NVKM_MEM_MAPPABLE;
if (!device->bar || device->bar->iomap_uncached)
nvkm_mmu_type(mmu, heap, type & ~NVKM_MEM_KIND);
else
nvkm_mmu_type(mmu, heap, type);
/* Coherent, cached, system memory.
*
* Unsupported on systems that aren't able to support snooped
* mappings, and also for block-linear mappings which must be
* done through BAR1.
*/
type |= NVKM_MEM_COHERENT;
if (device->func->cpu_coherent)
nvkm_mmu_type(mmu, heap, type & ~NVKM_MEM_KIND);
/* Uncached system memory. */
nvkm_mmu_type(mmu, heap, type |= NVKM_MEM_UNCACHED);
}
static void
nvkm_mmu_vram(struct nvkm_mmu *mmu)
{
struct nvkm_device *device = mmu->subdev.device;
struct nvkm_mm *mm = &device->fb->ram->vram;
const u64 sizeN = nvkm_mm_heap_size(mm, NVKM_RAM_MM_NORMAL);
const u64 sizeU = nvkm_mm_heap_size(mm, NVKM_RAM_MM_NOMAP);
const u64 sizeM = nvkm_mm_heap_size(mm, NVKM_RAM_MM_MIXED);
u8 type = NVKM_MEM_KIND * !!mmu->func->kind;
u8 heap = NVKM_MEM_VRAM;
int heapM, heapN, heapU;
/* Mixed-memory doesn't support compression or display. */
heapM = nvkm_mmu_heap(mmu, heap, sizeM << NVKM_RAM_MM_SHIFT);
heap |= NVKM_MEM_COMP;
heap |= NVKM_MEM_DISP;
heapN = nvkm_mmu_heap(mmu, heap, sizeN << NVKM_RAM_MM_SHIFT);
heapU = nvkm_mmu_heap(mmu, heap, sizeU << NVKM_RAM_MM_SHIFT);
/* Add non-mappable VRAM types first so that they're preferred
* over anything else. Mixed-memory will be slower than other
* heaps, it's prioritised last.
*/
nvkm_mmu_type(mmu, heapU, type);
nvkm_mmu_type(mmu, heapN, type);
nvkm_mmu_type(mmu, heapM, type);
/* Add host memory types next, under the assumption that users
* wanting mappable memory want to use them as staging buffers
* or the like.
*/
nvkm_mmu_host(mmu);
/* Mappable VRAM types go last, as they're basically the worst
* possible type to ask for unless there's no other choice.
*/
if (device->bar) {
/* Write-combined BAR1 access. */
type |= NVKM_MEM_MAPPABLE;
if (!device->bar->iomap_uncached) {
nvkm_mmu_type(mmu, heapN, type);
nvkm_mmu_type(mmu, heapM, type);
}
/* Uncached BAR1 access. */
type |= NVKM_MEM_COHERENT;
type |= NVKM_MEM_UNCACHED;
nvkm_mmu_type(mmu, heapN, type);
nvkm_mmu_type(mmu, heapM, type);
}
}
static int
nvkm_mmu_oneinit(struct nvkm_subdev *subdev)
{
struct nvkm_mmu *mmu = nvkm_mmu(subdev);
/* Determine available memory types. */
if (mmu->subdev.device->fb && mmu->subdev.device->fb->ram)
nvkm_mmu_vram(mmu);
else
nvkm_mmu_host(mmu);
if (mmu->func->vmm.global) {
int ret = nvkm_vmm_new(subdev->device, 0, 0, NULL, 0, NULL,
"gart", &mmu->vmm);
if (ret)
return ret;
}
return 0;
}
static int
nvkm_mmu_init(struct nvkm_subdev *subdev)
{
struct nvkm_mmu *mmu = nvkm_mmu(subdev);
if (mmu->func->init)
mmu->func->init(mmu);
return 0;
}
static void *
nvkm_mmu_dtor(struct nvkm_subdev *subdev)
{
struct nvkm_mmu *mmu = nvkm_mmu(subdev);
nvkm_vmm_unref(&mmu->vmm);
nvkm_mmu_ptc_fini(mmu);
mutex_destroy(&mmu->mutex);
if (mmu->func->dtor)
mmu->func->dtor(mmu);
return mmu;
}
static const struct nvkm_subdev_func
nvkm_mmu = {
.dtor = nvkm_mmu_dtor,
.oneinit = nvkm_mmu_oneinit,
.init = nvkm_mmu_init,
};
void
nvkm_mmu_ctor(const struct nvkm_mmu_func *func, struct nvkm_device *device,
enum nvkm_subdev_type type, int inst, struct nvkm_mmu *mmu)
{
nvkm_subdev_ctor(&nvkm_mmu, device, type, inst, &mmu->subdev);
mmu->func = func;
mmu->dma_bits = func->dma_bits;
nvkm_mmu_ptc_init(mmu);
mutex_init(&mmu->mutex);
mmu->user.ctor = nvkm_ummu_new;
mmu->user.base = func->mmu.user;
}
int
nvkm_mmu_new_(const struct nvkm_mmu_func *func, struct nvkm_device *device,
enum nvkm_subdev_type type, int inst, struct nvkm_mmu **pmmu)
{
if (!(*pmmu = kzalloc_obj(**pmmu)))
return -ENOMEM;
nvkm_mmu_ctor(func, device, type, inst, *pmmu);
return 0;
}
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