drivers/gpu/drm/nouveau/nvkm/subdev/mmu/base.c - linux - Git at Google

 /*
  * 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);
 }

 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(sizeof(*pt), GFP_KERNEL)))
 		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(sizeof(*ptp), GFP_KERNEL))) {
 			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(sizeof(*ptc), GFP_KERNEL);
 	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(sizeof(*pt), GFP_KERNEL)))
 		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 u32 sizeN = nvkm_mm_heap_size(mm, NVKM_RAM_MM_NORMAL);
 	const u32 sizeU = nvkm_mm_heap_size(mm, NVKM_RAM_MM_NOMAP);
 	const u32 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);
 	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,
 	      int index, struct nvkm_mmu *mmu)
 {
 	nvkm_subdev_ctor(&nvkm_mmu, device, index, &mmu->subdev);
 	mmu->func = func;
 	mmu->dma_bits = func->dma_bits;
 	nvkm_mmu_ptc_init(mmu);
 	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,
 	      int index, struct nvkm_mmu **pmmu)
 {
 	if (!(*pmmu = kzalloc(sizeof(**pmmu), GFP_KERNEL)))
 		return -ENOMEM;
 	nvkm_mmu_ctor(func, device, index, *pmmu);
 	return 0;
 }
	/*
	* 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);
	}

	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(sizeof(*pt), GFP_KERNEL)))
	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(sizeof(*ptp), GFP_KERNEL))) {
	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(sizeof(*ptc), GFP_KERNEL);
	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(sizeof(*pt), GFP_KERNEL)))
	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 u32 sizeN = nvkm_mm_heap_size(mm, NVKM_RAM_MM_NORMAL);
	const u32 sizeU = nvkm_mm_heap_size(mm, NVKM_RAM_MM_NOMAP);
	const u32 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);
	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,
	int index, struct nvkm_mmu *mmu)
	{
	nvkm_subdev_ctor(&nvkm_mmu, device, index, &mmu->subdev);
	mmu->func = func;
	mmu->dma_bits = func->dma_bits;
	nvkm_mmu_ptc_init(mmu);
	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,
	int index, struct nvkm_mmu **pmmu)
	{
	if (!(pmmu = kzalloc(sizeof(*pmmu), GFP_KERNEL)))
	return -ENOMEM;
	nvkm_mmu_ctor(func, device, index, *pmmu);
	return 0;
	}