midgard/r13p0/kernel/drivers/gpu/arm/midgard/mali_kbase_mem_linux.h - manifest_repos/mali-driver - Git at Google

 /*
  *
  * (C) COPYRIGHT 2010, 2012-2016 ARM Limited. All rights reserved.
  *
  * This program is free software and is provided to you under the terms of the
  * GNU General Public License version 2 as published by the Free Software
  * Foundation, and any use by you of this program is subject to the terms
  * of such GNU licence.
  *
  * A copy of the licence is included with the program, and can also be obtained
  * from Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor,
  * Boston, MA  02110-1301, USA.
  *
  */


 /**
  * @file mali_kbase_mem_linux.h
  * Base kernel memory APIs, Linux implementation.
  */

 #ifndef _KBASE_MEM_LINUX_H_
 #define _KBASE_MEM_LINUX_H_

 /** A HWC dump mapping */
 struct kbase_hwc_dma_mapping {
 	void       *cpu_va;
 	dma_addr_t  dma_pa;
 	size_t      size;
 };

 struct kbase_va_region *kbase_mem_alloc(struct kbase_context *kctx, u64 va_pages, u64 commit_pages, u64 extent, u64 *flags, u64 *gpu_va, u16 *va_alignment);
 int kbase_mem_query(struct kbase_context *kctx, u64 gpu_addr, int query, u64 *const pages);
 int kbase_mem_import(struct kbase_context *kctx, enum base_mem_import_type type,
 		void __user *phandle, u64 *gpu_va, u64 *va_pages,
 		u64 *flags);
 u64 kbase_mem_alias(struct kbase_context *kctx, u64 *flags, u64 stride, u64 nents, struct base_mem_aliasing_info *ai, u64 *num_pages);
 int kbase_mem_flags_change(struct kbase_context *kctx, u64 gpu_addr, unsigned int flags, unsigned int mask);
 int kbase_mem_commit(struct kbase_context *kctx, u64 gpu_addr, u64 new_pages, enum base_backing_threshold_status *failure_reason);
 int kbase_mmap(struct file *file, struct vm_area_struct *vma);

 /**
  * kbase_mem_evictable_init - Initialize the Ephemeral memory the eviction
  * mechanism.
  * @kctx: The kbase context to initialize.
  *
  * Return: Zero on success or -errno on failure.
  */
 int kbase_mem_evictable_init(struct kbase_context *kctx);

 /**
  * kbase_mem_evictable_deinit - De-initialize the Ephemeral memory eviction
  * mechanism.
  * @kctx: The kbase context to de-initialize.
  */
 void kbase_mem_evictable_deinit(struct kbase_context *kctx);

 /**
  * kbase_mem_grow_gpu_mapping - Grow the GPU mapping of an allocation
  * @kctx:      Context the region belongs to
  * @reg:       The GPU region
  * @new_pages: The number of pages after the grow
  * @old_pages: The number of pages before the grow
  *
  * Return: 0 on success, -errno on error.
  *
  * Expand the GPU mapping to encompass the new psychical pages which have
  * been added to the allocation.
  *
  * Note: Caller must be holding the region lock.
  */
 int kbase_mem_grow_gpu_mapping(struct kbase_context *kctx,
 		struct kbase_va_region *reg,
 		u64 new_pages, u64 old_pages);

 /**
  * kbase_mem_evictable_make - Make a physical allocation eligible for eviction
  * @gpu_alloc: The physical allocation to make evictable
  *
  * Return: 0 on success, -errno on error.
  *
  * Take the provided region and make all the physical pages within it
  * reclaimable by the kernel, updating the per-process VM stats as well.
  * Remove any CPU mappings (as these can't be removed in the shrinker callback
  * as mmap_sem might already be taken) but leave the GPU mapping intact as
  * and until the shrinker reclaims the allocation.
  *
  * Note: Must be called with the region lock of the containing context.
  */
 int kbase_mem_evictable_make(struct kbase_mem_phy_alloc *gpu_alloc);

 /**
  * kbase_mem_evictable_unmake - Remove a physical allocations eligibility for
  * eviction.
  * @alloc: The physical allocation to remove eviction eligibility from.
  *
  * Return: True if the allocation had its backing restored and false if
  * it hasn't.
  *
  * Make the physical pages in the region no longer reclaimable and update the
  * per-process stats, if the shrinker has already evicted the memory then
  * re-allocate it if the region is still alive.
  *
  * Note: Must be called with the region lock of the containing context.
  */
 bool kbase_mem_evictable_unmake(struct kbase_mem_phy_alloc *alloc);

 struct kbase_vmap_struct {
 	u64 gpu_addr;
 	struct kbase_mem_phy_alloc *cpu_alloc;
 	struct kbase_mem_phy_alloc *gpu_alloc;
 	phys_addr_t *cpu_pages;
 	phys_addr_t *gpu_pages;
 	void *addr;
 	size_t size;
 	bool is_cached;
 };


 /**
  * kbase_vmap_prot - Map a GPU VA range into the kernel safely, only if the
  * requested access permissions are supported
  * @kctx:         Context the VA range belongs to
  * @gpu_addr:     Start address of VA range
  * @size:         Size of VA range
  * @prot_request: Flags indicating how the caller will then access the memory
  * @map:          Structure to be given to kbase_vunmap() on freeing
  *
  * Return: Kernel-accessible CPU pointer to the VA range, or NULL on error
  *
  * Map a GPU VA Range into the kernel. The VA range must be contained within a
  * GPU memory region. Appropriate CPU cache-flushing operations are made as
  * required, dependent on the CPU mapping for the memory region.
  *
  * This is safer than using kmap() on the pages directly,
  * because the pages here are refcounted to prevent freeing (and hence reuse
  * elsewhere in the system) until an kbase_vunmap()
  *
  * The flags in @prot_request should use KBASE_REG_{CPU,GPU}_{RD,WR}, to check
  * whether the region should allow the intended access, and return an error if
  * disallowed. This is essential for security of imported memory, particularly
  * a user buf from SHM mapped into the process as RO. In that case, write
  * access must be checked if the intention is for kernel to write to the
  * memory.
  *
  * The checks are also there to help catch access errors on memory where
  * security is not a concern: imported memory that is always RW, and memory
  * that was allocated and owned by the process attached to @kctx. In this case,
  * it helps to identify memory that was was mapped with the wrong access type.
  *
  * Note: KBASE_REG_GPU_{RD,WR} flags are currently supported for legacy cases
  * where either the security of memory is solely dependent on those flags, or
  * when userspace code was expecting only the GPU to access the memory (e.g. HW
  * workarounds).
  *
  */
 void *kbase_vmap_prot(struct kbase_context *kctx, u64 gpu_addr, size_t size,
 		      unsigned long prot_request, struct kbase_vmap_struct *map);

 /**
  * kbase_vmap - Map a GPU VA range into the kernel safely
  * @kctx:     Context the VA range belongs to
  * @gpu_addr: Start address of VA range
  * @size:     Size of VA range
  * @map:      Structure to be given to kbase_vunmap() on freeing
  *
  * Return: Kernel-accessible CPU pointer to the VA range, or NULL on error
  *
  * Map a GPU VA Range into the kernel. The VA range must be contained within a
  * GPU memory region. Appropriate CPU cache-flushing operations are made as
  * required, dependent on the CPU mapping for the memory region.
  *
  * This is safer than using kmap() on the pages directly,
  * because the pages here are refcounted to prevent freeing (and hence reuse
  * elsewhere in the system) until an kbase_vunmap()
  *
  * kbase_vmap_prot() should be used in preference, since kbase_vmap() makes no
  * checks to ensure the security of e.g. imported user bufs from RO SHM.
  */
 void *kbase_vmap(struct kbase_context *kctx, u64 gpu_addr, size_t size,
 		struct kbase_vmap_struct *map);

 /**
  * kbase_vunmap - Unmap a GPU VA range from the kernel
  * @kctx: Context the VA range belongs to
  * @map:  Structure describing the mapping from the corresponding kbase_vmap()
  *        call
  *
  * Unmaps a GPU VA range from the kernel, given its @map structure obtained
  * from kbase_vmap(). Appropriate CPU cache-flushing operations are made as
  * required, dependent on the CPU mapping for the memory region.
  *
  * The reference taken on pages during kbase_vmap() is released.
  */
 void kbase_vunmap(struct kbase_context *kctx, struct kbase_vmap_struct *map);

 /** @brief Allocate memory from kernel space and map it onto the GPU
  *
  * @param kctx   The context used for the allocation/mapping
  * @param size   The size of the allocation in bytes
  * @param handle An opaque structure used to contain the state needed to free the memory
  * @return the VA for kernel space and GPU MMU
  */
 void *kbase_va_alloc(struct kbase_context *kctx, u32 size, struct kbase_hwc_dma_mapping *handle);

 /** @brief Free/unmap memory allocated by kbase_va_alloc
  *
  * @param kctx   The context used for the allocation/mapping
  * @param handle An opaque structure returned by the kbase_va_alloc function.
  */
 void kbase_va_free(struct kbase_context *kctx, struct kbase_hwc_dma_mapping *handle);

 #endif				/* _KBASE_MEM_LINUX_H_ */
	/*
	*
	* (C) COPYRIGHT 2010, 2012-2016 ARM Limited. All rights reserved.
	*
	* This program is free software and is provided to you under the terms of the
	* GNU General Public License version 2 as published by the Free Software
	* Foundation, and any use by you of this program is subject to the terms
	* of such GNU licence.
	*
	* A copy of the licence is included with the program, and can also be obtained
	* from Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor,
	* Boston, MA 02110-1301, USA.
	*
	*/





	/**
	* @file mali_kbase_mem_linux.h
	* Base kernel memory APIs, Linux implementation.
	*/

	#ifndef _KBASE_MEM_LINUX_H_
	#define _KBASE_MEM_LINUX_H_

	/** A HWC dump mapping */
	struct kbase_hwc_dma_mapping {
	void *cpu_va;
	dma_addr_t dma_pa;
	size_t size;
	};

	struct kbase_va_region kbase_mem_alloc(struct kbase_context kctx, u64 va_pages, u64 commit_pages, u64 extent, u64 flags, u64 gpu_va, u16 *va_alignment);
	int kbase_mem_query(struct kbase_context kctx, u64 gpu_addr, int query, u64 const pages);
	int kbase_mem_import(struct kbase_context *kctx, enum base_mem_import_type type,
	void __user phandle, u64 gpu_va, u64 *va_pages,
	u64 *flags);
	u64 kbase_mem_alias(struct kbase_context kctx, u64 flags, u64 stride, u64 nents, struct base_mem_aliasing_info ai, u64 num_pages);
	int kbase_mem_flags_change(struct kbase_context *kctx, u64 gpu_addr, unsigned int flags, unsigned int mask);
	int kbase_mem_commit(struct kbase_context kctx, u64 gpu_addr, u64 new_pages, enum base_backing_threshold_status failure_reason);
	int kbase_mmap(struct file file, struct vm_area_struct vma);

	/**
	* kbase_mem_evictable_init - Initialize the Ephemeral memory the eviction
	* mechanism.
	* @kctx: The kbase context to initialize.
	*
	* Return: Zero on success or -errno on failure.
	*/
	int kbase_mem_evictable_init(struct kbase_context *kctx);

	/**
	* kbase_mem_evictable_deinit - De-initialize the Ephemeral memory eviction
	* mechanism.
	* @kctx: The kbase context to de-initialize.
	*/
	void kbase_mem_evictable_deinit(struct kbase_context *kctx);

	/**
	* kbase_mem_grow_gpu_mapping - Grow the GPU mapping of an allocation
	* @kctx: Context the region belongs to
	* @reg: The GPU region
	* @new_pages: The number of pages after the grow
	* @old_pages: The number of pages before the grow
	*
	* Return: 0 on success, -errno on error.
	*
	* Expand the GPU mapping to encompass the new psychical pages which have
	* been added to the allocation.
	*
	* Note: Caller must be holding the region lock.
	*/
	int kbase_mem_grow_gpu_mapping(struct kbase_context *kctx,
	struct kbase_va_region *reg,
	u64 new_pages, u64 old_pages);

	/**
	* kbase_mem_evictable_make - Make a physical allocation eligible for eviction
	* @gpu_alloc: The physical allocation to make evictable
	*
	* Return: 0 on success, -errno on error.
	*
	* Take the provided region and make all the physical pages within it
	* reclaimable by the kernel, updating the per-process VM stats as well.
	* Remove any CPU mappings (as these can't be removed in the shrinker callback
	* as mmap_sem might already be taken) but leave the GPU mapping intact as
	* and until the shrinker reclaims the allocation.
	*
	* Note: Must be called with the region lock of the containing context.
	*/
	int kbase_mem_evictable_make(struct kbase_mem_phy_alloc *gpu_alloc);

	/**
	* kbase_mem_evictable_unmake - Remove a physical allocations eligibility for
	* eviction.
	* @alloc: The physical allocation to remove eviction eligibility from.
	*
	* Return: True if the allocation had its backing restored and false if
	* it hasn't.
	*
	* Make the physical pages in the region no longer reclaimable and update the
	* per-process stats, if the shrinker has already evicted the memory then
	* re-allocate it if the region is still alive.
	*
	* Note: Must be called with the region lock of the containing context.
	*/
	bool kbase_mem_evictable_unmake(struct kbase_mem_phy_alloc *alloc);

	struct kbase_vmap_struct {
	u64 gpu_addr;
	struct kbase_mem_phy_alloc *cpu_alloc;
	struct kbase_mem_phy_alloc *gpu_alloc;
	phys_addr_t *cpu_pages;
	phys_addr_t *gpu_pages;
	void *addr;
	size_t size;
	bool is_cached;
	};


	/**
	* kbase_vmap_prot - Map a GPU VA range into the kernel safely, only if the
	* requested access permissions are supported
	* @kctx: Context the VA range belongs to
	* @gpu_addr: Start address of VA range
	* @size: Size of VA range
	* @prot_request: Flags indicating how the caller will then access the memory
	* @map: Structure to be given to kbase_vunmap() on freeing
	*
	* Return: Kernel-accessible CPU pointer to the VA range, or NULL on error
	*
	* Map a GPU VA Range into the kernel. The VA range must be contained within a
	* GPU memory region. Appropriate CPU cache-flushing operations are made as
	* required, dependent on the CPU mapping for the memory region.
	*
	* This is safer than using kmap() on the pages directly,
	* because the pages here are refcounted to prevent freeing (and hence reuse
	* elsewhere in the system) until an kbase_vunmap()
	*
	* The flags in @prot_request should use KBASE_REG_{CPU,GPU}_{RD,WR}, to check
	* whether the region should allow the intended access, and return an error if
	* disallowed. This is essential for security of imported memory, particularly
	* a user buf from SHM mapped into the process as RO. In that case, write
	* access must be checked if the intention is for kernel to write to the
	* memory.
	*
	* The checks are also there to help catch access errors on memory where
	* security is not a concern: imported memory that is always RW, and memory
	* that was allocated and owned by the process attached to @kctx. In this case,
	* it helps to identify memory that was was mapped with the wrong access type.
	*
	* Note: KBASE_REG_GPU_{RD,WR} flags are currently supported for legacy cases
	* where either the security of memory is solely dependent on those flags, or
	* when userspace code was expecting only the GPU to access the memory (e.g. HW
	* workarounds).
	*
	*/
	void kbase_vmap_prot(struct kbase_context kctx, u64 gpu_addr, size_t size,
	unsigned long prot_request, struct kbase_vmap_struct *map);

	/**
	* kbase_vmap - Map a GPU VA range into the kernel safely
	* @kctx: Context the VA range belongs to
	* @gpu_addr: Start address of VA range
	* @size: Size of VA range
	* @map: Structure to be given to kbase_vunmap() on freeing
	*
	* Return: Kernel-accessible CPU pointer to the VA range, or NULL on error
	*
	* Map a GPU VA Range into the kernel. The VA range must be contained within a
	* GPU memory region. Appropriate CPU cache-flushing operations are made as
	* required, dependent on the CPU mapping for the memory region.
	*
	* This is safer than using kmap() on the pages directly,
	* because the pages here are refcounted to prevent freeing (and hence reuse
	* elsewhere in the system) until an kbase_vunmap()
	*
	* kbase_vmap_prot() should be used in preference, since kbase_vmap() makes no
	* checks to ensure the security of e.g. imported user bufs from RO SHM.
	*/
	void kbase_vmap(struct kbase_context kctx, u64 gpu_addr, size_t size,
	struct kbase_vmap_struct *map);

	/**
	* kbase_vunmap - Unmap a GPU VA range from the kernel
	* @kctx: Context the VA range belongs to
	* @map: Structure describing the mapping from the corresponding kbase_vmap()
	* call
	*
	* Unmaps a GPU VA range from the kernel, given its @map structure obtained
	* from kbase_vmap(). Appropriate CPU cache-flushing operations are made as
	* required, dependent on the CPU mapping for the memory region.
	*
	* The reference taken on pages during kbase_vmap() is released.
	*/
	void kbase_vunmap(struct kbase_context kctx, struct kbase_vmap_struct map);

	/** @brief Allocate memory from kernel space and map it onto the GPU
	*
	* @param kctx The context used for the allocation/mapping
	* @param size The size of the allocation in bytes
	* @param handle An opaque structure used to contain the state needed to free the memory
	* @return the VA for kernel space and GPU MMU
	*/
	void kbase_va_alloc(struct kbase_context kctx, u32 size, struct kbase_hwc_dma_mapping *handle);

	/** @brief Free/unmap memory allocated by kbase_va_alloc
	*
	* @param kctx The context used for the allocation/mapping
	* @param handle An opaque structure returned by the kbase_va_alloc function.
	*/
	void kbase_va_free(struct kbase_context kctx, struct kbase_hwc_dma_mapping handle);

	#endif /* _KBASE_MEM_LINUX_H_ */