drivers/gpu/ion/ion_priv.h - kernel/msm - Gitiles

 /*
  * drivers/gpu/ion/ion_priv.h
  *
  * Copyright (C) 2011 Google, Inc.
  * Copyright (c) 2011-2013, The Linux Foundation. All rights reserved.
  *
  * This software is licensed under the terms of the GNU General Public
  * License version 2, as published by the Free Software Foundation, and
  * may be copied, distributed, and modified under those terms.
  *
  * This program is distributed in the hope that it will be useful,
  * but WITHOUT ANY WARRANTY; without even the implied warranty of
  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
  * GNU General Public License for more details.
  *
  */

 #ifndef _ION_PRIV_H
 #define _ION_PRIV_H

 #include <linux/ion.h>
 #include <linux/kref.h>
 #include <linux/mm_types.h>
 #include <linux/mutex.h>
 #include <linux/rbtree.h>
 #include <linux/seq_file.h>

 #include "msm_ion_priv.h"
 #include <linux/sched.h>
 #include <linux/shrinker.h>
 #include <linux/types.h>

 struct ion_buffer *ion_handle_buffer(struct ion_handle *handle);

 /**
  * struct ion_buffer - metadata for a particular buffer
  * @ref:		refernce count
  * @node:		node in the ion_device buffers tree
  * @dev:		back pointer to the ion_device
  * @heap:		back pointer to the heap the buffer came from
  * @flags:		buffer specific flags
  * @size:		size of the buffer
  * @priv_virt:		private data to the buffer representable as
  *			a void *
  * @priv_phys:		private data to the buffer representable as
  *			an ion_phys_addr_t (and someday a phys_addr_t)
  * @lock:		protects the buffers cnt fields
  * @kmap_cnt:		number of times the buffer is mapped to the kernel
  * @vaddr:		the kenrel mapping if kmap_cnt is not zero
  * @dmap_cnt:		number of times the buffer is mapped for dma
  * @sg_table:		the sg table for the buffer if dmap_cnt is not zero
 */
 struct ion_buffer {
 	struct kref ref;
 	struct rb_node node;
 	struct ion_device *dev;
 	struct ion_heap *heap;
 	unsigned long flags;
 	size_t size;
 	union {
 		void *priv_virt;
 		ion_phys_addr_t priv_phys;
 	};
 	struct mutex lock;
 	int kmap_cnt;
 	void *vaddr;
 	int dmap_cnt;
 	struct sg_table *sg_table;
 	unsigned long *dirty;
 	struct list_head vmas;
 	int marked;
 };

 /**
  * struct ion_heap_ops - ops to operate on a given heap
  * @allocate:		allocate memory
  * @free:		free memory
  * @phys		get physical address of a buffer (only define on
  *			physically contiguous heaps)
  * @map_dma		map the memory for dma to a scatterlist
  * @unmap_dma		unmap the memory for dma
  * @map_kernel		map memory to the kernel
  * @unmap_kernel	unmap memory to the kernel
  * @map_user		map memory to userspace
  * @unmap_user		unmap memory to userspace
  */
 struct ion_heap_ops {
 	int (*allocate) (struct ion_heap *heap,
 			 struct ion_buffer *buffer, unsigned long len,
 			 unsigned long align, unsigned long flags);
 	void (*free) (struct ion_buffer *buffer);
 	int (*phys) (struct ion_heap *heap, struct ion_buffer *buffer,
 		     ion_phys_addr_t *addr, size_t *len);
 	struct sg_table *(*map_dma) (struct ion_heap *heap,
 					struct ion_buffer *buffer);
 	void (*unmap_dma) (struct ion_heap *heap, struct ion_buffer *buffer);
 	void * (*map_kernel) (struct ion_heap *heap, struct ion_buffer *buffer);
 	void (*unmap_kernel) (struct ion_heap *heap, struct ion_buffer *buffer);
 	int (*map_user) (struct ion_heap *mapper, struct ion_buffer *buffer,
 			 struct vm_area_struct *vma);
 	void (*unmap_user) (struct ion_heap *mapper, struct ion_buffer *buffer);
 	int (*print_debug)(struct ion_heap *heap, struct seq_file *s,
 			   const struct rb_root *mem_map);
 	int (*secure_heap)(struct ion_heap *heap, int version, void *data);
 	int (*unsecure_heap)(struct ion_heap *heap, int version, void *data);
 	int (*secure_buffer)(struct ion_buffer *buffer, int version,
 				void *data, int flags);
 	int (*unsecure_buffer)(struct ion_buffer *buffer, int force_unsecure);
 };

 /**
  * struct ion_heap - represents a heap in the system
  * @node:		rb node to put the heap on the device's tree of heaps
  * @dev:		back pointer to the ion_device
  * @type:		type of heap
  * @ops:		ops struct as above
  * @id:			id of heap, also indicates priority of this heap when
  *			allocating.  These are specified by platform data and
  *			MUST be unique
  * @name:		used for debugging
  * @priv:		private heap data
  * @debug_show:		called when heap debug file is read to add any
  *			heap specific debug info to output
  *
  * Represents a pool of memory from which buffers can be made.  In some
  * systems the only heap is regular system memory allocated via vmalloc.
  * On others, some blocks might require large physically contiguous buffers
  * that are allocated from a specially reserved heap.
  */
 struct ion_heap {
 	struct rb_node node;
 	struct ion_device *dev;
 	enum ion_heap_type type;
 	struct ion_heap_ops *ops;
 	int id;
 	const char *name;
 	void *priv;
 	int (*debug_show)(struct ion_heap *heap, struct seq_file *, void *);
 };

 /**
  * ion_buffer_cached - this ion buffer is cached
  * @buffer:		buffer
  *
  * indicates whether this ion buffer is cached
  */
 bool ion_buffer_cached(struct ion_buffer *buffer);

 /**
  * ion_buffer_fault_user_mappings - fault in user mappings of this buffer
  * @buffer:		buffer
  *
  * indicates whether userspace mappings of this buffer will be faulted
  * in, this can affect how buffers are allocated from the heap.
  */
 bool ion_buffer_fault_user_mappings(struct ion_buffer *buffer);

 /**
  * ion_device_create - allocates and returns an ion device
  * @custom_ioctl:	arch specific ioctl function if applicable
  *
  * returns a valid device or -PTR_ERR
  */
 struct ion_device *ion_device_create(long (*custom_ioctl)
 				     (struct ion_client *client,
 				      unsigned int cmd,
 				      unsigned long arg));

 /**
  * ion_device_destroy - free and device and it's resource
  * @dev:		the device
  */
 void ion_device_destroy(struct ion_device *dev);

 /**
  * ion_device_add_heap - adds a heap to the ion device
  * @dev:		the device
  * @heap:		the heap to add
  */
 void ion_device_add_heap(struct ion_device *dev, struct ion_heap *heap);

 /**
  * functions for creating and destroying the built in ion heaps.
  * architectures can add their own custom architecture specific
  * heaps as appropriate.
  */

 struct ion_heap *ion_heap_create(struct ion_platform_heap *);
 void ion_heap_destroy(struct ion_heap *);

 struct ion_heap *ion_system_heap_create(struct ion_platform_heap *);
 void ion_system_heap_destroy(struct ion_heap *);

 struct ion_heap *ion_system_contig_heap_create(struct ion_platform_heap *);
 void ion_system_contig_heap_destroy(struct ion_heap *);

 struct ion_heap *ion_carveout_heap_create(struct ion_platform_heap *);
 void ion_carveout_heap_destroy(struct ion_heap *);

 /**
  * kernel api to allocate/free from carveout -- used when carveout is
  * used to back an architecture specific custom heap
  */
 ion_phys_addr_t ion_carveout_allocate(struct ion_heap *heap, unsigned long size,
 				      unsigned long align);
 void ion_carveout_free(struct ion_heap *heap, ion_phys_addr_t addr,
 		       unsigned long size);

 /**
  * The carveout heap returns physical addresses, since 0 may be a valid
  * physical address, this is used to indicate allocation failed
  */
 #define ION_CARVEOUT_ALLOCATE_FAIL -1


 /**
  * functions for creating and destroying a heap pool -- allows you
  * to keep a pool of pre allocated memory to use from your heap.  Keeping
  * a pool of memory that is ready for dma, ie any cached mapping have been
  * invalidated from the cache, provides a significant peformance benefit on
  * many systems */

 /**
  * struct ion_page_pool - pagepool struct
  * @count:		number of items in the pool
  * @items:		list of items
  * @shrinker:		a shrinker for the items
  * @mutex:		lock protecting this struct and especially the count
  *			item list
  * @alloc:		function to be used to allocate pageory when the pool
  *			is empty
  * @free:		function to be used to free pageory back to the system
  *			when the shrinker fires
  * @gfp_mask:		gfp_mask to use from alloc
  * @order:		order of pages in the pool
  *
  * Allows you to keep a pool of pre allocated pages to use from your heap.
  * Keeping a pool of pages that is ready for dma, ie any cached mapping have
  * been invalidated from the cache, provides a significant peformance benefit
  * on many systems
  */
 struct ion_page_pool {
 	int count;
 	struct list_head items;
 	struct shrinker shrinker;
 	struct mutex mutex;
 	void *(*alloc)(struct ion_page_pool *pool);
 	void (*free)(struct ion_page_pool *pool, struct page *page);
 	gfp_t gfp_mask;
 	unsigned int order;
 };

 struct ion_page_pool *ion_page_pool_create(gfp_t gfp_mask, unsigned int order);
 void ion_page_pool_destroy(struct ion_page_pool *);
 void *ion_page_pool_alloc(struct ion_page_pool *);
 void ion_page_pool_free(struct ion_page_pool *, struct page *);

 #endif /* _ION_PRIV_H */
	/*
	* drivers/gpu/ion/ion_priv.h
	*
	* Copyright (C) 2011 Google, Inc.
	* Copyright (c) 2011-2013, The Linux Foundation. All rights reserved.
	*
	* This software is licensed under the terms of the GNU General Public
	* License version 2, as published by the Free Software Foundation, and
	* may be copied, distributed, and modified under those terms.
	*
	* This program is distributed in the hope that it will be useful,
	* but WITHOUT ANY WARRANTY; without even the implied warranty of
	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	* GNU General Public License for more details.
	*
	*/

	#ifndef _ION_PRIV_H
	#define _ION_PRIV_H

	#include <linux/ion.h>
	#include <linux/kref.h>
	#include <linux/mm_types.h>
	#include <linux/mutex.h>
	#include <linux/rbtree.h>
	#include <linux/seq_file.h>

	#include "msm_ion_priv.h"
	#include <linux/sched.h>
	#include <linux/shrinker.h>
	#include <linux/types.h>

	struct ion_buffer ion_handle_buffer(struct ion_handle handle);

	/**
	* struct ion_buffer - metadata for a particular buffer
	* @ref: refernce count
	* @node: node in the ion_device buffers tree
	* @dev: back pointer to the ion_device
	* @heap: back pointer to the heap the buffer came from
	* @flags: buffer specific flags
	* @size: size of the buffer
	* @priv_virt: private data to the buffer representable as
	* a void *
	* @priv_phys: private data to the buffer representable as
	* an ion_phys_addr_t (and someday a phys_addr_t)
	* @lock: protects the buffers cnt fields
	* @kmap_cnt: number of times the buffer is mapped to the kernel
	* @vaddr: the kenrel mapping if kmap_cnt is not zero
	* @dmap_cnt: number of times the buffer is mapped for dma
	* @sg_table: the sg table for the buffer if dmap_cnt is not zero
	*/
	struct ion_buffer {
	struct kref ref;
	struct rb_node node;
	struct ion_device *dev;
	struct ion_heap *heap;
	unsigned long flags;
	size_t size;
	union {
	void *priv_virt;
	ion_phys_addr_t priv_phys;
	};
	struct mutex lock;
	int kmap_cnt;
	void *vaddr;
	int dmap_cnt;
	struct sg_table *sg_table;
	unsigned long *dirty;
	struct list_head vmas;
	int marked;
	};

	/**
	* struct ion_heap_ops - ops to operate on a given heap
	* @allocate: allocate memory
	* @free: free memory
	* @phys get physical address of a buffer (only define on
	* physically contiguous heaps)
	* @map_dma map the memory for dma to a scatterlist
	* @unmap_dma unmap the memory for dma
	* @map_kernel map memory to the kernel
	* @unmap_kernel unmap memory to the kernel
	* @map_user map memory to userspace
	* @unmap_user unmap memory to userspace
	*/
	struct ion_heap_ops {
	int (allocate) (struct ion_heap heap,
	struct ion_buffer *buffer, unsigned long len,
	unsigned long align, unsigned long flags);
	void (free) (struct ion_buffer buffer);
	int (phys) (struct ion_heap heap, struct ion_buffer *buffer,
	ion_phys_addr_t addr, size_t len);
	struct sg_table (map_dma) (struct ion_heap *heap,
	struct ion_buffer *buffer);
	void (unmap_dma) (struct ion_heap heap, struct ion_buffer *buffer);
	void * (map_kernel) (struct ion_heap heap, struct ion_buffer *buffer);
	void (unmap_kernel) (struct ion_heap heap, struct ion_buffer *buffer);
	int (map_user) (struct ion_heap mapper, struct ion_buffer *buffer,
	struct vm_area_struct *vma);
	void (unmap_user) (struct ion_heap mapper, struct ion_buffer *buffer);
	int (print_debug)(struct ion_heap heap, struct seq_file *s,
	const struct rb_root *mem_map);
	int (secure_heap)(struct ion_heap heap, int version, void *data);
	int (unsecure_heap)(struct ion_heap heap, int version, void *data);
	int (secure_buffer)(struct ion_buffer buffer, int version,
	void *data, int flags);
	int (unsecure_buffer)(struct ion_buffer buffer, int force_unsecure);
	};

	/**
	* struct ion_heap - represents a heap in the system
	* @node: rb node to put the heap on the device's tree of heaps
	* @dev: back pointer to the ion_device
	* @type: type of heap
	* @ops: ops struct as above
	* @id: id of heap, also indicates priority of this heap when
	* allocating. These are specified by platform data and
	* MUST be unique
	* @name: used for debugging
	* @priv: private heap data
	* @debug_show: called when heap debug file is read to add any
	* heap specific debug info to output
	*
	* Represents a pool of memory from which buffers can be made. In some
	* systems the only heap is regular system memory allocated via vmalloc.
	* On others, some blocks might require large physically contiguous buffers
	* that are allocated from a specially reserved heap.
	*/
	struct ion_heap {
	struct rb_node node;
	struct ion_device *dev;
	enum ion_heap_type type;
	struct ion_heap_ops *ops;
	int id;
	const char *name;
	void *priv;
	int (debug_show)(struct ion_heap heap, struct seq_file , void );
	};

	/**
	* ion_buffer_cached - this ion buffer is cached
	* @buffer: buffer
	*
	* indicates whether this ion buffer is cached
	*/
	bool ion_buffer_cached(struct ion_buffer *buffer);

	/**
	* ion_buffer_fault_user_mappings - fault in user mappings of this buffer
	* @buffer: buffer
	*
	* indicates whether userspace mappings of this buffer will be faulted
	* in, this can affect how buffers are allocated from the heap.
	*/
	bool ion_buffer_fault_user_mappings(struct ion_buffer *buffer);

	/**
	* ion_device_create - allocates and returns an ion device
	* @custom_ioctl: arch specific ioctl function if applicable
	*
	* returns a valid device or -PTR_ERR
	*/
	struct ion_device ion_device_create(long (custom_ioctl)
	(struct ion_client *client,
	unsigned int cmd,
	unsigned long arg));

	/**
	* ion_device_destroy - free and device and it's resource
	* @dev: the device
	*/
	void ion_device_destroy(struct ion_device *dev);

	/**
	* ion_device_add_heap - adds a heap to the ion device
	* @dev: the device
	* @heap: the heap to add
	*/
	void ion_device_add_heap(struct ion_device dev, struct ion_heap heap);

	/**
	* functions for creating and destroying the built in ion heaps.
	* architectures can add their own custom architecture specific
	* heaps as appropriate.
	*/

	struct ion_heap ion_heap_create(struct ion_platform_heap );
	void ion_heap_destroy(struct ion_heap *);

	struct ion_heap ion_system_heap_create(struct ion_platform_heap );
	void ion_system_heap_destroy(struct ion_heap *);

	struct ion_heap ion_system_contig_heap_create(struct ion_platform_heap );
	void ion_system_contig_heap_destroy(struct ion_heap *);

	struct ion_heap ion_carveout_heap_create(struct ion_platform_heap );
	void ion_carveout_heap_destroy(struct ion_heap *);

	/**
	* kernel api to allocate/free from carveout -- used when carveout is
	* used to back an architecture specific custom heap
	*/
	ion_phys_addr_t ion_carveout_allocate(struct ion_heap *heap, unsigned long size,
	unsigned long align);
	void ion_carveout_free(struct ion_heap *heap, ion_phys_addr_t addr,
	unsigned long size);

	/**
	* The carveout heap returns physical addresses, since 0 may be a valid
	* physical address, this is used to indicate allocation failed
	*/
	#define ION_CARVEOUT_ALLOCATE_FAIL -1


	/**
	* functions for creating and destroying a heap pool -- allows you
	* to keep a pool of pre allocated memory to use from your heap. Keeping
	* a pool of memory that is ready for dma, ie any cached mapping have been
	* invalidated from the cache, provides a significant peformance benefit on
	* many systems */

	/**
	* struct ion_page_pool - pagepool struct
	* @count: number of items in the pool
	* @items: list of items
	* @shrinker: a shrinker for the items
	* @mutex: lock protecting this struct and especially the count
	* item list
	* @alloc: function to be used to allocate pageory when the pool
	* is empty
	* @free: function to be used to free pageory back to the system
	* when the shrinker fires
	* @gfp_mask: gfp_mask to use from alloc
	* @order: order of pages in the pool
	*
	* Allows you to keep a pool of pre allocated pages to use from your heap.
	* Keeping a pool of pages that is ready for dma, ie any cached mapping have
	* been invalidated from the cache, provides a significant peformance benefit
	* on many systems
	*/
	struct ion_page_pool {
	int count;
	struct list_head items;
	struct shrinker shrinker;
	struct mutex mutex;
	void (alloc)(struct ion_page_pool *pool);
	void (free)(struct ion_page_pool pool, struct page *page);
	gfp_t gfp_mask;
	unsigned int order;
	};

	struct ion_page_pool *ion_page_pool_create(gfp_t gfp_mask, unsigned int order);
	void ion_page_pool_destroy(struct ion_page_pool *);
	void ion_page_pool_alloc(struct ion_page_pool );
	void ion_page_pool_free(struct ion_page_pool , struct page );

	#endif /* _ION_PRIV_H */