include/net/page_pool.h - linux - Git at Google

 /* SPDX-License-Identifier: GPL-2.0
  *
  * page_pool.h
  *	Author:	Jesper Dangaard Brouer <netoptimizer@brouer.com>
  *	Copyright (C) 2016 Red Hat, Inc.
  */

 /**
  * DOC: page_pool allocator
  *
  * This page_pool allocator is optimized for the XDP mode that
  * uses one-frame-per-page, but have fallbacks that act like the
  * regular page allocator APIs.
  *
  * Basic use involve replacing alloc_pages() calls with the
  * page_pool_alloc_pages() call.  Drivers should likely use
  * page_pool_dev_alloc_pages() replacing dev_alloc_pages().
  *
  * If page_pool handles DMA mapping (use page->private), then API user
  * is responsible for invoking page_pool_put_page() once.  In-case of
  * elevated refcnt, the DMA state is released, assuming other users of
  * the page will eventually call put_page().
  *
  * If no DMA mapping is done, then it can act as shim-layer that
  * fall-through to alloc_page.  As no state is kept on the page, the
  * regular put_page() call is sufficient.
  */
 #ifndef _NET_PAGE_POOL_H
 #define _NET_PAGE_POOL_H

 #include <linux/mm.h> /* Needed by ptr_ring */
 #include <linux/ptr_ring.h>
 #include <linux/dma-direction.h>

 #define PP_FLAG_DMA_MAP 1 /* Should page_pool do the DMA map/unmap */
 #define PP_FLAG_ALL	PP_FLAG_DMA_MAP

 /*
  * Fast allocation side cache array/stack
  *
  * The cache size and refill watermark is related to the network
  * use-case.  The NAPI budget is 64 packets.  After a NAPI poll the RX
  * ring is usually refilled and the max consumed elements will be 64,
  * thus a natural max size of objects needed in the cache.
  *
  * Keeping room for more objects, is due to XDP_DROP use-case.  As
  * XDP_DROP allows the opportunity to recycle objects directly into
  * this array, as it shares the same softirq/NAPI protection.  If
  * cache is already full (or partly full) then the XDP_DROP recycles
  * would have to take a slower code path.
  */
 #define PP_ALLOC_CACHE_SIZE	128
 #define PP_ALLOC_CACHE_REFILL	64
 struct pp_alloc_cache {
 	u32 count;
 	void *cache[PP_ALLOC_CACHE_SIZE];
 };

 struct page_pool_params {
 	unsigned int	flags;
 	unsigned int	order;
 	unsigned int	pool_size;
 	int		nid;  /* Numa node id to allocate from pages from */
 	struct device	*dev; /* device, for DMA pre-mapping purposes */
 	enum dma_data_direction dma_dir; /* DMA mapping direction */
 };

 struct page_pool {
 	struct rcu_head rcu;
 	struct page_pool_params p;

 	/*
 	 * Data structure for allocation side
 	 *
 	 * Drivers allocation side usually already perform some kind
 	 * of resource protection.  Piggyback on this protection, and
 	 * require driver to protect allocation side.
 	 *
 	 * For NIC drivers this means, allocate a page_pool per
 	 * RX-queue. As the RX-queue is already protected by
 	 * Softirq/BH scheduling and napi_schedule. NAPI schedule
 	 * guarantee that a single napi_struct will only be scheduled
 	 * on a single CPU (see napi_schedule).
 	 */
 	struct pp_alloc_cache alloc ____cacheline_aligned_in_smp;

 	/* Data structure for storing recycled pages.
 	 *
 	 * Returning/freeing pages is more complicated synchronization
 	 * wise, because free's can happen on remote CPUs, with no
 	 * association with allocation resource.
 	 *
 	 * Use ptr_ring, as it separates consumer and producer
 	 * effeciently, it a way that doesn't bounce cache-lines.
 	 *
 	 * TODO: Implement bulk return pages into this structure.
 	 */
 	struct ptr_ring ring;
 };

 struct page *page_pool_alloc_pages(struct page_pool *pool, gfp_t gfp);

 static inline struct page *page_pool_dev_alloc_pages(struct page_pool *pool)
 {
 	gfp_t gfp = (GFP_ATOMIC | __GFP_NOWARN);

 	return page_pool_alloc_pages(pool, gfp);
 }

 struct page_pool *page_pool_create(const struct page_pool_params *params);

 void page_pool_destroy(struct page_pool *pool);

 /* Never call this directly, use helpers below */
 void __page_pool_put_page(struct page_pool *pool,
 			  struct page *page, bool allow_direct);

 static inline void page_pool_put_page(struct page_pool *pool,
 				      struct page *page, bool allow_direct)
 {
 	/* When page_pool isn't compiled-in, net/core/xdp.c doesn't
 	 * allow registering MEM_TYPE_PAGE_POOL, but shield linker.
 	 */
 #ifdef CONFIG_PAGE_POOL
 	__page_pool_put_page(pool, page, allow_direct);
 #endif
 }
 /* Very limited use-cases allow recycle direct */
 static inline void page_pool_recycle_direct(struct page_pool *pool,
 					    struct page *page)
 {
 	__page_pool_put_page(pool, page, true);
 }

 static inline bool is_page_pool_compiled_in(void)
 {
 #ifdef CONFIG_PAGE_POOL
 	return true;
 #else
 	return false;
 #endif
 }

 #endif /* _NET_PAGE_POOL_H */
	/* SPDX-License-Identifier: GPL-2.0
	*
	* page_pool.h
	* Author: Jesper Dangaard Brouer <netoptimizer@brouer.com>
	* Copyright (C) 2016 Red Hat, Inc.
	*/

	/**
	* DOC: page_pool allocator
	*
	* This page_pool allocator is optimized for the XDP mode that
	* uses one-frame-per-page, but have fallbacks that act like the
	* regular page allocator APIs.
	*
	* Basic use involve replacing alloc_pages() calls with the
	* page_pool_alloc_pages() call. Drivers should likely use
	* page_pool_dev_alloc_pages() replacing dev_alloc_pages().
	*
	* If page_pool handles DMA mapping (use page->private), then API user
	* is responsible for invoking page_pool_put_page() once. In-case of
	* elevated refcnt, the DMA state is released, assuming other users of
	* the page will eventually call put_page().
	*
	* If no DMA mapping is done, then it can act as shim-layer that
	* fall-through to alloc_page. As no state is kept on the page, the
	* regular put_page() call is sufficient.
	*/
	#ifndef _NET_PAGE_POOL_H
	#define _NET_PAGE_POOL_H

	#include <linux/mm.h> /* Needed by ptr_ring */
	#include <linux/ptr_ring.h>
	#include <linux/dma-direction.h>

	#define PP_FLAG_DMA_MAP 1 /* Should page_pool do the DMA map/unmap */
	#define PP_FLAG_ALL PP_FLAG_DMA_MAP

	/*
	* Fast allocation side cache array/stack
	*
	* The cache size and refill watermark is related to the network
	* use-case. The NAPI budget is 64 packets. After a NAPI poll the RX
	* ring is usually refilled and the max consumed elements will be 64,
	* thus a natural max size of objects needed in the cache.
	*
	* Keeping room for more objects, is due to XDP_DROP use-case. As
	* XDP_DROP allows the opportunity to recycle objects directly into
	* this array, as it shares the same softirq/NAPI protection. If
	* cache is already full (or partly full) then the XDP_DROP recycles
	* would have to take a slower code path.
	*/
	#define PP_ALLOC_CACHE_SIZE 128
	#define PP_ALLOC_CACHE_REFILL 64
	struct pp_alloc_cache {
	u32 count;
	void *cache[PP_ALLOC_CACHE_SIZE];
	};

	struct page_pool_params {
	unsigned int flags;
	unsigned int order;
	unsigned int pool_size;
	int nid; /* Numa node id to allocate from pages from */
	struct device dev; / device, for DMA pre-mapping purposes */
	enum dma_data_direction dma_dir; /* DMA mapping direction */
	};

	struct page_pool {
	struct rcu_head rcu;
	struct page_pool_params p;

	/*
	* Data structure for allocation side
	*
	* Drivers allocation side usually already perform some kind
	* of resource protection. Piggyback on this protection, and
	* require driver to protect allocation side.
	*
	* For NIC drivers this means, allocate a page_pool per
	* RX-queue. As the RX-queue is already protected by
	* Softirq/BH scheduling and napi_schedule. NAPI schedule
	* guarantee that a single napi_struct will only be scheduled
	* on a single CPU (see napi_schedule).
	*/
	struct pp_alloc_cache alloc ____cacheline_aligned_in_smp;

	/* Data structure for storing recycled pages.
	*
	* Returning/freeing pages is more complicated synchronization
	* wise, because free's can happen on remote CPUs, with no
	* association with allocation resource.
	*
	* Use ptr_ring, as it separates consumer and producer
	* effeciently, it a way that doesn't bounce cache-lines.
	*
	* TODO: Implement bulk return pages into this structure.
	*/
	struct ptr_ring ring;
	};

	struct page page_pool_alloc_pages(struct page_pool pool, gfp_t gfp);

	static inline struct page page_pool_dev_alloc_pages(struct page_pool pool)
	{
	gfp_t gfp = (GFP_ATOMIC \| __GFP_NOWARN);

	return page_pool_alloc_pages(pool, gfp);
	}

	struct page_pool page_pool_create(const struct page_pool_params params);

	void page_pool_destroy(struct page_pool *pool);

	/* Never call this directly, use helpers below */
	void __page_pool_put_page(struct page_pool *pool,
	struct page *page, bool allow_direct);

	static inline void page_pool_put_page(struct page_pool *pool,
	struct page *page, bool allow_direct)
	{
	/* When page_pool isn't compiled-in, net/core/xdp.c doesn't
	* allow registering MEM_TYPE_PAGE_POOL, but shield linker.
	*/
	#ifdef CONFIG_PAGE_POOL
	__page_pool_put_page(pool, page, allow_direct);
	#endif
	}
	/* Very limited use-cases allow recycle direct */
	static inline void page_pool_recycle_direct(struct page_pool *pool,
	struct page *page)
	{
	__page_pool_put_page(pool, page, true);
	}

	static inline bool is_page_pool_compiled_in(void)
	{
	#ifdef CONFIG_PAGE_POOL
	return true;
	#else
	return false;
	#endif
	}

	#endif /* _NET_PAGE_POOL_H */