Blame - fs/xfs/kmem.h - hafnium/third_party/linux

blob: 8e6b3ba81c03e398d2b91c76c456760c2a97ae82 [file] [log] [blame]

Andrew Scull	b4b6d4a	2019-01-02 15:54:55 +0000	[diff] [blame]	1	// SPDX-License-Identifier: GPL-2.0
				2	/*
				3	* Copyright (c) 2000-2005 Silicon Graphics, Inc.
				4	* All Rights Reserved.
				5	*/
				6	#ifndef __XFS_SUPPORT_KMEM_H__
				7	#define __XFS_SUPPORT_KMEM_H__
				8
				9	#include <linux/slab.h>
				10	#include <linux/sched.h>
				11	#include <linux/mm.h>
				12	#include <linux/vmalloc.h>
				13
				14	/*
				15	* General memory allocation interfaces
				16	*/
				17
				18	typedef unsigned __bitwise xfs_km_flags_t;
				19	#define KM_SLEEP ((__force xfs_km_flags_t)0x0001u)
				20	#define KM_NOSLEEP ((__force xfs_km_flags_t)0x0002u)
				21	#define KM_NOFS ((__force xfs_km_flags_t)0x0004u)
				22	#define KM_MAYFAIL ((__force xfs_km_flags_t)0x0008u)
				23	#define KM_ZERO ((__force xfs_km_flags_t)0x0010u)
				24
				25	/*
				26	* We use a special process flag to avoid recursive callbacks into
				27	* the filesystem during transactions. We will also issue our own
				28	* warnings, so we explicitly skip any generic ones (silly of us).
				29	*/
				30	static inline gfp_t
				31	kmem_flags_convert(xfs_km_flags_t flags)
				32	{
				33	gfp_t lflags;
				34
				35	BUG_ON(flags & ~(KM_SLEEP\|KM_NOSLEEP\|KM_NOFS\|KM_MAYFAIL\|KM_ZERO));
				36
				37	if (flags & KM_NOSLEEP) {
				38	lflags = GFP_ATOMIC \| __GFP_NOWARN;
				39	} else {
				40	lflags = GFP_KERNEL \| __GFP_NOWARN;
				41	if (flags & KM_NOFS)
				42	lflags &= ~__GFP_FS;
				43	}
				44
				45	/*
				46	* Default page/slab allocator behavior is to retry for ever
				47	* for small allocations. We can override this behavior by using
				48	* __GFP_RETRY_MAYFAIL which will tell the allocator to retry as long
				49	* as it is feasible but rather fail than retry forever for all
				50	* request sizes.
				51	*/
				52	if (flags & KM_MAYFAIL)
				53	lflags \|= __GFP_RETRY_MAYFAIL;
				54
				55	if (flags & KM_ZERO)
				56	lflags \|= __GFP_ZERO;
				57
				58	return lflags;
				59	}
				60
				61	extern void *kmem_alloc(size_t, xfs_km_flags_t);
				62	extern void *kmem_alloc_large(size_t size, xfs_km_flags_t);
				63	extern void kmem_realloc(const void , size_t, xfs_km_flags_t);
				64	static inline void kmem_free(const void *ptr)
				65	{
				66	kvfree(ptr);
				67	}
				68
				69
				70	static inline void *
				71	kmem_zalloc(size_t size, xfs_km_flags_t flags)
				72	{
				73	return kmem_alloc(size, flags \| KM_ZERO);
				74	}
				75
				76	static inline void *
				77	kmem_zalloc_large(size_t size, xfs_km_flags_t flags)
				78	{
				79	return kmem_alloc_large(size, flags \| KM_ZERO);
				80	}
				81
				82	/*
				83	* Zone interfaces
				84	*/
				85
				86	#define KM_ZONE_HWALIGN SLAB_HWCACHE_ALIGN
				87	#define KM_ZONE_RECLAIM SLAB_RECLAIM_ACCOUNT
				88	#define KM_ZONE_SPREAD SLAB_MEM_SPREAD
				89	#define KM_ZONE_ACCOUNT SLAB_ACCOUNT
				90
				91	#define kmem_zone kmem_cache
				92	#define kmem_zone_t struct kmem_cache
				93
				94	static inline kmem_zone_t *
				95	kmem_zone_init(int size, char *zone_name)
				96	{
				97	return kmem_cache_create(zone_name, size, 0, 0, NULL);
				98	}
				99
				100	static inline kmem_zone_t *
				101	kmem_zone_init_flags(int size, char *zone_name, slab_flags_t flags,
				102	void (construct)(void ))
				103	{
				104	return kmem_cache_create(zone_name, size, 0, flags, construct);
				105	}
				106
				107	static inline void
				108	kmem_zone_free(kmem_zone_t zone, void ptr)
				109	{
				110	kmem_cache_free(zone, ptr);
				111	}
				112
				113	static inline void
				114	kmem_zone_destroy(kmem_zone_t *zone)
				115	{
				116	kmem_cache_destroy(zone);
				117	}
				118
				119	extern void kmem_zone_alloc(kmem_zone_t , xfs_km_flags_t);
				120
				121	static inline void *
				122	kmem_zone_zalloc(kmem_zone_t *zone, xfs_km_flags_t flags)
				123	{
				124	return kmem_zone_alloc(zone, flags \| KM_ZERO);
				125	}
				126
				127	#endif /* __XFS_SUPPORT_KMEM_H__ */