/*
 * GPL HEADER START
 *
 * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
 *
 * This program is free software; you can redistribute it and/or modify
 * it under the terms of the GNU General Public License version 2 only,
 * as published by the Free Software Foundation.
 *
 * 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 version 2 for more details (a copy is included
 * in the LICENSE file that accompanied this code).
 *
 * You should have received a copy of the GNU General Public License
 * version 2 along with this program; If not, see
 * http://www.sun.com/software/products/lustre/docs/GPLv2.pdf
 *
 * Please contact Sun Microsystems, Inc., 4150 Network Circle, Santa Clara,
 * CA 95054 USA or visit www.sun.com if you need additional information or
 * have any questions.
 *
 * GPL HEADER END
 */
/*
 * Copyright (c) 2008, 2010, Oracle and/or its affiliates. All rights reserved.
 * Use is subject to license terms.
 *
 * Copyright (c) 2011, 2012, Intel Corporation.
 */
/*
 * This file is part of Lustre, http://www.lustre.org/
 * Lustre is a trademark of Sun Microsystems, Inc.
 *
 * libcfs/include/libcfs/libcfs_private.h
 *
 * Various defines for libcfs.
 *
 */

#ifndef __LIBCFS_PRIVATE_H__
#define __LIBCFS_PRIVATE_H__

/* XXX this layering violation is for nidstrings */
#include <linux/lnet/types.h>

#ifndef DEBUG_SUBSYSTEM
# define DEBUG_SUBSYSTEM S_UNDEFINED
#endif



/*
 * When this is on, LASSERT macro includes check for assignment used instead
 * of equality check, but doesn't have unlikely(). Turn this on from time to
 * time to make test-builds. This shouldn't be on for production release.
 */
#define LASSERT_CHECKED (0)


#define LASSERTF(cond, fmt, ...)					\
do {									\
	if (unlikely(!(cond))) {					\
		LIBCFS_DEBUG_MSG_DATA_DECL(__msg_data, D_EMERG, NULL);	\
		libcfs_debug_msg(&__msg_data,				\
				 "ASSERTION( %s ) failed: " fmt, #cond,	\
				 ## __VA_ARGS__);			\
		lbug_with_loc(&__msg_data);				\
	}								\
} while (0)

#define LASSERT(cond) LASSERTF(cond, "\n")

#ifdef CONFIG_LUSTRE_DEBUG_EXPENSIVE_CHECK
/**
 * This is for more expensive checks that one doesn't want to be enabled all
 * the time. LINVRNT() has to be explicitly enabled by
 * CONFIG_LUSTRE_DEBUG_EXPENSIVE_CHECK option.
 */
# define LINVRNT(exp) LASSERT(exp)
#else
# define LINVRNT(exp) ((void)sizeof!!(exp))
#endif

#define KLASSERT(e) LASSERT(e)

void lbug_with_loc(struct libcfs_debug_msg_data *) __attribute__((noreturn));

#define LBUG()							  \
do {								    \
	LIBCFS_DEBUG_MSG_DATA_DECL(msgdata, D_EMERG, NULL);	     \
	lbug_with_loc(&msgdata);					\
} while(0)

extern atomic_t libcfs_kmemory;
/*
 * Memory
 */

# define libcfs_kmem_inc(ptr, size)		\
do {						\
	atomic_add(size, &libcfs_kmemory);	\
} while (0)

# define libcfs_kmem_dec(ptr, size)		\
do {						\
	atomic_sub(size, &libcfs_kmemory);	\
} while (0)

# define libcfs_kmem_read()			\
	atomic_read(&libcfs_kmemory)


#ifndef LIBCFS_VMALLOC_SIZE
#define LIBCFS_VMALLOC_SIZE	(2 << PAGE_CACHE_SHIFT) /* 2 pages */
#endif

#define LIBCFS_ALLOC_PRE(size, mask)					    \
do {									    \
	LASSERT(!in_interrupt() ||					    \
		((size) <= LIBCFS_VMALLOC_SIZE &&			    \
		 ((mask) & GFP_ATOMIC)) != 0);			    \
} while (0)

#define LIBCFS_ALLOC_POST(ptr, size)					    \
do {									    \
	if (unlikely((ptr) == NULL)) {					    \
		CERROR("LNET: out of memory at %s:%d (tried to alloc '"	    \
		       #ptr "' = %d)\n", __FILE__, __LINE__, (int)(size));  \
		CERROR("LNET: %d total bytes allocated by lnet\n",	    \
		       libcfs_kmem_read());				    \
	} else {							    \
		memset((ptr), 0, (size));				    \
		libcfs_kmem_inc((ptr), (size));				    \
		CDEBUG(D_MALLOC, "alloc '" #ptr "': %d at %p (tot %d).\n",  \
		       (int)(size), (ptr), libcfs_kmem_read());		    \
	}								   \
} while (0)

/**
 * allocate memory with GFP flags @mask
 */
#define LIBCFS_ALLOC_GFP(ptr, size, mask)				    \
do {									    \
	LIBCFS_ALLOC_PRE((size), (mask));				    \
	(ptr) = (size) <= LIBCFS_VMALLOC_SIZE ?				    \
		kmalloc((size), (mask)) : vmalloc(size);	    \
	LIBCFS_ALLOC_POST((ptr), (size));				    \
} while (0)

/**
 * default allocator
 */
#define LIBCFS_ALLOC(ptr, size) \
	LIBCFS_ALLOC_GFP(ptr, size, __GFP_IO)

/**
 * non-sleeping allocator
 */
#define LIBCFS_ALLOC_ATOMIC(ptr, size) \
	LIBCFS_ALLOC_GFP(ptr, size, GFP_ATOMIC)

/**
 * allocate memory for specified CPU partition
 *   \a cptab != NULL, \a cpt is CPU partition id of \a cptab
 *   \a cptab == NULL, \a cpt is HW NUMA node id
 */
#define LIBCFS_CPT_ALLOC_GFP(ptr, cptab, cpt, size, mask)		    \
do {									    \
	LIBCFS_ALLOC_PRE((size), (mask));				    \
	(ptr) = (size) <= LIBCFS_VMALLOC_SIZE ?				    \
		kmalloc_node((size), (mask), cfs_cpt_spread_node(cptab, cpt)) :\
		vmalloc_node(size, cfs_cpt_spread_node(cptab, cpt));	    \
	LIBCFS_ALLOC_POST((ptr), (size));				    \
} while (0)

/** default numa allocator */
#define LIBCFS_CPT_ALLOC(ptr, cptab, cpt, size)				    \
	LIBCFS_CPT_ALLOC_GFP(ptr, cptab, cpt, size, __GFP_IO)

#define LIBCFS_FREE(ptr, size)					  \
do {								    \
	int s = (size);						 \
	if (unlikely((ptr) == NULL)) {				  \
		CERROR("LIBCFS: free NULL '" #ptr "' (%d bytes) at "    \
		       "%s:%d\n", s, __FILE__, __LINE__);	       \
		break;						  \
	}							       \
	libcfs_kmem_dec((ptr), s);				      \
	CDEBUG(D_MALLOC, "kfreed '" #ptr "': %d at %p (tot %d).\n",     \
	       s, (ptr), libcfs_kmem_read());				\
	if (unlikely(s > LIBCFS_VMALLOC_SIZE))			  \
		vfree(ptr);				    \
	else							    \
		kfree(ptr);					  \
} while (0)

/******************************************************************************/

/* htonl hack - either this, or compile with -O2. Stupid byteorder/generic.h */
#if defined(__GNUC__) && (__GNUC__ >= 2) && !defined(__OPTIMIZE__)
#define ___htonl(x) __cpu_to_be32(x)
#define ___htons(x) __cpu_to_be16(x)
#define ___ntohl(x) __be32_to_cpu(x)
#define ___ntohs(x) __be16_to_cpu(x)
#define htonl(x) ___htonl(x)
#define ntohl(x) ___ntohl(x)
#define htons(x) ___htons(x)
#define ntohs(x) ___ntohs(x)
#endif

void libcfs_debug_dumpstack(task_t *tsk);
void libcfs_run_upcall(char **argv);
void libcfs_run_lbug_upcall(struct libcfs_debug_msg_data *);
void libcfs_debug_dumplog(void);
int libcfs_debug_init(unsigned long bufsize);
int libcfs_debug_cleanup(void);
int libcfs_debug_clear_buffer(void);
int libcfs_debug_mark_buffer(const char *text);

void libcfs_debug_set_level(unsigned int debug_level);


/*
 * allocate per-cpu-partition data, returned value is an array of pointers,
 * variable can be indexed by CPU ID.
 *	cptable != NULL: size of array is number of CPU partitions
 *	cptable == NULL: size of array is number of HW cores
 */
void *cfs_percpt_alloc(struct cfs_cpt_table *cptab, unsigned int size);
/*
 * destory per-cpu-partition variable
 */
void  cfs_percpt_free(void *vars);
int   cfs_percpt_number(void *vars);
void *cfs_percpt_current(void *vars);
void *cfs_percpt_index(void *vars, int idx);

#define cfs_percpt_for_each(var, i, vars)		\
	for (i = 0; i < cfs_percpt_number(vars) &&	\
		    ((var) = (vars)[i]) != NULL; i++)

/*
 * allocate a variable array, returned value is an array of pointers.
 * Caller can specify length of array by count.
 */
void *cfs_array_alloc(int count, unsigned int size);
void  cfs_array_free(void *vars);

#define LASSERT_ATOMIC_ENABLED	  (1)

#if LASSERT_ATOMIC_ENABLED

/** assert value of @a is equal to @v */
#define LASSERT_ATOMIC_EQ(a, v)				 \
do {							    \
	LASSERTF(atomic_read(a) == v,		       \
		 "value: %d\n", atomic_read((a)));	  \
} while (0)

/** assert value of @a is unequal to @v */
#define LASSERT_ATOMIC_NE(a, v)				 \
do {							    \
	LASSERTF(atomic_read(a) != v,		       \
		 "value: %d\n", atomic_read((a)));	  \
} while (0)

/** assert value of @a is little than @v */
#define LASSERT_ATOMIC_LT(a, v)				 \
do {							    \
	LASSERTF(atomic_read(a) < v,			\
		 "value: %d\n", atomic_read((a)));	  \
} while (0)

/** assert value of @a is little/equal to @v */
#define LASSERT_ATOMIC_LE(a, v)				 \
do {							    \
	LASSERTF(atomic_read(a) <= v,		       \
		 "value: %d\n", atomic_read((a)));	  \
} while (0)

/** assert value of @a is great than @v */
#define LASSERT_ATOMIC_GT(a, v)				 \
do {							    \
	LASSERTF(atomic_read(a) > v,			\
		 "value: %d\n", atomic_read((a)));	  \
} while (0)

/** assert value of @a is great/equal to @v */
#define LASSERT_ATOMIC_GE(a, v)				 \
do {							    \
	LASSERTF(atomic_read(a) >= v,		       \
		 "value: %d\n", atomic_read((a)));	  \
} while (0)

/** assert value of @a is great than @v1 and little than @v2 */
#define LASSERT_ATOMIC_GT_LT(a, v1, v2)			 \
do {							    \
	int __v = atomic_read(a);			   \
	LASSERTF(__v > v1 && __v < v2, "value: %d\n", __v);     \
} while (0)

/** assert value of @a is great than @v1 and little/equal to @v2 */
#define LASSERT_ATOMIC_GT_LE(a, v1, v2)			 \
do {							    \
	int __v = atomic_read(a);			   \
	LASSERTF(__v > v1 && __v <= v2, "value: %d\n", __v);    \
} while (0)

/** assert value of @a is great/equal to @v1 and little than @v2 */
#define LASSERT_ATOMIC_GE_LT(a, v1, v2)			 \
do {							    \
	int __v = atomic_read(a);			   \
	LASSERTF(__v >= v1 && __v < v2, "value: %d\n", __v);    \
} while (0)

/** assert value of @a is great/equal to @v1 and little/equal to @v2 */
#define LASSERT_ATOMIC_GE_LE(a, v1, v2)			 \
do {							    \
	int __v = atomic_read(a);			   \
	LASSERTF(__v >= v1 && __v <= v2, "value: %d\n", __v);   \
} while (0)

#else /* !LASSERT_ATOMIC_ENABLED */

#define LASSERT_ATOMIC_EQ(a, v)		 do {} while (0)
#define LASSERT_ATOMIC_NE(a, v)		 do {} while (0)
#define LASSERT_ATOMIC_LT(a, v)		 do {} while (0)
#define LASSERT_ATOMIC_LE(a, v)		 do {} while (0)
#define LASSERT_ATOMIC_GT(a, v)		 do {} while (0)
#define LASSERT_ATOMIC_GE(a, v)		 do {} while (0)
#define LASSERT_ATOMIC_GT_LT(a, v1, v2)	 do {} while (0)
#define LASSERT_ATOMIC_GT_LE(a, v1, v2)	 do {} while (0)
#define LASSERT_ATOMIC_GE_LT(a, v1, v2)	 do {} while (0)
#define LASSERT_ATOMIC_GE_LE(a, v1, v2)	 do {} while (0)

#endif /* LASSERT_ATOMIC_ENABLED */

#define LASSERT_ATOMIC_ZERO(a)		  LASSERT_ATOMIC_EQ(a, 0)
#define LASSERT_ATOMIC_POS(a)		   LASSERT_ATOMIC_GT(a, 0)

#define CFS_ALLOC_PTR(ptr)      LIBCFS_ALLOC(ptr, sizeof (*(ptr)));
#define CFS_FREE_PTR(ptr)       LIBCFS_FREE(ptr, sizeof (*(ptr)));

/*
 * percpu partition lock
 *
 * There are some use-cases like this in Lustre:
 * . each CPU partition has it's own private data which is frequently changed,
 *   and mostly by the local CPU partition.
 * . all CPU partitions share some global data, these data are rarely changed.
 *
 * LNet is typical example.
 * CPU partition lock is designed for this kind of use-cases:
 * . each CPU partition has it's own private lock
 * . change on private data just needs to take the private lock
 * . read on shared data just needs to take _any_ of private locks
 * . change on shared data needs to take _all_ private locks,
 *   which is slow and should be really rare.
 */

enum {
	CFS_PERCPT_LOCK_EX	= -1, /* negative */
};


struct cfs_percpt_lock {
	/* cpu-partition-table for this lock */
	struct cfs_cpt_table	*pcl_cptab;
	/* exclusively locked */
	unsigned int		pcl_locked;
	/* private lock table */
	spinlock_t		**pcl_locks;
};

/* return number of private locks */
static inline int
cfs_percpt_lock_num(struct cfs_percpt_lock *pcl)
{
	return cfs_cpt_number(pcl->pcl_cptab);
}


/*
 * create a cpu-partition lock based on CPU partition table \a cptab,
 * each private lock has extra \a psize bytes padding data
 */
struct cfs_percpt_lock *cfs_percpt_lock_alloc(struct cfs_cpt_table *cptab);
/* destroy a cpu-partition lock */
void cfs_percpt_lock_free(struct cfs_percpt_lock *pcl);

/* lock private lock \a index of \a pcl */
void cfs_percpt_lock(struct cfs_percpt_lock *pcl, int index);
/* unlock private lock \a index of \a pcl */
void cfs_percpt_unlock(struct cfs_percpt_lock *pcl, int index);
/* create percpt (atomic) refcount based on @cptab */
atomic_t **cfs_percpt_atomic_alloc(struct cfs_cpt_table *cptab, int val);
/* destroy percpt refcount */
void cfs_percpt_atomic_free(atomic_t **refs);
/* return sum of all percpu refs */
int cfs_percpt_atomic_summary(atomic_t **refs);


/** Compile-time assertion.

 * Check an invariant described by a constant expression at compile time by
 * forcing a compiler error if it does not hold.  \a cond must be a constant
 * expression as defined by the ISO C Standard:
 *
 *       6.8.4.2  The switch statement
 *       ....
 *       [#3] The expression of each case label shall be  an  integer
 *       constant   expression  and  no  two  of  the  case  constant
 *       expressions in the same switch statement shall have the same
 *       value  after  conversion...
 *
 */
#define CLASSERT(cond) do {switch(42) {case (cond): case 0: break;}} while (0)

/* support decl needed both by kernel and liblustre */
int	 libcfs_isknown_lnd(int type);
char       *libcfs_lnd2modname(int type);
char       *libcfs_lnd2str(int type);
int	 libcfs_str2lnd(const char *str);
char       *libcfs_net2str(__u32 net);
char       *libcfs_nid2str(lnet_nid_t nid);
__u32       libcfs_str2net(const char *str);
lnet_nid_t  libcfs_str2nid(const char *str);
int	 libcfs_str2anynid(lnet_nid_t *nid, const char *str);
char       *libcfs_id2str(lnet_process_id_t id);
void	cfs_free_nidlist(struct list_head *list);
int	 cfs_parse_nidlist(char *str, int len, struct list_head *list);
int	 cfs_match_nid(lnet_nid_t nid, struct list_head *list);

/** \addtogroup lnet_addr
 * @{ */
/* how an LNET NID encodes net:address */
/** extract the address part of an lnet_nid_t */
#define LNET_NIDADDR(nid)      ((__u32)((nid) & 0xffffffff))
/** extract the network part of an lnet_nid_t */
#define LNET_NIDNET(nid)       ((__u32)(((nid) >> 32)) & 0xffffffff)
/** make an lnet_nid_t from a network part and an address part */
#define LNET_MKNID(net,addr)   ((((__u64)(net))<<32)|((__u64)(addr)))
/* how net encodes type:number */
#define LNET_NETNUM(net)       ((net) & 0xffff)
#define LNET_NETTYP(net)       (((net) >> 16) & 0xffff)
#define LNET_MKNET(typ,num)    ((((__u32)(typ))<<16)|((__u32)(num)))
/** @} lnet_addr */

/* max value for numeric network address */
#define MAX_NUMERIC_VALUE 0xffffffff

/* implication */
#define ergo(a, b) (!(a) || (b))
/* logical equivalence */
#define equi(a, b) (!!(a) == !!(b))

#ifndef CFS_CURRENT_TIME
# define CFS_CURRENT_TIME time(0)
#endif

/* --------------------------------------------------------------------
 * Light-weight trace
 * Support for temporary event tracing with minimal Heisenberg effect.
 * All stuff about lwt are put in arch/kp30.h
 * -------------------------------------------------------------------- */

struct libcfs_device_userstate
{
	int	   ldu_memhog_pages;
	struct page   *ldu_memhog_root_page;
};

/* what used to be in portals_lib.h */
#ifndef MIN
# define MIN(a,b) (((a)<(b)) ? (a): (b))
#endif
#ifndef MAX
# define MAX(a,b) (((a)>(b)) ? (a): (b))
#endif

#define MKSTR(ptr) ((ptr))? (ptr) : ""

static inline int cfs_size_round4 (int val)
{
	return (val + 3) & (~0x3);
}

#ifndef HAVE_CFS_SIZE_ROUND
static inline int cfs_size_round (int val)
{
	return (val + 7) & (~0x7);
}
#define HAVE_CFS_SIZE_ROUND
#endif

static inline int cfs_size_round16(int val)
{
	return (val + 0xf) & (~0xf);
}

static inline int cfs_size_round32(int val)
{
	return (val + 0x1f) & (~0x1f);
}

static inline int cfs_size_round0(int val)
{
	if (!val)
		return 0;
	return (val + 1 + 7) & (~0x7);
}

static inline size_t cfs_round_strlen(char *fset)
{
	return (size_t)cfs_size_round((int)strlen(fset) + 1);
}

/* roundup \a val to power2 */
static inline unsigned int cfs_power2_roundup(unsigned int val)
{
	if (val != LOWEST_BIT_SET(val)) { /* not a power of 2 already */
		do {
			val &= ~LOWEST_BIT_SET(val);
		} while (val != LOWEST_BIT_SET(val));
		/* ...and round up */
		val <<= 1;
	}
	return val;
}

#define LOGL(var,len,ptr)				       \
do {							    \
	if (var)						\
		memcpy((char *)ptr, (const char *)var, len);    \
	ptr += cfs_size_round(len);			     \
} while (0)

#define LOGU(var,len,ptr)				       \
do {							    \
	if (var)						\
		memcpy((char *)var, (const char *)ptr, len);    \
	ptr += cfs_size_round(len);			     \
} while (0)

#define LOGL0(var,len,ptr)			      \
do {						    \
	if (!len)				       \
		break;				  \
	memcpy((char *)ptr, (const char *)var, len);    \
	*((char *)(ptr) + len) = 0;		     \
	ptr += cfs_size_round(len + 1);		 \
} while (0)

/**
 *  Lustre Network Driver types.
 */
enum {
	/* Only add to these values (i.e. don't ever change or redefine them):
	 * network addresses depend on them... */
	QSWLND    = 1,
	SOCKLND   = 2,
	GMLND     = 3, /* obsolete, keep it so that libcfs_nid2str works */
	PTLLND    = 4,
	O2IBLND   = 5,
	CIBLND    = 6,
	OPENIBLND = 7,
	IIBLND    = 8,
	LOLND     = 9,
	RALND     = 10,
	VIBLND    = 11,
	MXLND     = 12,
	GNILND    = 13,
};

#endif