WebSurf/content/fs_backing_store.c

/*
 * Copyright 2014 Vincent Sanders <vince@netsurf-browser.org>
 *
 * This file is part of NetSurf, http://www.netsurf-browser.org/
 *
 * NetSurf is free software; you can redistribute it and/or modify
 * it under the terms of the GNU General Public License as published by
 * the Free Software Foundation; version 2 of the License.
 *
 * NetSurf 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.
 *
 * You should have received a copy of the GNU General Public License
 * along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */

/**
 * \file
 * Low-level resource cache persistent storage implementation.
 *
 * file based backing store.
 *
 * \todo Consider improving eviction sorting to include objects size
 *         and remaining lifetime and other cost metrics.
 *
 * \todo make backing store have a more efficient small object storage.
 *
 */

#include <unistd.h>
#include <string.h>
#include <sys/stat.h>
#include <sys/types.h>
#include <fcntl.h>
#include <errno.h>
#include <time.h>
#include <stdlib.h>

#include "utils/filepath.h"
#include "utils/file.h"
#include "utils/nsurl.h"
#include "utils/log.h"
#include "utils/utils.h"
#include "utils/messages.h"
#include "desktop/gui_internal.h"
#include "desktop/gui_misc.h"

#include "content/backing_store.h"

/** Default number of bits of the ident to use in index hash */
#define DEFAULT_IDENT_SIZE 20

/** Default number of bits to use for an entry index. */
#define DEFAULT_ENTRY_SIZE 16

/** Backing store file format version */
#define CONTROL_VERSION 120

/** Number of milliseconds after a update before control data maintinance is performed  */
#define CONTROL_MAINT_TIME 10000

/** Get address from ident */
#define BS_ADDRESS(ident, state) ((ident) & ((1 << state->ident_bits) - 1))

/** Lookup store entry index from ident */
#define BS_ENTRY_INDEX(ident, state) state->addrmap[(ident) & ((1 << state->ident_bits) - 1)]

/** Get store entry from ident. */
#define BS_ENTRY(ident, state) state->entries[state->addrmap[(ident) & ((1 << state->ident_bits) - 1)]]

/** Filename of serialised entries */
#define ENTRIES_FNAME "entries"

/**
 * The type used to store index values refering to store entries. Care
 * must be taken with this type as it is used to build address to
 * entry mapping so changing the size will have large impacts on
 * memory usage.
 */
typedef uint16_t entry_index_t;

/**
 * The type used as a binary identifier for each entry derived from
 * the url. A larger identifier will have fewer collisions but
 * requires proportionately more storage.
 */
typedef uint32_t entry_ident_t;

/**
 * Entry extension index values.
 */
enum store_entry_elem_idx {
	ENTRY_ELEM_DATA = 0, /**< entry element is data */
	ENTRY_ELEM_META = 1,  /**< entry element is metadata */
	ENTRY_ELEM_COUNT = 2, /**< count of elements on an entry */
};

/**
 * flags that indicate what additional information is contained within
 * an entry element.
 */
enum store_entry_elem_flags {
	/** store not managing any allocation on entry */
	ENTRY_ELEM_FLAG_NONE = 0,
	/** entry data allocation is on heap */
	ENTRY_ELEM_FLAG_HEAP = 0x1,
	/** entry data allocation is mmaped */
	ENTRY_ELEM_FLAG_MMAP = 0x2,
	/** entry data allocation is in small object pool */
	ENTRY_ELEM_FLAG_SMALL = 0x4,
};


/**
 * Backing store entry element.
 *
 * @note Order is important to avoid excessive structure packing overhead.
 */
struct store_entry_element {
	union {
		struct {
			uint8_t* data; /**< data allocated on heap */
			uint8_t ref; /**< reference count */
		} __attribute__((__packed__)) heap;
		struct {
			uint8_t* data; /**< data is from an mmapping */
			uint8_t ref; /**< reference count */
		} __attribute__((__packed__)) map;
		struct {
			uint16_t block; /**< small object data block */
		} __attribute__((__packed__)) sml;
	} u ;
	uint8_t flags; /* extension flags */
	uint32_t size; /**< size of entry element on disc */
};

/**
 * Backing store object index entry.
 *
 * An entry in the backing store contains two elements for the actual
 * data and the metadata. The two elements are treated identically for
 * storage lifetime but as a collective whole for expiration and
 * indexing.
 *
 * @note Order is important to avoid excessive structure packing overhead.
 */
struct store_entry {
	int64_t last_used; /**< unix time the entry was last used */
	entry_ident_t ident; /**< entry identifier */
	uint16_t use_count; /**< number of times this entry has been accessed */
	/** Entry element (data or meta) specific information */
	struct store_entry_element elem[ENTRY_ELEM_COUNT];
};

/**
 * Parameters controlling the backing store.
 */
struct store_state {
	char *path; /**< The path to the backing store */
	size_t limit; /**< The backing store upper bound target size */
	size_t hysteresis; /**< The hysteresis around the target size */

	unsigned int ident_bits; /**< log2 number of bits to use for address. */

	struct store_entry *entries; /**< store entries. */
	unsigned int entry_bits; /**< log2 number of bits in entry index. */
	unsigned int last_entry; /**< index of last usable entry. */

	/** flag indicating if the entries have been made persistant
	 * since they were last changed.
	 */
	bool entries_dirty;

	/** URL identifier to entry index mapping.
	 *
	 * This is an open coded index on the entries url field and
	 * provides a computationaly inexpensive way to go from the
	 * url to an entry.
	 */
	entry_index_t *addrmap;

	uint64_t total_alloc; /**< total size of all allocated storage. */

	size_t hit_count; /**< number of cache hits */
	uint64_t hit_size; /**< size of storage served */
	size_t miss_count; /**< number of cache misses */

};

/**
 * Global storage state.
 *
 * @todo Investigate if there is a way to have a context rather than
 * use a global.
 */
struct store_state *storestate;


/**
 * Remove a backing store entry from the entry table.
 *
 * This finds the store entry associated with the given key and
 * removes it from the table. The removed entry is returned but is
 * only valid until the next set_store_entry call.
 *
 * @param state The store state to use.
 * @param ident The entry ident of the entry to store.
 * @param bse Pointer used to return value.
 * @return NSERROR_OK and bse updated on succes or NSERROR_NOT_FOUND
 *         if no entry coresponds to the url.
 */
static nserror
remove_store_entry(struct store_state *state,
		   entry_ident_t ident,
		   struct store_entry **bse)
{
	entry_index_t sei; /* store entry index */

	sei = BS_ENTRY_INDEX(ident, state);
	if (sei == 0) {
		LOG(("ident 0x%08x not in index", ident));
		return NSERROR_NOT_FOUND;
	}

	if (state->entries[sei].ident != ident) {
		/* entry ident did not match */
		LOG(("ident 0x%08x did not match entry index %d", ident, sei));
		return NSERROR_NOT_FOUND;
	}

	/* check if the entry has storage already allocated */
	if (((state->entries[sei].elem[ENTRY_ELEM_DATA].flags &
	     (ENTRY_ELEM_FLAG_HEAP | ENTRY_ELEM_FLAG_MMAP)) != 0) ||
	    ((state->entries[sei].elem[ENTRY_ELEM_META].flags &
	      (ENTRY_ELEM_FLAG_HEAP | ENTRY_ELEM_FLAG_MMAP)) != 0)) {
		/* this entry cannot be removed as it has associated
		 * allocation.
		 */
		LOG(("attempt to remove entry with in use data"));
		return NSERROR_PERMISSION;
	}

	/* sei is entry to be removed, we swap it to the end of the
	 * table so there are no gaps and the returned entry is held
	 * in storage with reasonable lifetime.
	 */

	/* remove entry from map */
	BS_ENTRY_INDEX(ident, state) = 0;

	/* global allocation accounting  */
	state->total_alloc -= state->entries[sei].elem[ENTRY_ELEM_DATA].size;
	state->total_alloc -= state->entries[sei].elem[ENTRY_ELEM_META].size;

	state->last_entry--;

	if (sei == state->last_entry) {
		/* the removed entry was the last one, how convenient */
		*bse = &state->entries[sei];
	} else {
		/* need to swap entries */
		struct store_entry tent;

		tent = state->entries[sei];
		state->entries[sei] = state->entries[state->last_entry];
		state->entries[state->last_entry] = tent;

		/* update map for moved entry */
		BS_ENTRY_INDEX(state->entries[sei].ident, state) = sei;

		*bse = &state->entries[state->last_entry];
	}

	return NSERROR_OK;
}


/**
 * Generate a filename for an object.
 *
 * this generates the filename for an object on disc. It is necessary
 * for this to generate a filename which conforms to the limitations
 * of all the filesystems the cache can be placed upon.
 *
 * From http://en.wikipedia.org/wiki/Comparison_of_file_systems#Limits
 * the relevant subset is:
 *  - path elements no longer than 8 characters
 *  - acceptable characters are A-Z, 0-9
 *  - short total path lengths (255 or less)
 *
 * The short total path lengths mean the encoding must represent as
 * much data as possible in the least number of characters.
 *
 * To achieve all these goals we use RFC4648 base32 encoding which packs
 * 5bits into each character of the filename.
 *
 * @note Version 1.00 of the cache implementation used base64 to
 * encode this, however that did not meet the requirement for only
 * using uppercase characters.
 *
 * @param state The store state to use.
 * @param ident The identifier to use.
 * @param flags flags to control the filename used.
 * @return The filename string or NULL on allocation error.
 */
static char *
store_fname(struct store_state *state,
	    entry_ident_t ident,
	    enum backing_store_flags flags)
{
	char *fname = NULL;
	uint8_t b32u_i[8]; /* base32 encoded ident */
	uint8_t b32u_d[6][2]; /* base32 ident as separate components */
	const char *dat;

	/* RFC4648 base32 encoding table */
	static const uint8_t encoding_table[] = {
		'A', 'B', 'C', 'D', 'E', 'F', 'G', 'H',
		'I', 'J', 'K', 'L', 'M', 'N', 'O', 'P',
		'Q', 'R', 'S', 'T', 'U', 'V', 'W', 'X',
		'Y', 'Z', '2', '3', '4', '5', '6', '7'
	};

	/* base32 encode ident */
	b32u_i[0] = b32u_d[0][0] = encoding_table[(ident      ) & 0x1f];
	b32u_i[1] = b32u_d[1][0] = encoding_table[(ident >>  5) & 0x1f];
	b32u_i[2] = b32u_d[2][0] = encoding_table[(ident >> 10) & 0x1f];
	b32u_i[3] = b32u_d[3][0] = encoding_table[(ident >> 15) & 0x1f];
	b32u_i[4] = b32u_d[4][0] = encoding_table[(ident >> 20) & 0x1f];
	b32u_i[5] = b32u_d[5][0] = encoding_table[(ident >> 25) & 0x1f];
	b32u_i[6] = encoding_table[(ident >> 30) & 0x1f];
	/* null terminate strings */
	b32u_i[7] = b32u_d[0][1] = b32u_d[1][1] = b32u_d[2][1] =
		b32u_d[3][1] = b32u_d[4][1] = b32u_d[5][1] = 0;

	if ((flags & BACKING_STORE_META) != 0) {
		dat = "m"; /* metadata */
	} else {
		dat = "d"; /* data */
	}

	/* number of chars with usefully encoded data in base 32 */
	switch(((state->ident_bits + 4) / 5)) {
	case 1:
		netsurf_mkpath(&fname, NULL, 3, state->path, dat,
			       b32u_i);
		break;

	case 2:
		netsurf_mkpath(&fname, NULL, 4, state->path, dat,
			       b32u_d[0],
			       b32u_i);
		break;

	case 3:
		netsurf_mkpath(&fname, NULL, 5, state->path, dat,
			       b32u_d[0], b32u_d[1],
			       b32u_i);
		break;

	case 4:
		netsurf_mkpath(&fname, NULL, 6, state->path, dat,
			       b32u_d[0], b32u_d[1], b32u_d[2],
			       b32u_i);
		break;

	case 5:
		netsurf_mkpath(&fname, NULL, 7, state->path, dat,
			       b32u_d[0], b32u_d[1], b32u_d[2], b32u_d[3],
			       b32u_i);
		break;

	case 6:
		netsurf_mkpath(&fname, NULL, 8, state->path, dat,
			       b32u_d[0], b32u_d[1], b32u_d[2], b32u_d[3],
			       b32u_d[4],
			       b32u_i);
		break;

	case 7:
		netsurf_mkpath(&fname, NULL, 9, state->path, dat,
			       b32u_d[0], b32u_d[1], b32u_d[2], b32u_d[3],
			       b32u_d[4], b32u_d[5],
			       b32u_i);
		break;

	default:
		assert("Invalid path depth in store_fname()" == NULL);
	}

	return fname;
}


/**
 * Remove the entry and files associated with an identifier.
 *
 * @param state The store state to use.
 * @param ident The identifier to use.
 * @return NSERROR_OK on sucess or error code on failure.
 */
static nserror
unlink_ident(struct store_state *state, entry_ident_t ident)
{
	char *fname;
	nserror ret;
	struct store_entry *bse;

	/* LOG(("ident %08x", ident)); */

	/* use the url hash as the entry identifier */
	ret = remove_store_entry(state, ident, &bse);
	if (ret != NSERROR_OK) {
		/* LOG(("entry not found")); */
		return ret;
	}

	fname = store_fname(state, bse->ident, BACKING_STORE_META);
	if (fname == NULL) {
		return NSERROR_NOMEM;
	}
	unlink(fname);
	free(fname);

	fname = store_fname(state, bse->ident, BACKING_STORE_NONE);
	if (fname == NULL) {
		return NSERROR_NOMEM;
	}
	unlink(fname);
	free(fname);

	return NSERROR_OK;
}


/**
 * Quick sort comparison.
 */
static int compar(const void *va, const void *vb)
{
	const struct store_entry *a = &BS_ENTRY(*(entry_ident_t *)va, storestate);
	const struct store_entry *b = &BS_ENTRY(*(entry_ident_t *)vb, storestate);

	/* consider the allocation flags - if an entry has an
	 * allocation it is considered more valuble as it cannot be
	 * freed.
	 */
	if ((a->elem[ENTRY_ELEM_DATA].flags == ENTRY_ELEM_FLAG_NONE) &&
	    (b->elem[ENTRY_ELEM_DATA].flags != ENTRY_ELEM_FLAG_NONE)) {
		return -1;
	} else if ((a->elem[ENTRY_ELEM_DATA].flags != ENTRY_ELEM_FLAG_NONE) &&
		   (b->elem[ENTRY_ELEM_DATA].flags == ENTRY_ELEM_FLAG_NONE)) {
		return 1;
	}

	if ((a->elem[ENTRY_ELEM_META].flags == ENTRY_ELEM_FLAG_NONE) &&
	    (b->elem[ENTRY_ELEM_META].flags != ENTRY_ELEM_FLAG_NONE)) {
		return -1;
	} else if ((a->elem[ENTRY_ELEM_META].flags != ENTRY_ELEM_FLAG_NONE) &&
		   (b->elem[ENTRY_ELEM_META].flags == ENTRY_ELEM_FLAG_NONE)) {
		return 1;
	}

	if (a->use_count < b->use_count) {
		return -1;
	} else if (a->use_count > b->use_count) {
		return 1;
	}
	/* use count is the same - now consider last use time */

	if (a->last_used < b->last_used) {
		return -1;
	} else if (a->last_used > b->last_used) {
		return 1;
	}

	/* they are the same */
	return 0;
}


/**
 * Evict entries from backing store as per configuration.
 *
 * Entries are evicted to ensure the cache remains within the
 * configured limits on size and number of entries.
 *
 * The approach is to check if the cache limits have been exceeded and
 * if so build and sort list of entries to evict. The list is sorted
 * by use count and then by age, so oldest object with least number of uses
 * get evicted first.
 *
 * @param state The store state to use.
 * @return NSERROR_OK on success or error code on failure.
 */
static nserror store_evict(struct store_state *state)
{
	entry_ident_t *elist; /* sorted list of entry identifiers */
	unsigned int ent;
	unsigned int ent_count;
	size_t removed; /* size of removed entries */
	nserror ret = NSERROR_OK;

	/* check if the cache has exceeded configured limit */
	if ((state->total_alloc < state->limit) &&
	    (state->last_entry < (1U << state->entry_bits))) {
		/* cache within limits */
		return NSERROR_OK;
	}

	LOG(("Evicting entries to reduce %d by %d",
	     state->total_alloc, state->hysteresis));

	/* allocate storage for the list */
	elist = malloc(sizeof(entry_ident_t) * state->last_entry);
	if (elist == NULL) {
		return NSERROR_NOMEM;
	}

	/* sort the list avoiding entry 0 which is the empty sentinel */
	for (ent = 1; ent < state->last_entry; ent++) {
		elist[ent - 1] = state->entries[ent].ident;
	}
	ent_count = ent - 1; /* important to keep this as the entry count will change when entries are removed */
	qsort(elist, ent_count, sizeof(entry_ident_t), compar);

	/* evict entries in listed order */
	removed = 0;
	for (ent = 0; ent < ent_count; ent++) {

		removed += BS_ENTRY(elist[ent], state).elem[ENTRY_ELEM_DATA].size;
		removed += BS_ENTRY(elist[ent], state).elem[ENTRY_ELEM_META].size;

		ret = unlink_ident(state, elist[ent]);
		if (ret != NSERROR_OK) {
			break;
		}

		if (removed > state->hysteresis) {
			break;
		}
	}

	free(elist);

	LOG(("removed %d in %d entries", removed, ent));

	return ret;
}


/**
 * Write filesystem entries to file.
 *
 * Serialise entry index out to storage.
 *
 * @param state The backing store state to serialise.
 * @return NSERROR_OK on sucess or error code on faliure.
 */
static nserror write_entries(struct store_state *state)
{
	int fd;
	char *tname = NULL; /* temporary file name for atomic replace */
	char *fname = NULL; /* target filename */
	size_t entries_size;
	size_t written;
	nserror ret;

	if (state->entries_dirty == false) {
		/* entries have not been updated since last write */
		return NSERROR_OK;
	}

	ret = netsurf_mkpath(&tname, NULL, 2, state->path, "t"ENTRIES_FNAME);
	if (ret != NSERROR_OK) {
		return ret;
	}

	fd = open(tname, O_RDWR | O_CREAT | O_TRUNC, S_IRUSR | S_IWUSR);
	if (fd == -1) {
		free(tname);
		return NSERROR_SAVE_FAILED;
	}

	entries_size = state->last_entry * sizeof(struct store_entry);

	written = (size_t)write(fd, state->entries, entries_size);

	close(fd);

	/* check all data was written */
	if (written != entries_size) {
		unlink(tname);
		free(tname);
		return NSERROR_SAVE_FAILED;
	}

	ret = netsurf_mkpath(&fname, NULL, 2, state->path, ENTRIES_FNAME);
	if (ret != NSERROR_OK) {
		unlink(tname);
		free(tname);
		return ret;
	}

	if (rename(tname, fname) != 0) {
		unlink(tname);
		free(tname);
		free(fname);
		return NSERROR_SAVE_FAILED;
	}

	return NSERROR_OK;
}

/**
 * maintinance of control structures.
 *
 * callback scheduled when control data has been update. Currently
 * this is for when the entries table is dirty and requires
 * serialising.
 *
 * \param s store state to maintain.
 */
static void control_maintinance(void *s)
{
	struct store_state *state = s;

	write_entries(state);
}


/**
 * Lookup a backing store entry in the entry table from a url.
 *
 * This finds the store entry associated with the given
 * key. Additionally if an entry is found it updates the usage data
 * about the entry.
 *
 * @param state The store state to use.
 * @param url The value used as the unique key to search entries for.
 * @param bse Pointer used to return value.
 * @return NSERROR_OK and bse updated on success or NSERROR_NOT_FOUND
 *         if no entry corresponds to the url.
 */
static nserror
get_store_entry(struct store_state *state, nsurl *url, struct store_entry **bse)
{
	entry_ident_t ident;
	unsigned int sei; /* store entry index */

	LOG(("url:%s", nsurl_access(url)));

	/* use the url hash as the entry identifier */
	ident = nsurl_hash(url);

	sei = BS_ENTRY_INDEX(ident, state);

	if (sei == 0) {
		LOG(("Failed to find ident 0x%x in index", ident));
		return NSERROR_NOT_FOUND;
	}

	if (state->entries[sei].ident != ident) {
		/* entry ident did not match */
		LOG(("ident did not match entry"));
		return NSERROR_NOT_FOUND;
	}

	*bse = &state->entries[sei];

	state->entries[sei].last_used = time(NULL);
	state->entries[sei].use_count++;

	state->entries_dirty = true;

	guit->browser->schedule(CONTROL_MAINT_TIME, control_maintinance, state);

	return NSERROR_OK;
}


/**
 * Set a backing store entry in the entry table from a url.
 *
 * This creates a backing store entry in the entry table for a url.
 *
 * @param state The store state to use.
 * @param url The value used as the unique key to search entries for.
 * @param flags flags affecting how the entry is stored.
 * @param data The data to store
 * @param datalen The length of data in \a data
 * @param bse Pointer used to return value.
 * @return NSERROR_OK and \a bse updated on success or NSERROR_NOT_FOUND
 *         if no entry coresponds to the url.
 */
static nserror
set_store_entry(struct store_state *state,
		nsurl *url,
		enum backing_store_flags flags,
		uint8_t *data,
		const size_t datalen,
		struct store_entry **bse)
{
	entry_ident_t ident;
	entry_index_t sei; /* store entry index */
	struct store_entry *se;
	nserror ret;
	struct store_entry_element *elem;

	LOG(("url:%s", nsurl_access(url)));

	/* evict entries as required and ensure there is at least one
	 * new entry available.
	 */
	ret = store_evict(state);
	if (ret != NSERROR_OK) {
		return ret;
	}

	/* use the url hash as the entry identifier */
	ident = nsurl_hash(url);

	/* get the entry index from the ident */
	sei = BS_ENTRY_INDEX(ident, state);
	if (sei == 0) {
		/* allocating the next available entry */
		sei = state->last_entry;
		state->last_entry++;
		BS_ENTRY_INDEX(ident, state) = sei;

		/* clear the new entry */
		memset(&state->entries[sei], 0, sizeof(struct store_entry));
	}

	/** @todo should we be checking the entry ident matches the
	 * url. Thats a collision in the address mapping right? and is
	 * it important?
	 */

	/* the entry */
	se = &state->entries[sei];

	/* the entry element */
	if ((flags & BACKING_STORE_META) != 0) {
		elem = &se->elem[ENTRY_ELEM_META];
	} else {
		elem = &se->elem[ENTRY_ELEM_DATA];
	}

	/* check if the element has storage already allocated */
	if ((elem->flags & (ENTRY_ELEM_FLAG_HEAP | ENTRY_ELEM_FLAG_MMAP)) != 0) {
		/* this entry cannot be removed as it has associated
		 * allocation.
		 */
		LOG(("attempt to remove entry with in use data"));
		return NSERROR_PERMISSION;
	}

	/* set the common entry data */
	se->ident = ident;
	se->use_count = 1;
	se->last_used = time(NULL);

	/* store the data in the element */
	elem->flags |= ENTRY_ELEM_FLAG_HEAP;
	elem->u.heap.data = data;
	elem->u.heap.ref = 1;

	/* account for size of entry element */
	state->total_alloc -= elem->size;
	elem->size = datalen;
	state->total_alloc += elem->size;

	/* ensure control maintinance scheduled. */
	state->entries_dirty = true;
	guit->browser->schedule(CONTROL_MAINT_TIME, control_maintinance, state);

	*bse = se;

	return NSERROR_OK;
}


/**
 * Open a file using a store ident.
 *
 * @param state The store state to use.
 * @param ident The identifier of the file to open.
 * @param flags The backing store flags.
 * @param openflags The flags used with the open call.
 * @return An fd from the open call or -1 on error.
 */
static int
store_open(struct store_state *state,
	   uint32_t ident,
	   enum backing_store_flags flags,
	   int openflags)
{
	char *fname;
	nserror ret;
	int fd;

	fname = store_fname(state, ident, flags);
	if (fname == NULL) {
		LOG(("filename error"));
		return -1;
	}

	/* ensure all path elements to file exist if creating file */
	if (openflags & O_CREAT) {
		ret = netsurf_mkdir_all(fname);
		if (ret != NSERROR_OK) {
			LOG(("file path \"%s\" could not be created", fname));
			free(fname);
			return -1;
		}
	}

	LOG(("opening %s", fname));
	fd = open(fname, openflags, S_IRUSR | S_IWUSR);

	free(fname);

	return fd;
}

/**
 * Construct address ident to filesystem entry map
 *
 * To allow a filesystem entry to be found from it's identifier we
 * construct an mapping index. This is a hash map from the entries URL
 * (its unique key) to filesystem entry.
 *
 * As the entire entry list must be iterated over to construct the map
 * we also compute the total storage in use.
 *
 * @param state The backing store global state.
 * @return NSERROR_OK on sucess or NSERROR_NOMEM if the map storage
 *         could not be allocated.
 */
static nserror
build_entrymap(struct store_state *state)
{
	unsigned int eloop;

	LOG(("Allocating %d bytes for max of %d buckets",
	     (1 << state->ident_bits) * sizeof(entry_index_t),
	     1 << state->ident_bits));

	state->addrmap = calloc(1 << state->ident_bits, sizeof(entry_index_t));
	if (state->addrmap == NULL) {
		return NSERROR_NOMEM;
	}

	state->total_alloc = 0;

	for (eloop = 1; eloop < state->last_entry; eloop++) {
		/*
		LOG(("entry:%d ident:0x%08x used:%d",
		     eloop,
		     BS_ADDRESS(state->entries[eloop].ident, state),
		     state->entries[eloop].use_count));
		*/

		/* update the address map to point at the entry */
		BS_ENTRY_INDEX(state->entries[eloop].ident, state) = eloop;

		/* account for the storage space */
		state->total_alloc += state->entries[eloop].elem[ENTRY_ELEM_DATA].size;
		state->total_alloc += state->entries[eloop].elem[ENTRY_ELEM_META].size;
		/* ensure entry does not have any allocation state */
		state->entries[eloop].elem[ENTRY_ELEM_DATA].flags &= ~(ENTRY_ELEM_FLAG_HEAP | ENTRY_ELEM_FLAG_MMAP);
		state->entries[eloop].elem[ENTRY_ELEM_META].flags &= ~(ENTRY_ELEM_FLAG_HEAP | ENTRY_ELEM_FLAG_MMAP);
	}

	return NSERROR_OK;
}

/**
 * Unlink entries file
 *
 * @param state The backing store state.
 * @return NSERROR_OK on sucess or error code on faliure.
 */
static nserror
unlink_entries(struct store_state *state)
{
	char *fname = NULL;
	nserror ret;

	ret = netsurf_mkpath(&fname, NULL, 2, state->path, ENTRIES_FNAME);
	if (ret != NSERROR_OK) {
		return ret;
	}

	unlink(fname);

	free(fname);
	return NSERROR_OK;
}

/**
 * Read description entries into memory.
 *
 * @param state The backing store state to put the loaded entries in.
 * @return NSERROR_OK on sucess or error code on faliure.
 */
static nserror
read_entries(struct store_state *state)
{
	int fd;
	ssize_t rd;
	size_t entries_size;
	char *fname = NULL;
	nserror ret;

	ret = netsurf_mkpath(&fname, NULL, 2, state->path, ENTRIES_FNAME);
	if (ret != NSERROR_OK) {
		return ret;
	}

	entries_size = (1 << state->entry_bits) * sizeof(struct store_entry);

	LOG(("Allocating %d bytes for max of %d entries of %d length elements %d length",
	     entries_size, 1 << state->entry_bits,
	     sizeof(struct store_entry),
	     sizeof(struct store_entry_element)));

	state->entries = calloc(1, entries_size);
	if (state->entries == NULL) {
		free(fname);
		return NSERROR_NOMEM;
	}

	fd = open(fname, O_RDWR);
	free(fname);
	if (fd != -1) {
		rd = read(fd, state->entries, entries_size);
		close(fd);
		if (rd > 0) {
			state->last_entry = rd / sizeof(struct store_entry);
			LOG(("Read %d entries", state->last_entry));
		}
	} else {
		/* could rebuild entries from fs */
		state->last_entry = 1;
	}
	return NSERROR_OK;
}

/**
 * Write the cache tag file.
 *
 * @param state The cache state.
 * @return NSERROR_OK on sucess or error code on faliure.
 */
static nserror
write_cache_tag(struct store_state *state)
{
	FILE *fcachetag;
	nserror ret;
	char *fname = NULL;

	ret = netsurf_mkpath(&fname, NULL, 2, state->path, "CACHEDIR.TAG");
	if (ret != NSERROR_OK) {
		return ret;
	}

	fcachetag = fopen(fname, "wb");

	free(fname);

	if (fcachetag == NULL) {
		return NSERROR_NOT_FOUND;
	}

	fprintf(fcachetag,
		"Signature: 8a477f597d28d172789f06886806bc55\n"
		"# This file is a cache directory tag created by NetSurf.\n"
		"# For information about cache directory tags, see:\n"
		"#	http://www.brynosaurus.com/cachedir/\n");

	fclose(fcachetag);

	return NSERROR_OK;
}

/**
 * Write the control file for the current state.
 *
 * @param state The state to write to the control file.
 * @return NSERROR_OK on sucess or error code on faliure.
 */
static nserror
write_control(struct store_state *state)
{
	FILE *fcontrol;
	nserror ret;
	char *fname = NULL;

	ret = netsurf_mkpath(&fname, NULL, 2, state->path, "control");
	if (ret != NSERROR_OK) {
		return ret;
	}

	LOG(("writing control file \"%s\"", fname));

	ret = netsurf_mkdir_all(fname);
	if (ret != NSERROR_OK) {
		free(fname);
		return ret;
	}

	fcontrol = fopen(fname, "wb");

	free(fname);

	if (fcontrol == NULL) {
		return NSERROR_NOT_FOUND;
	}

	fprintf(fcontrol, "%u%c", CONTROL_VERSION, 0);
	fprintf(fcontrol, "%u%c", state->entry_bits, 0);
	fprintf(fcontrol, "%u%c", state->ident_bits, 0);
	fprintf(fcontrol, "%u%c", state->last_entry, 0);

	fclose(fcontrol);

	return NSERROR_OK;
}


/**
 * Read and parse the control file.
 *
 * @param state The state to read from the control file.
 * @return NSERROR_OK on sucess or error code on faliure.
 */
static nserror
read_control(struct store_state *state)
{
	nserror ret;
	FILE *fcontrol;
	unsigned int ctrlversion;
	unsigned int addrbits;
	unsigned int entrybits;
	char *fname = NULL;

	ret = netsurf_mkpath(&fname, NULL, 2, state->path, "control");
	if (ret != NSERROR_OK) {
		return ret;
	}

	LOG(("opening control file \"%s\"", fname));

	fcontrol = fopen(fname, "rb");

	free(fname);

	if (fcontrol == NULL) {
		/* unable to open control file */
		if (errno == ENOENT) {
			return NSERROR_NOT_FOUND;
		} else {
			return NSERROR_INIT_FAILED;
		}
	}

	/* read control and setup new state */

	/* first line is version */
	if (fscanf(fcontrol, "%u", &ctrlversion) != 1) {
		goto control_error;
	}

	if (ctrlversion != CONTROL_VERSION) {
		goto control_error;
	}

	if (fgetc(fcontrol) != 0) {
		goto control_error;
	}

	/* second line is log2 max number of entries */
	if (fscanf(fcontrol, "%u", &entrybits) != 1) {
		goto control_error;
	}
	if (fgetc(fcontrol) != 0) {
		goto control_error;
	}

	/* second line is log2 size of address hash */
	if (fscanf(fcontrol, "%u", &addrbits) != 1) {
		goto control_error;
	}
	if (fgetc(fcontrol) != 0) {
		goto control_error;
	}

	fclose(fcontrol);

	state->entry_bits = entrybits;
	state->ident_bits = addrbits;

	return NSERROR_OK;

control_error: /* problem with the control file */

	fclose(fcontrol);

	return NSERROR_INIT_FAILED;
}




/* Functions exported in the backing store table */

/**
 * Initialise the backing store.
 *
 * @param parameters to configure backing store.
 * @return NSERROR_OK on success or error code on faliure.
 */
static nserror
initialise(const struct llcache_store_parameters *parameters)
{
	struct store_state *newstate;
	nserror ret;

	/* check backing store is not already initialised */
	if (storestate != NULL) {
		return NSERROR_INIT_FAILED;
	}

	/* if we are not allowed any space simply give up on init */
	if (parameters->limit == 0) {
		return NSERROR_OK;
	}

	/* if the path to the cache directory is not set do not init */
	if (parameters->path == NULL) {
		return NSERROR_OK;
	}

	/* allocate new store state and set defaults */
	newstate = calloc(1, sizeof(struct store_state));
	if (newstate == NULL) {
		return NSERROR_NOMEM;
	}

	newstate->path = strdup(parameters->path);
	newstate->limit = parameters->limit;
	newstate->hysteresis = parameters->hysteresis;

	if (parameters->address_size == 0) {
		newstate->ident_bits = DEFAULT_IDENT_SIZE;
	} else {
		newstate->ident_bits = parameters->address_size;
	}

	if (parameters->entry_size == 0) {
		newstate->entry_bits = DEFAULT_ENTRY_SIZE;
	} else {
		newstate->entry_bits = parameters->entry_size;
	}

	/* read store control and create new if required */
	ret = read_control(newstate);
	if (ret != NSERROR_OK) {
		LOG(("read control failed %s", messages_get_errorcode(ret)));
		ret = write_control(newstate);
		if (ret == NSERROR_OK) {
			unlink_entries(newstate);
			write_cache_tag(newstate);
		}
	}
	if (ret != NSERROR_OK) {
		/* that went well obviously */
		free(newstate->path);
		free(newstate);
		return ret;
	}

	/* ensure the maximum number of entries can be represented in
	 * the type available to store it.
	 */
	if (newstate->entry_bits > (8 * sizeof(entry_index_t))) {
		newstate->entry_bits = (8 * sizeof(entry_index_t));
	}

	/* read filesystem entries */
	ret = read_entries(newstate);
	if (ret != NSERROR_OK) {
		/* that went well obviously */
		free(newstate->path);
		free(newstate);
		return ret;
	}

	/* build entry hash map */
	ret = build_entrymap(newstate);
	if (ret != NSERROR_OK) {
		/* that obviously went well  */
		free(newstate->path);
		free(newstate);
		return ret;
	}

	storestate = newstate;

	LOG(("FS backing store init successful"));

	LOG(("path:%s limit:%d hyst:%d addr:%d entries:%d", newstate->path, newstate->limit, newstate->hysteresis, newstate->ident_bits, newstate->entry_bits));
	LOG(("Using %lld/%lld", newstate->total_alloc, newstate->limit));

	return NSERROR_OK;
}


/**
 * Finalise the backing store.
 *
 * @return NSERROR_OK on success.
 */
static nserror
finalise(void)
{
	if (storestate != NULL) {
		guit->browser->schedule(-1, control_maintinance, storestate);
		write_entries(storestate);

		/* avoid division by zero */
		if (storestate->miss_count == 0) {
			storestate->miss_count = 1;
		}
		LOG(("hits:%d misses:%d hit ratio:%d returned:%d bytes",
		     storestate->hit_count, storestate->miss_count,
		     storestate->hit_count / storestate->miss_count,
		     storestate->hit_size));

		free(storestate->path);
		free(storestate);
		storestate = NULL;
	}
	return NSERROR_OK;
}


/**
 * Place an object in the backing store.
 *
 * takes ownership of the heap block passed in.
 *
 * @param url The url is used as the unique primary key for the data.
 * @param flags The flags to control how the object is stored.
 * @param data The objects source data.
 * @param datalen The length of the \a data.
 * @return NSERROR_OK on success or error code on faliure.
 */
static nserror
store(nsurl *url,
      enum backing_store_flags flags,
      uint8_t *data,
      const size_t datalen)
{
	nserror ret;
	struct store_entry *bse;
	ssize_t written;
	int fd;

	/* check backing store is initialised */
	if (storestate == NULL) {
		return NSERROR_INIT_FAILED;
	}

	/* set the store entry up */
	ret = set_store_entry(storestate, url, flags, data, datalen, &bse);
	if (ret != NSERROR_OK) {
		LOG(("store entry setting failed"));
		return ret;
	}

	fd = store_open(storestate, bse->ident, flags, O_CREAT | O_WRONLY);
	if (fd < 0) {
		perror("");
		LOG(("Open failed %d",fd));
		return NSERROR_SAVE_FAILED;
	}


	LOG(("Writing %d bytes from %p", datalen, data));
	written = write(fd, data, datalen);

	close(fd);
	if (written < 0 || (size_t) written < datalen) {
		/** @todo Delete the file? */
		return NSERROR_SAVE_FAILED;
	}

	return NSERROR_OK;
}

/**
 * release any allocation for an entry
 */
static nserror entry_release_alloc(struct store_entry_element *elem)
{
	if ((elem->flags & ENTRY_ELEM_FLAG_HEAP) != 0) {
		elem->u.heap.ref--;
		if (elem->u.heap.ref == 0) {
			LOG(("freeing %p", elem->u.heap.data));
			free(elem->u.heap.data);
			elem->flags &= ~ENTRY_ELEM_FLAG_HEAP;
		}
	}
	return NSERROR_OK;
}

/**
 * Retrive an object from the backing store.
 *
 * @param[in] url The url is used as the unique primary key for the data.
 * @param[in] flags The flags to control how the object is retrieved.
 * @param[out] data_out The objects data.
 * @param[out] datalen_out The length of the \a data retrieved.
 * @return NSERROR_OK on success or error code on faliure.
 */
static nserror
fetch(nsurl *url,
      enum backing_store_flags bsflags,
      uint8_t **data_out,
      size_t *datalen_out)
{
	nserror ret;
	struct store_entry *bse;
	struct store_entry_element *elem;
	uint8_t *data;
	size_t datalen;
	int fd;
	ssize_t rd;

	/* check backing store is initialised */
	if (storestate == NULL) {
		return NSERROR_INIT_FAILED;
	}

	ret = get_store_entry(storestate, url, &bse);
	if (ret != NSERROR_OK) {
		LOG(("entry not found"));
		storestate->miss_count++;
		return ret;
	}
	storestate->hit_count++;

	LOG(("retriving cache file for url:%s", nsurl_access(url)));

	fd = store_open(storestate, bse->ident, bsflags, O_RDONLY);
	if (fd < 0) {
		LOG(("Open failed"));
		/** @todo should this invalidate the entry? */
		return NSERROR_NOT_FOUND;
	}

	/* the entry element */
	if ((bsflags & BACKING_STORE_META) != 0) {
		elem = &bse->elem[ENTRY_ELEM_META];
	} else {
		elem = &bse->elem[ENTRY_ELEM_DATA];
	}

	data = *data_out;
	datalen = *datalen_out;
	/** @todo should this check datalen is sufficient? */

	/* need to deal with buffers */
	if (data == NULL) {
		if ((elem->flags & ENTRY_ELEM_FLAG_HEAP) != 0) {
			/* a heap allocation already exists. Return
			 * that allocation and bump our ref count.
			 */
			data = elem->u.heap.data;
			elem->u.heap.ref++;
			datalen = elem->size;
			LOG(("Using existing heap allocation %p", elem->u.heap.data));
		} else {
			datalen = elem->size;
			data = malloc(elem->size);
			if (data == NULL) {
				close(fd);
				return NSERROR_NOMEM;
			}

			/* store allocated buffer so track ownership */
			elem->flags |= ENTRY_ELEM_FLAG_HEAP;
			elem->u.heap.data = data;
			elem->u.heap.ref = 1;
			LOG(("Creating new heap allocation %p", elem->u.heap.data));
		}
	} else if (datalen == 0) {
		/* caller provided a buffer but no length bad parameter */
		return NSERROR_BAD_PARAMETER;
	}

	LOG(("Reading %d bytes into %p from file", datalen, data));

	/** @todo this read should be an a loop */
	rd = read(fd, data, datalen);
	if (rd <= 0) {
		LOG(("read returned %d", rd));
		close(fd);
		if ((*data_out) == NULL) {
			entry_release_alloc(elem);
		}
		return NSERROR_NOT_FOUND;
	}

	close(fd);

	storestate->hit_size += datalen;

	*data_out = data;
	*datalen_out = datalen;

	return NSERROR_OK;
}


/**
 * release a previously fetched or stored memory object.
 *
 * @param url The url is used as the unique primary key to invalidate.
 * @param[in] flags The flags to control how the object data is released.
 * @return NSERROR_OK on success or error code on faliure.
 */
static nserror release(nsurl *url, enum backing_store_flags bsflags)
{
	nserror ret;
	struct store_entry *bse;
	struct store_entry_element *elem;

	/* check backing store is initialised */
	if (storestate == NULL) {
		return NSERROR_INIT_FAILED;
	}

	ret = get_store_entry(storestate, url, &bse);
	if (ret != NSERROR_OK) {
		LOG(("entry not found"));
		return ret;
	}

	/* the entry element */
	if ((bsflags & BACKING_STORE_META) != 0) {
		elem = &bse->elem[ENTRY_ELEM_META];
	} else {
		elem = &bse->elem[ENTRY_ELEM_DATA];
	}

	return entry_release_alloc(elem);
}


/**
 * Invalidate a source object from the backing store.
 *
 * The entry (if present in the backing store) must no longer
 * be returned as a result to the fetch or meta operations.
 *
 * @param url The url is used as the unique primary key to invalidate.
 * @return NSERROR_OK on success or error code on faliure.
 */
static nserror
invalidate(nsurl *url)
{
	/* check backing store is initialised */
	if (storestate == NULL) {
		return NSERROR_INIT_FAILED;
	}

	LOG(("url:%s", nsurl_access(url)));

	return unlink_ident(storestate, nsurl_hash(url));
}


static struct gui_llcache_table llcache_table = {
	.initialise = initialise,
	.finalise = finalise,
	.store = store,
	.fetch = fetch,
	.invalidate = invalidate,
	.release = release,
};

struct gui_llcache_table *filesystem_llcache_table = &llcache_table;