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gnupg/g10/keydb.c

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/* keydb.c - key database dispatcher
* Copyright (C) 2001-2013 Free Software Foundation, Inc.
* Coyrright (C) 2001-2015 Werner Koch
*
* This file is part of GnuPG.
*
* GnuPG is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
2007-07-04 21:49:40 +02:00
* the Free Software Foundation; either version 3 of the License, or
* (at your option) any later version.
*
* GnuPG 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
2007-07-04 21:49:40 +02:00
* along with this program; if not, see <http://www.gnu.org/licenses/>.
*/
#include <config.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <errno.h>
#include <assert.h>
#include <sys/types.h>
#include <sys/stat.h>
#include <unistd.h>
#include "gpg.h"
#include "util.h"
#include "options.h"
#include "main.h" /*try_make_homedir ()*/
#include "packet.h"
#include "keyring.h"
#include "../kbx/keybox.h"
#include "keydb.h"
#include "i18n.h"
static int active_handles;
typedef enum
{
KEYDB_RESOURCE_TYPE_NONE = 0,
KEYDB_RESOURCE_TYPE_KEYRING,
KEYDB_RESOURCE_TYPE_KEYBOX
} KeydbResourceType;
#define MAX_KEYDB_RESOURCES 40
struct resource_item
{
KeydbResourceType type;
union {
KEYRING_HANDLE kr;
KEYBOX_HANDLE kb;
} u;
void *token;
};
static struct resource_item all_resources[MAX_KEYDB_RESOURCES];
static int used_resources;
static void *primary_keyring=NULL;
/* This is a simple cache used to return the last result of a
successful fingerprint search. This works only for keybox resources
because (due to lack of a copy_keyblock function) we need to store
an image of the keyblock which is fortunately instantly available
for keyboxes. */
enum keyblock_cache_states {
KEYBLOCK_CACHE_EMPTY,
KEYBLOCK_CACHE_PREPARED,
KEYBLOCK_CACHE_FILLED
};
struct keyblock_cache {
enum keyblock_cache_states state;
byte fpr[MAX_FINGERPRINT_LEN];
iobuf_t iobuf; /* Image of the keyblock. */
u32 *sigstatus;
int pk_no;
int uid_no;
};
struct keydb_handle
{
/* When we locked all of the resources in ACTIVE (using keyring_lock
/ keybox_lock, as appropriate). */
int locked;
/* The index into ACTIVE of the resources in which the last search
result was found. Initially -1. */
int found;
/* Initially -1 (invalid). This is used to save a search result and
later restore it as the selected result. */
int saved_found;
/* The number of skipped long blobs since the last search
(keydb_search_reset). */
unsigned long skipped_long_blobs;
/* If set, this disables the use of the keyblock cache. */
int no_caching;
/* Whether the next search will be from the beginning of the
database (and thus consider all records). */
int is_reset;
/* The "file position." In our case, this is index of the current
resource in ACTIVE. */
int current;
/* The number of resources in ACTIVE. */
int used;
/* Cache of the last found and parsed key block (only used for
keyboxes, not keyrings). */
struct keyblock_cache keyblock_cache;
/* Copy of ALL_RESOURCES when keydb_new is called. */
struct resource_item active[MAX_KEYDB_RESOURCES];
};
/* Looking up keys is expensive. To hide the cost, we cache whether
keys exist in the key database. Then, if we know a key does not
exist, we don't have to spend time looking it up. This
particularly helps the --list-sigs and --check-sigs commands.
The cache stores the results in a hash using separate chaining.
Concretely: we use the LSB of the keyid to index the hash table and
each bucket consists of a linked list of entries. An entry
consists of the 64-bit key id. If a key id is not in the cache,
then we don't know whether it is in the DB or not.
To simplify the cache consistency protocol, we simply flush the
whole cache whenever a key is inserted or updated. */
#define KID_NOT_FOUND_CACHE_BUCKETS 256
static struct kid_not_found_cache_bucket *
kid_not_found_cache[KID_NOT_FOUND_CACHE_BUCKETS];
/* The total number of entries in the hash table. */
static unsigned int kid_not_found_cache_count;
struct kid_not_found_cache_bucket
{
struct kid_not_found_cache_bucket *next;
u32 kid[2];
};
static int lock_all (KEYDB_HANDLE hd);
static void unlock_all (KEYDB_HANDLE hd);
/* Check whether the keyid KID is in key id is definately not in the
database.
Returns:
0 - Indeterminate: the key id is not in the cache; we don't know
whether the key is in the database or not. If you want a
definitive answer, you'll need to perform a lookup.
1 - There is definitely no key with this key id in the database.
We searched for a key with this key id previously, but we
didn't find it in the database. */
static int
kid_not_found_p (u32 *kid)
{
struct kid_not_found_cache_bucket *k;
for (k = kid_not_found_cache[kid[0] % KID_NOT_FOUND_CACHE_BUCKETS]; k; k = k->next)
if (k->kid[0] == kid[0] && k->kid[1] == kid[1])
{
if (DBG_CACHE)
log_debug ("keydb: kid_not_found_p (%08lx%08lx) => not in DB\n",
(ulong)kid[0], (ulong)kid[1]);
return 1;
}
if (DBG_CACHE)
log_debug ("keydb: kid_not_found_p (%08lx%08lx) => indeterminate\n",
(ulong)kid[0], (ulong)kid[1]);
return 0;
}
/* Insert the keyid KID into the kid_not_found_cache. FOUND is whether
the key is in the key database or not.
Note this function does not check whether the key id is already in
the cache. As such, kid_not_found_p() should be called first. */
static void
kid_not_found_insert (u32 *kid)
{
struct kid_not_found_cache_bucket *k;
if (DBG_CACHE)
log_debug ("keydb: kid_not_found_insert (%08lx%08lx)\n",
(ulong)kid[0], (ulong)kid[1]);
k = xmalloc (sizeof *k);
k->kid[0] = kid[0];
k->kid[1] = kid[1];
k->next = kid_not_found_cache[kid[0] % KID_NOT_FOUND_CACHE_BUCKETS];
kid_not_found_cache[kid[0] % KID_NOT_FOUND_CACHE_BUCKETS] = k;
kid_not_found_cache_count++;
}
/* Flush the kid not found cache. */
static void
kid_not_found_flush (void)
{
struct kid_not_found_cache_bucket *k, *knext;
int i;
if (DBG_CACHE)
log_debug ("keydb: kid_not_found_flush\n");
if (!kid_not_found_cache_count)
return;
for (i=0; i < DIM(kid_not_found_cache); i++)
{
for (k = kid_not_found_cache[i]; k; k = knext)
{
knext = k->next;
xfree (k);
}
kid_not_found_cache[i] = NULL;
}
kid_not_found_cache_count = 0;
}
gpg: Cache keybox searches. * common/iobuf.c (iobuf_seek): Fix for temp streams. * g10/pubkey-enc.c (get_session_key, get_it): Add some log_clock calls. * g10/keydb.c (dump_search_desc): New. (enum_keyblock_states, struct keyblock_cache): New. (keyblock_cache_clear): New. (keydb_get_keyblock, keydb_search): Implement a keyblock cache. (keydb_update_keyblock, keydb_insert_keyblock, keydb_delete_keyblock) (keydb_rebuild_caches, keydb_search_reset): Clear the cache. -- Gpg uses the key database at several places without a central coordination. This leads to several scans of the keybox for the same key. To improve that we now use a simple cache to store a retrieved keyblock in certain cases. In theory this caching could also be done for old keyrings, but it is a bit more work and questionable whether it is needed; the keybox scheme is anyway much faster than keyrings. Using a keybox with 20000 384 bit ECDSA/ECHD keypairs and a 252 byte sample text we get these values for encrypt and decrypt operations on an Core i5 4*3.33Ghz system. The option --trust-model=always is used. Times are given in milliseconds wall time. | | enc | dec | dec,q | |-----------+-----+-----+-------| | key 1 | 48 | 96 | 70 | | key 10000 | 60 | 98 | 80 | | key 20000 | 69 | 106 | 88 | | 10 keys | 540 | 290 | 70 | The 10 keys test uses a mix of keys, the first one is used for decryption but all keys are looked up so that information about are printed. The last column gives decryption results w/o information printing (--quiet). The keybox is always scanned sequentially without using any index. By adding an index to the keybox it will be possible to further reduce the time required for keys stored to the end of the file.
2013-01-08 14:44:49 +01:00
static void
keyblock_cache_clear (struct keydb_handle *hd)
gpg: Cache keybox searches. * common/iobuf.c (iobuf_seek): Fix for temp streams. * g10/pubkey-enc.c (get_session_key, get_it): Add some log_clock calls. * g10/keydb.c (dump_search_desc): New. (enum_keyblock_states, struct keyblock_cache): New. (keyblock_cache_clear): New. (keydb_get_keyblock, keydb_search): Implement a keyblock cache. (keydb_update_keyblock, keydb_insert_keyblock, keydb_delete_keyblock) (keydb_rebuild_caches, keydb_search_reset): Clear the cache. -- Gpg uses the key database at several places without a central coordination. This leads to several scans of the keybox for the same key. To improve that we now use a simple cache to store a retrieved keyblock in certain cases. In theory this caching could also be done for old keyrings, but it is a bit more work and questionable whether it is needed; the keybox scheme is anyway much faster than keyrings. Using a keybox with 20000 384 bit ECDSA/ECHD keypairs and a 252 byte sample text we get these values for encrypt and decrypt operations on an Core i5 4*3.33Ghz system. The option --trust-model=always is used. Times are given in milliseconds wall time. | | enc | dec | dec,q | |-----------+-----+-----+-------| | key 1 | 48 | 96 | 70 | | key 10000 | 60 | 98 | 80 | | key 20000 | 69 | 106 | 88 | | 10 keys | 540 | 290 | 70 | The 10 keys test uses a mix of keys, the first one is used for decryption but all keys are looked up so that information about are printed. The last column gives decryption results w/o information printing (--quiet). The keybox is always scanned sequentially without using any index. By adding an index to the keybox it will be possible to further reduce the time required for keys stored to the end of the file.
2013-01-08 14:44:49 +01:00
{
hd->keyblock_cache.state = KEYBLOCK_CACHE_EMPTY;
xfree (hd->keyblock_cache.sigstatus);
hd->keyblock_cache.sigstatus = NULL;
iobuf_close (hd->keyblock_cache.iobuf);
hd->keyblock_cache.iobuf = NULL;
gpg: Cache keybox searches. * common/iobuf.c (iobuf_seek): Fix for temp streams. * g10/pubkey-enc.c (get_session_key, get_it): Add some log_clock calls. * g10/keydb.c (dump_search_desc): New. (enum_keyblock_states, struct keyblock_cache): New. (keyblock_cache_clear): New. (keydb_get_keyblock, keydb_search): Implement a keyblock cache. (keydb_update_keyblock, keydb_insert_keyblock, keydb_delete_keyblock) (keydb_rebuild_caches, keydb_search_reset): Clear the cache. -- Gpg uses the key database at several places without a central coordination. This leads to several scans of the keybox for the same key. To improve that we now use a simple cache to store a retrieved keyblock in certain cases. In theory this caching could also be done for old keyrings, but it is a bit more work and questionable whether it is needed; the keybox scheme is anyway much faster than keyrings. Using a keybox with 20000 384 bit ECDSA/ECHD keypairs and a 252 byte sample text we get these values for encrypt and decrypt operations on an Core i5 4*3.33Ghz system. The option --trust-model=always is used. Times are given in milliseconds wall time. | | enc | dec | dec,q | |-----------+-----+-----+-------| | key 1 | 48 | 96 | 70 | | key 10000 | 60 | 98 | 80 | | key 20000 | 69 | 106 | 88 | | 10 keys | 540 | 290 | 70 | The 10 keys test uses a mix of keys, the first one is used for decryption but all keys are looked up so that information about are printed. The last column gives decryption results w/o information printing (--quiet). The keybox is always scanned sequentially without using any index. By adding an index to the keybox it will be possible to further reduce the time required for keys stored to the end of the file.
2013-01-08 14:44:49 +01:00
}
/* Handle the creation of a keyring or a keybox if it does not yet
exist. Take into account that other processes might have the
keyring/keybox already locked. This lock check does not work if
the directory itself is not yet available. If IS_BOX is true the
filename is expected to refer to a keybox. If FORCE_CREATE is true
the keyring or keybox will be created.
Return 0 if it is okay to access the specified file. */
static int
maybe_create_keyring_or_box (char *filename, int is_box, int force_create)
{
dotlock_t lockhd = NULL;
IOBUF iobuf;
int rc;
mode_t oldmask;
char *last_slash_in_filename;
int save_slash;
/* A quick test whether the filename already exists. */
if (!access (filename, F_OK))
return 0;
/* If we don't want to create a new file at all, there is no need to
go any further - bail out right here. */
if (!force_create)
return gpg_error (GPG_ERR_ENOENT);
/* First of all we try to create the home directory. Note, that we
don't do any locking here because any sane application of gpg
would create the home directory by itself and not rely on gpg's
tricky auto-creation which is anyway only done for certain home
directory name pattern. */
last_slash_in_filename = strrchr (filename, DIRSEP_C);
#if HAVE_W32_SYSTEM
{
/* Windows may either have a slash or a backslash. Take care of it. */
char *p = strrchr (filename, '/');
if (!last_slash_in_filename || p > last_slash_in_filename)
last_slash_in_filename = p;
}
#endif /*HAVE_W32_SYSTEM*/
if (!last_slash_in_filename)
return gpg_error (GPG_ERR_ENOENT); /* No slash at all - should
not happen though. */
save_slash = *last_slash_in_filename;
*last_slash_in_filename = 0;
if (access(filename, F_OK))
{
static int tried;
if (!tried)
{
tried = 1;
try_make_homedir (filename);
}
if (access (filename, F_OK))
{
rc = gpg_error_from_syserror ();
2008-01-30 15:26:57 +01:00
*last_slash_in_filename = save_slash;
goto leave;
}
}
*last_slash_in_filename = save_slash;
/* To avoid races with other instances of gpg trying to create or
update the keyring (it is removed during an update for a short
time), we do the next stuff in a locked state. */
lockhd = dotlock_create (filename, 0);
if (!lockhd)
{
rc = gpg_error_from_syserror ();
/* A reason for this to fail is that the directory is not
writable. However, this whole locking stuff does not make
sense if this is the case. An empty non-writable directory
with no keyring is not really useful at all. */
if (opt.verbose)
log_info ("can't allocate lock for '%s': %s\n",
filename, gpg_strerror (rc));
if (!force_create)
return gpg_error (GPG_ERR_ENOENT); /* Won't happen. */
else
return rc;
}
if ( dotlock_take (lockhd, -1) )
{
rc = gpg_error_from_syserror ();
/* This is something bad. Probably a stale lockfile. */
log_info ("can't lock '%s': %s\n", filename, gpg_strerror (rc));
goto leave;
}
/* Now the real test while we are locked. */
if (!access (filename, F_OK))
{
rc = 0; /* Okay, we may access the file now. */
goto leave;
}
/* The file does not yet exist, create it now. */
oldmask = umask (077);
if (is_secured_filename (filename))
{
iobuf = NULL;
gpg_err_set_errno (EPERM);
}
else
iobuf = iobuf_create (filename, 0);
umask (oldmask);
if (!iobuf)
{
rc = gpg_error_from_syserror ();
if (is_box)
log_error (_("error creating keybox '%s': %s\n"),
filename, gpg_strerror (rc));
else
log_error (_("error creating keyring '%s': %s\n"),
filename, gpg_strerror (rc));
goto leave;
}
iobuf_close (iobuf);
/* Must invalidate that ugly cache */
2010-03-08 18:05:37 +01:00
iobuf_ioctl (NULL, IOBUF_IOCTL_INVALIDATE_CACHE, 0, filename);
/* Make sure that at least one record is in a new keybox file, so
that the detection magic will work the next time it is used. */
if (is_box)
{
FILE *fp = fopen (filename, "w");
if (!fp)
rc = gpg_error_from_syserror ();
else
{
gpg: Take care to use pubring.kbx if it has ever been used. * kbx/keybox-defs.h (struct keybox_handle): Add field for_openpgp. * kbx/keybox-file.c (_keybox_write_header_blob): Set openpgp header flag. * kbx/keybox-blob.c (_keybox_update_header_blob): Add arg for_openpgp and set header flag. * kbx/keybox-init.c (keybox_new): Rename to do_keybox_new, make static and add arg for_openpgp. (keybox_new_openpgp, keybox_new_x509): New. Use them instead of the former keybox_new. * kbx/keybox-update.c (blob_filecopy): Add arg for_openpgp and set the openpgp header flags. * g10/keydb.c (rt_from_file): New. Factored out and extended from keydb_add_resource. (keydb_add_resource): Switch to the kbx file if it has the openpgp flag set. * kbx/keybox-dump.c (dump_header_blob): Print header flags. -- The problem was reported by dkg on gnupg-devel (2014-10-07): I just discovered a new problem, though, which will affect people on systems that have gpg and gpg2 coinstalled: 0) create a new keyring with gpg2, and use it exclusively with gpg2 for a while. 1) somehow (accidentally?) use gpg (1.4.x) again -- this creates ~/.gnupg/pubring.gpg 2) future runs of gpg2 now only look at pubring.gpg and ignore pubring.kbx -- the keys you had accumulated in the keybox are no longer listed in the output of gpg2 --list-keys Note that gpgsm has always used pubring.kbx and thus this file might already be there but without gpg ever inserted a key. The new flag in the KBX header gives us an indication whether a KBX file has ever been written by gpg >= 2.1. If that is the case we will use it instead of the default pubring.gpg. Signed-off-by: Werner Koch <wk@gnupg.org>
2014-10-09 19:10:32 +02:00
rc = _keybox_write_header_blob (fp, 1);
fclose (fp);
}
if (rc)
{
if (is_box)
log_error (_("error creating keybox '%s': %s\n"),
filename, gpg_strerror (rc));
else
log_error (_("error creating keyring '%s': %s\n"),
filename, gpg_strerror (rc));
goto leave;
}
}
if (!opt.quiet)
{
if (is_box)
log_info (_("keybox '%s' created\n"), filename);
else
log_info (_("keyring '%s' created\n"), filename);
}
rc = 0;
leave:
if (lockhd)
{
dotlock_release (lockhd);
dotlock_destroy (lockhd);
}
return rc;
}
/* Helper for keydb_add_resource. Opens FILENAME to figure out the
resource type.
Returns the specified file's likely type. If the file does not
exist, returns KEYDB_RESOURCE_TYPE_NONE and sets *R_FOUND to 0.
Otherwise, tries to figure out the file's type. This is either
KEYDB_RESOURCE_TYPE_KEYBOX, KEYDB_RESOURCE_TYPE_KEYRING or
KEYDB_RESOURCE_TYPE_KEYNONE. If the file is a keybox and it has
the OpenPGP flag set, then R_OPENPGP is also set. */
gpg: Take care to use pubring.kbx if it has ever been used. * kbx/keybox-defs.h (struct keybox_handle): Add field for_openpgp. * kbx/keybox-file.c (_keybox_write_header_blob): Set openpgp header flag. * kbx/keybox-blob.c (_keybox_update_header_blob): Add arg for_openpgp and set header flag. * kbx/keybox-init.c (keybox_new): Rename to do_keybox_new, make static and add arg for_openpgp. (keybox_new_openpgp, keybox_new_x509): New. Use them instead of the former keybox_new. * kbx/keybox-update.c (blob_filecopy): Add arg for_openpgp and set the openpgp header flags. * g10/keydb.c (rt_from_file): New. Factored out and extended from keydb_add_resource. (keydb_add_resource): Switch to the kbx file if it has the openpgp flag set. * kbx/keybox-dump.c (dump_header_blob): Print header flags. -- The problem was reported by dkg on gnupg-devel (2014-10-07): I just discovered a new problem, though, which will affect people on systems that have gpg and gpg2 coinstalled: 0) create a new keyring with gpg2, and use it exclusively with gpg2 for a while. 1) somehow (accidentally?) use gpg (1.4.x) again -- this creates ~/.gnupg/pubring.gpg 2) future runs of gpg2 now only look at pubring.gpg and ignore pubring.kbx -- the keys you had accumulated in the keybox are no longer listed in the output of gpg2 --list-keys Note that gpgsm has always used pubring.kbx and thus this file might already be there but without gpg ever inserted a key. The new flag in the KBX header gives us an indication whether a KBX file has ever been written by gpg >= 2.1. If that is the case we will use it instead of the default pubring.gpg. Signed-off-by: Werner Koch <wk@gnupg.org>
2014-10-09 19:10:32 +02:00
static KeydbResourceType
rt_from_file (const char *filename, int *r_found, int *r_openpgp)
{
u32 magic;
unsigned char verbuf[4];
FILE *fp;
KeydbResourceType rt = KEYDB_RESOURCE_TYPE_NONE;
*r_found = *r_openpgp = 0;
fp = fopen (filename, "rb");
if (fp)
{
*r_found = 1;
if (fread (&magic, 4, 1, fp) == 1 )
{
if (magic == 0x13579ace || magic == 0xce9a5713)
; /* GDBM magic - not anymore supported. */
else if (fread (&verbuf, 4, 1, fp) == 1
&& verbuf[0] == 1
&& fread (&magic, 4, 1, fp) == 1
&& !memcmp (&magic, "KBXf", 4))
{
if ((verbuf[3] & 0x02))
*r_openpgp = 1;
rt = KEYDB_RESOURCE_TYPE_KEYBOX;
}
else
rt = KEYDB_RESOURCE_TYPE_KEYRING;
}
else /* Maybe empty: assume keyring. */
rt = KEYDB_RESOURCE_TYPE_KEYRING;
fclose (fp);
}
return rt;
}
gpg_error_t
keydb_add_resource (const char *url, unsigned int flags)
{
/* Whether we have successfully registered a resource. */
static int any_registered;
/* The file named by the URL (i.e., without the prototype). */
const char *resname = url;
char *filename = NULL;
int create;
int read_only = !!(flags&KEYDB_RESOURCE_FLAG_READONLY);
int is_default = !!(flags&KEYDB_RESOURCE_FLAG_DEFAULT);
int is_gpgvdef = !!(flags&KEYDB_RESOURCE_FLAG_GPGVDEF);
int rc = 0;
KeydbResourceType rt = KEYDB_RESOURCE_TYPE_NONE;
void *token;
/* Create the resource if it is the first registered one. */
create = (!read_only && !any_registered);
if (strlen (resname) > 11 && !strncmp( resname, "gnupg-ring:", 11) )
{
rt = KEYDB_RESOURCE_TYPE_KEYRING;
resname += 11;
}
else if (strlen (resname) > 10 && !strncmp (resname, "gnupg-kbx:", 10) )
{
rt = KEYDB_RESOURCE_TYPE_KEYBOX;
resname += 10;
}
#if !defined(HAVE_DRIVE_LETTERS) && !defined(__riscos__)
else if (strchr (resname, ':'))
{
log_error ("invalid key resource URL '%s'\n", url );
rc = gpg_error (GPG_ERR_GENERAL);
goto leave;
}
#endif /* !HAVE_DRIVE_LETTERS && !__riscos__ */
if (*resname != DIRSEP_C
#ifdef HAVE_W32_SYSTEM
&& *resname != '/' /* Fixme: does not handle drive letters. */
#endif
)
{
/* Do tilde expansion etc. */
if (strchr (resname, DIRSEP_C)
#ifdef HAVE_W32_SYSTEM
|| strchr (resname, '/') /* Windows also accepts this. */
#endif
)
filename = make_filename (resname, NULL);
else
filename = make_filename (opt.homedir, resname, NULL);
}
else
filename = xstrdup (resname);
/* See whether we can determine the filetype. */
if (rt == KEYDB_RESOURCE_TYPE_NONE)
{
gpg: Take care to use pubring.kbx if it has ever been used. * kbx/keybox-defs.h (struct keybox_handle): Add field for_openpgp. * kbx/keybox-file.c (_keybox_write_header_blob): Set openpgp header flag. * kbx/keybox-blob.c (_keybox_update_header_blob): Add arg for_openpgp and set header flag. * kbx/keybox-init.c (keybox_new): Rename to do_keybox_new, make static and add arg for_openpgp. (keybox_new_openpgp, keybox_new_x509): New. Use them instead of the former keybox_new. * kbx/keybox-update.c (blob_filecopy): Add arg for_openpgp and set the openpgp header flags. * g10/keydb.c (rt_from_file): New. Factored out and extended from keydb_add_resource. (keydb_add_resource): Switch to the kbx file if it has the openpgp flag set. * kbx/keybox-dump.c (dump_header_blob): Print header flags. -- The problem was reported by dkg on gnupg-devel (2014-10-07): I just discovered a new problem, though, which will affect people on systems that have gpg and gpg2 coinstalled: 0) create a new keyring with gpg2, and use it exclusively with gpg2 for a while. 1) somehow (accidentally?) use gpg (1.4.x) again -- this creates ~/.gnupg/pubring.gpg 2) future runs of gpg2 now only look at pubring.gpg and ignore pubring.kbx -- the keys you had accumulated in the keybox are no longer listed in the output of gpg2 --list-keys Note that gpgsm has always used pubring.kbx and thus this file might already be there but without gpg ever inserted a key. The new flag in the KBX header gives us an indication whether a KBX file has ever been written by gpg >= 2.1. If that is the case we will use it instead of the default pubring.gpg. Signed-off-by: Werner Koch <wk@gnupg.org>
2014-10-09 19:10:32 +02:00
int found, openpgp_flag;
int pass = 0;
size_t filenamelen;
check_again:
filenamelen = strlen (filename);
gpg: Take care to use pubring.kbx if it has ever been used. * kbx/keybox-defs.h (struct keybox_handle): Add field for_openpgp. * kbx/keybox-file.c (_keybox_write_header_blob): Set openpgp header flag. * kbx/keybox-blob.c (_keybox_update_header_blob): Add arg for_openpgp and set header flag. * kbx/keybox-init.c (keybox_new): Rename to do_keybox_new, make static and add arg for_openpgp. (keybox_new_openpgp, keybox_new_x509): New. Use them instead of the former keybox_new. * kbx/keybox-update.c (blob_filecopy): Add arg for_openpgp and set the openpgp header flags. * g10/keydb.c (rt_from_file): New. Factored out and extended from keydb_add_resource. (keydb_add_resource): Switch to the kbx file if it has the openpgp flag set. * kbx/keybox-dump.c (dump_header_blob): Print header flags. -- The problem was reported by dkg on gnupg-devel (2014-10-07): I just discovered a new problem, though, which will affect people on systems that have gpg and gpg2 coinstalled: 0) create a new keyring with gpg2, and use it exclusively with gpg2 for a while. 1) somehow (accidentally?) use gpg (1.4.x) again -- this creates ~/.gnupg/pubring.gpg 2) future runs of gpg2 now only look at pubring.gpg and ignore pubring.kbx -- the keys you had accumulated in the keybox are no longer listed in the output of gpg2 --list-keys Note that gpgsm has always used pubring.kbx and thus this file might already be there but without gpg ever inserted a key. The new flag in the KBX header gives us an indication whether a KBX file has ever been written by gpg >= 2.1. If that is the case we will use it instead of the default pubring.gpg. Signed-off-by: Werner Koch <wk@gnupg.org>
2014-10-09 19:10:32 +02:00
rt = rt_from_file (filename, &found, &openpgp_flag);
if (found)
{
gpg: Take care to use pubring.kbx if it has ever been used. * kbx/keybox-defs.h (struct keybox_handle): Add field for_openpgp. * kbx/keybox-file.c (_keybox_write_header_blob): Set openpgp header flag. * kbx/keybox-blob.c (_keybox_update_header_blob): Add arg for_openpgp and set header flag. * kbx/keybox-init.c (keybox_new): Rename to do_keybox_new, make static and add arg for_openpgp. (keybox_new_openpgp, keybox_new_x509): New. Use them instead of the former keybox_new. * kbx/keybox-update.c (blob_filecopy): Add arg for_openpgp and set the openpgp header flags. * g10/keydb.c (rt_from_file): New. Factored out and extended from keydb_add_resource. (keydb_add_resource): Switch to the kbx file if it has the openpgp flag set. * kbx/keybox-dump.c (dump_header_blob): Print header flags. -- The problem was reported by dkg on gnupg-devel (2014-10-07): I just discovered a new problem, though, which will affect people on systems that have gpg and gpg2 coinstalled: 0) create a new keyring with gpg2, and use it exclusively with gpg2 for a while. 1) somehow (accidentally?) use gpg (1.4.x) again -- this creates ~/.gnupg/pubring.gpg 2) future runs of gpg2 now only look at pubring.gpg and ignore pubring.kbx -- the keys you had accumulated in the keybox are no longer listed in the output of gpg2 --list-keys Note that gpgsm has always used pubring.kbx and thus this file might already be there but without gpg ever inserted a key. The new flag in the KBX header gives us an indication whether a KBX file has ever been written by gpg >= 2.1. If that is the case we will use it instead of the default pubring.gpg. Signed-off-by: Werner Koch <wk@gnupg.org>
2014-10-09 19:10:32 +02:00
/* The file exists and we have the resource type in RT.
Now let us check whether in addition to the "pubring.gpg"
a "pubring.kbx with openpgp keys exists. This is so that
GPG 2.1 will use an existing "pubring.kbx" by default iff
that file has been created or used by 2.1. This check is
needed because after creation or use of the kbx file with
2.1 an older version of gpg may have created a new
pubring.gpg for its own use. */
if (!pass && is_default && rt == KEYDB_RESOURCE_TYPE_KEYRING
&& filenamelen > 4 && !strcmp (filename+filenamelen-4, ".gpg"))
{
gpg: Take care to use pubring.kbx if it has ever been used. * kbx/keybox-defs.h (struct keybox_handle): Add field for_openpgp. * kbx/keybox-file.c (_keybox_write_header_blob): Set openpgp header flag. * kbx/keybox-blob.c (_keybox_update_header_blob): Add arg for_openpgp and set header flag. * kbx/keybox-init.c (keybox_new): Rename to do_keybox_new, make static and add arg for_openpgp. (keybox_new_openpgp, keybox_new_x509): New. Use them instead of the former keybox_new. * kbx/keybox-update.c (blob_filecopy): Add arg for_openpgp and set the openpgp header flags. * g10/keydb.c (rt_from_file): New. Factored out and extended from keydb_add_resource. (keydb_add_resource): Switch to the kbx file if it has the openpgp flag set. * kbx/keybox-dump.c (dump_header_blob): Print header flags. -- The problem was reported by dkg on gnupg-devel (2014-10-07): I just discovered a new problem, though, which will affect people on systems that have gpg and gpg2 coinstalled: 0) create a new keyring with gpg2, and use it exclusively with gpg2 for a while. 1) somehow (accidentally?) use gpg (1.4.x) again -- this creates ~/.gnupg/pubring.gpg 2) future runs of gpg2 now only look at pubring.gpg and ignore pubring.kbx -- the keys you had accumulated in the keybox are no longer listed in the output of gpg2 --list-keys Note that gpgsm has always used pubring.kbx and thus this file might already be there but without gpg ever inserted a key. The new flag in the KBX header gives us an indication whether a KBX file has ever been written by gpg >= 2.1. If that is the case we will use it instead of the default pubring.gpg. Signed-off-by: Werner Koch <wk@gnupg.org>
2014-10-09 19:10:32 +02:00
strcpy (filename+filenamelen-4, ".kbx");
if ((rt_from_file (filename, &found, &openpgp_flag)
== KEYDB_RESOURCE_TYPE_KEYBOX) && found && openpgp_flag)
rt = KEYDB_RESOURCE_TYPE_KEYBOX;
gpg: Take care to use pubring.kbx if it has ever been used. * kbx/keybox-defs.h (struct keybox_handle): Add field for_openpgp. * kbx/keybox-file.c (_keybox_write_header_blob): Set openpgp header flag. * kbx/keybox-blob.c (_keybox_update_header_blob): Add arg for_openpgp and set header flag. * kbx/keybox-init.c (keybox_new): Rename to do_keybox_new, make static and add arg for_openpgp. (keybox_new_openpgp, keybox_new_x509): New. Use them instead of the former keybox_new. * kbx/keybox-update.c (blob_filecopy): Add arg for_openpgp and set the openpgp header flags. * g10/keydb.c (rt_from_file): New. Factored out and extended from keydb_add_resource. (keydb_add_resource): Switch to the kbx file if it has the openpgp flag set. * kbx/keybox-dump.c (dump_header_blob): Print header flags. -- The problem was reported by dkg on gnupg-devel (2014-10-07): I just discovered a new problem, though, which will affect people on systems that have gpg and gpg2 coinstalled: 0) create a new keyring with gpg2, and use it exclusively with gpg2 for a while. 1) somehow (accidentally?) use gpg (1.4.x) again -- this creates ~/.gnupg/pubring.gpg 2) future runs of gpg2 now only look at pubring.gpg and ignore pubring.kbx -- the keys you had accumulated in the keybox are no longer listed in the output of gpg2 --list-keys Note that gpgsm has always used pubring.kbx and thus this file might already be there but without gpg ever inserted a key. The new flag in the KBX header gives us an indication whether a KBX file has ever been written by gpg >= 2.1. If that is the case we will use it instead of the default pubring.gpg. Signed-off-by: Werner Koch <wk@gnupg.org>
2014-10-09 19:10:32 +02:00
else /* Restore filename */
strcpy (filename+filenamelen-4, ".gpg");
}
}
else if (!pass && is_gpgvdef
&& filenamelen > 4 && !strcmp (filename+filenamelen-4, ".kbx"))
{
/* Not found but gpgv's default "trustedkeys.kbx" file has
been requested. We did not found it so now check whether
a "trustedkeys.gpg" file exists and use that instead. */
KeydbResourceType rttmp;
strcpy (filename+filenamelen-4, ".gpg");
rttmp = rt_from_file (filename, &found, &openpgp_flag);
if (found
&& ((rttmp == KEYDB_RESOURCE_TYPE_KEYBOX && openpgp_flag)
|| (rttmp == KEYDB_RESOURCE_TYPE_KEYRING)))
rt = rttmp;
else /* Restore filename */
strcpy (filename+filenamelen-4, ".kbx");
}
else if (!pass
&& is_default && create
&& filenamelen > 4 && !strcmp (filename+filenamelen-4, ".gpg"))
{
/* The file does not exist, the default resource has been
requested, the file shall be created, and the file has a
".gpg" suffix. Change the suffix to ".kbx" and try once
more. This way we achieve that we open an existing
".gpg" keyring, but create a new keybox file with an
".kbx" suffix. */
strcpy (filename+filenamelen-4, ".kbx");
pass++;
goto check_again;
}
else /* No file yet: create keybox. */
rt = KEYDB_RESOURCE_TYPE_KEYBOX;
}
switch (rt)
{
case KEYDB_RESOURCE_TYPE_NONE:
log_error ("unknown type of key resource '%s'\n", url );
rc = gpg_error (GPG_ERR_GENERAL);
goto leave;
case KEYDB_RESOURCE_TYPE_KEYRING:
rc = maybe_create_keyring_or_box (filename, 0, create);
if (rc)
goto leave;
if (keyring_register_filename (filename, read_only, &token))
{
if (used_resources >= MAX_KEYDB_RESOURCES)
rc = gpg_error (GPG_ERR_RESOURCE_LIMIT);
else
{
if ((flags & KEYDB_RESOURCE_FLAG_PRIMARY))
primary_keyring = token;
all_resources[used_resources].type = rt;
all_resources[used_resources].u.kr = NULL; /* Not used here */
all_resources[used_resources].token = token;
used_resources++;
}
}
else
{
/* This keyring was already registered, so ignore it.
However, we can still mark it as primary even if it was
already registered. */
if ((flags & KEYDB_RESOURCE_FLAG_PRIMARY))
primary_keyring = token;
}
break;
case KEYDB_RESOURCE_TYPE_KEYBOX:
{
rc = maybe_create_keyring_or_box (filename, 1, create);
if (rc)
goto leave;
/* FIXME: How do we register a read-only keybox? */
token = keybox_register_file (filename, 0);
if (token)
{
if (used_resources >= MAX_KEYDB_RESOURCES)
rc = gpg_error (GPG_ERR_RESOURCE_LIMIT);
else
{
/* if ((flags & KEYDB_RESOURCE_FLAG_PRIMARY)) */
/* primary_keyring = token; */
all_resources[used_resources].type = rt;
all_resources[used_resources].u.kb = NULL; /* Not used here */
all_resources[used_resources].token = token;
/* FIXME: Do a compress run if needed and no other
user is currently using the keybox. */
used_resources++;
}
}
else
{
/* Already registered. We will mark it as the primary key
if requested. */
/* FIXME: How to do that? Change the keybox interface? */
/* if ((flags & KEYDB_RESOURCE_FLAG_PRIMARY)) */
/* primary_keyring = token; */
}
}
break;
default:
log_error ("resource type of '%s' not supported\n", url);
rc = gpg_error (GPG_ERR_GENERAL);
goto leave;
}
/* fixme: check directory permissions and print a warning */
leave:
if (rc)
log_error (_("keyblock resource '%s': %s\n"), filename, gpg_strerror (rc));
else
any_registered = 1;
xfree (filename);
return rc;
}
void
keydb_dump_stats (void)
{
if (kid_not_found_cache_count)
log_info ("keydb: kid_not_found_cache: total: %u\n",
kid_not_found_cache_count);
}
KEYDB_HANDLE
keydb_new (void)
{
KEYDB_HANDLE hd;
int i, j;
int die = 0;
gpg: Cache keybox searches. * common/iobuf.c (iobuf_seek): Fix for temp streams. * g10/pubkey-enc.c (get_session_key, get_it): Add some log_clock calls. * g10/keydb.c (dump_search_desc): New. (enum_keyblock_states, struct keyblock_cache): New. (keyblock_cache_clear): New. (keydb_get_keyblock, keydb_search): Implement a keyblock cache. (keydb_update_keyblock, keydb_insert_keyblock, keydb_delete_keyblock) (keydb_rebuild_caches, keydb_search_reset): Clear the cache. -- Gpg uses the key database at several places without a central coordination. This leads to several scans of the keybox for the same key. To improve that we now use a simple cache to store a retrieved keyblock in certain cases. In theory this caching could also be done for old keyrings, but it is a bit more work and questionable whether it is needed; the keybox scheme is anyway much faster than keyrings. Using a keybox with 20000 384 bit ECDSA/ECHD keypairs and a 252 byte sample text we get these values for encrypt and decrypt operations on an Core i5 4*3.33Ghz system. The option --trust-model=always is used. Times are given in milliseconds wall time. | | enc | dec | dec,q | |-----------+-----+-----+-------| | key 1 | 48 | 96 | 70 | | key 10000 | 60 | 98 | 80 | | key 20000 | 69 | 106 | 88 | | 10 keys | 540 | 290 | 70 | The 10 keys test uses a mix of keys, the first one is used for decryption but all keys are looked up so that information about are printed. The last column gives decryption results w/o information printing (--quiet). The keybox is always scanned sequentially without using any index. By adding an index to the keybox it will be possible to further reduce the time required for keys stored to the end of the file.
2013-01-08 14:44:49 +01:00
if (DBG_CLOCK)
log_clock ("keydb_new");
hd = xmalloc_clear (sizeof *hd);
hd->found = -1;
hd->saved_found = -1;
hd->is_reset = 1;
assert (used_resources <= MAX_KEYDB_RESOURCES);
for (i=j=0; ! die && i < used_resources; i++)
{
switch (all_resources[i].type)
{
case KEYDB_RESOURCE_TYPE_NONE: /* ignore */
break;
case KEYDB_RESOURCE_TYPE_KEYRING:
hd->active[j].type = all_resources[i].type;
hd->active[j].token = all_resources[i].token;
hd->active[j].u.kr = keyring_new (all_resources[i].token);
if (!hd->active[j].u.kr)
die = 1;
j++;
break;
case KEYDB_RESOURCE_TYPE_KEYBOX:
hd->active[j].type = all_resources[i].type;
hd->active[j].token = all_resources[i].token;
gpg: Take care to use pubring.kbx if it has ever been used. * kbx/keybox-defs.h (struct keybox_handle): Add field for_openpgp. * kbx/keybox-file.c (_keybox_write_header_blob): Set openpgp header flag. * kbx/keybox-blob.c (_keybox_update_header_blob): Add arg for_openpgp and set header flag. * kbx/keybox-init.c (keybox_new): Rename to do_keybox_new, make static and add arg for_openpgp. (keybox_new_openpgp, keybox_new_x509): New. Use them instead of the former keybox_new. * kbx/keybox-update.c (blob_filecopy): Add arg for_openpgp and set the openpgp header flags. * g10/keydb.c (rt_from_file): New. Factored out and extended from keydb_add_resource. (keydb_add_resource): Switch to the kbx file if it has the openpgp flag set. * kbx/keybox-dump.c (dump_header_blob): Print header flags. -- The problem was reported by dkg on gnupg-devel (2014-10-07): I just discovered a new problem, though, which will affect people on systems that have gpg and gpg2 coinstalled: 0) create a new keyring with gpg2, and use it exclusively with gpg2 for a while. 1) somehow (accidentally?) use gpg (1.4.x) again -- this creates ~/.gnupg/pubring.gpg 2) future runs of gpg2 now only look at pubring.gpg and ignore pubring.kbx -- the keys you had accumulated in the keybox are no longer listed in the output of gpg2 --list-keys Note that gpgsm has always used pubring.kbx and thus this file might already be there but without gpg ever inserted a key. The new flag in the KBX header gives us an indication whether a KBX file has ever been written by gpg >= 2.1. If that is the case we will use it instead of the default pubring.gpg. Signed-off-by: Werner Koch <wk@gnupg.org>
2014-10-09 19:10:32 +02:00
hd->active[j].u.kb = keybox_new_openpgp (all_resources[i].token, 0);
if (!hd->active[j].u.kb)
die = 1;
j++;
break;
}
}
hd->used = j;
active_handles++;
if (die)
{
keydb_release (hd);
hd = NULL;
}
return hd;
}
void
keydb_release (KEYDB_HANDLE hd)
{
int i;
if (!hd)
return;
assert (active_handles > 0);
active_handles--;
unlock_all (hd);
for (i=0; i < hd->used; i++)
{
switch (hd->active[i].type)
{
case KEYDB_RESOURCE_TYPE_NONE:
break;
case KEYDB_RESOURCE_TYPE_KEYRING:
keyring_release (hd->active[i].u.kr);
break;
case KEYDB_RESOURCE_TYPE_KEYBOX:
keybox_release (hd->active[i].u.kb);
break;
}
}
xfree (hd);
}
void
keydb_disable_caching (KEYDB_HANDLE hd)
{
if (hd)
hd->no_caching = 1;
}
const char *
keydb_get_resource_name (KEYDB_HANDLE hd)
{
int idx;
const char *s = NULL;
if (!hd)
return NULL;
if ( hd->found >= 0 && hd->found < hd->used)
idx = hd->found;
else if ( hd->current >= 0 && hd->current < hd->used)
idx = hd->current;
else
idx = 0;
switch (hd->active[idx].type)
{
case KEYDB_RESOURCE_TYPE_NONE:
s = NULL;
break;
case KEYDB_RESOURCE_TYPE_KEYRING:
s = keyring_get_resource_name (hd->active[idx].u.kr);
break;
case KEYDB_RESOURCE_TYPE_KEYBOX:
s = keybox_get_resource_name (hd->active[idx].u.kb);
break;
}
return s? s: "";
}
static int
lock_all (KEYDB_HANDLE hd)
{
int i, rc = 0;
/* Fixme: This locking scheme may lead to a deadlock if the resources
are not added in the same order by all processes. We are
currently only allowing one resource so it is not a problem.
[Oops: Who claimed the latter]
To fix this we need to use a lock file to protect lock_all. */
for (i=0; !rc && i < hd->used; i++)
{
switch (hd->active[i].type)
{
case KEYDB_RESOURCE_TYPE_NONE:
break;
case KEYDB_RESOURCE_TYPE_KEYRING:
rc = keyring_lock (hd->active[i].u.kr, 1);
break;
case KEYDB_RESOURCE_TYPE_KEYBOX:
rc = keybox_lock (hd->active[i].u.kb, 1);
break;
}
}
if (rc)
{
/* Revert the already taken locks. */
for (i--; i >= 0; i--)
{
switch (hd->active[i].type)
{
case KEYDB_RESOURCE_TYPE_NONE:
break;
case KEYDB_RESOURCE_TYPE_KEYRING:
keyring_lock (hd->active[i].u.kr, 0);
break;
case KEYDB_RESOURCE_TYPE_KEYBOX:
rc = keybox_lock (hd->active[i].u.kb, 0);
break;
}
}
}
else
hd->locked = 1;
return rc;
}
static void
unlock_all (KEYDB_HANDLE hd)
{
int i;
if (!hd->locked)
return;
for (i=hd->used-1; i >= 0; i--)
{
switch (hd->active[i].type)
{
case KEYDB_RESOURCE_TYPE_NONE:
break;
case KEYDB_RESOURCE_TYPE_KEYRING:
keyring_lock (hd->active[i].u.kr, 0);
break;
case KEYDB_RESOURCE_TYPE_KEYBOX:
keybox_lock (hd->active[i].u.kb, 0);
break;
}
}
hd->locked = 0;
}
void
keydb_push_found_state (KEYDB_HANDLE hd)
{
if (!hd)
return;
if (hd->found < 0 || hd->found >= hd->used)
{
hd->saved_found = -1;
return;
}
switch (hd->active[hd->found].type)
{
case KEYDB_RESOURCE_TYPE_NONE:
break;
case KEYDB_RESOURCE_TYPE_KEYRING:
keyring_push_found_state (hd->active[hd->found].u.kr);
break;
case KEYDB_RESOURCE_TYPE_KEYBOX:
keybox_push_found_state (hd->active[hd->found].u.kb);
break;
}
hd->saved_found = hd->found;
hd->found = -1;
}
void
keydb_pop_found_state (KEYDB_HANDLE hd)
{
if (!hd)
return;
hd->found = hd->saved_found;
hd->saved_found = -1;
if (hd->found < 0 || hd->found >= hd->used)
return;
switch (hd->active[hd->found].type)
{
case KEYDB_RESOURCE_TYPE_NONE:
break;
case KEYDB_RESOURCE_TYPE_KEYRING:
keyring_pop_found_state (hd->active[hd->found].u.kr);
break;
case KEYDB_RESOURCE_TYPE_KEYBOX:
keybox_pop_found_state (hd->active[hd->found].u.kb);
break;
}
}
static gpg_error_t
parse_keyblock_image (iobuf_t iobuf, int pk_no, int uid_no,
const u32 *sigstatus, kbnode_t *r_keyblock)
{
gpg_error_t err;
PACKET *pkt;
kbnode_t keyblock = NULL;
kbnode_t node, *tail;
int in_cert, save_mode;
u32 n_sigs;
int pk_count, uid_count;
*r_keyblock = NULL;
pkt = xtrymalloc (sizeof *pkt);
if (!pkt)
return gpg_error_from_syserror ();
init_packet (pkt);
save_mode = set_packet_list_mode (0);
in_cert = 0;
n_sigs = 0;
tail = NULL;
pk_count = uid_count = 0;
while ((err = parse_packet (iobuf, pkt)) != -1)
{
if (gpg_err_code (err) == GPG_ERR_UNKNOWN_PACKET)
{
free_packet (pkt);
init_packet (pkt);
continue;
}
if (err)
{
log_error ("parse_keyblock_image: read error: %s\n",
gpg_strerror (err));
err = gpg_error (GPG_ERR_INV_KEYRING);
break;
}
/* Filter allowed packets. */
switch (pkt->pkttype)
{
case PKT_PUBLIC_KEY:
case PKT_PUBLIC_SUBKEY:
case PKT_SECRET_KEY:
case PKT_SECRET_SUBKEY:
case PKT_USER_ID:
case PKT_ATTRIBUTE:
case PKT_SIGNATURE:
break; /* Allowed per RFC. */
default:
/* Note that can't allow ring trust packets here and some of
the other GPG specific packets don't make sense either. */
log_error ("skipped packet of type %d in keybox\n",
(int)pkt->pkttype);
free_packet(pkt);
init_packet(pkt);
continue;
}
/* Other sanity checks. */
if (!in_cert && pkt->pkttype != PKT_PUBLIC_KEY)
{
log_error ("parse_keyblock_image: first packet in a keybox blob "
"is not a public key packet\n");
err = gpg_error (GPG_ERR_INV_KEYRING);
break;
}
if (in_cert && (pkt->pkttype == PKT_PUBLIC_KEY
|| pkt->pkttype == PKT_SECRET_KEY))
{
log_error ("parse_keyblock_image: "
"multiple keyblocks in a keybox blob\n");
err = gpg_error (GPG_ERR_INV_KEYRING);
break;
}
in_cert = 1;
if (pkt->pkttype == PKT_SIGNATURE && sigstatus)
{
PKT_signature *sig = pkt->pkt.signature;
n_sigs++;
if (n_sigs > sigstatus[0])
{
log_error ("parse_keyblock_image: "
"more signatures than found in the meta data\n");
err = gpg_error (GPG_ERR_INV_KEYRING);
break;
}
if (sigstatus[n_sigs])
{
sig->flags.checked = 1;
if (sigstatus[n_sigs] == 1 )
; /* missing key */
else if (sigstatus[n_sigs] == 2 )
; /* bad signature */
else if (sigstatus[n_sigs] < 0x10000000)
; /* bad flag */
else
{
sig->flags.valid = 1;
/* Fixme: Shall we set the expired flag here? */
}
}
}
node = new_kbnode (pkt);
switch (pkt->pkttype)
{
case PKT_PUBLIC_KEY:
case PKT_PUBLIC_SUBKEY:
case PKT_SECRET_KEY:
case PKT_SECRET_SUBKEY:
if (++pk_count == pk_no)
node->flag |= 1;
break;
case PKT_USER_ID:
if (++uid_count == uid_no)
node->flag |= 2;
break;
default:
break;
}
if (!keyblock)
keyblock = node;
else
*tail = node;
tail = &node->next;
pkt = xtrymalloc (sizeof *pkt);
if (!pkt)
{
err = gpg_error_from_syserror ();
break;
}
init_packet (pkt);
}
set_packet_list_mode (save_mode);
if (err == -1 && keyblock)
err = 0; /* Got the entire keyblock. */
if (!err && sigstatus && n_sigs != sigstatus[0])
{
log_error ("parse_keyblock_image: signature count does not match\n");
err = gpg_error (GPG_ERR_INV_KEYRING);
}
if (err)
release_kbnode (keyblock);
else
*r_keyblock = keyblock;
free_packet (pkt);
xfree (pkt);
return err;
}
gpg_error_t
keydb_get_keyblock (KEYDB_HANDLE hd, KBNODE *ret_kb)
{
gpg_error_t err = 0;
*ret_kb = NULL;
if (!hd)
return gpg_error (GPG_ERR_INV_ARG);
if (DBG_CLOCK)
log_clock ("keydb_get_keybock enter");
if (hd->keyblock_cache.state == KEYBLOCK_CACHE_FILLED)
gpg: Cache keybox searches. * common/iobuf.c (iobuf_seek): Fix for temp streams. * g10/pubkey-enc.c (get_session_key, get_it): Add some log_clock calls. * g10/keydb.c (dump_search_desc): New. (enum_keyblock_states, struct keyblock_cache): New. (keyblock_cache_clear): New. (keydb_get_keyblock, keydb_search): Implement a keyblock cache. (keydb_update_keyblock, keydb_insert_keyblock, keydb_delete_keyblock) (keydb_rebuild_caches, keydb_search_reset): Clear the cache. -- Gpg uses the key database at several places without a central coordination. This leads to several scans of the keybox for the same key. To improve that we now use a simple cache to store a retrieved keyblock in certain cases. In theory this caching could also be done for old keyrings, but it is a bit more work and questionable whether it is needed; the keybox scheme is anyway much faster than keyrings. Using a keybox with 20000 384 bit ECDSA/ECHD keypairs and a 252 byte sample text we get these values for encrypt and decrypt operations on an Core i5 4*3.33Ghz system. The option --trust-model=always is used. Times are given in milliseconds wall time. | | enc | dec | dec,q | |-----------+-----+-----+-------| | key 1 | 48 | 96 | 70 | | key 10000 | 60 | 98 | 80 | | key 20000 | 69 | 106 | 88 | | 10 keys | 540 | 290 | 70 | The 10 keys test uses a mix of keys, the first one is used for decryption but all keys are looked up so that information about are printed. The last column gives decryption results w/o information printing (--quiet). The keybox is always scanned sequentially without using any index. By adding an index to the keybox it will be possible to further reduce the time required for keys stored to the end of the file.
2013-01-08 14:44:49 +01:00
{
err = iobuf_seek (hd->keyblock_cache.iobuf, 0);
gpg: Cache keybox searches. * common/iobuf.c (iobuf_seek): Fix for temp streams. * g10/pubkey-enc.c (get_session_key, get_it): Add some log_clock calls. * g10/keydb.c (dump_search_desc): New. (enum_keyblock_states, struct keyblock_cache): New. (keyblock_cache_clear): New. (keydb_get_keyblock, keydb_search): Implement a keyblock cache. (keydb_update_keyblock, keydb_insert_keyblock, keydb_delete_keyblock) (keydb_rebuild_caches, keydb_search_reset): Clear the cache. -- Gpg uses the key database at several places without a central coordination. This leads to several scans of the keybox for the same key. To improve that we now use a simple cache to store a retrieved keyblock in certain cases. In theory this caching could also be done for old keyrings, but it is a bit more work and questionable whether it is needed; the keybox scheme is anyway much faster than keyrings. Using a keybox with 20000 384 bit ECDSA/ECHD keypairs and a 252 byte sample text we get these values for encrypt and decrypt operations on an Core i5 4*3.33Ghz system. The option --trust-model=always is used. Times are given in milliseconds wall time. | | enc | dec | dec,q | |-----------+-----+-----+-------| | key 1 | 48 | 96 | 70 | | key 10000 | 60 | 98 | 80 | | key 20000 | 69 | 106 | 88 | | 10 keys | 540 | 290 | 70 | The 10 keys test uses a mix of keys, the first one is used for decryption but all keys are looked up so that information about are printed. The last column gives decryption results w/o information printing (--quiet). The keybox is always scanned sequentially without using any index. By adding an index to the keybox it will be possible to further reduce the time required for keys stored to the end of the file.
2013-01-08 14:44:49 +01:00
if (err)
{
log_error ("keydb_get_keyblock: failed to rewind iobuf for cache\n");
keyblock_cache_clear (hd);
}
else
{
err = parse_keyblock_image (hd->keyblock_cache.iobuf,
hd->keyblock_cache.pk_no,
hd->keyblock_cache.uid_no,
hd->keyblock_cache.sigstatus,
ret_kb);
if (err)
keyblock_cache_clear (hd);
if (DBG_CLOCK)
log_clock (err? "keydb_get_keyblock leave (cached, failed)"
: "keydb_get_keyblock leave (cached)");
return err;
}
gpg: Cache keybox searches. * common/iobuf.c (iobuf_seek): Fix for temp streams. * g10/pubkey-enc.c (get_session_key, get_it): Add some log_clock calls. * g10/keydb.c (dump_search_desc): New. (enum_keyblock_states, struct keyblock_cache): New. (keyblock_cache_clear): New. (keydb_get_keyblock, keydb_search): Implement a keyblock cache. (keydb_update_keyblock, keydb_insert_keyblock, keydb_delete_keyblock) (keydb_rebuild_caches, keydb_search_reset): Clear the cache. -- Gpg uses the key database at several places without a central coordination. This leads to several scans of the keybox for the same key. To improve that we now use a simple cache to store a retrieved keyblock in certain cases. In theory this caching could also be done for old keyrings, but it is a bit more work and questionable whether it is needed; the keybox scheme is anyway much faster than keyrings. Using a keybox with 20000 384 bit ECDSA/ECHD keypairs and a 252 byte sample text we get these values for encrypt and decrypt operations on an Core i5 4*3.33Ghz system. The option --trust-model=always is used. Times are given in milliseconds wall time. | | enc | dec | dec,q | |-----------+-----+-----+-------| | key 1 | 48 | 96 | 70 | | key 10000 | 60 | 98 | 80 | | key 20000 | 69 | 106 | 88 | | 10 keys | 540 | 290 | 70 | The 10 keys test uses a mix of keys, the first one is used for decryption but all keys are looked up so that information about are printed. The last column gives decryption results w/o information printing (--quiet). The keybox is always scanned sequentially without using any index. By adding an index to the keybox it will be possible to further reduce the time required for keys stored to the end of the file.
2013-01-08 14:44:49 +01:00
}
if (hd->found < 0 || hd->found >= hd->used)
return gpg_error (GPG_ERR_VALUE_NOT_FOUND);
switch (hd->active[hd->found].type)
{
case KEYDB_RESOURCE_TYPE_NONE:
err = gpg_error (GPG_ERR_GENERAL); /* oops */
break;
case KEYDB_RESOURCE_TYPE_KEYRING:
err = keyring_get_keyblock (hd->active[hd->found].u.kr, ret_kb);
break;
case KEYDB_RESOURCE_TYPE_KEYBOX:
{
iobuf_t iobuf;
u32 *sigstatus;
int pk_no, uid_no;
err = keybox_get_keyblock (hd->active[hd->found].u.kb,
&iobuf, &pk_no, &uid_no, &sigstatus);
if (!err)
{
err = parse_keyblock_image (iobuf, pk_no, uid_no, sigstatus,
ret_kb);
if (!err && hd->keyblock_cache.state == KEYBLOCK_CACHE_PREPARED)
gpg: Cache keybox searches. * common/iobuf.c (iobuf_seek): Fix for temp streams. * g10/pubkey-enc.c (get_session_key, get_it): Add some log_clock calls. * g10/keydb.c (dump_search_desc): New. (enum_keyblock_states, struct keyblock_cache): New. (keyblock_cache_clear): New. (keydb_get_keyblock, keydb_search): Implement a keyblock cache. (keydb_update_keyblock, keydb_insert_keyblock, keydb_delete_keyblock) (keydb_rebuild_caches, keydb_search_reset): Clear the cache. -- Gpg uses the key database at several places without a central coordination. This leads to several scans of the keybox for the same key. To improve that we now use a simple cache to store a retrieved keyblock in certain cases. In theory this caching could also be done for old keyrings, but it is a bit more work and questionable whether it is needed; the keybox scheme is anyway much faster than keyrings. Using a keybox with 20000 384 bit ECDSA/ECHD keypairs and a 252 byte sample text we get these values for encrypt and decrypt operations on an Core i5 4*3.33Ghz system. The option --trust-model=always is used. Times are given in milliseconds wall time. | | enc | dec | dec,q | |-----------+-----+-----+-------| | key 1 | 48 | 96 | 70 | | key 10000 | 60 | 98 | 80 | | key 20000 | 69 | 106 | 88 | | 10 keys | 540 | 290 | 70 | The 10 keys test uses a mix of keys, the first one is used for decryption but all keys are looked up so that information about are printed. The last column gives decryption results w/o information printing (--quiet). The keybox is always scanned sequentially without using any index. By adding an index to the keybox it will be possible to further reduce the time required for keys stored to the end of the file.
2013-01-08 14:44:49 +01:00
{
hd->keyblock_cache.state = KEYBLOCK_CACHE_FILLED;
hd->keyblock_cache.sigstatus = sigstatus;
hd->keyblock_cache.iobuf = iobuf;
hd->keyblock_cache.pk_no = pk_no;
hd->keyblock_cache.uid_no = uid_no;
gpg: Cache keybox searches. * common/iobuf.c (iobuf_seek): Fix for temp streams. * g10/pubkey-enc.c (get_session_key, get_it): Add some log_clock calls. * g10/keydb.c (dump_search_desc): New. (enum_keyblock_states, struct keyblock_cache): New. (keyblock_cache_clear): New. (keydb_get_keyblock, keydb_search): Implement a keyblock cache. (keydb_update_keyblock, keydb_insert_keyblock, keydb_delete_keyblock) (keydb_rebuild_caches, keydb_search_reset): Clear the cache. -- Gpg uses the key database at several places without a central coordination. This leads to several scans of the keybox for the same key. To improve that we now use a simple cache to store a retrieved keyblock in certain cases. In theory this caching could also be done for old keyrings, but it is a bit more work and questionable whether it is needed; the keybox scheme is anyway much faster than keyrings. Using a keybox with 20000 384 bit ECDSA/ECHD keypairs and a 252 byte sample text we get these values for encrypt and decrypt operations on an Core i5 4*3.33Ghz system. The option --trust-model=always is used. Times are given in milliseconds wall time. | | enc | dec | dec,q | |-----------+-----+-----+-------| | key 1 | 48 | 96 | 70 | | key 10000 | 60 | 98 | 80 | | key 20000 | 69 | 106 | 88 | | 10 keys | 540 | 290 | 70 | The 10 keys test uses a mix of keys, the first one is used for decryption but all keys are looked up so that information about are printed. The last column gives decryption results w/o information printing (--quiet). The keybox is always scanned sequentially without using any index. By adding an index to the keybox it will be possible to further reduce the time required for keys stored to the end of the file.
2013-01-08 14:44:49 +01:00
}
else
{
xfree (sigstatus);
iobuf_close (iobuf);
}
}
}
break;
}
if (hd->keyblock_cache.state != KEYBLOCK_CACHE_FILLED)
keyblock_cache_clear (hd);
gpg: Cache keybox searches. * common/iobuf.c (iobuf_seek): Fix for temp streams. * g10/pubkey-enc.c (get_session_key, get_it): Add some log_clock calls. * g10/keydb.c (dump_search_desc): New. (enum_keyblock_states, struct keyblock_cache): New. (keyblock_cache_clear): New. (keydb_get_keyblock, keydb_search): Implement a keyblock cache. (keydb_update_keyblock, keydb_insert_keyblock, keydb_delete_keyblock) (keydb_rebuild_caches, keydb_search_reset): Clear the cache. -- Gpg uses the key database at several places without a central coordination. This leads to several scans of the keybox for the same key. To improve that we now use a simple cache to store a retrieved keyblock in certain cases. In theory this caching could also be done for old keyrings, but it is a bit more work and questionable whether it is needed; the keybox scheme is anyway much faster than keyrings. Using a keybox with 20000 384 bit ECDSA/ECHD keypairs and a 252 byte sample text we get these values for encrypt and decrypt operations on an Core i5 4*3.33Ghz system. The option --trust-model=always is used. Times are given in milliseconds wall time. | | enc | dec | dec,q | |-----------+-----+-----+-------| | key 1 | 48 | 96 | 70 | | key 10000 | 60 | 98 | 80 | | key 20000 | 69 | 106 | 88 | | 10 keys | 540 | 290 | 70 | The 10 keys test uses a mix of keys, the first one is used for decryption but all keys are looked up so that information about are printed. The last column gives decryption results w/o information printing (--quiet). The keybox is always scanned sequentially without using any index. By adding an index to the keybox it will be possible to further reduce the time required for keys stored to the end of the file.
2013-01-08 14:44:49 +01:00
if (DBG_CLOCK)
log_clock (err? "keydb_get_keyblock leave (failed)"
: "keydb_get_keyblock leave");
return err;
}
/* Build a keyblock image from KEYBLOCK. Returns 0 on success and
only then stores a new iobuf object at R_IOBUF and a signature
status vecotor at R_SIGSTATUS. */
static gpg_error_t
build_keyblock_image (kbnode_t keyblock, iobuf_t *r_iobuf, u32 **r_sigstatus)
{
gpg_error_t err;
iobuf_t iobuf;
kbnode_t kbctx, node;
u32 n_sigs;
u32 *sigstatus;
*r_iobuf = NULL;
if (r_sigstatus)
*r_sigstatus = NULL;
/* Allocate a vector for the signature cache. This is an array of
u32 values with the first value giving the number of elements to
follow and each element descriping the cache status of the
signature. */
if (r_sigstatus)
{
for (kbctx=NULL, n_sigs=0; (node = walk_kbnode (keyblock, &kbctx, 0));)
if (node->pkt->pkttype == PKT_SIGNATURE)
n_sigs++;
sigstatus = xtrycalloc (1+n_sigs, sizeof *sigstatus);
if (!sigstatus)
return gpg_error_from_syserror ();
}
else
sigstatus = NULL;
iobuf = iobuf_temp ();
for (kbctx = NULL, n_sigs = 0; (node = walk_kbnode (keyblock, &kbctx, 0));)
{
/* Make sure to use only packets valid on a keyblock. */
switch (node->pkt->pkttype)
{
case PKT_PUBLIC_KEY:
case PKT_PUBLIC_SUBKEY:
case PKT_SIGNATURE:
case PKT_USER_ID:
case PKT_ATTRIBUTE:
/* Note that we don't want the ring trust packets. They are
not useful. */
break;
default:
continue;
}
err = build_packet (iobuf, node->pkt);
if (err)
{
iobuf_close (iobuf);
return err;
}
/* Build signature status vector. */
if (node->pkt->pkttype == PKT_SIGNATURE)
{
PKT_signature *sig = node->pkt->pkt.signature;
n_sigs++;
/* Fixme: Detect the "missing key" status. */
if (sig->flags.checked && sigstatus)
{
if (sig->flags.valid)
{
if (!sig->expiredate)
sigstatus[n_sigs] = 0xffffffff;
else if (sig->expiredate < 0x1000000)
sigstatus[n_sigs] = 0x10000000;
else
sigstatus[n_sigs] = sig->expiredate;
}
else
sigstatus[n_sigs] = 0x00000002; /* Bad signature. */
}
}
}
if (sigstatus)
sigstatus[0] = n_sigs;
*r_iobuf = iobuf;
if (r_sigstatus)
*r_sigstatus = sigstatus;
return 0;
}
gpg_error_t
keydb_update_keyblock (KEYDB_HANDLE hd, kbnode_t kb)
{
gpg_error_t err;
if (!hd)
return gpg_error (GPG_ERR_INV_ARG);
kid_not_found_flush ();
keyblock_cache_clear (hd);
gpg: Cache keybox searches. * common/iobuf.c (iobuf_seek): Fix for temp streams. * g10/pubkey-enc.c (get_session_key, get_it): Add some log_clock calls. * g10/keydb.c (dump_search_desc): New. (enum_keyblock_states, struct keyblock_cache): New. (keyblock_cache_clear): New. (keydb_get_keyblock, keydb_search): Implement a keyblock cache. (keydb_update_keyblock, keydb_insert_keyblock, keydb_delete_keyblock) (keydb_rebuild_caches, keydb_search_reset): Clear the cache. -- Gpg uses the key database at several places without a central coordination. This leads to several scans of the keybox for the same key. To improve that we now use a simple cache to store a retrieved keyblock in certain cases. In theory this caching could also be done for old keyrings, but it is a bit more work and questionable whether it is needed; the keybox scheme is anyway much faster than keyrings. Using a keybox with 20000 384 bit ECDSA/ECHD keypairs and a 252 byte sample text we get these values for encrypt and decrypt operations on an Core i5 4*3.33Ghz system. The option --trust-model=always is used. Times are given in milliseconds wall time. | | enc | dec | dec,q | |-----------+-----+-----+-------| | key 1 | 48 | 96 | 70 | | key 10000 | 60 | 98 | 80 | | key 20000 | 69 | 106 | 88 | | 10 keys | 540 | 290 | 70 | The 10 keys test uses a mix of keys, the first one is used for decryption but all keys are looked up so that information about are printed. The last column gives decryption results w/o information printing (--quiet). The keybox is always scanned sequentially without using any index. By adding an index to the keybox it will be possible to further reduce the time required for keys stored to the end of the file.
2013-01-08 14:44:49 +01:00
if (hd->found < 0 || hd->found >= hd->used)
return gpg_error (GPG_ERR_VALUE_NOT_FOUND);
if (opt.dry_run)
return 0;
err = lock_all (hd);
if (err)
return err;
switch (hd->active[hd->found].type)
{
case KEYDB_RESOURCE_TYPE_NONE:
err = gpg_error (GPG_ERR_GENERAL); /* oops */
break;
case KEYDB_RESOURCE_TYPE_KEYRING:
err = keyring_update_keyblock (hd->active[hd->found].u.kr, kb);
break;
case KEYDB_RESOURCE_TYPE_KEYBOX:
{
iobuf_t iobuf;
err = build_keyblock_image (kb, &iobuf, NULL);
if (!err)
{
err = keybox_update_keyblock (hd->active[hd->found].u.kb,
iobuf_get_temp_buffer (iobuf),
iobuf_get_temp_length (iobuf));
iobuf_close (iobuf);
}
}
break;
}
unlock_all (hd);
return err;
}
gpg_error_t
keydb_insert_keyblock (KEYDB_HANDLE hd, kbnode_t kb)
{
gpg_error_t err;
int idx;
if (!hd)
return gpg_error (GPG_ERR_INV_ARG);
kid_not_found_flush ();
keyblock_cache_clear (hd);
gpg: Cache keybox searches. * common/iobuf.c (iobuf_seek): Fix for temp streams. * g10/pubkey-enc.c (get_session_key, get_it): Add some log_clock calls. * g10/keydb.c (dump_search_desc): New. (enum_keyblock_states, struct keyblock_cache): New. (keyblock_cache_clear): New. (keydb_get_keyblock, keydb_search): Implement a keyblock cache. (keydb_update_keyblock, keydb_insert_keyblock, keydb_delete_keyblock) (keydb_rebuild_caches, keydb_search_reset): Clear the cache. -- Gpg uses the key database at several places without a central coordination. This leads to several scans of the keybox for the same key. To improve that we now use a simple cache to store a retrieved keyblock in certain cases. In theory this caching could also be done for old keyrings, but it is a bit more work and questionable whether it is needed; the keybox scheme is anyway much faster than keyrings. Using a keybox with 20000 384 bit ECDSA/ECHD keypairs and a 252 byte sample text we get these values for encrypt and decrypt operations on an Core i5 4*3.33Ghz system. The option --trust-model=always is used. Times are given in milliseconds wall time. | | enc | dec | dec,q | |-----------+-----+-----+-------| | key 1 | 48 | 96 | 70 | | key 10000 | 60 | 98 | 80 | | key 20000 | 69 | 106 | 88 | | 10 keys | 540 | 290 | 70 | The 10 keys test uses a mix of keys, the first one is used for decryption but all keys are looked up so that information about are printed. The last column gives decryption results w/o information printing (--quiet). The keybox is always scanned sequentially without using any index. By adding an index to the keybox it will be possible to further reduce the time required for keys stored to the end of the file.
2013-01-08 14:44:49 +01:00
if (opt.dry_run)
return 0;
if (hd->found >= 0 && hd->found < hd->used)
idx = hd->found;
else if (hd->current >= 0 && hd->current < hd->used)
idx = hd->current;
else
return gpg_error (GPG_ERR_GENERAL);
err = lock_all (hd);
if (err)
return err;
switch (hd->active[idx].type)
{
case KEYDB_RESOURCE_TYPE_NONE:
err = gpg_error (GPG_ERR_GENERAL); /* oops */
break;
case KEYDB_RESOURCE_TYPE_KEYRING:
err = keyring_insert_keyblock (hd->active[idx].u.kr, kb);
break;
case KEYDB_RESOURCE_TYPE_KEYBOX:
{ /* We need to turn our kbnode_t list of packets into a proper
keyblock first. This is required by the OpenPGP key parser
included in the keybox code. Eventually we can change this
kludge to have the caller pass the image. */
iobuf_t iobuf;
u32 *sigstatus;
err = build_keyblock_image (kb, &iobuf, &sigstatus);
if (!err)
{
err = keybox_insert_keyblock (hd->active[idx].u.kb,
iobuf_get_temp_buffer (iobuf),
iobuf_get_temp_length (iobuf),
sigstatus);
xfree (sigstatus);
iobuf_close (iobuf);
}
}
break;
}
unlock_all (hd);
return err;
}
gpg_error_t
keydb_delete_keyblock (KEYDB_HANDLE hd)
{
gpg_error_t rc;
if (!hd)
return gpg_error (GPG_ERR_INV_ARG);
kid_not_found_flush ();
keyblock_cache_clear (hd);
gpg: Cache keybox searches. * common/iobuf.c (iobuf_seek): Fix for temp streams. * g10/pubkey-enc.c (get_session_key, get_it): Add some log_clock calls. * g10/keydb.c (dump_search_desc): New. (enum_keyblock_states, struct keyblock_cache): New. (keyblock_cache_clear): New. (keydb_get_keyblock, keydb_search): Implement a keyblock cache. (keydb_update_keyblock, keydb_insert_keyblock, keydb_delete_keyblock) (keydb_rebuild_caches, keydb_search_reset): Clear the cache. -- Gpg uses the key database at several places without a central coordination. This leads to several scans of the keybox for the same key. To improve that we now use a simple cache to store a retrieved keyblock in certain cases. In theory this caching could also be done for old keyrings, but it is a bit more work and questionable whether it is needed; the keybox scheme is anyway much faster than keyrings. Using a keybox with 20000 384 bit ECDSA/ECHD keypairs and a 252 byte sample text we get these values for encrypt and decrypt operations on an Core i5 4*3.33Ghz system. The option --trust-model=always is used. Times are given in milliseconds wall time. | | enc | dec | dec,q | |-----------+-----+-----+-------| | key 1 | 48 | 96 | 70 | | key 10000 | 60 | 98 | 80 | | key 20000 | 69 | 106 | 88 | | 10 keys | 540 | 290 | 70 | The 10 keys test uses a mix of keys, the first one is used for decryption but all keys are looked up so that information about are printed. The last column gives decryption results w/o information printing (--quiet). The keybox is always scanned sequentially without using any index. By adding an index to the keybox it will be possible to further reduce the time required for keys stored to the end of the file.
2013-01-08 14:44:49 +01:00
if (hd->found < 0 || hd->found >= hd->used)
return gpg_error (GPG_ERR_VALUE_NOT_FOUND);
if (opt.dry_run)
return 0;
rc = lock_all (hd);
if (rc)
return rc;
switch (hd->active[hd->found].type)
{
case KEYDB_RESOURCE_TYPE_NONE:
rc = gpg_error (GPG_ERR_GENERAL);
break;
case KEYDB_RESOURCE_TYPE_KEYRING:
rc = keyring_delete_keyblock (hd->active[hd->found].u.kr);
break;
case KEYDB_RESOURCE_TYPE_KEYBOX:
rc = keybox_delete (hd->active[hd->found].u.kb);
break;
}
unlock_all (hd);
return rc;
}
gpg_error_t
keydb_locate_writable (KEYDB_HANDLE hd)
{
gpg_error_t rc;
if (!hd)
return GPG_ERR_INV_ARG;
rc = keydb_search_reset (hd); /* this does reset hd->current */
if (rc)
return rc;
/* If we have a primary set, try that one first */
if (primary_keyring)
{
for ( ; hd->current >= 0 && hd->current < hd->used; hd->current++)
{
if(hd->active[hd->current].token==primary_keyring)
{
if(keyring_is_writable (hd->active[hd->current].token))
return 0;
else
break;
}
}
rc = keydb_search_reset (hd); /* this does reset hd->current */
if (rc)
return rc;
}
for ( ; hd->current >= 0 && hd->current < hd->used; hd->current++)
{
switch (hd->active[hd->current].type)
{
case KEYDB_RESOURCE_TYPE_NONE:
BUG();
break;
case KEYDB_RESOURCE_TYPE_KEYRING:
if (keyring_is_writable (hd->active[hd->current].token))
return 0; /* found (hd->current is set to it) */
break;
case KEYDB_RESOURCE_TYPE_KEYBOX:
if (keybox_is_writable (hd->active[hd->current].token))
return 0; /* found (hd->current is set to it) */
break;
}
}
return gpg_error (GPG_ERR_NOT_FOUND);
}
void
keydb_rebuild_caches (int noisy)
{
int i, rc;
for (i=0; i < used_resources; i++)
{
if (!keyring_is_writable (all_resources[i].token))
continue;
switch (all_resources[i].type)
{
case KEYDB_RESOURCE_TYPE_NONE: /* ignore */
break;
case KEYDB_RESOURCE_TYPE_KEYRING:
rc = keyring_rebuild_cache (all_resources[i].token,noisy);
if (rc)
log_error (_("failed to rebuild keyring cache: %s\n"),
gpg_strerror (rc));
break;
case KEYDB_RESOURCE_TYPE_KEYBOX:
/* N/A. */
break;
}
}
}
unsigned long
keydb_get_skipped_counter (KEYDB_HANDLE hd)
{
return hd ? hd->skipped_long_blobs : 0;
}
gpg_error_t
keydb_search_reset (KEYDB_HANDLE hd)
{
gpg_error_t rc = 0;
int i;
if (!hd)
return gpg_error (GPG_ERR_INV_ARG);
keyblock_cache_clear (hd);
gpg: Cache keybox searches. * common/iobuf.c (iobuf_seek): Fix for temp streams. * g10/pubkey-enc.c (get_session_key, get_it): Add some log_clock calls. * g10/keydb.c (dump_search_desc): New. (enum_keyblock_states, struct keyblock_cache): New. (keyblock_cache_clear): New. (keydb_get_keyblock, keydb_search): Implement a keyblock cache. (keydb_update_keyblock, keydb_insert_keyblock, keydb_delete_keyblock) (keydb_rebuild_caches, keydb_search_reset): Clear the cache. -- Gpg uses the key database at several places without a central coordination. This leads to several scans of the keybox for the same key. To improve that we now use a simple cache to store a retrieved keyblock in certain cases. In theory this caching could also be done for old keyrings, but it is a bit more work and questionable whether it is needed; the keybox scheme is anyway much faster than keyrings. Using a keybox with 20000 384 bit ECDSA/ECHD keypairs and a 252 byte sample text we get these values for encrypt and decrypt operations on an Core i5 4*3.33Ghz system. The option --trust-model=always is used. Times are given in milliseconds wall time. | | enc | dec | dec,q | |-----------+-----+-----+-------| | key 1 | 48 | 96 | 70 | | key 10000 | 60 | 98 | 80 | | key 20000 | 69 | 106 | 88 | | 10 keys | 540 | 290 | 70 | The 10 keys test uses a mix of keys, the first one is used for decryption but all keys are looked up so that information about are printed. The last column gives decryption results w/o information printing (--quiet). The keybox is always scanned sequentially without using any index. By adding an index to the keybox it will be possible to further reduce the time required for keys stored to the end of the file.
2013-01-08 14:44:49 +01:00
if (DBG_CLOCK)
log_clock ("keydb_search_reset");
if (DBG_CACHE)
log_debug ("keydb_search: reset (hd=%p)", hd);
hd->skipped_long_blobs = 0;
hd->current = 0;
hd->found = -1;
/* Now reset all resources. */
for (i=0; !rc && i < hd->used; i++)
{
switch (hd->active[i].type)
{
case KEYDB_RESOURCE_TYPE_NONE:
break;
case KEYDB_RESOURCE_TYPE_KEYRING:
rc = keyring_search_reset (hd->active[i].u.kr);
break;
case KEYDB_RESOURCE_TYPE_KEYBOX:
rc = keybox_search_reset (hd->active[i].u.kb);
break;
}
}
hd->is_reset = 1;
return rc;
}
gpg: Cache keybox searches. * common/iobuf.c (iobuf_seek): Fix for temp streams. * g10/pubkey-enc.c (get_session_key, get_it): Add some log_clock calls. * g10/keydb.c (dump_search_desc): New. (enum_keyblock_states, struct keyblock_cache): New. (keyblock_cache_clear): New. (keydb_get_keyblock, keydb_search): Implement a keyblock cache. (keydb_update_keyblock, keydb_insert_keyblock, keydb_delete_keyblock) (keydb_rebuild_caches, keydb_search_reset): Clear the cache. -- Gpg uses the key database at several places without a central coordination. This leads to several scans of the keybox for the same key. To improve that we now use a simple cache to store a retrieved keyblock in certain cases. In theory this caching could also be done for old keyrings, but it is a bit more work and questionable whether it is needed; the keybox scheme is anyway much faster than keyrings. Using a keybox with 20000 384 bit ECDSA/ECHD keypairs and a 252 byte sample text we get these values for encrypt and decrypt operations on an Core i5 4*3.33Ghz system. The option --trust-model=always is used. Times are given in milliseconds wall time. | | enc | dec | dec,q | |-----------+-----+-----+-------| | key 1 | 48 | 96 | 70 | | key 10000 | 60 | 98 | 80 | | key 20000 | 69 | 106 | 88 | | 10 keys | 540 | 290 | 70 | The 10 keys test uses a mix of keys, the first one is used for decryption but all keys are looked up so that information about are printed. The last column gives decryption results w/o information printing (--quiet). The keybox is always scanned sequentially without using any index. By adding an index to the keybox it will be possible to further reduce the time required for keys stored to the end of the file.
2013-01-08 14:44:49 +01:00
static void
dump_search_desc (KEYDB_HANDLE hd, const char *text,
KEYDB_SEARCH_DESC *desc, size_t ndesc)
gpg: Cache keybox searches. * common/iobuf.c (iobuf_seek): Fix for temp streams. * g10/pubkey-enc.c (get_session_key, get_it): Add some log_clock calls. * g10/keydb.c (dump_search_desc): New. (enum_keyblock_states, struct keyblock_cache): New. (keyblock_cache_clear): New. (keydb_get_keyblock, keydb_search): Implement a keyblock cache. (keydb_update_keyblock, keydb_insert_keyblock, keydb_delete_keyblock) (keydb_rebuild_caches, keydb_search_reset): Clear the cache. -- Gpg uses the key database at several places without a central coordination. This leads to several scans of the keybox for the same key. To improve that we now use a simple cache to store a retrieved keyblock in certain cases. In theory this caching could also be done for old keyrings, but it is a bit more work and questionable whether it is needed; the keybox scheme is anyway much faster than keyrings. Using a keybox with 20000 384 bit ECDSA/ECHD keypairs and a 252 byte sample text we get these values for encrypt and decrypt operations on an Core i5 4*3.33Ghz system. The option --trust-model=always is used. Times are given in milliseconds wall time. | | enc | dec | dec,q | |-----------+-----+-----+-------| | key 1 | 48 | 96 | 70 | | key 10000 | 60 | 98 | 80 | | key 20000 | 69 | 106 | 88 | | 10 keys | 540 | 290 | 70 | The 10 keys test uses a mix of keys, the first one is used for decryption but all keys are looked up so that information about are printed. The last column gives decryption results w/o information printing (--quiet). The keybox is always scanned sequentially without using any index. By adding an index to the keybox it will be possible to further reduce the time required for keys stored to the end of the file.
2013-01-08 14:44:49 +01:00
{
int n;
const char *s;
for (n=0; n < ndesc; n++)
{
switch (desc[n].mode)
{
case KEYDB_SEARCH_MODE_NONE: s = "none"; break;
case KEYDB_SEARCH_MODE_EXACT: s = "exact"; break;
case KEYDB_SEARCH_MODE_SUBSTR: s = "substr"; break;
case KEYDB_SEARCH_MODE_MAIL: s = "mail"; break;
case KEYDB_SEARCH_MODE_MAILSUB: s = "mailsub"; break;
case KEYDB_SEARCH_MODE_MAILEND: s = "mailend"; break;
case KEYDB_SEARCH_MODE_WORDS: s = "words"; break;
case KEYDB_SEARCH_MODE_SHORT_KID: s = "short_kid"; break;
case KEYDB_SEARCH_MODE_LONG_KID: s = "long_kid"; break;
case KEYDB_SEARCH_MODE_FPR16: s = "fpr16"; break;
case KEYDB_SEARCH_MODE_FPR20: s = "fpr20"; break;
case KEYDB_SEARCH_MODE_FPR: s = "fpr"; break;
case KEYDB_SEARCH_MODE_ISSUER: s = "issuer"; break;
case KEYDB_SEARCH_MODE_ISSUER_SN: s = "issuer_sn"; break;
case KEYDB_SEARCH_MODE_SN: s = "sn"; break;
case KEYDB_SEARCH_MODE_SUBJECT: s = "subject"; break;
case KEYDB_SEARCH_MODE_KEYGRIP: s = "keygrip"; break;
case KEYDB_SEARCH_MODE_FIRST: s = "first"; break;
case KEYDB_SEARCH_MODE_NEXT: s = "next"; break;
default: s = "?"; break;
}
if (!n)
log_debug ("%s: mode=%s (hd=%p)", text, s, hd);
gpg: Cache keybox searches. * common/iobuf.c (iobuf_seek): Fix for temp streams. * g10/pubkey-enc.c (get_session_key, get_it): Add some log_clock calls. * g10/keydb.c (dump_search_desc): New. (enum_keyblock_states, struct keyblock_cache): New. (keyblock_cache_clear): New. (keydb_get_keyblock, keydb_search): Implement a keyblock cache. (keydb_update_keyblock, keydb_insert_keyblock, keydb_delete_keyblock) (keydb_rebuild_caches, keydb_search_reset): Clear the cache. -- Gpg uses the key database at several places without a central coordination. This leads to several scans of the keybox for the same key. To improve that we now use a simple cache to store a retrieved keyblock in certain cases. In theory this caching could also be done for old keyrings, but it is a bit more work and questionable whether it is needed; the keybox scheme is anyway much faster than keyrings. Using a keybox with 20000 384 bit ECDSA/ECHD keypairs and a 252 byte sample text we get these values for encrypt and decrypt operations on an Core i5 4*3.33Ghz system. The option --trust-model=always is used. Times are given in milliseconds wall time. | | enc | dec | dec,q | |-----------+-----+-----+-------| | key 1 | 48 | 96 | 70 | | key 10000 | 60 | 98 | 80 | | key 20000 | 69 | 106 | 88 | | 10 keys | 540 | 290 | 70 | The 10 keys test uses a mix of keys, the first one is used for decryption but all keys are looked up so that information about are printed. The last column gives decryption results w/o information printing (--quiet). The keybox is always scanned sequentially without using any index. By adding an index to the keybox it will be possible to further reduce the time required for keys stored to the end of the file.
2013-01-08 14:44:49 +01:00
else
log_debug ("%*s mode=%s", (int)strlen (text), "", s);
if (desc[n].mode == KEYDB_SEARCH_MODE_LONG_KID)
log_printf (" %08lX%08lX", (unsigned long)desc[n].u.kid[0],
(unsigned long)desc[n].u.kid[1]);
else if (desc[n].mode == KEYDB_SEARCH_MODE_SHORT_KID)
log_printf (" %08lX", (unsigned long)desc[n].u.kid[1]);
else if (desc[n].mode == KEYDB_SEARCH_MODE_SUBSTR)
log_printf (" '%s'", desc[n].u.name);
}
}
gpg_error_t
keydb_search (KEYDB_HANDLE hd, KEYDB_SEARCH_DESC *desc,
size_t ndesc, size_t *descindex)
{
gpg_error_t rc;
int was_reset = hd->is_reset;
/* If an entry is already in the cache, then don't add it again. */
int already_in_cache = 0;
if (descindex)
*descindex = 0; /* Make sure it is always set on return. */
if (!hd)
return gpg_error (GPG_ERR_INV_ARG);
if (DBG_CLOCK)
log_clock ("keydb_search enter");
gpg: Cache keybox searches. * common/iobuf.c (iobuf_seek): Fix for temp streams. * g10/pubkey-enc.c (get_session_key, get_it): Add some log_clock calls. * g10/keydb.c (dump_search_desc): New. (enum_keyblock_states, struct keyblock_cache): New. (keyblock_cache_clear): New. (keydb_get_keyblock, keydb_search): Implement a keyblock cache. (keydb_update_keyblock, keydb_insert_keyblock, keydb_delete_keyblock) (keydb_rebuild_caches, keydb_search_reset): Clear the cache. -- Gpg uses the key database at several places without a central coordination. This leads to several scans of the keybox for the same key. To improve that we now use a simple cache to store a retrieved keyblock in certain cases. In theory this caching could also be done for old keyrings, but it is a bit more work and questionable whether it is needed; the keybox scheme is anyway much faster than keyrings. Using a keybox with 20000 384 bit ECDSA/ECHD keypairs and a 252 byte sample text we get these values for encrypt and decrypt operations on an Core i5 4*3.33Ghz system. The option --trust-model=always is used. Times are given in milliseconds wall time. | | enc | dec | dec,q | |-----------+-----+-----+-------| | key 1 | 48 | 96 | 70 | | key 10000 | 60 | 98 | 80 | | key 20000 | 69 | 106 | 88 | | 10 keys | 540 | 290 | 70 | The 10 keys test uses a mix of keys, the first one is used for decryption but all keys are looked up so that information about are printed. The last column gives decryption results w/o information printing (--quiet). The keybox is always scanned sequentially without using any index. By adding an index to the keybox it will be possible to further reduce the time required for keys stored to the end of the file.
2013-01-08 14:44:49 +01:00
if (DBG_CACHE)
dump_search_desc (hd, "keydb_search", desc, ndesc);
gpg: Cache keybox searches. * common/iobuf.c (iobuf_seek): Fix for temp streams. * g10/pubkey-enc.c (get_session_key, get_it): Add some log_clock calls. * g10/keydb.c (dump_search_desc): New. (enum_keyblock_states, struct keyblock_cache): New. (keyblock_cache_clear): New. (keydb_get_keyblock, keydb_search): Implement a keyblock cache. (keydb_update_keyblock, keydb_insert_keyblock, keydb_delete_keyblock) (keydb_rebuild_caches, keydb_search_reset): Clear the cache. -- Gpg uses the key database at several places without a central coordination. This leads to several scans of the keybox for the same key. To improve that we now use a simple cache to store a retrieved keyblock in certain cases. In theory this caching could also be done for old keyrings, but it is a bit more work and questionable whether it is needed; the keybox scheme is anyway much faster than keyrings. Using a keybox with 20000 384 bit ECDSA/ECHD keypairs and a 252 byte sample text we get these values for encrypt and decrypt operations on an Core i5 4*3.33Ghz system. The option --trust-model=always is used. Times are given in milliseconds wall time. | | enc | dec | dec,q | |-----------+-----+-----+-------| | key 1 | 48 | 96 | 70 | | key 10000 | 60 | 98 | 80 | | key 20000 | 69 | 106 | 88 | | 10 keys | 540 | 290 | 70 | The 10 keys test uses a mix of keys, the first one is used for decryption but all keys are looked up so that information about are printed. The last column gives decryption results w/o information printing (--quiet). The keybox is always scanned sequentially without using any index. By adding an index to the keybox it will be possible to further reduce the time required for keys stored to the end of the file.
2013-01-08 14:44:49 +01:00
if (ndesc == 1 && desc[0].mode == KEYDB_SEARCH_MODE_LONG_KID
&& (already_in_cache = kid_not_found_p (desc[0].u.kid)) == 1 )
{
if (DBG_CLOCK)
log_clock ("keydb_search leave (not found, cached)");
return gpg_error (GPG_ERR_NOT_FOUND);
}
/* NB: If one of the exact search modes below is used in a loop to
walk over all keys (with the same fingerprint) the caching must
have been disabled for the handle. */
if (!hd->no_caching
&& ndesc == 1
&& (desc[0].mode == KEYDB_SEARCH_MODE_FPR20
|| desc[0].mode == KEYDB_SEARCH_MODE_FPR)
&& hd->keyblock_cache.state == KEYBLOCK_CACHE_FILLED
&& !memcmp (hd->keyblock_cache.fpr, desc[0].u.fpr, 20))
gpg: Cache keybox searches. * common/iobuf.c (iobuf_seek): Fix for temp streams. * g10/pubkey-enc.c (get_session_key, get_it): Add some log_clock calls. * g10/keydb.c (dump_search_desc): New. (enum_keyblock_states, struct keyblock_cache): New. (keyblock_cache_clear): New. (keydb_get_keyblock, keydb_search): Implement a keyblock cache. (keydb_update_keyblock, keydb_insert_keyblock, keydb_delete_keyblock) (keydb_rebuild_caches, keydb_search_reset): Clear the cache. -- Gpg uses the key database at several places without a central coordination. This leads to several scans of the keybox for the same key. To improve that we now use a simple cache to store a retrieved keyblock in certain cases. In theory this caching could also be done for old keyrings, but it is a bit more work and questionable whether it is needed; the keybox scheme is anyway much faster than keyrings. Using a keybox with 20000 384 bit ECDSA/ECHD keypairs and a 252 byte sample text we get these values for encrypt and decrypt operations on an Core i5 4*3.33Ghz system. The option --trust-model=always is used. Times are given in milliseconds wall time. | | enc | dec | dec,q | |-----------+-----+-----+-------| | key 1 | 48 | 96 | 70 | | key 10000 | 60 | 98 | 80 | | key 20000 | 69 | 106 | 88 | | 10 keys | 540 | 290 | 70 | The 10 keys test uses a mix of keys, the first one is used for decryption but all keys are looked up so that information about are printed. The last column gives decryption results w/o information printing (--quiet). The keybox is always scanned sequentially without using any index. By adding an index to the keybox it will be possible to further reduce the time required for keys stored to the end of the file.
2013-01-08 14:44:49 +01:00
{
/* (DESCINDEX is already set). */
gpg: Cache keybox searches. * common/iobuf.c (iobuf_seek): Fix for temp streams. * g10/pubkey-enc.c (get_session_key, get_it): Add some log_clock calls. * g10/keydb.c (dump_search_desc): New. (enum_keyblock_states, struct keyblock_cache): New. (keyblock_cache_clear): New. (keydb_get_keyblock, keydb_search): Implement a keyblock cache. (keydb_update_keyblock, keydb_insert_keyblock, keydb_delete_keyblock) (keydb_rebuild_caches, keydb_search_reset): Clear the cache. -- Gpg uses the key database at several places without a central coordination. This leads to several scans of the keybox for the same key. To improve that we now use a simple cache to store a retrieved keyblock in certain cases. In theory this caching could also be done for old keyrings, but it is a bit more work and questionable whether it is needed; the keybox scheme is anyway much faster than keyrings. Using a keybox with 20000 384 bit ECDSA/ECHD keypairs and a 252 byte sample text we get these values for encrypt and decrypt operations on an Core i5 4*3.33Ghz system. The option --trust-model=always is used. Times are given in milliseconds wall time. | | enc | dec | dec,q | |-----------+-----+-----+-------| | key 1 | 48 | 96 | 70 | | key 10000 | 60 | 98 | 80 | | key 20000 | 69 | 106 | 88 | | 10 keys | 540 | 290 | 70 | The 10 keys test uses a mix of keys, the first one is used for decryption but all keys are looked up so that information about are printed. The last column gives decryption results w/o information printing (--quiet). The keybox is always scanned sequentially without using any index. By adding an index to the keybox it will be possible to further reduce the time required for keys stored to the end of the file.
2013-01-08 14:44:49 +01:00
if (DBG_CLOCK)
log_clock ("keydb_search leave (cached)");
return 0;
}
rc = -1;
while ((rc == -1 || gpg_err_code (rc) == GPG_ERR_EOF)
&& hd->current >= 0 && hd->current < hd->used)
{
switch (hd->active[hd->current].type)
{
case KEYDB_RESOURCE_TYPE_NONE:
BUG(); /* we should never see it here */
break;
case KEYDB_RESOURCE_TYPE_KEYRING:
rc = keyring_search (hd->active[hd->current].u.kr, desc,
ndesc, descindex);
break;
case KEYDB_RESOURCE_TYPE_KEYBOX:
rc = keybox_search (hd->active[hd->current].u.kb, desc,
ndesc, KEYBOX_BLOBTYPE_PGP,
descindex, &hd->skipped_long_blobs);
break;
}
if (rc == -1 || gpg_err_code (rc) == GPG_ERR_EOF)
{
/* EOF -> switch to next resource */
hd->current++;
}
else if (!rc)
hd->found = hd->current;
}
hd->is_reset = 0;
gpg: Cache keybox searches. * common/iobuf.c (iobuf_seek): Fix for temp streams. * g10/pubkey-enc.c (get_session_key, get_it): Add some log_clock calls. * g10/keydb.c (dump_search_desc): New. (enum_keyblock_states, struct keyblock_cache): New. (keyblock_cache_clear): New. (keydb_get_keyblock, keydb_search): Implement a keyblock cache. (keydb_update_keyblock, keydb_insert_keyblock, keydb_delete_keyblock) (keydb_rebuild_caches, keydb_search_reset): Clear the cache. -- Gpg uses the key database at several places without a central coordination. This leads to several scans of the keybox for the same key. To improve that we now use a simple cache to store a retrieved keyblock in certain cases. In theory this caching could also be done for old keyrings, but it is a bit more work and questionable whether it is needed; the keybox scheme is anyway much faster than keyrings. Using a keybox with 20000 384 bit ECDSA/ECHD keypairs and a 252 byte sample text we get these values for encrypt and decrypt operations on an Core i5 4*3.33Ghz system. The option --trust-model=always is used. Times are given in milliseconds wall time. | | enc | dec | dec,q | |-----------+-----+-----+-------| | key 1 | 48 | 96 | 70 | | key 10000 | 60 | 98 | 80 | | key 20000 | 69 | 106 | 88 | | 10 keys | 540 | 290 | 70 | The 10 keys test uses a mix of keys, the first one is used for decryption but all keys are looked up so that information about are printed. The last column gives decryption results w/o information printing (--quiet). The keybox is always scanned sequentially without using any index. By adding an index to the keybox it will be possible to further reduce the time required for keys stored to the end of the file.
2013-01-08 14:44:49 +01:00
rc = ((rc == -1 || gpg_err_code (rc) == GPG_ERR_EOF)
? gpg_error (GPG_ERR_NOT_FOUND)
: rc);
keyblock_cache_clear (hd);
if (!hd->no_caching
&& !rc
&& ndesc == 1 && (desc[0].mode == KEYDB_SEARCH_MODE_FPR20
|| desc[0].mode == KEYDB_SEARCH_MODE_FPR))
gpg: Cache keybox searches. * common/iobuf.c (iobuf_seek): Fix for temp streams. * g10/pubkey-enc.c (get_session_key, get_it): Add some log_clock calls. * g10/keydb.c (dump_search_desc): New. (enum_keyblock_states, struct keyblock_cache): New. (keyblock_cache_clear): New. (keydb_get_keyblock, keydb_search): Implement a keyblock cache. (keydb_update_keyblock, keydb_insert_keyblock, keydb_delete_keyblock) (keydb_rebuild_caches, keydb_search_reset): Clear the cache. -- Gpg uses the key database at several places without a central coordination. This leads to several scans of the keybox for the same key. To improve that we now use a simple cache to store a retrieved keyblock in certain cases. In theory this caching could also be done for old keyrings, but it is a bit more work and questionable whether it is needed; the keybox scheme is anyway much faster than keyrings. Using a keybox with 20000 384 bit ECDSA/ECHD keypairs and a 252 byte sample text we get these values for encrypt and decrypt operations on an Core i5 4*3.33Ghz system. The option --trust-model=always is used. Times are given in milliseconds wall time. | | enc | dec | dec,q | |-----------+-----+-----+-------| | key 1 | 48 | 96 | 70 | | key 10000 | 60 | 98 | 80 | | key 20000 | 69 | 106 | 88 | | 10 keys | 540 | 290 | 70 | The 10 keys test uses a mix of keys, the first one is used for decryption but all keys are looked up so that information about are printed. The last column gives decryption results w/o information printing (--quiet). The keybox is always scanned sequentially without using any index. By adding an index to the keybox it will be possible to further reduce the time required for keys stored to the end of the file.
2013-01-08 14:44:49 +01:00
{
hd->keyblock_cache.state = KEYBLOCK_CACHE_PREPARED;
memcpy (hd->keyblock_cache.fpr, desc[0].u.fpr, 20);
gpg: Cache keybox searches. * common/iobuf.c (iobuf_seek): Fix for temp streams. * g10/pubkey-enc.c (get_session_key, get_it): Add some log_clock calls. * g10/keydb.c (dump_search_desc): New. (enum_keyblock_states, struct keyblock_cache): New. (keyblock_cache_clear): New. (keydb_get_keyblock, keydb_search): Implement a keyblock cache. (keydb_update_keyblock, keydb_insert_keyblock, keydb_delete_keyblock) (keydb_rebuild_caches, keydb_search_reset): Clear the cache. -- Gpg uses the key database at several places without a central coordination. This leads to several scans of the keybox for the same key. To improve that we now use a simple cache to store a retrieved keyblock in certain cases. In theory this caching could also be done for old keyrings, but it is a bit more work and questionable whether it is needed; the keybox scheme is anyway much faster than keyrings. Using a keybox with 20000 384 bit ECDSA/ECHD keypairs and a 252 byte sample text we get these values for encrypt and decrypt operations on an Core i5 4*3.33Ghz system. The option --trust-model=always is used. Times are given in milliseconds wall time. | | enc | dec | dec,q | |-----------+-----+-----+-------| | key 1 | 48 | 96 | 70 | | key 10000 | 60 | 98 | 80 | | key 20000 | 69 | 106 | 88 | | 10 keys | 540 | 290 | 70 | The 10 keys test uses a mix of keys, the first one is used for decryption but all keys are looked up so that information about are printed. The last column gives decryption results w/o information printing (--quiet). The keybox is always scanned sequentially without using any index. By adding an index to the keybox it will be possible to further reduce the time required for keys stored to the end of the file.
2013-01-08 14:44:49 +01:00
}
if (gpg_err_code (rc) == GPG_ERR_NOT_FOUND
&& ndesc == 1 && desc[0].mode == KEYDB_SEARCH_MODE_LONG_KID && was_reset
&& !already_in_cache)
kid_not_found_insert (desc[0].u.kid);
if (DBG_CLOCK)
gpg: Cache keybox searches. * common/iobuf.c (iobuf_seek): Fix for temp streams. * g10/pubkey-enc.c (get_session_key, get_it): Add some log_clock calls. * g10/keydb.c (dump_search_desc): New. (enum_keyblock_states, struct keyblock_cache): New. (keyblock_cache_clear): New. (keydb_get_keyblock, keydb_search): Implement a keyblock cache. (keydb_update_keyblock, keydb_insert_keyblock, keydb_delete_keyblock) (keydb_rebuild_caches, keydb_search_reset): Clear the cache. -- Gpg uses the key database at several places without a central coordination. This leads to several scans of the keybox for the same key. To improve that we now use a simple cache to store a retrieved keyblock in certain cases. In theory this caching could also be done for old keyrings, but it is a bit more work and questionable whether it is needed; the keybox scheme is anyway much faster than keyrings. Using a keybox with 20000 384 bit ECDSA/ECHD keypairs and a 252 byte sample text we get these values for encrypt and decrypt operations on an Core i5 4*3.33Ghz system. The option --trust-model=always is used. Times are given in milliseconds wall time. | | enc | dec | dec,q | |-----------+-----+-----+-------| | key 1 | 48 | 96 | 70 | | key 10000 | 60 | 98 | 80 | | key 20000 | 69 | 106 | 88 | | 10 keys | 540 | 290 | 70 | The 10 keys test uses a mix of keys, the first one is used for decryption but all keys are looked up so that information about are printed. The last column gives decryption results w/o information printing (--quiet). The keybox is always scanned sequentially without using any index. By adding an index to the keybox it will be possible to further reduce the time required for keys stored to the end of the file.
2013-01-08 14:44:49 +01:00
log_clock (rc? "keydb_search leave (not found)"
: "keydb_search leave (found)");
return rc;
}
gpg_error_t
keydb_search_first (KEYDB_HANDLE hd)
{
gpg_error_t err;
KEYDB_SEARCH_DESC desc;
err = keydb_search_reset (hd);
if (err)
return err;
memset (&desc, 0, sizeof desc);
desc.mode = KEYDB_SEARCH_MODE_FIRST;
err = keydb_search (hd, &desc, 1, NULL);
if (gpg_err_code (err) == GPG_ERR_LEGACY_KEY)
err = keydb_search_next (hd);
return err;
}
gpg_error_t
keydb_search_next (KEYDB_HANDLE hd)
{
gpg_error_t err;
KEYDB_SEARCH_DESC desc;
do
{
memset (&desc, 0, sizeof desc);
desc.mode = KEYDB_SEARCH_MODE_NEXT;
err = keydb_search (hd, &desc, 1, NULL);
}
while (gpg_err_code (err) == GPG_ERR_LEGACY_KEY);
return err;
}
gpg_error_t
keydb_search_kid (KEYDB_HANDLE hd, u32 *kid)
{
KEYDB_SEARCH_DESC desc;
memset (&desc, 0, sizeof desc);
desc.mode = KEYDB_SEARCH_MODE_LONG_KID;
desc.u.kid[0] = kid[0];
desc.u.kid[1] = kid[1];
return keydb_search (hd, &desc, 1, NULL);
}
gpg_error_t
keydb_search_fpr (KEYDB_HANDLE hd, const byte *fpr)
{
gpg_error_t err;
KEYDB_SEARCH_DESC desc;
memset (&desc, 0, sizeof desc);
desc.mode = KEYDB_SEARCH_MODE_FPR;
memcpy (desc.u.fpr, fpr, MAX_FINGERPRINT_LEN);
do
{
err = keydb_search (hd, &desc, 1, NULL);
}
while (gpg_err_code (err) == GPG_ERR_LEGACY_KEY);
return err;
}