Commit b41592ec authored by Rich Prohaska's avatar Rich Prohaska Committed by Yoni Fogel

merge tokudb revision 7776-7883 to toudb.1032b. closes #1260

git-svn-id: file:///svn/toku/tokudb.1032b@7888 c7de825b-a66e-492c-adef-691d508d4ae1
parent 05384e8c
......@@ -2,7 +2,7 @@
#include <assert.h>
#include <db_cxx.h>
static void hexdump(Dbt *d) {
static inline void hexdump(Dbt *d) {
unsigned char *cp = (unsigned char *) d->get_data();
int n = d->get_size();
printf(" ");
......
......@@ -11,10 +11,9 @@
#include "list.h"
#include "mempool.h"
#include "kv-pair.h"
#include "leafentry.h"
typedef void *OMTVALUE;
#include "omt.h"
#include "leafentry.h"
#ifndef BRT_FANOUT
#define BRT_FANOUT 16
......@@ -263,7 +262,13 @@ int toku_cmd_leafval_heaviside (OMTVALUE leafentry, void *extra);
int toku_brt_root_put_cmd(BRT brt, BRT_CMD cmd, TOKULOGGER logger);
int toku_cachefile_root_put_cmd (CACHEFILE cf, BRT_CMD cmd, TOKULOGGER logger);
void *mempool_malloc_from_omt(OMT omt, struct mempool *mp, size_t size);
void *mempool_malloc_from_omt(OMT omt, struct mempool *mp, size_t size, void **maybe_free);
// Effect: Allocate a new object of size SIZE in MP. If MP runs out of space, allocate new a new mempool space, and copy all the items
// from the OMT (which items refer to items in the old mempool) into the new mempool.
// If MAYBE_FREE is NULL then free the old mempool's space.
// Otherwise, store the old mempool's space in maybe_free.
void mempool_release(struct mempool *); // release anything that was not released when the ..._norelease function was called.
void toku_verify_all_in_mempool(BRTNODE node);
......@@ -281,6 +286,7 @@ enum brt_layout_version_e {
void toku_brtheader_free (struct brt_header *h);
int toku_brtheader_close (CACHEFILE cachefile, void *header_v);
int toku_brtheader_checkpoint (CACHEFILE cachefile, void *header_v);
#define BLOCK_ALLOCATOR_ALIGNMENT 4096
// How much must be reserved at the beginning for the block?
......
This diff is collapsed.
......@@ -271,7 +271,7 @@ void toku_serialize_brtnode_to (int fd, BLOCKNUM blocknum, BRTNODE node, struct
printf("%s:%d w.done=%u calculated_size=%u\n", __FILE__, __LINE__, w.ndone, calculated_size);
assert(calculated_size==w.ndone);
// The uncompressed part of the header is
// The uncompressed part of the block header is
// tokuleaf(8),
// version(4),
// lsn(8),
......
......@@ -71,12 +71,8 @@ int toku_testsetup_insert_to_leaf (BRT brt, BLOCKNUM blocknum, char *key, int ke
assert(node->height==0);
u_int32_t lesize, disksize;
LEAFENTRY tmp_leafentry;
r = le_committed(keylen, key, vallen, val, &lesize, &disksize, &tmp_leafentry);
LEAFENTRY leafentry = mempool_malloc_from_omt(node->u.l.buffer, &node->u.l.buffer_mempool, lesize);
memcpy(leafentry, tmp_leafentry, lesize);
toku_free(tmp_leafentry);
LEAFENTRY leafentry;
r = le_committed(keylen, key, vallen, val, &lesize, &disksize, &leafentry, node->u.l.buffer, &node->u.l.buffer_mempool, 0);
OMTVALUE storeddatav;
u_int32_t idx;
......
This diff is collapsed.
......@@ -125,6 +125,7 @@ struct cachefile {
void *userdata;
int (*close_userdata)(CACHEFILE cf, void *userdata); // when closing the last reference to a cachefile, first call this function.
int (*checkpoint_userdata)(CACHEFILE cf, void *userdata); // when checkpointing a cachefile, call this function.
};
int toku_create_cachetable(CACHETABLE *result, long size_limit, LSN initial_lsn, TOKULOGGER logger) {
......@@ -229,6 +230,7 @@ int toku_cachetable_openfd (CACHEFILE *cf, CACHETABLE t, int fd, const char *fna
newcf->userdata = 0;
newcf->close_userdata = 0;
newcf->checkpoint_userdata = 0;
*cf = newcf;
return 0;
......@@ -252,6 +254,7 @@ int toku_cachefile_set_fd (CACHEFILE cf, int fd, const char *fname) {
return r;
}
cf->close_userdata = NULL;
cf->checkpoint_userdata = NULL;
cf->userdata = NULL;
close(cf->fd);
......@@ -313,6 +316,7 @@ int toku_cachefile_close (CACHEFILE *cfp, TOKULOGGER logger) {
return r;
}
cf->close_userdata = NULL;
cf->checkpoint_userdata = NULL;
cf->userdata = NULL;
cf->cachetable->cachefiles = remove_cf_from_list(cf, cf->cachetable->cachefiles);
cachetable_unlock(ct);
......@@ -1081,6 +1085,16 @@ int toku_cachetable_checkpoint (CACHETABLE ct) {
cachetable_complete_write_pair(ct, p, FALSE);
}
{
CACHEFILE cf;
for (cf = ct->cachefiles; cf; cf=cf->next) {
if (cf->checkpoint_userdata) {
int r = cf->checkpoint_userdata(cf, cf->userdata);
assert(r==0);
}
}
}
ct->checkpointing = 0; // clear the checkpoint in progress flag
}
......@@ -1219,9 +1233,15 @@ int toku_cachetable_get_key_state (CACHETABLE ct, CACHEKEY key, CACHEFILE cf, vo
return r;
}
void toku_cachefile_set_userdata (CACHEFILE cf, void *userdata, int (*close_userdata)(CACHEFILE, void*)) {
void
toku_cachefile_set_userdata (CACHEFILE cf,
void *userdata,
int (*close_userdata)(CACHEFILE, void*),
int (*checkpoint_userdata)(CACHEFILE, void*))
{
cf->userdata = userdata;
cf->close_userdata = close_userdata;
cf->checkpoint_userdata = checkpoint_userdata;
}
void *toku_cachefile_get_userdata(CACHEFILE cf) {
......
......@@ -61,8 +61,9 @@ typedef void (*CACHETABLE_FLUSH_CALLBACK)(CACHEFILE, CACHEKEY key, void *value,
// associated with the key are returned.
typedef int (*CACHETABLE_FETCH_CALLBACK)(CACHEFILE, CACHEKEY key, u_int32_t fullhash, void **value, long *sizep, void *extraargs, LSN *written_lsn);
void toku_cachefile_set_userdata(CACHEFILE cf, void *userdata, int (*close_userdata)(CACHEFILE, void*));
// Effect: Store some cachefile-specific user data. When the last reference to a cachefile is closed, we call close_userdata.
void toku_cachefile_set_userdata(CACHEFILE cf, void *userdata, int (*close_userdata)(CACHEFILE, void*), int (*checkpoint_userdata)(CACHEFILE, void*));
// Effect: Store some cachefile-specific user data. When the last reference to a cachefile is closed, we call close_userdata().
// When the cachefile needs to be checkpointed, we call checkpoint_userdata().
// If userdata is already non-NULL, then we simply overwrite it.
void *toku_cachefile_get_userdata(CACHEFILE);
// Effect: Get the user dataa.
......
......@@ -6,9 +6,20 @@ u_int32_t toku_le_crc(LEAFENTRY v) {
return x1764_memory(v, leafentry_memsize(v));
}
int le_committed (u_int32_t klen, void* kval, u_int32_t dlen, void* dval, u_int32_t *resultsize, u_int32_t *disksize, LEAFENTRY *result) {
static void *
le_malloc(OMT omt, struct mempool *mp, size_t size, void **maybe_free)
{
if (omt)
return mempool_malloc_from_omt(omt, mp, size, maybe_free);
else
return toku_malloc(size);
}
int
le_committed (u_int32_t klen, void* kval, u_int32_t dlen, void* dval, u_int32_t *resultsize, u_int32_t *disksize, LEAFENTRY *result,
OMT omt, struct mempool *mp, void **maybe_free) {
size_t size = 9+klen+dlen;
unsigned char *lec=toku_malloc(size);
unsigned char *lec=le_malloc(omt, mp, size, maybe_free);
assert(lec);
lec[0] = LE_COMMITTED;
putint(lec+1, klen);
......@@ -20,10 +31,12 @@ int le_committed (u_int32_t klen, void* kval, u_int32_t dlen, void* dval, u_int3
*result=(LEAFENTRY)lec;
return 0;
}
int le_both (TXNID xid, u_int32_t klen, void* kval, u_int32_t clen, void* cval, u_int32_t plen, void* pval,
u_int32_t *resultsize, u_int32_t *disksize, LEAFENTRY *result) {
u_int32_t *resultsize, u_int32_t *disksize, LEAFENTRY *result,
OMT omt, struct mempool *mp, void **maybe_free) {
size_t size = 1+8+4*3+klen+clen+plen;
unsigned char *lec=toku_malloc(size);
unsigned char *lec=le_malloc(omt, mp, size, maybe_free);
assert(lec);
lec[0] = LE_BOTH;
putint64(lec+1, xid);
......@@ -39,10 +52,13 @@ int le_both (TXNID xid, u_int32_t klen, void* kval, u_int32_t clen, void* cval,
return 0;
}
int le_provdel (TXNID xid, u_int32_t klen, void* kval, u_int32_t dlen, void* dval,
u_int32_t *memsize, u_int32_t *disksize, LEAFENTRY *result) {
int
le_provdel (TXNID xid, u_int32_t klen, void* kval, u_int32_t dlen, void* dval,
u_int32_t *memsize, u_int32_t *disksize, LEAFENTRY *result,
OMT omt, struct mempool *mp, void **maybe_free) {
size_t size = 1 + 8 + 2*4 + klen + dlen;
unsigned char *lec=toku_malloc(size);
unsigned char *lec= le_malloc(omt, mp, size, maybe_free);
assert(lec);
lec[0] = LE_PROVDEL;
putint64(lec+1, xid);
......@@ -55,9 +71,12 @@ int le_provdel (TXNID xid, u_int32_t klen, void* kval, u_int32_t dlen, void* dv
*result=(LEAFENTRY)lec;
return 0;
}
int le_provpair (TXNID xid, u_int32_t klen, void* kval, u_int32_t plen, void* pval, u_int32_t *memsize, u_int32_t *disksize, LEAFENTRY *result) {
int
le_provpair (TXNID xid, u_int32_t klen, void* kval, u_int32_t plen, void* pval, u_int32_t *memsize, u_int32_t *disksize, LEAFENTRY *result,
OMT omt, struct mempool *mp, void **maybe_free) {
size_t size = 1 + 8 + 2*4 + klen + plen;
unsigned char *lec=toku_malloc(size);
unsigned char *lec= le_malloc(omt, mp, size, maybe_free);
assert(lec);
lec[0] = LE_PROVPAIR;
putint64(lec+1, xid);
......@@ -154,7 +173,8 @@ int toku_fread_LEAFENTRY(FILE *f, LEAFENTRY *le, struct x1764 *checksum, u_int32
r = toku_fread_BYTESTRING(f, &a, checksum, len); if (r!=0) return r;
r = toku_fread_BYTESTRING(f, &b, checksum, len); if (r!=0) return r;
r = le_committed(a.len, a.data, b.len, b.data,
&memsize, &disksize, le);
&memsize, &disksize, le,
0, 0, 0);
toku_free_BYTESTRING(a);
toku_free_BYTESTRING(b);
return r;
......@@ -164,7 +184,8 @@ int toku_fread_LEAFENTRY(FILE *f, LEAFENTRY *le, struct x1764 *checksum, u_int32
r = toku_fread_BYTESTRING(f, &b, checksum, len); if (r!=0) return r;
r = toku_fread_BYTESTRING(f, &c, checksum, len); if (r!=0) return r;
r = le_both(xid, a.len, a.data, b.len, b.data, c.len, c.data,
&memsize, &disksize, le);
&memsize, &disksize, le,
0, 0, 0);
toku_free_BYTESTRING(a);
toku_free_BYTESTRING(b);
toku_free_BYTESTRING(c);
......@@ -174,7 +195,8 @@ int toku_fread_LEAFENTRY(FILE *f, LEAFENTRY *le, struct x1764 *checksum, u_int32
r = toku_fread_BYTESTRING(f, &a, checksum, len); if (r!=0) return r;
r = toku_fread_BYTESTRING(f, &b, checksum, len); if (r!=0) return r;
r = le_provdel(xid, a.len, a.data, b.len, b.data,
&memsize, &disksize, le);
&memsize, &disksize, le,
0, 0, 0);
toku_free_BYTESTRING(a);
toku_free_BYTESTRING(b);
return r;
......@@ -183,7 +205,8 @@ int toku_fread_LEAFENTRY(FILE *f, LEAFENTRY *le, struct x1764 *checksum, u_int32
r = toku_fread_BYTESTRING(f, &a, checksum, len); if (r!=0) return r;
r = toku_fread_BYTESTRING(f, &b, checksum, len); if (r!=0) return r;
r = le_provpair(xid, a.len, a.data, b.len, b.data,
&memsize, &disksize, le);
&memsize, &disksize, le,
0, 0, 0);
toku_free_BYTESTRING(a);
toku_free_BYTESTRING(b);
return r;
......
......@@ -33,13 +33,16 @@
u_int32_t toku_le_crc(LEAFENTRY v);
int le_committed (u_int32_t klen, void* kval, u_int32_t dlen, void* dval, u_int32_t *resultsize, u_int32_t *disksize, LEAFENTRY *result);
int le_committed (u_int32_t klen, void* kval, u_int32_t dlen, void* dval, u_int32_t *resultsize, u_int32_t *disksize, LEAFENTRY *result,
OMT, struct mempool *, void **maybe_free);
int le_both (TXNID xid, u_int32_t cklen, void* ckval, u_int32_t cdlen, void* cdval, u_int32_t pdlen, void* pdval,
u_int32_t *memsize, u_int32_t *disksize, LEAFENTRY *result);
u_int32_t *memsize, u_int32_t *disksize, LEAFENTRY *result,
OMT, struct mempool *, void **maybe_free);
int le_provdel (TXNID xid, u_int32_t klen, void* kval, u_int32_t dlen, void* dval,
u_int32_t *resultsize, u_int32_t *memsize, LEAFENTRY *result);
int le_provpair (TXNID xid, u_int32_t klen, void* kval, u_int32_t dlen, void* dval,
u_int32_t *memsize, u_int32_t *disksize, LEAFENTRY *result);
u_int32_t *resultsize, u_int32_t *memsize, LEAFENTRY *result,
OMT, struct mempool *, void **maybe_free);
int le_provpair (TXNID xid, u_int32_t klen, void* kval, u_int32_t plen, void* pval, u_int32_t *memsize, u_int32_t *disksize, LEAFENTRY *result,
OMT omt, struct mempool *mp, void **maybe_free);
enum le_state { LE_COMMITTED=1, // A committed pair.
LE_BOTH, // A committed pair and a provisional pair.
......
......@@ -158,7 +158,7 @@ static void toku_recover_fheader (LSN UU(lsn), TXNID UU(txnid),FILENUM filenum,L
pair->brt->h = h;
pair->brt->nodesize = h->nodesize;
pair->brt->flags = h->nodesize;
toku_cachefile_set_userdata(pair->cf, pair->brt->h, toku_brtheader_close);
toku_cachefile_set_userdata(pair->cf, pair->brt->h, toku_brtheader_close, toku_brtheader_checkpoint);
}
static void
......@@ -613,7 +613,7 @@ toku_recover_insertleafentry (LSN lsn, FILENUM filenum, BLOCKNUM blocknum, u_int
node->log_lsn = lsn;
{
int memsize = leafentry_memsize(newleafentry);
void *mem = mempool_malloc_from_omt(node->u.l.buffer, &node->u.l.buffer_mempool, memsize);
void *mem = mempool_malloc_from_omt(node->u.l.buffer, &node->u.l.buffer_mempool, memsize, 0);
assert(mem);
memcpy(mem, newleafentry, memsize);
r = toku_omt_insert_at(node->u.l.buffer, mem, idx);
......
#include "portability.h"
#include <string.h>
#include "brttypes.h"
#include "leafentry.h"
#include "includes.h"
static void test_leafentry_1 (void) {
LEAFENTRY l;
int r;
u_int32_t msize, dsize;
r = le_committed(4, "abc", 3, "xy", &msize, &dsize, &l);
r = le_committed(4, "abc", 3, "xy", &msize, &dsize, &l, 0, 0, 0);
assert(r==0);
char expect[] = {LE_COMMITTED,
0, 0, 0, 4,
......@@ -24,7 +24,7 @@ static void test_leafentry_2 (void) {
LEAFENTRY l;
int r;
u_int32_t msize, dsize;
r = le_both(0x0123456789abcdef0LL, 3, "ab", 4, "xyz", 5, "lmno", &msize, &dsize, &l);
r = le_both(0x0123456789abcdef0LL, 3, "ab", 4, "xyz", 5, "lmno", &msize, &dsize, &l, 0, 0, 0);
assert(r==0);
char expect[] = {LE_BOTH,
0x12, 0x34, 0x56, 0x78, 0x9a, 0xbc, 0xde, 0xf0,
......@@ -41,7 +41,7 @@ static void test_leafentry_3 (void) {
LEAFENTRY l;
int r;
u_int32_t msize, dsize;
r = le_provdel(0x0123456789abcdef0LL, 3, "ab", 5, "lmno", &msize, &dsize, &l);
r = le_provdel(0x0123456789abcdef0LL, 3, "ab", 5, "lmno", &msize, &dsize, &l, 0, 0, 0);
assert(r==0);
char expect[] = {LE_PROVDEL,
0x12, 0x34, 0x56, 0x78, 0x9a, 0xbc, 0xde, 0xf0,
......@@ -57,7 +57,7 @@ static void test_leafentry_4 (void) {
LEAFENTRY l;
int r;
u_int32_t msize, dsize;
r = le_provpair(0x0123456789abcdef0LL, 3, "ab", 5, "lmno", &msize, &dsize, &l);
r = le_provpair(0x0123456789abcdef0LL, 3, "ab", 5, "lmno", &msize, &dsize, &l, 0, 0, 0);
assert(r==0);
char expect[] = {LE_PROVPAIR,
0x12, 0x34, 0x56, 0x78, 0x9a, 0xbc, 0xde, 0xf0,
......@@ -89,7 +89,7 @@ static void test_leafentry_3long (void) {
LEAFENTRY l;
int r;
u_int32_t msize, dsize;
r = le_provdel(0x0123456789abcdef0LL, 301, zeros, 1025, zeros, &msize, &dsize, &l);
r = le_provdel(0x0123456789abcdef0LL, 301, zeros, 1025, zeros, &msize, &dsize, &l, 0, 0, 0);
assert(r==0);
assert(sizeof(expect_3long)==msize);
assert(msize==dsize);
......
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