c81c11f62c
FossilOrigin-Name: f6c045f649036958078cb15cd9d5453680c82b0c
459 lines
13 KiB
C
459 lines
13 KiB
C
/*
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** 2008 November 18
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**
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** The author disclaims copyright to this source code. In place of
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** a legal notice, here is a blessing:
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**
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** May you do good and not evil.
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** May you find forgiveness for yourself and forgive others.
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** May you share freely, never taking more than you give.
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**
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*************************************************************************
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**
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** This file contains code used for testing the SQLite system.
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** None of the code in this file goes into a deliverable build.
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**
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** This file contains an application-defined pager cache
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** implementation that can be plugged in in place of the
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** default pcache. This alternative pager cache will throw
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** some errors that the default cache does not.
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**
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** This pagecache implementation is designed for simplicity
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** not speed.
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*/
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#include "sqlite3.h"
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#include <string.h>
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#include <assert.h>
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/*
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** Global data used by this test implementation. There is no
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** mutexing, which means this page cache will not work in a
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** multi-threaded test.
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*/
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typedef struct testpcacheGlobalType testpcacheGlobalType;
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struct testpcacheGlobalType {
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void *pDummy; /* Dummy allocation to simulate failures */
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int nInstance; /* Number of current instances */
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unsigned discardChance; /* Chance of discarding on an unpin (0-100) */
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unsigned prngSeed; /* Seed for the PRNG */
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unsigned highStress; /* Call xStress agressively */
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};
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static testpcacheGlobalType testpcacheGlobal;
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/*
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** Initializer.
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**
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** Verify that the initializer is only called when the system is
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** uninitialized. Allocate some memory and report SQLITE_NOMEM if
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** the allocation fails. This provides a means to test the recovery
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** from a failed initialization attempt. It also verifies that the
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** the destructor always gets call - otherwise there would be a
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** memory leak.
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*/
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static int testpcacheInit(void *pArg){
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assert( pArg==(void*)&testpcacheGlobal );
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assert( testpcacheGlobal.pDummy==0 );
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assert( testpcacheGlobal.nInstance==0 );
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testpcacheGlobal.pDummy = sqlite3_malloc(10);
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return testpcacheGlobal.pDummy==0 ? SQLITE_NOMEM : SQLITE_OK;
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}
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/*
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** Destructor
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**
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** Verify that this is only called after initialization.
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** Free the memory allocated by the initializer.
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*/
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static void testpcacheShutdown(void *pArg){
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assert( pArg==(void*)&testpcacheGlobal );
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assert( testpcacheGlobal.pDummy!=0 );
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assert( testpcacheGlobal.nInstance==0 );
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sqlite3_free( testpcacheGlobal.pDummy );
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testpcacheGlobal.pDummy = 0;
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}
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/*
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** Number of pages in a cache.
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**
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** The number of pages is a hard upper bound in this test module.
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** If more pages are requested, sqlite3PcacheFetch() returns NULL.
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**
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** If testing with in-memory temp tables, provide a larger pcache.
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** Some of the test cases need this.
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*/
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#if defined(SQLITE_TEMP_STORE) && SQLITE_TEMP_STORE>=2
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# define TESTPCACHE_NPAGE 499
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#else
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# define TESTPCACHE_NPAGE 217
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#endif
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#define TESTPCACHE_RESERVE 17
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/*
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** Magic numbers used to determine validity of the page cache.
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*/
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#define TESTPCACHE_VALID 0x364585fd
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#define TESTPCACHE_CLEAR 0xd42670d4
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/*
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** Private implementation of a page cache.
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*/
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typedef struct testpcache testpcache;
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struct testpcache {
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int szPage; /* Size of each page. Multiple of 8. */
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int bPurgeable; /* True if the page cache is purgeable */
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int nFree; /* Number of unused slots in a[] */
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int nPinned; /* Number of pinned slots in a[] */
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unsigned iRand; /* State of the PRNG */
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unsigned iMagic; /* Magic number for sanity checking */
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struct testpcachePage {
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unsigned key; /* The key for this page. 0 means unallocated */
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int isPinned; /* True if the page is pinned */
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void *pData; /* Data for this page */
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} a[TESTPCACHE_NPAGE]; /* All pages in the cache */
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};
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/*
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** Get a random number using the PRNG in the given page cache.
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*/
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static unsigned testpcacheRandom(testpcache *p){
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unsigned x = 0;
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int i;
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for(i=0; i<4; i++){
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p->iRand = (p->iRand*69069 + 5);
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x = (x<<8) | ((p->iRand>>16)&0xff);
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}
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return x;
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}
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/*
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** Allocate a new page cache instance.
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*/
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static sqlite3_pcache *testpcacheCreate(int szPage, int bPurgeable){
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int nMem;
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char *x;
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testpcache *p;
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int i;
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assert( testpcacheGlobal.pDummy!=0 );
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szPage = (szPage+7)&~7;
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nMem = sizeof(testpcache) + TESTPCACHE_NPAGE*szPage;
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p = sqlite3_malloc( nMem );
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if( p==0 ) return 0;
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x = (char*)&p[1];
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p->szPage = szPage;
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p->nFree = TESTPCACHE_NPAGE;
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p->nPinned = 0;
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p->iRand = testpcacheGlobal.prngSeed;
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p->bPurgeable = bPurgeable;
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p->iMagic = TESTPCACHE_VALID;
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for(i=0; i<TESTPCACHE_NPAGE; i++, x += szPage){
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p->a[i].key = 0;
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p->a[i].isPinned = 0;
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p->a[i].pData = (void*)x;
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}
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testpcacheGlobal.nInstance++;
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return (sqlite3_pcache*)p;
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}
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/*
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** Set the cache size
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*/
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static void testpcacheCachesize(sqlite3_pcache *pCache, int newSize){
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testpcache *p = (testpcache*)pCache;
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assert( p->iMagic==TESTPCACHE_VALID );
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assert( newSize>=1 );
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assert( testpcacheGlobal.pDummy!=0 );
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assert( testpcacheGlobal.nInstance>0 );
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}
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/*
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** Return the number of pages in the cache that are being used.
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** This includes both pinned and unpinned pages.
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*/
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static int testpcachePagecount(sqlite3_pcache *pCache){
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testpcache *p = (testpcache*)pCache;
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assert( p->iMagic==TESTPCACHE_VALID );
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assert( testpcacheGlobal.pDummy!=0 );
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assert( testpcacheGlobal.nInstance>0 );
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return TESTPCACHE_NPAGE - p->nFree;
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}
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/*
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** Fetch a page.
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*/
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static void *testpcacheFetch(
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sqlite3_pcache *pCache,
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unsigned key,
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int createFlag
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){
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testpcache *p = (testpcache*)pCache;
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int i, j;
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assert( p->iMagic==TESTPCACHE_VALID );
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assert( testpcacheGlobal.pDummy!=0 );
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assert( testpcacheGlobal.nInstance>0 );
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/* See if the page is already in cache. Return immediately if it is */
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for(i=0; i<TESTPCACHE_NPAGE; i++){
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if( p->a[i].key==key ){
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if( !p->a[i].isPinned ){
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p->nPinned++;
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assert( p->nPinned <= TESTPCACHE_NPAGE - p->nFree );
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p->a[i].isPinned = 1;
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}
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return p->a[i].pData;
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}
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}
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/* If createFlag is 0, never allocate a new page */
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if( createFlag==0 ){
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return 0;
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}
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/* If no pages are available, always fail */
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if( p->nPinned==TESTPCACHE_NPAGE ){
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return 0;
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}
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/* Do not allocate the last TESTPCACHE_RESERVE pages unless createFlag is 2 */
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if( p->nPinned>=TESTPCACHE_NPAGE-TESTPCACHE_RESERVE && createFlag<2 ){
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return 0;
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}
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/* Do not allocate if highStress is enabled and createFlag is not 2.
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**
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** The highStress setting causes pagerStress() to be called much more
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** often, which exercises the pager logic more intensely.
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*/
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if( testpcacheGlobal.highStress && createFlag<2 ){
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return 0;
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}
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/* Find a free page to allocate if there are any free pages.
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** Withhold TESTPCACHE_RESERVE free pages until createFlag is 2.
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*/
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if( p->nFree>TESTPCACHE_RESERVE || (createFlag==2 && p->nFree>0) ){
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j = testpcacheRandom(p) % TESTPCACHE_NPAGE;
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for(i=0; i<TESTPCACHE_NPAGE; i++, j = (j+1)%TESTPCACHE_NPAGE){
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if( p->a[j].key==0 ){
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p->a[j].key = key;
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p->a[j].isPinned = 1;
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memset(p->a[j].pData, 0, p->szPage);
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p->nPinned++;
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p->nFree--;
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assert( p->nPinned <= TESTPCACHE_NPAGE - p->nFree );
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return p->a[j].pData;
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}
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}
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/* The prior loop always finds a freepage to allocate */
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assert( 0 );
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}
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/* If this cache is not purgeable then we have to fail.
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*/
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if( p->bPurgeable==0 ){
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return 0;
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}
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/* If there are no free pages, recycle a page. The page to
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** recycle is selected at random from all unpinned pages.
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*/
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j = testpcacheRandom(p) % TESTPCACHE_NPAGE;
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for(i=0; i<TESTPCACHE_NPAGE; i++, j = (j+1)%TESTPCACHE_NPAGE){
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if( p->a[j].key>0 && p->a[j].isPinned==0 ){
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p->a[j].key = key;
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p->a[j].isPinned = 1;
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memset(p->a[j].pData, 0, p->szPage);
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p->nPinned++;
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assert( p->nPinned <= TESTPCACHE_NPAGE - p->nFree );
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return p->a[j].pData;
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}
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}
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/* The previous loop always finds a page to recycle. */
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assert(0);
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return 0;
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}
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/*
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** Unpin a page.
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*/
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static void testpcacheUnpin(
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sqlite3_pcache *pCache,
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void *pOldPage,
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int discard
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){
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testpcache *p = (testpcache*)pCache;
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int i;
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assert( p->iMagic==TESTPCACHE_VALID );
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assert( testpcacheGlobal.pDummy!=0 );
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assert( testpcacheGlobal.nInstance>0 );
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/* Randomly discard pages as they are unpinned according to the
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** discardChance setting. If discardChance is 0, the random discard
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** never happens. If discardChance is 100, it always happens.
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*/
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if( p->bPurgeable
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&& (100-testpcacheGlobal.discardChance) <= (testpcacheRandom(p)%100)
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){
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discard = 1;
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}
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for(i=0; i<TESTPCACHE_NPAGE; i++){
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if( p->a[i].pData==pOldPage ){
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/* The pOldPage pointer always points to a pinned page */
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assert( p->a[i].isPinned );
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p->a[i].isPinned = 0;
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p->nPinned--;
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assert( p->nPinned>=0 );
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if( discard ){
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p->a[i].key = 0;
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p->nFree++;
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assert( p->nFree<=TESTPCACHE_NPAGE );
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}
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return;
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}
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}
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/* The pOldPage pointer always points to a valid page */
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assert( 0 );
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}
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/*
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** Rekey a single page.
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*/
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static void testpcacheRekey(
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sqlite3_pcache *pCache,
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void *pOldPage,
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unsigned oldKey,
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unsigned newKey
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){
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testpcache *p = (testpcache*)pCache;
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int i;
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assert( p->iMagic==TESTPCACHE_VALID );
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assert( testpcacheGlobal.pDummy!=0 );
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assert( testpcacheGlobal.nInstance>0 );
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/* If there already exists another page at newKey, verify that
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** the other page is unpinned and discard it.
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*/
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for(i=0; i<TESTPCACHE_NPAGE; i++){
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if( p->a[i].key==newKey ){
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/* The new key is never a page that is already pinned */
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assert( p->a[i].isPinned==0 );
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p->a[i].key = 0;
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p->nFree++;
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assert( p->nFree<=TESTPCACHE_NPAGE );
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break;
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}
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}
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/* Find the page to be rekeyed and rekey it.
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*/
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for(i=0; i<TESTPCACHE_NPAGE; i++){
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if( p->a[i].key==oldKey ){
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/* The oldKey and pOldPage parameters match */
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assert( p->a[i].pData==pOldPage );
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/* Page to be rekeyed must be pinned */
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assert( p->a[i].isPinned );
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p->a[i].key = newKey;
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return;
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}
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}
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/* Rekey is always given a valid page to work with */
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assert( 0 );
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}
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/*
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** Truncate the page cache. Every page with a key of iLimit or larger
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** is discarded.
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*/
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static void testpcacheTruncate(sqlite3_pcache *pCache, unsigned iLimit){
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testpcache *p = (testpcache*)pCache;
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unsigned int i;
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assert( p->iMagic==TESTPCACHE_VALID );
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assert( testpcacheGlobal.pDummy!=0 );
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assert( testpcacheGlobal.nInstance>0 );
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for(i=0; i<TESTPCACHE_NPAGE; i++){
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if( p->a[i].key>=iLimit ){
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p->a[i].key = 0;
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if( p->a[i].isPinned ){
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p->nPinned--;
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assert( p->nPinned>=0 );
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}
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p->nFree++;
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assert( p->nFree<=TESTPCACHE_NPAGE );
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}
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}
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}
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/*
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** Destroy a page cache.
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*/
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static void testpcacheDestroy(sqlite3_pcache *pCache){
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testpcache *p = (testpcache*)pCache;
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assert( p->iMagic==TESTPCACHE_VALID );
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assert( testpcacheGlobal.pDummy!=0 );
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assert( testpcacheGlobal.nInstance>0 );
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p->iMagic = TESTPCACHE_CLEAR;
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sqlite3_free(p);
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testpcacheGlobal.nInstance--;
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}
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/*
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** Invoke this routine to register or unregister the testing pager cache
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** implemented by this file.
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**
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** Install the test pager cache if installFlag is 1 and uninstall it if
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** installFlag is 0.
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**
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** When installing, discardChance is a number between 0 and 100 that
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** indicates the probability of discarding a page when unpinning the
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** page. 0 means never discard (unless the discard flag is set).
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** 100 means always discard.
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*/
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void installTestPCache(
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int installFlag, /* True to install. False to uninstall. */
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unsigned discardChance, /* 0-100. Chance to discard on unpin */
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unsigned prngSeed, /* Seed for the PRNG */
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unsigned highStress /* Call xStress agressively */
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){
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static const sqlite3_pcache_methods testPcache = {
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(void*)&testpcacheGlobal,
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testpcacheInit,
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testpcacheShutdown,
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testpcacheCreate,
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testpcacheCachesize,
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testpcachePagecount,
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testpcacheFetch,
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testpcacheUnpin,
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testpcacheRekey,
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testpcacheTruncate,
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testpcacheDestroy,
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};
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static sqlite3_pcache_methods defaultPcache;
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static int isInstalled = 0;
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assert( testpcacheGlobal.nInstance==0 );
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assert( testpcacheGlobal.pDummy==0 );
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assert( discardChance<=100 );
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testpcacheGlobal.discardChance = discardChance;
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testpcacheGlobal.prngSeed = prngSeed ^ (prngSeed<<16);
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testpcacheGlobal.highStress = highStress;
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if( installFlag!=isInstalled ){
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if( installFlag ){
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sqlite3_config(SQLITE_CONFIG_GETPCACHE, &defaultPcache);
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assert( defaultPcache.xCreate!=testpcacheCreate );
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sqlite3_config(SQLITE_CONFIG_PCACHE, &testPcache);
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}else{
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assert( defaultPcache.xCreate!=0 );
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sqlite3_config(SQLITE_CONFIG_PCACHE, &defaultPcache);
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}
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isInstalled = installFlag;
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}
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}
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