mariadb/ft/tests/cachetable-simple-clone2.cc

/* -*- mode: C++; c-basic-offset: 4; indent-tabs-mode: nil -*- */
// vim: ft=cpp:expandtab:ts=8:sw=4:softtabstop=4:
#ident "$Id$"
#ident "Copyright (c) 2007-2012 Tokutek Inc.  All rights reserved."
#include "includes.h"
#include "test.h"
#include "cachetable-test.h"

bool clone_called;
bool check_flush;
bool flush_expected;
bool flush_called;

static void 
clone_callback(void* UU(value_data), void** cloned_value_data, PAIR_ATTR* new_attr, bool UU(for_checkpoint), void* UU(write_extraargs))
{
    *cloned_value_data = (void *)1;
    new_attr->is_valid = false;
    clone_called = true;
}

static void
flush (
    CACHEFILE f __attribute__((__unused__)),
    int UU(fd),
    CACHEKEY k  __attribute__((__unused__)),
    void *v     __attribute__((__unused__)),
    void** UU(dd),
    void *e     __attribute__((__unused__)),
    PAIR_ATTR s      __attribute__((__unused__)),
    PAIR_ATTR* new_size      __attribute__((__unused__)),
    bool w      __attribute__((__unused__)),
    bool keep   __attribute__((__unused__)),
    bool c      __attribute__((__unused__)),
    bool UU(is_clone)
    ) 
{  
    if (w && check_flush) {
        assert(flush_expected);
        flush_called = true;
    }
}

//
// test the following things for simple cloning:
//  - verifies that after teh checkpoint ends, the PAIR is properly 
//     dirty or clean based on the second unpin
//
static void
test_clean (enum cachetable_dirty dirty, bool cloneable) {
    const int test_limit = 200;
    int r;
    CACHETABLE ct;
    toku_cachetable_create(&ct, test_limit, ZERO_LSN, NULL_LOGGER);
    char fname1[] = __SRCFILE__ "test1.dat";
    unlink(fname1);
    CACHEFILE f1;
    r = toku_cachetable_openf(&f1, ct, fname1, O_RDWR|O_CREAT, S_IRWXU|S_IRWXG|S_IRWXO); assert(r == 0);
    create_dummy_functions(f1);
    check_flush = false;
    
    void* v1;
    long s1;
    CACHETABLE_WRITE_CALLBACK wc = def_write_callback(NULL);
    wc.clone_callback = cloneable ? clone_callback : NULL;
    wc.flush_callback = flush;
    r = toku_cachetable_get_and_pin(f1, make_blocknum(1), 1, &v1, &s1, wc, def_fetch, def_pf_req_callback, def_pf_callback, true, NULL);
    r = toku_test_cachetable_unpin(f1, make_blocknum(1), 1, CACHETABLE_DIRTY, make_pair_attr(8));
    
    // begin checkpoint, since pair is clean, we should not 
    // have the clone called
    CHECKPOINTER cp = toku_cachetable_get_checkpointer(ct);
    toku_cachetable_begin_checkpoint(cp, NULL);
    assert_zero(r);
    r = toku_cachetable_get_and_pin(f1, make_blocknum(1), 1, &v1, &s1, wc, def_fetch, def_pf_req_callback, def_pf_callback, true, NULL);
    
    // at this point, there should be no more dirty writes
    r = toku_test_cachetable_unpin(f1, make_blocknum(1), 1, dirty, make_pair_attr(8));
    usleep(2*1024*1024);
    toku_cachetable_end_checkpoint(
        cp, 
        NULL, 
        NULL,
        NULL
    );
    
    check_flush = true;
    flush_expected = (dirty == CACHETABLE_DIRTY) ? true : false;
    flush_called = false;
    
    toku_cachetable_verify(ct);
    toku_cachefile_close(&f1, false, ZERO_LSN);
    toku_cachetable_close(&ct);
    if (flush_expected) assert(flush_called);
}

int
test_main(int argc, const char *argv[]) {
  default_parse_args(argc, argv);
  test_clean(CACHETABLE_CLEAN, true);
  test_clean(CACHETABLE_DIRTY, true);
  test_clean(CACHETABLE_CLEAN, false);
  test_clean(CACHETABLE_DIRTY, false);
  return 0;
}