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/* -*- mode: C++; c-basic-offset: 4; indent-tabs-mode: nil -*- */
// vim: ft=cpp:expandtab:ts=8:sw=4:softtabstop=4:
#ident "$Id$"
/*======
This file is part of PerconaFT.


Copyright (c) 2006, 2015, Percona and/or its affiliates. All rights reserved.

    PerconaFT is free software: you can redistribute it and/or modify
    it under the terms of the GNU General Public License, version 2,
    as published by the Free Software Foundation.

    PerconaFT is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.

    You should have received a copy of the GNU General Public License
    along with PerconaFT.  If not, see <http://www.gnu.org/licenses/>.

----------------------------------------

    PerconaFT is free software: you can redistribute it and/or modify
    it under the terms of the GNU Affero General Public License, version 3,
    as published by the Free Software Foundation.

    PerconaFT 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 Affero General Public License for more details.

    You should have received a copy of the GNU Affero General Public License
    along with PerconaFT.  If not, see <http://www.gnu.org/licenses/>.
======= */

#ident "Copyright (c) 2006, 2015, Percona and/or its affiliates. All rights reserved."

/* The goal of this test.  Make sure that inserts stay behind deletes. */


#include "test.h"

#include <ft-cachetable-wrappers.h>

#include "ft-flusher.h"
#include "ft-flusher-internal.h"
#include "cachetable/checkpoint.h"

static TOKUTXN const null_txn = 0;

enum { NODESIZE = 1024, KSIZE=NODESIZE-100, TOKU_PSIZE=20 };

CACHETABLE ct;
FT_HANDLE t;
const char *fname = TOKU_TEST_FILENAME;

int curr_child_to_flush;
int num_flushes_called;

static int child_to_flush(FT UU(h), FTNODE parent, void* UU(extra)) {
    // internal node has 2 children
    if (parent->height == 1) {
        assert(parent->n_children == 2);
        return curr_child_to_flush;
    }
    // root has 1 child
    else if (parent->height == 2) {
        assert(parent->n_children == 1);
        return 0;
    }
    else {
        assert(false);
    }
    return curr_child_to_flush;
}

static void update_status(FTNODE UU(child), int UU(dirtied), void* UU(extra)) {
    num_flushes_called++;
}



static bool
dont_destroy_bn(void* UU(extra))
{
    return false;
}

static void merge_should_not_happen(struct flusher_advice* UU(fa),
                              FT UU(h),
                              FTNODE UU(parent),
                              int UU(childnum),
                              FTNODE UU(child),
                              void* UU(extra))
{
    assert(false);
}

static bool recursively_flush_should_not_happen(FTNODE UU(child), void* UU(extra)) {
    assert(false);
}

static bool always_flush(FTNODE UU(child), void* UU(extra)) {
    return true;
}


static void
doit (void) {
    BLOCKNUM node_internal, node_root;
    BLOCKNUM node_leaf[2];
    int r;
    
    toku_cachetable_create(&ct, 500*1024*1024, ZERO_LSN, nullptr);
    unlink(fname);
    r = toku_open_ft_handle(fname, 1, &t, NODESIZE, NODESIZE/2, TOKU_DEFAULT_COMPRESSION_METHOD, ct, null_txn, toku_builtin_compare_fun);
    assert(r==0);

    toku_testsetup_initialize();  // must precede any other toku_testsetup calls

    r = toku_testsetup_leaf(t, &node_leaf[0], 1, NULL, NULL);
    assert(r==0);
    r = toku_testsetup_leaf(t, &node_leaf[1], 1, NULL, NULL);
    assert(r==0);

    char* pivots[1];
    pivots[0] = toku_strdup("kkkkk");
    int pivot_len = 6;
    r = toku_testsetup_nonleaf(t, 1, &node_internal, 2, node_leaf, pivots, &pivot_len);
    assert(r==0);

    r = toku_testsetup_nonleaf(t, 2, &node_root, 1, &node_internal, 0, 0);
    assert(r==0);

    r = toku_testsetup_root(t, node_root);
    assert(r==0);

    char filler[900-2*bn_data::HEADER_LENGTH];
    memset(filler, 0, sizeof(filler));
    // now we insert filler data so that a merge does not happen
    r = toku_testsetup_insert_to_leaf (
        t, 
        node_leaf[0], 
        "b", // key
        2, // keylen
        filler, 
        sizeof(filler)
        );
    assert(r==0);
    r = toku_testsetup_insert_to_leaf (
        t, 
        node_leaf[1], 
        "y", // key
        2, // keylen
        filler, 
        sizeof(filler)
        );
    assert(r==0);

    // make buffers in internal node non-empty
    r = toku_testsetup_insert_to_nonleaf(
        t, 
        node_internal, 
        FT_INSERT, 
        "a",
        2,
        NULL,
        0
        );
    assert_zero(r);
    r = toku_testsetup_insert_to_nonleaf(
        t, 
        node_internal, 
        FT_INSERT, 
        "z",
        2,
        NULL,
        0
        );
    assert_zero(r);
    
    //
    // now run a checkpoint to get everything clean
    //
    CHECKPOINTER cp = toku_cachetable_get_checkpointer(ct);
    r = toku_checkpoint(cp, NULL, NULL, NULL, NULL, NULL, CLIENT_CHECKPOINT);
    assert_zero(r);

    // now with setup done, start the test
    // test that if toku_ft_flush_some_child properly honors
    // what we say and flushes the child we pick
    FTNODE node = NULL;
    toku_pin_node_with_min_bfe(&node, node_internal, t);
    toku_ftnode_assert_fully_in_memory(node);
    assert(node->n_children == 2);
    assert(!node->dirty());
    assert(toku_bnc_n_entries(node->bp[0].ptr.u.nonleaf) > 0);
    assert(toku_bnc_n_entries(node->bp[1].ptr.u.nonleaf) > 0);

    struct flusher_advice fa;
    flusher_advice_init(
        &fa,
        child_to_flush,
        dont_destroy_bn,
        recursively_flush_should_not_happen,
        merge_should_not_happen,
        update_status,
	default_pick_child_after_split,
        NULL
        );
    curr_child_to_flush = 0;
    num_flushes_called = 0;
    toku_ft_flush_some_child(t->ft, node, &fa);
    assert(num_flushes_called == 1);

    toku_pin_node_with_min_bfe(&node, node_internal, t);
    toku_ftnode_assert_fully_in_memory(node);
    assert(node->dirty());
    assert(node->n_children == 2);
    // child 0 should have empty buffer because it flushed
    // child 1 should still have message in buffer
    assert(toku_bnc_n_entries(node->bp[0].ptr.u.nonleaf) == 0);
    assert(toku_bnc_n_entries(node->bp[1].ptr.u.nonleaf) > 0);
    toku_unpin_ftnode(t->ft, node);
    r = toku_checkpoint(cp, NULL, NULL, NULL, NULL, NULL, CLIENT_CHECKPOINT);
    assert_zero(r);    
    toku_pin_node_with_min_bfe(&node, node_internal, t);
    assert(!node->dirty());
    curr_child_to_flush = 1;
    num_flushes_called = 0;
    toku_ft_flush_some_child(t->ft, node, &fa);
    assert(num_flushes_called == 1);
    
    toku_pin_node_with_min_bfe(&node, node_internal, t);
    assert(node->dirty());
    toku_ftnode_assert_fully_in_memory(node);
    assert(node->n_children == 2);
    // both buffers should be empty now
    assert(toku_bnc_n_entries(node->bp[0].ptr.u.nonleaf) == 0);
    assert(toku_bnc_n_entries(node->bp[1].ptr.u.nonleaf) == 0);
    // now let's do a flush with an empty buffer, make sure it is ok
    toku_unpin_ftnode(t->ft, node);
    r = toku_checkpoint(cp, NULL, NULL, NULL, NULL, NULL, CLIENT_CHECKPOINT);
    assert_zero(r);    
    toku_pin_node_with_min_bfe(&node, node_internal, t);
    assert(!node->dirty());
    curr_child_to_flush = 0;
    num_flushes_called = 0;
    toku_ft_flush_some_child(t->ft, node, &fa);
    assert(num_flushes_called == 1);

    toku_pin_node_with_min_bfe(&node, node_internal, t);
    assert(node->dirty()); // nothing was flushed, but since we were trying to flush to a leaf, both become dirty
    toku_ftnode_assert_fully_in_memory(node);
    assert(node->n_children == 2);
    // both buffers should be empty now
    assert(toku_bnc_n_entries(node->bp[0].ptr.u.nonleaf) == 0);
    assert(toku_bnc_n_entries(node->bp[1].ptr.u.nonleaf) == 0);
    toku_unpin_ftnode(t->ft, node);

    // now let's start a flush from the root, that always recursively flushes    
    flusher_advice_init(
        &fa,
        child_to_flush,
        dont_destroy_bn,
        always_flush,
        merge_should_not_happen,
        update_status,
	default_pick_child_after_split,
        NULL
        );
    // use a for loop so to get us down both paths
    for (int i = 0; i < 2; i++) {
        toku_pin_node_with_min_bfe(&node, node_root, t);
        toku_ftnode_assert_fully_in_memory(node); // entire root is in memory
        curr_child_to_flush = i;
        num_flushes_called = 0;
        toku_ft_flush_some_child(t->ft, node, &fa);
        assert(num_flushes_called == 2);
    
        toku_pin_node_with_min_bfe(&node, node_internal, t);
        assert(node->dirty());
        toku_unpin_ftnode(t->ft, node);
        toku_pin_node_with_min_bfe(&node, node_leaf[0], t);
        assert(node->dirty());
        toku_unpin_ftnode(t->ft, node);
        toku_pin_node_with_min_bfe(&node, node_leaf[1], t);
        if (i == 0) {
            assert(!node->dirty());
        }
        else {
            assert(node->dirty());
        }
        toku_unpin_ftnode(t->ft, node);
    }

    // now one more test to show a bug was fixed
    // if there is nothing to flush from parent to child,
    // and child is not fully in memory, we used to crash
    // so, to make sure that is fixed, let's get internal to not
    // be fully in memory, and make sure the above test works
    
    // a hack to get internal compressed
    r = toku_testsetup_insert_to_nonleaf(
        t, 
        node_internal, 
        FT_INSERT, 
        "c",
        2,
        NULL,
        0
        );
    assert_zero(r);
    r = toku_checkpoint(cp, NULL, NULL, NULL, NULL, NULL, CLIENT_CHECKPOINT);
    assert_zero(r);    
    toku_pin_node_with_min_bfe(&node, node_internal, t);
    for (int i = 0; i < 20; i++) {
        toku_ftnode_pe_callback(node, make_pair_attr(0xffffffff), t->ft, def_pe_finalize_impl, nullptr);
    }
    assert(BP_STATE(node,0) == PT_COMPRESSED);
    toku_unpin_ftnode(t->ft, node);

    //now let's do the same test as above
    toku_pin_node_with_min_bfe(&node, node_root, t);
    toku_ftnode_assert_fully_in_memory(node); // entire root is in memory
    curr_child_to_flush = 0;
    num_flushes_called = 0;
    toku_ft_flush_some_child(t->ft, node, &fa);
    assert(num_flushes_called == 2);
    
    r = toku_close_ft_handle_nolsn(t, 0);    assert(r==0);
    toku_cachetable_close(&ct);

    toku_free(pivots[0]);
}

int
test_main (int argc __attribute__((__unused__)), const char *argv[] __attribute__((__unused__))) {
    doit();
    return 0;
}