/* Test program for tsearch et al.
Copyright (C) 1997-2019 Free Software Foundation, Inc.
This file is part of the GNU C Library.
The GNU C Library is free software; you can redistribute it and/or
modify it under the terms of the GNU Lesser General Public
License as published by the Free Software Foundation; either
version 2.1 of the License, or (at your option) any later version.
The GNU C Library 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
Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public
License along with the GNU C Library; if not, see
. */
#ifndef _GNU_SOURCE
# define _GNU_SOURCE 1
#endif
#include
#include
#include
#include
#include
#include
#define SEED 0
#define BALANCED 1
#define PASSES 100
#if BALANCED
#include
#define SIZE 1000
#else
#define SIZE 100
#endif
enum order
{
ascending,
descending,
randomorder
};
enum action
{
build,
build_and_del,
delete,
find
};
/* Set to 1 if a test is flunked. */
static int error = 0;
/* The keys we add to the tree. */
static int x[SIZE];
/* Pointers into the key array, possibly permutated, to define an order
for insertion/removal. */
static int y[SIZE];
/* Flags set for each element visited during a tree walk. */
static int z[SIZE];
/* Depths for all the elements, to check that the depth is constant for
all three visits. */
static int depths[SIZE];
/* Maximum depth during a tree walk. */
static int max_depth;
static int stack_align_check[2];
/* Used to compare walk traces between the two implementations. */
struct walk_trace_element
{
const void *key;
VISIT which;
int depth;
};
#define DYNARRAY_STRUCT walk_trace_list
#define DYNARRAY_ELEMENT struct walk_trace_element
#define DYNARRAY_PREFIX walk_trace_
#define DYNARRAY_INITIAL_SIZE 0
#include
static struct walk_trace_list walk_trace;
/* Compare two keys. */
static int
cmp_fn (const void *a, const void *b)
{
if (!stack_align_check[0])
stack_align_check[0] = TEST_STACK_ALIGN () ? -1 : 1;
return *(const int *) a - *(const int *) b;
}
/* Permute an array of integers. */
static void
memfry (int *string)
{
int i;
for (i = 0; i < SIZE; ++i)
{
int32_t j;
int c;
j = random () % SIZE;
c = string[i];
string[i] = string[j];
string[j] = c;
}
}
struct twalk_with_twalk_r_closure
{
void (*action) (const void *, VISIT, int);
int depth;
};
static void
twalk_with_twalk_r_action (const void *nodep, VISIT which, void *closure0)
{
struct twalk_with_twalk_r_closure *closure = closure0;
switch (which)
{
case leaf:
closure->action (nodep, which, closure->depth);
break;
case preorder:
closure->action (nodep, which, closure->depth);
++closure->depth;
break;
case postorder:
/* The preorder action incremented the depth. */
closure->action (nodep, which, closure->depth - 1);
break;
case endorder:
--closure->depth;
closure->action (nodep, which, closure->depth);
break;
}
}
static void
twalk_with_twalk_r (const void *root,
void (*action) (const void *, VISIT, int))
{
struct twalk_with_twalk_r_closure closure = { action, 0 };
twalk_r (root, twalk_with_twalk_r_action, &closure);
TEST_COMPARE (closure.depth, 0);
}
static void
walk_action (const void *nodep, const VISIT which, const int depth)
{
int key = **(int **) nodep;
walk_trace_add (&walk_trace,
(struct walk_trace_element) { nodep, which, depth });
if (!stack_align_check[1])
stack_align_check[1] = TEST_STACK_ALIGN () ? -1 : 1;
if (depth > max_depth)
max_depth = depth;
if (which == leaf || which == preorder)
{
++z[key];
depths[key] = depth;
}
else
{
if (depths[key] != depth)
{
fputs ("Depth for one element is not constant during tree walk.\n",
stdout);
}
}
}
static void
walk_tree_with (void *root, int expected_count,
void (*walk) (const void *,
void (*) (const void *, VISIT, int)))
{
int i;
memset (z, 0, sizeof z);
max_depth = 0;
walk (root, walk_action);
for (i = 0; i < expected_count; ++i)
if (z[i] != 1)
{
fputs ("Node was not visited.\n", stdout);
error = 1;
}
#if BALANCED
if (max_depth > log (expected_count) * 2 + 2)
#else
if (max_depth > expected_count)
#endif
{
fputs ("Depth too large during tree walk.\n", stdout);
error = 1;
}
}
static void
walk_tree (void *root, int expected_count)
{
walk_trace_clear (&walk_trace);
walk_tree_with (root, expected_count, twalk);
TEST_VERIFY (!walk_trace_has_failed (&walk_trace));
size_t first_list_size;
struct walk_trace_element *first_list
= walk_trace_finalize (&walk_trace, &first_list_size);
TEST_VERIFY_EXIT (first_list != NULL);
walk_tree_with (root, expected_count, twalk_with_twalk_r);
TEST_VERIFY (!walk_trace_has_failed (&walk_trace));
/* Compare the two traces. */
TEST_COMPARE (first_list_size, walk_trace_size (&walk_trace));
for (size_t i = 0; i < first_list_size && i < walk_trace_size (&walk_trace);
++i)
{
TEST_VERIFY (first_list[i].key == walk_trace_at (&walk_trace, i)->key);
TEST_COMPARE (first_list[i].which, walk_trace_at (&walk_trace, i)->which);
TEST_COMPARE (first_list[i].depth, walk_trace_at (&walk_trace, i)->depth);
}
walk_trace_free (&walk_trace);
}
/* Perform an operation on a tree. */
static void
mangle_tree (enum order how, enum action what, void **root, int lag)
{
int i;
if (how == randomorder)
{
for (i = 0; i < SIZE; ++i)
y[i] = i;
memfry (y);
}
for (i = 0; i < SIZE + lag; ++i)
{
void *elem;
int j, k;
switch (how)
{
case randomorder:
if (i >= lag)
k = y[i - lag];
else
/* Ensure that the array index is within bounds. */
k = y[(SIZE - i - 1 + lag) % SIZE];
j = y[i % SIZE];
break;
case ascending:
k = i - lag;
j = i;
break;
case descending:
k = SIZE - i - 1 + lag;
j = SIZE - i - 1;
break;
default:
/* This never should happen, but gcc isn't smart enough to
recognize it. */
abort ();
}
switch (what)
{
case build_and_del:
case build:
if (i < SIZE)
{
if (tfind (x + j, (void *const *) root, cmp_fn) != NULL)
{
fputs ("Found element which is not in tree yet.\n", stdout);
error = 1;
}
elem = tsearch (x + j, root, cmp_fn);
if (elem == 0
|| tfind (x + j, (void *const *) root, cmp_fn) == NULL)
{
fputs ("Couldn't find element after it was added.\n",
stdout);
error = 1;
}
}
if (what == build || i < lag)
break;
j = k;
/* fall through */
case delete:
elem = tfind (x + j, (void *const *) root, cmp_fn);
if (elem == NULL || tdelete (x + j, root, cmp_fn) == NULL)
{
fputs ("Error deleting element.\n", stdout);
error = 1;
}
break;
case find:
if (tfind (x + j, (void *const *) root, cmp_fn) == NULL)
{
fputs ("Couldn't find element after it was added.\n", stdout);
error = 1;
}
break;
}
}
}
static int
do_test (void)
{
int total_error = 0;
static char state[8] = { 1, 2, 3, 4, 5, 6, 7, 8 };
void *root = NULL;
int i, j;
initstate (SEED, state, 8);
for (i = 0; i < SIZE; ++i)
x[i] = i;
/* Do this loop several times to get different permutations for the
random case. */
fputs ("Series I\n", stdout);
for (i = 0; i < PASSES; ++i)
{
fprintf (stdout, "Pass %d... ", i + 1);
fflush (stdout);
error = 0;
mangle_tree (ascending, build, &root, 0);
mangle_tree (ascending, find, &root, 0);
mangle_tree (descending, find, &root, 0);
mangle_tree (randomorder, find, &root, 0);
walk_tree (root, SIZE);
mangle_tree (ascending, delete, &root, 0);
mangle_tree (ascending, build, &root, 0);
walk_tree (root, SIZE);
mangle_tree (descending, delete, &root, 0);
mangle_tree (ascending, build, &root, 0);
walk_tree (root, SIZE);
mangle_tree (randomorder, delete, &root, 0);
mangle_tree (descending, build, &root, 0);
mangle_tree (ascending, find, &root, 0);
mangle_tree (descending, find, &root, 0);
mangle_tree (randomorder, find, &root, 0);
walk_tree (root, SIZE);
mangle_tree (descending, delete, &root, 0);
mangle_tree (descending, build, &root, 0);
walk_tree (root, SIZE);
mangle_tree (descending, delete, &root, 0);
mangle_tree (descending, build, &root, 0);
walk_tree (root, SIZE);
mangle_tree (randomorder, delete, &root, 0);
mangle_tree (randomorder, build, &root, 0);
mangle_tree (ascending, find, &root, 0);
mangle_tree (descending, find, &root, 0);
mangle_tree (randomorder, find, &root, 0);
walk_tree (root, SIZE);
mangle_tree (randomorder, delete, &root, 0);
for (j = 1; j < SIZE; j *= 2)
{
mangle_tree (randomorder, build_and_del, &root, j);
}
fputs (error ? " failed!\n" : " ok.\n", stdout);
total_error |= error;
}
fputs ("Series II\n", stdout);
for (i = 1; i < SIZE; i *= 2)
{
fprintf (stdout, "For size %d... ", i);
fflush (stdout);
error = 0;
mangle_tree (ascending, build_and_del, &root, i);
mangle_tree (descending, build_and_del, &root, i);
mangle_tree (ascending, build_and_del, &root, i);
mangle_tree (descending, build_and_del, &root, i);
mangle_tree (ascending, build_and_del, &root, i);
mangle_tree (descending, build_and_del, &root, i);
mangle_tree (ascending, build_and_del, &root, i);
mangle_tree (descending, build_and_del, &root, i);
fputs (error ? " failed!\n" : " ok.\n", stdout);
total_error |= error;
}
for (i = 0; i < 2; ++i)
if (stack_align_check[i] == 0)
{
printf ("stack alignment check %d not run\n", i);
total_error |= 1;
}
else if (stack_align_check[i] != 1)
{
printf ("stack insufficiently aligned in check %d\n", i);
total_error |= 1;
}
return total_error;
}
#define TEST_FUNCTION do_test ()
#include "../test-skeleton.c"