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/* Copyright 2013-2014 IBM Corp.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or
* implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include <config.h>
#include <stdbool.h>
#include <stdint.h>
#define BITS_PER_LONG (sizeof(long) * 8)
#include "dummy-cpu.h"
#include <stdlib.h>
#include <string.h>
/* Use these before we override definitions below. */
static void *real_malloc(size_t size)
{
return malloc(size);
}
static inline void real_free(void *p)
{
return free(p);
}
#undef malloc
#undef free
#undef realloc
#include <skiboot.h>
#define is_rodata(p) true
#include "../mem_region.c"
#include "../malloc.c"
#include "../device.c"
#include <assert.h>
#include <stdio.h>
struct dt_node *dt_root;
void lock_caller(struct lock *l, const char *caller)
{
(void)caller;
assert(!l->lock_val);
l->lock_val++;
}
void unlock(struct lock *l)
{
assert(l->lock_val);
l->lock_val--;
}
bool lock_held_by_me(struct lock *l)
{
return l->lock_val;
}
#define TEST_HEAP_ORDER 12
#define TEST_HEAP_SIZE (1ULL << TEST_HEAP_ORDER)
static bool heap_empty(void)
{
const struct alloc_hdr *h = region_start(&skiboot_heap);
return h->num_longs == skiboot_heap.len / sizeof(long);
}
int main(void)
{
char *test_heap;
void *p, *ptrs[100];
size_t i;
struct mem_region *r;
/* Use malloc for the heap, so valgrind can find issues. */
test_heap = real_malloc(TEST_HEAP_SIZE);
skiboot_heap.start = (unsigned long)test_heap;
skiboot_heap.len = TEST_HEAP_SIZE;
lock(&skiboot_heap.free_list_lock);
/* Allocations of various sizes. */
for (i = 0; i < TEST_HEAP_ORDER; i++) {
p = mem_alloc(&skiboot_heap, 1ULL << i, 1, "here");
assert(p);
assert(mem_check(&skiboot_heap));
assert(!strcmp(((struct alloc_hdr *)p)[-1].location, "here"));
assert(p > (void *)test_heap);
assert(p + (1ULL << i) <= (void *)test_heap + TEST_HEAP_SIZE);
assert(mem_allocated_size(p) >= 1ULL << i);
mem_free(&skiboot_heap, p, "freed");
assert(heap_empty());
assert(mem_check(&skiboot_heap));
assert(!strcmp(((struct alloc_hdr *)p)[-1].location, "freed"));
}
p = mem_alloc(&skiboot_heap, 1ULL << i, 1, "here");
assert(!p);
mem_free(&skiboot_heap, p, "freed");
assert(heap_empty());
assert(mem_check(&skiboot_heap));
/* Allocations of various alignments: use small alloc first. */
ptrs[0] = mem_alloc(&skiboot_heap, 1, 1, "small");
for (i = 0; ; i++) {
p = mem_alloc(&skiboot_heap, 1, 1ULL << i, "here");
assert(mem_check(&skiboot_heap));
/* We will eventually fail... */
if (!p) {
assert(i >= TEST_HEAP_ORDER);
break;
}
assert(p);
assert((long)p % (1ULL << i) == 0);
assert(p > (void *)test_heap);
assert(p + 1 <= (void *)test_heap + TEST_HEAP_SIZE);
mem_free(&skiboot_heap, p, "freed");
assert(mem_check(&skiboot_heap));
}
mem_free(&skiboot_heap, ptrs[0], "small freed");
assert(heap_empty());
assert(mem_check(&skiboot_heap));
/* Many little allocations, freed in reverse order. */
for (i = 0; i < 100; i++) {
ptrs[i] = mem_alloc(&skiboot_heap, sizeof(long), 1, "here");
assert(ptrs[i]);
assert(ptrs[i] > (void *)test_heap);
assert(ptrs[i] + sizeof(long)
<= (void *)test_heap + TEST_HEAP_SIZE);
assert(mem_check(&skiboot_heap));
}
mem_dump_free();
for (i = 0; i < 100; i++)
mem_free(&skiboot_heap, ptrs[100 - 1 - i], "freed");
assert(heap_empty());
assert(mem_check(&skiboot_heap));
/* Check the prev_free gets updated properly. */
ptrs[0] = mem_alloc(&skiboot_heap, sizeof(long), 1, "ptrs[0]");
ptrs[1] = mem_alloc(&skiboot_heap, sizeof(long), 1, "ptrs[1]");
assert(ptrs[1] > ptrs[0]);
mem_free(&skiboot_heap, ptrs[0], "ptrs[0] free");
assert(mem_check(&skiboot_heap));
ptrs[0] = mem_alloc(&skiboot_heap, sizeof(long), 1, "ptrs[0] again");
assert(mem_check(&skiboot_heap));
mem_free(&skiboot_heap, ptrs[1], "ptrs[1] free");
mem_free(&skiboot_heap, ptrs[0], "ptrs[0] free");
assert(mem_check(&skiboot_heap));
assert(heap_empty());
#if 0
printf("Heap map:\n");
for (i = 0; i < TEST_HEAP_SIZE / sizeof(long); i++) {
printf("%u", test_bit(skiboot_heap.bitmap, i));
if (i % 64 == 63)
printf("\n");
else if (i % 8 == 7)
printf(" ");
}
#endif
/* Simple enlargement, then free */
p = mem_alloc(&skiboot_heap, 1, 1, "one byte");
assert(p);
assert(mem_resize(&skiboot_heap, p, 100, "hundred bytes"));
assert(mem_allocated_size(p) >= 100);
assert(mem_check(&skiboot_heap));
assert(!strcmp(((struct alloc_hdr *)p)[-1].location, "hundred bytes"));
mem_free(&skiboot_heap, p, "freed");
/* Simple shrink, then free */
p = mem_alloc(&skiboot_heap, 100, 1, "100 bytes");
assert(p);
assert(mem_resize(&skiboot_heap, p, 1, "1 byte"));
assert(mem_allocated_size(p) < 100);
assert(mem_check(&skiboot_heap));
assert(!strcmp(((struct alloc_hdr *)p)[-1].location, "1 byte"));
mem_free(&skiboot_heap, p, "freed");
/* Lots of resizing (enlarge). */
p = mem_alloc(&skiboot_heap, 1, 1, "one byte");
assert(p);
for (i = 1; i <= TEST_HEAP_SIZE - sizeof(struct alloc_hdr); i++) {
assert(mem_resize(&skiboot_heap, p, i, "enlarge"));
assert(mem_allocated_size(p) >= i);
assert(mem_check(&skiboot_heap));
}
/* Can't make it larger though. */
assert(!mem_resize(&skiboot_heap, p, i, "enlarge"));
for (i = TEST_HEAP_SIZE - sizeof(struct alloc_hdr); i > 0; i--) {
assert(mem_resize(&skiboot_heap, p, i, "shrink"));
assert(mem_check(&skiboot_heap));
}
mem_free(&skiboot_heap, p, "freed");
assert(mem_check(&skiboot_heap));
unlock(&skiboot_heap.free_list_lock);
/* lock the regions list */
lock(&mem_region_lock);
/* Test splitting of a region. */
r = new_region("base", (unsigned long)test_heap,
TEST_HEAP_SIZE, NULL, REGION_SKIBOOT_HEAP);
assert(add_region(r));
r = new_region("splitter", (unsigned long)test_heap + TEST_HEAP_SIZE/4,
TEST_HEAP_SIZE/2, NULL, REGION_RESERVED);
assert(add_region(r));
/* Now we should have *three* regions. */
i = 0;
list_for_each(®ions, r, list) {
if (region_start(r) == test_heap) {
assert(r->len == TEST_HEAP_SIZE/4);
assert(strcmp(r->name, "base") == 0);
assert(r->type == REGION_SKIBOOT_HEAP);
} else if (region_start(r) == test_heap + TEST_HEAP_SIZE / 4) {
assert(r->len == TEST_HEAP_SIZE/2);
assert(strcmp(r->name, "splitter") == 0);
assert(r->type == REGION_RESERVED);
assert(!r->free_list.n.next);
} else if (region_start(r) == test_heap + TEST_HEAP_SIZE/4*3) {
assert(r->len == TEST_HEAP_SIZE/4);
assert(strcmp(r->name, "base") == 0);
assert(r->type == REGION_SKIBOOT_HEAP);
} else
abort();
assert(mem_check(r));
i++;
}
mem_dump_free();
assert(i == 3);
while ((r = list_pop(®ions, struct mem_region, list)) != NULL) {
lock(&skiboot_heap.free_list_lock);
mem_free(&skiboot_heap, r, __location__);
unlock(&skiboot_heap.free_list_lock);
}
unlock(&mem_region_lock);
assert(skiboot_heap.free_list_lock.lock_val == 0);
real_free(test_heap);
return 0;
}
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