scrcpy/app/tests/test_bytebuf.c
Romain Vimont b60a8aa657 Add two-step write feature to bytebuf
If there is exactly one producer, then it can assume that the remaining
space in the buffer will only increase until it writes something.

This assumption may allow the producer to write to the buffer (up to a
known safe size) without any synchronization mechanism, thus allowing
to read and write different parts of the buffer in parallel.

The producer can then commit the write with a lock held, and update its
knowledge of the safe empty remaining space.

PR #3757 <https://github.com/Genymobile/scrcpy/pull/3757>
2023-03-10 22:22:15 +01:00

126 lines
3.6 KiB
C

#include "common.h"
#include <assert.h>
#include <string.h>
#include "util/bytebuf.h"
void test_bytebuf_simple(void) {
struct sc_bytebuf buf;
uint8_t data[20];
bool ok = sc_bytebuf_init(&buf, 20);
assert(ok);
sc_bytebuf_write(&buf, (uint8_t *) "hello", sizeof("hello") - 1);
assert(sc_bytebuf_read_available(&buf) == 5);
sc_bytebuf_read(&buf, data, 4);
assert(!strncmp((char *) data, "hell", 4));
sc_bytebuf_write(&buf, (uint8_t *) " world", sizeof(" world") - 1);
assert(sc_bytebuf_read_available(&buf) == 7);
sc_bytebuf_write(&buf, (uint8_t *) "!", 1);
assert(sc_bytebuf_read_available(&buf) == 8);
sc_bytebuf_read(&buf, &data[4], 8);
assert(sc_bytebuf_read_available(&buf) == 0);
data[12] = '\0';
assert(!strcmp((char *) data, "hello world!"));
assert(sc_bytebuf_read_available(&buf) == 0);
sc_bytebuf_destroy(&buf);
}
void test_bytebuf_boundaries(void) {
struct sc_bytebuf buf;
uint8_t data[20];
bool ok = sc_bytebuf_init(&buf, 20);
assert(ok);
sc_bytebuf_write(&buf, (uint8_t *) "hello ", sizeof("hello ") - 1);
assert(sc_bytebuf_read_available(&buf) == 6);
sc_bytebuf_write(&buf, (uint8_t *) "hello ", sizeof("hello ") - 1);
assert(sc_bytebuf_read_available(&buf) == 12);
sc_bytebuf_write(&buf, (uint8_t *) "hello ", sizeof("hello ") - 1);
assert(sc_bytebuf_read_available(&buf) == 18);
sc_bytebuf_read(&buf, data, 9);
assert(!strncmp((char *) data, "hello hel", 9));
assert(sc_bytebuf_read_available(&buf) == 9);
sc_bytebuf_write(&buf, (uint8_t *) "world", sizeof("world") - 1);
assert(sc_bytebuf_read_available(&buf) == 14);
sc_bytebuf_write(&buf, (uint8_t *) "!", 1);
assert(sc_bytebuf_read_available(&buf) == 15);
sc_bytebuf_skip(&buf, 3);
assert(sc_bytebuf_read_available(&buf) == 12);
sc_bytebuf_read(&buf, data, 12);
data[12] = '\0';
assert(!strcmp((char *) data, "hello world!"));
assert(sc_bytebuf_read_available(&buf) == 0);
sc_bytebuf_destroy(&buf);
}
void test_bytebuf_two_steps_write(void) {
struct sc_bytebuf buf;
uint8_t data[20];
bool ok = sc_bytebuf_init(&buf, 20);
assert(ok);
sc_bytebuf_write(&buf, (uint8_t *) "hello ", sizeof("hello ") - 1);
assert(sc_bytebuf_read_available(&buf) == 6);
sc_bytebuf_write(&buf, (uint8_t *) "hello ", sizeof("hello ") - 1);
assert(sc_bytebuf_read_available(&buf) == 12);
sc_bytebuf_prepare_write(&buf, (uint8_t *) "hello ", sizeof("hello ") - 1);
assert(sc_bytebuf_read_available(&buf) == 12); // write not committed yet
sc_bytebuf_read(&buf, data, 9);
assert(!strncmp((char *) data, "hello hel", 3));
assert(sc_bytebuf_read_available(&buf) == 3);
sc_bytebuf_commit_write(&buf, sizeof("hello ") - 1);
assert(sc_bytebuf_read_available(&buf) == 9);
sc_bytebuf_prepare_write(&buf, (uint8_t *) "world", sizeof("world") - 1);
assert(sc_bytebuf_read_available(&buf) == 9); // write not committed yet
sc_bytebuf_commit_write(&buf, sizeof("world") - 1);
assert(sc_bytebuf_read_available(&buf) == 14);
sc_bytebuf_write(&buf, (uint8_t *) "!", 1);
assert(sc_bytebuf_read_available(&buf) == 15);
sc_bytebuf_skip(&buf, 3);
assert(sc_bytebuf_read_available(&buf) == 12);
sc_bytebuf_read(&buf, data, 12);
data[12] = '\0';
assert(!strcmp((char *) data, "hello world!"));
assert(sc_bytebuf_read_available(&buf) == 0);
sc_bytebuf_destroy(&buf);
}
int main(int argc, char *argv[]) {
(void) argc;
(void) argv;
test_bytebuf_simple();
test_bytebuf_boundaries();
test_bytebuf_two_steps_write();
return 0;
}