minix/test/test71.c
Ben Gras 32a4e0d84d many new tests
. test70: regression test for m_out vfs race condition

The following tests use testcache.c to generate test i/o
patterns, generate random write data and verify the reads.

	. test71: blackbox full-stack test of FS operation, testing
	  using the regular VFS interface crazy i/o patterns
	  with various working set sizes, triggering only
	  primary cache, also secondary cache, and finally
	  disk i/o and verifying contents all the time
	. test72: unit test of libminixfs, implementing
	  functions it needs from -lsys and -lblockdriver
	  and the client in order to simulate a working
	  cache client and backend environment.
	. test73: blackbox test of secondary vm cache in isolation

Change-Id: I1287e9753182b8719e634917ad158e3c1e079ceb
2013-04-19 16:21:48 +00:00

131 lines
2.8 KiB
C

/* Test 71 - full hierachy storage test.
*
* Black box test of storage: test consistent file contents
* under various working sets and access patterns.
*
* Using varying working set sizes, exercise various cache
* layers separately.
*
* There is a 'smoke test' mode, suitable for running interactively,
* and a 'regression test' (big) mode, meant for batch invocation only
* as it takes very long.
*/
#include <sys/types.h>
#include <sys/ioc_memory.h>
#include <stdio.h>
#include <assert.h>
#include <string.h>
#include <stdlib.h>
#include <unistd.h>
#include <fcntl.h>
#include "common.h"
#include "testcache.h"
/* we want to flexibly split this test over multiple files
* - for big working sets we might run over the 2GB MFS file limit
* - we might want to test the FS being able to handle lots of
* files / unusual metadata situations
*/
#define MBPERFILE 100
#define MB (1024*1024)
#define MAXFILES ((u64_t) MAXBLOCKS * MAXBLOCKSIZE / MB / MBPERFILE + 1)
static int fds[MAXFILES];
static void
get_fd_offset(int b, int blocksize, u64_t *file_offset, int *fd)
{
u64_t offset = (u64_t) b * blocksize;
int filenumber;
filenumber = offset / MB / MBPERFILE;
assert(filenumber >= 0 && filenumber < MAXFILES);
assert(fds[filenumber] > 0);
*fd = fds[filenumber];
*file_offset = offset - (filenumber * MBPERFILE * MB);
}
int
dowriteblock(int b, int blocksize, u32_t seed, char *data)
{
u64_t offset;
int fd;
get_fd_offset(b, blocksize, &offset, &fd);
if(pwrite(fd, data, blocksize, offset) < blocksize) {
perror("pwrite");
return -1;
}
return blocksize;
}
int
readblock(int b, int blocksize, u32_t seed, char *data)
{
u64_t offset;
int fd;
get_fd_offset(b, blocksize, &offset, &fd);
if(pread(fd, data, blocksize, offset) < blocksize) {
perror("pread");
return -1;
}
return blocksize;
}
void testend(void) { }
int
main(int argc, char *argv[])
{
int f, big = !!getenv(BIGVARNAME), iter = 2;
start(71);
cachequiet(!big);
if(big) iter = 3;
for(f = 0; f < MAXFILES; f++) {
char tempfilename[] = "cachetest.XXXXXXXX";
fds[f] = mkstemp(tempfilename);
if(fds[f] < 0) { perror("mkstemp"); e(20); return 1; }
assert(fds[f] > 0);
}
/* Try various combinations working set sizes
* and block sizes in order to specifically
* target the primary cache, then primary+secondary
* cache, then primary+secondary cache+secondary
* cache eviction.
*/
if(dotest(PAGE_SIZE, 100, iter)) e(5);
if(dotest(PAGE_SIZE*2, 100, iter)) e(2);
if(dotest(PAGE_SIZE*3, 100, iter)) e(3);
if(dotest(PAGE_SIZE, 20000, iter)) e(5);
if(big) {
u32_t totalmem, freemem, cachedmem;
if(dotest(PAGE_SIZE, 150000, iter)) e(5);
getmem(&totalmem, &freemem, &cachedmem);
if(dotest(PAGE_SIZE, totalmem*1.5, iter)) e(6);
}
for(f = 0; f < MAXFILES; f++) {
assert(fds[f] > 0);
close(fds[f]);
}
quit();
return 0;
}