#if !defined(MUNIT_OUTPUT_FILE)
# define MUNIT_OUTPUT_FILE stdout
#endif
#if !defined(MUNIT_TEST_TIME_FORMAT)
# define MUNIT_TEST_TIME_FORMAT "0.8f"
#endif
#if !defined(MUNIT_TEST_NAME_LEN)
# define MUNIT_TEST_NAME_LEN 37
#endif
#if !defined(MUNIT_DISABLE_TIMING)
# define MUNIT_ENABLE_TIMING
#endif
#if defined(_POSIX_C_SOURCE) && (_POSIX_C_SOURCE < 200809L)
# undef _POSIX_C_SOURCE
#endif
#if !defined(_POSIX_C_SOURCE)
# define _POSIX_C_SOURCE 200809L
#endif
#if defined(_XOPEN_SOURCE)
# undef _XOPEN_SOURCE
#endif
#if defined(__STDC_VERSION__)
# if __STDC_VERSION__ >= 201112L
# define _XOPEN_SOURCE 700
# elif __STDC_VERSION__ >= 199901L
# define _XOPEN_SOURCE 600
# endif
#endif
#if defined(_MSC_VER) && !defined(_CRT_NONSTDC_NO_DEPRECATE)
# define _CRT_NONSTDC_NO_DEPRECATE
#endif
#if defined(__STDC_VERSION__) && (__STDC_VERSION__ >= 199901L)
# include <stdbool.h>
#elif defined(_WIN32)
#endif
#include <limits.h>
#include <time.h>
#include <errno.h>
#include <string.h>
#include <stdlib.h>
#include <stdio.h>
#include <stdarg.h>
#include <setjmp.h>
#if !defined(MUNIT_NO_NL_LANGINFO) && !defined(_WIN32)
# define MUNIT_NL_LANGINFO
# include <locale.h>
# include <langinfo.h>
# include <strings.h>
#endif
#if !defined(_WIN32)
# include <unistd.h>
# include <sys/types.h>
# include <sys/wait.h>
#else
# include <windows.h>
# include <io.h>
# include <fcntl.h>
# if !defined(STDERR_FILENO)
# define STDERR_FILENO _fileno(stderr)
# endif
#endif
#include "munit.h"
#define MUNIT_STRINGIFY(x) #x
#define MUNIT_XSTRINGIFY(x) MUNIT_STRINGIFY(x)
#if defined(__GNUC__) || defined(__INTEL_COMPILER) || defined(__SUNPRO_CC) || \
defined(__IBMCPP__)
# define MUNIT_THREAD_LOCAL __thread
#elif (defined(__STDC_VERSION__) && (__STDC_VERSION__ >= 201102L)) || \
defined(_Thread_local)
# define MUNIT_THREAD_LOCAL _Thread_local
#elif defined(_WIN32)
# define MUNIT_THREAD_LOCAL __declspec(thread)
#endif
#if defined(_MSC_VER) && (_MSC_VER <= 1800)
# pragma warning(disable : 4127)
#endif
#if defined(_WIN32) || defined(__EMSCRIPTEN__)
# define MUNIT_NO_FORK
#endif
#if defined(__EMSCRIPTEN__)
# define MUNIT_NO_BUFFER
#endif
static MunitLogLevel munit_log_level_visible = MUNIT_LOG_INFO;
static MunitLogLevel munit_log_level_fatal = MUNIT_LOG_ERROR;
#if defined(MUNIT_THREAD_LOCAL)
static MUNIT_THREAD_LOCAL munit_bool munit_error_jmp_buf_valid = 0;
static MUNIT_THREAD_LOCAL jmp_buf munit_error_jmp_buf;
#endif
#if defined(__MINGW32__) || defined(__MINGW64__)
# pragma GCC diagnostic push
# pragma GCC diagnostic ignored "-Wsuggest-attribute=format"
#endif
MUNIT_PRINTF(5, 0)
static void munit_logf_exv(MunitLogLevel level, FILE *fp, const char *filename,
int line, const char *format, va_list ap) {
if (level < munit_log_level_visible)
return;
switch (level) {
case MUNIT_LOG_DEBUG:
fputs("Debug", fp);
break;
case MUNIT_LOG_INFO:
fputs("Info", fp);
break;
case MUNIT_LOG_WARNING:
fputs("Warning", fp);
break;
case MUNIT_LOG_ERROR:
fputs("Error", fp);
break;
default:
munit_logf_ex(MUNIT_LOG_ERROR, filename, line, "Invalid log level (%d)",
level);
return;
}
fputs(": ", fp);
if (filename != NULL)
fprintf(fp, "%s:%d: ", filename, line);
vfprintf(fp, format, ap);
fputc('\n', fp);
}
MUNIT_PRINTF(3, 4)
static void munit_logf_internal(MunitLogLevel level, FILE *fp,
const char *format, ...) {
va_list ap;
va_start(ap, format);
munit_logf_exv(level, fp, NULL, 0, format, ap);
va_end(ap);
}
static void munit_log_internal(MunitLogLevel level, FILE *fp,
const char *message) {
munit_logf_internal(level, fp, "%s", message);
}
void munit_logf_ex(MunitLogLevel level, const char *filename, int line,
const char *format, ...) {
va_list ap;
va_start(ap, format);
munit_logf_exv(level, stderr, filename, line, format, ap);
va_end(ap);
if (level >= munit_log_level_fatal) {
#if defined(MUNIT_THREAD_LOCAL)
if (munit_error_jmp_buf_valid)
longjmp(munit_error_jmp_buf, 1);
#endif
abort();
}
}
void munit_errorf_ex(const char *filename, int line, const char *format, ...) {
va_list ap;
va_start(ap, format);
munit_logf_exv(MUNIT_LOG_ERROR, stderr, filename, line, format, ap);
va_end(ap);
#if defined(MUNIT_THREAD_LOCAL)
if (munit_error_jmp_buf_valid)
longjmp(munit_error_jmp_buf, 1);
#endif
abort();
}
#if defined(__MINGW32__) || defined(__MINGW64__)
# pragma GCC diagnostic pop
#endif
#if !defined(MUNIT_STRERROR_LEN)
# define MUNIT_STRERROR_LEN 80
#endif
static void munit_log_errno(MunitLogLevel level, FILE *fp, const char *msg) {
#if defined(MUNIT_NO_STRERROR_R) || \
(defined(__MINGW32__) && !defined(MINGW_HAS_SECURE_API))
munit_logf_internal(level, fp, "%s: %s (%d)", msg, strerror(errno), errno);
#else
char munit_error_str[MUNIT_STRERROR_LEN];
munit_error_str[0] = '\0';
# if !defined(_WIN32)
strerror_r(errno, munit_error_str, MUNIT_STRERROR_LEN);
# else
strerror_s(munit_error_str, MUNIT_STRERROR_LEN, errno);
# endif
munit_logf_internal(level, fp, "%s: %s (%d)", msg, munit_error_str, errno);
#endif
}
void *munit_malloc_ex(const char *filename, int line, size_t size) {
void *ptr;
if (size == 0)
return NULL;
ptr = calloc(1, size);
if (MUNIT_UNLIKELY(ptr == NULL)) {
munit_logf_ex(MUNIT_LOG_ERROR, filename, line,
"Failed to allocate %" MUNIT_SIZE_MODIFIER "u bytes.", size);
}
return ptr;
}
#if defined(MUNIT_ENABLE_TIMING)
# define psnip_uint64_t munit_uint64_t
# define psnip_uint32_t munit_uint32_t
# if !defined(PSNIP_CLOCK_H)
# define PSNIP_CLOCK_H
# if !defined(psnip_uint64_t)
# include "../exact-int/exact-int.h"
# endif
# if !defined(PSNIP_CLOCK_STATIC_INLINE)
# if defined(__GNUC__)
# define PSNIP_CLOCK__COMPILER_ATTRIBUTES __attribute__((__unused__))
# else
# define PSNIP_CLOCK__COMPILER_ATTRIBUTES
# endif
# define PSNIP_CLOCK__FUNCTION PSNIP_CLOCK__COMPILER_ATTRIBUTES static
# endif
enum PsnipClockType {
PSNIP_CLOCK_TYPE_WALL = 1,
PSNIP_CLOCK_TYPE_CPU = 2,
PSNIP_CLOCK_TYPE_MONOTONIC = 3
};
struct PsnipClockTimespec {
psnip_uint64_t seconds;
psnip_uint64_t nanoseconds;
};
# define PSNIP_CLOCK_METHOD_CLOCK_GETTIME 1
# define PSNIP_CLOCK_METHOD_TIME 2
# define PSNIP_CLOCK_METHOD_GETTIMEOFDAY 3
# define PSNIP_CLOCK_METHOD_QUERYPERFORMANCECOUNTER 4
# define PSNIP_CLOCK_METHOD_MACH_ABSOLUTE_TIME 5
# define PSNIP_CLOCK_METHOD_CLOCK 6
# define PSNIP_CLOCK_METHOD_GETPROCESSTIMES 7
# define PSNIP_CLOCK_METHOD_GETRUSAGE 8
# define PSNIP_CLOCK_METHOD_GETSYSTEMTIMEPRECISEASFILETIME 9
# define PSNIP_CLOCK_METHOD_GETTICKCOUNT64 10
# include <assert.h>
# if defined(HEDLEY_UNREACHABLE)
# define PSNIP_CLOCK_UNREACHABLE() HEDLEY_UNREACHABLE()
# else
# define PSNIP_CLOCK_UNREACHABLE() assert(0)
# endif
# if defined(__unix__) || defined(__unix) || defined(__linux__)
# include <limits.h>
# include <unistd.h>
# endif
# if defined(_POSIX_TIMERS) && (_POSIX_TIMERS > 0)
# if (defined(__GLIBC__) && \
(__GLIBC__ > 2 || (__GLIBC__ == 2 && __GLIBC_MINOR__ >= 17))) || \
(defined(__FreeBSD__))
# define PSNIP_CLOCK_HAVE_CLOCK_GETTIME
# elif !defined(PSNIP_CLOCK_NO_LIBRT)
# define PSNIP_CLOCK_HAVE_CLOCK_GETTIME
# endif
# endif
# if defined(_WIN32)
# if !defined(PSNIP_CLOCK_CPU_METHOD)
# define PSNIP_CLOCK_CPU_METHOD PSNIP_CLOCK_METHOD_GETPROCESSTIMES
# endif
# if !defined(PSNIP_CLOCK_MONOTONIC_METHOD)
# define PSNIP_CLOCK_MONOTONIC_METHOD \
PSNIP_CLOCK_METHOD_QUERYPERFORMANCECOUNTER
# endif
# endif
# if defined(__MACH__) && !defined(__gnu_hurd__)
# if !defined(PSNIP_CLOCK_MONOTONIC_METHOD)
# define PSNIP_CLOCK_MONOTONIC_METHOD \
PSNIP_CLOCK_METHOD_MACH_ABSOLUTE_TIME
# endif
# endif
# if defined(PSNIP_CLOCK_HAVE_CLOCK_GETTIME)
# include <time.h>
# if !defined(PSNIP_CLOCK_WALL_METHOD)
# if defined(CLOCK_REALTIME_PRECISE)
# define PSNIP_CLOCK_WALL_METHOD PSNIP_CLOCK_METHOD_CLOCK_GETTIME
# define PSNIP_CLOCK_CLOCK_GETTIME_WALL CLOCK_REALTIME_PRECISE
# elif !defined(__sun)
# define PSNIP_CLOCK_WALL_METHOD PSNIP_CLOCK_METHOD_CLOCK_GETTIME
# define PSNIP_CLOCK_CLOCK_GETTIME_WALL CLOCK_REALTIME
# endif
# endif
# if !defined(PSNIP_CLOCK_CPU_METHOD)
# if defined(_POSIX_CPUTIME) || defined(CLOCK_PROCESS_CPUTIME_ID)
# define PSNIP_CLOCK_CPU_METHOD PSNIP_CLOCK_METHOD_CLOCK_GETTIME
# define PSNIP_CLOCK_CLOCK_GETTIME_CPU CLOCK_PROCESS_CPUTIME_ID
# elif defined(CLOCK_VIRTUAL)
# define PSNIP_CLOCK_CPU_METHOD PSNIP_CLOCK_METHOD_CLOCK_GETTIME
# define PSNIP_CLOCK_CLOCK_GETTIME_CPU CLOCK_VIRTUAL
# endif
# endif
# if !defined(PSNIP_CLOCK_MONOTONIC_METHOD)
# if defined(CLOCK_MONOTONIC_RAW)
# define PSNIP_CLOCK_MONOTONIC_METHOD PSNIP_CLOCK_METHOD_CLOCK_GETTIME
# define PSNIP_CLOCK_CLOCK_GETTIME_MONOTONIC CLOCK_MONOTONIC
# elif defined(CLOCK_MONOTONIC_PRECISE)
# define PSNIP_CLOCK_MONOTONIC_METHOD PSNIP_CLOCK_METHOD_CLOCK_GETTIME
# define PSNIP_CLOCK_CLOCK_GETTIME_MONOTONIC CLOCK_MONOTONIC_PRECISE
# elif defined(_POSIX_MONOTONIC_CLOCK) || defined(CLOCK_MONOTONIC)
# define PSNIP_CLOCK_MONOTONIC_METHOD PSNIP_CLOCK_METHOD_CLOCK_GETTIME
# define PSNIP_CLOCK_CLOCK_GETTIME_MONOTONIC CLOCK_MONOTONIC
# endif
# endif
# endif
# if defined(_POSIX_VERSION) && (_POSIX_VERSION >= 200112L)
# if !defined(PSNIP_CLOCK_WALL_METHOD)
# define PSNIP_CLOCK_WALL_METHOD PSNIP_CLOCK_METHOD_GETTIMEOFDAY
# endif
# endif
# if !defined(PSNIP_CLOCK_WALL_METHOD)
# define PSNIP_CLOCK_WALL_METHOD PSNIP_CLOCK_METHOD_TIME
# endif
# if !defined(PSNIP_CLOCK_CPU_METHOD)
# define PSNIP_CLOCK_CPU_METHOD PSNIP_CLOCK_METHOD_CLOCK
# endif
# if !defined(PSNIP_CLOCK_MONOTONIC_METHOD) && \
defined(PSNIP_CLOCK_REQUIRE_MONOTONIC)
# error No monotonic clock found.
# endif
# if (defined(PSNIP_CLOCK_CPU_METHOD) && \
(PSNIP_CLOCK_CPU_METHOD == PSNIP_CLOCK_METHOD_CLOCK_GETTIME)) || \
(defined(PSNIP_CLOCK_WALL_METHOD) && \
(PSNIP_CLOCK_WALL_METHOD == PSNIP_CLOCK_METHOD_CLOCK_GETTIME)) || \
(defined(PSNIP_CLOCK_MONOTONIC_METHOD) && \
(PSNIP_CLOCK_MONOTONIC_METHOD == PSNIP_CLOCK_METHOD_CLOCK_GETTIME)) || \
(defined(PSNIP_CLOCK_CPU_METHOD) && \
(PSNIP_CLOCK_CPU_METHOD == PSNIP_CLOCK_METHOD_CLOCK)) || \
(defined(PSNIP_CLOCK_WALL_METHOD) && \
(PSNIP_CLOCK_WALL_METHOD == PSNIP_CLOCK_METHOD_CLOCK)) || \
(defined(PSNIP_CLOCK_MONOTONIC_METHOD) && \
(PSNIP_CLOCK_MONOTONIC_METHOD == PSNIP_CLOCK_METHOD_CLOCK)) || \
(defined(PSNIP_CLOCK_CPU_METHOD) && \
(PSNIP_CLOCK_CPU_METHOD == PSNIP_CLOCK_METHOD_TIME)) || \
(defined(PSNIP_CLOCK_WALL_METHOD) && \
(PSNIP_CLOCK_WALL_METHOD == PSNIP_CLOCK_METHOD_TIME)) || \
(defined(PSNIP_CLOCK_MONOTONIC_METHOD) && \
(PSNIP_CLOCK_MONOTONIC_METHOD == PSNIP_CLOCK_METHOD_TIME))
# include <time.h>
# endif
# if (defined(PSNIP_CLOCK_CPU_METHOD) && \
(PSNIP_CLOCK_CPU_METHOD == PSNIP_CLOCK_METHOD_GETTIMEOFDAY)) || \
(defined(PSNIP_CLOCK_WALL_METHOD) && \
(PSNIP_CLOCK_WALL_METHOD == PSNIP_CLOCK_METHOD_GETTIMEOFDAY)) || \
(defined(PSNIP_CLOCK_MONOTONIC_METHOD) && \
(PSNIP_CLOCK_MONOTONIC_METHOD == PSNIP_CLOCK_METHOD_GETTIMEOFDAY))
# include <sys/time.h>
# endif
# if (defined(PSNIP_CLOCK_CPU_METHOD) && \
(PSNIP_CLOCK_CPU_METHOD == PSNIP_CLOCK_METHOD_GETPROCESSTIMES)) || \
(defined(PSNIP_CLOCK_WALL_METHOD) && \
(PSNIP_CLOCK_WALL_METHOD == PSNIP_CLOCK_METHOD_GETPROCESSTIMES)) || \
(defined(PSNIP_CLOCK_MONOTONIC_METHOD) && \
(PSNIP_CLOCK_MONOTONIC_METHOD == \
PSNIP_CLOCK_METHOD_GETPROCESSTIMES)) || \
(defined(PSNIP_CLOCK_CPU_METHOD) && \
(PSNIP_CLOCK_CPU_METHOD == PSNIP_CLOCK_METHOD_GETTICKCOUNT64)) || \
(defined(PSNIP_CLOCK_WALL_METHOD) && \
(PSNIP_CLOCK_WALL_METHOD == PSNIP_CLOCK_METHOD_GETTICKCOUNT64)) || \
(defined(PSNIP_CLOCK_MONOTONIC_METHOD) && \
(PSNIP_CLOCK_MONOTONIC_METHOD == PSNIP_CLOCK_METHOD_GETTICKCOUNT64))
# include <windows.h>
# endif
# if (defined(PSNIP_CLOCK_CPU_METHOD) && \
(PSNIP_CLOCK_CPU_METHOD == PSNIP_CLOCK_METHOD_GETRUSAGE)) || \
(defined(PSNIP_CLOCK_WALL_METHOD) && \
(PSNIP_CLOCK_WALL_METHOD == PSNIP_CLOCK_METHOD_GETRUSAGE)) || \
(defined(PSNIP_CLOCK_MONOTONIC_METHOD) && \
(PSNIP_CLOCK_MONOTONIC_METHOD == PSNIP_CLOCK_METHOD_GETRUSAGE))
# include <sys/time.h>
# include <sys/resource.h>
# endif
# if (defined(PSNIP_CLOCK_CPU_METHOD) && \
(PSNIP_CLOCK_CPU_METHOD == PSNIP_CLOCK_METHOD_MACH_ABSOLUTE_TIME)) || \
(defined(PSNIP_CLOCK_WALL_METHOD) && \
(PSNIP_CLOCK_WALL_METHOD == PSNIP_CLOCK_METHOD_MACH_ABSOLUTE_TIME)) || \
(defined(PSNIP_CLOCK_MONOTONIC_METHOD) && \
(PSNIP_CLOCK_MONOTONIC_METHOD == \
PSNIP_CLOCK_METHOD_MACH_ABSOLUTE_TIME))
# include <CoreServices/CoreServices.h>
# include <mach/mach.h>
# include <mach/mach_time.h>
# endif
# define PSNIP_CLOCK_NSEC_PER_SEC ((psnip_uint32_t)(1000000000ULL))
# if (defined(PSNIP_CLOCK_CPU_METHOD) && \
(PSNIP_CLOCK_CPU_METHOD == PSNIP_CLOCK_METHOD_CLOCK_GETTIME)) || \
(defined(PSNIP_CLOCK_WALL_METHOD) && \
(PSNIP_CLOCK_WALL_METHOD == PSNIP_CLOCK_METHOD_CLOCK_GETTIME)) || \
(defined(PSNIP_CLOCK_MONOTONIC_METHOD) && \
(PSNIP_CLOCK_MONOTONIC_METHOD == PSNIP_CLOCK_METHOD_CLOCK_GETTIME))
PSNIP_CLOCK__FUNCTION psnip_uint32_t
psnip_clock__clock_getres(clockid_t clk_id) {
struct timespec res;
int r;
r = clock_getres(clk_id, &res);
if (r != 0)
return 0;
return (psnip_uint32_t)(PSNIP_CLOCK_NSEC_PER_SEC /
(psnip_uint64_t)res.tv_nsec);
}
PSNIP_CLOCK__FUNCTION int
psnip_clock__clock_gettime(clockid_t clk_id, struct PsnipClockTimespec *res) {
struct timespec ts;
if (clock_gettime(clk_id, &ts) != 0)
return -10;
res->seconds = (psnip_uint64_t)(ts.tv_sec);
res->nanoseconds = (psnip_uint64_t)(ts.tv_nsec);
return 0;
}
# endif
PSNIP_CLOCK__FUNCTION psnip_uint32_t psnip_clock_wall_get_precision(void) {
# if !defined(PSNIP_CLOCK_WALL_METHOD)
return 0;
# elif defined(PSNIP_CLOCK_WALL_METHOD) && \
PSNIP_CLOCK_WALL_METHOD == PSNIP_CLOCK_METHOD_CLOCK_GETTIME
return psnip_clock__clock_getres(PSNIP_CLOCK_CLOCK_GETTIME_WALL);
# elif defined(PSNIP_CLOCK_WALL_METHOD) && \
PSNIP_CLOCK_WALL_METHOD == PSNIP_CLOCK_METHOD_GETTIMEOFDAY
return 1000000;
# elif defined(PSNIP_CLOCK_WALL_METHOD) && \
PSNIP_CLOCK_WALL_METHOD == PSNIP_CLOCK_METHOD_TIME
return 1;
# else
return 0;
# endif
}
PSNIP_CLOCK__FUNCTION int
psnip_clock_wall_get_time(struct PsnipClockTimespec *res) {
# if !defined(PSNIP_CLOCK_WALL_METHOD)
(void)res;
return -2;
# elif defined(PSNIP_CLOCK_WALL_METHOD) && \
PSNIP_CLOCK_WALL_METHOD == PSNIP_CLOCK_METHOD_CLOCK_GETTIME
return psnip_clock__clock_gettime(PSNIP_CLOCK_CLOCK_GETTIME_WALL, res);
# elif defined(PSNIP_CLOCK_WALL_METHOD) && \
PSNIP_CLOCK_WALL_METHOD == PSNIP_CLOCK_METHOD_TIME
res->seconds = time(NULL);
res->nanoseconds = 0;
# elif defined(PSNIP_CLOCK_WALL_METHOD) && \
PSNIP_CLOCK_WALL_METHOD == PSNIP_CLOCK_METHOD_GETTIMEOFDAY
struct timeval tv;
if (gettimeofday(&tv, NULL) != 0)
return -6;
res->seconds = (psnip_uint64_t)tv.tv_sec;
res->nanoseconds = (psnip_uint64_t)tv.tv_usec * 1000;
# else
(void)res;
return -2;
# endif
return 0;
}
PSNIP_CLOCK__FUNCTION psnip_uint32_t psnip_clock_cpu_get_precision(void) {
# if !defined(PSNIP_CLOCK_CPU_METHOD)
return 0;
# elif defined(PSNIP_CLOCK_CPU_METHOD) && \
PSNIP_CLOCK_CPU_METHOD == PSNIP_CLOCK_METHOD_CLOCK_GETTIME
return psnip_clock__clock_getres(PSNIP_CLOCK_CLOCK_GETTIME_CPU);
# elif defined(PSNIP_CLOCK_CPU_METHOD) && \
PSNIP_CLOCK_CPU_METHOD == PSNIP_CLOCK_METHOD_CLOCK
return CLOCKS_PER_SEC;
# elif defined(PSNIP_CLOCK_CPU_METHOD) && \
PSNIP_CLOCK_CPU_METHOD == PSNIP_CLOCK_METHOD_GETPROCESSTIMES
return PSNIP_CLOCK_NSEC_PER_SEC / 100;
# else
return 0;
# endif
}
PSNIP_CLOCK__FUNCTION int
psnip_clock_cpu_get_time(struct PsnipClockTimespec *res) {
# if !defined(PSNIP_CLOCK_CPU_METHOD)
(void)res;
return -2;
# elif defined(PSNIP_CLOCK_CPU_METHOD) && \
PSNIP_CLOCK_CPU_METHOD == PSNIP_CLOCK_METHOD_CLOCK_GETTIME
return psnip_clock__clock_gettime(PSNIP_CLOCK_CLOCK_GETTIME_CPU, res);
# elif defined(PSNIP_CLOCK_CPU_METHOD) && \
PSNIP_CLOCK_CPU_METHOD == PSNIP_CLOCK_METHOD_CLOCK
clock_t t = clock();
if (t == ((clock_t)-1))
return -5;
res->seconds = t / CLOCKS_PER_SEC;
res->nanoseconds =
(t % CLOCKS_PER_SEC) * (PSNIP_CLOCK_NSEC_PER_SEC / CLOCKS_PER_SEC);
# elif defined(PSNIP_CLOCK_CPU_METHOD) && \
PSNIP_CLOCK_CPU_METHOD == PSNIP_CLOCK_METHOD_GETPROCESSTIMES
FILETIME CreationTime, ExitTime, KernelTime, UserTime;
LARGE_INTEGER date, adjust;
if (!GetProcessTimes(GetCurrentProcess(), &CreationTime, &ExitTime,
&KernelTime, &UserTime))
return -7;
date.HighPart = (LONG)UserTime.dwHighDateTime;
date.LowPart = UserTime.dwLowDateTime;
adjust.QuadPart = 11644473600000 * 10000;
date.QuadPart -= adjust.QuadPart;
res->seconds = (psnip_uint64_t)(date.QuadPart / 10000000);
res->nanoseconds = (psnip_uint64_t)(date.QuadPart % 10000000) *
(PSNIP_CLOCK_NSEC_PER_SEC / 100);
# elif PSNIP_CLOCK_CPU_METHOD == PSNIP_CLOCK_METHOD_GETRUSAGE
struct rusage usage;
if (getrusage(RUSAGE_SELF, &usage) != 0)
return -8;
res->seconds = usage.ru_utime.tv_sec;
res->nanoseconds = tv.tv_usec * 1000;
# else
(void)res;
return -2;
# endif
return 0;
}
PSNIP_CLOCK__FUNCTION psnip_uint32_t psnip_clock_monotonic_get_precision(void) {
# if !defined(PSNIP_CLOCK_MONOTONIC_METHOD)
return 0;
# elif defined(PSNIP_CLOCK_MONOTONIC_METHOD) && \
PSNIP_CLOCK_MONOTONIC_METHOD == PSNIP_CLOCK_METHOD_CLOCK_GETTIME
return psnip_clock__clock_getres(PSNIP_CLOCK_CLOCK_GETTIME_MONOTONIC);
# elif defined(PSNIP_CLOCK_MONOTONIC_METHOD) && \
PSNIP_CLOCK_MONOTONIC_METHOD == PSNIP_CLOCK_METHOD_MACH_ABSOLUTE_TIME
static mach_timebase_info_data_t tbi = {
0,
};
if (tbi.denom == 0)
mach_timebase_info(&tbi);
return (psnip_uint32_t)(tbi.numer / tbi.denom);
# elif defined(PSNIP_CLOCK_MONOTONIC_METHOD) && \
PSNIP_CLOCK_MONOTONIC_METHOD == PSNIP_CLOCK_METHOD_GETTICKCOUNT64
return 1000;
# elif defined(PSNIP_CLOCK_MONOTONIC_METHOD) && \
PSNIP_CLOCK_MONOTONIC_METHOD == \
PSNIP_CLOCK_METHOD_QUERYPERFORMANCECOUNTER
LARGE_INTEGER Frequency;
QueryPerformanceFrequency(&Frequency);
return (psnip_uint32_t)((Frequency.QuadPart > PSNIP_CLOCK_NSEC_PER_SEC)
? PSNIP_CLOCK_NSEC_PER_SEC
: Frequency.QuadPart);
# else
return 0;
# endif
}
PSNIP_CLOCK__FUNCTION int
psnip_clock_monotonic_get_time(struct PsnipClockTimespec *res) {
# if !defined(PSNIP_CLOCK_MONOTONIC_METHOD)
(void)res;
return -2;
# elif defined(PSNIP_CLOCK_MONOTONIC_METHOD) && \
PSNIP_CLOCK_MONOTONIC_METHOD == PSNIP_CLOCK_METHOD_CLOCK_GETTIME
return psnip_clock__clock_gettime(PSNIP_CLOCK_CLOCK_GETTIME_MONOTONIC, res);
# elif defined(PSNIP_CLOCK_MONOTONIC_METHOD) && \
PSNIP_CLOCK_MONOTONIC_METHOD == PSNIP_CLOCK_METHOD_MACH_ABSOLUTE_TIME
psnip_uint64_t nsec = mach_absolute_time();
static mach_timebase_info_data_t tbi = {
0,
};
if (tbi.denom == 0)
mach_timebase_info(&tbi);
nsec *= ((psnip_uint64_t)tbi.numer) / ((psnip_uint64_t)tbi.denom);
res->seconds = nsec / PSNIP_CLOCK_NSEC_PER_SEC;
res->nanoseconds = nsec % PSNIP_CLOCK_NSEC_PER_SEC;
# elif defined(PSNIP_CLOCK_MONOTONIC_METHOD) && \
PSNIP_CLOCK_MONOTONIC_METHOD == \
PSNIP_CLOCK_METHOD_QUERYPERFORMANCECOUNTER
LARGE_INTEGER t, f;
if (QueryPerformanceCounter(&t) == 0)
return -12;
QueryPerformanceFrequency(&f);
res->seconds = (psnip_uint64_t)(t.QuadPart / f.QuadPart);
res->nanoseconds = (psnip_uint64_t)(t.QuadPart % f.QuadPart);
if (f.QuadPart > PSNIP_CLOCK_NSEC_PER_SEC)
res->nanoseconds /= (psnip_uint64_t)f.QuadPart / PSNIP_CLOCK_NSEC_PER_SEC;
else
res->nanoseconds *= PSNIP_CLOCK_NSEC_PER_SEC / (psnip_uint64_t)f.QuadPart;
# elif defined(PSNIP_CLOCK_MONOTONIC_METHOD) && \
PSNIP_CLOCK_MONOTONIC_METHOD == PSNIP_CLOCK_METHOD_GETTICKCOUNT64
const ULONGLONG msec = GetTickCount64();
res->seconds = msec / 1000;
res->nanoseconds = sec % 1000;
# else
return -2;
# endif
return 0;
}
PSNIP_CLOCK__FUNCTION psnip_uint32_t
psnip_clock_get_precision(enum PsnipClockType clock_type) {
switch (clock_type) {
case PSNIP_CLOCK_TYPE_MONOTONIC:
return psnip_clock_monotonic_get_precision();
case PSNIP_CLOCK_TYPE_CPU:
return psnip_clock_cpu_get_precision();
case PSNIP_CLOCK_TYPE_WALL:
return psnip_clock_wall_get_precision();
}
PSNIP_CLOCK_UNREACHABLE();
return 0;
}
PSNIP_CLOCK__FUNCTION int psnip_clock_get_time(enum PsnipClockType clock_type,
struct PsnipClockTimespec *res) {
assert(res != NULL);
switch (clock_type) {
case PSNIP_CLOCK_TYPE_MONOTONIC:
return psnip_clock_monotonic_get_time(res);
case PSNIP_CLOCK_TYPE_CPU:
return psnip_clock_cpu_get_time(res);
case PSNIP_CLOCK_TYPE_WALL:
return psnip_clock_wall_get_time(res);
}
return -1;
}
# endif
static psnip_uint64_t munit_clock_get_elapsed(struct PsnipClockTimespec *start,
struct PsnipClockTimespec *end) {
psnip_uint64_t r = (end->seconds - start->seconds) * PSNIP_CLOCK_NSEC_PER_SEC;
if (end->nanoseconds < start->nanoseconds) {
return r - (start->nanoseconds - end->nanoseconds);
}
return r + (end->nanoseconds - start->nanoseconds);
}
#else
# include <time.h>
#endif
#if defined(__STDC_VERSION__) && (__STDC_VERSION__ >= 201112L) && \
!defined(__STDC_NO_ATOMICS__) && !defined(__EMSCRIPTEN__) && \
(!defined(__GNUC_MINOR__) || (__GNUC__ > 4) || \
(__GNUC__ == 4 && __GNUC_MINOR__ > 8))
# define HAVE_STDATOMIC
#elif defined(__clang__)
# if __has_extension(c_atomic)
# define HAVE_CLANG_ATOMICS
# endif
#endif
#if defined(__clang__) && defined(_WIN32)
# undef HAVE_STDATOMIC
# if defined(__c2__)
# undef HAVE_CLANG_ATOMICS
# endif
#endif
#if defined(_OPENMP)
# define ATOMIC_UINT32_T uint32_t
#elif defined(HAVE_STDATOMIC)
# include <stdatomic.h>
# define ATOMIC_UINT32_T _Atomic uint32_t
#elif defined(HAVE_CLANG_ATOMICS)
# define ATOMIC_UINT32_T _Atomic uint32_t
#elif defined(_WIN32)
# define ATOMIC_UINT32_T volatile LONG
#else
# define ATOMIC_UINT32_T volatile uint32_t
#endif
static ATOMIC_UINT32_T munit_rand_state = 42;
#if defined(_OPENMP)
static inline void munit_atomic_store(ATOMIC_UINT32_T *dest,
ATOMIC_UINT32_T value) {
# pragma omp critical(munit_atomics)
*dest = value;
}
static inline uint32_t munit_atomic_load(ATOMIC_UINT32_T *src) {
int ret;
# pragma omp critical(munit_atomics)
ret = *src;
return ret;
}
static inline uint32_t munit_atomic_cas(ATOMIC_UINT32_T *dest,
ATOMIC_UINT32_T *expected,
ATOMIC_UINT32_T desired) {
munit_bool ret;
# pragma omp critical(munit_atomics)
{
if (*dest == *expected) {
*dest = desired;
ret = 1;
} else {
ret = 0;
}
}
return ret;
}
#elif defined(HAVE_STDATOMIC)
# define munit_atomic_store(dest, value) atomic_store(dest, value)
# define munit_atomic_load(src) atomic_load(src)
# define munit_atomic_cas(dest, expected, value) \
atomic_compare_exchange_weak(dest, expected, value)
#elif defined(HAVE_CLANG_ATOMICS)
# define munit_atomic_store(dest, value) \
__c11_atomic_store(dest, value, __ATOMIC_SEQ_CST)
# define munit_atomic_load(src) __c11_atomic_load(src, __ATOMIC_SEQ_CST)
# define munit_atomic_cas(dest, expected, value) \
__c11_atomic_compare_exchange_weak(dest, expected, value, \
__ATOMIC_SEQ_CST, __ATOMIC_SEQ_CST)
#elif defined(__GNUC__) && (__GNUC__ > 4) || \
(__GNUC__ == 4 && __GNUC_MINOR__ >= 7)
# define munit_atomic_store(dest, value) \
__atomic_store_n(dest, value, __ATOMIC_SEQ_CST)
# define munit_atomic_load(src) __atomic_load_n(src, __ATOMIC_SEQ_CST)
# define munit_atomic_cas(dest, expected, value) \
__atomic_compare_exchange_n(dest, expected, value, 1, __ATOMIC_SEQ_CST, \
__ATOMIC_SEQ_CST)
#elif defined(__GNUC__) && (__GNUC__ >= 4)
# define munit_atomic_store(dest, value) \
do { \
*(dest) = (value); \
} while (0)
# define munit_atomic_load(src) (*(src))
# define munit_atomic_cas(dest, expected, value) \
__sync_bool_compare_and_swap(dest, *expected, value)
#elif defined(_WIN32)
# define munit_atomic_store(dest, value) \
do { \
*(dest) = (value); \
} while (0)
# define munit_atomic_load(src) (*(src))
# define munit_atomic_cas(dest, expected, value) \
InterlockedCompareExchange((dest), (value), *(expected))
#else
# warning No atomic implementation, PRNG will not be thread-safe
# define munit_atomic_store(dest, value) \
do { \
*(dest) = (value); \
} while (0)
# define munit_atomic_load(src) (*(src))
static inline munit_bool munit_atomic_cas(ATOMIC_UINT32_T *dest,
ATOMIC_UINT32_T *expected,
ATOMIC_UINT32_T desired) {
if (*dest == *expected) {
*dest = desired;
return 1;
} else {
return 0;
}
}
#endif
#define MUNIT_PRNG_MULTIPLIER (747796405U)
#define MUNIT_PRNG_INCREMENT (1729U)
static munit_uint32_t munit_rand_next_state(munit_uint32_t state) {
return state * MUNIT_PRNG_MULTIPLIER + MUNIT_PRNG_INCREMENT;
}
static munit_uint32_t munit_rand_from_state(munit_uint32_t state) {
munit_uint32_t res = ((state >> ((state >> 28) + 4)) ^ state) * (277803737U);
res ^= res >> 22;
return res;
}
void munit_rand_seed(munit_uint32_t seed) {
munit_uint32_t state = munit_rand_next_state(seed + MUNIT_PRNG_INCREMENT);
munit_atomic_store(&munit_rand_state, state);
}
static munit_uint32_t munit_rand_generate_seed(void) {
munit_uint32_t seed, state;
#if defined(MUNIT_ENABLE_TIMING)
struct PsnipClockTimespec wc = {
0,
};
psnip_clock_get_time(PSNIP_CLOCK_TYPE_WALL, &wc);
seed = (munit_uint32_t)wc.nanoseconds;
#else
seed = (munit_uint32_t)time(NULL);
#endif
state = munit_rand_next_state(seed + MUNIT_PRNG_INCREMENT);
return munit_rand_from_state(state);
}
static munit_uint32_t munit_rand_state_uint32(munit_uint32_t *state) {
const munit_uint32_t old = *state;
*state = munit_rand_next_state(old);
return munit_rand_from_state(old);
}
munit_uint32_t munit_rand_uint32(void) {
munit_uint32_t old, state;
do {
old = munit_atomic_load(&munit_rand_state);
state = munit_rand_next_state(old);
} while (!munit_atomic_cas(&munit_rand_state, &old, state));
return munit_rand_from_state(old);
}
static void munit_rand_state_memory(munit_uint32_t *state, size_t size,
munit_uint8_t *data) {
size_t members_remaining = size / sizeof(munit_uint32_t);
size_t bytes_remaining = size % sizeof(munit_uint32_t);
munit_uint8_t *b = data;
munit_uint32_t rv;
while (members_remaining-- > 0) {
rv = munit_rand_state_uint32(state);
memcpy(b, &rv, sizeof(munit_uint32_t));
b += sizeof(munit_uint32_t);
}
if (bytes_remaining != 0) {
rv = munit_rand_state_uint32(state);
memcpy(b, &rv, bytes_remaining);
}
}
void munit_rand_memory(size_t size, munit_uint8_t *data) {
munit_uint32_t old, state;
do {
state = old = munit_atomic_load(&munit_rand_state);
munit_rand_state_memory(&state, size, data);
} while (!munit_atomic_cas(&munit_rand_state, &old, state));
}
static munit_uint32_t munit_rand_state_at_most(munit_uint32_t *state,
munit_uint32_t salt,
munit_uint32_t max) {
const munit_uint32_t min = (~max + 1U) % max;
munit_uint32_t x;
if (max == (~((munit_uint32_t)0U)))
return munit_rand_state_uint32(state) ^ salt;
max++;
do {
x = munit_rand_state_uint32(state) ^ salt;
} while (x < min);
return x % max;
}
static munit_uint32_t munit_rand_at_most(munit_uint32_t salt,
munit_uint32_t max) {
munit_uint32_t old, state;
munit_uint32_t retval;
do {
state = old = munit_atomic_load(&munit_rand_state);
retval = munit_rand_state_at_most(&state, salt, max);
} while (!munit_atomic_cas(&munit_rand_state, &old, state));
return retval;
}
int munit_rand_int_range(int min, int max) {
munit_uint64_t range = (munit_uint64_t)max - (munit_uint64_t)min;
if (min > max)
return munit_rand_int_range(max, min);
if (range > (~((munit_uint32_t)0U)))
range = (~((munit_uint32_t)0U));
return min + (int)munit_rand_at_most(0, (munit_uint32_t)range);
}
double munit_rand_double(void) {
munit_uint32_t old, state;
double retval = 0.0;
do {
state = old = munit_atomic_load(&munit_rand_state);
retval = munit_rand_state_uint32(&state) / ((~((munit_uint32_t)0U)) + 1.0);
} while (!munit_atomic_cas(&munit_rand_state, &old, state));
return retval;
}
typedef struct {
unsigned int successful;
unsigned int skipped;
unsigned int failed;
unsigned int errored;
#if defined(MUNIT_ENABLE_TIMING)
munit_uint64_t cpu_clock;
munit_uint64_t wall_clock;
#endif
} MunitReport;
typedef struct {
const char *prefix;
const MunitSuite *suite;
const char **tests;
munit_uint32_t seed;
unsigned int iterations;
MunitParameter *parameters;
munit_bool single_parameter_mode;
void *user_data;
MunitReport report;
munit_bool colorize;
munit_bool fork;
munit_bool show_stderr;
munit_bool fatal_failures;
} MunitTestRunner;
const char *munit_parameters_get(const MunitParameter params[],
const char *key) {
const MunitParameter *param;
for (param = params; param != NULL && param->name != NULL; param++)
if (strcmp(param->name, key) == 0)
return param->value;
return NULL;
}
#if defined(MUNIT_ENABLE_TIMING)
static void munit_print_time(FILE *fp, munit_uint64_t nanoseconds) {
fprintf(fp, "%" MUNIT_TEST_TIME_FORMAT,
((double)nanoseconds) / ((double)PSNIP_CLOCK_NSEC_PER_SEC));
}
#endif
static MunitResult munit_parameters_add(size_t *params_size,
MunitParameter **params, char *name,
char *value) {
*params = realloc(*params, sizeof(MunitParameter) * (*params_size + 2));
if (*params == NULL)
return MUNIT_ERROR;
(*params)[*params_size].name = name;
(*params)[*params_size].value = value;
(*params_size)++;
(*params)[*params_size].name = NULL;
(*params)[*params_size].value = NULL;
return MUNIT_OK;
}
static char *munit_maybe_concat(size_t *len, char *prefix, char *suffix) {
char *res;
size_t res_l;
const size_t prefix_l = prefix != NULL ? strlen(prefix) : 0;
const size_t suffix_l = suffix != NULL ? strlen(suffix) : 0;
if (prefix_l == 0 && suffix_l == 0) {
res = NULL;
res_l = 0;
} else if (prefix_l == 0 && suffix_l != 0) {
res = suffix;
res_l = suffix_l;
} else if (prefix_l != 0 && suffix_l == 0) {
res = prefix;
res_l = prefix_l;
} else {
res_l = prefix_l + suffix_l;
res = malloc(res_l + 1);
memcpy(res, prefix, prefix_l);
memcpy(res + prefix_l, suffix, suffix_l);
res[res_l] = 0;
}
if (len != NULL)
*len = res_l;
return res;
}
static void munit_maybe_free_concat(char *s, const char *prefix,
const char *suffix) {
if (prefix != s && suffix != s)
free(s);
}
static munit_uint32_t munit_str_hash(const char *name) {
const char *p;
munit_uint32_t h = 5381U;
for (p = name; *p != '\0'; p++)
h = (munit_uint32_t)(h << 5) + h + (munit_uint32_t)*p;
return h;
}
static void munit_splice(int from, int to) {
munit_uint8_t buf[1024];
#if !defined(_WIN32)
ssize_t len;
ssize_t bytes_written;
ssize_t write_res;
#else
int len;
int bytes_written;
int write_res;
#endif
do {
len = read(from, buf, sizeof(buf));
if (len > 0) {
bytes_written = 0;
do {
write_res = write(to, buf + bytes_written,
#if !defined(_WIN32)
(size_t)
#else
(unsigned int)
#endif
(len - bytes_written));
if (write_res < 0)
break;
bytes_written += write_res;
} while (bytes_written < len);
} else
break;
} while (1);
}
static MunitResult munit_test_runner_exec(MunitTestRunner *runner,
const MunitTest *test,
const MunitParameter params[],
MunitReport *report) {
unsigned int iterations = runner->iterations;
MunitResult result = MUNIT_FAIL;
#if defined(MUNIT_ENABLE_TIMING)
struct PsnipClockTimespec wall_clock_begin =
{
0,
},
wall_clock_end = {
0,
};
struct PsnipClockTimespec cpu_clock_begin =
{
0,
},
cpu_clock_end = {
0,
};
#endif
unsigned int i = 0;
if ((test->options & MUNIT_TEST_OPTION_SINGLE_ITERATION) ==
MUNIT_TEST_OPTION_SINGLE_ITERATION)
iterations = 1;
else if (iterations == 0)
iterations = runner->suite->iterations;
munit_rand_seed(runner->seed);
do {
void *data = (test->setup == NULL) ? runner->user_data
: test->setup(params, runner->user_data);
#if defined(MUNIT_ENABLE_TIMING)
psnip_clock_get_time(PSNIP_CLOCK_TYPE_WALL, &wall_clock_begin);
psnip_clock_get_time(PSNIP_CLOCK_TYPE_CPU, &cpu_clock_begin);
#endif
result = test->test(params, data);
#if defined(MUNIT_ENABLE_TIMING)
psnip_clock_get_time(PSNIP_CLOCK_TYPE_WALL, &wall_clock_end);
psnip_clock_get_time(PSNIP_CLOCK_TYPE_CPU, &cpu_clock_end);
#endif
if (test->tear_down != NULL)
test->tear_down(data);
if (MUNIT_LIKELY(result == MUNIT_OK)) {
report->successful++;
#if defined(MUNIT_ENABLE_TIMING)
report->wall_clock +=
munit_clock_get_elapsed(&wall_clock_begin, &wall_clock_end);
report->cpu_clock +=
munit_clock_get_elapsed(&cpu_clock_begin, &cpu_clock_end);
#endif
} else {
switch ((int)result) {
case MUNIT_SKIP:
report->skipped++;
break;
case MUNIT_FAIL:
report->failed++;
break;
case MUNIT_ERROR:
report->errored++;
break;
default:
break;
}
break;
}
} while (++i < iterations);
return result;
}
#if defined(MUNIT_EMOTICON)
# define MUNIT_RESULT_STRING_OK ":)"
# define MUNIT_RESULT_STRING_SKIP ":|"
# define MUNIT_RESULT_STRING_FAIL ":("
# define MUNIT_RESULT_STRING_ERROR ":o"
# define MUNIT_RESULT_STRING_TODO ":/"
#else
# define MUNIT_RESULT_STRING_OK "OK "
# define MUNIT_RESULT_STRING_SKIP "SKIP "
# define MUNIT_RESULT_STRING_FAIL "FAIL "
# define MUNIT_RESULT_STRING_ERROR "ERROR"
# define MUNIT_RESULT_STRING_TODO "TODO "
#endif
static void munit_test_runner_print_color(const MunitTestRunner *runner,
const char *string, char color) {
if (runner->colorize)
fprintf(MUNIT_OUTPUT_FILE, "\x1b[3%cm%s\x1b[39m", color, string);
else
fputs(string, MUNIT_OUTPUT_FILE);
}
#if !defined(MUNIT_NO_BUFFER)
static int munit_replace_stderr(FILE *stderr_buf) {
if (stderr_buf != NULL) {
const int orig_stderr = dup(STDERR_FILENO);
int errfd = fileno(stderr_buf);
if (MUNIT_UNLIKELY(errfd == -1)) {
exit(EXIT_FAILURE);
}
dup2(errfd, STDERR_FILENO);
return orig_stderr;
}
return -1;
}
static void munit_restore_stderr(int orig_stderr) {
if (orig_stderr != -1) {
dup2(orig_stderr, STDERR_FILENO);
close(orig_stderr);
}
}
#endif
static void
munit_test_runner_run_test_with_params(MunitTestRunner *runner,
const MunitTest *test,
const MunitParameter params[]) {
MunitResult result = MUNIT_OK;
MunitReport report = {0, 0, 0, 0,
#if defined(MUNIT_ENABLE_TIMING)
0, 0
#endif
};
unsigned int output_l;
munit_bool first;
const MunitParameter *param;
FILE *stderr_buf;
#if !defined(MUNIT_NO_FORK)
int pipefd[2];
pid_t fork_pid;
ssize_t bytes_written = 0;
ssize_t write_res;
ssize_t bytes_read = 0;
ssize_t read_res;
int status = 0;
pid_t changed_pid;
#endif
if (params != NULL) {
output_l = 2;
fputs(" ", MUNIT_OUTPUT_FILE);
first = 1;
for (param = params; param != NULL && param->name != NULL; param++) {
if (!first) {
fputs(", ", MUNIT_OUTPUT_FILE);
output_l += 2;
} else {
first = 0;
}
output_l += (unsigned int)fprintf(MUNIT_OUTPUT_FILE, "%s=%s", param->name,
param->value);
}
while (output_l++ < MUNIT_TEST_NAME_LEN) {
fputc(' ', MUNIT_OUTPUT_FILE);
}
}
fflush(MUNIT_OUTPUT_FILE);
stderr_buf = NULL;
#if !defined(_WIN32) || defined(__MINGW32__)
stderr_buf = tmpfile();
#else
tmpfile_s(&stderr_buf);
#endif
if (stderr_buf == NULL) {
munit_log_errno(MUNIT_LOG_ERROR, stderr,
"unable to create buffer for stderr");
result = MUNIT_ERROR;
goto print_result;
}
#if !defined(MUNIT_NO_FORK)
if (runner->fork) {
pipefd[0] = -1;
pipefd[1] = -1;
if (pipe(pipefd) != 0) {
munit_log_errno(MUNIT_LOG_ERROR, stderr, "unable to create pipe");
result = MUNIT_ERROR;
goto print_result;
}
fork_pid = fork();
if (fork_pid == 0) {
int orig_stderr;
close(pipefd[0]);
orig_stderr = munit_replace_stderr(stderr_buf);
munit_test_runner_exec(runner, test, params, &report);
close(orig_stderr);
do {
write_res =
write(pipefd[1], ((munit_uint8_t *)(&report)) + bytes_written,
sizeof(report) - (size_t)bytes_written);
if (write_res < 0) {
if (stderr_buf != NULL) {
munit_log_errno(MUNIT_LOG_ERROR, stderr, "unable to write to pipe");
}
exit(EXIT_FAILURE);
}
bytes_written += write_res;
} while ((size_t)bytes_written < sizeof(report));
if (stderr_buf != NULL)
fclose(stderr_buf);
close(pipefd[1]);
exit(EXIT_SUCCESS);
} else if (fork_pid == -1) {
close(pipefd[0]);
close(pipefd[1]);
if (stderr_buf != NULL) {
munit_log_errno(MUNIT_LOG_ERROR, stderr, "unable to fork");
}
report.errored++;
result = MUNIT_ERROR;
} else {
close(pipefd[1]);
do {
read_res = read(pipefd[0], ((munit_uint8_t *)(&report)) + bytes_read,
sizeof(report) - (size_t)bytes_read);
if (read_res < 1)
break;
bytes_read += read_res;
} while (bytes_read < (ssize_t)sizeof(report));
changed_pid = waitpid(fork_pid, &status, 0);
if (MUNIT_LIKELY(changed_pid == fork_pid) &&
MUNIT_LIKELY(WIFEXITED(status))) {
if (bytes_read != sizeof(report)) {
munit_logf_internal(MUNIT_LOG_ERROR, stderr_buf,
"child exited unexpectedly with status %d",
WEXITSTATUS(status));
report.errored++;
} else if (WEXITSTATUS(status) != EXIT_SUCCESS) {
munit_logf_internal(MUNIT_LOG_ERROR, stderr_buf,
"child exited with status %d",
WEXITSTATUS(status));
report.errored++;
}
} else {
if (WIFSIGNALED(status)) {
# if defined(_XOPEN_VERSION) && (_XOPEN_VERSION >= 700)
munit_logf_internal(MUNIT_LOG_ERROR, stderr_buf,
"child killed by signal %d (%s)",
WTERMSIG(status), strsignal(WTERMSIG(status)));
# else
munit_logf_internal(MUNIT_LOG_ERROR, stderr_buf,
"child killed by signal %d", WTERMSIG(status));
# endif
} else if (WIFSTOPPED(status)) {
munit_logf_internal(MUNIT_LOG_ERROR, stderr_buf,
"child stopped by signal %d", WSTOPSIG(status));
}
report.errored++;
}
close(pipefd[0]);
waitpid(fork_pid, NULL, 0);
}
} else
#endif
{
#if !defined(MUNIT_NO_BUFFER)
const volatile int orig_stderr = munit_replace_stderr(stderr_buf);
#endif
#if defined(MUNIT_THREAD_LOCAL)
if (MUNIT_UNLIKELY(setjmp(munit_error_jmp_buf) != 0)) {
result = MUNIT_FAIL;
report.failed++;
} else {
munit_error_jmp_buf_valid = 1;
result = munit_test_runner_exec(runner, test, params, &report);
}
#else
result = munit_test_runner_exec(runner, test, params, &report);
#endif
#if !defined(MUNIT_NO_BUFFER)
munit_restore_stderr(orig_stderr);
#endif
goto print_result;
}
print_result:
fputs("[ ", MUNIT_OUTPUT_FILE);
if ((test->options & MUNIT_TEST_OPTION_TODO) == MUNIT_TEST_OPTION_TODO) {
if (report.failed != 0 || report.errored != 0 || report.skipped != 0) {
munit_test_runner_print_color(runner, MUNIT_RESULT_STRING_TODO, '3');
result = MUNIT_OK;
} else {
munit_test_runner_print_color(runner, MUNIT_RESULT_STRING_ERROR, '1');
if (MUNIT_LIKELY(stderr_buf != NULL))
munit_log_internal(MUNIT_LOG_ERROR, stderr_buf,
"Test marked TODO, but was successful.");
runner->report.failed++;
result = MUNIT_ERROR;
}
} else if (report.failed > 0) {
munit_test_runner_print_color(runner, MUNIT_RESULT_STRING_FAIL, '1');
runner->report.failed++;
result = MUNIT_FAIL;
} else if (report.errored > 0) {
munit_test_runner_print_color(runner, MUNIT_RESULT_STRING_ERROR, '1');
runner->report.errored++;
result = MUNIT_ERROR;
} else if (report.skipped > 0) {
munit_test_runner_print_color(runner, MUNIT_RESULT_STRING_SKIP, '3');
runner->report.skipped++;
result = MUNIT_SKIP;
} else if (report.successful > 1) {
munit_test_runner_print_color(runner, MUNIT_RESULT_STRING_OK, '2');
#if defined(MUNIT_ENABLE_TIMING)
fputs(" ] [ ", MUNIT_OUTPUT_FILE);
munit_print_time(MUNIT_OUTPUT_FILE, report.wall_clock / report.successful);
fputs(" / ", MUNIT_OUTPUT_FILE);
munit_print_time(MUNIT_OUTPUT_FILE, report.cpu_clock / report.successful);
fprintf(MUNIT_OUTPUT_FILE,
" CPU ]\n %-" MUNIT_XSTRINGIFY(MUNIT_TEST_NAME_LEN) "s Total: [ ",
"");
munit_print_time(MUNIT_OUTPUT_FILE, report.wall_clock);
fputs(" / ", MUNIT_OUTPUT_FILE);
munit_print_time(MUNIT_OUTPUT_FILE, report.cpu_clock);
fputs(" CPU", MUNIT_OUTPUT_FILE);
#endif
runner->report.successful++;
result = MUNIT_OK;
} else if (report.successful > 0) {
munit_test_runner_print_color(runner, MUNIT_RESULT_STRING_OK, '2');
#if defined(MUNIT_ENABLE_TIMING)
fputs(" ] [ ", MUNIT_OUTPUT_FILE);
munit_print_time(MUNIT_OUTPUT_FILE, report.wall_clock);
fputs(" / ", MUNIT_OUTPUT_FILE);
munit_print_time(MUNIT_OUTPUT_FILE, report.cpu_clock);
fputs(" CPU", MUNIT_OUTPUT_FILE);
#endif
runner->report.successful++;
result = MUNIT_OK;
}
fputs(" ]\n", MUNIT_OUTPUT_FILE);
if (stderr_buf != NULL) {
if (result == MUNIT_FAIL || result == MUNIT_ERROR || runner->show_stderr) {
fflush(MUNIT_OUTPUT_FILE);
rewind(stderr_buf);
munit_splice(fileno(stderr_buf), STDERR_FILENO);
fflush(stderr);
}
fclose(stderr_buf);
}
}
static void munit_test_runner_run_test_wild(MunitTestRunner *runner,
const MunitTest *test,
const char *test_name,
MunitParameter *params,
MunitParameter *p) {
const MunitParameterEnum *pe;
char **values;
MunitParameter *next;
for (pe = test->parameters; pe != NULL && pe->name != NULL; pe++) {
if (p->name == pe->name)
break;
}
if (pe == NULL)
return;
for (values = pe->values; *values != NULL; values++) {
next = p + 1;
p->value = *values;
if (next->name == NULL) {
munit_test_runner_run_test_with_params(runner, test, params);
} else {
munit_test_runner_run_test_wild(runner, test, test_name, params, next);
}
if (runner->fatal_failures &&
(runner->report.failed != 0 || runner->report.errored != 0))
break;
}
}
static void munit_test_runner_run_test(MunitTestRunner *runner,
const MunitTest *test,
const char *prefix) {
char *test_name =
munit_maybe_concat(NULL, (char *)prefix, (char *)test->name);
MunitParameter *params = NULL;
size_t params_l = 0;
MunitParameter *wild_params = NULL;
size_t wild_params_l = 0;
const MunitParameterEnum *pe;
const MunitParameter *cli_p;
munit_bool filled;
unsigned int possible;
char **vals;
size_t first_wild;
const MunitParameter *wp;
int pidx;
munit_rand_seed(runner->seed);
fprintf(MUNIT_OUTPUT_FILE, "%-" MUNIT_XSTRINGIFY(MUNIT_TEST_NAME_LEN) "s",
test_name);
if (test->parameters == NULL) {
munit_test_runner_run_test_with_params(runner, test, NULL);
} else {
fputc('\n', MUNIT_OUTPUT_FILE);
for (pe = test->parameters; pe != NULL && pe->name != NULL; pe++) {
filled = 0;
for (cli_p = runner->parameters; cli_p != NULL && cli_p->name != NULL;
cli_p++) {
if (strcmp(cli_p->name, pe->name) == 0) {
if (MUNIT_UNLIKELY(munit_parameters_add(¶ms_l, ¶ms, pe->name,
cli_p->value) != MUNIT_OK))
goto cleanup;
filled = 1;
break;
}
}
if (filled)
continue;
if (pe->values == NULL || pe->values[0] == NULL)
continue;
if (runner->single_parameter_mode) {
possible = 0;
for (vals = pe->values; *vals != NULL; vals++)
possible++;
pidx = (int)munit_rand_at_most(munit_str_hash(test_name), possible - 1);
if (MUNIT_UNLIKELY(munit_parameters_add(¶ms_l, ¶ms, pe->name,
pe->values[pidx]) != MUNIT_OK))
goto cleanup;
} else {
if (MUNIT_UNLIKELY(munit_parameters_add(&wild_params_l, &wild_params,
pe->name, NULL) != MUNIT_OK))
goto cleanup;
}
}
if (wild_params_l != 0) {
first_wild = params_l;
for (wp = wild_params; wp != NULL && wp->name != NULL; wp++) {
for (pe = test->parameters;
pe != NULL && pe->name != NULL && pe->values != NULL; pe++) {
if (strcmp(wp->name, pe->name) == 0) {
if (MUNIT_UNLIKELY(munit_parameters_add(¶ms_l, ¶ms,
pe->name,
pe->values[0]) != MUNIT_OK))
goto cleanup;
}
}
}
munit_test_runner_run_test_wild(runner, test, test_name, params,
params + first_wild);
} else {
munit_test_runner_run_test_with_params(runner, test, params);
}
cleanup:
free(params);
free(wild_params);
}
munit_maybe_free_concat(test_name, prefix, test->name);
}
static void munit_test_runner_run_suite(MunitTestRunner *runner,
const MunitSuite *suite,
const char *prefix) {
size_t pre_l;
char *pre = munit_maybe_concat(&pre_l, (char *)prefix, (char *)suite->prefix);
const MunitTest *test;
const char **test_name;
const MunitSuite *child_suite;
for (test = suite->tests; test != NULL && test->test != NULL; test++) {
if (runner->tests != NULL) {
for (test_name = runner->tests; test_name != NULL && *test_name != NULL;
test_name++) {
if ((pre_l == 0 || strncmp(pre, *test_name, pre_l) == 0) &&
strncmp(test->name, *test_name + pre_l,
strlen(*test_name + pre_l)) == 0) {
munit_test_runner_run_test(runner, test, pre);
if (runner->fatal_failures &&
(runner->report.failed != 0 || runner->report.errored != 0))
goto cleanup;
}
}
} else {
munit_test_runner_run_test(runner, test, pre);
}
}
if (runner->fatal_failures &&
(runner->report.failed != 0 || runner->report.errored != 0))
goto cleanup;
for (child_suite = suite->suites;
child_suite != NULL && child_suite->prefix != NULL; child_suite++) {
munit_test_runner_run_suite(runner, child_suite, pre);
}
cleanup:
munit_maybe_free_concat(pre, prefix, suite->prefix);
}
static void munit_test_runner_run(MunitTestRunner *runner) {
munit_test_runner_run_suite(runner, runner->suite, NULL);
}
static void munit_print_help(int argc, char *const *argv, void *user_data,
const MunitArgument arguments[]) {
const MunitArgument *arg;
(void)argc;
printf("USAGE: %s [OPTIONS...] [TEST...]\n\n", argv[0]);
puts(
" --seed SEED\n"
" Value used to seed the PRNG. Must be a 32-bit integer in "
"decimal\n"
" notation with no separators (commas, decimals, spaces, "
"etc.), or\n"
" hexidecimal prefixed by \"0x\".\n"
" --iterations N\n"
" Run each test N times. 0 means the default number.\n"
" --param name value\n"
" A parameter key/value pair which will be passed to any test "
"with\n"
" takes a parameter of that name. If not provided, the test "
"will be\n"
" run once for each possible parameter value.\n"
" --list Write a list of all available tests.\n"
" --list-params\n"
" Write a list of all available tests and their possible "
"parameters.\n"
" --single Run each parameterized test in a single configuration "
"instead of\n"
" every possible combination\n"
" --log-visible debug|info|warning|error\n"
" --log-fatal debug|info|warning|error\n"
" Set the level at which messages of different severities are "
"visible,\n"
" or cause the test to terminate.\n"
#if !defined(MUNIT_NO_FORK)
" --no-fork Do not execute tests in a child process. If this option is "
"supplied\n"
" and a test crashes (including by failing an assertion), no "
"further\n"
" tests will be performed.\n"
#endif
" --fatal-failures\n"
" Stop executing tests as soon as a failure is found.\n"
" --show-stderr\n"
" Show data written to stderr by the tests, even if the test "
"succeeds.\n"
" --color auto|always|never\n"
" Colorize (or don't) the output.\n"
" --help Print this help message and exit.\n");
#if defined(MUNIT_NL_LANGINFO)
setlocale(LC_ALL, "");
fputs((strcasecmp("UTF-8", nl_langinfo(CODESET)) == 0) ? "µnit" : "munit",
stdout);
#else
puts("munit");
#endif
printf(" %d.%d.%d\n"
"Full documentation at: https://nemequ.github.io/munit/\n",
(MUNIT_CURRENT_VERSION >> 16) & 0xff,
(MUNIT_CURRENT_VERSION >> 8) & 0xff,
(MUNIT_CURRENT_VERSION >> 0) & 0xff);
for (arg = arguments; arg != NULL && arg->name != NULL; arg++)
arg->write_help(arg, user_data);
}
static const MunitArgument *
munit_arguments_find(const MunitArgument arguments[], const char *name) {
const MunitArgument *arg;
for (arg = arguments; arg != NULL && arg->name != NULL; arg++)
if (strcmp(arg->name, name) == 0)
return arg;
return NULL;
}
static void munit_suite_list_tests(const MunitSuite *suite,
munit_bool show_params, const char *prefix) {
size_t pre_l;
char *pre = munit_maybe_concat(&pre_l, (char *)prefix, (char *)suite->prefix);
const MunitTest *test;
const MunitParameterEnum *params;
munit_bool first;
char **val;
const MunitSuite *child_suite;
for (test = suite->tests; test != NULL && test->name != NULL; test++) {
if (pre != NULL)
fputs(pre, stdout);
puts(test->name);
if (show_params) {
for (params = test->parameters; params != NULL && params->name != NULL;
params++) {
fprintf(stdout, " - %s: ", params->name);
if (params->values == NULL) {
puts("Any");
} else {
first = 1;
for (val = params->values; *val != NULL; val++) {
if (!first) {
fputs(", ", stdout);
} else {
first = 0;
}
fputs(*val, stdout);
}
putc('\n', stdout);
}
}
}
}
for (child_suite = suite->suites;
child_suite != NULL && child_suite->prefix != NULL; child_suite++) {
munit_suite_list_tests(child_suite, show_params, pre);
}
munit_maybe_free_concat(pre, prefix, suite->prefix);
}
static munit_bool munit_stream_supports_ansi(FILE *stream) {
#if !defined(_WIN32)
return isatty(fileno(stream));
#else
# if !defined(__MINGW32__)
size_t ansicon_size = 0;
# endif
if (isatty(fileno(stream))) {
# if !defined(__MINGW32__)
getenv_s(&ansicon_size, NULL, 0, "ANSICON");
return ansicon_size != 0;
# else
return getenv("ANSICON") != NULL;
# endif
}
return 0;
#endif
}
int munit_suite_main_custom(const MunitSuite *suite, void *user_data, int argc,
char *const *argv,
const MunitArgument arguments[]) {
int result = EXIT_FAILURE;
MunitTestRunner runner;
size_t parameters_size = 0;
size_t tests_size = 0;
int arg;
char *envptr;
unsigned long ts;
char *endptr;
unsigned long long iterations;
MunitLogLevel level;
const MunitArgument *argument;
const char **runner_tests;
unsigned int tests_run;
unsigned int tests_total;
runner.prefix = NULL;
runner.suite = NULL;
runner.tests = NULL;
runner.seed = 0;
runner.iterations = 0;
runner.parameters = NULL;
runner.single_parameter_mode = 0;
runner.user_data = NULL;
runner.report.successful = 0;
runner.report.skipped = 0;
runner.report.failed = 0;
runner.report.errored = 0;
#if defined(MUNIT_ENABLE_TIMING)
runner.report.cpu_clock = 0;
runner.report.wall_clock = 0;
#endif
runner.colorize = 0;
#if !defined(_WIN32)
runner.fork = 1;
#else
runner.fork = 0;
#endif
runner.show_stderr = 0;
runner.fatal_failures = 0;
runner.suite = suite;
runner.user_data = user_data;
runner.seed = munit_rand_generate_seed();
runner.colorize = munit_stream_supports_ansi(MUNIT_OUTPUT_FILE);
for (arg = 1; arg < argc; arg++) {
if (strncmp("--", argv[arg], 2) == 0) {
if (strcmp("seed", argv[arg] + 2) == 0) {
if (arg + 1 >= argc) {
munit_logf_internal(MUNIT_LOG_ERROR, stderr,
"%s requires an argument", argv[arg]);
goto cleanup;
}
envptr = argv[arg + 1];
ts = strtoul(argv[arg + 1], &envptr, 0);
if (*envptr != '\0' || ts > (~((munit_uint32_t)0U))) {
munit_logf_internal(MUNIT_LOG_ERROR, stderr,
"invalid value ('%s') passed to %s",
argv[arg + 1], argv[arg]);
goto cleanup;
}
runner.seed = (munit_uint32_t)ts;
arg++;
} else if (strcmp("iterations", argv[arg] + 2) == 0) {
if (arg + 1 >= argc) {
munit_logf_internal(MUNIT_LOG_ERROR, stderr,
"%s requires an argument", argv[arg]);
goto cleanup;
}
endptr = argv[arg + 1];
iterations = strtoul(argv[arg + 1], &endptr, 0);
if (*endptr != '\0' || iterations > UINT_MAX) {
munit_logf_internal(MUNIT_LOG_ERROR, stderr,
"invalid value ('%s') passed to %s",
argv[arg + 1], argv[arg]);
goto cleanup;
}
runner.iterations = (unsigned int)iterations;
arg++;
} else if (strcmp("param", argv[arg] + 2) == 0) {
if (arg + 2 >= argc) {
munit_logf_internal(MUNIT_LOG_ERROR, stderr,
"%s requires two arguments", argv[arg]);
goto cleanup;
}
runner.parameters = realloc(runner.parameters, sizeof(MunitParameter) *
(parameters_size + 2));
if (runner.parameters == NULL) {
munit_log_internal(MUNIT_LOG_ERROR, stderr,
"failed to allocate memory");
goto cleanup;
}
runner.parameters[parameters_size].name = (char *)argv[arg + 1];
runner.parameters[parameters_size].value = (char *)argv[arg + 2];
parameters_size++;
runner.parameters[parameters_size].name = NULL;
runner.parameters[parameters_size].value = NULL;
arg += 2;
} else if (strcmp("color", argv[arg] + 2) == 0) {
if (arg + 1 >= argc) {
munit_logf_internal(MUNIT_LOG_ERROR, stderr,
"%s requires an argument", argv[arg]);
goto cleanup;
}
if (strcmp(argv[arg + 1], "always") == 0)
runner.colorize = 1;
else if (strcmp(argv[arg + 1], "never") == 0)
runner.colorize = 0;
else if (strcmp(argv[arg + 1], "auto") == 0)
runner.colorize = munit_stream_supports_ansi(MUNIT_OUTPUT_FILE);
else {
munit_logf_internal(MUNIT_LOG_ERROR, stderr,
"invalid value ('%s') passed to %s",
argv[arg + 1], argv[arg]);
goto cleanup;
}
arg++;
} else if (strcmp("help", argv[arg] + 2) == 0) {
munit_print_help(argc, argv, user_data, arguments);
result = EXIT_SUCCESS;
goto cleanup;
} else if (strcmp("single", argv[arg] + 2) == 0) {
runner.single_parameter_mode = 1;
} else if (strcmp("show-stderr", argv[arg] + 2) == 0) {
runner.show_stderr = 1;
#if !defined(_WIN32)
} else if (strcmp("no-fork", argv[arg] + 2) == 0) {
runner.fork = 0;
#endif
} else if (strcmp("fatal-failures", argv[arg] + 2) == 0) {
runner.fatal_failures = 1;
} else if (strcmp("log-visible", argv[arg] + 2) == 0 ||
strcmp("log-fatal", argv[arg] + 2) == 0) {
if (arg + 1 >= argc) {
munit_logf_internal(MUNIT_LOG_ERROR, stderr,
"%s requires an argument", argv[arg]);
goto cleanup;
}
if (strcmp(argv[arg + 1], "debug") == 0)
level = MUNIT_LOG_DEBUG;
else if (strcmp(argv[arg + 1], "info") == 0)
level = MUNIT_LOG_INFO;
else if (strcmp(argv[arg + 1], "warning") == 0)
level = MUNIT_LOG_WARNING;
else if (strcmp(argv[arg + 1], "error") == 0)
level = MUNIT_LOG_ERROR;
else {
munit_logf_internal(MUNIT_LOG_ERROR, stderr,
"invalid value ('%s') passed to %s",
argv[arg + 1], argv[arg]);
goto cleanup;
}
if (strcmp("log-visible", argv[arg] + 2) == 0)
munit_log_level_visible = level;
else
munit_log_level_fatal = level;
arg++;
} else if (strcmp("list", argv[arg] + 2) == 0) {
munit_suite_list_tests(suite, 0, NULL);
result = EXIT_SUCCESS;
goto cleanup;
} else if (strcmp("list-params", argv[arg] + 2) == 0) {
munit_suite_list_tests(suite, 1, NULL);
result = EXIT_SUCCESS;
goto cleanup;
} else {
argument = munit_arguments_find(arguments, argv[arg] + 2);
if (argument == NULL) {
munit_logf_internal(MUNIT_LOG_ERROR, stderr,
"unknown argument ('%s')", argv[arg]);
goto cleanup;
}
if (!argument->parse_argument(suite, user_data, &arg, argc, argv))
goto cleanup;
}
} else {
runner_tests =
realloc((void *)runner.tests, sizeof(char *) * (tests_size + 2));
if (runner_tests == NULL) {
munit_log_internal(MUNIT_LOG_ERROR, stderr,
"failed to allocate memory");
goto cleanup;
}
runner.tests = runner_tests;
runner.tests[tests_size++] = argv[arg];
runner.tests[tests_size] = NULL;
}
}
fflush(stderr);
fprintf(MUNIT_OUTPUT_FILE,
"Running test suite with seed 0x%08" PRIx32 "...\n", runner.seed);
munit_test_runner_run(&runner);
tests_run =
runner.report.successful + runner.report.failed + runner.report.errored;
tests_total = tests_run + runner.report.skipped;
if (tests_run == 0) {
fprintf(stderr, "No tests run, %d (100%%) skipped.\n",
runner.report.skipped);
} else {
fprintf(MUNIT_OUTPUT_FILE,
"%d of %d (%0.0f%%) tests successful, %d (%0.0f%%) test skipped.\n",
runner.report.successful, tests_run,
(((double)runner.report.successful) / ((double)tests_run)) * 100.0,
runner.report.skipped,
(((double)runner.report.skipped) / ((double)tests_total)) * 100.0);
}
if (runner.report.failed == 0 && runner.report.errored == 0) {
result = EXIT_SUCCESS;
}
cleanup:
free(runner.parameters);
free((void *)runner.tests);
return result;
}
int munit_suite_main(const MunitSuite *suite, void *user_data, int argc,
char *const *argv) {
return munit_suite_main_custom(suite, user_data, argc, argv, NULL);
}
static uint8_t hexchars[] = "0123456789abcdef";
static uint8_t *hexdump_addr(uint8_t *dest, size_t addr) {
size_t i;
uint8_t a;
for (i = 0; i < 4; ++i) {
a = (addr >> (3 - i) * 8) & 0xff;
*dest++ = hexchars[a >> 4];
*dest++ = hexchars[a & 0xf];
}
return dest;
}
static uint8_t *asciidump(uint8_t *dest, const uint8_t *data, size_t datalen) {
size_t i;
*dest++ = '|';
for (i = 0; i < datalen; ++i) {
if (0x20 <= data[i] && data[i] <= 0x7e) {
*dest++ = data[i];
} else {
*dest++ = '.';
}
}
*dest++ = '|';
return dest;
}
static uint8_t *hexdump8(uint8_t *dest, const uint8_t *data, size_t datalen) {
size_t i;
for (i = 0; i < datalen; ++i) {
*dest++ = hexchars[data[i] >> 4];
*dest++ = hexchars[data[i] & 0xf];
*dest++ = ' ';
}
for (; i < 8; ++i) {
*dest++ = ' ';
*dest++ = ' ';
*dest++ = ' ';
}
return dest;
}
static uint8_t *hexdump16(uint8_t *dest, const uint8_t *data, size_t datalen) {
dest = hexdump8(dest, data, datalen < 8 ? datalen : 8);
*dest++ = ' ';
if (datalen < 8) {
data = NULL;
datalen = 0;
} else {
data += 8;
datalen -= 8;
}
dest = hexdump8(dest, data, datalen);
*dest++ = ' ';
return dest;
}
static uint8_t *hexdump_line(uint8_t *dest, const uint8_t *data, size_t datalen,
size_t addr) {
dest = hexdump_addr(dest, addr);
*dest++ = ' ';
*dest++ = ' ';
dest = hexdump16(dest, data, datalen);
dest = asciidump(dest, data, datalen);
return dest;
}
int munit_hexdump(FILE *fp, const void *data, size_t datalen) {
size_t offset = 0, n, len;
uint8_t buf[128], *p;
const uint8_t *s;
int repeated = 0;
if (datalen == 0) {
return 0;
}
for (; offset < datalen; offset += 16) {
n = datalen - offset;
s = (const uint8_t *)data + offset;
if (n >= 16) {
n = 16;
if (offset > 0) {
if (memcmp(s - 16, s, 16) == 0) {
if (repeated) {
continue;
}
repeated = 1;
if (fwrite("*\n", 1, 2, fp) < 2) {
return -1;
}
continue;
}
repeated = 0;
}
}
p = hexdump_line(buf, s, n, offset);
*p++ = '\n';
len = (size_t)(p - buf);
if (fwrite(buf, 1, len, fp) < len) {
return -1;
}
}
p = hexdump_addr(buf, datalen);
*p++ = '\n';
len = (size_t)(p - buf);
if (fwrite(buf, 1, len, fp) < len) {
return -1;
}
return 0;
}
int munit_hexdump_diff(FILE *fp, const void *a, size_t alen, const void *b,
size_t blen) {
size_t offset = 0, k, i, len, ncomp, maxlen, adoff = 0;
uint8_t buf[128], *p;
const uint8_t mk[2] = {'-', '+'};
struct datasource {
const uint8_t *data;
size_t datalen;
const uint8_t *s;
size_t n;
} ds[] = {{a, alen, NULL, 0}, {b, blen, NULL, 0}}, *dp;
maxlen = alen < blen ? blen : alen;
for (; offset < maxlen; offset += 16) {
for (k = 0; k < 2; ++k) {
dp = &ds[k];
if (offset < dp->datalen) {
dp->s = (const uint8_t *)dp->data + offset;
dp->n = dp->datalen - offset;
if (dp->n > 16) {
dp->n = 16;
}
} else {
dp->s = NULL;
dp->n = 0;
}
}
if (ds[0].n == ds[1].n && memcmp(ds[0].s, ds[1].s, ds[0].n) == 0) {
continue;
}
for (k = 0; k < 2; ++k) {
dp = &ds[k];
if (!dp->n) {
continue;
}
p = buf;
*p++ = mk[k];
*p++ = mk[k];
*p++ = mk[k];
*p++ = mk[k];
p = hexdump_line(p, dp->s, dp->n, offset);
*p++ = '\n';
len = (size_t)(p - buf);
if (fwrite(buf, 1, len, fp) < len) {
return -1;
}
}
if (!ds[0].n || !ds[1].n) {
continue;
}
ncomp = ds[0].n < ds[1].n ? ds[0].n : ds[1].n;
p = buf + 4 + 10;
memset(buf, ' ', 4 + 78);
for (i = 0; i < ncomp; ++i) {
if (ds[0].s[i] == ds[1].s[i]) {
*p++ = ' ';
*p++ = ' ';
} else {
adoff = 4 + 10 + 51 + i;
*(buf + adoff) = '^';
*p++ = '^';
*p++ = '^';
}
*p++ = ' ';
if (i == 7) {
*p++ = ' ';
}
}
if (adoff) {
len = adoff + 1;
} else {
len = (size_t)(p - buf);
}
buf[len++] = '\n';
if (fwrite(buf, 1, len, fp) < len) {
return -1;
}
}
return 0;
}