src/xz/util.c - third_party/xz - Git at Google

 ///////////////////////////////////////////////////////////////////////////////
 //
 /// \file       util.c
 /// \brief      Miscellaneous utility functions
 //
 //  Author:     Lasse Collin
 //
 //  This file has been put into the public domain.
 //  You can do whatever you want with this file.
 //
 ///////////////////////////////////////////////////////////////////////////////

 #include "private.h"
 #include <stdarg.h>


 /// Buffers for uint64_to_str() and uint64_to_nicestr()
 static char bufs[4][128];

 /// Thousand separator support in uint64_to_str() and uint64_to_nicestr()
 static enum { UNKNOWN, WORKS, BROKEN } thousand = UNKNOWN;


 extern void *
 xrealloc(void *ptr, size_t size)
 {
 	assert(size > 0);

 	// Save ptr so that we can free it if realloc fails.
 	// The point is that message_fatal ends up calling stdio functions
 	// which in some libc implementations might allocate memory from
 	// the heap. Freeing ptr improves the chances that there's free
 	// memory for stdio functions if they need it.
 	void *p = ptr;
 	ptr = realloc(ptr, size);

 	if (ptr == NULL) {
 		const int saved_errno = errno;
 		free(p);
 		message_fatal("%s", strerror(saved_errno));
 	}

 	return ptr;
 }


 extern char *
 xstrdup(const char *src)
 {
 	assert(src != NULL);
 	const size_t size = strlen(src) + 1;
 	char *dest = xmalloc(size);
 	return memcpy(dest, src, size);
 }


 extern uint64_t
 str_to_uint64(const char *name, const char *value, uint64_t min, uint64_t max)
 {
 	uint64_t result = 0;

 	// Skip blanks.
 	while (*value == ' ' || *value == '\t')
 		++value;

 	// Accept special value "max". Supporting "min" doesn't seem useful.
 	if (strcmp(value, "max") == 0)
 		return max;

 	if (*value < '0' || *value > '9')
 		message_fatal(_("%s: Value is not a non-negative "
 				"decimal integer"), value);

 	do {
 		// Don't overflow.
 		if (result > UINT64_MAX / 10)
 			goto error;

 		result *= 10;

 		// Another overflow check
 		const uint32_t add = *value - '0';
 		if (UINT64_MAX - add < result)
 			goto error;

 		result += add;
 		++value;
 	} while (*value >= '0' && *value <= '9');

 	if (*value != '\0') {
 		// Look for suffix. Originally this supported both base-2
 		// and base-10, but since there seems to be little need
 		// for base-10 in this program, treat everything as base-2
 		// and also be more relaxed about the case of the first
 		// letter of the suffix.
 		uint64_t multiplier = 0;
 		if (*value == 'k' || *value == 'K')
 			multiplier = UINT64_C(1) << 10;
 		else if (*value == 'm' || *value == 'M')
 			multiplier = UINT64_C(1) << 20;
 		else if (*value == 'g' || *value == 'G')
 			multiplier = UINT64_C(1) << 30;

 		++value;

 		// Allow also e.g. Ki, KiB, and KB.
 		if (*value != '\0' && strcmp(value, "i") != 0
 				&& strcmp(value, "iB") != 0
 				&& strcmp(value, "B") != 0)
 			multiplier = 0;

 		if (multiplier == 0) {
 			message(V_ERROR, _("%s: Invalid multiplier suffix"),
 					value - 1);
 			message_fatal(_("Valid suffixes are `KiB' (2^10), "
 					"`MiB' (2^20), and `GiB' (2^30)."));
 		}

 		// Don't overflow here either.
 		if (result > UINT64_MAX / multiplier)
 			goto error;

 		result *= multiplier;
 	}

 	if (result < min || result > max)
 		goto error;

 	return result;

 error:
 	message_fatal(_("Value of the option `%s' must be in the range "
 				"[%" PRIu64 ", %" PRIu64 "]"),
 				name, min, max);
 }


 extern uint64_t
 round_up_to_mib(uint64_t n)
 {
 	return (n >> 20) + ((n & ((UINT32_C(1) << 20) - 1)) != 0);
 }


 /// Check if thousand separator is supported. Run-time checking is easiest,
 /// because it seems to be sometimes lacking even on POSIXish system.
 static void
 check_thousand_sep(uint32_t slot)
 {
 	if (thousand == UNKNOWN) {
 		bufs[slot][0] = '\0';
 		snprintf(bufs[slot], sizeof(bufs[slot]), "%'u", 1U);
 		thousand = bufs[slot][0] == '1' ? WORKS : BROKEN;
 	}

 	return;
 }


 extern const char *
 uint64_to_str(uint64_t value, uint32_t slot)
 {
 	assert(slot < ARRAY_SIZE(bufs));

 	check_thousand_sep(slot);

 	if (thousand == WORKS)
 		snprintf(bufs[slot], sizeof(bufs[slot]), "%'" PRIu64, value);
 	else
 		snprintf(bufs[slot], sizeof(bufs[slot]), "%" PRIu64, value);

 	return bufs[slot];
 }


 extern const char *
 uint64_to_nicestr(uint64_t value, enum nicestr_unit unit_min,
 		enum nicestr_unit unit_max, bool always_also_bytes,
 		uint32_t slot)
 {
 	assert(unit_min <= unit_max);
 	assert(unit_max <= NICESTR_TIB);
 	assert(slot < ARRAY_SIZE(bufs));

 	check_thousand_sep(slot);

 	enum nicestr_unit unit = NICESTR_B;
 	char *pos = bufs[slot];
 	size_t left = sizeof(bufs[slot]);

 	if ((unit_min == NICESTR_B && value < 10000)
 			|| unit_max == NICESTR_B) {
 		// The value is shown as bytes.
 		if (thousand == WORKS)
 			my_snprintf(&pos, &left, "%'u", (unsigned int)value);
 		else
 			my_snprintf(&pos, &left, "%u", (unsigned int)value);
 	} else {
 		// Scale the value to a nicer unit. Unless unit_min and
 		// unit_max limit us, we will show at most five significant
 		// digits with one decimal place.
 		double d = (double)(value);
 		do {
 			d /= 1024.0;
 			++unit;
 		} while (unit < unit_min || (d > 9999.9 && unit < unit_max));

 		if (thousand == WORKS)
 			my_snprintf(&pos, &left, "%'.1f", d);
 		else
 			my_snprintf(&pos, &left, "%.1f", d);
 	}

 	static const char suffix[5][4] = { "B", "KiB", "MiB", "GiB", "TiB" };
 	my_snprintf(&pos, &left, " %s", suffix[unit]);

 	if (always_also_bytes && value >= 10000) {
 		if (thousand == WORKS)
 			snprintf(pos, left, " (%'" PRIu64 " B)", value);
 		else
 			snprintf(pos, left, " (%" PRIu64 " B)", value);
 	}

 	return bufs[slot];
 }


 extern void
 my_snprintf(char **pos, size_t *left, const char *fmt, ...)
 {
 	va_list ap;
 	va_start(ap, fmt);
 	const int len = vsnprintf(*pos, *left, fmt, ap);
 	va_end(ap);

 	// If an error occurred, we want the caller to think that the whole
 	// buffer was used. This way no more data will be written to the
 	// buffer. We don't need better error handling here, although it
 	// is possible that the result looks garbage on the terminal if
 	// e.g. an UTF-8 character gets split. That shouldn't (easily)
 	// happen though, because the buffers used have some extra room.
 	if (len < 0 || (size_t)(len) >= *left) {
 		*left = 0;
 	} else {
 		*pos += len;
 		*left -= len;
 	}

 	return;
 }


 extern bool
 is_empty_filename(const char *filename)
 {
 	if (filename[0] == '\0') {
 		message_error(_("Empty filename, skipping"));
 		return true;
 	}

 	return false;
 }


 extern bool
 is_tty_stdin(void)
 {
 	const bool ret = isatty(STDIN_FILENO);

 	if (ret)
 		message_error(_("Compressed data cannot be read from "
 				"a terminal"));

 	return ret;
 }


 extern bool
 is_tty_stdout(void)
 {
 	const bool ret = isatty(STDOUT_FILENO);

 	if (ret)
 		message_error(_("Compressed data cannot be written to "
 				"a terminal"));

 	return ret;
 }
	///////////////////////////////////////////////////////////////////////////////
	//
	/// \file util.c
	/// \brief Miscellaneous utility functions
	//
	// Author: Lasse Collin
	//
	// This file has been put into the public domain.
	// You can do whatever you want with this file.
	//
	///////////////////////////////////////////////////////////////////////////////

	#include "private.h"
	#include <stdarg.h>


	/// Buffers for uint64_to_str() and uint64_to_nicestr()
	static char bufs[4][128];

	/// Thousand separator support in uint64_to_str() and uint64_to_nicestr()
	static enum { UNKNOWN, WORKS, BROKEN } thousand = UNKNOWN;


	extern void *
	xrealloc(void *ptr, size_t size)
	{
	assert(size > 0);

	// Save ptr so that we can free it if realloc fails.
	// The point is that message_fatal ends up calling stdio functions
	// which in some libc implementations might allocate memory from
	// the heap. Freeing ptr improves the chances that there's free
	// memory for stdio functions if they need it.
	void *p = ptr;
	ptr = realloc(ptr, size);

	if (ptr == NULL) {
	const int saved_errno = errno;
	free(p);
	message_fatal("%s", strerror(saved_errno));
	}

	return ptr;
	}


	extern char *
	xstrdup(const char *src)
	{
	assert(src != NULL);
	const size_t size = strlen(src) + 1;
	char *dest = xmalloc(size);
	return memcpy(dest, src, size);
	}


	extern uint64_t
	str_to_uint64(const char name, const char value, uint64_t min, uint64_t max)
	{
	uint64_t result = 0;

	// Skip blanks.
	while (value == ' ' \|\| value == '\t')
	++value;

	// Accept special value "max". Supporting "min" doesn't seem useful.
	if (strcmp(value, "max") == 0)
	return max;

	if (value < '0' \|\| value > '9')
	message_fatal(_("%s: Value is not a non-negative "
	"decimal integer"), value);

	do {
	// Don't overflow.
	if (result > UINT64_MAX / 10)
	goto error;

	result *= 10;

	// Another overflow check
	const uint32_t add = *value - '0';
	if (UINT64_MAX - add < result)
	goto error;

	result += add;
	++value;
	} while (value >= '0' && value <= '9');

	if (*value != '\0') {
	// Look for suffix. Originally this supported both base-2
	// and base-10, but since there seems to be little need
	// for base-10 in this program, treat everything as base-2
	// and also be more relaxed about the case of the first
	// letter of the suffix.
	uint64_t multiplier = 0;
	if (value == 'k' \|\| value == 'K')
	multiplier = UINT64_C(1) << 10;
	else if (value == 'm' \|\| value == 'M')
	multiplier = UINT64_C(1) << 20;
	else if (value == 'g' \|\| value == 'G')
	multiplier = UINT64_C(1) << 30;

	++value;

	// Allow also e.g. Ki, KiB, and KB.
	if (*value != '\0' && strcmp(value, "i") != 0
	&& strcmp(value, "iB") != 0
	&& strcmp(value, "B") != 0)
	multiplier = 0;

	if (multiplier == 0) {
	message(V_ERROR, _("%s: Invalid multiplier suffix"),
	value - 1);
	message_fatal(_("Valid suffixes are `KiB' (2^10), "
	"`MiB' (2^20), and `GiB' (2^30)."));
	}

	// Don't overflow here either.
	if (result > UINT64_MAX / multiplier)
	goto error;

	result *= multiplier;
	}

	if (result < min \|\| result > max)
	goto error;

	return result;

	error:
	message_fatal(_("Value of the option `%s' must be in the range "
	"[%" PRIu64 ", %" PRIu64 "]"),
	name, min, max);
	}


	extern uint64_t
	round_up_to_mib(uint64_t n)
	{
	return (n >> 20) + ((n & ((UINT32_C(1) << 20) - 1)) != 0);
	}


	/// Check if thousand separator is supported. Run-time checking is easiest,
	/// because it seems to be sometimes lacking even on POSIXish system.
	static void
	check_thousand_sep(uint32_t slot)
	{
	if (thousand == UNKNOWN) {
	bufs[slot][0] = '\0';
	snprintf(bufs[slot], sizeof(bufs[slot]), "%'u", 1U);
	thousand = bufs[slot][0] == '1' ? WORKS : BROKEN;
	}

	return;
	}


	extern const char *
	uint64_to_str(uint64_t value, uint32_t slot)
	{
	assert(slot < ARRAY_SIZE(bufs));

	check_thousand_sep(slot);

	if (thousand == WORKS)
	snprintf(bufs[slot], sizeof(bufs[slot]), "%'" PRIu64, value);
	else
	snprintf(bufs[slot], sizeof(bufs[slot]), "%" PRIu64, value);

	return bufs[slot];
	}


	extern const char *
	uint64_to_nicestr(uint64_t value, enum nicestr_unit unit_min,
	enum nicestr_unit unit_max, bool always_also_bytes,
	uint32_t slot)
	{
	assert(unit_min <= unit_max);
	assert(unit_max <= NICESTR_TIB);
	assert(slot < ARRAY_SIZE(bufs));

	check_thousand_sep(slot);

	enum nicestr_unit unit = NICESTR_B;
	char *pos = bufs[slot];
	size_t left = sizeof(bufs[slot]);

	if ((unit_min == NICESTR_B && value < 10000)
	\|\| unit_max == NICESTR_B) {
	// The value is shown as bytes.
	if (thousand == WORKS)
	my_snprintf(&pos, &left, "%'u", (unsigned int)value);
	else
	my_snprintf(&pos, &left, "%u", (unsigned int)value);
	} else {
	// Scale the value to a nicer unit. Unless unit_min and
	// unit_max limit us, we will show at most five significant
	// digits with one decimal place.
	double d = (double)(value);
	do {
	d /= 1024.0;
	++unit;
	} while (unit < unit_min \|\| (d > 9999.9 && unit < unit_max));

	if (thousand == WORKS)
	my_snprintf(&pos, &left, "%'.1f", d);
	else
	my_snprintf(&pos, &left, "%.1f", d);
	}

	static const char suffix[5][4] = { "B", "KiB", "MiB", "GiB", "TiB" };
	my_snprintf(&pos, &left, " %s", suffix[unit]);

	if (always_also_bytes && value >= 10000) {
	if (thousand == WORKS)
	snprintf(pos, left, " (%'" PRIu64 " B)", value);
	else
	snprintf(pos, left, " (%" PRIu64 " B)", value);
	}

	return bufs[slot];
	}


	extern void
	my_snprintf(char *pos, size_t left, const char *fmt, ...)
	{
	va_list ap;
	va_start(ap, fmt);
	const int len = vsnprintf(pos, left, fmt, ap);
	va_end(ap);

	// If an error occurred, we want the caller to think that the whole
	// buffer was used. This way no more data will be written to the
	// buffer. We don't need better error handling here, although it
	// is possible that the result looks garbage on the terminal if
	// e.g. an UTF-8 character gets split. That shouldn't (easily)
	// happen though, because the buffers used have some extra room.
	if (len < 0 \|\| (size_t)(len) >= *left) {
	*left = 0;
	} else {
	*pos += len;
	*left -= len;
	}

	return;
	}


	extern bool
	is_empty_filename(const char *filename)
	{
	if (filename[0] == '\0') {
	message_error(_("Empty filename, skipping"));
	return true;
	}

	return false;
	}


	extern bool
	is_tty_stdin(void)
	{
	const bool ret = isatty(STDIN_FILENO);

	if (ret)
	message_error(_("Compressed data cannot be read from "
	"a terminal"));

	return ret;
	}


	extern bool
	is_tty_stdout(void)
	{
	const bool ret = isatty(STDOUT_FILENO);

	if (ret)
	message_error(_("Compressed data cannot be written to "
	"a terminal"));

	return ret;
	}