python/src/Python/pystrtod.c - toolchain/benchmark - Git at Google

 /* -*- Mode: C; c-file-style: "python" -*- */

 #include <Python.h>
 #include <locale.h>

 /* ascii character tests (as opposed to locale tests) */
 #define ISSPACE(c)  ((c) == ' ' || (c) == '\f' || (c) == '\n' || \
                      (c) == '\r' || (c) == '\t' || (c) == '\v')
 #define ISDIGIT(c)  ((c) >= '0' && (c) <= '9')


 /**
  * PyOS_ascii_strtod:
  * @nptr:    the string to convert to a numeric value.
  * @endptr:  if non-%NULL, it returns the character after
  *           the last character used in the conversion.
  *
  * Converts a string to a #gdouble value.
  * This function behaves like the standard strtod() function
  * does in the C locale. It does this without actually
  * changing the current locale, since that would not be
  * thread-safe.
  *
  * This function is typically used when reading configuration
  * files or other non-user input that should be locale independent.
  * To handle input from the user you should normally use the
  * locale-sensitive system strtod() function.
  *
  * If the correct value would cause overflow, plus or minus %HUGE_VAL
  * is returned (according to the sign of the value), and %ERANGE is
  * stored in %errno. If the correct value would cause underflow,
  * zero is returned and %ERANGE is stored in %errno.
  * If memory allocation fails, %ENOMEM is stored in %errno.
  *
  * This function resets %errno before calling strtod() so that
  * you can reliably detect overflow and underflow.
  *
  * Return value: the #gdouble value.
  **/
 double
 PyOS_ascii_strtod(const char *nptr, char **endptr)
 {
 	char *fail_pos;
 	double val = -1.0;
 	struct lconv *locale_data;
 	const char *decimal_point;
 	size_t decimal_point_len;
 	const char *p, *decimal_point_pos;
 	const char *end = NULL; /* Silence gcc */
 	const char *digits_pos = NULL;
 	int negate = 0;

 	assert(nptr != NULL);

 	fail_pos = NULL;

 	locale_data = localeconv();
 	decimal_point = locale_data->decimal_point;
 	decimal_point_len = strlen(decimal_point);

 	assert(decimal_point_len != 0);

 	decimal_point_pos = NULL;

 	/* We process any leading whitespace and the optional sign manually,
 	   then pass the remainder to the system strtod.  This ensures that
 	   the result of an underflow has the correct sign. (bug #1725)  */

 	p = nptr;
 	/* Skip leading space */
 	while (ISSPACE(*p))
 		p++;

 	/* Process leading sign, if present */
 	if (*p == '-') {
 		negate = 1;
 		p++;
 	} else if (*p == '+') {
 		p++;
 	}

 	/* What's left should begin with a digit, a decimal point, or one of
 	   the letters i, I, n, N. It should not begin with 0x or 0X */
 	if ((!ISDIGIT(*p) &&
 	     *p != '.' && *p != 'i' && *p != 'I' && *p != 'n' && *p != 'N')
 	    ||
 	    (*p == '0' && (p[1] == 'x' || p[1] == 'X')))
 	{
 		if (endptr)
 			*endptr = (char*)nptr;
 		errno = EINVAL;
 		return val;
 	}
 	digits_pos = p;

 	if (decimal_point[0] != '.' ||
 	    decimal_point[1] != 0)
 	{
 		while (ISDIGIT(*p))
 			p++;

 		if (*p == '.')
 		{
 			decimal_point_pos = p++;

 			while (ISDIGIT(*p))
 				p++;

 			if (*p == 'e' || *p == 'E')
 				p++;
 			if (*p == '+' || *p == '-')
 				p++;
 			while (ISDIGIT(*p))
 				p++;
 			end = p;
 		}
 		else if (strncmp(p, decimal_point, decimal_point_len) == 0)
 		{
 			/* Python bug #1417699 */
 			if (endptr)
 				*endptr = (char*)nptr;
 			errno = EINVAL;
 			return val;
 		}
 		/* For the other cases, we need not convert the decimal
 		   point */
 	}

 	/* Set errno to zero, so that we can distinguish zero results
 	   and underflows */
 	errno = 0;

 	if (decimal_point_pos)
 	{
 		char *copy, *c;

 		/* We need to convert the '.' to the locale specific decimal
 		   point */
 		copy = (char *)PyMem_MALLOC(end - digits_pos +
 					    1 + decimal_point_len);
 		if (copy == NULL) {
 			if (endptr)
 				*endptr = (char *)nptr;
 			errno = ENOMEM;
 			return val;
 		}

 		c = copy;
 		memcpy(c, digits_pos, decimal_point_pos - digits_pos);
 		c += decimal_point_pos - digits_pos;
 		memcpy(c, decimal_point, decimal_point_len);
 		c += decimal_point_len;
 		memcpy(c, decimal_point_pos + 1,
 		       end - (decimal_point_pos + 1));
 		c += end - (decimal_point_pos + 1);
 		*c = 0;

 		val = strtod(copy, &fail_pos);

 		if (fail_pos)
 		{
 			if (fail_pos > decimal_point_pos)
 				fail_pos = (char *)digits_pos +
 					(fail_pos - copy) -
 					(decimal_point_len - 1);
 			else
 				fail_pos = (char *)digits_pos +
 					(fail_pos - copy);
 		}

 		PyMem_FREE(copy);

 	}
 	else {
 		val = strtod(digits_pos, &fail_pos);
 	}

 	if (fail_pos == digits_pos)
 		fail_pos = (char *)nptr;

 	if (negate && fail_pos != nptr)
 		val = -val;

 	if (endptr)
 		*endptr = fail_pos;

 	return val;
 }

 struct lconv local_ddd;

 struct lconv *
 localeconv()
 {
   local_ddd.decimal_point = ".";
   local_ddd.grouping = "";
   local_ddd.thousands_sep = ",";
   return &local_ddd;
 }

 /* Given a string that may have a decimal point in the current
    locale, change it back to a dot.  Since the string cannot get
    longer, no need for a maximum buffer size parameter. */
 Py_LOCAL_INLINE(void)
 change_decimal_from_locale_to_dot(char* buffer)
 {
 	struct lconv *locale_data = localeconv();
 	const char *decimal_point = locale_data->decimal_point;

 	if (decimal_point[0] != '.' || decimal_point[1] != 0) {
 		size_t decimal_point_len = strlen(decimal_point);

 		if (*buffer == '+' || *buffer == '-')
 			buffer++;
 		while (isdigit(Py_CHARMASK(*buffer)))
 			buffer++;
 		if (strncmp(buffer, decimal_point, decimal_point_len) == 0) {
 			*buffer = '.';
 			buffer++;
 			if (decimal_point_len > 1) {
 				/* buffer needs to get smaller */
 				size_t rest_len = strlen(buffer +
 						     (decimal_point_len - 1));
 				memmove(buffer,
 					buffer + (decimal_point_len - 1),
 					rest_len);
 				buffer[rest_len] = 0;
 			}
 		}
 	}
 }


 /* From the C99 standard, section 7.19.6:
 The exponent always contains at least two digits, and only as many more digits
 as necessary to represent the exponent.
 */
 #define MIN_EXPONENT_DIGITS 2

 /* Ensure that any exponent, if present, is at least MIN_EXPONENT_DIGITS
    in length. */
 Py_LOCAL_INLINE(void)
 ensure_minimum_exponent_length(char* buffer, size_t buf_size)
 {
 	char *p = strpbrk(buffer, "eE");
 	if (p && (*(p + 1) == '-' || *(p + 1) == '+')) {
 		char *start = p + 2;
 		int exponent_digit_cnt = 0;
 		int leading_zero_cnt = 0;
 		int in_leading_zeros = 1;
 		int significant_digit_cnt;

 		/* Skip over the exponent and the sign. */
 		p += 2;

 		/* Find the end of the exponent, keeping track of leading
 		   zeros. */
 		while (*p && isdigit(Py_CHARMASK(*p))) {
 			if (in_leading_zeros && *p == '0')
 				++leading_zero_cnt;
 			if (*p != '0')
 				in_leading_zeros = 0;
 			++p;
 			++exponent_digit_cnt;
 		}

 		significant_digit_cnt = exponent_digit_cnt - leading_zero_cnt;
 		if (exponent_digit_cnt == MIN_EXPONENT_DIGITS) {
 			/* If there are 2 exactly digits, we're done,
 			   regardless of what they contain */
 		}
 		else if (exponent_digit_cnt > MIN_EXPONENT_DIGITS) {
 			int extra_zeros_cnt;

 			/* There are more than 2 digits in the exponent.  See
 			   if we can delete some of the leading zeros */
 			if (significant_digit_cnt < MIN_EXPONENT_DIGITS)
 				significant_digit_cnt = MIN_EXPONENT_DIGITS;
 			extra_zeros_cnt = exponent_digit_cnt -
 				significant_digit_cnt;

 			/* Delete extra_zeros_cnt worth of characters from the
 			   front of the exponent */
 			assert(extra_zeros_cnt >= 0);

 			/* Add one to significant_digit_cnt to copy the
 			   trailing 0 byte, thus setting the length */
 			memmove(start,
 				start + extra_zeros_cnt,
 				significant_digit_cnt + 1);
 		}
 		else {
 			/* If there are fewer than 2 digits, add zeros
 			   until there are 2, if there's enough room */
 			int zeros = MIN_EXPONENT_DIGITS - exponent_digit_cnt;
 			if (start + zeros + exponent_digit_cnt + 1
 			      < buffer + buf_size) {
 				memmove(start + zeros, start,
 					exponent_digit_cnt + 1);
 				memset(start, '0', zeros);
 			}
 		}
 	}
 }

 /* Ensure that buffer has a decimal point in it.  The decimal point
    will not be in the current locale, it will always be '.' */
 Py_LOCAL_INLINE(void)
 ensure_decimal_point(char* buffer, size_t buf_size)
 {
 	int insert_count = 0;
 	char* chars_to_insert;

 	/* search for the first non-digit character */
 	char *p = buffer;
 	if (*p == '-' || *p == '+')
 		/* Skip leading sign, if present.  I think this could only
 		   ever be '-', but it can't hurt to check for both. */
 		++p;
 	while (*p && isdigit(Py_CHARMASK(*p)))
 		++p;

 	if (*p == '.') {
 		if (isdigit(Py_CHARMASK(*(p+1)))) {
 			/* Nothing to do, we already have a decimal
 			   point and a digit after it */
 		}
 		else {
 			/* We have a decimal point, but no following
 			   digit.  Insert a zero after the decimal. */
 			++p;
 			chars_to_insert = "0";
 			insert_count = 1;
 		}
 	}
 	else {
 		chars_to_insert = ".0";
 		insert_count = 2;
 	}
 	if (insert_count) {
 		size_t buf_len = strlen(buffer);
 		if (buf_len + insert_count + 1 >= buf_size) {
 			/* If there is not enough room in the buffer
 			   for the additional text, just skip it.  It's
 			   not worth generating an error over. */
 		}
 		else {
 			memmove(p + insert_count, p,
 				buffer + strlen(buffer) - p + 1);
 			memcpy(p, chars_to_insert, insert_count);
 		}
 	}
 }

 /* Add the locale specific grouping characters to buffer.  Note
    that any decimal point (if it's present) in buffer is already
    locale-specific.  Return 0 on error, else 1. */
 Py_LOCAL_INLINE(int)
 add_thousands_grouping(char* buffer, size_t buf_size)
 {
 	Py_ssize_t len = strlen(buffer);
 	struct lconv *locale_data = localeconv();
 	const char *decimal_point = locale_data->decimal_point;

 	/* Find the decimal point, if any.  We're only concerned
 	   about the characters to the left of the decimal when
 	   adding grouping. */
 	char *p = strstr(buffer, decimal_point);
 	if (!p) {
 		/* No decimal, use the entire string. */

 		/* If any exponent, adjust p. */
 		p = strpbrk(buffer, "eE");
 		if (!p)
 			/* No exponent and no decimal.  Use the entire
 			   string. */
 			p = buffer + len;
 	}
 	/* At this point, p points just past the right-most character we
 	   want to format.  We need to add the grouping string for the
 	   characters between buffer and p. */
 	return _PyString_InsertThousandsGrouping(buffer, len, p-buffer,
 						 buf_size, NULL, 1);
 }

 /* see FORMATBUFLEN in unicodeobject.c */
 #define FLOAT_FORMATBUFLEN 120

 /**
  * PyOS_ascii_formatd:
  * @buffer: A buffer to place the resulting string in
  * @buf_size: The length of the buffer.
  * @format: The printf()-style format to use for the
  *          code to use for converting.
  * @d: The #gdouble to convert
  *
  * Converts a #gdouble to a string, using the '.' as
  * decimal point. To format the number you pass in
  * a printf()-style format string. Allowed conversion
  * specifiers are 'e', 'E', 'f', 'F', 'g', 'G', and 'n'.
  *
  * 'n' is the same as 'g', except it uses the current locale.
  * 'Z' is the same as 'g', except it always has a decimal and
  *     at least one digit after the decimal.
  *
  * Return value: The pointer to the buffer with the converted string.
  **/
 char *
 PyOS_ascii_formatd(char       *buffer,
 		   size_t      buf_size,
 		   const char *format,
 		   double      d)
 {
 	char format_char;
 	size_t format_len = strlen(format);

 	/* For type 'n', we need to make a copy of the format string, because
 	   we're going to modify 'n' -> 'g', and format is const char*, so we
 	   can't modify it directly.  FLOAT_FORMATBUFLEN should be longer than
 	   we ever need this to be.  There's an upcoming check to ensure it's
 	   big enough. */
 	/* Issue 2264: code 'Z' requires copying the format.  'Z' is 'g', but
 	   also with at least one character past the decimal. */
 	char tmp_format[FLOAT_FORMATBUFLEN];

 	/* The last character in the format string must be the format char */
 	format_char = format[format_len - 1];

 	if (format[0] != '%')
 		return NULL;

 	/* I'm not sure why this test is here.  It's ensuring that the format
 	   string after the first character doesn't have a single quote, a
 	   lowercase l, or a percent. This is the reverse of the commented-out
 	   test about 10 lines ago. */
 	if (strpbrk(format + 1, "'l%"))
 		return NULL;

 	/* Also curious about this function is that it accepts format strings
 	   like "%xg", which are invalid for floats.  In general, the
 	   interface to this function is not very good, but changing it is
 	   difficult because it's a public API. */

 	if (!(format_char == 'e' || format_char == 'E' ||
 	      format_char == 'f' || format_char == 'F' ||
 	      format_char == 'g' || format_char == 'G' ||
 	      format_char == 'n' || format_char == 'Z'))
 		return NULL;

 	/* Map 'n' or 'Z' format_char to 'g', by copying the format string and
 	   replacing the final char with a 'g' */
 	if (format_char == 'n' || format_char == 'Z') {
 		if (format_len + 1 >= sizeof(tmp_format)) {
 			/* The format won't fit in our copy.  Error out.  In
 			   practice, this will never happen and will be
 			   detected by returning NULL */
 			return NULL;
 		}
 		strcpy(tmp_format, format);
 		tmp_format[format_len - 1] = 'g';
 		format = tmp_format;
 	}


 	/* Have PyOS_snprintf do the hard work */
 	PyOS_snprintf(buffer, buf_size, format, d);

 	/* Do various fixups on the return string */

 	/* Get the current locale, and find the decimal point string.
 	   Convert that string back to a dot.  Do not do this if using the
 	   'n' (number) format code, since we want to keep the localized
 	   decimal point in that case. */
 	if (format_char != 'n')
 		change_decimal_from_locale_to_dot(buffer);

 	/* If an exponent exists, ensure that the exponent is at least
 	   MIN_EXPONENT_DIGITS digits, providing the buffer is large enough
 	   for the extra zeros.  Also, if there are more than
 	   MIN_EXPONENT_DIGITS, remove as many zeros as possible until we get
 	   back to MIN_EXPONENT_DIGITS */
 	ensure_minimum_exponent_length(buffer, buf_size);

 	/* If format_char is 'Z', make sure we have at least one character
 	   after the decimal point (and make sure we have a decimal point). */
 	if (format_char == 'Z')
 		ensure_decimal_point(buffer, buf_size);

 	/* If format_char is 'n', add the thousands grouping. */
 	if (format_char == 'n')
 		if (!add_thousands_grouping(buffer, buf_size))
 			return NULL;

 	return buffer;
 }

 double
 PyOS_ascii_atof(const char *nptr)
 {
 	return PyOS_ascii_strtod(nptr, NULL);
 }
	/* -- Mode: C; c-file-style: "python" -- */

	#include <Python.h>
	#include <locale.h>

	/* ascii character tests (as opposed to locale tests) */
	#define ISSPACE(c) ((c) == ' ' \|\| (c) == '\f' \|\| (c) == '\n' \|\| \
	(c) == '\r' \|\| (c) == '\t' \|\| (c) == '\v')
	#define ISDIGIT(c) ((c) >= '0' && (c) <= '9')


	/**
	* PyOS_ascii_strtod:
	* @nptr: the string to convert to a numeric value.
	* @endptr: if non-%NULL, it returns the character after
	* the last character used in the conversion.
	*
	* Converts a string to a #gdouble value.
	* This function behaves like the standard strtod() function
	* does in the C locale. It does this without actually
	* changing the current locale, since that would not be
	* thread-safe.
	*
	* This function is typically used when reading configuration
	* files or other non-user input that should be locale independent.
	* To handle input from the user you should normally use the
	* locale-sensitive system strtod() function.
	*
	* If the correct value would cause overflow, plus or minus %HUGE_VAL
	* is returned (according to the sign of the value), and %ERANGE is
	* stored in %errno. If the correct value would cause underflow,
	* zero is returned and %ERANGE is stored in %errno.
	* If memory allocation fails, %ENOMEM is stored in %errno.
	*
	* This function resets %errno before calling strtod() so that
	* you can reliably detect overflow and underflow.
	*
	* Return value: the #gdouble value.
	**/
	double
	PyOS_ascii_strtod(const char nptr, char *endptr)
	{
	char *fail_pos;
	double val = -1.0;
	struct lconv *locale_data;
	const char *decimal_point;
	size_t decimal_point_len;
	const char p, decimal_point_pos;
	const char end = NULL; / Silence gcc */
	const char *digits_pos = NULL;
	int negate = 0;

	assert(nptr != NULL);

	fail_pos = NULL;

	locale_data = localeconv();
	decimal_point = locale_data->decimal_point;
	decimal_point_len = strlen(decimal_point);

	assert(decimal_point_len != 0);

	decimal_point_pos = NULL;

	/* We process any leading whitespace and the optional sign manually,
	then pass the remainder to the system strtod. This ensures that
	the result of an underflow has the correct sign. (bug #1725) */

	p = nptr;
	/* Skip leading space */
	while (ISSPACE(*p))
	p++;

	/* Process leading sign, if present */
	if (*p == '-') {
	negate = 1;
	p++;
	} else if (*p == '+') {
	p++;
	}

	/* What's left should begin with a digit, a decimal point, or one of
	the letters i, I, n, N. It should not begin with 0x or 0X */
	if ((!ISDIGIT(*p) &&
	p != '.' && p != 'i' && p != 'I' && p != 'n' && *p != 'N')
	\|\|
	(*p == '0' && (p[1] == 'x' \|\| p[1] == 'X')))
	{
	if (endptr)
	endptr = (char)nptr;
	errno = EINVAL;
	return val;
	}
	digits_pos = p;

	if (decimal_point[0] != '.' \|\|
	decimal_point[1] != 0)
	{
	while (ISDIGIT(*p))
	p++;

	if (*p == '.')
	{
	decimal_point_pos = p++;

	while (ISDIGIT(*p))
	p++;

	if (p == 'e' \|\| p == 'E')
	p++;
	if (p == '+' \|\| p == '-')
	p++;
	while (ISDIGIT(*p))
	p++;
	end = p;
	}
	else if (strncmp(p, decimal_point, decimal_point_len) == 0)
	{
	/* Python bug #1417699 */
	if (endptr)
	endptr = (char)nptr;
	errno = EINVAL;
	return val;
	}
	/* For the other cases, we need not convert the decimal
	point */
	}

	/* Set errno to zero, so that we can distinguish zero results
	and underflows */
	errno = 0;

	if (decimal_point_pos)
	{
	char copy, c;

	/* We need to convert the '.' to the locale specific decimal
	point */
	copy = (char *)PyMem_MALLOC(end - digits_pos +
	1 + decimal_point_len);
	if (copy == NULL) {
	if (endptr)
	endptr = (char )nptr;
	errno = ENOMEM;
	return val;
	}

	c = copy;
	memcpy(c, digits_pos, decimal_point_pos - digits_pos);
	c += decimal_point_pos - digits_pos;
	memcpy(c, decimal_point, decimal_point_len);
	c += decimal_point_len;
	memcpy(c, decimal_point_pos + 1,
	end - (decimal_point_pos + 1));
	c += end - (decimal_point_pos + 1);
	*c = 0;

	val = strtod(copy, &fail_pos);

	if (fail_pos)
	{
	if (fail_pos > decimal_point_pos)
	fail_pos = (char *)digits_pos +
	(fail_pos - copy) -
	(decimal_point_len - 1);
	else
	fail_pos = (char *)digits_pos +
	(fail_pos - copy);
	}

	PyMem_FREE(copy);

	}
	else {
	val = strtod(digits_pos, &fail_pos);
	}

	if (fail_pos == digits_pos)
	fail_pos = (char *)nptr;

	if (negate && fail_pos != nptr)
	val = -val;

	if (endptr)
	*endptr = fail_pos;

	return val;
	}

	struct lconv local_ddd;

	struct lconv *
	localeconv()
	{
	local_ddd.decimal_point = ".";
	local_ddd.grouping = "";
	local_ddd.thousands_sep = ",";
	return &local_ddd;
	}

	/* Given a string that may have a decimal point in the current
	locale, change it back to a dot. Since the string cannot get
	longer, no need for a maximum buffer size parameter. */
	Py_LOCAL_INLINE(void)
	change_decimal_from_locale_to_dot(char* buffer)
	{
	struct lconv *locale_data = localeconv();
	const char *decimal_point = locale_data->decimal_point;

	if (decimal_point[0] != '.' \|\| decimal_point[1] != 0) {
	size_t decimal_point_len = strlen(decimal_point);

	if (buffer == '+' \|\| buffer == '-')
	buffer++;
	while (isdigit(Py_CHARMASK(*buffer)))
	buffer++;
	if (strncmp(buffer, decimal_point, decimal_point_len) == 0) {
	*buffer = '.';
	buffer++;
	if (decimal_point_len > 1) {
	/* buffer needs to get smaller */
	size_t rest_len = strlen(buffer +
	(decimal_point_len - 1));
	memmove(buffer,
	buffer + (decimal_point_len - 1),
	rest_len);
	buffer[rest_len] = 0;
	}
	}
	}
	}


	/* From the C99 standard, section 7.19.6:
	The exponent always contains at least two digits, and only as many more digits
	as necessary to represent the exponent.
	*/
	#define MIN_EXPONENT_DIGITS 2

	/* Ensure that any exponent, if present, is at least MIN_EXPONENT_DIGITS
	in length. */
	Py_LOCAL_INLINE(void)
	ensure_minimum_exponent_length(char* buffer, size_t buf_size)
	{
	char *p = strpbrk(buffer, "eE");
	if (p && ((p + 1) == '-' \|\| (p + 1) == '+')) {
	char *start = p + 2;
	int exponent_digit_cnt = 0;
	int leading_zero_cnt = 0;
	int in_leading_zeros = 1;
	int significant_digit_cnt;

	/* Skip over the exponent and the sign. */
	p += 2;

	/* Find the end of the exponent, keeping track of leading
	zeros. */
	while (p && isdigit(Py_CHARMASK(p))) {
	if (in_leading_zeros && *p == '0')
	++leading_zero_cnt;
	if (*p != '0')
	in_leading_zeros = 0;
	++p;
	++exponent_digit_cnt;
	}

	significant_digit_cnt = exponent_digit_cnt - leading_zero_cnt;
	if (exponent_digit_cnt == MIN_EXPONENT_DIGITS) {
	/* If there are 2 exactly digits, we're done,
	regardless of what they contain */
	}
	else if (exponent_digit_cnt > MIN_EXPONENT_DIGITS) {
	int extra_zeros_cnt;

	/* There are more than 2 digits in the exponent. See
	if we can delete some of the leading zeros */
	if (significant_digit_cnt < MIN_EXPONENT_DIGITS)
	significant_digit_cnt = MIN_EXPONENT_DIGITS;
	extra_zeros_cnt = exponent_digit_cnt -
	significant_digit_cnt;

	/* Delete extra_zeros_cnt worth of characters from the
	front of the exponent */
	assert(extra_zeros_cnt >= 0);

	/* Add one to significant_digit_cnt to copy the
	trailing 0 byte, thus setting the length */
	memmove(start,
	start + extra_zeros_cnt,
	significant_digit_cnt + 1);
	}
	else {
	/* If there are fewer than 2 digits, add zeros
	until there are 2, if there's enough room */
	int zeros = MIN_EXPONENT_DIGITS - exponent_digit_cnt;
	if (start + zeros + exponent_digit_cnt + 1
	< buffer + buf_size) {
	memmove(start + zeros, start,
	exponent_digit_cnt + 1);
	memset(start, '0', zeros);
	}
	}
	}
	}

	/* Ensure that buffer has a decimal point in it. The decimal point
	will not be in the current locale, it will always be '.' */
	Py_LOCAL_INLINE(void)
	ensure_decimal_point(char* buffer, size_t buf_size)
	{
	int insert_count = 0;
	char* chars_to_insert;

	/* search for the first non-digit character */
	char *p = buffer;
	if (p == '-' \|\| p == '+')
	/* Skip leading sign, if present. I think this could only
	ever be '-', but it can't hurt to check for both. */
	++p;
	while (p && isdigit(Py_CHARMASK(p)))
	++p;

	if (*p == '.') {
	if (isdigit(Py_CHARMASK(*(p+1)))) {
	/* Nothing to do, we already have a decimal
	point and a digit after it */
	}
	else {
	/* We have a decimal point, but no following
	digit. Insert a zero after the decimal. */
	++p;
	chars_to_insert = "0";
	insert_count = 1;
	}
	}
	else {
	chars_to_insert = ".0";
	insert_count = 2;
	}
	if (insert_count) {
	size_t buf_len = strlen(buffer);
	if (buf_len + insert_count + 1 >= buf_size) {
	/* If there is not enough room in the buffer
	for the additional text, just skip it. It's
	not worth generating an error over. */
	}
	else {
	memmove(p + insert_count, p,
	buffer + strlen(buffer) - p + 1);
	memcpy(p, chars_to_insert, insert_count);
	}
	}
	}

	/* Add the locale specific grouping characters to buffer. Note
	that any decimal point (if it's present) in buffer is already
	locale-specific. Return 0 on error, else 1. */
	Py_LOCAL_INLINE(int)
	add_thousands_grouping(char* buffer, size_t buf_size)
	{
	Py_ssize_t len = strlen(buffer);
	struct lconv *locale_data = localeconv();
	const char *decimal_point = locale_data->decimal_point;

	/* Find the decimal point, if any. We're only concerned
	about the characters to the left of the decimal when
	adding grouping. */
	char *p = strstr(buffer, decimal_point);
	if (!p) {
	/* No decimal, use the entire string. */

	/* If any exponent, adjust p. */
	p = strpbrk(buffer, "eE");
	if (!p)
	/* No exponent and no decimal. Use the entire
	string. */
	p = buffer + len;
	}
	/* At this point, p points just past the right-most character we
	want to format. We need to add the grouping string for the
	characters between buffer and p. */
	return _PyString_InsertThousandsGrouping(buffer, len, p-buffer,
	buf_size, NULL, 1);
	}

	/* see FORMATBUFLEN in unicodeobject.c */
	#define FLOAT_FORMATBUFLEN 120

	/**
	* PyOS_ascii_formatd:
	* @buffer: A buffer to place the resulting string in
	* @buf_size: The length of the buffer.
	* @format: The printf()-style format to use for the
	* code to use for converting.
	* @d: The #gdouble to convert
	*
	* Converts a #gdouble to a string, using the '.' as
	* decimal point. To format the number you pass in
	* a printf()-style format string. Allowed conversion
	* specifiers are 'e', 'E', 'f', 'F', 'g', 'G', and 'n'.
	*
	* 'n' is the same as 'g', except it uses the current locale.
	* 'Z' is the same as 'g', except it always has a decimal and
	* at least one digit after the decimal.
	*
	* Return value: The pointer to the buffer with the converted string.
	**/
	char *
	PyOS_ascii_formatd(char *buffer,
	size_t buf_size,
	const char *format,
	double d)
	{
	char format_char;
	size_t format_len = strlen(format);

	/* For type 'n', we need to make a copy of the format string, because
	we're going to modify 'n' -> 'g', and format is const char*, so we
	can't modify it directly. FLOAT_FORMATBUFLEN should be longer than
	we ever need this to be. There's an upcoming check to ensure it's
	big enough. */
	/* Issue 2264: code 'Z' requires copying the format. 'Z' is 'g', but
	also with at least one character past the decimal. */
	char tmp_format[FLOAT_FORMATBUFLEN];

	/* The last character in the format string must be the format char */
	format_char = format[format_len - 1];

	if (format[0] != '%')
	return NULL;

	/* I'm not sure why this test is here. It's ensuring that the format
	string after the first character doesn't have a single quote, a
	lowercase l, or a percent. This is the reverse of the commented-out
	test about 10 lines ago. */
	if (strpbrk(format + 1, "'l%"))
	return NULL;

	/* Also curious about this function is that it accepts format strings
	like "%xg", which are invalid for floats. In general, the
	interface to this function is not very good, but changing it is
	difficult because it's a public API. */

	if (!(format_char == 'e' \|\| format_char == 'E' \|\|
	format_char == 'f' \|\| format_char == 'F' \|\|
	format_char == 'g' \|\| format_char == 'G' \|\|
	format_char == 'n' \|\| format_char == 'Z'))
	return NULL;

	/* Map 'n' or 'Z' format_char to 'g', by copying the format string and
	replacing the final char with a 'g' */
	if (format_char == 'n' \|\| format_char == 'Z') {
	if (format_len + 1 >= sizeof(tmp_format)) {
	/* The format won't fit in our copy. Error out. In
	practice, this will never happen and will be
	detected by returning NULL */
	return NULL;
	}
	strcpy(tmp_format, format);
	tmp_format[format_len - 1] = 'g';
	format = tmp_format;
	}


	/* Have PyOS_snprintf do the hard work */
	PyOS_snprintf(buffer, buf_size, format, d);

	/* Do various fixups on the return string */

	/* Get the current locale, and find the decimal point string.
	Convert that string back to a dot. Do not do this if using the
	'n' (number) format code, since we want to keep the localized
	decimal point in that case. */
	if (format_char != 'n')
	change_decimal_from_locale_to_dot(buffer);

	/* If an exponent exists, ensure that the exponent is at least
	MIN_EXPONENT_DIGITS digits, providing the buffer is large enough
	for the extra zeros. Also, if there are more than
	MIN_EXPONENT_DIGITS, remove as many zeros as possible until we get
	back to MIN_EXPONENT_DIGITS */
	ensure_minimum_exponent_length(buffer, buf_size);

	/* If format_char is 'Z', make sure we have at least one character
	after the decimal point (and make sure we have a decimal point). */
	if (format_char == 'Z')
	ensure_decimal_point(buffer, buf_size);

	/* If format_char is 'n', add the thousands grouping. */
	if (format_char == 'n')
	if (!add_thousands_grouping(buffer, buf_size))
	return NULL;

	return buffer;
	}

	double
	PyOS_ascii_atof(const char *nptr)
	{
	return PyOS_ascii_strtod(nptr, NULL);
	}