/* +----------------------------------------------------------------------+ | PHP version 4.0 | +----------------------------------------------------------------------+ | Copyright (c) 1997, 1998, 1999, 2000 The PHP Group | +----------------------------------------------------------------------+ | This source file is subject to version 2.02 of the PHP license, | | that is bundled with this package in the file LICENSE, and is | | available at through the world-wide-web at | | http://www.php.net/license/2_02.txt. | | If you did not receive a copy of the PHP license and are unable to | | obtain it through the world-wide-web, please send a note to | | license@php.net so we can mail you a copy immediately. | +----------------------------------------------------------------------+ | Authors: Jim Winstead (jimw@php.net) | | Stig Sæther Bakken | | Zeev Suraski | | PHP 4.0 patches by Thies C. Arntzen (thies@digicol.de) | +----------------------------------------------------------------------+ */ /* $Id: */ #include "php.h" #include "php_math.h" #include #include #ifndef M_PI #define M_PI 3.14159265358979323846 #endif char *_php_math_number_format(double, int, char ,char); /* {{{ proto int abs(int number) Return the absolute value of the number */ PHP_FUNCTION(abs) { zval **value; if (ZEND_NUM_ARGS()!=1||zend_get_parameters_ex(1,&value)==FAILURE) { WRONG_PARAM_COUNT; } convert_scalar_to_number_ex(value); if ((*value)->type == IS_DOUBLE) { RETURN_DOUBLE(fabs((*value)->value.dval)); } else if ((*value)->type == IS_LONG) { RETURN_LONG((*value)->value.lval < 0 ? -(*value)->value.lval : (*value)->value.lval); } RETURN_FALSE; } /* }}} */ /* {{{ proto int ceil(double number) Returns the next highest integer value of the number */ PHP_FUNCTION(ceil) { zval **value; if (ZEND_NUM_ARGS()!=1||zend_get_parameters_ex(1,&value)==FAILURE) { WRONG_PARAM_COUNT; } convert_scalar_to_number_ex(value); if ((*value)->type == IS_DOUBLE) { RETURN_LONG((long)ceil((*value)->value.dval)); } else if ((*value)->type == IS_LONG) { RETURN_LONG((*value)->value.lval); } RETURN_FALSE; } /* }}} */ /* {{{ proto int floor(double number) Returns the next lowest integer value from the number */ PHP_FUNCTION(floor) { zval **value; if (ZEND_NUM_ARGS()!=1||zend_get_parameters_ex(1,&value)==FAILURE) { WRONG_PARAM_COUNT; } convert_scalar_to_number_ex(value); if ((*value)->type == IS_DOUBLE) { RETURN_LONG((long)floor((*value)->value.dval)); } else if ((*value)->type == IS_LONG) { RETURN_LONG((*value)->value.lval); } RETURN_FALSE; } /* }}} */ /* {{{ proto double round(double number [, int precision]) Returns the number rounded to specified precision. */ PHP_FUNCTION(round) { zval **value, **precision; int places = 0; double f, return_val; if (ZEND_NUM_ARGS() < 1 || ZEND_NUM_ARGS() > 2 || zend_get_parameters_ex(ZEND_NUM_ARGS(), &value, &precision) == FAILURE) { WRONG_PARAM_COUNT; } if (ZEND_NUM_ARGS() == 2) { convert_to_long_ex(precision); places = (int) Z_LVAL_PP(precision); } convert_scalar_to_number_ex(value); switch (Z_TYPE_PP(value)) { case IS_LONG: /* Simple case - long that doesn't need to be rounded. */ if (places >= 0) { RETURN_DOUBLE((double) Z_LVAL_PP(value)); } /* break omitted intentionally */ case IS_DOUBLE: return_val = (Z_TYPE_PP(value) == IS_LONG) ? (double)Z_LVAL_PP(value) : Z_DVAL_PP(value); f = pow(10.0, places); return_val *= f; if (return_val >= 0.0) return_val = floor(return_val + 0.5); else return_val = ceil(return_val - 0.5); return_val /= f; RETURN_DOUBLE(return_val); break; default: RETURN_FALSE; break; } } /* }}} */ /* {{{ proto double sin(double number) Returns the sine of the number in radians */ PHP_FUNCTION(sin) { zval **num; if (ZEND_NUM_ARGS() != 1 || zend_get_parameters_ex(1, &num) == FAILURE) { WRONG_PARAM_COUNT; } convert_to_double_ex(num); return_value->value.dval = sin((*num)->value.dval); return_value->type = IS_DOUBLE; } /* }}} */ /* {{{ proto double cos(double number) Returns the cosine of the number in radians */ PHP_FUNCTION(cos) { zval **num; if (ZEND_NUM_ARGS() != 1 || zend_get_parameters_ex(1, &num) == FAILURE) { WRONG_PARAM_COUNT; } convert_to_double_ex(num); return_value->value.dval = cos((*num)->value.dval); return_value->type = IS_DOUBLE; } /* }}} */ /* {{{ proto double tan(double number) Returns the tangent of the number in radians */ PHP_FUNCTION(tan) { zval **num; if (ZEND_NUM_ARGS() != 1 || zend_get_parameters_ex(1, &num) == FAILURE) { WRONG_PARAM_COUNT; } convert_to_double_ex(num); return_value->value.dval = tan((*num)->value.dval); return_value->type = IS_DOUBLE; } /* }}} */ /* {{{ proto double asin(double number) Returns the arc sine of the number in radians */ PHP_FUNCTION(asin) { zval **num; if (ZEND_NUM_ARGS() != 1 || zend_get_parameters_ex(1, &num) == FAILURE) { WRONG_PARAM_COUNT; } convert_to_double_ex(num); return_value->value.dval = asin((*num)->value.dval); return_value->type = IS_DOUBLE; } /* }}} */ /* {{{ proto double acos(double number) Return the arc cosine of the number in radians */ PHP_FUNCTION(acos) { zval **num; if (ZEND_NUM_ARGS() != 1 || zend_get_parameters_ex(1, &num) == FAILURE) { WRONG_PARAM_COUNT; } convert_to_double_ex(num); return_value->value.dval = acos((*num)->value.dval); return_value->type = IS_DOUBLE; } /* }}} */ /* {{{ proto double atan(double number) Returns the arc tangent of the number in radians */ PHP_FUNCTION(atan) { zval **num; if (ZEND_NUM_ARGS() != 1 || zend_get_parameters_ex(1, &num) == FAILURE) { WRONG_PARAM_COUNT; } convert_to_double_ex(num); return_value->value.dval = atan((*num)->value.dval); return_value->type = IS_DOUBLE; } /* }}} */ /* {{{ proto double atan2(double y, double x) Returns the arc tangent of y/x, with the resulting quadrant determined by the signs of y and x */ PHP_FUNCTION(atan2) { zval **num1, **num2; if (ZEND_NUM_ARGS() != 2 || zend_get_parameters_ex(2, &num1, &num2) == FAILURE) { WRONG_PARAM_COUNT; } convert_to_double_ex(num1); convert_to_double_ex(num2); return_value->value.dval = atan2((*num1)->value.dval,(*num2)->value.dval); return_value->type = IS_DOUBLE; } /* }}} */ /* {{{ proto double pi(void) Returns an approximation of pi */ PHP_FUNCTION(pi) { return_value->value.dval = M_PI; return_value->type = IS_DOUBLE; } /* }}} */ /* {{{ proto double pow(double base, double exponent) Returns base raised to the power of exponent */ PHP_FUNCTION(pow) { zval **num1, **num2; if (ZEND_NUM_ARGS() != 2 || zend_get_parameters_ex(2,&num1,&num2) == FAILURE) { WRONG_PARAM_COUNT; } convert_to_double_ex(num1); convert_to_double_ex(num2); RETURN_DOUBLE(pow((*num1)->value.dval, (*num2)->value.dval)); } /* }}} */ /* {{{ proto double exp(double number) Returns e raised to the power of the number */ PHP_FUNCTION(exp) { zval **num; if (ZEND_NUM_ARGS() != 1 || zend_get_parameters_ex(1, &num) == FAILURE) { WRONG_PARAM_COUNT; } convert_to_double_ex(num); return_value->value.dval = exp((*num)->value.dval); return_value->type = IS_DOUBLE; } /* }}} */ /* {{{ proto double log(double number) Returns the natural logarithm of the number */ PHP_FUNCTION(log) { zval **num; if (ZEND_NUM_ARGS() != 1 || zend_get_parameters_ex(1, &num) == FAILURE) { WRONG_PARAM_COUNT; } convert_to_double_ex(num); return_value->value.dval = log((*num)->value.dval); return_value->type = IS_DOUBLE; } /* }}} */ /* {{{ proto double log10(double number) Returns the base-10 logarithm of the number */ PHP_FUNCTION(log10) { zval **num; if (ZEND_NUM_ARGS() != 1 || zend_get_parameters_ex(1, &num) == FAILURE) { WRONG_PARAM_COUNT; } convert_to_double_ex(num); return_value->value.dval = log10((*num)->value.dval); return_value->type = IS_DOUBLE; } /* }}} */ /* {{{ proto double sqrt(double number) Returns the square root of the number */ PHP_FUNCTION(sqrt) { zval **num; if (ZEND_NUM_ARGS() != 1 || zend_get_parameters_ex(1, &num) == FAILURE) { WRONG_PARAM_COUNT; } convert_to_double_ex(num); return_value->value.dval = sqrt((*num)->value.dval); return_value->type = IS_DOUBLE; } /* }}} */ /* {{{ proto double deg2rad(double number) Converts the number in degrees to the radian equivalent */ PHP_FUNCTION(deg2rad) { zval **deg; if (ZEND_NUM_ARGS() != 1 || zend_get_parameters_ex(1, °) == FAILURE) { WRONG_PARAM_COUNT; } convert_to_double_ex(deg); RETVAL_DOUBLE(((*deg)->value.dval / 180.0) * M_PI); } /* }}} */ /* {{{ proto double rad2deg(double number) Converts the radian number to the equivalent number in degrees */ PHP_FUNCTION(rad2deg) { zval **rad; if (ZEND_NUM_ARGS() != 1 || zend_get_parameters_ex(1, &rad) == FAILURE) { WRONG_PARAM_COUNT; } convert_to_double_ex(rad); RETVAL_DOUBLE(((*rad)->value.dval / M_PI) * 180); } /* }}} */ /* {{{ _php_math_basetolong */ /* * Convert a string representation of a base(2-36) number to a long. */ static long _php_math_basetolong(zval *arg, int base) { long mult = 1, num = 0, digit; int i; char c, *s; if (arg->type != IS_STRING || base < 2 || base > 36) { return 0; } s = arg->value.str.val; for (i = arg->value.str.len - 1; i >= 0; i--, mult *= base) { c = toupper(s[i]); if (c >= '0' && c <= '9') { digit = (c - '0'); } else if (c >= 'A' && c <= 'Z') { digit = (c - 'A' + 10); } else { continue; } if (digit >= base) { continue; } num += mult * digit; } return num; } /* }}} */ /* {{{ _php_math_longtobase */ /* * Convert a long to a string containing a base(2-36) representation of * the number. */ static char * _php_math_longtobase(zval *arg, int base) { static char digits[] = "0123456789abcdefghijklmnopqrstuvwxyz"; char *result, *ptr, *ret; int len, digit; long value; if (arg->type != IS_LONG || base < 2 || base > 36) { return empty_string; } value = arg->value.lval; /* allocates space for the longest possible result with the lowest base */ len = (sizeof(arg->value.lval) * 8) + 1; result = emalloc((sizeof(arg->value.lval) * 8) + 1); ptr = result + len - 1; *ptr-- = '\0'; do { digit = value % base; *ptr = digits[digit]; value /= base; } while (ptr-- > result && value); ptr++; ret = estrdup(ptr); efree(result); return ret; } /* }}} */ /* {{{ proto int bindec(string binary_number) Returns the decimal equivalent of the binary number */ PHP_FUNCTION(bindec) { zval **arg; long ret; if (ZEND_NUM_ARGS() != 1 || zend_get_parameters_ex(1, &arg) == FAILURE) { WRONG_PARAM_COUNT; } convert_to_string_ex(arg); ret = _php_math_basetolong(*arg, 2); RETVAL_LONG(ret); } /* }}} */ /* {{{ proto int hexdec(string hexadecimal_number) Returns the decimal equivalent of the hexadecimal number */ PHP_FUNCTION(hexdec) { zval **arg; long ret; if (ZEND_NUM_ARGS() != 1 || zend_get_parameters_ex(1, &arg) == FAILURE) { WRONG_PARAM_COUNT; } convert_to_string_ex(arg); ret = _php_math_basetolong(*arg, 16); RETVAL_LONG(ret); } /* }}} */ /* {{{ proto int octdec(string octal_number) Returns the decimal equivalent of an octal string */ PHP_FUNCTION(octdec) { zval **arg; long ret; if (ZEND_NUM_ARGS() != 1 || zend_get_parameters_ex(1, &arg) == FAILURE) { WRONG_PARAM_COUNT; } convert_to_string_ex(arg); ret = _php_math_basetolong(*arg, 8); RETVAL_LONG(ret); } /* }}} */ /* {{{ proto string decbin(int decimal_number) Returns a string containing a binary representation of the number */ PHP_FUNCTION(decbin) { zval **arg; char *result; if (ZEND_NUM_ARGS() != 1 || zend_get_parameters_ex(1, &arg) == FAILURE) { WRONG_PARAM_COUNT; } convert_to_long_ex(arg); result = _php_math_longtobase(*arg, 2); return_value->type = IS_STRING; return_value->value.str.len = strlen(result); return_value->value.str.val = result; } /* }}} */ /* {{{ proto string decoct(int decimal_number) Returns a string containing an octal representation of the given number */ PHP_FUNCTION(decoct) { zval **arg; char *result; if (ZEND_NUM_ARGS() != 1 || zend_get_parameters_ex(1, &arg) == FAILURE) { WRONG_PARAM_COUNT; } convert_to_long_ex(arg); result = _php_math_longtobase(*arg, 8); return_value->type = IS_STRING; return_value->value.str.len = strlen(result); return_value->value.str.val = result; } /* }}} */ /* {{{ proto string dechex(int decimal_number) Returns a string containing a hexadecimal representation of the given number */ PHP_FUNCTION(dechex) { zval **arg; char *result; if (ZEND_NUM_ARGS() != 1 || zend_get_parameters_ex(1, &arg) == FAILURE) { WRONG_PARAM_COUNT; } convert_to_long_ex(arg); result = _php_math_longtobase(*arg, 16); return_value->type = IS_STRING; return_value->value.str.len = strlen(result); return_value->value.str.val = result; } /* }}} */ /* {{{ proto string base_convert(string number, int frombase, int tobase) Converts a number in a string from any base <= 36 to any base <= 36. */ PHP_FUNCTION(base_convert) { zval **number, **frombase, **tobase, temp; char *result; if (ZEND_NUM_ARGS() != 3 || zend_get_parameters_ex(3, &number, &frombase, &tobase) == FAILURE) { WRONG_PARAM_COUNT; } convert_to_string_ex(number); convert_to_long_ex(frombase); convert_to_long_ex(tobase); if ((*frombase)->value.lval < 2 || (*frombase)->value.lval > 36) { php_error(E_WARNING, "base_convert: invalid `from base' (%d)",(*frombase)->value.lval); RETURN_FALSE; } if ((*tobase)->value.lval < 2 || (*tobase)->value.lval > 36) { php_error(E_WARNING, "base_convert: invalid `to base' (%d)",(*tobase)->value.lval); RETURN_FALSE; } temp.type = IS_LONG; temp.value.lval = _php_math_basetolong(*number, (*frombase)->value.lval); result = _php_math_longtobase(&temp, (*tobase)->value.lval); RETVAL_STRING(result, 0); } /* }}} */ /* {{{ _php_math_number_format */ char *_php_math_number_format(double d,int dec,char dec_point,char thousand_sep) { char *tmpbuf,*resbuf; char *s,*t; /* source, target */ int tmplen,reslen=0; int count=0; int is_negative=0; if (d<0) { is_negative=1; d = -d; } dec = MAX(0,dec); tmpbuf = (char *) emalloc(1+DBL_MAX_10_EXP+1+dec+1); tmplen=sprintf(tmpbuf,"%.*f",dec,d); if (!isdigit((int)tmpbuf[0])) { return tmpbuf; } if (dec) { reslen = dec+1 + (tmplen-dec-1) + (tmplen-1-dec-1)/3; } else { reslen = tmplen+(tmplen-1)/3; } if (is_negative) { reslen++; } resbuf = (char *) emalloc(reslen+1); s = tmpbuf+tmplen-1; t = resbuf+reslen; *t-- = 0; if (dec) { while (isdigit((int)*s)) { *t-- = *s--; } *t-- = dec_point; /* copy that dot */ s--; } while(s>=tmpbuf) { *t-- = *s--; if ((++count%3)==0 && s>=tmpbuf) { *t-- = thousand_sep; } } if (is_negative) { *t-- = '-'; } efree(tmpbuf); return resbuf; } /* }}} */ /* {{{ proto string number_format(double number [, int num_decimal_places [, string dec_seperator, string thousands_seperator]]) Formats a number with grouped thousands */ PHP_FUNCTION(number_format) { zval **num,**dec,**t_s,**d_p; char thousand_sep=',', dec_point='.'; switch(ZEND_NUM_ARGS()) { case 1: if (zend_get_parameters_ex(1, &num)==FAILURE) { RETURN_FALSE; } convert_to_double_ex(num); RETURN_STRING(_php_math_number_format((*num)->value.dval,0,dec_point,thousand_sep),0); break; case 2: if (zend_get_parameters_ex(2, &num, &dec)==FAILURE) { RETURN_FALSE; } convert_to_double_ex(num); convert_to_long_ex(dec); RETURN_STRING(_php_math_number_format((*num)->value.dval,(*dec)->value.lval,dec_point,thousand_sep),0); break; case 4: if (zend_get_parameters_ex(4, &num, &dec, &d_p, &t_s)==FAILURE) { RETURN_FALSE; } convert_to_double_ex(num); convert_to_long_ex(dec); convert_to_string_ex(d_p); convert_to_string_ex(t_s); if ((*d_p)->value.str.len==1) { dec_point=(*d_p)->value.str.val[0]; } if ((*t_s)->value.str.len==1) { thousand_sep=(*t_s)->value.str.val[0]; } RETURN_STRING(_php_math_number_format((*num)->value.dval,(*dec)->value.lval,dec_point,thousand_sep),0); break; default: WRONG_PARAM_COUNT; break; } } /* }}} */ /* * Local variables: * tab-width: 4 * c-basic-offset: 4 * End: */