[apple/javascriptcore.git] / tests / mozilla / ecma / Expressions / 11.5.1.js

/* The contents of this file are subject to the Netscape Public
 * License Version 1.1 (the "License"); you may not use this file
 * except in compliance with the License. You may obtain a copy of
 * the License at http://www.mozilla.org/NPL/
 *
 * Software distributed under the License is distributed on an "AS
 * IS" basis, WITHOUT WARRANTY OF ANY KIND, either express or
 * implied. See the License for the specific language governing
 * rights and limitations under the License.
 *
 * The Original Code is Mozilla Communicator client code, released March
 * 31, 1998.
 *
 * The Initial Developer of the Original Code is Netscape Communications
 * Corporation. Portions created by Netscape are
 * Copyright (C) 1998 Netscape Communications Corporation. All
 * Rights Reserved.
 *
 * Contributor(s): 
 * 
 */
/**
    File Name:          11.5.1.js
    ECMA Section:       11.5.1 Applying the * operator
    Description:

    11.5.1 Applying the * operator

    The * operator performs multiplication, producing the product of its
    operands. Multiplication is commutative. Multiplication is not always
    associative in ECMAScript, because of finite precision.

    The result of a floating-point multiplication is governed by the rules
    of IEEE 754 double-precision arithmetic:

    If either operand is NaN, the result is NaN.
    The sign of the result is positive if both operands have the same sign,
    negative if the operands have different signs.
    Multiplication of an infinity by a zero results in NaN.
    Multiplication of an infinity by an infinity results in an infinity.
    The sign is determined by the rule already stated above.
    Multiplication of an infinity by a finite non-zero value results in a
    signed infinity. The sign is determined by the rule already stated above.
    In the remaining cases, where neither an infinity or NaN is involved, the
    product is computed and rounded to the nearest representable value using IEEE
    754 round-to-nearest mode. If the magnitude is too large to represent,
    the result is then an infinity of appropriate sign. If the magnitude is
    oo small to represent, the result is then a zero
    of appropriate sign. The ECMAScript language requires support of gradual
    underflow as defined by IEEE 754.

    Author:             christine@netscape.com
    Date:               12 november 1997
*/
    var SECTION = "11.5.1";
    var VERSION = "ECMA_1";
    startTest();
    var testcases = getTestCases();

    writeHeaderToLog( SECTION + " Applying the * operator");
    test();

function test() {
    for ( tc=0; tc < testcases.length; tc++ ) {
        testcases[tc].passed = writeTestCaseResult(
                            testcases[tc].expect,
                            testcases[tc].actual,
                            testcases[tc].description +" = "+
                            testcases[tc].actual );

        testcases[tc].reason += ( testcases[tc].passed ) ? "" : "wrong value ";
    }
    stopTest();
    return ( testcases );
}
function getTestCases() {
    var array = new Array();
    var item = 0;

    array[item++] = new TestCase( SECTION,    "Number.NaN * Number.NaN",    Number.NaN,     Number.NaN * Number.NaN );
    array[item++] = new TestCase( SECTION,    "Number.NaN * 1",             Number.NaN,     Number.NaN * 1 );
    array[item++] = new TestCase( SECTION,    "1 * Number.NaN",             Number.NaN,     1 * Number.NaN );

    array[item++] = new TestCase( SECTION,    "Number.POSITIVE_INFINITY * 0",   Number.NaN, Number.POSITIVE_INFINITY * 0 );
    array[item++] = new TestCase( SECTION,    "Number.NEGATIVE_INFINITY * 0",   Number.NaN, Number.NEGATIVE_INFINITY * 0 );
    array[item++] = new TestCase( SECTION,    "0 * Number.POSITIVE_INFINITY",   Number.NaN, 0 * Number.POSITIVE_INFINITY );
    array[item++] = new TestCase( SECTION,    "0 * Number.NEGATIVE_INFINITY",   Number.NaN, 0 * Number.NEGATIVE_INFINITY );

    array[item++] = new TestCase( SECTION,    "-0 * Number.POSITIVE_INFINITY",  Number.NaN,   -0 * Number.POSITIVE_INFINITY );
    array[item++] = new TestCase( SECTION,    "-0 * Number.NEGATIVE_INFINITY",  Number.NaN,   -0 * Number.NEGATIVE_INFINITY );
    array[item++] = new TestCase( SECTION,    "Number.POSITIVE_INFINITY * -0",  Number.NaN,   Number.POSITIVE_INFINITY * -0 );
    array[item++] = new TestCase( SECTION,    "Number.NEGATIVE_INFINITY * -0",  Number.NaN,   Number.NEGATIVE_INFINITY * -0 );

    array[item++] = new TestCase( SECTION,    "0 * -0",                         -0,         0 * -0 );
    array[item++] = new TestCase( SECTION,    "-0 * 0",                         -0,         -0 * 0 );
    array[item++] = new TestCase( SECTION,    "-0 * -0",                        0,          -0 * -0 );
    array[item++] = new TestCase( SECTION,    "0 * 0",                          0,          0 * 0 );

    array[item++] = new TestCase( SECTION,    "Number.NEGATIVE_INFINITY * Number.NEGATIVE_INFINITY",    Number.POSITIVE_INFINITY,   Number.NEGATIVE_INFINITY * Number.NEGATIVE_INFINITY );
    array[item++] = new TestCase( SECTION,    "Number.POSITIVE_INFINITY * Number.NEGATIVE_INFINITY",    Number.NEGATIVE_INFINITY,   Number.POSITIVE_INFINITY * Number.NEGATIVE_INFINITY );
    array[item++] = new TestCase( SECTION,    "Number.NEGATIVE_INFINITY * Number.POSITIVE_INFINITY",    Number.NEGATIVE_INFINITY,   Number.NEGATIVE_INFINITY * Number.POSITIVE_INFINITY );
    array[item++] = new TestCase( SECTION,    "Number.POSITIVE_INFINITY * Number.POSITIVE_INFINITY",    Number.POSITIVE_INFINITY,   Number.POSITIVE_INFINITY * Number.POSITIVE_INFINITY );

    array[item++] = new TestCase( SECTION,    "Number.NEGATIVE_INFINITY * 1 ",                          Number.NEGATIVE_INFINITY,   Number.NEGATIVE_INFINITY * 1 );
    array[item++] = new TestCase( SECTION,    "Number.NEGATIVE_INFINITY * -1 ",                         Number.POSITIVE_INFINITY,   Number.NEGATIVE_INFINITY * -1 );
    array[item++] = new TestCase( SECTION,    "1 * Number.NEGATIVE_INFINITY",                           Number.NEGATIVE_INFINITY,   1 * Number.NEGATIVE_INFINITY );
    array[item++] = new TestCase( SECTION,    "-1 * Number.NEGATIVE_INFINITY",                          Number.POSITIVE_INFINITY,   -1 * Number.NEGATIVE_INFINITY );

    array[item++] = new TestCase( SECTION,    "Number.POSITIVE_INFINITY * 1 ",                          Number.POSITIVE_INFINITY,   Number.POSITIVE_INFINITY * 1 );
    array[item++] = new TestCase( SECTION,    "Number.POSITIVE_INFINITY * -1 ",                         Number.NEGATIVE_INFINITY,   Number.POSITIVE_INFINITY * -1 );
    array[item++] = new TestCase( SECTION,    "1 * Number.POSITIVE_INFINITY",                           Number.POSITIVE_INFINITY,   1 * Number.POSITIVE_INFINITY );
    array[item++] = new TestCase( SECTION,    "-1 * Number.POSITIVE_INFINITY",                          Number.NEGATIVE_INFINITY,   -1 * Number.POSITIVE_INFINITY );

    return ( array );
}
Commit	Line	Data
b37bf2e1 A	1	/* The contents of this file are subject to the Netscape Public
	2	* License Version 1.1 (the "License"); you may not use this file
	3	* except in compliance with the License. You may obtain a copy of
	4	* the License at http://www.mozilla.org/NPL/
	5	*
	6	* Software distributed under the License is distributed on an "AS
	7	* IS" basis, WITHOUT WARRANTY OF ANY KIND, either express or
	8	* implied. See the License for the specific language governing
	9	* rights and limitations under the License.
	10	*
	11	* The Original Code is Mozilla Communicator client code, released March
	12	* 31, 1998.
	13	*
	14	* The Initial Developer of the Original Code is Netscape Communications
	15	* Corporation. Portions created by Netscape are
	16	* Copyright (C) 1998 Netscape Communications Corporation. All
	17	* Rights Reserved.
	18	*
	19	* Contributor(s):
	20	*
	21	*/
	22	/**
	23	File Name: 11.5.1.js
	24	ECMA Section: 11.5.1 Applying the * operator
	25	Description:
	26
	27	11.5.1 Applying the * operator
	28
	29	The * operator performs multiplication, producing the product of its
	30	operands. Multiplication is commutative. Multiplication is not always
	31	associative in ECMAScript, because of finite precision.
	32
	33	The result of a floating-point multiplication is governed by the rules
	34	of IEEE 754 double-precision arithmetic:
	35
	36	If either operand is NaN, the result is NaN.
	37	The sign of the result is positive if both operands have the same sign,
	38	negative if the operands have different signs.
	39	Multiplication of an infinity by a zero results in NaN.
	40	Multiplication of an infinity by an infinity results in an infinity.
	41	The sign is determined by the rule already stated above.
	42	Multiplication of an infinity by a finite non-zero value results in a
	43	signed infinity. The sign is determined by the rule already stated above.
	44	In the remaining cases, where neither an infinity or NaN is involved, the
	45	product is computed and rounded to the nearest representable value using IEEE
	46	754 round-to-nearest mode. If the magnitude is too large to represent,
	47	the result is then an infinity of appropriate sign. If the magnitude is
	48	oo small to represent, the result is then a zero
	49	of appropriate sign. The ECMAScript language requires support of gradual
	50	underflow as defined by IEEE 754.
	51
	52	Author: christine@netscape.com
	53	Date: 12 november 1997
	54	*/
	55	var SECTION = "11.5.1";
	56	var VERSION = "ECMA_1";
	57	startTest();
	58	var testcases = getTestCases();
	59
	60	writeHeaderToLog( SECTION + " Applying the * operator");
	61	test();
	62
	63	function test() {
	64	for ( tc=0; tc < testcases.length; tc++ ) {
65	testcases[tc].passed = writeTestCaseResult(
66	testcases[tc].expect,
67	testcases[tc].actual,
68	testcases[tc].description +" = "+
69	testcases[tc].actual );
70
71	testcases[tc].reason += ( testcases[tc].passed ) ? "" : "wrong value ";
72	}
73	stopTest();
74	return ( testcases );
75	}
76	function getTestCases() {
77	var array = new Array();
78	var item = 0;
79
80	array[item++] = new TestCase( SECTION, "Number.NaN * Number.NaN", Number.NaN, Number.NaN * Number.NaN );
81	array[item++] = new TestCase( SECTION, "Number.NaN * 1", Number.NaN, Number.NaN * 1 );
82	array[item++] = new TestCase( SECTION, "1 * Number.NaN", Number.NaN, 1 * Number.NaN );
83
84	array[item++] = new TestCase( SECTION, "Number.POSITIVE_INFINITY * 0", Number.NaN, Number.POSITIVE_INFINITY * 0 );
85	array[item++] = new TestCase( SECTION, "Number.NEGATIVE_INFINITY * 0", Number.NaN, Number.NEGATIVE_INFINITY * 0 );
86	array[item++] = new TestCase( SECTION, "0 * Number.POSITIVE_INFINITY", Number.NaN, 0 * Number.POSITIVE_INFINITY );
87	array[item++] = new TestCase( SECTION, "0 * Number.NEGATIVE_INFINITY", Number.NaN, 0 * Number.NEGATIVE_INFINITY );
88
89	array[item++] = new TestCase( SECTION, "-0 * Number.POSITIVE_INFINITY", Number.NaN, -0 * Number.POSITIVE_INFINITY );
90	array[item++] = new TestCase( SECTION, "-0 * Number.NEGATIVE_INFINITY", Number.NaN, -0 * Number.NEGATIVE_INFINITY );
91	array[item++] = new TestCase( SECTION, "Number.POSITIVE_INFINITY * -0", Number.NaN, Number.POSITIVE_INFINITY * -0 );
92	array[item++] = new TestCase( SECTION, "Number.NEGATIVE_INFINITY * -0", Number.NaN, Number.NEGATIVE_INFINITY * -0 );
93
94	array[item++] = new TestCase( SECTION, "0 * -0", -0, 0 * -0 );
95	array[item++] = new TestCase( SECTION, "-0 * 0", -0, -0 * 0 );
96	array[item++] = new TestCase( SECTION, "-0 * -0", 0, -0 * -0 );
97	array[item++] = new TestCase( SECTION, "0 * 0", 0, 0 * 0 );
98
99	array[item++] = new TestCase( SECTION, "Number.NEGATIVE_INFINITY * Number.NEGATIVE_INFINITY", Number.POSITIVE_INFINITY, Number.NEGATIVE_INFINITY * Number.NEGATIVE_INFINITY );
100	array[item++] = new TestCase( SECTION, "Number.POSITIVE_INFINITY * Number.NEGATIVE_INFINITY", Number.NEGATIVE_INFINITY, Number.POSITIVE_INFINITY * Number.NEGATIVE_INFINITY );
101	array[item++] = new TestCase( SECTION, "Number.NEGATIVE_INFINITY * Number.POSITIVE_INFINITY", Number.NEGATIVE_INFINITY, Number.NEGATIVE_INFINITY * Number.POSITIVE_INFINITY );
102	array[item++] = new TestCase( SECTION, "Number.POSITIVE_INFINITY * Number.POSITIVE_INFINITY", Number.POSITIVE_INFINITY, Number.POSITIVE_INFINITY * Number.POSITIVE_INFINITY );
103
104	array[item++] = new TestCase( SECTION, "Number.NEGATIVE_INFINITY * 1 ", Number.NEGATIVE_INFINITY, Number.NEGATIVE_INFINITY * 1 );
105	array[item++] = new TestCase( SECTION, "Number.NEGATIVE_INFINITY * -1 ", Number.POSITIVE_INFINITY, Number.NEGATIVE_INFINITY * -1 );
106	array[item++] = new TestCase( SECTION, "1 * Number.NEGATIVE_INFINITY", Number.NEGATIVE_INFINITY, 1 * Number.NEGATIVE_INFINITY );
107	array[item++] = new TestCase( SECTION, "-1 * Number.NEGATIVE_INFINITY", Number.POSITIVE_INFINITY, -1 * Number.NEGATIVE_INFINITY );
108
109	array[item++] = new TestCase( SECTION, "Number.POSITIVE_INFINITY * 1 ", Number.POSITIVE_INFINITY, Number.POSITIVE_INFINITY * 1 );
110	array[item++] = new TestCase( SECTION, "Number.POSITIVE_INFINITY * -1 ", Number.NEGATIVE_INFINITY, Number.POSITIVE_INFINITY * -1 );
111	array[item++] = new TestCase( SECTION, "1 * Number.POSITIVE_INFINITY", Number.POSITIVE_INFINITY, 1 * Number.POSITIVE_INFINITY );
112	array[item++] = new TestCase( SECTION, "-1 * Number.POSITIVE_INFINITY", Number.NEGATIVE_INFINITY, -1 * Number.POSITIVE_INFINITY );
113
114	return ( array );
115	}