src/third_party/mozjs-45/js/src/tests/ecma/GlobalObject/15.1.2.2-1.js - cobalt - Git at Google

 /* -*- tab-width: 2; indent-tabs-mode: nil; js-indent-level: 2 -*- */
 /* This Source Code Form is subject to the terms of the Mozilla Public
  * License, v. 2.0. If a copy of the MPL was not distributed with this
  * file, You can obtain one at http://mozilla.org/MPL/2.0/. */


 /**
    File Name:          15.1.2.2-1.js
    ECMA Section:       15.1.2.2 Function properties of the global object
    parseInt( string, radix )

    Description:

    The parseInt function produces an integer value dictated by intepretation
    of the contents of the string argument according to the specified radix.

    When the parseInt function is called, the following steps are taken:

    1.   Call ToString(string).
    2.   Compute a substring of Result(1) consisting of the leftmost character
    that is not a StrWhiteSpaceChar and all characters to the right of
    that character. (In other words, remove leading whitespace.)
    3.   Let sign be 1.
    4.   If Result(2) is not empty and the first character of Result(2) is a
    minus sign -, let sign be -1.
    5.   If Result(2) is not empty and the first character of Result(2) is a
    plus sign + or a minus sign -, then Result(5) is the substring of
    Result(2) produced by removing the first character; otherwise, Result(5)
    is Result(2).
    6.   If the radix argument is not supplied, go to step 12.
    7.   Call ToInt32(radix).
    8.   If Result(7) is zero, go to step 12; otherwise, if Result(7) < 2 or
    Result(7) > 36, return NaN.
    9.   Let R be Result(7).
    10.   If R = 16 and the length of Result(5) is at least 2 and the first two
    characters of Result(5) are either "0x" or "0X", let S be the substring
    of Result(5) consisting of all but the first two characters; otherwise,
    let S be Result(5).
    11.   Go to step 22.
    12.   If Result(5) is empty or the first character of Result(5) is not 0,
    go to step 20.
    13.   If the length of Result(5) is at least 2 and the second character of
    Result(5) is x or X, go to step 17.
    14.   Let R be 8.
    15.   Let S be Result(5).
    16.   Go to step 22.
    17.   Let R be 16.
    18.   Let S be the substring of Result(5) consisting of all but the first
    two characters.
    19.   Go to step 22.
    20.   Let R be 10.
    21.   Let S be Result(5).
    22.   If S contains any character that is not a radix-R digit, then let Z be
    the substring of S consisting of all characters to the left of the
    leftmost such character; otherwise, let Z be S.
    23.   If Z is empty, return NaN.
    24.   Compute the mathematical integer value that is represented by Z in
    radix-R notation. (But if R is 10 and Z contains more than 20
    significant digits, every digit after the 20th may be replaced by a 0
    digit, at the option of the implementation; and if R is not 2, 4, 8,
    10, 16, or 32, then Result(24) may be an implementation-dependent
    approximation to the mathematical integer value that is represented
    by Z in radix-R notation.)
    25.   Compute the number value for Result(24).
    26.   Return sign Result(25).

    Note that parseInt may interpret only a leading portion of the string as
    an integer value; it ignores any characters that cannot be interpreted as
    part of the notation of an integer, and no indication is given that any
    such characters were ignored.

    Author:             christine@netscape.com
    Date:               28 october 1997

 */
 var SECTION = "15.1.2.2-1";
 var VERSION = "ECMA_1";
 var TITLE   = "parseInt(string, radix)";
 var BUGNUMBER = "none";

 startTest();

 writeHeaderToLog( SECTION + " "+ TITLE);

 var HEX_STRING = "0x0";
 var HEX_VALUE = 0;

 new TestCase( SECTION,
 	      "parseInt.length",
 	      2,
 	      parseInt.length );

 new TestCase( SECTION,
 	      "parseInt.length = 0; parseInt.length",
 	      2,
 	      eval("parseInt.length = 0; parseInt.length") );

 new TestCase( SECTION,
 	      "var PROPS=''; for ( var p in parseInt ) { PROPS += p; }; PROPS",   "",
 	      eval("var PROPS=''; for ( var p in parseInt ) { PROPS += p; }; PROPS") );

 new TestCase( SECTION,
 	      "parseInt()",
 	      NaN,
 	      parseInt() );

 new TestCase( SECTION,
 	      "parseInt('')",
 	      NaN,
 	      parseInt("") );

 new TestCase( SECTION,
 	      "parseInt('','')",
 	      NaN,
 	      parseInt("","") );

 new TestCase( SECTION,
 	      "parseInt(\"     0xabcdef     ",
 	      11259375,
 	      parseInt( "      0xabcdef     " ));

 new TestCase( SECTION,
 	      "parseInt(\"     0XABCDEF     ",
 	      11259375,
 	      parseInt( "      0XABCDEF     " ) );

 new TestCase( SECTION,
 	      "parseInt( 0xabcdef )",
 	      11259375,
 	      parseInt( "0xabcdef") );

 new TestCase( SECTION,
 	      "parseInt( 0XABCDEF )",
 	      11259375,
 	      parseInt( "0XABCDEF") );

 for ( HEX_STRING = "0x0", HEX_VALUE = 0, POWER = 0; POWER < 15; POWER++, HEX_STRING = HEX_STRING +"f" ) {
   new TestCase( SECTION, "parseInt('"+HEX_STRING+"')",    HEX_VALUE,  parseInt(HEX_STRING) );
   HEX_VALUE += Math.pow(16,POWER)*15;
 }
 for ( HEX_STRING = "0X0", HEX_VALUE = 0, POWER = 0; POWER < 15; POWER++, HEX_STRING = HEX_STRING +"f" ) {
   new TestCase( SECTION, "parseInt('"+HEX_STRING+"')",    HEX_VALUE,  parseInt(HEX_STRING) );
   HEX_VALUE += Math.pow(16,POWER)*15;
 }
 for ( HEX_STRING = "0x0", HEX_VALUE = 0, POWER = 0; POWER < 15; POWER++, HEX_STRING = HEX_STRING +"f" ) {
   new TestCase( SECTION, "parseInt('"+HEX_STRING+"', 16)",    HEX_VALUE,  parseInt(HEX_STRING,16) );
   HEX_VALUE += Math.pow(16,POWER)*15;
 }
 for ( HEX_STRING = "0x0", HEX_VALUE = 0, POWER = 0; POWER < 15; POWER++, HEX_STRING = HEX_STRING +"f" ) {
   new TestCase( SECTION, "parseInt('"+HEX_STRING+"', 16)",    HEX_VALUE,  parseInt(HEX_STRING,16) );
   HEX_VALUE += Math.pow(16,POWER)*15;
 }
 for ( HEX_STRING = "0x0", HEX_VALUE = 0, POWER = 0; POWER < 15; POWER++, HEX_STRING = HEX_STRING +"f" ) {
   new TestCase( SECTION, "parseInt('"+HEX_STRING+"', null)",    HEX_VALUE,  parseInt(HEX_STRING,null) );
   HEX_VALUE += Math.pow(16,POWER)*15;
 }
 for ( HEX_STRING = "0x0", HEX_VALUE = 0, POWER = 0; POWER < 15; POWER++, HEX_STRING = HEX_STRING +"f" ) {
   new TestCase( SECTION, "parseInt('"+HEX_STRING+"', void 0)",    HEX_VALUE,  parseInt(HEX_STRING, void 0) );
   HEX_VALUE += Math.pow(16,POWER)*15;
 }

 // a few tests with spaces

 for ( var space = " ", HEX_STRING = "0x0", HEX_VALUE = 0, POWER = 0;
       POWER < 15;
       POWER++, HEX_STRING = HEX_STRING +"f", space += " ")
 {
   new TestCase( SECTION, "parseInt('"+space+HEX_STRING+space+"', void 0)",    HEX_VALUE,  parseInt(space+HEX_STRING+space, void 0) );
   HEX_VALUE += Math.pow(16,POWER)*15;
 }

 new TestCase(SECTION, "parseInt(BOM + '123', 10)", 123, parseInt("\uFEFF" + "123", 10));

 // a few tests with negative numbers
 for ( HEX_STRING = "-0x0", HEX_VALUE = 0, POWER = 0; POWER < 15; POWER++, HEX_STRING = HEX_STRING +"f" ) {
   new TestCase( SECTION, "parseInt('"+HEX_STRING+"')",    HEX_VALUE,  parseInt(HEX_STRING) );
   HEX_VALUE -= Math.pow(16,POWER)*15;
 }

 // we should stop parsing when we get to a value that is not a numeric literal for the type we expect

 for ( HEX_STRING = "0x0", HEX_VALUE = 0, POWER = 0; POWER < 15; POWER++, HEX_STRING = HEX_STRING +"f" ) {
   new TestCase( SECTION, "parseInt('"+HEX_STRING+"g', 16)",    HEX_VALUE,  parseInt(HEX_STRING+"g",16) );
   HEX_VALUE += Math.pow(16,POWER)*15;
 }
 for ( HEX_STRING = "0x0", HEX_VALUE = 0, POWER = 0; POWER < 15; POWER++, HEX_STRING = HEX_STRING +"f" ) {
   new TestCase( SECTION, "parseInt('"+HEX_STRING+"G', 16)",    HEX_VALUE,  parseInt(HEX_STRING+"G",16) );
   HEX_VALUE += Math.pow(16,POWER)*15;
 }

 for ( HEX_STRING = "-0x0", HEX_VALUE = 0, POWER = 0; POWER < 15; POWER++, HEX_STRING = HEX_STRING +"f" ) {
   new TestCase( SECTION, "parseInt('"+HEX_STRING+"')",    HEX_VALUE,  parseInt(HEX_STRING) );
   HEX_VALUE -= Math.pow(16,POWER)*15;
 }
 for ( HEX_STRING = "-0X0", HEX_VALUE = 0, POWER = 0; POWER < 15; POWER++, HEX_STRING = HEX_STRING +"f" ) {
   new TestCase( SECTION, "parseInt('"+HEX_STRING+"')",    HEX_VALUE,  parseInt(HEX_STRING) );
   HEX_VALUE -= Math.pow(16,POWER)*15;
 }
 for ( HEX_STRING = "-0x0", HEX_VALUE = 0, POWER = 0; POWER < 15; POWER++, HEX_STRING = HEX_STRING +"f" ) {
   new TestCase( SECTION, "parseInt('"+HEX_STRING+"', 16)",    HEX_VALUE,  parseInt(HEX_STRING,16) );
   HEX_VALUE -= Math.pow(16,POWER)*15;
 }
 for ( HEX_STRING = "-0x0", HEX_VALUE = 0, POWER = 0; POWER < 15; POWER++, HEX_STRING = HEX_STRING +"f" ) {
   new TestCase( SECTION, "parseInt('"+HEX_STRING+"', 16)",    HEX_VALUE,  parseInt(HEX_STRING,16) );
   HEX_VALUE -= Math.pow(16,POWER)*15;
 }

 // Numbers that start with 0 and do not provide a radix should use 10 as radix
 // per ES5, not octal (as it was in ES3).

 var OCT_STRING = "0";
 var OCT_VALUE = 0;

 for ( OCT_STRING = "0", OCT_VALUE = 0, POWER = 0; POWER < 15; POWER++, OCT_STRING = OCT_STRING +"7" ) {
   new TestCase( SECTION, "parseInt('"+OCT_STRING+"')",    OCT_VALUE,  parseInt(OCT_STRING) );
   OCT_VALUE += Math.pow(10,POWER)*7;
 }

 for ( OCT_STRING = "-0", OCT_VALUE = 0, POWER = 0; POWER < 15; POWER++, OCT_STRING = OCT_STRING +"7" ) {
   new TestCase( SECTION, "parseInt('"+OCT_STRING+"')",    OCT_VALUE,  parseInt(OCT_STRING) );
   OCT_VALUE -= Math.pow(10,POWER)*7;
 }

 // should get octal-based results if we provid the radix of 8 (or 010)

 for ( OCT_STRING = "0", OCT_VALUE = 0, POWER = 0; POWER < 15; POWER++, OCT_STRING = OCT_STRING +"7" ) {
   new TestCase( SECTION, "parseInt('"+OCT_STRING+"', 8)",    OCT_VALUE,  parseInt(OCT_STRING,8) );
   OCT_VALUE += Math.pow(8,POWER)*7;
 }
 for ( OCT_STRING = "-0", OCT_VALUE = 0, POWER = 0; POWER < 15; POWER++, OCT_STRING = OCT_STRING +"7" ) {
   new TestCase( SECTION, "parseInt('"+OCT_STRING+"', 010)",    OCT_VALUE,  parseInt(OCT_STRING,010) );
   OCT_VALUE -= Math.pow(8,POWER)*7;
 }

 // we shall stop parsing digits when we get one that isn't a numeric literal of the type we think
 // it should be.
 for ( OCT_STRING = "0", OCT_VALUE = 0, POWER = 0; POWER < 15; POWER++, OCT_STRING = OCT_STRING +"7" ) {
   new TestCase( SECTION, "parseInt('"+OCT_STRING+"8', 8)",    OCT_VALUE,  parseInt(OCT_STRING+"8",8) );
   OCT_VALUE += Math.pow(8,POWER)*7;
 }
 for ( OCT_STRING = "-0", OCT_VALUE = 0, POWER = 0; POWER < 15; POWER++, OCT_STRING = OCT_STRING +"7" ) {
   new TestCase( SECTION, "parseInt('"+OCT_STRING+"8', 010)",    OCT_VALUE,  parseInt(OCT_STRING+"8",010) );
   OCT_VALUE -= Math.pow(8,POWER)*7;
 }

 new TestCase( SECTION,
 	      "parseInt( '0x' )",
 	      NaN,
 	      parseInt("0x") );

 new TestCase( SECTION,
 	      "parseInt( '0X' )",
 	      NaN,
 	      parseInt("0X") );

 new TestCase( SECTION,
 	      "parseInt( '11111111112222222222' )",
 	      11111111112222222222,
 	      parseInt("11111111112222222222") );

 new TestCase( SECTION,
 	      "parseInt( '111111111122222222223' )",
 	      111111111122222222220,
 	      parseInt("111111111122222222223") );

 new TestCase( SECTION,
 	      "parseInt( '11111111112222222222',10 )",
 	      11111111112222222222,
 	      parseInt("11111111112222222222",10) );

 new TestCase( SECTION,
 	      "parseInt( '111111111122222222223',10 )",
 	      111111111122222222220,
 	      parseInt("111111111122222222223",10) );

 new TestCase( SECTION,
 	      "parseInt( '01234567890', -1 )",
 	      Number.NaN,
 	      parseInt("01234567890",-1) );

 new TestCase( SECTION,
 	      "parseInt( '01234567890', 0 )",
 	      1234567890,
 	      parseInt("01234567890", 0) );

 new TestCase( SECTION,
 	      "parseInt( '01234567890', 1 )",
 	      Number.NaN,
 	      parseInt("01234567890",1) );

 new TestCase( SECTION,
 	      "parseInt( '01234567890', 2 )",
 	      1,
 	      parseInt("01234567890",2) );

 new TestCase( SECTION,
 	      "parseInt( '01234567890', 3 )",
 	      5,
 	      parseInt("01234567890",3) );

 new TestCase( SECTION,
 	      "parseInt( '01234567890', 4 )",
 	      27,
 	      parseInt("01234567890",4) );

 new TestCase( SECTION,
 	      "parseInt( '01234567890', 5 )",
 	      194,
 	      parseInt("01234567890",5) );

 new TestCase( SECTION,
 	      "parseInt( '01234567890', 6 )",
 	      1865,
 	      parseInt("01234567890",6) );

 new TestCase( SECTION,
 	      "parseInt( '01234567890', 7 )",
 	      22875,
 	      parseInt("01234567890",7) );

 new TestCase( SECTION,
 	      "parseInt( '01234567890', 8 )",
 	      342391,
 	      parseInt("01234567890",8) );

 new TestCase( SECTION,
 	      "parseInt( '01234567890', 9 )",
 	      6053444,
 	      parseInt("01234567890",9) );

 new TestCase( SECTION,
 	      "parseInt( '01234567890', 10 )",
 	      1234567890,
 	      parseInt("01234567890",10) );

 // need more test cases with hex radix

 new TestCase( SECTION,
 	      "parseInt( '1234567890', '0xa')",
 	      1234567890,
 	      parseInt("1234567890","0xa") );

 new TestCase( SECTION,
 	      "parseInt( '012345', 11 )",
 	      17715,
 	      parseInt("012345",11) );

 new TestCase( SECTION,
 	      "parseInt( '012345', 35 )",
 	      1590195,
 	      parseInt("012345",35) );

 new TestCase( SECTION,
 	      "parseInt( '012345', 36 )",
 	      1776965,
 	      parseInt("012345",36) );

 new TestCase( SECTION,
 	      "parseInt( '012345', 37 )",
 	      Number.NaN,
 	      parseInt("012345",37) );

 test();
	/* -- tab-width: 2; indent-tabs-mode: nil; js-indent-level: 2 -- */
	/* This Source Code Form is subject to the terms of the Mozilla Public
	* License, v. 2.0. If a copy of the MPL was not distributed with this
	* file, You can obtain one at http://mozilla.org/MPL/2.0/. */


	/**
	File Name: 15.1.2.2-1.js
	ECMA Section: 15.1.2.2 Function properties of the global object
	parseInt( string, radix )

	Description:

	The parseInt function produces an integer value dictated by intepretation
	of the contents of the string argument according to the specified radix.

	When the parseInt function is called, the following steps are taken:

	1. Call ToString(string).
	2. Compute a substring of Result(1) consisting of the leftmost character
	that is not a StrWhiteSpaceChar and all characters to the right of
	that character. (In other words, remove leading whitespace.)
	3. Let sign be 1.
	4. If Result(2) is not empty and the first character of Result(2) is a
	minus sign -, let sign be -1.
	5. If Result(2) is not empty and the first character of Result(2) is a
	plus sign + or a minus sign -, then Result(5) is the substring of
	Result(2) produced by removing the first character; otherwise, Result(5)
	is Result(2).
	6. If the radix argument is not supplied, go to step 12.
	7. Call ToInt32(radix).
	8. If Result(7) is zero, go to step 12; otherwise, if Result(7) < 2 or
	Result(7) > 36, return NaN.
	9. Let R be Result(7).
	10. If R = 16 and the length of Result(5) is at least 2 and the first two
	characters of Result(5) are either "0x" or "0X", let S be the substring
	of Result(5) consisting of all but the first two characters; otherwise,
	let S be Result(5).
	11. Go to step 22.
	12. If Result(5) is empty or the first character of Result(5) is not 0,
	go to step 20.
	13. If the length of Result(5) is at least 2 and the second character of
	Result(5) is x or X, go to step 17.
	14. Let R be 8.
	15. Let S be Result(5).
	16. Go to step 22.
	17. Let R be 16.
	18. Let S be the substring of Result(5) consisting of all but the first
	two characters.
	19. Go to step 22.
	20. Let R be 10.
	21. Let S be Result(5).
	22. If S contains any character that is not a radix-R digit, then let Z be
	the substring of S consisting of all characters to the left of the
	leftmost such character; otherwise, let Z be S.
	23. If Z is empty, return NaN.
	24. Compute the mathematical integer value that is represented by Z in
	radix-R notation. (But if R is 10 and Z contains more than 20
	significant digits, every digit after the 20th may be replaced by a 0
	digit, at the option of the implementation; and if R is not 2, 4, 8,
	10, 16, or 32, then Result(24) may be an implementation-dependent
	approximation to the mathematical integer value that is represented
	by Z in radix-R notation.)
	25. Compute the number value for Result(24).
	26. Return sign Result(25).

	Note that parseInt may interpret only a leading portion of the string as
	an integer value; it ignores any characters that cannot be interpreted as
	part of the notation of an integer, and no indication is given that any
	such characters were ignored.

	Author: christine@netscape.com
	Date: 28 october 1997

	*/
	var SECTION = "15.1.2.2-1";
	var VERSION = "ECMA_1";
	var TITLE = "parseInt(string, radix)";
	var BUGNUMBER = "none";

	startTest();

	writeHeaderToLog( SECTION + " "+ TITLE);

	var HEX_STRING = "0x0";
	var HEX_VALUE = 0;

	new TestCase( SECTION,
	"parseInt.length",
	2,
	parseInt.length );

	new TestCase( SECTION,
	"parseInt.length = 0; parseInt.length",
	2,
	eval("parseInt.length = 0; parseInt.length") );

	new TestCase( SECTION,
	"var PROPS=''; for ( var p in parseInt ) { PROPS += p; }; PROPS", "",
	eval("var PROPS=''; for ( var p in parseInt ) { PROPS += p; }; PROPS") );

	new TestCase( SECTION,
	"parseInt()",
	NaN,
	parseInt() );

	new TestCase( SECTION,
	"parseInt('')",
	NaN,
	parseInt("") );

	new TestCase( SECTION,
	"parseInt('','')",
	NaN,
	parseInt("","") );

	new TestCase( SECTION,
	"parseInt(\" 0xabcdef ",
	11259375,
	parseInt( " 0xabcdef " ));

	new TestCase( SECTION,
	"parseInt(\" 0XABCDEF ",
	11259375,
	parseInt( " 0XABCDEF " ) );

	new TestCase( SECTION,
	"parseInt( 0xabcdef )",
	11259375,
	parseInt( "0xabcdef") );

	new TestCase( SECTION,
	"parseInt( 0XABCDEF )",
	11259375,
	parseInt( "0XABCDEF") );

	for ( HEX_STRING = "0x0", HEX_VALUE = 0, POWER = 0; POWER < 15; POWER++, HEX_STRING = HEX_STRING +"f" ) {
	new TestCase( SECTION, "parseInt('"+HEX_STRING+"')", HEX_VALUE, parseInt(HEX_STRING) );
	HEX_VALUE += Math.pow(16,POWER)*15;
	}
	for ( HEX_STRING = "0X0", HEX_VALUE = 0, POWER = 0; POWER < 15; POWER++, HEX_STRING = HEX_STRING +"f" ) {
	new TestCase( SECTION, "parseInt('"+HEX_STRING+"')", HEX_VALUE, parseInt(HEX_STRING) );
	HEX_VALUE += Math.pow(16,POWER)*15;
	}
	for ( HEX_STRING = "0x0", HEX_VALUE = 0, POWER = 0; POWER < 15; POWER++, HEX_STRING = HEX_STRING +"f" ) {
	new TestCase( SECTION, "parseInt('"+HEX_STRING+"', 16)", HEX_VALUE, parseInt(HEX_STRING,16) );
	HEX_VALUE += Math.pow(16,POWER)*15;
	}
	for ( HEX_STRING = "0x0", HEX_VALUE = 0, POWER = 0; POWER < 15; POWER++, HEX_STRING = HEX_STRING +"f" ) {
	new TestCase( SECTION, "parseInt('"+HEX_STRING+"', 16)", HEX_VALUE, parseInt(HEX_STRING,16) );
	HEX_VALUE += Math.pow(16,POWER)*15;
	}
	for ( HEX_STRING = "0x0", HEX_VALUE = 0, POWER = 0; POWER < 15; POWER++, HEX_STRING = HEX_STRING +"f" ) {
	new TestCase( SECTION, "parseInt('"+HEX_STRING+"', null)", HEX_VALUE, parseInt(HEX_STRING,null) );
	HEX_VALUE += Math.pow(16,POWER)*15;
	}
	for ( HEX_STRING = "0x0", HEX_VALUE = 0, POWER = 0; POWER < 15; POWER++, HEX_STRING = HEX_STRING +"f" ) {
	new TestCase( SECTION, "parseInt('"+HEX_STRING+"', void 0)", HEX_VALUE, parseInt(HEX_STRING, void 0) );
	HEX_VALUE += Math.pow(16,POWER)*15;
	}

	// a few tests with spaces

	for ( var space = " ", HEX_STRING = "0x0", HEX_VALUE = 0, POWER = 0;
	POWER < 15;
	POWER++, HEX_STRING = HEX_STRING +"f", space += " ")
	{
	new TestCase( SECTION, "parseInt('"+space+HEX_STRING+space+"', void 0)", HEX_VALUE, parseInt(space+HEX_STRING+space, void 0) );
	HEX_VALUE += Math.pow(16,POWER)*15;
	}

	new TestCase(SECTION, "parseInt(BOM + '123', 10)", 123, parseInt("\uFEFF" + "123", 10));

	// a few tests with negative numbers
	for ( HEX_STRING = "-0x0", HEX_VALUE = 0, POWER = 0; POWER < 15; POWER++, HEX_STRING = HEX_STRING +"f" ) {
	new TestCase( SECTION, "parseInt('"+HEX_STRING+"')", HEX_VALUE, parseInt(HEX_STRING) );
	HEX_VALUE -= Math.pow(16,POWER)*15;
	}

	// we should stop parsing when we get to a value that is not a numeric literal for the type we expect

	for ( HEX_STRING = "0x0", HEX_VALUE = 0, POWER = 0; POWER < 15; POWER++, HEX_STRING = HEX_STRING +"f" ) {
	new TestCase( SECTION, "parseInt('"+HEX_STRING+"g', 16)", HEX_VALUE, parseInt(HEX_STRING+"g",16) );
	HEX_VALUE += Math.pow(16,POWER)*15;
	}
	for ( HEX_STRING = "0x0", HEX_VALUE = 0, POWER = 0; POWER < 15; POWER++, HEX_STRING = HEX_STRING +"f" ) {
	new TestCase( SECTION, "parseInt('"+HEX_STRING+"G', 16)", HEX_VALUE, parseInt(HEX_STRING+"G",16) );
	HEX_VALUE += Math.pow(16,POWER)*15;
	}

	for ( HEX_STRING = "-0x0", HEX_VALUE = 0, POWER = 0; POWER < 15; POWER++, HEX_STRING = HEX_STRING +"f" ) {
	new TestCase( SECTION, "parseInt('"+HEX_STRING+"')", HEX_VALUE, parseInt(HEX_STRING) );
	HEX_VALUE -= Math.pow(16,POWER)*15;
	}
	for ( HEX_STRING = "-0X0", HEX_VALUE = 0, POWER = 0; POWER < 15; POWER++, HEX_STRING = HEX_STRING +"f" ) {
	new TestCase( SECTION, "parseInt('"+HEX_STRING+"')", HEX_VALUE, parseInt(HEX_STRING) );
	HEX_VALUE -= Math.pow(16,POWER)*15;
	}
	for ( HEX_STRING = "-0x0", HEX_VALUE = 0, POWER = 0; POWER < 15; POWER++, HEX_STRING = HEX_STRING +"f" ) {
	new TestCase( SECTION, "parseInt('"+HEX_STRING+"', 16)", HEX_VALUE, parseInt(HEX_STRING,16) );
	HEX_VALUE -= Math.pow(16,POWER)*15;
	}
	for ( HEX_STRING = "-0x0", HEX_VALUE = 0, POWER = 0; POWER < 15; POWER++, HEX_STRING = HEX_STRING +"f" ) {
	new TestCase( SECTION, "parseInt('"+HEX_STRING+"', 16)", HEX_VALUE, parseInt(HEX_STRING,16) );
	HEX_VALUE -= Math.pow(16,POWER)*15;
	}

	// Numbers that start with 0 and do not provide a radix should use 10 as radix
	// per ES5, not octal (as it was in ES3).

	var OCT_STRING = "0";
	var OCT_VALUE = 0;

	for ( OCT_STRING = "0", OCT_VALUE = 0, POWER = 0; POWER < 15; POWER++, OCT_STRING = OCT_STRING +"7" ) {
	new TestCase( SECTION, "parseInt('"+OCT_STRING+"')", OCT_VALUE, parseInt(OCT_STRING) );
	OCT_VALUE += Math.pow(10,POWER)*7;
	}

	for ( OCT_STRING = "-0", OCT_VALUE = 0, POWER = 0; POWER < 15; POWER++, OCT_STRING = OCT_STRING +"7" ) {
	new TestCase( SECTION, "parseInt('"+OCT_STRING+"')", OCT_VALUE, parseInt(OCT_STRING) );
	OCT_VALUE -= Math.pow(10,POWER)*7;
	}

	// should get octal-based results if we provid the radix of 8 (or 010)

	for ( OCT_STRING = "0", OCT_VALUE = 0, POWER = 0; POWER < 15; POWER++, OCT_STRING = OCT_STRING +"7" ) {
	new TestCase( SECTION, "parseInt('"+OCT_STRING+"', 8)", OCT_VALUE, parseInt(OCT_STRING,8) );
	OCT_VALUE += Math.pow(8,POWER)*7;
	}
	for ( OCT_STRING = "-0", OCT_VALUE = 0, POWER = 0; POWER < 15; POWER++, OCT_STRING = OCT_STRING +"7" ) {
	new TestCase( SECTION, "parseInt('"+OCT_STRING+"', 010)", OCT_VALUE, parseInt(OCT_STRING,010) );
	OCT_VALUE -= Math.pow(8,POWER)*7;
	}

	// we shall stop parsing digits when we get one that isn't a numeric literal of the type we think
	// it should be.
	for ( OCT_STRING = "0", OCT_VALUE = 0, POWER = 0; POWER < 15; POWER++, OCT_STRING = OCT_STRING +"7" ) {
	new TestCase( SECTION, "parseInt('"+OCT_STRING+"8', 8)", OCT_VALUE, parseInt(OCT_STRING+"8",8) );
	OCT_VALUE += Math.pow(8,POWER)*7;
	}
	for ( OCT_STRING = "-0", OCT_VALUE = 0, POWER = 0; POWER < 15; POWER++, OCT_STRING = OCT_STRING +"7" ) {
	new TestCase( SECTION, "parseInt('"+OCT_STRING+"8', 010)", OCT_VALUE, parseInt(OCT_STRING+"8",010) );
	OCT_VALUE -= Math.pow(8,POWER)*7;
	}

	new TestCase( SECTION,
	"parseInt( '0x' )",
	NaN,
	parseInt("0x") );

	new TestCase( SECTION,
	"parseInt( '0X' )",
	NaN,
	parseInt("0X") );

	new TestCase( SECTION,
	"parseInt( '11111111112222222222' )",
	11111111112222222222,
	parseInt("11111111112222222222") );

	new TestCase( SECTION,
	"parseInt( '111111111122222222223' )",
	111111111122222222220,
	parseInt("111111111122222222223") );

	new TestCase( SECTION,
	"parseInt( '11111111112222222222',10 )",
	11111111112222222222,
	parseInt("11111111112222222222",10) );

	new TestCase( SECTION,
	"parseInt( '111111111122222222223',10 )",
	111111111122222222220,
	parseInt("111111111122222222223",10) );

	new TestCase( SECTION,
	"parseInt( '01234567890', -1 )",
	Number.NaN,
	parseInt("01234567890",-1) );

	new TestCase( SECTION,
	"parseInt( '01234567890', 0 )",
	1234567890,
	parseInt("01234567890", 0) );

	new TestCase( SECTION,
	"parseInt( '01234567890', 1 )",
	Number.NaN,
	parseInt("01234567890",1) );

	new TestCase( SECTION,
	"parseInt( '01234567890', 2 )",
	1,
	parseInt("01234567890",2) );

	new TestCase( SECTION,
	"parseInt( '01234567890', 3 )",
	5,
	parseInt("01234567890",3) );

	new TestCase( SECTION,
	"parseInt( '01234567890', 4 )",
	27,
	parseInt("01234567890",4) );

	new TestCase( SECTION,
	"parseInt( '01234567890', 5 )",
	194,
	parseInt("01234567890",5) );

	new TestCase( SECTION,
	"parseInt( '01234567890', 6 )",
	1865,
	parseInt("01234567890",6) );

	new TestCase( SECTION,
	"parseInt( '01234567890', 7 )",
	22875,
	parseInt("01234567890",7) );

	new TestCase( SECTION,
	"parseInt( '01234567890', 8 )",
	342391,
	parseInt("01234567890",8) );

	new TestCase( SECTION,
	"parseInt( '01234567890', 9 )",
	6053444,
	parseInt("01234567890",9) );

	new TestCase( SECTION,
	"parseInt( '01234567890', 10 )",
	1234567890,
	parseInt("01234567890",10) );

	// need more test cases with hex radix

	new TestCase( SECTION,
	"parseInt( '1234567890', '0xa')",
	1234567890,
	parseInt("1234567890","0xa") );

	new TestCase( SECTION,
	"parseInt( '012345', 11 )",
	17715,
	parseInt("012345",11) );

	new TestCase( SECTION,
	"parseInt( '012345', 35 )",
	1590195,
	parseInt("012345",35) );

	new TestCase( SECTION,
	"parseInt( '012345', 36 )",
	1776965,
	parseInt("012345",36) );

	new TestCase( SECTION,
	"parseInt( '012345', 37 )",
	Number.NaN,
	parseInt("012345",37) );

	test();