// Copyright 2019 the V8 project authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. // Tier-up behavior differs between slow and fast paths in // RegExp.prototype.replace with a function as an argument. // Flags: --regexp-tier-up --regexp-tier-up-ticks=1 // Flags: --allow-natives-syntax --no-force-slow-path --no-regexp-interpret-all const kLatin1 = true; const kUnicode = false; function CheckRegexpNotYetCompiled(regexp) { assertFalse(%RegexpHasBytecode(regexp, kLatin1) && %RegexpHasNativeCode(regexp, kLatin1)); assertFalse(%RegexpHasBytecode(regexp, kUnicode) && %RegexpHasNativeCode(regexp, kUnicode)); } // Testing RegExp.test method which calls into Runtime_RegExpExec. let re = new RegExp('^.$'); CheckRegexpNotYetCompiled(re); // Testing first execution of regexp with one-byte string subject. re.test("a"); assertTrue(%RegexpHasBytecode(re, kLatin1)); assertTrue(!%RegexpHasBytecode(re, kUnicode) && !%RegexpHasNativeCode(re, kUnicode)); // Testing second execution of regexp now with a two-byte string subject. // This will compile to native code because we have a single tick counter // for both string representations. re.test("π"); assertTrue(%RegexpHasBytecode(re, kLatin1)); assertTrue(!%RegexpHasBytecode(re, kUnicode) && %RegexpHasNativeCode(re,kUnicode)); // Testing tier-up when we're back to executing the regexp with a one byte // string. re.test("6"); assertTrue(!%RegexpHasBytecode(re, kLatin1) && %RegexpHasNativeCode(re,kLatin1)); assertTrue(!%RegexpHasBytecode(re, kUnicode) && %RegexpHasNativeCode(re,kUnicode)); re.test("7"); assertTrue(!%RegexpHasBytecode(re, kLatin1) && %RegexpHasNativeCode(re,kLatin1)); assertTrue(!%RegexpHasBytecode(re, kUnicode) && %RegexpHasNativeCode(re,kUnicode)); // Testing String.replace method for non-global regexps. var subject = "a11"; re = /\w1/; CheckRegexpNotYetCompiled(re); subject.replace(re, "x"); assertTrue(%RegexpHasBytecode(re, kLatin1)); assertTrue(!%RegexpHasBytecode(re, kUnicode) && !%RegexpHasNativeCode(re, kUnicode)); subject.replace(re, "x"); assertTrue(!%RegexpHasBytecode(re, kLatin1) && %RegexpHasNativeCode(re, kLatin1)); assertTrue(!%RegexpHasBytecode(re, kUnicode) && !%RegexpHasNativeCode(re, kUnicode)); // Testing String.replace method for global regexps. let re_g = /\w111/g; CheckRegexpNotYetCompiled(re_g); // This regexp will not match, so it will only execute the bytecode once, // without tiering-up and recompiling to native code. subject.replace(re_g, "x"); assertTrue(%RegexpHasBytecode(re_g, kLatin1)); assertTrue(!%RegexpHasBytecode(re_g, kUnicode) && !%RegexpHasNativeCode(re_g, kUnicode)); // This regexp will match, so it will execute twice, and tier-up. re_g = /\w1/g; CheckRegexpNotYetCompiled(re_g); subject.replace(re_g, "x"); assertTrue(!%RegexpHasBytecode(re_g, kLatin1) && %RegexpHasNativeCode(re_g, kLatin1)); assertTrue(!%RegexpHasBytecode(re_g, kUnicode) && !%RegexpHasNativeCode(re_g, kUnicode)); // Testing String.replace method for global regexps with a function as a // parameter. This will tier-up eagerly and compile to native code right // away, even though the regexp is only executed once. function f() { return "x"; } re_g = /\w2/g; CheckRegexpNotYetCompiled(re_g); subject.replace(re_g, f); assertTrue(!%RegexpHasBytecode(re_g, kLatin1) && %RegexpHasNativeCode(re_g, kLatin1)); assertTrue(!%RegexpHasBytecode(re_g, kUnicode) && !%RegexpHasNativeCode(re_g, kUnicode));