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Diffstat (limited to 'js/src/jsapi-tests/testJitRangeAnalysis.cpp')
-rw-r--r-- | js/src/jsapi-tests/testJitRangeAnalysis.cpp | 338 |
1 files changed, 338 insertions, 0 deletions
diff --git a/js/src/jsapi-tests/testJitRangeAnalysis.cpp b/js/src/jsapi-tests/testJitRangeAnalysis.cpp new file mode 100644 index 000000000..bcf642cb2 --- /dev/null +++ b/js/src/jsapi-tests/testJitRangeAnalysis.cpp @@ -0,0 +1,338 @@ +/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 -*- + * vim: set ts=8 sts=4 et sw=4 tw=99: + */ +/* 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/. */ + +#include "mozilla/ArrayUtils.h" + +#include "jit/IonAnalysis.h" +#include "jit/MIRGenerator.h" +#include "jit/MIRGraph.h" +#include "jit/RangeAnalysis.h" + +#include "jsapi-tests/testJitMinimalFunc.h" +#include "jsapi-tests/tests.h" + +using namespace js; +using namespace js::jit; + +static bool +EquivalentRanges(const Range* a, const Range* b) { + if (a->hasInt32UpperBound() != b->hasInt32UpperBound()) + return false; + if (a->hasInt32LowerBound() != b->hasInt32LowerBound()) + return false; + if (a->hasInt32UpperBound() && (a->upper() != b->upper())) + return false; + if (a->hasInt32LowerBound() && (a->lower() != b->lower())) + return false; + if (a->canHaveFractionalPart() != b->canHaveFractionalPart()) + return false; + if (a->canBeNegativeZero() != b->canBeNegativeZero()) + return false; + if (a->canBeNaN() != b->canBeNaN()) + return false; + if (a->canBeInfiniteOrNaN() != b->canBeInfiniteOrNaN()) + return false; + if (!a->canBeInfiniteOrNaN() && (a->exponent() != b->exponent())) + return false; + return true; +} + +BEGIN_TEST(testJitRangeAnalysis_MathSign) +{ + MinimalAlloc func; + + Range* xnan = new(func.alloc) Range(); + + Range* ninf = Range::NewDoubleSingletonRange(func.alloc, mozilla::NegativeInfinity<double>()); + Range* n1_5 = Range::NewDoubleSingletonRange(func.alloc, -1.5); + Range* n1_0 = Range::NewDoubleSingletonRange(func.alloc, -1); + Range* n0_5 = Range::NewDoubleSingletonRange(func.alloc, -0.5); + Range* n0_0 = Range::NewDoubleSingletonRange(func.alloc, -0.0); + + Range* p0_0 = Range::NewDoubleSingletonRange(func.alloc, 0.0); + Range* p0_5 = Range::NewDoubleSingletonRange(func.alloc, 0.5); + Range* p1_0 = Range::NewDoubleSingletonRange(func.alloc, 1.0); + Range* p1_5 = Range::NewDoubleSingletonRange(func.alloc, 1.5); + Range* pinf = Range::NewDoubleSingletonRange(func.alloc, mozilla::PositiveInfinity<double>()); + + Range* xnanSign = Range::sign(func.alloc, xnan); + + Range* ninfSign = Range::sign(func.alloc, ninf); + Range* n1_5Sign = Range::sign(func.alloc, n1_5); + Range* n1_0Sign = Range::sign(func.alloc, n1_0); + Range* n0_5Sign = Range::sign(func.alloc, n0_5); + Range* n0_0Sign = Range::sign(func.alloc, n0_0); + + Range* p0_0Sign = Range::sign(func.alloc, p0_0); + Range* p0_5Sign = Range::sign(func.alloc, p0_5); + Range* p1_0Sign = Range::sign(func.alloc, p1_0); + Range* p1_5Sign = Range::sign(func.alloc, p1_5); + Range* pinfSign = Range::sign(func.alloc, pinf); + + CHECK(!xnanSign); + CHECK(EquivalentRanges(ninfSign, Range::NewInt32SingletonRange(func.alloc, -1))); + CHECK(EquivalentRanges(n1_5Sign, Range::NewInt32SingletonRange(func.alloc, -1))); + CHECK(EquivalentRanges(n1_0Sign, Range::NewInt32SingletonRange(func.alloc, -1))); + + // This should ideally be just -1, but range analysis can't represent the + // specific fractional range of the constant. + CHECK(EquivalentRanges(n0_5Sign, Range::NewInt32Range(func.alloc, -1, 0))); + + CHECK(EquivalentRanges(n0_0Sign, Range::NewDoubleSingletonRange(func.alloc, -0.0))); + + CHECK(!n0_0Sign->canHaveFractionalPart()); + CHECK(n0_0Sign->canBeNegativeZero()); + CHECK(n0_0Sign->lower() == 0); + CHECK(n0_0Sign->upper() == 0); + + CHECK(EquivalentRanges(p0_0Sign, Range::NewInt32SingletonRange(func.alloc, 0))); + + CHECK(!p0_0Sign->canHaveFractionalPart()); + CHECK(!p0_0Sign->canBeNegativeZero()); + CHECK(p0_0Sign->lower() == 0); + CHECK(p0_0Sign->upper() == 0); + + // This should ideally be just 1, but range analysis can't represent the + // specific fractional range of the constant. + CHECK(EquivalentRanges(p0_5Sign, Range::NewInt32Range(func.alloc, 0, 1))); + + CHECK(EquivalentRanges(p1_0Sign, Range::NewInt32SingletonRange(func.alloc, 1))); + CHECK(EquivalentRanges(p1_5Sign, Range::NewInt32SingletonRange(func.alloc, 1))); + CHECK(EquivalentRanges(pinfSign, Range::NewInt32SingletonRange(func.alloc, 1))); + + return true; +} +END_TEST(testJitRangeAnalysis_MathSign) + +BEGIN_TEST(testJitRangeAnalysis_MathSignBeta) +{ + MinimalFunc func; + MathCache cache; + + MBasicBlock* entry = func.createEntryBlock(); + MBasicBlock* thenBlock = func.createBlock(entry); + MBasicBlock* elseBlock = func.createBlock(entry); + MBasicBlock* elseThenBlock = func.createBlock(elseBlock); + MBasicBlock* elseElseBlock = func.createBlock(elseBlock); + + // if (p < 0) + MParameter* p = func.createParameter(); + entry->add(p); + MConstant* c0 = MConstant::New(func.alloc, DoubleValue(0.0)); + entry->add(c0); + MConstant* cm0 = MConstant::New(func.alloc, DoubleValue(-0.0)); + entry->add(cm0); + MCompare* cmp = MCompare::New(func.alloc, p, c0, JSOP_LT); + cmp->setCompareType(MCompare::Compare_Double); + entry->add(cmp); + entry->end(MTest::New(func.alloc, cmp, thenBlock, elseBlock)); + + // { + // return Math.sign(p + -0); + // } + MAdd* thenAdd = MAdd::New(func.alloc, p, cm0, MIRType::Double); + thenBlock->add(thenAdd); + MMathFunction* thenSign = MMathFunction::New(func.alloc, thenAdd, MMathFunction::Sign, &cache); + thenBlock->add(thenSign); + MReturn* thenRet = MReturn::New(func.alloc, thenSign); + thenBlock->end(thenRet); + + // else + // { + // if (p >= 0) + MCompare* elseCmp = MCompare::New(func.alloc, p, c0, JSOP_GE); + elseCmp->setCompareType(MCompare::Compare_Double); + elseBlock->add(elseCmp); + elseBlock->end(MTest::New(func.alloc, elseCmp, elseThenBlock, elseElseBlock)); + + // { + // return Math.sign(p + -0); + // } + MAdd* elseThenAdd = MAdd::New(func.alloc, p, cm0, MIRType::Double); + elseThenBlock->add(elseThenAdd); + MMathFunction* elseThenSign = MMathFunction::New(func.alloc, elseThenAdd, MMathFunction::Sign, &cache); + elseThenBlock->add(elseThenSign); + MReturn* elseThenRet = MReturn::New(func.alloc, elseThenSign); + elseThenBlock->end(elseThenRet); + + // else + // { + // return Math.sign(p + -0); + // } + // } + MAdd* elseElseAdd = MAdd::New(func.alloc, p, cm0, MIRType::Double); + elseElseBlock->add(elseElseAdd); + MMathFunction* elseElseSign = MMathFunction::New(func.alloc, elseElseAdd, MMathFunction::Sign, &cache); + elseElseBlock->add(elseElseSign); + MReturn* elseElseRet = MReturn::New(func.alloc, elseElseSign); + elseElseBlock->end(elseElseRet); + + if (!func.runRangeAnalysis()) + return false; + + CHECK(!p->range()); + CHECK(EquivalentRanges(c0->range(), Range::NewDoubleSingletonRange(func.alloc, 0.0))); + CHECK(EquivalentRanges(cm0->range(), Range::NewDoubleSingletonRange(func.alloc, -0.0))); + + // On the (p < 0) side, p is negative and not -0 (surprise!) + CHECK(EquivalentRanges(thenAdd->range(), + new(func.alloc) Range(Range::NoInt32LowerBound, 0, + Range::IncludesFractionalParts, + Range::ExcludesNegativeZero, + Range::IncludesInfinity))); + + // Consequently, its Math.sign value is not -0 either. + CHECK(EquivalentRanges(thenSign->range(), + new(func.alloc) Range(-1, 0, + Range::ExcludesFractionalParts, + Range::ExcludesNegativeZero, + 0))); + + // On the (p >= 0) side, p is not negative and may be -0 (surprise!) + CHECK(EquivalentRanges(elseThenAdd->range(), + new(func.alloc) Range(0, Range::NoInt32UpperBound, + Range::IncludesFractionalParts, + Range::IncludesNegativeZero, + Range::IncludesInfinity))); + + // Consequently, its Math.sign value may be -0 too. + CHECK(EquivalentRanges(elseThenSign->range(), + new(func.alloc) Range(0, 1, + Range::ExcludesFractionalParts, + Range::IncludesNegativeZero, + 0))); + + // Otherwise, p may be NaN. + CHECK(elseElseAdd->range()->isUnknown()); + CHECK(!elseElseSign->range()); + + return true; +} +END_TEST(testJitRangeAnalysis_MathSignBeta) + +BEGIN_TEST(testJitRangeAnalysis_StrictCompareBeta) +{ + MinimalFunc func; + + MBasicBlock* entry = func.createEntryBlock(); + MBasicBlock* thenBlock = func.createBlock(entry); + MBasicBlock* elseBlock = func.createBlock(entry); + + // if (p === 0) + MParameter* p = func.createParameter(); + entry->add(p); + MConstant* c0 = MConstant::New(func.alloc, DoubleValue(0.0)); + entry->add(c0); + MCompare* cmp = MCompare::New(func.alloc, p, c0, JSOP_STRICTEQ); + entry->add(cmp); + entry->end(MTest::New(func.alloc, cmp, thenBlock, elseBlock)); + + // { + // return p + -0; + // } + MConstant* cm0 = MConstant::New(func.alloc, DoubleValue(-0.0)); + thenBlock->add(cm0); + MAdd* thenAdd = MAdd::New(func.alloc, p, cm0, MIRType::Double); + thenBlock->add(thenAdd); + MReturn* thenRet = MReturn::New(func.alloc, thenAdd); + thenBlock->end(thenRet); + + // else + // { + // return 0; + // } + MReturn* elseRet = MReturn::New(func.alloc, c0); + elseBlock->end(elseRet); + + // If range analysis inserts a beta node for p, it will be able to compute + // a meaningful range for p + -0. + + // We can't do beta node insertion with STRICTEQ and a non-numeric + // comparison though. + MCompare::CompareType nonNumerics[] = { + MCompare::Compare_Unknown, + MCompare::Compare_Object, + MCompare::Compare_Bitwise, + MCompare::Compare_String + }; + for (size_t i = 0; i < mozilla::ArrayLength(nonNumerics); ++i) { + cmp->setCompareType(nonNumerics[i]); + if (!func.runRangeAnalysis()) + return false; + CHECK(!thenAdd->range() || thenAdd->range()->isUnknown()); + ClearDominatorTree(func.graph); + } + + // We can do it with a numeric comparison. + cmp->setCompareType(MCompare::Compare_Double); + if (!func.runRangeAnalysis()) + return false; + CHECK(EquivalentRanges(thenAdd->range(), + Range::NewDoubleRange(func.alloc, 0.0, 0.0))); + + return true; +} +END_TEST(testJitRangeAnalysis_StrictCompareBeta) + + +static void +deriveShiftRightRange(int32_t lhsLower, int32_t lhsUpper, + int32_t rhsLower, int32_t rhsUpper, + int32_t* min, int32_t* max) +{ + // This is the reference algorithm and should be verifiable by inspection. + int64_t i, j; + *min = INT32_MAX; *max = INT32_MIN; + for (i = lhsLower; i <= lhsUpper; i++) { + for (j = rhsLower; j <= rhsUpper; j++) { + int32_t r = int32_t(i) >> (int32_t(j) & 0x1f); + if (r > *max) *max = r; + if (r < *min) *min = r; + } + } +} + +static bool +checkShiftRightRange(int32_t lhsLow, int32_t lhsHigh, int32_t lhsInc, + int32_t rhsLow, int32_t rhsHigh, int32_t rhsInc) +{ + MinimalAlloc func; + int64_t lhsLower, lhsUpper, rhsLower, rhsUpper; + + for (lhsLower = lhsLow; lhsLower <= lhsHigh; lhsLower += lhsInc) { + for (lhsUpper = lhsLower; lhsUpper <= lhsHigh; lhsUpper += lhsInc) { + Range* lhsRange = Range::NewInt32Range(func.alloc, lhsLower, lhsUpper); + for (rhsLower = rhsLow; rhsLower <= rhsHigh; rhsLower += rhsInc) { + for (rhsUpper = rhsLower; rhsUpper <= rhsHigh; rhsUpper += rhsInc) { + if (!func.alloc.ensureBallast()) + return false; + + Range* rhsRange = Range::NewInt32Range(func.alloc, rhsLower, rhsUpper); + Range* result = Range::rsh(func.alloc, lhsRange, rhsRange); + int32_t min, max; + deriveShiftRightRange(lhsLower, lhsUpper, + rhsLower, rhsUpper, + &min, &max); + if (!result->isInt32() || + result->lower() != min || + result->upper() != max) { + return false; + } + } + } + } + } + return true; +} + +BEGIN_TEST(testJitRangeAnalysis_shiftRight) +{ + CHECK(checkShiftRightRange(-16, 15, 1, 0, 31, 1)); + CHECK(checkShiftRightRange( -8, 7, 1, -64, 63, 1)); + return true; +} +END_TEST(testJitRangeAnalysis_shiftRight) |