/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- * vim: set ts=8 sts=2 et sw=2 tw=80: * 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/. */ #ifndef vm_BytecodeUtil_inl_h #define vm_BytecodeUtil_inl_h #include "vm/BytecodeUtil.h" #include "frontend/SourceNotes.h" // SrcNote, SrcNoteType, SrcNoteIterator #include "vm/JSScript.h" namespace js { static inline unsigned GetDefCount(jsbytecode* pc) { /* * Add an extra pushed value for Or/And opcodes, so that they are included * in the pushed array of stack values for type inference. */ JSOp op = JSOp(*pc); switch (op) { case JSOp::Or: case JSOp::And: case JSOp::Coalesce: return 1; case JSOp::Pick: case JSOp::Unpick: /* * Pick pops and pushes how deep it looks in the stack + 1 * items. i.e. if the stack were |a b[2] c[1] d[0]|, pick 2 * would pop b, c, and d to rearrange the stack to |a c[0] * d[1] b[2]|. */ return pc[1] + 1; default: return StackDefs(op); } } static inline unsigned GetUseCount(jsbytecode* pc) { JSOp op = JSOp(*pc); if (op == JSOp::Pick || op == JSOp::Unpick) { return pc[1] + 1; } return StackUses(op, pc); } static inline JSOp ReverseCompareOp(JSOp op) { switch (op) { case JSOp::Gt: return JSOp::Lt; case JSOp::Ge: return JSOp::Le; case JSOp::Lt: return JSOp::Gt; case JSOp::Le: return JSOp::Ge; case JSOp::Eq: case JSOp::Ne: case JSOp::StrictEq: case JSOp::StrictNe: return op; default: MOZ_CRASH("unrecognized op"); } } static inline JSOp NegateCompareOp(JSOp op) { switch (op) { case JSOp::Gt: return JSOp::Le; case JSOp::Ge: return JSOp::Lt; case JSOp::Lt: return JSOp::Ge; case JSOp::Le: return JSOp::Gt; case JSOp::Eq: return JSOp::Ne; case JSOp::Ne: return JSOp::Eq; case JSOp::StrictNe: return JSOp::StrictEq; case JSOp::StrictEq: return JSOp::StrictNe; default: MOZ_CRASH("unrecognized op"); } } class BytecodeRange { public: BytecodeRange(JSContext* cx, JSScript* script) : script(cx, script), pc(script->code()), end(pc + script->length()) {} bool empty() const { return pc == end; } jsbytecode* frontPC() const { return pc; } JSOp frontOpcode() const { return JSOp(*pc); } size_t frontOffset() const { return script->pcToOffset(pc); } void popFront() { pc += GetBytecodeLength(pc); } private: RootedScript script; jsbytecode* pc; jsbytecode* end; }; class BytecodeRangeWithPosition : private BytecodeRange { public: using BytecodeRange::empty; using BytecodeRange::frontOffset; using BytecodeRange::frontOpcode; using BytecodeRange::frontPC; BytecodeRangeWithPosition(JSContext* cx, JSScript* script) : BytecodeRange(cx, script), initialLine(script->lineno()), lineno(script->lineno()), column(script->column()), sn(script->notes()), snpc(script->code()), isEntryPoint(false), isBreakpoint(false), seenStepSeparator(false), wasArtifactEntryPoint(false) { if (!sn->isTerminator()) { snpc += sn->delta(); } updatePosition(); while (frontPC() != script->main()) { popFront(); } if (frontOpcode() != JSOp::JumpTarget) { isEntryPoint = true; } else { wasArtifactEntryPoint = true; } } void popFront() { BytecodeRange::popFront(); if (empty()) { isEntryPoint = false; } else { updatePosition(); } // The following conditions are handling artifacts introduced by the // bytecode emitter, such that we do not add breakpoints on empty // statements of the source code of the user. if (wasArtifactEntryPoint) { wasArtifactEntryPoint = false; isEntryPoint = true; } if (isEntryPoint && frontOpcode() == JSOp::JumpTarget) { wasArtifactEntryPoint = isEntryPoint; isEntryPoint = false; } } size_t frontLineNumber() const { return lineno; } size_t frontColumnNumber() const { return column; } // Entry points are restricted to bytecode offsets that have an // explicit mention in the line table. This restriction avoids a // number of failing cases caused by some instructions not having // sensible (to the user) line numbers, and it is one way to // implement the idea that the bytecode emitter should tell the // debugger exactly which offsets represent "interesting" (to the // user) places to stop. bool frontIsEntryPoint() const { return isEntryPoint; } // Breakable points are explicitly marked by the emitter as locations where // the debugger may want to allow users to pause. bool frontIsBreakablePoint() const { return isBreakpoint; } // Breakable step points are the first breakable point after a // SrcNote::StepSep note has been encountered. bool frontIsBreakableStepPoint() const { return isBreakpoint && seenStepSeparator; } private: void updatePosition() { if (isBreakpoint) { isBreakpoint = false; seenStepSeparator = false; } // Determine the current line number by reading all source notes up to // and including the current offset. jsbytecode* lastLinePC = nullptr; SrcNoteIterator iter(sn); for (; !iter.atEnd() && snpc <= frontPC(); ++iter, snpc += (*iter)->delta()) { auto sn = *iter; SrcNoteType type = sn->type(); if (type == SrcNoteType::ColSpan) { ptrdiff_t colspan = SrcNote::ColSpan::getSpan(sn); MOZ_ASSERT(ptrdiff_t(column) + colspan >= 0); column += colspan; lastLinePC = snpc; } else if (type == SrcNoteType::SetLine) { lineno = SrcNote::SetLine::getLine(sn, initialLine); column = 0; lastLinePC = snpc; } else if (type == SrcNoteType::NewLine) { lineno++; column = 0; lastLinePC = snpc; } else if (type == SrcNoteType::Breakpoint) { isBreakpoint = true; lastLinePC = snpc; } else if (type == SrcNoteType::StepSep) { seenStepSeparator = true; lastLinePC = snpc; } } sn = *iter; isEntryPoint = lastLinePC == frontPC(); } size_t initialLine; size_t lineno; size_t column; const SrcNote* sn; jsbytecode* snpc; bool isEntryPoint; bool isBreakpoint; bool seenStepSeparator; bool wasArtifactEntryPoint; }; } // namespace js #endif /* vm_BytecodeUtil_inl_h */