implement LR optimisation in Python3 + align naming + DFAState ctor bugs

2016-11-30 00:40:42 +08:00 · 2016-11-30 00:40:42 +08:00 · 6e071f4950
parent ccde4051bd
commit 6e071f4950
6 changed files with 178 additions and 15 deletions
--- a/runtime/Python3/src/antlr4/ParserInterpreter.py
+++ b/runtime/Python3/src/antlr4/ParserInterpreter.py
@ -71,7 +71,7 @@ class ParserInterpreter(Parser):
        for state in atn.states:
            if not isinstance(state, StarLoopEntryState):
                continue
-            if state.precedenceRuleDecision:
+            if state.isPrecedenceDecision:
                self.pushRecursionContextStates.add(state.stateNumber)
        # get atn simulator that knows how to do predictions
        self._interp = ParserATNSimulator(self, atn, self.decisionToDFA, self.sharedContextCache)
--- a/runtime/Python3/src/antlr4/atn/ATNDeserializer.py
+++ b/runtime/Python3/src/antlr4/atn/ATNDeserializer.py
@ -368,7 +368,7 @@ class ATNDeserializer (object):
    #
    # Analyze the {@link StarLoopEntryState} states in the specified ATN to set
-    # the {@link StarLoopEntryState#precedenceRuleDecision} field to the
+    # the {@link StarLoopEntryState#isPrecedenceDecision} field to the
    # correct value.
    #
    # @param atn The ATN.
@ -387,7 +387,7 @@ class ATNDeserializer (object):
                if isinstance(maybeLoopEndState, LoopEndState):
                    if maybeLoopEndState.epsilonOnlyTransitions and \
                            isinstance(maybeLoopEndState.transitions[0].target, RuleStopState):
-                        state.precedenceRuleDecision = True
+                        state.isPrecedenceDecision = True
    def verifyATN(self, atn:ATN):
        if not self.deserializationOptions.verifyATN:
--- a/runtime/Python3/src/antlr4/atn/ATNSimulator.py
+++ b/runtime/Python3/src/antlr4/atn/ATNSimulator.py
@ -37,7 +37,7 @@ from antlr4.dfa.DFAState import DFAState
 class ATNSimulator(object):
    # Must distinguish between missing edge and edge we know leads nowhere#/
-    ERROR = DFAState(ATNConfigSet())
+    ERROR = DFAState(configs=ATNConfigSet())
    ERROR.stateNumber = 0x7FFFFFFF
    # The context cache maps all PredictionContext objects that are ==
--- a/runtime/Python3/src/antlr4/atn/ATNState.py
+++ b/runtime/Python3/src/antlr4/atn/ATNState.py
@ -261,7 +261,7 @@ class StarLoopEntryState(DecisionState):
        self.stateType = self.STAR_LOOP_ENTRY
        self.loopBackState = None
        # Indicates whether this state can benefit from a precedence DFA during SLL decision making.
-        self.precedenceRuleDecision = None
+        self.isPrecedenceDecision = None
 # Mark the end of a * or + loop.
 class LoopEndState(ATNState):
--- a/runtime/Python3/src/antlr4/atn/ParserATNSimulator.py
+++ b/runtime/Python3/src/antlr4/atn/ParserATNSimulator.py
@ -346,15 +346,6 @@ class ParserATNSimulator(ATNSimulator):
                                       " exec LA(1)==" + self.getLookaheadName(input) +
                                       ", outerContext=" + outerContext.toString(self.parser.literalNames, None))
                # If this is not a precedence DFA, we check the ATN start state
                # to determine if this ATN start state is the decision for the
                # closure block that determines whether a precedence rule
                # should continue or complete.
                #
                if not dfa.precedenceDfa and isinstance(dfa.atnStartState, StarLoopEntryState):
                    if dfa.atnStartState.precedenceRuleDecision:
                        dfa.setPrecedenceDfa(True)
                fullCtx = False
                s0_closure = self.computeStartState(dfa.atnStartState, ParserRuleContext.EMPTY, fullCtx)
@ -365,6 +356,7 @@ class ParserATNSimulator(ATNSimulator):
                    # appropriate start state for the precedence level rather
                    # than simply setting DFA.s0.
                    #
                    dfa.s0.configs = s0_closure # not used for prediction but useful to know start configs anyway
                    s0_closure = self.applyPrecedenceFilter(s0_closure)
                    s0 = self.addDFAState(dfa, DFAState(configs=s0_closure))
                    dfa.setPrecedenceStartState(self.parser.getPrecedence(), s0)
@ -1173,7 +1165,13 @@ class ParserATNSimulator(ATNSimulator):
            # make sure to not return here, because EOF transitions can act as
            # both epsilon transitions and non-epsilon transitions.
        first = True
        for t in p.transitions:
            if first:
                first = False
                if self.canDropLoopEntryEdgeInLeftRecursiveRule(config):
                    continue
            continueCollecting = collectPredicates and not isinstance(t, ActionTransition)
            c = self.getEpsilonTarget(config, t, continueCollecting, depth == 0, fullCtx, treatEofAsEpsilon)
            if c is not None:
@ -1210,6 +1208,161 @@ class ParserATNSimulator(ATNSimulator):
                self.closureCheckingStopState(c, configs, closureBusy, continueCollecting, fullCtx, newDepth, treatEofAsEpsilon)
    # Implements first-edge (loop entry) elimination as an optimization
    #  during closure operations.  See antlr/antlr4#1398.
    #
    # The optimization is to avoid adding the loop entry config when
    # the exit path can only lead back to the same
    # StarLoopEntryState after popping context at the rule end state
    # (traversing only epsilon edges, so we're still in closure, in
    # this same rule).
    #
    # We need to detect any state that can reach loop entry on
    # epsilon w/o exiting rule. We don't have to look at FOLLOW
    # links, just ensure that all stack tops for config refer to key
    # states in LR rule.
    #
    # To verify we are in the right situation we must first check
    # closure is at a StarLoopEntryState generated during LR removal.
    # Then we check that each stack top of context is a return state
    # from one of these cases:
    #
    #   1. 'not' expr, '(' type ')' expr. The return state points at loop entry state
    #   2. expr op expr. The return state is the block end of internal block of (...)*
    #   3. 'between' expr 'and' expr. The return state of 2nd expr reference.
    #      That state points at block end of internal block of (...)*.
    #   4. expr '?' expr ':' expr. The return state points at block end,
    #      which points at loop entry state.
    #
    # If any is true for each stack top, then closure does not add a
    # config to the current config set for edge[0], the loop entry branch.
    #
    #  Conditions fail if any context for the current config is:
    #
    #   a. empty (we'd fall out of expr to do a global FOLLOW which could
    #      even be to some weird spot in expr) or,
    #   b. lies outside of expr or,
    #   c. lies within expr but at a state not the BlockEndState
    #   generated during LR removal
    #
    # Do we need to evaluate predicates ever in closure for this case?
    #
    # No. Predicates, including precedence predicates, are only
    # evaluated when computing a DFA start state. I.e., only before
    # the lookahead (but not parser) consumes a token.
    #
    # There are no epsilon edges allowed in LR rule alt blocks or in
    # the "primary" part (ID here). If closure is in
    # StarLoopEntryState any lookahead operation will have consumed a
    # token as there are no epsilon-paths that lead to
    # StarLoopEntryState. We do not have to evaluate predicates
    # therefore if we are in the generated StarLoopEntryState of a LR
    # rule. Note that when making a prediction starting at that
    # decision point, decision d=2, compute-start-state performs
    # closure starting at edges[0], edges[1] emanating from
    # StarLoopEntryState. That means it is not performing closure on
    # StarLoopEntryState during compute-start-state.
    #
    # How do we know this always gives same prediction answer?
    #
    # Without predicates, loop entry and exit paths are ambiguous
    # upon remaining input +b (in, say, a+b). Either paths lead to
    # valid parses. Closure can lead to consuming + immediately or by
    # falling out of this call to expr back into expr and loop back
    # again to StarLoopEntryState to match +b. In this special case,
    # we choose the more efficient path, which is to take the bypass
    # path.
    #
    # The lookahead language has not changed because closure chooses
    # one path over the other. Both paths lead to consuming the same
    # remaining input during a lookahead operation. If the next token
    # is an operator, lookahead will enter the choice block with
    # operators. If it is not, lookahead will exit expr. Same as if
    # closure had chosen to enter the choice block immediately.
    #
    # Closure is examining one config (some loopentrystate, some alt,
    # context) which means it is considering exactly one alt. Closure
    # always copies the same alt to any derived configs.
    #
    # How do we know this optimization doesn't mess up precedence in
    # our parse trees?
    #
    # Looking through expr from left edge of stat only has to confirm
    # that an input, say, a+b+c; begins with any valid interpretation
    # of an expression. The precedence actually doesn't matter when
    # making a decision in stat seeing through expr. It is only when
    # parsing rule expr that we must use the precedence to get the
    # right interpretation and, hence, parse tree.
    #
    # @since 4.6
    #
    def canDropLoopEntryEdgeInLeftRecursiveRule(self, config):
        # return False
        p = config.state
        # First check to see if we are in StarLoopEntryState generated during
        # left-recursion elimination. For efficiency, also check if
        # the context has an empty stack case. If so, it would mean
        # global FOLLOW so we can't perform optimization
        # Are we the special loop entry/exit state? or SLL wildcard
        if p.stateType != ATNState.STAR_LOOP_ENTRY  \
                or not p.isPrecedenceDecision       \
                or config.context.isEmpty()         \
                or config.context.hasEmptyPath():
            return False
        # Require all return states to return back to the same rule
        # that p is in.
        numCtxs = len(config.context)
        for i in range(0, numCtxs):  # for each stack context
            returnState = self.atn.states[config.context.getReturnState(i)]
            if returnState.ruleIndex != p.ruleIndex:
                return False
        decisionStartState = p.transitions[0].target
        blockEndStateNum = decisionStartState.endState.stateNumber
        blockEndState = self.atn.states[blockEndStateNum]
        # Verify that the top of each stack context leads to loop entry/exit
        # state through epsilon edges and w/o leaving rule.
        for i in range(0, numCtxs):  # for each stack context
            returnStateNumber = config.context.getReturnState(i)
            returnState = self.atn.states[returnStateNumber]
            # all states must have single outgoing epsilon edge
            if len(returnState.transitions) != 1 or not returnState.transitions[0].isEpsilon:
                return False
            # Look for prefix op case like 'not expr', (' type ')' expr
            returnStateTarget = returnState.transitions[0].target
            if returnState.stateType == ATNState.BLOCK_END and returnStateTarget is p:
                continue
            # Look for 'expr op expr' or case where expr's return state is block end
            # of (...)* internal block; the block end points to loop back
            # which points to p but we don't need to check that
            if returnState is blockEndState:
                continue
            # Look for ternary expr ? expr : expr. The return state points at block end,
            # which points at loop entry state
            if returnStateTarget is blockEndState:
                continue
            # Look for complex prefix 'between expr and expr' case where 2nd expr's
            # return state points at block end state of (...)* internal block
            if returnStateTarget.stateType == ATNState.BLOCK_END \
                and len(returnStateTarget.transitions) == 1 \
                and returnStateTarget.transitions[0].isEpsilon \
                and returnStateTarget.transitions[0].target is p:
                    continue
            # anything else ain't conforming
            return False
        return True
    def getRuleName(self, index:int):
        if self.parser is not None and index>=0:
            return self.parser.ruleNames[index]
--- a/runtime/Python3/src/antlr4/dfa/DFA.py
+++ b/runtime/Python3/src/antlr4/dfa/DFA.py
@ -27,6 +27,7 @@
 #  THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
 #  (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
 #  THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
 from antlr4.atn.ATNState import StarLoopEntryState
 from antlr4.atn.ATNConfigSet import ATNConfigSet
 from antlr4.atn.ATNState import DecisionState
@ -49,6 +50,15 @@ class DFA(object):
        # {@link #setPrecedenceDfa}.
        self.precedenceDfa = False
        if isinstance(atnStartState, StarLoopEntryState):
            if atnStartState.isPrecedenceDecision:
                self.precedenceDfa = True
                precedenceState = DFAState(configs=ATNConfigSet())
                precedenceState.edges = []
                precedenceState.isAcceptState = False
                precedenceState.requiresFullContext = False
                self.s0 = precedenceState
    # Get the start state for a specific precedence value.
    #
@ -112,7 +122,7 @@ class DFA(object):
        if self.precedenceDfa != precedenceDfa:
            self._states = dict()
            if precedenceDfa:
-                precedenceState = DFAState(ATNConfigSet())
+                precedenceState = DFAState(configs=ATNConfigSet())
                precedenceState.edges = []
                precedenceState.isAcceptState = False
                precedenceState.requiresFullContext = False