Implement escape analysis.

2015-07-04 04:16:37 +03:00 · 2015-07-04 04:16:37 +03:00 · 16432d2652
parent 4358c5c453
commit 16432d2652
5 changed files with 316 additions and 9 deletions
--- a/artiq/compiler/builtins.py
+++ b/artiq/compiler/builtins.py
@ -132,3 +132,7 @@ def is_exn_constructor(typ, name=None):
            typ.name == name
    else:
        return isinstance(typ, types.TExceptionConstructor)
 def is_mutable(typ):
    return typ.fold(False, lambda accum, typ:
        is_list(typ) or types.is_function(typ))
--- a/artiq/compiler/transforms/asttyped_rewriter.py
+++ b/artiq/compiler/transforms/asttyped_rewriter.py
@ -28,32 +28,32 @@ class LocalExtractor(algorithm.Visitor):
        # parameters can't be declared as global or nonlocal
        self.params     = set()
-    def visit_in_assign(self, node):
+    def visit_in_assign(self, node, in_assign):
        try:
-            self.in_assign = True
+            old_in_assign, self.in_assign = self.in_assign, in_assign
            return self.visit(node)
        finally:
-            self.in_assign = False
+            self.in_assign = old_in_assign
    def visit_Assign(self, node):
        self.visit(node.value)
        for target in node.targets:
-            self.visit_in_assign(target)
+            self.visit_in_assign(target, in_assign=True)
    def visit_For(self, node):
        self.visit(node.iter)
-        self.visit_in_assign(node.target)
+        self.visit_in_assign(node.target, in_assign=True)
        self.visit(node.body)
        self.visit(node.orelse)
    def visit_withitem(self, node):
        self.visit(node.context_expr)
        if node.optional_vars is not None:
-            self.visit_in_assign(node.optional_vars)
+            self.visit_in_assign(node.optional_vars, in_assign=True)
    def visit_comprehension(self, node):
        self.visit(node.iter)
-        self.visit_in_assign(node.target)
+        self.visit_in_assign(node.target, in_assign=True)
        for if_ in node.ifs:
            self.visit(node.ifs)
@ -99,6 +99,13 @@ class LocalExtractor(algorithm.Visitor):
            # creates a new binding for x in f's scope
            self._assignable(node.id)
    def visit_Attribute(self, node):
        self.visit_in_assign(node.value, in_assign=False)
    def visit_Subscript(self, node):
        self.visit_in_assign(node.value, in_assign=False)
        self.visit_in_assign(node.slice, in_assign=False)
    def _check_not_in(self, name, names, curkind, newkind, loc):
        if name in names:
            diag = diagnostic.Diagnostic("error",
--- a/artiq/compiler/transforms/inferencer.py
+++ b/artiq/compiler/transforms/inferencer.py
@ -350,7 +350,6 @@ class Inferencer(algorithm.Visitor):
                            return types.is_mono(opreand.type) and \
                                opreand.type.find().name == typ.find().name
                        other_node = next(filter(wide_enough, operands))
                    print(typ, other_node)
                    node.left, *node.comparators = \
                        [self._coerce_one(typ, operand, other_node) for operand in operands]
        self._unify(node.type, builtins.TBool(),
--- a/artiq/compiler/validators/init.py
+++ b/artiq/compiler/validators/init.py
@ -1 +1,2 @@
 from .monomorphism import MonomorphismValidator
 from .escape import EscapeValidator
--- a/artiq/compiler/validators/escape.py
+++ b/artiq/compiler/validators/escape.py
@ -3,8 +3,304 @@
 the region of its allocation.
 """
 import functools
 from pythonparser import algorithm, diagnostic
 from .. import asttyped, types, builtins
 class Region:
    """
    A last-in-first-out allocation region. Tied to lexical scoping
    and is internally represented simply by a source range.
    :ivar range: (:class:`pythonparser.source.Range` or None)
    """
    def __init__(self, source_range=None):
        self.range = source_range
    def present(self):
        return bool(self.range)
    def includes(self, other):
        assert self.range
        assert self.range.source_buffer == other.range.source_buffer
        return self.range.begin_pos <= other.range.begin_pos and \
                    self.range.end_pos >= other.range.end_pos
    def intersects(self, other):
        assert self.range.source_buffer == other.range.source_buffer
        assert self.range
        return (self.range.begin_pos <= other.range.begin_pos <= self.range.end_pos and \
                    other.range.end_pos > self.range.end_pos) or \
               (other.range.begin_pos <= self.range.begin_pos <= other.range.end_pos and \
                    self.range.end_pos > other.range.end_pos)
    def contract(self, other):
        if not self.range:
            self.range = other.range
    def outlives(lhs, rhs):
        if lhs is None: # lhs lives forever
            return True
        elif rhs is None: # rhs lives forever, lhs does not
            return False
        else:
            assert not lhs.intersects(rhs)
            return lhs.includes(rhs)
    def __repr__(self):
        return "Region({})".format(repr(self.range))
 class RegionOf(algorithm.Visitor):
    """
    Visit an expression and return the list of regions that must
    be alive for the expression to execute.
    """
    def __init__(self, env_stack, youngest_region):
        self.env_stack, self.youngest_region = env_stack, youngest_region
    # Liveness determined by assignments
    def visit_NameT(self, node):
        # First, look at stack regions
        for region in reversed(self.env_stack[1:]):
            if node.id in region:
                return region[node.id]
        # Then, look at the global region of this module
        if node.id in self.env_stack[0]:
            return None
        assert False
    # Value lives as long as the current scope, if it's mutable,
    # or else forever
    def visit_BinOpT(self, node):
        if builtins.is_mutable(node.type):
            return self.youngest_region
        else:
            return None
    # Value lives as long as the object/container, if it's mutable,
    # or else forever
    def visit_accessor(self, node):
        if builtins.is_mutable(node.type):
            return self.visit(node.value)
        else:
            return None
    visit_AttributeT = visit_accessor
    visit_SubscriptT = visit_accessor
    # Value lives as long as the shortest living operand
    def visit_selecting(self, nodes):
        regions = [self.visit(node) for node in nodes]
        regions = list(filter(lambda x: x, regions))
        if any(regions):
            regions.sort(key=functools.cmp_to_key(Region.outlives), reverse=True)
            return regions[0]
        else:
            return None
    def visit_BoolOpT(self, node):
        return self.visit_selecting(node.values)
    def visit_IfExpT(self, node):
        return self.visit_selecting([node.body, node.orelse])
    def visit_TupleT(self, node):
        return self.visit_selecting(node.elts)
    # Value lives as long as the current scope
    def visit_allocating(self, node):
        return self.youngest_region
    visit_DictT = visit_allocating
    visit_DictCompT = visit_allocating
    visit_GeneratorExpT = visit_allocating
    visit_LambdaT = visit_allocating
    visit_ListT = visit_allocating
    visit_ListCompT = visit_allocating
    visit_SetT = visit_allocating
    visit_SetCompT = visit_allocating
    visit_StrT = visit_allocating
    # Value lives forever
    def visit_immutable(self, node):
        assert not builtins.is_mutable(node.type)
        return None
    visit_CompareT = visit_immutable
    visit_EllipsisT = visit_immutable
    visit_NameConstantT = visit_immutable
    visit_NumT = visit_immutable
    visit_UnaryOpT = visit_immutable
    visit_CallT = visit_immutable
    # Not implemented
    def visit_unimplemented(self, node):
        assert False
    visit_StarredT = visit_unimplemented
    visit_YieldT = visit_unimplemented
    visit_YieldFromT = visit_unimplemented
 class AssignedNamesOf(algorithm.Visitor):
    """
    Visit an expression and return the list of names that appear
    on the lhs of assignment, directly or through an accessor.
    """
    def visit_NameT(self, node):
        return [node]
    def visit_accessor(self, node):
        return self.visit(node.value)
    visit_AttributeT = visit_accessor
    visit_SubscriptT = visit_accessor
    def visit_sequence(self, node):
        return reduce(list.__add__, map(self.visit, node.elts))
    visit_TupleT = visit_sequence
    visit_ListT = visit_sequence
    def visit_StarredT(self, node):
        assert False
 class EscapeValidator(algorithm.Visitor):
-    pass
+    def __init__(self, engine):
        self.engine = engine
        self.youngest_region = None
        self.env_stack = []
        self.youngest_env = None
    def _region_of(self, expr):
        return RegionOf(self.env_stack, self.youngest_region).visit(expr)
    def _names_of(self, expr):
        return AssignedNamesOf().visit(expr)
    def _diagnostics_for(self, region, loc, descr="the value of the expression"):
        if region:
            return [
                diagnostic.Diagnostic("note",
                    "{descr} is alive from this point...", {"descr": descr},
                    region.range.begin()),
                diagnostic.Diagnostic("note",
                    "... to this point", {},
                    region.range.end())
            ]
        else:
            return [
                diagnostic.Diagnostic("note",
                    "{descr} is alive forever", {"descr": descr},
                    loc)
            ]
    def visit_in_region(self, node, region):
        try:
            old_youngest_region = self.youngest_region
            self.youngest_region = region
            old_youngest_env = self.youngest_env
            self.youngest_env = {}
            for name in node.typing_env:
                if builtins.is_mutable(node.typing_env[name]):
                    self.youngest_env[name] = Region(None) # not yet known
                else:
                    self.youngest_env[name] = None # lives forever
            self.env_stack.append(self.youngest_env)
            self.generic_visit(node)
        finally:
            self.env_stack.pop()
            self.youngest_env = old_youngest_env
            self.youngest_region = old_youngest_region
    def visit_ModuleT(self, node):
        self.visit_in_region(node, None)
    def visit_FunctionDefT(self, node):
        self.youngest_env[node.name] = self.youngest_region
        self.visit_in_region(node, Region(node.loc))
    # Only three ways for a pointer to escape:
    #   * Assigning or op-assigning it (we ensure an outlives relationship)
    #   * Returning it (we only allow returning values that live forever)
    #   * Raising it (we forbid raising mutable data)
    #
    # Literals doesn't count: a constructed object is always
    # outlived by all its constituents.
    # Closures don't count: see above.
    # Calling functions doesn't count: arguments never outlive
    # the function body.
    def visit_assignment(self, target, value, is_aug_assign=False):
        target_region = self._region_of(target)
        value_region  = self._region_of(value) if not is_aug_assign else self.youngest_region
        # If this is a variable, we might need to contract the live range.
        if value_region is not None:
            for name in self._names_of(target):
                region = self._region_of(name)
                if region is not None:
                    region.contract(value_region)
        # The assigned value should outlive the assignee
        if not Region.outlives(value_region, target_region):
            if is_aug_assign:
                target_desc = "the assignment target, allocated here,"
            else:
                target_desc = "the assignment target"
            note = diagnostic.Diagnostic("note",
                "this expression has type {type}",
                {"type": types.TypePrinter().name(value.type)},
                value.loc)
            diag = diagnostic.Diagnostic("error",
                "the assigned value does not outlive the assignment target", {},
                value.loc, [target.loc],
                notes=self._diagnostics_for(target_region, target.loc,
                                            target_desc) +
                      self._diagnostics_for(value_region, value.loc,
                                            "the assigned value"))
            self.engine.process(diag)
    def visit_Assign(self, node):
        for target in node.targets:
            self.visit_assignment(target, node.value)
    def visit_AugAssign(self, node):
        if builtins.is_mutable(node.target.type):
            # If the target is mutable, op-assignment will allocate
            # in the youngest region.
            self.visit_assignment(node.target, node.value, is_aug_assign=True)
    def visit_Return(self, node):
        region = self._region_of(node.value)
        if region:
            note = diagnostic.Diagnostic("note",
                "this expression has type {type}",
                {"type": types.TypePrinter().name(node.value.type)},
                node.value.loc)
            diag = diagnostic.Diagnostic("error",
                "cannot return a mutable value that does not live forever", {},
                node.value.loc, notes=self._diagnostics_for(region, node.value.loc) + [note])
            self.engine.process(diag)
    def visit_Raise(self, node):
        if builtins.is_mutable(node.exc.type):
            note = diagnostic.Diagnostic("note",
                "this expression has type {type}",
                {"type": types.TypePrinter().name(node.exc.type)},
                node.exc.loc)
            diag = diagnostic.Diagnostic("error",
                "cannot raise a mutable value", {},
                node.exc.loc, notes=[note])
            self.engine.process(diag)
`@ -1 +1,2 @@`
	`from .monomorphism import MonomorphismValidator`	`from .monomorphism import MonomorphismValidator`
		`from .escape import EscapeValidator`