forked from M-Labs/artiq
compiler: Implement unary plus/minus for arrays
Implementation is needlessly generic to anticipate coercion/transcendental functions.
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0d8fbd4f19
commit
4426e4144f
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@ -88,6 +88,8 @@ class ARTIQIRGenerator(algorithm.Visitor):
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necessary. They are kept track of in global dictionaries, with a mangled name
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necessary. They are kept track of in global dictionaries, with a mangled name
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containing types and operations as key:
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containing types and operations as key:
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:ivar array_unaryop_funcs: the map from mangled name to implementation of unary
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operations for arrays
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:ivar array_binop_funcs: the map from mangled name to implementation of binary
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:ivar array_binop_funcs: the map from mangled name to implementation of binary
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operations between arrays
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operations between arrays
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"""
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"""
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@ -118,6 +120,7 @@ class ARTIQIRGenerator(algorithm.Visitor):
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self.function_map = dict()
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self.function_map = dict()
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self.variable_map = dict()
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self.variable_map = dict()
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self.method_map = defaultdict(lambda: [])
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self.method_map = defaultdict(lambda: [])
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self.array_unaryop_funcs = dict()
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self.array_binop_funcs = dict()
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self.array_binop_funcs = dict()
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def annotate_calls(self, devirtualization):
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def annotate_calls(self, devirtualization):
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@ -1316,6 +1319,68 @@ class ARTIQIRGenerator(algorithm.Visitor):
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value_tail.append(ir.Branch(tail))
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value_tail.append(ir.Branch(tail))
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return phi
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return phi
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def _make_array_unaryop(self, name, make_op, result_type, arg_type):
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try:
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result = ir.Argument(result_type, "result")
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arg = ir.Argument(arg_type, "arg")
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# TODO: We'd like to use a "C function" here to be able to supply
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# specialised implementations in a library in the future (and e.g. avoid
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# passing around the context argument), but the code generator currently
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# doesn't allow emitting them.
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args = [result, arg]
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typ = types.TFunction(args=OrderedDict([(arg.name, arg.type)
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for arg in args]),
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optargs=OrderedDict(),
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ret=builtins.TNone())
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env_args = [ir.EnvironmentArgument(self.current_env.type, "ARG.ENV")]
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# TODO: What to use for loc?
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func = ir.Function(typ, name, env_args + args, loc=None)
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func.is_internal = True
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func.is_generated = True
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self.functions.append(func)
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old_func, self.current_function = self.current_function, func
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entry = self.add_block("entry")
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old_block, self.current_block = self.current_block, entry
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old_final_branch, self.final_branch = self.final_branch, None
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old_unwind, self.unwind_target = self.unwind_target, None
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shape = self.append(ir.GetAttr(arg, "shape"))
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result_buffer = self.append(ir.GetAttr(result, "buffer"))
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arg_buffer = self.append(ir.GetAttr(arg, "buffer"))
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num_total_elts = self._get_total_array_len(shape)
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def body_gen(index):
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a = self.append(ir.GetElem(arg_buffer, index))
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self.append(
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ir.SetElem(result_buffer, index, self.append(make_op(a))))
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return self.append(
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ir.Arith(ast.Add(loc=None), index, ir.Constant(1, self._size_type)))
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self._make_loop(
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ir.Constant(0, self._size_type), lambda index: self.append(
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ir.Compare(ast.Lt(loc=None), index, num_total_elts)), body_gen)
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self.append(ir.Return(ir.Constant(None, builtins.TNone())))
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return func
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finally:
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self.current_function = old_func
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self.current_block = old_block
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self.final_branch = old_final_branch
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self.unwind_target = old_unwind
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def _get_array_unaryop(self, name, make_op, result_type, arg_type):
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name = "_array_{}_{}".format(
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name, self._mangle_arrayop_types([result_type, arg_type]))
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if name not in self.array_unaryop_funcs:
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self.array_binop_funcs[name] = self._make_array_unaryop(
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name, make_op, result_type, arg_type)
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return self.array_binop_funcs[name]
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def visit_UnaryOpT(self, node):
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def visit_UnaryOpT(self, node):
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if isinstance(node.op, ast.Not):
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if isinstance(node.op, ast.Not):
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cond = self.coerce_to_bool(self.visit(node.operand))
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cond = self.coerce_to_bool(self.visit(node.operand))
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@ -1327,9 +1392,18 @@ class ARTIQIRGenerator(algorithm.Visitor):
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return self.append(ir.Arith(ast.BitXor(loc=None),
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return self.append(ir.Arith(ast.BitXor(loc=None),
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ir.Constant(-1, operand.type), operand))
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ir.Constant(-1, operand.type), operand))
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elif isinstance(node.op, ast.USub):
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elif isinstance(node.op, ast.USub):
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def make_sub(val):
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return ir.Arith(ast.Sub(loc=None),
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ir.Constant(0, val.type), val)
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operand = self.visit(node.operand)
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operand = self.visit(node.operand)
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return self.append(ir.Arith(ast.Sub(loc=None),
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if builtins.is_array(operand.type):
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ir.Constant(0, operand.type), operand))
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shape = self.append(ir.GetAttr(operand, "shape"))
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result = self._alloate_new_array(node.type.find()["elt"], shape)
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func = self._get_array_unaryop("USub", make_sub, node.type, operand.type)
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self._invoke_arrayop(func, [result, operand])
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return result
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else:
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return self.append(make_sub(operand))
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elif isinstance(node.op, ast.UAdd):
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elif isinstance(node.op, ast.UAdd):
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# No-op.
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# No-op.
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return self.visit(node.operand)
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return self.visit(node.operand)
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@ -1423,10 +1497,7 @@ class ARTIQIRGenerator(algorithm.Visitor):
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self.final_branch = old_final_branch
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self.final_branch = old_final_branch
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self.unwind_target = old_unwind
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self.unwind_target = old_unwind
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def _get_array_binop(self, op, result_type, lhs_type, rhs_type):
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def _mangle_arrayop_types(self, types):
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# Currently, we always have any type coercions resolved explicitly in the AST.
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# In the future, this might no longer be true and the three types might all
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# differ.
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def name_error(typ):
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def name_error(typ):
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assert False, "Internal compiler error: No RPC tag for {}".format(typ)
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assert False, "Internal compiler error: No RPC tag for {}".format(typ)
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@ -1438,13 +1509,30 @@ class ARTIQIRGenerator(algorithm.Visitor):
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return (ir.rpc_tag(typ["elt"], name_error).decode() +
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return (ir.rpc_tag(typ["elt"], name_error).decode() +
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str(typ["num_dims"].find().value))
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str(typ["num_dims"].find().value))
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name = "_array_{}_{}_{}_{}".format(
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return "_".join(mangle_name(t) for t in types)
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type(op).__name__, *(map(mangle_name, (result_type, lhs_type, rhs_type))))
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def _get_array_binop(self, op, result_type, lhs_type, rhs_type):
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# Currently, we always have any type coercions resolved explicitly in the AST.
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# In the future, this might no longer be true and the three types might all
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# differ.
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name = "_array_{}_{}".format(
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type(op).__name__,
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self._mangle_arrayop_types([result_type, lhs_type, rhs_type]))
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if name not in self.array_binop_funcs:
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if name not in self.array_binop_funcs:
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self.array_binop_funcs[name] = self._make_array_binop(
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self.array_binop_funcs[name] = self._make_array_binop(
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name, op, result_type, lhs_type, rhs_type)
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name, op, result_type, lhs_type, rhs_type)
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return self.array_binop_funcs[name]
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return self.array_binop_funcs[name]
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def _invoke_arrayop(self, func, params):
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closure = self.append(
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ir.Closure(func, ir.Constant(None, ir.TEnvironment("arrayop", {}))))
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if self.unwind_target is None:
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self.append(ir.Call(closure, params, {}))
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else:
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after_invoke = self.add_block("arrayop.invoke")
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self.append(ir.Invoke(func, params, {}, after_invoke, self.unwind_target))
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self.current_block = after_invoke
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def visit_BinOpT(self, node):
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def visit_BinOpT(self, node):
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if builtins.is_array(node.type):
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if builtins.is_array(node.type):
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lhs = self.visit(node.left)
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lhs = self.visit(node.left)
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@ -1457,14 +1545,8 @@ class ARTIQIRGenerator(algorithm.Visitor):
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result = self._alloate_new_array(node.type.find()["elt"], shape)
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result = self._alloate_new_array(node.type.find()["elt"], shape)
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func = self._get_array_binop(node.op, node.type, node.left.type, node.right.type)
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func = self._get_array_binop(node.op, node.type, node.left.type, node.right.type)
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closure = self.append(ir.Closure(func, ir.Constant(None, ir.TEnvironment("arrayop", {}))))
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self._invoke_arrayop(func, [result, lhs, rhs])
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params = [result, lhs, rhs]
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if self.unwind_target is None:
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insn = self.append(ir.Call(closure, params, {}))
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else:
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after_invoke = self.add_block("arrayop.invoke")
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insn = self.append(ir.Invoke(func, params, {}, after_invoke, self.unwind_target))
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self.current_block = after_invoke
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return result
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return result
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elif builtins.is_numeric(node.type):
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elif builtins.is_numeric(node.type):
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lhs = self.visit(node.left)
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lhs = self.visit(node.left)
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@ -298,10 +298,21 @@ class Inferencer(algorithm.Visitor):
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node.operand.loc)
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node.operand.loc)
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self.engine.process(diag)
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self.engine.process(diag)
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else: # UAdd, USub
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else: # UAdd, USub
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if types.is_var(operand_type):
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return
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if builtins.is_numeric(operand_type):
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if builtins.is_numeric(operand_type):
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self._unify(node.type, operand_type,
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self._unify(node.type, operand_type, node.loc, None)
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node.loc, None)
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return
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elif not types.is_var(operand_type):
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if builtins.is_array(operand_type):
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elt = operand_type.find()["elt"]
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if builtins.is_numeric(elt):
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self._unify(node.type, operand_type, node.loc, None)
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return
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if types.is_var(elt):
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return
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diag = diagnostic.Diagnostic("error",
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diag = diagnostic.Diagnostic("error",
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"expected unary '{op}' operand to be of numeric type, not {type}",
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"expected unary '{op}' operand to be of numeric type, not {type}",
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{"op": node.op.loc.source(),
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{"op": node.op.loc.source(),
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@ -436,7 +447,8 @@ class Inferencer(algorithm.Visitor):
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return typ
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return typ
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def map_return(typ):
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def map_return(typ):
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a = builtins.TArray(elt=typ, num_dims=left_dims)
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elt = builtins.TFloat() if isinstance(op, ast.Div) else typ
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a = builtins.TArray(elt=elt, num_dims=left_dims)
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return (a, a, a)
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return (a, a, a)
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return self._coerce_numeric((left, right),
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return self._coerce_numeric((left, right),
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@ -156,7 +156,7 @@ class RegionOf(algorithm.Visitor):
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visit_NameConstantT = visit_immutable
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visit_NameConstantT = visit_immutable
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visit_NumT = visit_immutable
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visit_NumT = visit_immutable
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visit_EllipsisT = visit_immutable
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visit_EllipsisT = visit_immutable
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visit_UnaryOpT = visit_immutable
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visit_UnaryOpT = visit_sometimes_allocating # possibly array op
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visit_CompareT = visit_immutable
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visit_CompareT = visit_immutable
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# Value lives forever
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# Value lives forever
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@ -0,0 +1,11 @@
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# RUN: %python -m artiq.compiler.testbench.jit %s
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a = array([1, 2])
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b = +a
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assert b[0] == 1
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assert b[1] == 2
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b = -a
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assert b[0] == -1
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assert b[1] == -2
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