Exemplo n.º 1
0
def lambdify(expr, args):
    if isinstance(args, Lambda):
        new_expr = args.expr
        new_expr = Return(new_expr)
        new_expr.set_fst(expr)
        f_arguments = args.variables
        func = FunctionDef('lambda', f_arguments, [], [new_expr])
        return func

    code = compile(args.body[0], '', 'single')
    g = {}
    eval(code, g)
    f_name = str(args.name)
    code = g[f_name]
    new_args = args.arguments
    new_expr = code(*new_args)
    f_arguments = list(new_expr.free_symbols)
    stmts = cse(new_expr)
    if isinstance(stmts[-1], (Assign, GC)):
        var = stmts[-1].lhs
    else:
        var = create_variable(expr)
        stmts[-1] = Assign(var, stmts[-1])
    stmts += [Return([var])]
    set_fst(stmts, args.fst)
    func = FunctionDef(f_name, new_args, [], stmts, decorators=args.decorators)
    return func
Exemplo n.º 2
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def as_static_function_call(func, mod_name, name=None):

    assert isinstance(func, FunctionDef)
    assert isinstance(mod_name, str)

    # create function alias by prepending 'mod_' to its name
    func_alias = func.clone('mod_' + str(func.name))

    # from module import func as func_alias
    imports = [Import(target=AsName(func.name, func_alias.name), source=mod_name)]

    # function arguments
    args = sanitize_arguments(func.arguments)
    # function body
    call    = FunctionCall(func_alias, args)
    results = func.results
    results = results[0] if len(results) == 1 else results
    stmt    = call if len(func.results) == 0 else Assign(results, call)
    body    = [stmt]

    # new function declaration
    new_func = FunctionDef(func.name, list(args), func.results, body,
                       arguments_inout = func.arguments_inout,
                       functions = func.functions,
                       interfaces = func.interfaces,
                       imports = imports,
                       doc_string = func.doc_string,
                       )

    # make it compatible with c
    static_func = as_static_function(new_func, name)

    return static_func
Exemplo n.º 3
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    def _create_wrapper_check(self, check_var, parse_args, types_dict, used_names, func_name):
        check_func_body = []
        flags = (len(types_dict) - 1) * 4
        for arg in types_dict:
            var_name = ""
            body = []
            types = []
            arg_type_check_list = list(types_dict[arg])
            arg_type_check_list.sort(key= lambda x : x[0].precision)
            for elem in arg_type_check_list:
                var_name = elem[0].name
                value = elem[2] << flags
                body.append((elem[1], [AugAssign(check_var, '+' ,value)]))
                types.append(elem[0])
            flags -= 4
            error = ' or '.join(['{} bit {}'.format(v.precision * 8 , str_dtype(v.dtype)) if not isinstance(v.dtype, NativeBool)
                            else  str_dtype(v.dtype) for v in types])
            body.append((LiteralTrue(), [PyErr_SetString('PyExc_TypeError', '"{} must be {}"'.format(var_name, error)), Return([LiteralInteger(0)])]))
            check_func_body += [If(*body)]

        check_func_body = [Assign(check_var, LiteralInteger(0))] + check_func_body
        check_func_body.append(Return([check_var]))
        # Creating check function definition
        check_func_name = self.get_new_name(used_names.union(self._global_names), 'type_check')
        self._global_names.add(check_func_name)
        check_func_def = FunctionDef(name = check_func_name,
            arguments = parse_args,
            results = [check_var],
            body = check_func_body,
            local_vars = [])
        return check_func_def
Exemplo n.º 4
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    def __new__(cls, name, arguments, results, body, **kwargs):
        generators = kwargs.pop('generators', {})
        m_results = kwargs.pop('m_results', [])

        obj = FunctionDef.__new__(cls, name, arguments, results, body,
                                  **kwargs)
        obj._generators = generators
        obj._m_results = m_results

        return obj
Exemplo n.º 5
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def as_static_function_call(func):
    assert (isinstance(func, FunctionDef))

    args = func.arguments
    args = sanitize_arguments(args)
    functions = func.functions
    body = [FunctionCall(func, args)]

    func = FunctionDef(func.name,
                       list(args), [],
                       body,
                       arguments_inout=func.arguments_inout,
                       functions=functions)
    static_func = as_static_function(func)

    return static_func
Exemplo n.º 6
0
    def _visit_FunctionDef(self, stmt):

        #  TODO check all inputs and which ones should be treated in stage 1 or 2

        name = self._visit(stmt.name)
        name = name.replace("'", '')

        arguments = self._visit(stmt.args)

        local_vars = []
        global_vars = []
        headers = []
        templates = {}
        hide = False
        kind = 'function'
        is_pure = False
        is_elemental = False
        is_private = False
        imports = []

        def fill_types(ls):
            container = []
            for arg in ls:
                if isinstance(arg, Symbol):
                    arg = arg.name
                    container.append(arg)
                elif isinstance(arg, LiteralString):
                    arg = str(arg)
                    arg = arg.strip("'").strip('"')
                    container.append(arg)
                else:
                    msg = 'Invalid argument of type {} passed to types decorator'.format(
                        type(arg))
                    errors.report(msg,
                                  bounding_box=(stmt.lineno, stmt.col_offset),
                                  severity='error')
            return container

        decorators = {}
        for d in self._visit(stmt.decorator_list):
            tmp_var = str(d) if isinstance(d, Symbol) else str(type(d))
            if tmp_var in decorators:
                decorators[tmp_var] += [d]
            else:
                decorators[tmp_var] = [d]

        if 'bypass' in decorators:
            return EmptyNode()

        if 'stack_array' in decorators:
            decorators['stack_array'] = tuple(
                str(b) for a in decorators['stack_array'] for b in a.args)

        if 'allow_negative_index' in decorators:
            decorators['allow_negative_index'] = tuple(
                str(b) for a in decorators['allow_negative_index']
                for b in a.args)

        # extract the templates
        if 'template' in decorators:
            for comb_types in decorators['template']:
                cache.clear_cache()
                types = []
                if len(comb_types.args) != 2:
                    msg = 'Number of Arguments provided to the template decorator is not valid'
                    errors.report(msg,
                                  symbol=comb_types,
                                  bounding_box=(stmt.lineno, stmt.col_offset),
                                  severity='error')

                for i in comb_types.args:
                    if isinstance(i,
                                  ValuedArgument) and not i.name in ('name',
                                                                     'types'):
                        msg = 'Argument provided to the template decorator is not valid'
                        errors.report(msg,
                                      symbol=comb_types,
                                      bounding_box=(stmt.lineno,
                                                    stmt.col_offset),
                                      severity='error')
                if all(isinstance(i, ValuedArgument) for i in comb_types.args):
                    tp_name, ls = (comb_types.args[0].value, comb_types.args[1].value) if\
                            comb_types.args[0].name == 'name' else\
                            (comb_types.args[1].value, comb_types.args[0].value)
                else:
                    tp_name = comb_types.args[0]
                    ls = comb_types.args[1]
                    ls = ls.value if isinstance(ls, ValuedArgument) else ls
                try:
                    tp_name = str(tp_name)
                    ls = ls if isinstance(ls, PythonTuple) else list(ls)
                except TypeError:
                    msg = 'Argument provided to the template decorator is not valid'
                    errors.report(msg,
                                  symbol=comb_types,
                                  bounding_box=(stmt.lineno, stmt.col_offset),
                                  severity='fatal')

                types = fill_types(ls)

                txt = '#$ header template ' + str(tp_name)
                txt += '(' + '|'.join(types) + ')'
                if tp_name in templates:
                    msg = 'The template "{}" is duplicated'.format(tp_name)
                    errors.report(msg,
                                  bounding_box=(stmt.lineno, stmt.col_offset),
                                  severity='warning')

                templates[tp_name] = hdr_parse(stmts=txt)

        # extract the types to construct a header
        if 'types' in decorators:
            for comb_types in decorators['types']:

                cache.clear_cache()
                results = []
                ls = comb_types.args

                if len(ls) > 0 and isinstance(ls[-1], ValuedArgument):
                    arg_name = ls[-1].name
                    if not arg_name == 'results':
                        msg = 'Argument "{}" provided to the types decorator is not valid'.format(
                            arg_name)
                        errors.report(msg,
                                      symbol=comb_types,
                                      bounding_box=(stmt.lineno,
                                                    stmt.col_offset),
                                      severity='error')
                    else:
                        container = ls[-1].value
                        container = container if isinstance(
                            container, PythonTuple) else [container]
                        results = fill_types(container)
                    types = fill_types(ls[:-1])
                else:
                    types = fill_types(ls)

                txt = '#$ header ' + name
                txt += '(' + ','.join(types) + ')'

                if results:
                    txt += ' results(' + ','.join(results) + ')'

                header = hdr_parse(stmts=txt)
                if name in self.namespace.static_functions:
                    header = header.to_static()
                headers += [header]

        body = stmt.body

        if 'sympy' in decorators.keys():
            # TODO maybe we should run pylint here
            stmt.decorators.pop()
            func = SympyFunction(name, arguments, [], [stmt.__str__()])
            func.set_fst(stmt)
            self.insert_function(func)
            return EmptyNode()

        elif 'python' in decorators.keys():

            # TODO maybe we should run pylint here

            stmt.decorators.pop()
            func = PythonFunction(name, arguments, [], [stmt.__str__()])
            func.set_fst(stmt)
            self.insert_function(func)
            return EmptyNode()

        else:
            body = self._visit(body)

        if 'pure' in decorators.keys():
            is_pure = True

        if 'elemental' in decorators.keys():
            is_elemental = True
            if len(arguments) > 1:
                errors.report(FORTRAN_ELEMENTAL_SINGLE_ARGUMENT,
                              symbol=decorators['elemental'],
                              bounding_box=(stmt.lineno, stmt.col_offset),
                              severity='error')

        if 'private' in decorators.keys():
            is_private = True

        returns = [i.expr for i in _atomic(body, cls=Return)]
        assert all(len(i) == len(returns[0]) for i in returns)
        results = []
        result_counter = 1
        for i in zip(*returns):
            if not all(i[0] == j for j in i) or not isinstance(i[0], Symbol):
                result_name, result_counter = create_variable(
                    self._used_names, prefix='Out', counter=result_counter)
                results.append(result_name)
            elif isinstance(i[0], Symbol) and any(i[0].name == x.name
                                                  for x in arguments):
                result_name, result_counter = create_variable(
                    self._used_names, prefix='Out', counter=result_counter)
                results.append(result_name)
            else:
                results.append(i[0])

        func = FunctionDef(name,
                           arguments,
                           results,
                           body,
                           local_vars=local_vars,
                           global_vars=global_vars,
                           hide=hide,
                           kind=kind,
                           is_pure=is_pure,
                           is_elemental=is_elemental,
                           is_private=is_private,
                           imports=imports,
                           decorators=decorators,
                           headers=headers,
                           templates=templates)

        func.set_fst(stmt)
        return func
Exemplo n.º 7
0
def ompfy(stmt, **options):
    """
    Converts some statements to OpenMP statments.

    stmt: stmt, list
        statement or a list of statements
    """
    if isinstance(stmt, (list, tuple, Tuple)):
        return [ompfy(i, **options) for i in stmt]

    if isinstance(stmt, Tensor):
        # TODO to implement
        return stmt

    if isinstance(stmt, ForIterator):
        iterable = ompfy(stmt.iterable, **options)
        target   = stmt.target
        body     = ompfy(stmt.body, **options)

        info, clauses = get_for_clauses(iterable)

        if (clauses is None):
            return ForIterator(target, iterable, body, strict=False)
        else:
            loop   = ForIterator(target, iterable, body, strict=False)
            nowait = info['nowait']
            return OMP_For(loop, clauses, nowait)

    if isinstance(stmt, For):
        iterable = ompfy(stmt.iterable, **options)
        target   = stmt.target
        body     = ompfy(stmt.body, **options)
        return For(target, iterable, body, strict=False)

    if isinstance(stmt, list):
        return [ompfy(a, **options) for a in stmt]

    if isinstance(stmt, While):
        test = ompfy(stmt.test, **options)
        body = ompfy(stmt.body, **options)
        return While(test, body)

    if isinstance(stmt, With):
        test     = ompfy(stmt.test, **options)
        body     = ompfy(stmt.body, **options)
        settings = ompfy(stmt.settings, **options)

        clauses = get_with_clauses(test)

        if (clauses is None):
            return With(test, body, settings)
        else:
            # TODO to be defined
            variables = []
            return OMP_Parallel(clauses, variables, body)

    if isinstance(stmt, If):
        args = []
        for block in stmt.args:
            test  = block[0]
            stmts = block[1]
            t = ompfy(test,  **options)
            s = ompfy(stmts, **options)
            args.append((t,s))
        return If(*args)

    if isinstance(stmt, FunctionDef):
        name        = ompfy(stmt.name,        **options)
        arguments   = ompfy(stmt.arguments,   **options)
        results     = ompfy(stmt.results,     **options)
        body        = ompfy(stmt.body,        **options)
        local_vars  = ompfy(stmt.local_vars,  **options)
        global_vars = ompfy(stmt.global_vars, **options)

        return FunctionDef(name, arguments, results,
                           body, local_vars, global_vars)

    if isinstance(stmt, ClassDef):
        name        = ompfy(stmt.name,        **options)
        attributs   = ompfy(stmt.attributs,   **options)
        methods     = ompfy(stmt.methods,     **options)
        options     = ompfy(stmt.options,     **options)

        return ClassDef(name, attributs, methods, options)

    if isinstance(stmt, Module):
        name        = ompfy(stmt.name,        **options)
        variables   = ompfy(stmt.variables,   **options)
        funcs       = ompfy(stmt.funcs    ,   **options)
        classes     = ompfy(stmt.classes  ,   **options)
        imports     = ompfy(stmt.imports  ,   **options)
        imports    += [Import('omp_lib')]

        return Module(name, variables, funcs, classes,
                      imports=imports)

    if isinstance(stmt, Program):
        name        = ompfy(stmt.name,        **options)
        variables   = ompfy(stmt.variables,   **options)
        funcs       = ompfy(stmt.funcs    ,   **options)
        classes     = ompfy(stmt.classes  ,   **options)
        imports     = ompfy(stmt.imports  ,   **options)
        body        = ompfy(stmt.body  ,   **options)
        modules     = ompfy(stmt.modules  ,   **options)
        imports    += [Import('omp_lib')]

        return Program(name, variables, funcs, classes, body,
                       imports=imports, modules=modules)

    if isinstance(stmt, ParallelBlock):
        variables = stmt.variables
        body      = stmt.body
        clauses   = stmt.clauses

        return OMP_Parallel(clauses, variables, body)

    return stmt
Exemplo n.º 8
0
    def _print_FunctionDef(self, expr):
        # Save all used names
        used_names = set([a.name for a in expr.arguments] +
                         [r.name for r in expr.results] + [expr.name.name])

        # Find a name for the wrapper function
        wrapper_name = self._get_wrapper_name(used_names, expr)
        used_names.add(wrapper_name)
        # Collect local variables
        wrapper_vars = {a.name: a for a in expr.arguments}
        wrapper_vars.update({r.name: r for r in expr.results})
        python_func_args = self.get_new_PyObject("args", used_names)
        python_func_kwargs = self.get_new_PyObject("kwargs", used_names)
        python_func_selfarg = self.get_new_PyObject("self", used_names)

        # Collect arguments and results
        wrapper_args = [
            python_func_selfarg, python_func_args, python_func_kwargs
        ]
        wrapper_results = [self.get_new_PyObject("result", used_names)]

        if expr.is_private:
            wrapper_func = FunctionDef(
                name=wrapper_name,
                arguments=wrapper_args,
                results=wrapper_results,
                body=[
                    PyErr_SetString(
                        'PyExc_NotImplementedError',
                        '"Private functions are not accessible from python"'),
                    AliasAssign(wrapper_results[0], Nil()),
                    Return(wrapper_results)
                ])
            return CCodePrinter._print_FunctionDef(self, wrapper_func)
        if any(isinstance(arg, FunctionAddress) for arg in expr.arguments):
            wrapper_func = FunctionDef(
                name=wrapper_name,
                arguments=wrapper_args,
                results=wrapper_results,
                body=[
                    PyErr_SetString('PyExc_NotImplementedError',
                                    '"Cannot pass a function as an argument"'),
                    AliasAssign(wrapper_results[0], Nil()),
                    Return(wrapper_results)
                ])
            return CCodePrinter._print_FunctionDef(self, wrapper_func)

        # Collect argument names for PyArgParse
        arg_names = [a.name for a in expr.arguments]
        keyword_list_name = self.get_new_name(used_names, 'kwlist')
        keyword_list = PyArgKeywords(keyword_list_name, arg_names)

        wrapper_body = [keyword_list]
        wrapper_body_translations = []

        parse_args = []
        collect_vars = {}
        for arg in expr.arguments:
            collect_var, cast_func = self.get_PyArgParseType(used_names, arg)
            collect_vars[arg] = collect_var

            body, tmp_variable = self._body_management(used_names, arg,
                                                       collect_var, cast_func,
                                                       True)
            if tmp_variable:
                wrapper_vars[tmp_variable.name] = tmp_variable

            # If the variable cannot be collected from PyArgParse directly
            wrapper_vars[collect_var.name] = collect_var

            # Save cast to argument variable
            wrapper_body_translations.extend(body)

            parse_args.append(collect_var)

            # Write default values
            if isinstance(arg, ValuedVariable):
                wrapper_body.append(
                    self.get_default_assign(parse_args[-1], arg))

        # Parse arguments
        parse_node = PyArg_ParseTupleNode(python_func_args, python_func_kwargs,
                                          expr.arguments, parse_args,
                                          keyword_list)
        wrapper_body.append(If((PyccelNot(parse_node), [Return([Nil()])])))
        wrapper_body.extend(wrapper_body_translations)

        # Call function
        static_function, static_args, additional_body = self._get_static_function(
            used_names, expr, collect_vars)
        wrapper_body.extend(additional_body)
        for var in static_args:
            wrapper_vars[var.name] = var

        if len(expr.results) == 0:
            func_call = FunctionCall(static_function, static_args)
        else:
            results = expr.results if len(
                expr.results) > 1 else expr.results[0]
            func_call = Assign(results,
                               FunctionCall(static_function, static_args))

        wrapper_body.append(func_call)

        # Loop over results to carry out necessary casts and collect Py_BuildValue type string
        res_args = []
        for a in expr.results:
            collect_var, cast_func = self.get_PyBuildValue(used_names, a)
            if cast_func is not None:
                wrapper_vars[collect_var.name] = collect_var
                wrapper_body.append(AliasAssign(collect_var, cast_func))

            res_args.append(
                VariableAddress(collect_var) if collect_var.
                is_pointer else collect_var)

        # Call PyBuildNode
        wrapper_body.append(
            AliasAssign(wrapper_results[0], PyBuildValueNode(res_args)))

        # Call free function for python type
        wrapper_body += [
            FunctionCall(Py_DECREF, [i]) for i in self._to_free_PyObject_list
        ]
        self._to_free_PyObject_list.clear()
        #Return
        wrapper_body.append(Return(wrapper_results))
        # Create FunctionDef and write using classic method
        wrapper_func = FunctionDef(name=wrapper_name,
                                   arguments=wrapper_args,
                                   results=wrapper_results,
                                   body=wrapper_body,
                                   local_vars=wrapper_vars.values())
        return CCodePrinter._print_FunctionDef(self, wrapper_func)
Exemplo n.º 9
0
    def _print_Interface(self, expr):

        # Collecting all functions
        funcs = expr.functions
        # Save all used names
        used_names = set(n.name for n in funcs)

        # Find a name for the wrapper function
        wrapper_name = self._get_wrapper_name(used_names, expr)
        self._global_names.add(wrapper_name)

        # Collect local variables
        python_func_args = self.get_new_PyObject("args", used_names)
        python_func_kwargs = self.get_new_PyObject("kwargs", used_names)
        python_func_selfarg = self.get_new_PyObject("self", used_names)

        # Collect wrapper arguments and results
        wrapper_args = [
            python_func_selfarg, python_func_args, python_func_kwargs
        ]
        wrapper_results = [self.get_new_PyObject("result", used_names)]

        # Collect parser arguments
        wrapper_vars = {}

        # Collect argument names for PyArgParse
        arg_names = [a.name for a in funcs[0].arguments]
        keyword_list_name = self.get_new_name(used_names, 'kwlist')
        keyword_list = PyArgKeywords(keyword_list_name, arg_names)
        wrapper_body = [keyword_list]

        wrapper_body_translations = []
        body_tmp = []

        # To store the mini function responsible of collecting value and calling interfaces functions and return the builded value
        funcs_def = []
        default_value = {
        }  # dict to collect all initialisation needed in the wrapper
        check_var = Variable(dtype=NativeInteger(),
                             name=self.get_new_name(used_names, "check"))
        wrapper_vars[check_var.name] = check_var
        types_dict = OrderedDict(
            (a, set()) for a in funcs[0].arguments
        )  #dict to collect each variable possible type and the corresponding flags
        # collect parse arg
        parse_args = [
            Variable(dtype=PyccelPyArrayObject(),
                     is_pointer=True,
                     rank=a.rank,
                     order=a.order,
                     name=self.get_new_name(used_names, a.name +
                                            "_tmp")) if a.rank > 0 else
            Variable(dtype=PyccelPyObject(),
                     name=self.get_new_name(used_names, a.name + "_tmp"),
                     is_pointer=True) for a in funcs[0].arguments
        ]
        # Managing the body of wrapper
        for func in funcs:
            mini_wrapper_func_body = []
            res_args = []
            mini_wrapper_func_vars = {a.name: a for a in func.arguments}
            flags = 0
            collect_vars = {}

            # Loop for all args in every functions and create the corresponding condition and body
            for p_arg, f_arg in zip(parse_args, func.arguments):
                collect_vars[f_arg] = p_arg
                body, tmp_variable = self._body_management(
                    used_names, f_arg, p_arg, None)
                if tmp_variable:
                    mini_wrapper_func_vars[tmp_variable.name] = tmp_variable

                # get check type function
                check = self._get_check_type_statement(f_arg, p_arg)
                # If the variable cannot be collected from PyArgParse directly
                wrapper_vars[p_arg.name] = p_arg

                # Save the body
                wrapper_body_translations.extend(body)

                # Write default values
                if isinstance(f_arg, ValuedVariable):
                    wrapper_body.append(
                        self.get_default_assign(parse_args[-1], f_arg))

                flag_value = flags_registry[(f_arg.dtype, f_arg.precision)]
                flags = (flags << 4) + flag_value  # shift by 4 to the left
                types_dict[f_arg].add(
                    (f_arg, check,
                     flag_value))  # collect variable type for each arguments
                mini_wrapper_func_body += body

            # create the corresponding function call
            static_function, static_args, additional_body = self._get_static_function(
                used_names, func, collect_vars)
            mini_wrapper_func_body.extend(additional_body)

            for var in static_args:
                mini_wrapper_func_vars[var.name] = var

            if len(func.results) == 0:
                func_call = FunctionCall(static_function, static_args)
            else:
                results = func.results if len(
                    func.results) > 1 else func.results[0]
                func_call = Assign(results,
                                   FunctionCall(static_function, static_args))

            mini_wrapper_func_body.append(func_call)

            # Loop for all res in every functions and create the corresponding body and cast
            for r in func.results:
                collect_var, cast_func = self.get_PyBuildValue(used_names, r)
                mini_wrapper_func_vars[collect_var.name] = collect_var
                if cast_func is not None:
                    mini_wrapper_func_vars[r.name] = r
                    mini_wrapper_func_body.append(
                        AliasAssign(collect_var, cast_func))
                res_args.append(
                    VariableAddress(collect_var) if collect_var.
                    is_pointer else collect_var)

            # Building PybuildValue and freeing the allocated variable after.
            mini_wrapper_func_body.append(
                AliasAssign(wrapper_results[0], PyBuildValueNode(res_args)))
            mini_wrapper_func_body += [
                FunctionCall(Py_DECREF, [i])
                for i in self._to_free_PyObject_list
            ]
            mini_wrapper_func_body.append(Return(wrapper_results))
            self._to_free_PyObject_list.clear()
            # Building Mini wrapper function
            mini_wrapper_func_name = self.get_new_name(
                used_names.union(self._global_names),
                func.name.name + '_mini_wrapper')
            self._global_names.add(mini_wrapper_func_name)

            mini_wrapper_func_def = FunctionDef(
                name=mini_wrapper_func_name,
                arguments=parse_args,
                results=wrapper_results,
                body=mini_wrapper_func_body,
                local_vars=mini_wrapper_func_vars.values())
            funcs_def.append(mini_wrapper_func_def)

            # append check condition to the functioncall
            body_tmp.append((PyccelEq(check_var, LiteralInteger(flags)), [
                AliasAssign(wrapper_results[0],
                            FunctionCall(mini_wrapper_func_def, parse_args))
            ]))

        # Errors / Types management
        # Creating check_type function
        check_func_def = self._create_wrapper_check(check_var, parse_args,
                                                    types_dict, used_names,
                                                    funcs[0].name.name)
        funcs_def.append(check_func_def)

        # Create the wrapper body with collected informations
        body_tmp = [((PyccelNot(check_var), [Return([Nil()])]))] + body_tmp
        body_tmp.append((LiteralTrue(), [
            PyErr_SetString('PyExc_TypeError',
                            '"Arguments combinations don\'t exist"'),
            Return([Nil()])
        ]))
        wrapper_body_translations = [If(*body_tmp)]

        # Parsing Arguments
        parse_node = PyArg_ParseTupleNode(python_func_args, python_func_kwargs,
                                          funcs[0].arguments, parse_args,
                                          keyword_list, True)
        wrapper_body += list(default_value.values())
        wrapper_body.append(If((PyccelNot(parse_node), [Return([Nil()])])))

        #finishing the wrapper body
        wrapper_body.append(
            Assign(check_var, FunctionCall(check_func_def, parse_args)))
        wrapper_body.extend(wrapper_body_translations)
        wrapper_body.append(Return(wrapper_results))  # Return

        # Create FunctionDef
        funcs_def.append(
            FunctionDef(name=wrapper_name,
                        arguments=wrapper_args,
                        results=wrapper_results,
                        body=wrapper_body,
                        local_vars=wrapper_vars.values()))

        sep = self._print(SeparatorComment(40))

        return sep + '\n'.join(
            CCodePrinter._print_FunctionDef(self, f) for f in funcs_def)
Exemplo n.º 10
0
def as_static_function(func):
    assert (isinstance(func, FunctionDef))

    args = func.arguments
    results = func.results
    body = func.body
    arguments_inout = func.arguments_inout
    functions = func.functions
    _results = []
    if results:
        if len(results) == 1:
            result = results[0]
            if result.rank > 0:
                # updates args
                args = list(args) + [result]
                arguments_inout += [False]
            else:
                _results = results

        else:
            raise NotImplementedError('when len(results) > 1')

    name = 'f2py_{}'.format(func.name).lower()

    # ...
    results_names = [i.name for i in results]
    _args = []
    _arguments_inout = []
    for i_a, a in enumerate(args):
        if not isinstance(a, Variable):
            raise TypeError('Expecting a Variable type for {}'.format(a))

        rank = a.rank
        if rank > 0:
            # ...
            additional_args = []
            for i in range(0, rank):
                n_name = 'n{i}_{name}'.format(name=str(a.name), i=i)
                n_arg = Variable('int', n_name)

                additional_args += [n_arg]

            shape_new = Tuple(*additional_args, sympify=False)
            # ...

            _args += additional_args
            for j in additional_args:
                _arguments_inout += [False]

            a_new = Variable(a.dtype,
                             a.name,
                             allocatable=a.allocatable,
                             is_pointer=a.is_pointer,
                             is_target=a.is_target,
                             is_optional=a.is_optional,
                             shape=shape_new,
                             rank=a.rank,
                             order=a.order,
                             precision=a.precision)

            if not (a.name in results_names):
                _args += [a_new]

            else:
                _results += [a_new]

        else:
            _args += [a]

        intent = arguments_inout[i_a]
        _arguments_inout += [intent]

    args = _args
    results = _results
    arguments_inout = _arguments_inout
    # ...

    return FunctionDef(name,
                       list(args),
                       results,
                       body,
                       local_vars=func.local_vars,
                       is_static=True,
                       arguments_inout=arguments_inout,
                       functions=functions)
Exemplo n.º 11
0
    def __new__(cls, func, import_lambda):

        # ...
        m_results = func.m_results

        name = 'interface_{}'.format(func.name)
        args = [i for i in func.arguments if not i in m_results]
        s_results = func.results

        results = list(s_results) + list(m_results)
        # ...

        # ...
        imports = [import_lambda]
        stmts = []
        # ...

        # ... out argument
        if len(results) == 1:
            outs = [Symbol('out')]

        else:
            outs = [Symbol('out_{}'.format(i)) for i in range(0, len(results))]
        # ...

        # ...
        generators = func.generators
        d_shapes = {}
        for i in m_results:
            d_shapes[i] = compute_shape(i, generators)
        # ...

        # ... TODO build statements
        if_cond = Is(Symbol('out'), Nil())

        if_body = []

        # TODO add imports from numpy
        if_body += [Import('zeros', 'numpy')]
        if_body += [Import('float64', 'numpy')]

        for i, var in enumerate(results):
            if var in m_results:
                shaping = d_shapes[var]

                if_body += shaping.stmts
                if_body += [Assign(outs[i], Zeros(shaping.var, var.dtype))]

        # update statements
        stmts = [If((if_cond, if_body))]
        # ...

        # ... add call to the python or pyccelized function
        stmts += [FunctionCall(func, args + outs)]
        # ...

        # ... add return out
        if len(outs) == 1:
            stmts += [Return(outs[0])]

        else:
            stmts += [Return(outs)]
        # ...

        # ...
        body = imports + stmts
        # ...

        # update arguments with optional
        args += [Assign(Symbol('out'), Nil())]

        return FunctionDef(name, args, results, body)