#! /usr/bin/env python """Generate C code from an ASDL description.""" import os, sys import asdl TABSIZE = 4 MAX_COL = 80 def get_c_type(name): """Return a string for the C name of the type. This function special cases the default types provided by asdl. """ if name in asdl.builtin_types: return name else: return "%s_ty" % name def reflow_lines(s, depth): """Reflow the line s indented depth tabs. Return a sequence of lines where no line extends beyond MAX_COL when properly indented. The first line is properly indented based exclusively on depth * TABSIZE. All following lines -- these are the reflowed lines generated by this function -- start at the same column as the first character beyond the opening { in the first line. """ size = MAX_COL - depth * TABSIZE if len(s) < size: return [s] lines = [] cur = s padding = "" while len(cur) > size: i = cur.rfind(' ', 0, size) # XXX this should be fixed for real if i == -1 and 'GeneratorExp' in cur: i = size + 3 assert i != -1, "Impossible line %d to reflow: %r" % (size, s) lines.append(padding + cur[:i]) if len(lines) == 1: # find new size based on brace j = cur.find('{', 0, i) if j >= 0: j += 2 # account for the brace and the space after it size -= j padding = " " * j else: j = cur.find('(', 0, i) if j >= 0: j += 1 # account for the paren (no space after it) size -= j padding = " " * j cur = cur[i+1:] else: lines.append(padding + cur) return lines def is_simple(sum): """Return True if a sum is a simple. A sum is simple if its types have no fields, e.g. unaryop = Invert | Not | UAdd | USub """ for t in sum.types: if t.fields: return False return True class EmitVisitor(asdl.VisitorBase): """Visit that emits lines""" def __init__(self, file): self.file = file self.identifiers = set() super(EmitVisitor, self).__init__() def emit_identifier(self, name): name = str(name) if name in self.identifiers: return self.emit("_Py_IDENTIFIER(%s);" % name, 0) self.identifiers.add(name) def emit(self, s, depth, reflow=True): # XXX reflow long lines? if reflow: lines = reflow_lines(s, depth) else: lines = [s] for line in lines: if line: line = (" " * TABSIZE * depth) + line self.file.write(line + "\n") class TypeDefVisitor(EmitVisitor): def visitModule(self, mod): for dfn in mod.dfns: self.visit(dfn) def visitType(self, type, depth=0): self.visit(type.value, type.name, depth) def visitSum(self, sum, name, depth): if is_simple(sum): self.simple_sum(sum, name, depth) else: self.sum_with_constructors(sum, name, depth) def simple_sum(self, sum, name, depth): enum = [] for i in range(len(sum.types)): type = sum.types[i] enum.append("%s=%d" % (type.name, i + 1)) enums = ", ".join(enum) ctype = get_c_type(name) s = "typedef enum _%s { %s } %s;" % (name, enums, ctype) self.emit(s, depth) self.emit("", depth) def sum_with_constructors(self, sum, name, depth): ctype = get_c_type(name) s = "typedef struct _%(name)s *%(ctype)s;" % locals() self.emit(s, depth) self.emit("", depth) def visitProduct(self, product, name, depth): ctype = get_c_type(name) s = "typedef struct _%(name)s *%(ctype)s;" % locals() self.emit(s, depth) self.emit("", depth) class StructVisitor(EmitVisitor): """Visitor to generate typedefs for AST.""" def visitModule(self, mod): for dfn in mod.dfns: self.visit(dfn) def visitType(self, type, depth=0): self.visit(type.value, type.name, depth) def visitSum(self, sum, name, depth): if not is_simple(sum): self.sum_with_constructors(sum, name, depth) def sum_with_constructors(self, sum, name, depth): def emit(s, depth=depth): self.emit(s % sys._getframe(1).f_locals, depth) enum = [] for i in range(len(sum.types)): type = sum.types[i] enum.append("%s_kind=%d" % (type.name, i + 1)) emit("enum _%(name)s_kind {" + ", ".join(enum) + "};") emit("struct _%(name)s {") emit("enum _%(name)s_kind kind;", depth + 1) emit("union {", depth + 1) for t in sum.types: self.visit(t, depth + 2) emit("} v;", depth + 1) for field in sum.attributes: # rudimentary attribute handling type = str(field.type) assert type in asdl.builtin_types, type emit("%s %s;" % (type, field.name), depth + 1); emit("};") emit("") def visitConstructor(self, cons, depth): if cons.fields: self.emit("struct {", depth) for f in cons.fields: self.visit(f, depth + 1) self.emit("} %s;" % cons.name, depth) self.emit("", depth) def visitField(self, field, depth): # XXX need to lookup field.type, because it might be something # like a builtin... ctype = get_c_type(field.type) name = field.name if field.seq: if field.type == 'cmpop': self.emit("asdl_int_seq *%(name)s;" % locals(), depth) else: self.emit("asdl_seq *%(name)s;" % locals(), depth) else: self.emit("%(ctype)s %(name)s;" % locals(), depth) def visitProduct(self, product, name, depth): self.emit("struct _%(name)s {" % locals(), depth) for f in product.fields: self.visit(f, depth + 1) for field in product.attributes: # rudimentary attribute handling type = str(field.type) assert type in asdl.builtin_types, type self.emit("%s %s;" % (type, field.name), depth + 1); self.emit("};", depth) self.emit("", depth) class PrototypeVisitor(EmitVisitor): """Generate function prototypes for the .h file""" def visitModule(self, mod): for dfn in mod.dfns: self.visit(dfn) def visitType(self, type): self.visit(type.value, type.name) def visitSum(self, sum, name): if is_simple(sum): pass # XXX else: for t in sum.types: self.visit(t, name, sum.attributes) def get_args(self, fields): """Return list of C argument into, one for each field. Argument info is 3-tuple of a C type, variable name, and flag that is true if type can be NULL. """ args = [] unnamed = {} for f in fields: if f.name is None: name = f.type c = unnamed[name] = unnamed.get(name, 0) + 1 if c > 1: name = "name%d" % (c - 1) else: name = f.name # XXX should extend get_c_type() to handle this if f.seq: if f.type == 'cmpop': ctype = "asdl_int_seq *" else: ctype = "asdl_seq *" else: ctype = get_c_type(f.type) args.append((ctype, name, f.opt or f.seq)) return args def visitConstructor(self, cons, type, attrs): args = self.get_args(cons.fields) attrs = self.get_args(attrs) ctype = get_c_type(type) self.emit_function(cons.name, ctype, args, attrs) def emit_function(self, name, ctype, args, attrs, union=True): args = args + attrs if args: argstr = ", ".join(["%s %s" % (atype, aname) for atype, aname, opt in args]) argstr += ", PyArena *arena" else: argstr = "PyArena *arena" margs = "a0" for i in range(1, len(args)+1): margs += ", a%d" % i self.emit("#define %s(%s) _Py_%s(%s)" % (name, margs, name, margs), 0, reflow=False) self.emit("%s _Py_%s(%s);" % (ctype, name, argstr), False) def visitProduct(self, prod, name): self.emit_function(name, get_c_type(name), self.get_args(prod.fields), self.get_args(prod.attributes), union=False) class FunctionVisitor(PrototypeVisitor): """Visitor to generate constructor functions for AST.""" def emit_function(self, name, ctype, args, attrs, union=True): def emit(s, depth=0, reflow=True): self.emit(s, depth, reflow) argstr = ", ".join(["%s %s" % (atype, aname) for atype, aname, opt in args + attrs]) if argstr: argstr += ", PyArena *arena" else: argstr = "PyArena *arena" self.emit("%s" % ctype, 0) emit("%s(%s)" % (name, argstr)) emit("{") emit("%s p;" % ctype, 1) for argtype, argname, opt in args: if not opt and argtype != "int": emit("if (!%s) {" % argname, 1) emit("PyErr_SetString(PyExc_ValueError,", 2) msg = "field %s is required for %s" % (argname, name) emit(' "%s");' % msg, 2, reflow=False) emit('return NULL;', 2) emit('}', 1) emit("p = (%s)PyArena_Malloc(arena, sizeof(*p));" % ctype, 1); emit("if (!p)", 1) emit("return NULL;", 2) if union: self.emit_body_union(name, args, attrs) else: self.emit_body_struct(name, args, attrs) emit("return p;", 1) emit("}") emit("") def emit_body_union(self, name, args, attrs): def emit(s, depth=0, reflow=True): self.emit(s, depth, reflow) emit("p->kind = %s_kind;" % name, 1) for argtype, argname, opt in args: emit("p->v.%s.%s = %s;" % (name, argname, argname), 1) for argtype, argname, opt in attrs: emit("p->%s = %s;" % (argname, argname), 1) def emit_body_struct(self, name, args, attrs): def emit(s, depth=0, reflow=True): self.emit(s, depth, reflow) for argtype, argname, opt in args: emit("p->%s = %s;" % (argname, argname), 1) for argtype, argname, opt in attrs: emit("p->%s = %s;" % (argname, argname), 1) class PickleVisitor(EmitVisitor): def visitModule(self, mod): for dfn in mod.dfns: self.visit(dfn) def visitType(self, type): self.visit(type.value, type.name) def visitSum(self, sum, name): pass def visitProduct(self, sum, name): pass def visitConstructor(self, cons, name): pass def visitField(self, sum): pass class Obj2ModPrototypeVisitor(PickleVisitor): def visitProduct(self, prod, name): code = "static int obj2ast_%s(PyObject* obj, %s* out, PyArena* arena);" self.emit(code % (name, get_c_type(name)), 0) visitSum = visitProduct class Obj2ModVisitor(PickleVisitor): def funcHeader(self, name): ctype = get_c_type(name) self.emit("int", 0) self.emit("obj2ast_%s(PyObject* obj, %s* out, PyArena* arena)" % (name, ctype), 0) self.emit("{", 0) self.emit("int isinstance;", 1) self.emit("", 0) def sumTrailer(self, name, add_label=False): self.emit("", 0) # there's really nothing more we can do if this fails ... error = "expected some sort of %s, but got %%R" % name format = "PyErr_Format(PyExc_TypeError, \"%s\", obj);" self.emit(format % error, 1, reflow=False) if add_label: self.emit("failed:", 1) self.emit("Py_XDECREF(tmp);", 1) self.emit("return 1;", 1) self.emit("}", 0) self.emit("", 0) def simpleSum(self, sum, name): self.funcHeader(name) for t in sum.types: line = ("isinstance = PyObject_IsInstance(obj, " "(PyObject *)%s_type);") self.emit(line % (t.name,), 1) self.emit("if (isinstance == -1) {", 1) self.emit("return 1;", 2) self.emit("}", 1) self.emit("if (isinstance) {", 1) self.emit("*out = %s;" % t.name, 2) self.emit("return 0;", 2) self.emit("}", 1) self.sumTrailer(name) def buildArgs(self, fields): return ", ".join(fields + ["arena"]) def complexSum(self, sum, name): self.funcHeader(name) self.emit("PyObject *tmp = NULL;", 1) for a in sum.attributes: self.visitAttributeDeclaration(a, name, sum=sum) self.emit("", 0) # XXX: should we only do this for 'expr'? self.emit("if (obj == Py_None) {", 1) self.emit("*out = NULL;", 2) self.emit("return 0;", 2) self.emit("}", 1) for a in sum.attributes: self.visitField(a, name, sum=sum, depth=1) for t in sum.types: line = "isinstance = PyObject_IsInstance(obj, (PyObject*)%s_type);" self.emit(line % (t.name,), 1) self.emit("if (isinstance == -1) {", 1) self.emit("return 1;", 2) self.emit("}", 1) self.emit("if (isinstance) {", 1) for f in t.fields: self.visitFieldDeclaration(f, t.name, sum=sum, depth=2) self.emit("", 0) for f in t.fields: self.visitField(f, t.name, sum=sum, depth=2) args = [f.name for f in t.fields] + [a.name for a in sum.attributes] self.emit("*out = %s(%s);" % (t.name, self.buildArgs(args)), 2) self.emit("if (*out == NULL) goto failed;", 2) self.emit("return 0;", 2) self.emit("}", 1) self.sumTrailer(name, True) def visitAttributeDeclaration(self, a, name, sum=sum): ctype = get_c_type(a.type) self.emit("%s %s;" % (ctype, a.name), 1) def visitSum(self, sum, name): if is_simple(sum): self.simpleSum(sum, name) else: self.complexSum(sum, name) def visitProduct(self, prod, name): ctype = get_c_type(name) self.emit("int", 0) self.emit("obj2ast_%s(PyObject* obj, %s* out, PyArena* arena)" % (name, ctype), 0) self.emit("{", 0) self.emit("PyObject* tmp = NULL;", 1) for f in prod.fields: self.visitFieldDeclaration(f, name, prod=prod, depth=1) for a in prod.attributes: self.visitFieldDeclaration(a, name, prod=prod, depth=1) self.emit("", 0) for f in prod.fields: self.visitField(f, name, prod=prod, depth=1) for a in prod.attributes: self.visitField(a, name, prod=prod, depth=1) args = [f.name for f in prod.fields] args.extend([a.name for a in prod.attributes]) self.emit("*out = %s(%s);" % (name, self.buildArgs(args)), 1) self.emit("return 0;", 1) self.emit("failed:", 0) self.emit("Py_XDECREF(tmp);", 1) self.emit("return 1;", 1) self.emit("}", 0) self.emit("", 0) def visitFieldDeclaration(self, field, name, sum=None, prod=None, depth=0): ctype = get_c_type(field.type) if field.seq: if self.isSimpleType(field): self.emit("asdl_int_seq* %s;" % field.name, depth) else: self.emit("asdl_seq* %s;" % field.name, depth) else: ctype = get_c_type(field.type) self.emit("%s %s;" % (ctype, field.name), depth) def isSimpleSum(self, field): # XXX can the members of this list be determined automatically? return field.type in ('expr_context', 'boolop', 'operator', 'unaryop', 'cmpop') def isNumeric(self, field): return get_c_type(field.type) in ("int", "bool") def isSimpleType(self, field): return self.isSimpleSum(field) or self.isNumeric(field) def visitField(self, field, name, sum=None, prod=None, depth=0): ctype = get_c_type(field.type) self.emit("if (_PyObject_LookupAttrId(obj, &PyId_%s, &tmp) < 0) {" % field.name, depth) self.emit("return 1;", depth+1) self.emit("}", depth) if not field.opt: self.emit("if (tmp == NULL) {", depth) message = "required field \\\"%s\\\" missing from %s" % (field.name, name) format = "PyErr_SetString(PyExc_TypeError, \"%s\");" self.emit(format % message, depth+1, reflow=False) self.emit("return 1;", depth+1) else: self.emit("if (tmp == NULL || tmp == Py_None) {", depth) self.emit("Py_CLEAR(tmp);", depth+1) if self.isNumeric(field): self.emit("%s = 0;" % field.name, depth+1) elif not self.isSimpleType(field): self.emit("%s = NULL;" % field.name, depth+1) else: raise TypeError("could not determine the default value for %s" % field.name) self.emit("}", depth) self.emit("else {", depth) self.emit("int res;", depth+1) if field.seq: self.emit("Py_ssize_t len;", depth+1) self.emit("Py_ssize_t i;", depth+1) self.emit("if (!PyList_Check(tmp)) {", depth+1) self.emit("PyErr_Format(PyExc_TypeError, \"%s field \\\"%s\\\" must " "be a list, not a %%.200s\", tmp->ob_type->tp_name);" % (name, field.name), depth+2, reflow=False) self.emit("goto failed;", depth+2) self.emit("}", depth+1) self.emit("len = PyList_GET_SIZE(tmp);", depth+1) if self.isSimpleType(field): self.emit("%s = _Py_asdl_int_seq_new(len, arena);" % field.name, depth+1) else: self.emit("%s = _Py_asdl_seq_new(len, arena);" % field.name, depth+1) self.emit("if (%s == NULL) goto failed;" % field.name, depth+1) self.emit("for (i = 0; i < len; i++) {", depth+1) self.emit("%s val;" % ctype, depth+2) self.emit("res = obj2ast_%s(PyList_GET_ITEM(tmp, i), &val, arena);" % field.type, depth+2, reflow=False) self.emit("if (res != 0) goto failed;", depth+2) self.emit("if (len != PyList_GET_SIZE(tmp)) {", depth+2) self.emit("PyErr_SetString(PyExc_RuntimeError, \"%s field \\\"%s\\\" " "changed size during iteration\");" % (name, field.name), depth+3, reflow=False) self.emit("goto failed;", depth+3) self.emit("}", depth+2) self.emit("asdl_seq_SET(%s, i, val);" % field.name, depth+2) self.emit("}", depth+1) else: self.emit("res = obj2ast_%s(tmp, &%s, arena);" % (field.type, field.name), depth+1) self.emit("if (res != 0) goto failed;", depth+1) self.emit("Py_CLEAR(tmp);", depth+1) self.emit("}", depth) class MarshalPrototypeVisitor(PickleVisitor): def prototype(self, sum, name): ctype = get_c_type(name) self.emit("static int marshal_write_%s(PyObject **, int *, %s);" % (name, ctype), 0) visitProduct = visitSum = prototype class PyTypesDeclareVisitor(PickleVisitor): def visitProduct(self, prod, name): self.emit("static PyTypeObject *%s_type;" % name, 0) self.emit("static PyObject* ast2obj_%s(void*);" % name, 0) if prod.attributes: for a in prod.attributes: self.emit_identifier(a.name) self.emit("static char *%s_attributes[] = {" % name, 0) for a in prod.attributes: self.emit('"%s",' % a.name, 1) self.emit("};", 0) if prod.fields: for f in prod.fields: self.emit_identifier(f.name) self.emit("static char *%s_fields[]={" % name,0) for f in prod.fields: self.emit('"%s",' % f.name, 1) self.emit("};", 0) def visitSum(self, sum, name): self.emit("static PyTypeObject *%s_type;" % name, 0) if sum.attributes: for a in sum.attributes: self.emit_identifier(a.name) self.emit("static char *%s_attributes[] = {" % name, 0) for a in sum.attributes: self.emit('"%s",' % a.name, 1) self.emit("};", 0) ptype = "void*" if is_simple(sum): ptype = get_c_type(name) tnames = [] for t in sum.types: tnames.append(str(t.name)+"_singleton") tnames = ", *".join(tnames) self.emit("static PyObject *%s;" % tnames, 0) self.emit("static PyObject* ast2obj_%s(%s);" % (name, ptype), 0) for t in sum.types: self.visitConstructor(t, name) def visitConstructor(self, cons, name): self.emit("static PyTypeObject *%s_type;" % cons.name, 0) if cons.fields: for t in cons.fields: self.emit_identifier(t.name) self.emit("static char *%s_fields[]={" % cons.name, 0) for t in cons.fields: self.emit('"%s",' % t.name, 1) self.emit("};",0) class PyTypesVisitor(PickleVisitor): def visitModule(self, mod): self.emit(""" _Py_IDENTIFIER(_fields); _Py_IDENTIFIER(_attributes); typedef struct { PyObject_HEAD PyObject *dict; } AST_object; static void ast_dealloc(AST_object *self) { /* bpo-31095: UnTrack is needed before calling any callbacks */ PyObject_GC_UnTrack(self); Py_CLEAR(self->dict); Py_TYPE(self)->tp_free(self); } static int ast_traverse(AST_object *self, visitproc visit, void *arg) { Py_VISIT(self->dict); return 0; } static int ast_clear(AST_object *self) { Py_CLEAR(self->dict); return 0; } static int ast_type_init(PyObject *self, PyObject *args, PyObject *kw) { Py_ssize_t i, numfields = 0; int res = -1; PyObject *key, *value, *fields; if (_PyObject_LookupAttrId((PyObject*)Py_TYPE(self), &PyId__fields, &fields) < 0) { goto cleanup; } if (fields) { numfields = PySequence_Size(fields); if (numfields == -1) goto cleanup; } res = 0; /* if no error occurs, this stays 0 to the end */ if (numfields < PyTuple_GET_SIZE(args)) { PyErr_Format(PyExc_TypeError, "%.400s constructor takes at most " "%zd positional argument%s", Py_TYPE(self)->tp_name, numfields, numfields == 1 ? "" : "s"); res = -1; goto cleanup; } for (i = 0; i < PyTuple_GET_SIZE(args); i++) { /* cannot be reached when fields is NULL */ PyObject *name = PySequence_GetItem(fields, i); if (!name) { res = -1; goto cleanup; } res = PyObject_SetAttr(self, name, PyTuple_GET_ITEM(args, i)); Py_DECREF(name); if (res < 0) goto cleanup; } if (kw) { i = 0; /* needed by PyDict_Next */ while (PyDict_Next(kw, &i, &key, &value)) { res = PyObject_SetAttr(self, key, value); if (res < 0) goto cleanup; } } cleanup: Py_XDECREF(fields); return res; } /* Pickling support */ static PyObject * ast_type_reduce(PyObject *self, PyObject *unused) { _Py_IDENTIFIER(__dict__); PyObject *dict; if (_PyObject_LookupAttrId(self, &PyId___dict__, &dict) < 0) { return NULL; } if (dict) { return Py_BuildValue("O()N", Py_TYPE(self), dict); } return Py_BuildValue("O()", Py_TYPE(self)); } static PyMethodDef ast_type_methods[] = { {"__reduce__", ast_type_reduce, METH_NOARGS, NULL}, {NULL} }; static PyGetSetDef ast_type_getsets[] = { {"__dict__", PyObject_GenericGetDict, PyObject_GenericSetDict}, {NULL} }; static PyTypeObject AST_type = { PyVarObject_HEAD_INIT(&PyType_Type, 0) "_ast.AST", sizeof(AST_object), 0, (destructor)ast_dealloc, /* tp_dealloc */ 0, /* tp_print */ 0, /* tp_getattr */ 0, /* tp_setattr */ 0, /* tp_reserved */ 0, /* tp_repr */ 0, /* tp_as_number */ 0, /* tp_as_sequence */ 0, /* tp_as_mapping */ 0, /* tp_hash */ 0, /* tp_call */ 0, /* tp_str */ PyObject_GenericGetAttr, /* tp_getattro */ PyObject_GenericSetAttr, /* tp_setattro */ 0, /* tp_as_buffer */ Py_TPFLAGS_DEFAULT | Py_TPFLAGS_BASETYPE | Py_TPFLAGS_HAVE_GC, /* tp_flags */ 0, /* tp_doc */ (traverseproc)ast_traverse, /* tp_traverse */ (inquiry)ast_clear, /* tp_clear */ 0, /* tp_richcompare */ 0, /* tp_weaklistoffset */ 0, /* tp_iter */ 0, /* tp_iternext */ ast_type_methods, /* tp_methods */ 0, /* tp_members */ ast_type_getsets, /* tp_getset */ 0, /* tp_base */ 0, /* tp_dict */ 0, /* tp_descr_get */ 0, /* tp_descr_set */ offsetof(AST_object, dict),/* tp_dictoffset */ (initproc)ast_type_init, /* tp_init */ PyType_GenericAlloc, /* tp_alloc */ PyType_GenericNew, /* tp_new */ PyObject_GC_Del, /* tp_free */ }; static PyTypeObject* make_type(char *type, PyTypeObject* base, char**fields, int num_fields) { _Py_IDENTIFIER(__module__); _Py_IDENTIFIER(_ast); PyObject *fnames, *result; int i; fnames = PyTuple_New(num_fields); if (!fnames) return NULL; for (i = 0; i < num_fields; i++) { PyObject *field = PyUnicode_FromString(fields[i]); if (!field) { Py_DECREF(fnames); return NULL; } PyTuple_SET_ITEM(fnames, i, field); } result = PyObject_CallFunction((PyObject*)&PyType_Type, "s(O){OOOO}", type, base, _PyUnicode_FromId(&PyId__fields), fnames, _PyUnicode_FromId(&PyId___module__), _PyUnicode_FromId(&PyId__ast)); Py_DECREF(fnames); return (PyTypeObject*)result; } static int add_attributes(PyTypeObject* type, char**attrs, int num_fields) { int i, result; PyObject *s, *l = PyTuple_New(num_fields); if (!l) return 0; for (i = 0; i < num_fields; i++) { s = PyUnicode_FromString(attrs[i]); if (!s) { Py_DECREF(l); return 0; } PyTuple_SET_ITEM(l, i, s); } result = _PyObject_SetAttrId((PyObject*)type, &PyId__attributes, l) >= 0; Py_DECREF(l); return result; } /* Conversion AST -> Python */ static PyObject* ast2obj_list(asdl_seq *seq, PyObject* (*func)(void*)) { Py_ssize_t i, n = asdl_seq_LEN(seq); PyObject *result = PyList_New(n); PyObject *value; if (!result) return NULL; for (i = 0; i < n; i++) { value = func(asdl_seq_GET(seq, i)); if (!value) { Py_DECREF(result); return NULL; } PyList_SET_ITEM(result, i, value); } return result; } static PyObject* ast2obj_object(void *o) { if (!o) o = Py_None; Py_INCREF((PyObject*)o); return (PyObject*)o; } #define ast2obj_singleton ast2obj_object #define ast2obj_constant ast2obj_object #define ast2obj_identifier ast2obj_object #define ast2obj_string ast2obj_object #define ast2obj_bytes ast2obj_object static PyObject* ast2obj_int(long b) { return PyLong_FromLong(b); } /* Conversion Python -> AST */ static int obj2ast_singleton(PyObject *obj, PyObject** out, PyArena* arena) { if (obj != Py_None && obj != Py_True && obj != Py_False) { PyErr_SetString(PyExc_ValueError, "AST singleton must be True, False, or None"); return 1; } *out = obj; return 0; } static int obj2ast_object(PyObject* obj, PyObject** out, PyArena* arena) { if (obj == Py_None) obj = NULL; if (obj) { if (PyArena_AddPyObject(arena, obj) < 0) { *out = NULL; return -1; } Py_INCREF(obj); } *out = obj; return 0; } static int obj2ast_constant(PyObject* obj, PyObject** out, PyArena* arena) { if (obj) { if (PyArena_AddPyObject(arena, obj) < 0) { *out = NULL; return -1; } Py_INCREF(obj); } *out = obj; return 0; } static int obj2ast_identifier(PyObject* obj, PyObject** out, PyArena* arena) { if (!PyUnicode_CheckExact(obj) && obj != Py_None) { PyErr_SetString(PyExc_TypeError, "AST identifier must be of type str"); return 1; } return obj2ast_object(obj, out, arena); } static int obj2ast_string(PyObject* obj, PyObject** out, PyArena* arena) { if (!PyUnicode_CheckExact(obj) && !PyBytes_CheckExact(obj)) { PyErr_SetString(PyExc_TypeError, "AST string must be of type str"); return 1; } return obj2ast_object(obj, out, arena); } static int obj2ast_bytes(PyObject* obj, PyObject** out, PyArena* arena) { if (!PyBytes_CheckExact(obj)) { PyErr_SetString(PyExc_TypeError, "AST bytes must be of type bytes"); return 1; } return obj2ast_object(obj, out, arena); } static int obj2ast_int(PyObject* obj, int* out, PyArena* arena) { int i; if (!PyLong_Check(obj)) { PyErr_Format(PyExc_ValueError, "invalid integer value: %R", obj); return 1; } i = _PyLong_AsInt(obj); if (i == -1 && PyErr_Occurred()) return 1; *out = i; return 0; } static int add_ast_fields(void) { PyObject *empty_tuple, *d; if (PyType_Ready(&AST_type) < 0) return -1; d = AST_type.tp_dict; empty_tuple = PyTuple_New(0); if (!empty_tuple || _PyDict_SetItemId(d, &PyId__fields, empty_tuple) < 0 || _PyDict_SetItemId(d, &PyId__attributes, empty_tuple) < 0) { Py_XDECREF(empty_tuple); return -1; } Py_DECREF(empty_tuple); return 0; } """, 0, reflow=False) self.emit("static int init_types(void)",0) self.emit("{", 0) self.emit("static int initialized;", 1) self.emit("if (initialized) return 1;", 1) self.emit("if (add_ast_fields() < 0) return 0;", 1) for dfn in mod.dfns: self.visit(dfn) self.emit("initialized = 1;", 1) self.emit("return 1;", 1); self.emit("}", 0) def visitProduct(self, prod, name): if prod.fields: fields = name+"_fields" else: fields = "NULL" self.emit('%s_type = make_type("%s", &AST_type, %s, %d);' % (name, name, fields, len(prod.fields)), 1) self.emit("if (!%s_type) return 0;" % name, 1) if prod.attributes: self.emit("if (!add_attributes(%s_type, %s_attributes, %d)) return 0;" % (name, name, len(prod.attributes)), 1) else: self.emit("if (!add_attributes(%s_type, NULL, 0)) return 0;" % name, 1) def visitSum(self, sum, name): self.emit('%s_type = make_type("%s", &AST_type, NULL, 0);' % (name, name), 1) self.emit("if (!%s_type) return 0;" % name, 1) if sum.attributes: self.emit("if (!add_attributes(%s_type, %s_attributes, %d)) return 0;" % (name, name, len(sum.attributes)), 1) else: self.emit("if (!add_attributes(%s_type, NULL, 0)) return 0;" % name, 1) simple = is_simple(sum) for t in sum.types: self.visitConstructor(t, name, simple) def visitConstructor(self, cons, name, simple): if cons.fields: fields = cons.name+"_fields" else: fields = "NULL" self.emit('%s_type = make_type("%s", %s_type, %s, %d);' % (cons.name, cons.name, name, fields, len(cons.fields)), 1) self.emit("if (!%s_type) return 0;" % cons.name, 1) if simple: self.emit("%s_singleton = PyType_GenericNew(%s_type, NULL, NULL);" % (cons.name, cons.name), 1) self.emit("if (!%s_singleton) return 0;" % cons.name, 1) class ASTModuleVisitor(PickleVisitor): def visitModule(self, mod): self.emit("static struct PyModuleDef _astmodule = {", 0) self.emit(' PyModuleDef_HEAD_INIT, "_ast"', 0) self.emit("};", 0) self.emit("PyMODINIT_FUNC", 0) self.emit("PyInit__ast(void)", 0) self.emit("{", 0) self.emit("PyObject *m, *d;", 1) self.emit("if (!init_types()) return NULL;", 1) self.emit('m = PyModule_Create(&_astmodule);', 1) self.emit("if (!m) return NULL;", 1) self.emit("d = PyModule_GetDict(m);", 1) self.emit('if (PyDict_SetItemString(d, "AST", (PyObject*)&AST_type) < 0) return NULL;', 1) self.emit('if (PyModule_AddIntMacro(m, PyCF_ONLY_AST) < 0)', 1) self.emit("return NULL;", 2) for dfn in mod.dfns: self.visit(dfn) self.emit("return m;", 1) self.emit("}", 0) def visitProduct(self, prod, name): self.addObj(name) def visitSum(self, sum, name): self.addObj(name) for t in sum.types: self.visitConstructor(t, name) def visitConstructor(self, cons, name): self.addObj(cons.name) def addObj(self, name): self.emit('if (PyDict_SetItemString(d, "%s", (PyObject*)%s_type) < 0) return NULL;' % (name, name), 1) _SPECIALIZED_SEQUENCES = ('stmt', 'expr') def find_sequence(fields, doing_specialization): """Return True if any field uses a sequence.""" for f in fields: if f.seq: if not doing_specialization: return True if str(f.type) not in _SPECIALIZED_SEQUENCES: return True return False def has_sequence(types, doing_specialization): for t in types: if find_sequence(t.fields, doing_specialization): return True return False class StaticVisitor(PickleVisitor): CODE = '''Very simple, always emit this static code. Override CODE''' def visit(self, object): self.emit(self.CODE, 0, reflow=False) class ObjVisitor(PickleVisitor): def func_begin(self, name): ctype = get_c_type(name) self.emit("PyObject*", 0) self.emit("ast2obj_%s(void* _o)" % (name), 0) self.emit("{", 0) self.emit("%s o = (%s)_o;" % (ctype, ctype), 1) self.emit("PyObject *result = NULL, *value = NULL;", 1) self.emit('if (!o) {', 1) self.emit("Py_RETURN_NONE;", 2) self.emit("}", 1) self.emit('', 0) def func_end(self): self.emit("return result;", 1) self.emit("failed:", 0) self.emit("Py_XDECREF(value);", 1) self.emit("Py_XDECREF(result);", 1) self.emit("return NULL;", 1) self.emit("}", 0) self.emit("", 0) def visitSum(self, sum, name): if is_simple(sum): self.simpleSum(sum, name) return self.func_begin(name) self.emit("switch (o->kind) {", 1) for i in range(len(sum.types)): t = sum.types[i] self.visitConstructor(t, i + 1, name) self.emit("}", 1) for a in sum.attributes: self.emit("value = ast2obj_%s(o->%s);" % (a.type, a.name), 1) self.emit("if (!value) goto failed;", 1) self.emit('if (_PyObject_SetAttrId(result, &PyId_%s, value) < 0)' % a.name, 1) self.emit('goto failed;', 2) self.emit('Py_DECREF(value);', 1) self.func_end() def simpleSum(self, sum, name): self.emit("PyObject* ast2obj_%s(%s_ty o)" % (name, name), 0) self.emit("{", 0) self.emit("switch(o) {", 1) for t in sum.types: self.emit("case %s:" % t.name, 2) self.emit("Py_INCREF(%s_singleton);" % t.name, 3) self.emit("return %s_singleton;" % t.name, 3) self.emit("default:", 2) self.emit('/* should never happen, but just in case ... */', 3) code = "PyErr_Format(PyExc_SystemError, \"unknown %s found\");" % name self.emit(code, 3, reflow=False) self.emit("return NULL;", 3) self.emit("}", 1) self.emit("}", 0) def visitProduct(self, prod, name): self.func_begin(name) self.emit("result = PyType_GenericNew(%s_type, NULL, NULL);" % name, 1); self.emit("if (!result) return NULL;", 1) for field in prod.fields: self.visitField(field, name, 1, True) for a in prod.attributes: self.emit("value = ast2obj_%s(o->%s);" % (a.type, a.name), 1) self.emit("if (!value) goto failed;", 1) self.emit('if (_PyObject_SetAttrId(result, &PyId_%s, value) < 0)' % a.name, 1) self.emit('goto failed;', 2) self.emit('Py_DECREF(value);', 1) self.func_end() def visitConstructor(self, cons, enum, name): self.emit("case %s_kind:" % cons.name, 1) self.emit("result = PyType_GenericNew(%s_type, NULL, NULL);" % cons.name, 2); self.emit("if (!result) goto failed;", 2) for f in cons.fields: self.visitField(f, cons.name, 2, False) self.emit("break;", 2) def visitField(self, field, name, depth, product): def emit(s, d): self.emit(s, depth + d) if product: value = "o->%s" % field.name else: value = "o->v.%s.%s" % (name, field.name) self.set(field, value, depth) emit("if (!value) goto failed;", 0) emit('if (_PyObject_SetAttrId(result, &PyId_%s, value) == -1)' % field.name, 0) emit("goto failed;", 1) emit("Py_DECREF(value);", 0) def emitSeq(self, field, value, depth, emit): emit("seq = %s;" % value, 0) emit("n = asdl_seq_LEN(seq);", 0) emit("value = PyList_New(n);", 0) emit("if (!value) goto failed;", 0) emit("for (i = 0; i < n; i++) {", 0) self.set("value", field, "asdl_seq_GET(seq, i)", depth + 1) emit("if (!value1) goto failed;", 1) emit("PyList_SET_ITEM(value, i, value1);", 1) emit("value1 = NULL;", 1) emit("}", 0) def set(self, field, value, depth): if field.seq: # XXX should really check for is_simple, but that requires a symbol table if field.type == "cmpop": # While the sequence elements are stored as void*, # ast2obj_cmpop expects an enum self.emit("{", depth) self.emit("Py_ssize_t i, n = asdl_seq_LEN(%s);" % value, depth+1) self.emit("value = PyList_New(n);", depth+1) self.emit("if (!value) goto failed;", depth+1) self.emit("for(i = 0; i < n; i++)", depth+1) # This cannot fail, so no need for error handling self.emit("PyList_SET_ITEM(value, i, ast2obj_cmpop((cmpop_ty)asdl_seq_GET(%s, i)));" % value, depth+2, reflow=False) self.emit("}", depth) else: self.emit("value = ast2obj_list(%s, ast2obj_%s);" % (value, field.type), depth) else: ctype = get_c_type(field.type) self.emit("value = ast2obj_%s(%s);" % (field.type, value), depth, reflow=False) class PartingShots(StaticVisitor): CODE = """ PyObject* PyAST_mod2obj(mod_ty t) { if (!init_types()) return NULL; return ast2obj_mod(t); } /* mode is 0 for "exec", 1 for "eval" and 2 for "single" input */ mod_ty PyAST_obj2mod(PyObject* ast, PyArena* arena, int mode) { mod_ty res; PyObject *req_type[3]; char *req_name[] = {"Module", "Expression", "Interactive"}; int isinstance; req_type[0] = (PyObject*)Module_type; req_type[1] = (PyObject*)Expression_type; req_type[2] = (PyObject*)Interactive_type; assert(0 <= mode && mode <= 2); if (!init_types()) return NULL; isinstance = PyObject_IsInstance(ast, req_type[mode]); if (isinstance == -1) return NULL; if (!isinstance) { PyErr_Format(PyExc_TypeError, "expected %s node, got %.400s", req_name[mode], Py_TYPE(ast)->tp_name); return NULL; } if (obj2ast_mod(ast, &res, arena) != 0) return NULL; else return res; } int PyAST_Check(PyObject* obj) { if (!init_types()) return -1; return PyObject_IsInstance(obj, (PyObject*)&AST_type); } """ class ChainOfVisitors: def __init__(self, *visitors): self.visitors = visitors def visit(self, object): for v in self.visitors: v.visit(object) v.emit("", 0) common_msg = "/* File automatically generated by %s. */\n\n" def main(srcfile, dump_module=False): argv0 = sys.argv[0] components = argv0.split(os.sep) argv0 = os.sep.join(components[-2:]) auto_gen_msg = common_msg % argv0 mod = asdl.parse(srcfile) if dump_module: print('Parsed Module:') print(mod) if not asdl.check(mod): sys.exit(1) if H_FILE: with open(H_FILE, "w") as f: f.write(auto_gen_msg) f.write('#include "asdl.h"\n\n') c = ChainOfVisitors(TypeDefVisitor(f), StructVisitor(f), PrototypeVisitor(f), ) c.visit(mod) f.write("PyObject* PyAST_mod2obj(mod_ty t);\n") f.write("mod_ty PyAST_obj2mod(PyObject* ast, PyArena* arena, int mode);\n") f.write("int PyAST_Check(PyObject* obj);\n") if C_FILE: with open(C_FILE, "w") as f: f.write(auto_gen_msg) f.write('#include \n') f.write('\n') f.write('#include "Python.h"\n') f.write('#include "%s-ast.h"\n' % mod.name) f.write('\n') f.write("static PyTypeObject AST_type;\n") v = ChainOfVisitors( PyTypesDeclareVisitor(f), PyTypesVisitor(f), Obj2ModPrototypeVisitor(f), FunctionVisitor(f), ObjVisitor(f), Obj2ModVisitor(f), ASTModuleVisitor(f), PartingShots(f), ) v.visit(mod) if __name__ == "__main__": import getopt H_FILE = '' C_FILE = '' dump_module = False opts, args = getopt.getopt(sys.argv[1:], "dh:c:") for o, v in opts: if o == '-h': H_FILE = v if o == '-c': C_FILE = v if o == '-d': dump_module = True if H_FILE and C_FILE: print('Must specify exactly one output file') sys.exit(1) elif len(args) != 1: print('Must specify single input file') sys.exit(1) main(args[0], dump_module)