#include #include "pegen.h" #include "string_parser.h" #include "pycore_runtime.h" // _PyRuntime #include "pycore_pystate.h" // _PyInterpreterState_GET() void * _PyPegen_dummy_name(Parser *p, ...) { return &_PyRuntime.parser.dummy_name; } /* Creates a single-element asdl_seq* that contains a */ asdl_seq * _PyPegen_singleton_seq(Parser *p, void *a) { assert(a != NULL); asdl_seq *seq = (asdl_seq*)_Py_asdl_generic_seq_new(1, p->arena); if (!seq) { return NULL; } asdl_seq_SET_UNTYPED(seq, 0, a); return seq; } /* Creates a copy of seq and prepends a to it */ asdl_seq * _PyPegen_seq_insert_in_front(Parser *p, void *a, asdl_seq *seq) { assert(a != NULL); if (!seq) { return _PyPegen_singleton_seq(p, a); } asdl_seq *new_seq = (asdl_seq*)_Py_asdl_generic_seq_new(asdl_seq_LEN(seq) + 1, p->arena); if (!new_seq) { return NULL; } asdl_seq_SET_UNTYPED(new_seq, 0, a); for (Py_ssize_t i = 1, l = asdl_seq_LEN(new_seq); i < l; i++) { asdl_seq_SET_UNTYPED(new_seq, i, asdl_seq_GET_UNTYPED(seq, i - 1)); } return new_seq; } /* Creates a copy of seq and appends a to it */ asdl_seq * _PyPegen_seq_append_to_end(Parser *p, asdl_seq *seq, void *a) { assert(a != NULL); if (!seq) { return _PyPegen_singleton_seq(p, a); } asdl_seq *new_seq = (asdl_seq*)_Py_asdl_generic_seq_new(asdl_seq_LEN(seq) + 1, p->arena); if (!new_seq) { return NULL; } for (Py_ssize_t i = 0, l = asdl_seq_LEN(new_seq); i + 1 < l; i++) { asdl_seq_SET_UNTYPED(new_seq, i, asdl_seq_GET_UNTYPED(seq, i)); } asdl_seq_SET_UNTYPED(new_seq, asdl_seq_LEN(new_seq) - 1, a); return new_seq; } static Py_ssize_t _get_flattened_seq_size(asdl_seq *seqs) { Py_ssize_t size = 0; for (Py_ssize_t i = 0, l = asdl_seq_LEN(seqs); i < l; i++) { asdl_seq *inner_seq = asdl_seq_GET_UNTYPED(seqs, i); size += asdl_seq_LEN(inner_seq); } return size; } /* Flattens an asdl_seq* of asdl_seq*s */ asdl_seq * _PyPegen_seq_flatten(Parser *p, asdl_seq *seqs) { Py_ssize_t flattened_seq_size = _get_flattened_seq_size(seqs); assert(flattened_seq_size > 0); asdl_seq *flattened_seq = (asdl_seq*)_Py_asdl_generic_seq_new(flattened_seq_size, p->arena); if (!flattened_seq) { return NULL; } int flattened_seq_idx = 0; for (Py_ssize_t i = 0, l = asdl_seq_LEN(seqs); i < l; i++) { asdl_seq *inner_seq = asdl_seq_GET_UNTYPED(seqs, i); for (Py_ssize_t j = 0, li = asdl_seq_LEN(inner_seq); j < li; j++) { asdl_seq_SET_UNTYPED(flattened_seq, flattened_seq_idx++, asdl_seq_GET_UNTYPED(inner_seq, j)); } } assert(flattened_seq_idx == flattened_seq_size); return flattened_seq; } void * _PyPegen_seq_last_item(asdl_seq *seq) { Py_ssize_t len = asdl_seq_LEN(seq); return asdl_seq_GET_UNTYPED(seq, len - 1); } void * _PyPegen_seq_first_item(asdl_seq *seq) { return asdl_seq_GET_UNTYPED(seq, 0); } /* Creates a new name of the form . */ expr_ty _PyPegen_join_names_with_dot(Parser *p, expr_ty first_name, expr_ty second_name) { assert(first_name != NULL && second_name != NULL); PyObject *uni = PyUnicode_FromFormat("%U.%U", first_name->v.Name.id, second_name->v.Name.id); if (!uni) { return NULL; } PyInterpreterState *interp = _PyInterpreterState_GET(); _PyUnicode_InternImmortal(interp, &uni); if (_PyArena_AddPyObject(p->arena, uni) < 0) { Py_DECREF(uni); return NULL; } return _PyAST_Name(uni, Load, EXTRA_EXPR(first_name, second_name)); } /* Counts the total number of dots in seq's tokens */ int _PyPegen_seq_count_dots(asdl_seq *seq) { int number_of_dots = 0; for (Py_ssize_t i = 0, l = asdl_seq_LEN(seq); i < l; i++) { Token *current_expr = asdl_seq_GET_UNTYPED(seq, i); switch (current_expr->type) { case ELLIPSIS: number_of_dots += 3; break; case DOT: number_of_dots += 1; break; default: Py_UNREACHABLE(); } } return number_of_dots; } /* Creates an alias with '*' as the identifier name */ alias_ty _PyPegen_alias_for_star(Parser *p, int lineno, int col_offset, int end_lineno, int end_col_offset, PyArena *arena) { PyObject *str = PyUnicode_InternFromString("*"); if (!str) { return NULL; } if (_PyArena_AddPyObject(p->arena, str) < 0) { Py_DECREF(str); return NULL; } return _PyAST_alias(str, NULL, lineno, col_offset, end_lineno, end_col_offset, arena); } /* Creates a new asdl_seq* with the identifiers of all the names in seq */ asdl_identifier_seq * _PyPegen_map_names_to_ids(Parser *p, asdl_expr_seq *seq) { Py_ssize_t len = asdl_seq_LEN(seq); assert(len > 0); asdl_identifier_seq *new_seq = _Py_asdl_identifier_seq_new(len, p->arena); if (!new_seq) { return NULL; } for (Py_ssize_t i = 0; i < len; i++) { expr_ty e = asdl_seq_GET(seq, i); asdl_seq_SET(new_seq, i, e->v.Name.id); } return new_seq; } /* Constructs a CmpopExprPair */ CmpopExprPair * _PyPegen_cmpop_expr_pair(Parser *p, cmpop_ty cmpop, expr_ty expr) { assert(expr != NULL); CmpopExprPair *a = _PyArena_Malloc(p->arena, sizeof(CmpopExprPair)); if (!a) { return NULL; } a->cmpop = cmpop; a->expr = expr; return a; } asdl_int_seq * _PyPegen_get_cmpops(Parser *p, asdl_seq *seq) { Py_ssize_t len = asdl_seq_LEN(seq); assert(len > 0); asdl_int_seq *new_seq = _Py_asdl_int_seq_new(len, p->arena); if (!new_seq) { return NULL; } for (Py_ssize_t i = 0; i < len; i++) { CmpopExprPair *pair = asdl_seq_GET_UNTYPED(seq, i); asdl_seq_SET(new_seq, i, pair->cmpop); } return new_seq; } asdl_expr_seq * _PyPegen_get_exprs(Parser *p, asdl_seq *seq) { Py_ssize_t len = asdl_seq_LEN(seq); assert(len > 0); asdl_expr_seq *new_seq = _Py_asdl_expr_seq_new(len, p->arena); if (!new_seq) { return NULL; } for (Py_ssize_t i = 0; i < len; i++) { CmpopExprPair *pair = asdl_seq_GET_UNTYPED(seq, i); asdl_seq_SET(new_seq, i, pair->expr); } return new_seq; } /* Creates an asdl_seq* where all the elements have been changed to have ctx as context */ static asdl_expr_seq * _set_seq_context(Parser *p, asdl_expr_seq *seq, expr_context_ty ctx) { Py_ssize_t len = asdl_seq_LEN(seq); if (len == 0) { return NULL; } asdl_expr_seq *new_seq = _Py_asdl_expr_seq_new(len, p->arena); if (!new_seq) { return NULL; } for (Py_ssize_t i = 0; i < len; i++) { expr_ty e = asdl_seq_GET(seq, i); asdl_seq_SET(new_seq, i, _PyPegen_set_expr_context(p, e, ctx)); } return new_seq; } static expr_ty _set_name_context(Parser *p, expr_ty e, expr_context_ty ctx) { return _PyAST_Name(e->v.Name.id, ctx, EXTRA_EXPR(e, e)); } static expr_ty _set_tuple_context(Parser *p, expr_ty e, expr_context_ty ctx) { return _PyAST_Tuple( _set_seq_context(p, e->v.Tuple.elts, ctx), ctx, EXTRA_EXPR(e, e)); } static expr_ty _set_list_context(Parser *p, expr_ty e, expr_context_ty ctx) { return _PyAST_List( _set_seq_context(p, e->v.List.elts, ctx), ctx, EXTRA_EXPR(e, e)); } static expr_ty _set_subscript_context(Parser *p, expr_ty e, expr_context_ty ctx) { return _PyAST_Subscript(e->v.Subscript.value, e->v.Subscript.slice, ctx, EXTRA_EXPR(e, e)); } static expr_ty _set_attribute_context(Parser *p, expr_ty e, expr_context_ty ctx) { return _PyAST_Attribute(e->v.Attribute.value, e->v.Attribute.attr, ctx, EXTRA_EXPR(e, e)); } static expr_ty _set_starred_context(Parser *p, expr_ty e, expr_context_ty ctx) { return _PyAST_Starred(_PyPegen_set_expr_context(p, e->v.Starred.value, ctx), ctx, EXTRA_EXPR(e, e)); } /* Creates an `expr_ty` equivalent to `expr` but with `ctx` as context */ expr_ty _PyPegen_set_expr_context(Parser *p, expr_ty expr, expr_context_ty ctx) { assert(expr != NULL); expr_ty new = NULL; switch (expr->kind) { case Name_kind: new = _set_name_context(p, expr, ctx); break; case Tuple_kind: new = _set_tuple_context(p, expr, ctx); break; case List_kind: new = _set_list_context(p, expr, ctx); break; case Subscript_kind: new = _set_subscript_context(p, expr, ctx); break; case Attribute_kind: new = _set_attribute_context(p, expr, ctx); break; case Starred_kind: new = _set_starred_context(p, expr, ctx); break; default: new = expr; } return new; } /* Constructs a KeyValuePair that is used when parsing a dict's key value pairs */ KeyValuePair * _PyPegen_key_value_pair(Parser *p, expr_ty key, expr_ty value) { KeyValuePair *a = _PyArena_Malloc(p->arena, sizeof(KeyValuePair)); if (!a) { return NULL; } a->key = key; a->value = value; return a; } /* Extracts all keys from an asdl_seq* of KeyValuePair*'s */ asdl_expr_seq * _PyPegen_get_keys(Parser *p, asdl_seq *seq) { Py_ssize_t len = asdl_seq_LEN(seq); asdl_expr_seq *new_seq = _Py_asdl_expr_seq_new(len, p->arena); if (!new_seq) { return NULL; } for (Py_ssize_t i = 0; i < len; i++) { KeyValuePair *pair = asdl_seq_GET_UNTYPED(seq, i); asdl_seq_SET(new_seq, i, pair->key); } return new_seq; } /* Extracts all values from an asdl_seq* of KeyValuePair*'s */ asdl_expr_seq * _PyPegen_get_values(Parser *p, asdl_seq *seq) { Py_ssize_t len = asdl_seq_LEN(seq); asdl_expr_seq *new_seq = _Py_asdl_expr_seq_new(len, p->arena); if (!new_seq) { return NULL; } for (Py_ssize_t i = 0; i < len; i++) { KeyValuePair *pair = asdl_seq_GET_UNTYPED(seq, i); asdl_seq_SET(new_seq, i, pair->value); } return new_seq; } /* Constructs a KeyPatternPair that is used when parsing mapping & class patterns */ KeyPatternPair * _PyPegen_key_pattern_pair(Parser *p, expr_ty key, pattern_ty pattern) { KeyPatternPair *a = _PyArena_Malloc(p->arena, sizeof(KeyPatternPair)); if (!a) { return NULL; } a->key = key; a->pattern = pattern; return a; } /* Extracts all keys from an asdl_seq* of KeyPatternPair*'s */ asdl_expr_seq * _PyPegen_get_pattern_keys(Parser *p, asdl_seq *seq) { Py_ssize_t len = asdl_seq_LEN(seq); asdl_expr_seq *new_seq = _Py_asdl_expr_seq_new(len, p->arena); if (!new_seq) { return NULL; } for (Py_ssize_t i = 0; i < len; i++) { KeyPatternPair *pair = asdl_seq_GET_UNTYPED(seq, i); asdl_seq_SET(new_seq, i, pair->key); } return new_seq; } /* Extracts all patterns from an asdl_seq* of KeyPatternPair*'s */ asdl_pattern_seq * _PyPegen_get_patterns(Parser *p, asdl_seq *seq) { Py_ssize_t len = asdl_seq_LEN(seq); asdl_pattern_seq *new_seq = _Py_asdl_pattern_seq_new(len, p->arena); if (!new_seq) { return NULL; } for (Py_ssize_t i = 0; i < len; i++) { KeyPatternPair *pair = asdl_seq_GET_UNTYPED(seq, i); asdl_seq_SET(new_seq, i, pair->pattern); } return new_seq; } /* Constructs a NameDefaultPair */ NameDefaultPair * _PyPegen_name_default_pair(Parser *p, arg_ty arg, expr_ty value, Token *tc) { NameDefaultPair *a = _PyArena_Malloc(p->arena, sizeof(NameDefaultPair)); if (!a) { return NULL; } a->arg = _PyPegen_add_type_comment_to_arg(p, arg, tc); a->value = value; return a; } /* Constructs a SlashWithDefault */ SlashWithDefault * _PyPegen_slash_with_default(Parser *p, asdl_arg_seq *plain_names, asdl_seq *names_with_defaults) { SlashWithDefault *a = _PyArena_Malloc(p->arena, sizeof(SlashWithDefault)); if (!a) { return NULL; } a->plain_names = plain_names; a->names_with_defaults = names_with_defaults; return a; } /* Constructs a StarEtc */ StarEtc * _PyPegen_star_etc(Parser *p, arg_ty vararg, asdl_seq *kwonlyargs, arg_ty kwarg) { StarEtc *a = _PyArena_Malloc(p->arena, sizeof(StarEtc)); if (!a) { return NULL; } a->vararg = vararg; a->kwonlyargs = kwonlyargs; a->kwarg = kwarg; return a; } asdl_seq * _PyPegen_join_sequences(Parser *p, asdl_seq *a, asdl_seq *b) { Py_ssize_t first_len = asdl_seq_LEN(a); Py_ssize_t second_len = asdl_seq_LEN(b); asdl_seq *new_seq = (asdl_seq*)_Py_asdl_generic_seq_new(first_len + second_len, p->arena); if (!new_seq) { return NULL; } int k = 0; for (Py_ssize_t i = 0; i < first_len; i++) { asdl_seq_SET_UNTYPED(new_seq, k++, asdl_seq_GET_UNTYPED(a, i)); } for (Py_ssize_t i = 0; i < second_len; i++) { asdl_seq_SET_UNTYPED(new_seq, k++, asdl_seq_GET_UNTYPED(b, i)); } return new_seq; } static asdl_arg_seq* _get_names(Parser *p, asdl_seq *names_with_defaults) { Py_ssize_t len = asdl_seq_LEN(names_with_defaults); asdl_arg_seq *seq = _Py_asdl_arg_seq_new(len, p->arena); if (!seq) { return NULL; } for (Py_ssize_t i = 0; i < len; i++) { NameDefaultPair *pair = asdl_seq_GET_UNTYPED(names_with_defaults, i); asdl_seq_SET(seq, i, pair->arg); } return seq; } static asdl_expr_seq * _get_defaults(Parser *p, asdl_seq *names_with_defaults) { Py_ssize_t len = asdl_seq_LEN(names_with_defaults); asdl_expr_seq *seq = _Py_asdl_expr_seq_new(len, p->arena); if (!seq) { return NULL; } for (Py_ssize_t i = 0; i < len; i++) { NameDefaultPair *pair = asdl_seq_GET_UNTYPED(names_with_defaults, i); asdl_seq_SET(seq, i, pair->value); } return seq; } static int _make_posonlyargs(Parser *p, asdl_arg_seq *slash_without_default, SlashWithDefault *slash_with_default, asdl_arg_seq **posonlyargs) { if (slash_without_default != NULL) { *posonlyargs = slash_without_default; } else if (slash_with_default != NULL) { asdl_arg_seq *slash_with_default_names = _get_names(p, slash_with_default->names_with_defaults); if (!slash_with_default_names) { return -1; } *posonlyargs = (asdl_arg_seq*)_PyPegen_join_sequences( p, (asdl_seq*)slash_with_default->plain_names, (asdl_seq*)slash_with_default_names); } else { *posonlyargs = _Py_asdl_arg_seq_new(0, p->arena); } return *posonlyargs == NULL ? -1 : 0; } static int _make_posargs(Parser *p, asdl_arg_seq *plain_names, asdl_seq *names_with_default, asdl_arg_seq **posargs) { if (names_with_default != NULL) { if (plain_names != NULL) { asdl_arg_seq *names_with_default_names = _get_names(p, names_with_default); if (!names_with_default_names) { return -1; } *posargs = (asdl_arg_seq*)_PyPegen_join_sequences( p,(asdl_seq*)plain_names, (asdl_seq*)names_with_default_names); } else { *posargs = _get_names(p, names_with_default); } } else { if (plain_names != NULL) { // With the current grammar, we never get here. // If that has changed, remove the assert, and test thoroughly. assert(0); *posargs = plain_names; } else { *posargs = _Py_asdl_arg_seq_new(0, p->arena); } } return *posargs == NULL ? -1 : 0; } static int _make_posdefaults(Parser *p, SlashWithDefault *slash_with_default, asdl_seq *names_with_default, asdl_expr_seq **posdefaults) { if (slash_with_default != NULL && names_with_default != NULL) { asdl_expr_seq *slash_with_default_values = _get_defaults(p, slash_with_default->names_with_defaults); if (!slash_with_default_values) { return -1; } asdl_expr_seq *names_with_default_values = _get_defaults(p, names_with_default); if (!names_with_default_values) { return -1; } *posdefaults = (asdl_expr_seq*)_PyPegen_join_sequences( p, (asdl_seq*)slash_with_default_values, (asdl_seq*)names_with_default_values); } else if (slash_with_default == NULL && names_with_default != NULL) { *posdefaults = _get_defaults(p, names_with_default); } else if (slash_with_default != NULL && names_with_default == NULL) { *posdefaults = _get_defaults(p, slash_with_default->names_with_defaults); } else { *posdefaults = _Py_asdl_expr_seq_new(0, p->arena); } return *posdefaults == NULL ? -1 : 0; } static int _make_kwargs(Parser *p, StarEtc *star_etc, asdl_arg_seq **kwonlyargs, asdl_expr_seq **kwdefaults) { if (star_etc != NULL && star_etc->kwonlyargs != NULL) { *kwonlyargs = _get_names(p, star_etc->kwonlyargs); } else { *kwonlyargs = _Py_asdl_arg_seq_new(0, p->arena); } if (*kwonlyargs == NULL) { return -1; } if (star_etc != NULL && star_etc->kwonlyargs != NULL) { *kwdefaults = _get_defaults(p, star_etc->kwonlyargs); } else { *kwdefaults = _Py_asdl_expr_seq_new(0, p->arena); } if (*kwdefaults == NULL) { return -1; } return 0; } /* Constructs an arguments_ty object out of all the parsed constructs in the parameters rule */ arguments_ty _PyPegen_make_arguments(Parser *p, asdl_arg_seq *slash_without_default, SlashWithDefault *slash_with_default, asdl_arg_seq *plain_names, asdl_seq *names_with_default, StarEtc *star_etc) { asdl_arg_seq *posonlyargs; if (_make_posonlyargs(p, slash_without_default, slash_with_default, &posonlyargs) == -1) { return NULL; } asdl_arg_seq *posargs; if (_make_posargs(p, plain_names, names_with_default, &posargs) == -1) { return NULL; } asdl_expr_seq *posdefaults; if (_make_posdefaults(p,slash_with_default, names_with_default, &posdefaults) == -1) { return NULL; } arg_ty vararg = NULL; if (star_etc != NULL && star_etc->vararg != NULL) { vararg = star_etc->vararg; } asdl_arg_seq *kwonlyargs; asdl_expr_seq *kwdefaults; if (_make_kwargs(p, star_etc, &kwonlyargs, &kwdefaults) == -1) { return NULL; } arg_ty kwarg = NULL; if (star_etc != NULL && star_etc->kwarg != NULL) { kwarg = star_etc->kwarg; } return _PyAST_arguments(posonlyargs, posargs, vararg, kwonlyargs, kwdefaults, kwarg, posdefaults, p->arena); } /* Constructs an empty arguments_ty object, that gets used when a function accepts no * arguments. */ arguments_ty _PyPegen_empty_arguments(Parser *p) { asdl_arg_seq *posonlyargs = _Py_asdl_arg_seq_new(0, p->arena); if (!posonlyargs) { return NULL; } asdl_arg_seq *posargs = _Py_asdl_arg_seq_new(0, p->arena); if (!posargs) { return NULL; } asdl_expr_seq *posdefaults = _Py_asdl_expr_seq_new(0, p->arena); if (!posdefaults) { return NULL; } asdl_arg_seq *kwonlyargs = _Py_asdl_arg_seq_new(0, p->arena); if (!kwonlyargs) { return NULL; } asdl_expr_seq *kwdefaults = _Py_asdl_expr_seq_new(0, p->arena); if (!kwdefaults) { return NULL; } return _PyAST_arguments(posonlyargs, posargs, NULL, kwonlyargs, kwdefaults, NULL, posdefaults, p->arena); } /* Encapsulates the value of an operator_ty into an AugOperator struct */ AugOperator * _PyPegen_augoperator(Parser *p, operator_ty kind) { AugOperator *a = _PyArena_Malloc(p->arena, sizeof(AugOperator)); if (!a) { return NULL; } a->kind = kind; return a; } /* Construct a FunctionDef equivalent to function_def, but with decorators */ stmt_ty _PyPegen_function_def_decorators(Parser *p, asdl_expr_seq *decorators, stmt_ty function_def) { assert(function_def != NULL); if (function_def->kind == AsyncFunctionDef_kind) { return _PyAST_AsyncFunctionDef( function_def->v.AsyncFunctionDef.name, function_def->v.AsyncFunctionDef.args, function_def->v.AsyncFunctionDef.body, decorators, function_def->v.AsyncFunctionDef.returns, function_def->v.AsyncFunctionDef.type_comment, function_def->v.AsyncFunctionDef.type_params, function_def->lineno, function_def->col_offset, function_def->end_lineno, function_def->end_col_offset, p->arena); } return _PyAST_FunctionDef( function_def->v.FunctionDef.name, function_def->v.FunctionDef.args, function_def->v.FunctionDef.body, decorators, function_def->v.FunctionDef.returns, function_def->v.FunctionDef.type_comment, function_def->v.FunctionDef.type_params, function_def->lineno, function_def->col_offset, function_def->end_lineno, function_def->end_col_offset, p->arena); } /* Construct a ClassDef equivalent to class_def, but with decorators */ stmt_ty _PyPegen_class_def_decorators(Parser *p, asdl_expr_seq *decorators, stmt_ty class_def) { assert(class_def != NULL); return _PyAST_ClassDef( class_def->v.ClassDef.name, class_def->v.ClassDef.bases, class_def->v.ClassDef.keywords, class_def->v.ClassDef.body, decorators, class_def->v.ClassDef.type_params, class_def->lineno, class_def->col_offset, class_def->end_lineno, class_def->end_col_offset, p->arena); } /* Construct a KeywordOrStarred */ KeywordOrStarred * _PyPegen_keyword_or_starred(Parser *p, void *element, int is_keyword) { KeywordOrStarred *a = _PyArena_Malloc(p->arena, sizeof(KeywordOrStarred)); if (!a) { return NULL; } a->element = element; a->is_keyword = is_keyword; return a; } /* Get the number of starred expressions in an asdl_seq* of KeywordOrStarred*s */ static int _seq_number_of_starred_exprs(asdl_seq *seq) { int n = 0; for (Py_ssize_t i = 0, l = asdl_seq_LEN(seq); i < l; i++) { KeywordOrStarred *k = asdl_seq_GET_UNTYPED(seq, i); if (!k->is_keyword) { n++; } } return n; } /* Extract the starred expressions of an asdl_seq* of KeywordOrStarred*s */ asdl_expr_seq * _PyPegen_seq_extract_starred_exprs(Parser *p, asdl_seq *kwargs) { int new_len = _seq_number_of_starred_exprs(kwargs); if (new_len == 0) { return NULL; } asdl_expr_seq *new_seq = _Py_asdl_expr_seq_new(new_len, p->arena); if (!new_seq) { return NULL; } int idx = 0; for (Py_ssize_t i = 0, len = asdl_seq_LEN(kwargs); i < len; i++) { KeywordOrStarred *k = asdl_seq_GET_UNTYPED(kwargs, i); if (!k->is_keyword) { asdl_seq_SET(new_seq, idx++, k->element); } } return new_seq; } /* Return a new asdl_seq* with only the keywords in kwargs */ asdl_keyword_seq* _PyPegen_seq_delete_starred_exprs(Parser *p, asdl_seq *kwargs) { Py_ssize_t len = asdl_seq_LEN(kwargs); Py_ssize_t new_len = len - _seq_number_of_starred_exprs(kwargs); if (new_len == 0) { return NULL; } asdl_keyword_seq *new_seq = _Py_asdl_keyword_seq_new(new_len, p->arena); if (!new_seq) { return NULL; } int idx = 0; for (Py_ssize_t i = 0; i < len; i++) { KeywordOrStarred *k = asdl_seq_GET_UNTYPED(kwargs, i); if (k->is_keyword) { asdl_seq_SET(new_seq, idx++, k->element); } } return new_seq; } expr_ty _PyPegen_ensure_imaginary(Parser *p, expr_ty exp) { if (exp->kind != Constant_kind || !PyComplex_CheckExact(exp->v.Constant.value)) { RAISE_SYNTAX_ERROR_KNOWN_LOCATION(exp, "imaginary number required in complex literal"); return NULL; } return exp; } expr_ty _PyPegen_ensure_real(Parser *p, expr_ty exp) { if (exp->kind != Constant_kind || PyComplex_CheckExact(exp->v.Constant.value)) { RAISE_SYNTAX_ERROR_KNOWN_LOCATION(exp, "real number required in complex literal"); return NULL; } return exp; } mod_ty _PyPegen_make_module(Parser *p, asdl_stmt_seq *a) { asdl_type_ignore_seq *type_ignores = NULL; Py_ssize_t num = p->type_ignore_comments.num_items; if (num > 0) { // Turn the raw (comment, lineno) pairs into TypeIgnore objects in the arena type_ignores = _Py_asdl_type_ignore_seq_new(num, p->arena); if (type_ignores == NULL) { return NULL; } for (Py_ssize_t i = 0; i < num; i++) { PyObject *tag = _PyPegen_new_type_comment(p, p->type_ignore_comments.items[i].comment); if (tag == NULL) { return NULL; } type_ignore_ty ti = _PyAST_TypeIgnore(p->type_ignore_comments.items[i].lineno, tag, p->arena); if (ti == NULL) { return NULL; } asdl_seq_SET(type_ignores, i, ti); } } return _PyAST_Module(a, type_ignores, p->arena); } PyObject * _PyPegen_new_type_comment(Parser *p, const char *s) { PyObject *res = PyUnicode_DecodeUTF8(s, strlen(s), NULL); if (res == NULL) { return NULL; } if (_PyArena_AddPyObject(p->arena, res) < 0) { Py_DECREF(res); return NULL; } return res; } arg_ty _PyPegen_add_type_comment_to_arg(Parser *p, arg_ty a, Token *tc) { if (tc == NULL) { return a; } const char *bytes = PyBytes_AsString(tc->bytes); if (bytes == NULL) { return NULL; } PyObject *tco = _PyPegen_new_type_comment(p, bytes); if (tco == NULL) { return NULL; } return _PyAST_arg(a->arg, a->annotation, tco, a->lineno, a->col_offset, a->end_lineno, a->end_col_offset, p->arena); } /* Checks if the NOTEQUAL token is valid given the current parser flags 0 indicates success and nonzero indicates failure (an exception may be set) */ int _PyPegen_check_barry_as_flufl(Parser *p, Token* t) { assert(t->bytes != NULL); assert(t->type == NOTEQUAL); const char* tok_str = PyBytes_AS_STRING(t->bytes); if (p->flags & PyPARSE_BARRY_AS_BDFL && strcmp(tok_str, "<>") != 0) { RAISE_SYNTAX_ERROR("with Barry as BDFL, use '<>' instead of '!='"); return -1; } if (!(p->flags & PyPARSE_BARRY_AS_BDFL)) { return strcmp(tok_str, "!="); } return 0; } int _PyPegen_check_legacy_stmt(Parser *p, expr_ty name) { if (name->kind != Name_kind) { return 0; } const char* candidates[2] = {"print", "exec"}; for (int i=0; i<2; i++) { if (PyUnicode_CompareWithASCIIString(name->v.Name.id, candidates[i]) == 0) { return 1; } } return 0; } static ResultTokenWithMetadata * result_token_with_metadata(Parser *p, void *result, PyObject *metadata) { ResultTokenWithMetadata *res = _PyArena_Malloc(p->arena, sizeof(ResultTokenWithMetadata)); if (res == NULL) { return NULL; } res->metadata = metadata; res->result = result; return res; } ResultTokenWithMetadata * _PyPegen_check_fstring_conversion(Parser *p, Token* conv_token, expr_ty conv) { if (conv_token->lineno != conv->lineno || conv_token->end_col_offset != conv->col_offset) { return RAISE_SYNTAX_ERROR_KNOWN_RANGE( conv_token, conv, "f-string: conversion type must come right after the exclamanation mark" ); } return result_token_with_metadata(p, conv, conv_token->metadata); } ResultTokenWithMetadata * _PyPegen_setup_full_format_spec(Parser *p, Token *colon, asdl_expr_seq *spec, int lineno, int col_offset, int end_lineno, int end_col_offset, PyArena *arena) { if (!spec) { return NULL; } // This is needed to keep compatibility with 3.11, where an empty format // spec is parsed as an *empty* JoinedStr node, instead of having an empty // constant in it. Py_ssize_t n_items = asdl_seq_LEN(spec); Py_ssize_t non_empty_count = 0; for (Py_ssize_t i = 0; i < n_items; i++) { expr_ty item = asdl_seq_GET(spec, i); non_empty_count += !(item->kind == Constant_kind && PyUnicode_CheckExact(item->v.Constant.value) && PyUnicode_GET_LENGTH(item->v.Constant.value) == 0); } if (non_empty_count != n_items) { asdl_expr_seq *resized_spec = _Py_asdl_expr_seq_new(non_empty_count, p->arena); if (resized_spec == NULL) { return NULL; } Py_ssize_t j = 0; for (Py_ssize_t i = 0; i < n_items; i++) { expr_ty item = asdl_seq_GET(spec, i); if (item->kind == Constant_kind && PyUnicode_CheckExact(item->v.Constant.value) && PyUnicode_GET_LENGTH(item->v.Constant.value) == 0) { continue; } asdl_seq_SET(resized_spec, j++, item); } assert(j == non_empty_count); spec = resized_spec; } expr_ty res = _PyAST_JoinedStr(spec, lineno, col_offset, end_lineno, end_col_offset, p->arena); if (!res) { return NULL; } return result_token_with_metadata(p, res, colon->metadata); } const char * _PyPegen_get_expr_name(expr_ty e) { assert(e != NULL); switch (e->kind) { case Attribute_kind: return "attribute"; case Subscript_kind: return "subscript"; case Starred_kind: return "starred"; case Name_kind: return "name"; case List_kind: return "list"; case Tuple_kind: return "tuple"; case Lambda_kind: return "lambda"; case Call_kind: return "function call"; case BoolOp_kind: case BinOp_kind: case UnaryOp_kind: return "expression"; case GeneratorExp_kind: return "generator expression"; case Yield_kind: case YieldFrom_kind: return "yield expression"; case Await_kind: return "await expression"; case ListComp_kind: return "list comprehension"; case SetComp_kind: return "set comprehension"; case DictComp_kind: return "dict comprehension"; case Dict_kind: return "dict literal"; case Set_kind: return "set display"; case JoinedStr_kind: case FormattedValue_kind: return "f-string expression"; case Constant_kind: { PyObject *value = e->v.Constant.value; if (value == Py_None) { return "None"; } if (value == Py_False) { return "False"; } if (value == Py_True) { return "True"; } if (value == Py_Ellipsis) { return "ellipsis"; } return "literal"; } case Compare_kind: return "comparison"; case IfExp_kind: return "conditional expression"; case NamedExpr_kind: return "named expression"; default: PyErr_Format(PyExc_SystemError, "unexpected expression in assignment %d (line %d)", e->kind, e->lineno); return NULL; } } expr_ty _PyPegen_get_last_comprehension_item(comprehension_ty comprehension) { if (comprehension->ifs == NULL || asdl_seq_LEN(comprehension->ifs) == 0) { return comprehension->iter; } return PyPegen_last_item(comprehension->ifs, expr_ty); } expr_ty _PyPegen_collect_call_seqs(Parser *p, asdl_expr_seq *a, asdl_seq *b, int lineno, int col_offset, int end_lineno, int end_col_offset, PyArena *arena) { Py_ssize_t args_len = asdl_seq_LEN(a); Py_ssize_t total_len = args_len; if (b == NULL) { return _PyAST_Call(_PyPegen_dummy_name(p), a, NULL, lineno, col_offset, end_lineno, end_col_offset, arena); } asdl_expr_seq *starreds = _PyPegen_seq_extract_starred_exprs(p, b); asdl_keyword_seq *keywords = _PyPegen_seq_delete_starred_exprs(p, b); if (starreds) { total_len += asdl_seq_LEN(starreds); } asdl_expr_seq *args = _Py_asdl_expr_seq_new(total_len, arena); Py_ssize_t i = 0; for (i = 0; i < args_len; i++) { asdl_seq_SET(args, i, asdl_seq_GET(a, i)); } for (; i < total_len; i++) { asdl_seq_SET(args, i, asdl_seq_GET(starreds, i - args_len)); } return _PyAST_Call(_PyPegen_dummy_name(p), args, keywords, lineno, col_offset, end_lineno, end_col_offset, arena); } // AST Error reporting helpers expr_ty _PyPegen_get_invalid_target(expr_ty e, TARGETS_TYPE targets_type) { if (e == NULL) { return NULL; } #define VISIT_CONTAINER(CONTAINER, TYPE) do { \ Py_ssize_t len = asdl_seq_LEN((CONTAINER)->v.TYPE.elts);\ for (Py_ssize_t i = 0; i < len; i++) {\ expr_ty other = asdl_seq_GET((CONTAINER)->v.TYPE.elts, i);\ expr_ty child = _PyPegen_get_invalid_target(other, targets_type);\ if (child != NULL) {\ return child;\ }\ }\ } while (0) // We only need to visit List and Tuple nodes recursively as those // are the only ones that can contain valid names in targets when // they are parsed as expressions. Any other kind of expression // that is a container (like Sets or Dicts) is directly invalid and // we don't need to visit it recursively. switch (e->kind) { case List_kind: VISIT_CONTAINER(e, List); return NULL; case Tuple_kind: VISIT_CONTAINER(e, Tuple); return NULL; case Starred_kind: if (targets_type == DEL_TARGETS) { return e; } return _PyPegen_get_invalid_target(e->v.Starred.value, targets_type); case Compare_kind: // This is needed, because the `a in b` in `for a in b` gets parsed // as a comparison, and so we need to search the left side of the comparison // for invalid targets. if (targets_type == FOR_TARGETS) { cmpop_ty cmpop = (cmpop_ty) asdl_seq_GET(e->v.Compare.ops, 0); if (cmpop == In) { return _PyPegen_get_invalid_target(e->v.Compare.left, targets_type); } return NULL; } return e; case Name_kind: case Subscript_kind: case Attribute_kind: return NULL; default: return e; } } void *_PyPegen_arguments_parsing_error(Parser *p, expr_ty e) { int kwarg_unpacking = 0; for (Py_ssize_t i = 0, l = asdl_seq_LEN(e->v.Call.keywords); i < l; i++) { keyword_ty keyword = asdl_seq_GET(e->v.Call.keywords, i); if (!keyword->arg) { kwarg_unpacking = 1; } } const char *msg = NULL; if (kwarg_unpacking) { msg = "positional argument follows keyword argument unpacking"; } else { msg = "positional argument follows keyword argument"; } return RAISE_SYNTAX_ERROR(msg); } void * _PyPegen_nonparen_genexp_in_call(Parser *p, expr_ty args, asdl_comprehension_seq *comprehensions) { /* The rule that calls this function is 'args for_if_clauses'. For the input f(L, x for x in y), L and x are in args and the for is parsed as a for_if_clause. We have to check if len <= 1, so that input like dict((a, b) for a, b in x) gets successfully parsed and then we pass the last argument (x in the above example) as the location of the error */ Py_ssize_t len = asdl_seq_LEN(args->v.Call.args); if (len <= 1) { return NULL; } comprehension_ty last_comprehension = PyPegen_last_item(comprehensions, comprehension_ty); return RAISE_SYNTAX_ERROR_KNOWN_RANGE( (expr_ty) asdl_seq_GET(args->v.Call.args, len - 1), _PyPegen_get_last_comprehension_item(last_comprehension), "Generator expression must be parenthesized" ); } // Fstring stuff static expr_ty _PyPegen_decode_fstring_part(Parser* p, int is_raw, expr_ty constant, Token* token) { assert(PyUnicode_CheckExact(constant->v.Constant.value)); const char* bstr = PyUnicode_AsUTF8(constant->v.Constant.value); if (bstr == NULL) { return NULL; } size_t len; if (strcmp(bstr, "{{") == 0 || strcmp(bstr, "}}") == 0) { len = 1; } else { len = strlen(bstr); } is_raw = is_raw || strchr(bstr, '\\') == NULL; PyObject *str = _PyPegen_decode_string(p, is_raw, bstr, len, token); if (str == NULL) { _Pypegen_raise_decode_error(p); return NULL; } if (_PyArena_AddPyObject(p->arena, str) < 0) { Py_DECREF(str); return NULL; } return _PyAST_Constant(str, NULL, constant->lineno, constant->col_offset, constant->end_lineno, constant->end_col_offset, p->arena); } static asdl_expr_seq * unpack_top_level_joined_strs(Parser *p, asdl_expr_seq *raw_expressions) { /* The parser might put multiple f-string values into an individual * JoinedStr node at the top level due to stuff like f-string debugging * expressions. This function flattens those and promotes them to the * upper level. Only simplifies AST, but the compiler already takes care * of the regular output, so this is not necessary if you are not going * to expose the output AST to Python level. */ Py_ssize_t i, req_size, raw_size; req_size = raw_size = asdl_seq_LEN(raw_expressions); expr_ty expr; for (i = 0; i < raw_size; i++) { expr = asdl_seq_GET(raw_expressions, i); if (expr->kind == JoinedStr_kind) { req_size += asdl_seq_LEN(expr->v.JoinedStr.values) - 1; } } asdl_expr_seq *expressions = _Py_asdl_expr_seq_new(req_size, p->arena); Py_ssize_t raw_index, req_index = 0; for (raw_index = 0; raw_index < raw_size; raw_index++) { expr = asdl_seq_GET(raw_expressions, raw_index); if (expr->kind == JoinedStr_kind) { asdl_expr_seq *values = expr->v.JoinedStr.values; for (Py_ssize_t n = 0; n < asdl_seq_LEN(values); n++) { asdl_seq_SET(expressions, req_index, asdl_seq_GET(values, n)); req_index++; } } else { asdl_seq_SET(expressions, req_index, expr); req_index++; } } return expressions; } expr_ty _PyPegen_joined_str(Parser *p, Token* a, asdl_expr_seq* raw_expressions, Token*b) { asdl_expr_seq *expr = unpack_top_level_joined_strs(p, raw_expressions); Py_ssize_t n_items = asdl_seq_LEN(expr); const char* quote_str = PyBytes_AsString(a->bytes); if (quote_str == NULL) { return NULL; } int is_raw = strpbrk(quote_str, "rR") != NULL; asdl_expr_seq *seq = _Py_asdl_expr_seq_new(n_items, p->arena); if (seq == NULL) { return NULL; } Py_ssize_t index = 0; for (Py_ssize_t i = 0; i < n_items; i++) { expr_ty item = asdl_seq_GET(expr, i); if (item->kind == Constant_kind) { item = _PyPegen_decode_fstring_part(p, is_raw, item, b); if (item == NULL) { return NULL; } /* Tokenizer emits string parts even when the underlying string might become an empty value (e.g. FSTRING_MIDDLE with the value \\n) so we need to check for them and simplify it here. */ if (PyUnicode_CheckExact(item->v.Constant.value) && PyUnicode_GET_LENGTH(item->v.Constant.value) == 0) { continue; } } asdl_seq_SET(seq, index++, item); } asdl_expr_seq *resized_exprs; if (index != n_items) { resized_exprs = _Py_asdl_expr_seq_new(index, p->arena); if (resized_exprs == NULL) { return NULL; } for (Py_ssize_t i = 0; i < index; i++) { asdl_seq_SET(resized_exprs, i, asdl_seq_GET(seq, i)); } } else { resized_exprs = seq; } return _PyAST_JoinedStr(resized_exprs, a->lineno, a->col_offset, b->end_lineno, b->end_col_offset, p->arena); } expr_ty _PyPegen_decoded_constant_from_token(Parser* p, Token* tok) { Py_ssize_t bsize; char* bstr; if (PyBytes_AsStringAndSize(tok->bytes, &bstr, &bsize) == -1) { return NULL; } PyObject* str = _PyPegen_decode_string(p, 0, bstr, bsize, tok); if (str == NULL) { return NULL; } if (_PyArena_AddPyObject(p->arena, str) < 0) { Py_DECREF(str); return NULL; } return _PyAST_Constant(str, NULL, tok->lineno, tok->col_offset, tok->end_lineno, tok->end_col_offset, p->arena); } expr_ty _PyPegen_constant_from_token(Parser* p, Token* tok) { char* bstr = PyBytes_AsString(tok->bytes); if (bstr == NULL) { return NULL; } PyObject* str = PyUnicode_FromString(bstr); if (str == NULL) { return NULL; } if (_PyArena_AddPyObject(p->arena, str) < 0) { Py_DECREF(str); return NULL; } return _PyAST_Constant(str, NULL, tok->lineno, tok->col_offset, tok->end_lineno, tok->end_col_offset, p->arena); } expr_ty _PyPegen_constant_from_string(Parser* p, Token* tok) { char* the_str = PyBytes_AsString(tok->bytes); if (the_str == NULL) { return NULL; } PyObject *s = _PyPegen_parse_string(p, tok); if (s == NULL) { _Pypegen_raise_decode_error(p); return NULL; } if (_PyArena_AddPyObject(p->arena, s) < 0) { Py_DECREF(s); return NULL; } PyObject *kind = NULL; if (the_str && the_str[0] == 'u') { kind = _PyPegen_new_identifier(p, "u"); if (kind == NULL) { return NULL; } } return _PyAST_Constant(s, kind, tok->lineno, tok->col_offset, tok->end_lineno, tok->end_col_offset, p->arena); } expr_ty _PyPegen_formatted_value(Parser *p, expr_ty expression, Token *debug, ResultTokenWithMetadata *conversion, ResultTokenWithMetadata *format, Token *closing_brace, int lineno, int col_offset, int end_lineno, int end_col_offset, PyArena *arena) { int conversion_val = -1; if (conversion != NULL) { expr_ty conversion_expr = (expr_ty) conversion->result; assert(conversion_expr->kind == Name_kind); Py_UCS4 first = PyUnicode_READ_CHAR(conversion_expr->v.Name.id, 0); if (PyUnicode_GET_LENGTH(conversion_expr->v.Name.id) > 1 || !(first == 's' || first == 'r' || first == 'a')) { RAISE_SYNTAX_ERROR_KNOWN_LOCATION(conversion_expr, "f-string: invalid conversion character %R: expected 's', 'r', or 'a'", conversion_expr->v.Name.id); return NULL; } conversion_val = Py_SAFE_DOWNCAST(first, Py_UCS4, int); } else if (debug && !format) { /* If no conversion is specified, use !r for debug expressions */ conversion_val = (int)'r'; } expr_ty formatted_value = _PyAST_FormattedValue( expression, conversion_val, format ? (expr_ty) format->result : NULL, lineno, col_offset, end_lineno, end_col_offset, arena ); if (debug) { /* Find the non whitespace token after the "=" */ int debug_end_line, debug_end_offset; PyObject *debug_metadata; if (conversion) { debug_end_line = ((expr_ty) conversion->result)->lineno; debug_end_offset = ((expr_ty) conversion->result)->col_offset; debug_metadata = conversion->metadata; } else if (format) { debug_end_line = ((expr_ty) format->result)->lineno; debug_end_offset = ((expr_ty) format->result)->col_offset + 1; debug_metadata = format->metadata; } else { debug_end_line = end_lineno; debug_end_offset = end_col_offset; debug_metadata = closing_brace->metadata; } expr_ty debug_text = _PyAST_Constant(debug_metadata, NULL, lineno, col_offset + 1, debug_end_line, debug_end_offset - 1, p->arena); if (!debug_text) { return NULL; } asdl_expr_seq *values = _Py_asdl_expr_seq_new(2, arena); asdl_seq_SET(values, 0, debug_text); asdl_seq_SET(values, 1, formatted_value); return _PyAST_JoinedStr(values, lineno, col_offset, debug_end_line, debug_end_offset, p->arena); } else { return formatted_value; } } expr_ty _PyPegen_concatenate_strings(Parser *p, asdl_expr_seq *strings, int lineno, int col_offset, int end_lineno, int end_col_offset, PyArena *arena) { Py_ssize_t len = asdl_seq_LEN(strings); assert(len > 0); int f_string_found = 0; int unicode_string_found = 0; int bytes_found = 0; Py_ssize_t i = 0; Py_ssize_t n_flattened_elements = 0; for (i = 0; i < len; i++) { expr_ty elem = asdl_seq_GET(strings, i); if (elem->kind == Constant_kind) { if (PyBytes_CheckExact(elem->v.Constant.value)) { bytes_found = 1; } else { unicode_string_found = 1; } n_flattened_elements++; } else { n_flattened_elements += asdl_seq_LEN(elem->v.JoinedStr.values); f_string_found = 1; } } if ((unicode_string_found || f_string_found) && bytes_found) { RAISE_SYNTAX_ERROR("cannot mix bytes and nonbytes literals"); return NULL; } if (bytes_found) { PyObject* res = PyBytes_FromString(""); /* Bytes literals never get a kind, but just for consistency since they are represented as Constant nodes, we'll mirror the same behavior as unicode strings for determining the kind. */ PyObject* kind = asdl_seq_GET(strings, 0)->v.Constant.kind; for (i = 0; i < len; i++) { expr_ty elem = asdl_seq_GET(strings, i); PyBytes_Concat(&res, elem->v.Constant.value); } if (!res || _PyArena_AddPyObject(arena, res) < 0) { Py_XDECREF(res); return NULL; } return _PyAST_Constant(res, kind, lineno, col_offset, end_lineno, end_col_offset, p->arena); } if (!f_string_found && len == 1) { return asdl_seq_GET(strings, 0); } asdl_expr_seq* flattened = _Py_asdl_expr_seq_new(n_flattened_elements, p->arena); if (flattened == NULL) { return NULL; } /* build flattened list */ Py_ssize_t current_pos = 0; Py_ssize_t j = 0; for (i = 0; i < len; i++) { expr_ty elem = asdl_seq_GET(strings, i); if (elem->kind == Constant_kind) { asdl_seq_SET(flattened, current_pos++, elem); } else { for (j = 0; j < asdl_seq_LEN(elem->v.JoinedStr.values); j++) { expr_ty subvalue = asdl_seq_GET(elem->v.JoinedStr.values, j); if (subvalue == NULL) { return NULL; } asdl_seq_SET(flattened, current_pos++, subvalue); } } } /* calculate folded element count */ Py_ssize_t n_elements = 0; int prev_is_constant = 0; for (i = 0; i < n_flattened_elements; i++) { expr_ty elem = asdl_seq_GET(flattened, i); /* The concatenation of a FormattedValue and an empty Contant should lead to the FormattedValue itself. Thus, we will not take any empty constants into account, just as in `_PyPegen_joined_str` */ if (f_string_found && elem->kind == Constant_kind && PyUnicode_CheckExact(elem->v.Constant.value) && PyUnicode_GET_LENGTH(elem->v.Constant.value) == 0) continue; if (!prev_is_constant || elem->kind != Constant_kind) { n_elements++; } prev_is_constant = elem->kind == Constant_kind; } asdl_expr_seq* values = _Py_asdl_expr_seq_new(n_elements, p->arena); if (values == NULL) { return NULL; } /* build folded list */ _PyUnicodeWriter writer; current_pos = 0; for (i = 0; i < n_flattened_elements; i++) { expr_ty elem = asdl_seq_GET(flattened, i); /* if the current elem and the following are constants, fold them and all consequent constants */ if (elem->kind == Constant_kind) { if (i + 1 < n_flattened_elements && asdl_seq_GET(flattened, i + 1)->kind == Constant_kind) { expr_ty first_elem = elem; /* When a string is getting concatenated, the kind of the string is determined by the first string in the concatenation sequence. u"abc" "def" -> u"abcdef" "abc" u"abc" -> "abcabc" */ PyObject *kind = elem->v.Constant.kind; _PyUnicodeWriter_Init(&writer); expr_ty last_elem = elem; for (j = i; j < n_flattened_elements; j++) { expr_ty current_elem = asdl_seq_GET(flattened, j); if (current_elem->kind == Constant_kind) { if (_PyUnicodeWriter_WriteStr( &writer, current_elem->v.Constant.value)) { _PyUnicodeWriter_Dealloc(&writer); return NULL; } last_elem = current_elem; } else { break; } } i = j - 1; PyObject *concat_str = _PyUnicodeWriter_Finish(&writer); if (concat_str == NULL) { _PyUnicodeWriter_Dealloc(&writer); return NULL; } if (_PyArena_AddPyObject(p->arena, concat_str) < 0) { Py_DECREF(concat_str); return NULL; } elem = _PyAST_Constant(concat_str, kind, first_elem->lineno, first_elem->col_offset, last_elem->end_lineno, last_elem->end_col_offset, p->arena); if (elem == NULL) { return NULL; } } /* Drop all empty contanst strings */ if (f_string_found && PyUnicode_CheckExact(elem->v.Constant.value) && PyUnicode_GET_LENGTH(elem->v.Constant.value) == 0) { continue; } } asdl_seq_SET(values, current_pos++, elem); } if (!f_string_found) { assert(n_elements == 1); expr_ty elem = asdl_seq_GET(values, 0); assert(elem->kind == Constant_kind); return elem; } assert(current_pos == n_elements); return _PyAST_JoinedStr(values, lineno, col_offset, end_lineno, end_col_offset, p->arena); }