/**\file parse_tree.h Programmatic representation of fish code. */ #ifndef FISH_PARSE_PRODUCTIONS_H #define FISH_PARSE_PRODUCTIONS_H #include #include "config.h" #include "util.h" #include "common.h" #include "tokenizer.h" #include "parse_constants.h" #include #include class parse_node_t; class parse_node_tree_t; typedef size_t node_offset_t; #define NODE_OFFSET_INVALID (static_cast(-1)) struct parse_error_t { /** Text of the error */ wcstring text; /** Code for the error */ enum parse_error_code_t code; /** Offset and length of the token in the source code that triggered this error */ size_t source_start; size_t source_length; /** Return a string describing the error, suitable for presentation to the user. If skip_caret is false, the offending line with a caret is printed as well */ wcstring describe(const wcstring &src, bool skip_caret = false) const; }; typedef std::vector parse_error_list_t; /* Returns a description of a list of parse errors */ wcstring parse_errors_description(const parse_error_list_t &errors, const wcstring &src, const wchar_t *prefix = NULL); /** A struct representing the token type that we use internally */ struct parse_token_t { enum parse_token_type_t type; // The type of the token as represented by the parser enum parse_keyword_t keyword; // Any keyword represented by this token bool has_dash_prefix; // Hackish: whether the source contains a dash prefix bool is_help_argument; // Hackish: whether the source looks like '-h' or '--help' size_t source_start; size_t source_length; wcstring describe() const; wcstring user_presentable_description() const; }; enum { parse_flag_none = 0, /* Attempt to build a "parse tree" no matter what. This may result in a 'forest' of disconnected trees. This is intended to be used by syntax highlighting. */ parse_flag_continue_after_error = 1 << 0, /* Include comment tokens */ parse_flag_include_comments = 1 << 1, /* Indicate that the tokenizer should accept incomplete tokens */ parse_flag_accept_incomplete_tokens = 1 << 2, /* Indicate that the parser should not generate the terminate token, allowing an 'unfinished' tree where some nodes may have no productions. */ parse_flag_leave_unterminated = 1 << 3 }; typedef unsigned int parse_tree_flags_t; wcstring parse_dump_tree(const parse_node_tree_t &tree, const wcstring &src); wcstring token_type_description(parse_token_type_t type); wcstring keyword_description(parse_keyword_t type); /** Class for nodes of a parse tree */ class parse_node_t { public: /* Type of the node */ enum parse_token_type_t type; /* Start in the source code */ size_t source_start; /* Length of our range in the source code */ size_t source_length; /* Parent */ node_offset_t parent; /* Children */ node_offset_t child_start; uint8_t child_count; /* Which production was used */ uint8_t production_idx; /* Description */ wcstring describe(void) const; /* Constructor */ explicit parse_node_t(parse_token_type_t ty) : type(ty), source_start(-1), source_length(0), parent(NODE_OFFSET_INVALID), child_start(0), child_count(0), production_idx(-1) { } node_offset_t child_offset(node_offset_t which) const { PARSE_ASSERT(which < child_count); return child_start + which; } /* Indicate if this node has a range of source code associated with it */ bool has_source() const { return source_start != (size_t)(-1); } /* Gets source for the node, or the empty string if it has no source */ wcstring get_source(const wcstring &str) const { if (! has_source()) return wcstring(); else return wcstring(str, this->source_start, this->source_length); } /* Returns whether the given location is within the source range or at its end */ bool location_in_or_at_end_of_source_range(size_t loc) const { return has_source() && source_start <= loc && loc - source_start <= source_length; } }; /* The parse tree itself */ class parse_node_tree_t : public std::vector { public: /* Get the node corresponding to a child of the given node, or NULL if there is no such child. If expected_type is provided, assert that the node has that type. */ const parse_node_t *get_child(const parse_node_t &parent, node_offset_t which, parse_token_type_t expected_type = token_type_invalid) const; /* Find the first direct child of the given node of the given type. asserts on failure */ const parse_node_t &find_child(const parse_node_t &parent, parse_token_type_t type) const; /* Get the node corresponding to the parent of the given node, or NULL if there is no such child. If expected_type is provided, only returns the parent if it is of that type. Note the asymmetry: get_child asserts since the children are known, but get_parent does not, since the parent may not be known. */ const parse_node_t *get_parent(const parse_node_t &node, parse_token_type_t expected_type = token_type_invalid) const; /* Returns the first ancestor of the given type, or NULL. */ const parse_node_t *get_first_ancestor_of_type(const parse_node_t &node, parse_token_type_t desired_type) const; /* Find all the nodes of a given type underneath a given node, up to max_count of them */ typedef std::vector parse_node_list_t; parse_node_list_t find_nodes(const parse_node_t &parent, parse_token_type_t type, size_t max_count = (size_t)(-1)) const; /* Finds the last node of a given type underneath a given node, or NULL if it could not be found. If parent is NULL, this finds the last node in the tree of that type. */ const parse_node_t *find_last_node_of_type(parse_token_type_t type, const parse_node_t *parent = NULL) const; /* Finds a node containing the given source location. If 'parent' is not NULL, it must be an ancestor. */ const parse_node_t *find_node_matching_source_location(parse_token_type_t type, size_t source_loc, const parse_node_t *parent) const; /* Indicate if the given argument_list or arguments_or_redirections_list is a root list, or has a parent */ bool argument_list_is_root(const parse_node_t &node) const; /* Utilities */ /* Given a plain statement, get the decoration (from the parent node), or none if there is no decoration */ enum parse_statement_decoration_t decoration_for_plain_statement(const parse_node_t &node) const; /* Given a plain statement, get the command by reference (from the child node). Returns true if successful. Clears the command on failure. */ bool command_for_plain_statement(const parse_node_t &node, const wcstring &src, wcstring *out_cmd) const; /* Given a plain statement, return true if the statement is part of a pipeline. If include_first is set, the first command in a pipeline is considered part of it; otherwise only the second or additional commands are */ bool statement_is_in_pipeline(const parse_node_t &node, bool include_first) const; /* Given a redirection, get the redirection type (or TOK_NONE) and target (file path, or fd) */ enum token_type type_for_redirection(const parse_node_t &node, const wcstring &src, int *out_fd, wcstring *out_target) const; /* If the given node is a block statement, returns the header node (for_header, while_header, begin_header, or function_header). Otherwise returns NULL */ const parse_node_t *header_node_for_block_statement(const parse_node_t &node) const; /* Given a node list (e.g. of type symbol_job_list) and a node type (e.g. symbol_job), return the next element of the given type in that list, and the tail (by reference). Returns NULL if we've exhausted the list. */ const parse_node_t *next_node_in_node_list(const parse_node_t &node_list, parse_token_type_t item_type, const parse_node_t **list_tail) const; /* Given a job, return all of its statements. These are 'specific statements' (e.g. symbol_decorated_statement, not symbol_statement) */ parse_node_list_t specific_statements_for_job(const parse_node_t &job) const; }; /* The big entry point. Parse a string! */ bool parse_tree_from_string(const wcstring &str, parse_tree_flags_t flags, parse_node_tree_t *output, parse_error_list_t *errors); /* Fish grammar: # A job_list is a list of jobs, separated by semicolons or newlines job_list = | job job_list job_list # A job is a non-empty list of statements, separated by pipes. (Non-empty is useful for cases like if statements, where we require a command). To represent "non-empty", we require a statement, followed by a possibly empty job_continuation job = statement job_continuation job_continuation = | statement job_continuation # A statement is a normal command, or an if / while / and etc statement = boolean_statement | block_statement | if_statement | switch_statement | decorated_statement # A block is a conditional, loop, or begin/end if_statement = if_clause else_clause end_command arguments_or_redirections_list if_clause = job STATEMENT_TERMINATOR job_list else_clause = | else_continuation else_continuation = if_clause else_clause | STATEMENT_TERMINATOR job_list switch_statement = SWITCH STATEMENT_TERMINATOR case_item_list end_command arguments_or_redirections_list case_item_list = | case_item case_item_list | case_item_list case_item = CASE argument_list STATEMENT_TERMINATOR job_list block_statement = block_header job_list end_command arguments_or_redirections_list block_header = for_header | while_header | function_header | begin_header for_header = FOR var_name IN argument_list while_header = WHILE job begin_header = BEGIN # Functions take arguments, and require at least one (the name). No redirections allowed. function_header = FUNCTION argument argument_list # A boolean statement is AND or OR or NOT boolean_statement = AND statement | OR statement | NOT statement # A decorated_statement is a command with a list of arguments_or_redirections, possibly with "builtin" or "command" or "exec" decorated_statement = plain_statement | COMMAND plain_statement | BUILTIN plain_statement | EXEC plain_statement plain_statement = arguments_or_redirections_list optional_background argument_list = | argument argument_list arguments_or_redirections_list = | argument_or_redirection arguments_or_redirections_list argument_or_redirection = argument | redirection argument = redirection = terminator = | optional_background = | end_command = END */ #endif