ruby/prism/parser.h

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C

/**
* @file parser.h
*
* The parser used to parse Ruby source.
*/
#ifndef PRISM_PARSER_H
#define PRISM_PARSER_H
#include "prism/defines.h"
#include "prism/ast.h"
#include "prism/encoding.h"
#include "prism/options.h"
#include "prism/static_literals.h"
#include "prism/util/pm_constant_pool.h"
#include "prism/util/pm_list.h"
#include "prism/util/pm_newline_list.h"
#include "prism/util/pm_string.h"
#include <stdbool.h>
/**
* This enum provides various bits that represent different kinds of states that
* the lexer can track. This is used to determine which kind of token to return
* based on the context of the parser.
*/
typedef enum {
PM_LEX_STATE_BIT_BEG,
PM_LEX_STATE_BIT_END,
PM_LEX_STATE_BIT_ENDARG,
PM_LEX_STATE_BIT_ENDFN,
PM_LEX_STATE_BIT_ARG,
PM_LEX_STATE_BIT_CMDARG,
PM_LEX_STATE_BIT_MID,
PM_LEX_STATE_BIT_FNAME,
PM_LEX_STATE_BIT_DOT,
PM_LEX_STATE_BIT_CLASS,
PM_LEX_STATE_BIT_LABEL,
PM_LEX_STATE_BIT_LABELED,
PM_LEX_STATE_BIT_FITEM
} pm_lex_state_bit_t;
/**
* This enum combines the various bits from the above enum into individual
* values that represent the various states of the lexer.
*/
typedef enum {
PM_LEX_STATE_NONE = 0,
PM_LEX_STATE_BEG = (1 << PM_LEX_STATE_BIT_BEG),
PM_LEX_STATE_END = (1 << PM_LEX_STATE_BIT_END),
PM_LEX_STATE_ENDARG = (1 << PM_LEX_STATE_BIT_ENDARG),
PM_LEX_STATE_ENDFN = (1 << PM_LEX_STATE_BIT_ENDFN),
PM_LEX_STATE_ARG = (1 << PM_LEX_STATE_BIT_ARG),
PM_LEX_STATE_CMDARG = (1 << PM_LEX_STATE_BIT_CMDARG),
PM_LEX_STATE_MID = (1 << PM_LEX_STATE_BIT_MID),
PM_LEX_STATE_FNAME = (1 << PM_LEX_STATE_BIT_FNAME),
PM_LEX_STATE_DOT = (1 << PM_LEX_STATE_BIT_DOT),
PM_LEX_STATE_CLASS = (1 << PM_LEX_STATE_BIT_CLASS),
PM_LEX_STATE_LABEL = (1 << PM_LEX_STATE_BIT_LABEL),
PM_LEX_STATE_LABELED = (1 << PM_LEX_STATE_BIT_LABELED),
PM_LEX_STATE_FITEM = (1 << PM_LEX_STATE_BIT_FITEM),
PM_LEX_STATE_BEG_ANY = PM_LEX_STATE_BEG | PM_LEX_STATE_MID | PM_LEX_STATE_CLASS,
PM_LEX_STATE_ARG_ANY = PM_LEX_STATE_ARG | PM_LEX_STATE_CMDARG,
PM_LEX_STATE_END_ANY = PM_LEX_STATE_END | PM_LEX_STATE_ENDARG | PM_LEX_STATE_ENDFN
} pm_lex_state_t;
/**
* The type of quote that a heredoc uses.
*/
typedef enum {
PM_HEREDOC_QUOTE_NONE,
PM_HEREDOC_QUOTE_SINGLE = '\'',
PM_HEREDOC_QUOTE_DOUBLE = '"',
PM_HEREDOC_QUOTE_BACKTICK = '`',
} pm_heredoc_quote_t;
/**
* The type of indentation that a heredoc uses.
*/
typedef enum {
PM_HEREDOC_INDENT_NONE,
PM_HEREDOC_INDENT_DASH,
PM_HEREDOC_INDENT_TILDE,
} pm_heredoc_indent_t;
/**
* All of the information necessary to store to lexing a heredoc.
*/
typedef struct {
/** A pointer to the start of the heredoc identifier. */
const uint8_t *ident_start;
/** The length of the heredoc identifier. */
size_t ident_length;
/** The type of quote that the heredoc uses. */
pm_heredoc_quote_t quote;
/** The type of indentation that the heredoc uses. */
pm_heredoc_indent_t indent;
} pm_heredoc_lex_mode_t;
/**
* When lexing Ruby source, the lexer has a small amount of state to tell which
* kind of token it is currently lexing. For example, when we find the start of
* a string, the first token that we return is a TOKEN_STRING_BEGIN token. After
* that the lexer is now in the PM_LEX_STRING mode, and will return tokens that
* are found as part of a string.
*/
typedef struct pm_lex_mode {
/** The type of this lex mode. */
enum {
/** This state is used when any given token is being lexed. */
PM_LEX_DEFAULT,
/**
* This state is used when we're lexing as normal but inside an embedded
* expression of a string.
*/
PM_LEX_EMBEXPR,
/**
* This state is used when we're lexing a variable that is embedded
* directly inside of a string with the # shorthand.
*/
PM_LEX_EMBVAR,
/** This state is used when you are inside the content of a heredoc. */
PM_LEX_HEREDOC,
/**
* This state is used when we are lexing a list of tokens, as in a %w
* word list literal or a %i symbol list literal.
*/
PM_LEX_LIST,
/**
* This state is used when a regular expression has been begun and we
* are looking for the terminator.
*/
PM_LEX_REGEXP,
/**
* This state is used when we are lexing a string or a string-like
* token, as in string content with either quote or an xstring.
*/
PM_LEX_STRING
} mode;
/** The data associated with this type of lex mode. */
union {
struct {
/** This keeps track of the nesting level of the list. */
size_t nesting;
/** Whether or not interpolation is allowed in this list. */
bool interpolation;
/**
* When lexing a list, it takes into account balancing the
* terminator if the terminator is one of (), [], {}, or <>.
*/
uint8_t incrementor;
/** This is the terminator of the list literal. */
uint8_t terminator;
/**
* This is the character set that should be used to delimit the
* tokens within the list.
*/
uint8_t breakpoints[11];
} list;
struct {
/**
* This keeps track of the nesting level of the regular expression.
*/
size_t nesting;
/**
* When lexing a regular expression, it takes into account balancing
* the terminator if the terminator is one of (), [], {}, or <>.
*/
uint8_t incrementor;
/** This is the terminator of the regular expression. */
uint8_t terminator;
/**
* This is the character set that should be used to delimit the
* tokens within the regular expression.
*/
uint8_t breakpoints[7];
} regexp;
struct {
/** This keeps track of the nesting level of the string. */
size_t nesting;
/** Whether or not interpolation is allowed in this string. */
bool interpolation;
/**
* Whether or not at the end of the string we should allow a :,
* which would indicate this was a dynamic symbol instead of a
* string.
*/
bool label_allowed;
/**
* When lexing a string, it takes into account balancing the
* terminator if the terminator is one of (), [], {}, or <>.
*/
uint8_t incrementor;
/**
* This is the terminator of the string. It is typically either a
* single or double quote.
*/
uint8_t terminator;
/**
* This is the character set that should be used to delimit the
* tokens within the string.
*/
uint8_t breakpoints[7];
} string;
struct {
/**
* All of the data necessary to lex a heredoc.
*/
pm_heredoc_lex_mode_t base;
/**
* This is the pointer to the character where lexing should resume
* once the heredoc has been completely processed.
*/
const uint8_t *next_start;
/**
* This is used to track the amount of common whitespace on each
* line so that we know how much to dedent each line in the case of
* a tilde heredoc.
*/
size_t *common_whitespace;
/** True if the previous token ended with a line continuation. */
bool line_continuation;
} heredoc;
} as;
/** The previous lex state so that it knows how to pop. */
struct pm_lex_mode *prev;
} pm_lex_mode_t;
/**
* We pre-allocate a certain number of lex states in order to avoid having to
* call malloc too many times while parsing. You really shouldn't need more than
* this because you only really nest deeply when doing string interpolation.
*/
#define PM_LEX_STACK_SIZE 4
/**
* The parser used to parse Ruby source.
*/
typedef struct pm_parser pm_parser_t;
/**
* While parsing, we keep track of a stack of contexts. This is helpful for
* error recovery so that we can pop back to a previous context when we hit a
* token that is understood by a parent context but not by the current context.
*/
typedef enum {
/** a null context, used for returning a value from a function */
PM_CONTEXT_NONE = 0,
/** a begin statement */
PM_CONTEXT_BEGIN,
/** an ensure statement with an explicit begin */
PM_CONTEXT_BEGIN_ENSURE,
/** a rescue else statement with an explicit begin */
PM_CONTEXT_BEGIN_ELSE,
/** a rescue statement with an explicit begin */
PM_CONTEXT_BEGIN_RESCUE,
/** expressions in block arguments using braces */
PM_CONTEXT_BLOCK_BRACES,
/** expressions in block arguments using do..end */
PM_CONTEXT_BLOCK_KEYWORDS,
/** an ensure statement within a do..end block */
PM_CONTEXT_BLOCK_ENSURE,
/** a rescue else statement within a do..end block */
PM_CONTEXT_BLOCK_ELSE,
/** a rescue statement within a do..end block */
PM_CONTEXT_BLOCK_RESCUE,
/** a case when statements */
PM_CONTEXT_CASE_WHEN,
/** a case in statements */
PM_CONTEXT_CASE_IN,
/** a class declaration */
PM_CONTEXT_CLASS,
/** an ensure statement within a class statement */
PM_CONTEXT_CLASS_ENSURE,
/** a rescue else statement within a class statement */
PM_CONTEXT_CLASS_ELSE,
/** a rescue statement within a class statement */
PM_CONTEXT_CLASS_RESCUE,
/** a method definition */
PM_CONTEXT_DEF,
/** an ensure statement within a method definition */
PM_CONTEXT_DEF_ENSURE,
/** a rescue else statement within a method definition */
PM_CONTEXT_DEF_ELSE,
/** a rescue statement within a method definition */
PM_CONTEXT_DEF_RESCUE,
/** a method definition's parameters */
PM_CONTEXT_DEF_PARAMS,
/** a defined? expression */
PM_CONTEXT_DEFINED,
/** a method definition's default parameter */
PM_CONTEXT_DEFAULT_PARAMS,
/** an else clause */
PM_CONTEXT_ELSE,
/** an elsif clause */
PM_CONTEXT_ELSIF,
/** an interpolated expression */
PM_CONTEXT_EMBEXPR,
/** a for loop */
PM_CONTEXT_FOR,
/** a for loop's index */
PM_CONTEXT_FOR_INDEX,
/** an if statement */
PM_CONTEXT_IF,
/** a lambda expression with braces */
PM_CONTEXT_LAMBDA_BRACES,
/** a lambda expression with do..end */
PM_CONTEXT_LAMBDA_DO_END,
/** an ensure statement within a lambda expression */
PM_CONTEXT_LAMBDA_ENSURE,
/** a rescue else statement within a lambda expression */
PM_CONTEXT_LAMBDA_ELSE,
/** a rescue statement within a lambda expression */
PM_CONTEXT_LAMBDA_RESCUE,
/** the predicate clause of a loop statement */
PM_CONTEXT_LOOP_PREDICATE,
/** the top level context */
PM_CONTEXT_MAIN,
/** a module declaration */
PM_CONTEXT_MODULE,
/** an ensure statement within a module statement */
PM_CONTEXT_MODULE_ENSURE,
/** a rescue else statement within a module statement */
PM_CONTEXT_MODULE_ELSE,
/** a rescue statement within a module statement */
PM_CONTEXT_MODULE_RESCUE,
/** a multiple target expression */
PM_CONTEXT_MULTI_TARGET,
/** a parenthesized expression */
PM_CONTEXT_PARENS,
/** an END block */
PM_CONTEXT_POSTEXE,
/** a predicate inside an if/elsif/unless statement */
PM_CONTEXT_PREDICATE,
/** a BEGIN block */
PM_CONTEXT_PREEXE,
/** a modifier rescue clause */
PM_CONTEXT_RESCUE_MODIFIER,
/** a singleton class definition */
PM_CONTEXT_SCLASS,
/** an ensure statement with a singleton class */
PM_CONTEXT_SCLASS_ENSURE,
/** a rescue else statement with a singleton class */
PM_CONTEXT_SCLASS_ELSE,
/** a rescue statement with a singleton class */
PM_CONTEXT_SCLASS_RESCUE,
/** a ternary expression */
PM_CONTEXT_TERNARY,
/** an unless statement */
PM_CONTEXT_UNLESS,
/** an until statement */
PM_CONTEXT_UNTIL,
/** a while statement */
PM_CONTEXT_WHILE,
} pm_context_t;
/** This is a node in a linked list of contexts. */
typedef struct pm_context_node {
/** The context that this node represents. */
pm_context_t context;
/** A pointer to the previous context in the linked list. */
struct pm_context_node *prev;
} pm_context_node_t;
/** This is the type of a comment that we've found while parsing. */
typedef enum {
PM_COMMENT_INLINE,
PM_COMMENT_EMBDOC
} pm_comment_type_t;
/**
* This is a node in the linked list of comments that we've found while parsing.
*
* @extends pm_list_node_t
*/
typedef struct pm_comment {
/** The embedded base node. */
pm_list_node_t node;
/** The location of the comment in the source. */
pm_location_t location;
/** The type of comment that we've found. */
pm_comment_type_t type;
} pm_comment_t;
/**
* This is a node in the linked list of magic comments that we've found while
* parsing.
*
* @extends pm_list_node_t
*/
typedef struct {
/** The embedded base node. */
pm_list_node_t node;
/** A pointer to the start of the key in the source. */
const uint8_t *key_start;
/** A pointer to the start of the value in the source. */
const uint8_t *value_start;
/** The length of the key in the source. */
uint32_t key_length;
/** The length of the value in the source. */
uint32_t value_length;
} pm_magic_comment_t;
/**
* When the encoding that is being used to parse the source is changed by prism,
* we provide the ability here to call out to a user-defined function.
*/
typedef void (*pm_encoding_changed_callback_t)(pm_parser_t *parser);
/**
* When you are lexing through a file, the lexer needs all of the information
* that the parser additionally provides (for example, the local table). So if
* you want to properly lex Ruby, you need to actually lex it in the context of
* the parser. In order to provide this functionality, we optionally allow a
* struct to be attached to the parser that calls back out to a user-provided
* callback when each token is lexed.
*/
typedef struct {
/**
* This opaque pointer is used to provide whatever information the user
* deemed necessary to the callback. In our case we use it to pass the array
* that the tokens get appended into.
*/
void *data;
/**
* This is the callback that is called when a token is lexed. It is passed
* the opaque data pointer, the parser, and the token that was lexed.
*/
void (*callback)(void *data, pm_parser_t *parser, pm_token_t *token);
} pm_lex_callback_t;
/** The type of shareable constant value that can be set. */
typedef uint8_t pm_shareable_constant_value_t;
static const pm_shareable_constant_value_t PM_SCOPE_SHAREABLE_CONSTANT_NONE = 0x0;
static const pm_shareable_constant_value_t PM_SCOPE_SHAREABLE_CONSTANT_LITERAL = PM_SHAREABLE_CONSTANT_NODE_FLAGS_LITERAL;
static const pm_shareable_constant_value_t PM_SCOPE_SHAREABLE_CONSTANT_EXPERIMENTAL_EVERYTHING = PM_SHAREABLE_CONSTANT_NODE_FLAGS_EXPERIMENTAL_EVERYTHING;
static const pm_shareable_constant_value_t PM_SCOPE_SHAREABLE_CONSTANT_EXPERIMENTAL_COPY = PM_SHAREABLE_CONSTANT_NODE_FLAGS_EXPERIMENTAL_COPY;
/**
* This tracks an individual local variable in a certain lexical context, as
* well as the number of times is it read.
*/
typedef struct {
/** The name of the local variable. */
pm_constant_id_t name;
/** The location of the local variable in the source. */
pm_location_t location;
/** The index of the local variable in the local table. */
uint32_t index;
/** The number of times the local variable is read. */
uint32_t reads;
/** The hash of the local variable. */
uint32_t hash;
} pm_local_t;
/**
* This is a set of local variables in a certain lexical context (method, class,
* module, etc.). We need to track how many times these variables are read in
* order to warn if they only get written.
*/
typedef struct pm_locals {
/** The number of local variables in the set. */
uint32_t size;
/** The capacity of the local variables set. */
uint32_t capacity;
/** The nullable allocated memory for the local variables in the set. */
pm_local_t *locals;
} pm_locals_t;
/** The flags about scope parameters that can be set. */
typedef uint8_t pm_scope_parameters_t;
static const pm_scope_parameters_t PM_SCOPE_PARAMETERS_NONE = 0x0;
static const pm_scope_parameters_t PM_SCOPE_PARAMETERS_FORWARDING_POSITIONALS = 0x1;
static const pm_scope_parameters_t PM_SCOPE_PARAMETERS_FORWARDING_KEYWORDS = 0x2;
static const pm_scope_parameters_t PM_SCOPE_PARAMETERS_FORWARDING_BLOCK = 0x4;
static const pm_scope_parameters_t PM_SCOPE_PARAMETERS_FORWARDING_ALL = 0x8;
static const pm_scope_parameters_t PM_SCOPE_PARAMETERS_IMPLICIT_DISALLOWED = 0x10;
static const pm_scope_parameters_t PM_SCOPE_PARAMETERS_NUMBERED_INNER = 0x20;
static const pm_scope_parameters_t PM_SCOPE_PARAMETERS_NUMBERED_FOUND = 0x40;
/**
* This struct represents a node in a linked list of scopes. Some scopes can see
* into their parent scopes, while others cannot.
*/
typedef struct pm_scope {
/** A pointer to the previous scope in the linked list. */
struct pm_scope *previous;
/** The IDs of the locals in the given scope. */
pm_locals_t locals;
/**
* This is a list of the implicit parameters contained within the block.
* These will be processed after the block is parsed to determine the kind
* of parameters node that should be used and to check if any errors need to
* be added.
*/
pm_node_list_t implicit_parameters;
/**
* This is a bitfield that indicates the parameters that are being used in
* this scope. It is a combination of the PM_SCOPE_PARAMETERS_* constants.
* There are three different kinds of parameters that can be used in a
* scope:
*
* - Ordinary parameters (e.g., def foo(bar); end)
* - Numbered parameters (e.g., def foo; _1; end)
* - The it parameter (e.g., def foo; it; end)
*
* If ordinary parameters are being used, then certain parameters can be
* forwarded to another method/structure. Those are indicated by four
* additional bits in the params field. For example, some combinations of:
*
* - def foo(*); end
* - def foo(**); end
* - def foo(&); end
* - def foo(...); end
*/
pm_scope_parameters_t parameters;
/**
* The current state of constant shareability for this scope. This is
* changed by magic shareable_constant_value comments.
*/
pm_shareable_constant_value_t shareable_constant;
/**
* A boolean indicating whether or not this scope can see into its parent.
* If closed is true, then the scope cannot see into its parent.
*/
bool closed;
} pm_scope_t;
/**
* A struct that represents a stack of boolean values.
*/
typedef uint32_t pm_state_stack_t;
/**
* This struct represents the overall parser. It contains a reference to the
* source file, as well as pointers that indicate where in the source it's
* currently parsing. It also contains the most recent and current token that
* it's considering.
*/
struct pm_parser {
/**
* The next node identifier that will be assigned. This is a unique
* identifier used to track nodes such that the syntax tree can be dropped
* but the node can be found through another parse.
*/
uint32_t node_id;
/** The current state of the lexer. */
pm_lex_state_t lex_state;
/** Tracks the current nesting of (), [], and {}. */
int enclosure_nesting;
/**
* Used to temporarily track the nesting of enclosures to determine if a {
* is the beginning of a lambda following the parameters of a lambda.
*/
int lambda_enclosure_nesting;
/**
* Used to track the nesting of braces to ensure we get the correct value
* when we are interpolating blocks with braces.
*/
int brace_nesting;
/**
* The stack used to determine if a do keyword belongs to the predicate of a
* while, until, or for loop.
*/
pm_state_stack_t do_loop_stack;
/**
* The stack used to determine if a do keyword belongs to the beginning of a
* block.
*/
pm_state_stack_t accepts_block_stack;
/** A stack of lex modes. */
struct {
/** The current mode of the lexer. */
pm_lex_mode_t *current;
/** The stack of lexer modes. */
pm_lex_mode_t stack[PM_LEX_STACK_SIZE];
/** The current index into the lexer mode stack. */
size_t index;
} lex_modes;
/** The pointer to the start of the source. */
const uint8_t *start;
/** The pointer to the end of the source. */
const uint8_t *end;
/** The previous token we were considering. */
pm_token_t previous;
/** The current token we're considering. */
pm_token_t current;
/**
* This is a special field set on the parser when we need the parser to jump
* to a specific location when lexing the next token, as opposed to just
* using the end of the previous token. Normally this is NULL.
*/
const uint8_t *next_start;
/**
* This field indicates the end of a heredoc whose identifier was found on
* the current line. If another heredoc is found on the same line, then this
* will be moved forward to the end of that heredoc. If no heredocs are
* found on a line then this is NULL.
*/
const uint8_t *heredoc_end;
/** The list of comments that have been found while parsing. */
pm_list_t comment_list;
/** The list of magic comments that have been found while parsing. */
pm_list_t magic_comment_list;
/**
* An optional location that represents the location of the __END__ marker
* and the rest of the content of the file. This content is loaded into the
* DATA constant when the file being parsed is the main file being executed.
*/
pm_location_t data_loc;
/** The list of warnings that have been found while parsing. */
pm_list_t warning_list;
/** The list of errors that have been found while parsing. */
pm_list_t error_list;
/** The current local scope. */
pm_scope_t *current_scope;
/** The current parsing context. */
pm_context_node_t *current_context;
/**
* The hash keys for the hash that is currently being parsed. This is not
* usually necessary because it can pass it down the various call chains,
* but in the event that you're parsing a hash that is being directly
* pushed into another hash with **, we need to share the hash keys so that
* we can warn for the nested hash as well.
*/
pm_static_literals_t *current_hash_keys;
/**
* The encoding functions for the current file is attached to the parser as
* it's parsing so that it can change with a magic comment.
*/
const pm_encoding_t *encoding;
/**
* When the encoding that is being used to parse the source is changed by
* prism, we provide the ability here to call out to a user-defined
* function.
*/
pm_encoding_changed_callback_t encoding_changed_callback;
/**
* This pointer indicates where a comment must start if it is to be
* considered an encoding comment.
*/
const uint8_t *encoding_comment_start;
/**
* This is an optional callback that can be attached to the parser that will
* be called whenever a new token is lexed by the parser.
*/
pm_lex_callback_t *lex_callback;
/**
* This is the path of the file being parsed. We use the filepath when
* constructing SourceFileNodes.
*/
pm_string_t filepath;
/**
* This constant pool keeps all of the constants defined throughout the file
* so that we can reference them later.
*/
pm_constant_pool_t constant_pool;
/** This is the list of newline offsets in the source file. */
pm_newline_list_t newline_list;
/**
* We want to add a flag to integer nodes that indicates their base. We only
* want to parse these once, but we don't have space on the token itself to
* communicate this information. So we store it here and pass it through
* when we find tokens that we need it for.
*/
pm_node_flags_t integer_base;
/**
* This string is used to pass information from the lexer to the parser. It
* is particularly necessary because of escape sequences.
*/
pm_string_t current_string;
/**
* The line number at the start of the parse. This will be used to offset
* the line numbers of all of the locations.
*/
int32_t start_line;
/**
* When a string-like expression is being lexed, any byte or escape sequence
* that resolves to a value whose top bit is set (i.e., >= 0x80) will
* explicitly set the encoding to the same encoding as the source.
* Alternatively, if a unicode escape sequence is used (e.g., \\u{80}) that
* resolves to a value whose top bit is set, then the encoding will be
* explicitly set to UTF-8.
*
* The _next_ time this happens, if the encoding that is about to become the
* explicitly set encoding does not match the previously set explicit
* encoding, a mixed encoding error will be emitted.
*
* When the expression is finished being lexed, the explicit encoding
* controls the encoding of the expression. For the most part this means
* that the expression will either be encoded in the source encoding or
* UTF-8. This holds for all encodings except US-ASCII. If the source is
* US-ASCII and an explicit encoding was set that was _not_ UTF-8, then the
* expression will be encoded as ASCII-8BIT.
*
* Note that if the expression is a list, different elements within the same
* list can have different encodings, so this will get reset between each
* element. Furthermore all of this only applies to lists that support
* interpolation, because otherwise escapes that could change the encoding
* are ignored.
*
* At first glance, it may make more sense for this to live on the lexer
* mode, but we need it here to communicate back to the parser for character
* literals that do not push a new lexer mode.
*/
const pm_encoding_t *explicit_encoding;
/**
* When parsing block exits (e.g., break, next, redo), we need to validate
* that they are in correct contexts. For the most part we can do this by
* looking at our parent contexts. However, modifier while and until
* expressions can change that context to make block exits valid. In these
* cases, we need to keep track of the block exits and then validate them
* after the expression has been parsed.
*
* We use a pointer here because we don't want to keep a whole list attached
* since this will only be used in the context of begin/end expressions.
*/
pm_node_list_t *current_block_exits;
/** The version of prism that we should use to parse. */
pm_options_version_t version;
/** The command line flags given from the options. */
uint8_t command_line;
/**
* Whether or not we have found a frozen_string_literal magic comment with
* a true or false value.
* May be:
* - PM_OPTIONS_FROZEN_STRING_LITERAL_DISABLED
* - PM_OPTIONS_FROZEN_STRING_LITERAL_ENABLED
* - PM_OPTIONS_FROZEN_STRING_LITERAL_UNSET
*/
int8_t frozen_string_literal;
/**
* Whether or not we are parsing an eval string. This impacts whether or not
* we should evaluate if block exits/yields are valid.
*/
bool parsing_eval;
/**
* Whether or not we are parsing a "partial" script, which is a script that
* will be evaluated in the context of another script, so we should not
* check jumps (next/break/etc.) for validity.
*/
bool partial_script;
/** Whether or not we're at the beginning of a command. */
bool command_start;
/** Whether or not we're currently recovering from a syntax error. */
bool recovering;
/**
* This is very specialized behavior for when you want to parse in a context
* that does not respect encoding comments. Its main use case is translating
* into the whitequark/parser AST which re-encodes source files in UTF-8
* before they are parsed and ignores encoding comments.
*/
bool encoding_locked;
/**
* Whether or not the encoding has been changed by a magic comment. We use
* this to provide a fast path for the lexer instead of going through the
* function pointer.
*/
bool encoding_changed;
/**
* This flag indicates that we are currently parsing a pattern matching
* expression and impacts that calculation of newlines.
*/
bool pattern_matching_newlines;
/** This flag indicates that we are currently parsing a keyword argument. */
bool in_keyword_arg;
/**
* Whether or not the parser has seen a token that has semantic meaning
* (i.e., a token that is not a comment or whitespace).
*/
bool semantic_token_seen;
/**
* True if the current regular expression being lexed contains only ASCII
* characters.
*/
bool current_regular_expression_ascii_only;
/**
* By default, Ruby always warns about mismatched indentation. This can be
* toggled with a magic comment.
*/
bool warn_mismatched_indentation;
};
#endif