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|
// © 2024 and later: Unicode, Inc. and others.
// License & terms of use: http://www.unicode.org/copyright.html
#include "unicode/utypes.h"
#if !UCONFIG_NO_FORMATTING
#if !UCONFIG_NO_MF2
#include "messageformat2_errors.h"
#include "messageformat2_macros.h"
#include "messageformat2_parser.h"
#include "uvector.h" // U_ASSERT
U_NAMESPACE_BEGIN
namespace message2 {
using namespace pluralimpl;
using namespace data_model;
/*
The `ERROR()` macro sets a syntax error in the context
and sets the offset in `parseError` to `index`. It does not alter control flow.
*/
#define ERROR(parseError, errorCode, index) \
if (!errors.hasSyntaxError()) { \
setParseError(parseError, index); \
errors.addSyntaxError(errorCode); \
}
// Returns true iff `index` is a valid index for the string `source`
static bool inBounds(const UnicodeString &source, uint32_t index) {
return (((int32_t)index) < source.length());
}
// Increments the line number and updates the "characters seen before
// current line" count in `parseError`, iff `source[index]` is a newline
void Parser::maybeAdvanceLine() {
if (source[index] == LF) {
parseError.line++;
// add 1 to index to get the number of characters seen so far
// (including the newline)
parseError.lengthBeforeCurrentLine = index + 1;
}
}
/*
Signals an error and returns either if `parseError` already denotes an
error, or `index` is out of bounds for the string `source`
*/
#define CHECK_BOUNDS(source, index, parseError, errorCode) \
if (!inBounds(source, index)) { \
ERROR(parseError, errorCode, index); \
return; \
}
// -------------------------------------
// Helper functions
static void copyContext(const UChar in[U_PARSE_CONTEXT_LEN], UChar out[U_PARSE_CONTEXT_LEN]) {
for (int32_t i = 0; i < U_PARSE_CONTEXT_LEN; i++) {
out[i] = in[i];
if (in[i] == '\0') {
break;
}
}
}
/* static */ void Parser::translateParseError(const MessageParseError &messageParseError, UParseError &parseError) {
parseError.line = messageParseError.line;
parseError.offset = messageParseError.offset;
copyContext(messageParseError.preContext, parseError.preContext);
copyContext(messageParseError.postContext, parseError.postContext);
}
/* static */ void Parser::setParseError(MessageParseError &parseError, uint32_t index) {
// Translate absolute to relative offset
parseError.offset = index // Start with total number of characters seen
- parseError.lengthBeforeCurrentLine; // Subtract all characters before the current line
// TODO: Fill this in with actual pre and post-context
parseError.preContext[0] = 0;
parseError.postContext[0] = 0;
}
// -------------------------------------
// Predicates
// Returns true if `c` is in the interval [`first`, `last`]
static bool inRange(UChar32 c, UChar32 first, UChar32 last) {
U_ASSERT(first < last);
return c >= first && c <= last;
}
/*
The following helper predicates should exactly match nonterminals in the MessageFormat 2 grammar:
`isContentChar()` : `content-char`
`isTextChar()` : `text-char`
`isReservedStart()` : `reserved-start`
`isReservedChar()` : `reserved-char`
`isAlpha()` : `ALPHA`
`isDigit()` : `DIGIT`
`isNameStart()` : `name-start`
`isNameChar()` : `name-char`
`isUnquotedStart()` : `unquoted-start`
`isQuotedChar()` : `quoted-char`
`isWhitespace()` : `s`
*/
static bool isContentChar(UChar32 c) {
return inRange(c, 0x0001, 0x0008) // Omit NULL, HTAB and LF
|| inRange(c, 0x000B, 0x000C) // Omit CR
|| inRange(c, 0x000E, 0x001F) // Omit SP
|| inRange(c, 0x0021, 0x002D) // Omit '.'
|| inRange(c, 0x002F, 0x003F) // Omit '@'
|| inRange(c, 0x0041, 0x005B) // Omit '\'
|| inRange(c, 0x005D, 0x007A) // Omit { | }
|| inRange(c, 0x007E, 0xD7FF) // Omit surrogates
|| inRange(c, 0xE000, 0x10FFFF);
}
// See `s` in the MessageFormat 2 grammar
inline bool isWhitespace(UChar32 c) {
switch (c) {
case SPACE:
case HTAB:
case CR:
case LF:
case IDEOGRAPHIC_SPACE:
return true;
default:
return false;
}
}
static bool isTextChar(UChar32 c) {
return isContentChar(c)
|| isWhitespace(c)
|| c == PERIOD
|| c == AT
|| c == PIPE;
}
// Note: this doesn't distinguish between private-use
// and reserved, since the data model doesn't
static bool isReservedStart(UChar32 c) {
switch (c) {
case BANG:
case PERCENT:
case ASTERISK:
case PLUS:
case LESS_THAN:
case GREATER_THAN:
case QUESTION:
case TILDE:
// Private-use
case CARET:
case AMPERSAND:
return true;
default:
return false;
}
}
static bool isReservedChar(UChar32 c) {
return isContentChar(c) || c == PERIOD;
}
static bool isReservedBodyStart(UChar32 c) {
return isReservedChar(c) || c == BACKSLASH || c == PIPE;
}
static bool isAlpha(UChar32 c) { return inRange(c, 0x0041, 0x005A) || inRange(c, 0x0061, 0x007A); }
static bool isDigit(UChar32 c) { return inRange(c, 0x0030, 0x0039); }
static bool isNameStart(UChar32 c) {
return isAlpha(c) || c == UNDERSCORE || inRange(c, 0x00C0, 0x00D6) || inRange(c, 0x00D8, 0x00F6) ||
inRange(c, 0x00F8, 0x02FF) || inRange(c, 0x0370, 0x037D) || inRange(c, 0x037F, 0x1FFF) ||
inRange(c, 0x200C, 0x200D) || inRange(c, 0x2070, 0x218F) || inRange(c, 0x2C00, 0x2FEF) ||
inRange(c, 0x3001, 0xD7FF) || inRange(c, 0xF900, 0xFDCF) || inRange(c, 0xFDF0, 0xFFFD) ||
inRange(c, 0x10000, 0xEFFFF);
}
static bool isNameChar(UChar32 c) {
return isNameStart(c) || isDigit(c) || c == HYPHEN || c == PERIOD || c == 0x00B7 ||
inRange(c, 0x0300, 0x036F) || inRange(c, 0x203F, 0x2040);
}
static bool isUnquotedStart(UChar32 c) {
return isNameStart(c) || isDigit(c) || c == HYPHEN || c == PERIOD || c == 0x00B7 ||
inRange(c, 0x0300, 0x036F) || inRange(c, 0x203F, 0x2040);
}
static bool isQuotedChar(UChar32 c) {
return isContentChar(c)
|| isWhitespace(c)
|| c == PERIOD
|| c == AT
|| c == LEFT_CURLY_BRACE
|| c == RIGHT_CURLY_BRACE;
}
// Returns true iff `c` can begin a `function` nonterminal
static bool isFunctionStart(UChar32 c) {
switch (c) {
case COLON: {
return true;
}
default: {
return false;
}
}
}
// Returns true iff `c` can begin an `annotation` nonterminal
static bool isAnnotationStart(UChar32 c) {
return isFunctionStart(c) || isReservedStart(c);
}
// Returns true iff `c` can begin either a `reserved-char` or `reserved-escape`
// literal
static bool reservedChunkFollows(UChar32 c) {
switch(c) {
// reserved-escape
case BACKSLASH:
// literal
case PIPE: {
return true;
}
default: {
// reserved-char
return (isReservedChar(c));
}
}
}
// Returns true iff `c` can begin a `literal` nonterminal
static bool isLiteralStart(UChar32 c) {
return (c == PIPE || isNameStart(c) || c == HYPHEN || isDigit(c));
}
// Returns true iff `c` can begin a `key` nonterminal
static bool isKeyStart(UChar32 c) {
return (c == ASTERISK || isLiteralStart(c));
}
inline bool isDeclarationStart(const UnicodeString& source, int32_t index) {
int32_t len = source.length();
int32_t next = index + 1;
return (source[index] == ID_LOCAL[0]
&& next < len
&& source[next] == ID_LOCAL[1])
|| (source[index] == ID_INPUT[0]
&& next < len
&& source[next] == ID_INPUT[1]);
}
// -------------------------------------
// Parsing functions
/*
TODO: Since handling the whitespace ambiguities needs to be repeated
in several different places and is hard to factor out,
it probably would be better to replace the parser with a lexer + parser
to separate tokenizing from parsing, which would simplify the code significantly.
This has the disadvantage that there is no token grammar for MessageFormat,
so one would have to be invented that isn't a component of the spec.
*/
/*
This is a recursive-descent scannerless parser that,
with a few exceptions, uses 1 character of lookahead.
This may not be an exhaustive list, as the additions of attributes and reserved
statements introduced several new ambiguities.
All but three of the exceptions involve ambiguities about the meaning of whitespace.
One ambiguity not involving whitespace is:
identifier -> namespace ":" name
vs.
identifier -> name
`namespace` and `name` can't be distinguished without arbitrary lookahead.
(For how this is handled, see parseIdentifier())
The second ambiguity not involving whitespace is:
complex-message -> *(declaration[s]) complex-body
-> declaration *(declaration[s]) complex-body
-> declaration complex-body
-> reserved-statement complex-body
-> .foo {$x} .match // ...
When processing the '.', arbitrary lookahead is required to distinguish the
arbitrary-length unsupported keyword from `.match`.
(For how this is handled, see parseDeclarations()).
The third ambiguity not involving whitespace is:
complex-message -> *(declaration [s]) complex-body
-> reserved-statement *(declaration [s]) complex-body
-> reserved-statement complex-body
-> reserved-statement quotedPattern
-> reserved-keyword [s reserved-body] 1*([s] expression) quoted-pattern
-> reserved-keyword expression quoted-pattern
Example: .foo {1} {{1}}
Without lookahead, the opening '{' of the quoted pattern can't be distinguished
from the opening '{' of another expression in the unsupported statement.
(Though this only requires 1 character of lookahead.)
Otherwise:
There are at least seven ambiguities in the grammar that can't be resolved with finite
lookahead (since whitespace sequences can be arbitrarily long). They are resolved
with a form of backtracking (early exit). No state needs to be saved/restored
since whitespace doesn't affect the shape of the resulting parse tree, so it's
not true backtracking.
In addition, the grammar has been refactored
in a semantics-preserving way in some cases to make the code easier to structure.
First: variant = when 1*(s key) [s] pattern
Example: when k {a}
When reading the first space after 'k', it's ambiguous whether it's the
required space before another key, or the optional space before `pattern`.
(See comments in parseNonEmptyKeys())
Second: expression = "{" [s] (((literal / variable) [s annotation]) / annotation) [s] "}"
annotation = (function *(s option)) / reserved
Example: {:f }
When reading the first space after 'f', it's ambiguous whether it's the
required space before an option, or the optional trailing space after an options list
(in this case, the options list is empty).
(See comments in parseOptions() -- handling this case also meant it was easier to base
the code on a slightly refactored grammar, which should be semantically equivalent.)
Third: expression = "{" [s] (((literal / variable) [s annotation]) / annotation) [s] "}"
annotation = (function *(s option)) / reserved
Example: {@a }
Similar to the previous case; see comments in parseReserved()
Fourth: expression = "{" [s] (((literal / variable) [s annotation]) / annotation) [s] "}"
Example: {|foo| }
When reading the first space after the '|', it's ambiguous whether it's the required
space before an annotation, or the optional trailing space before the '}'.
(See comments in parseLiteralOrVariableWithAnnotation(); handling this case relies on
the same grammar refactoring as the second exception.)
Most functions match a non-terminal in the grammar, except as explained
in comments.
Fifth: matcher = match-statement 1*([s] variant)
-> match 1 *([s] selector) 1*([s] variant)
Example: match {42} * {{_}}
When reading the space after the first '}', it's unclear whether
it's the optional space before another selector, or the optional space
before a variant.
Sixth: annotation-expression = "{" [s] annotation *(s attribute) [s] "}"
-> "{" [s] function *(s attribute) [s] "}"
-> "{" [s] ":" identifier *(s option) *(s attribute) [s] "}"
-> "{" [s] ":" identifier s attribute *(s attribute) [s] "}"
Example: {:func @foo}
(Note: the same ambiguity is present with variable-expression and literal-expression)
Seventh:
When parsing the space, it's unclear whether it's the optional space before an
option, or the optional space before an attribute.
Unless otherwise noted in a comment, all helper functions that take
a `source` string, an `index` unsigned int, and an `errorCode` `UErrorCode`
have the precondition:
`index` < `source.length()`
and the postcondition:
`U_FAILURE(errorCode)` || `index < `source.length()`
*/
/*
No pre, no post.
A message may end with whitespace, so `index` may equal `source.length()` on exit.
*/
void Parser::parseWhitespaceMaybeRequired(bool required, UErrorCode& errorCode) {
bool sawWhitespace = false;
// The loop exits either when we consume all the input,
// or when we see a non-whitespace character.
while (true) {
// Check if all input has been consumed
if (!inBounds(source, index)) {
// If whitespace isn't required -- or if we saw it already --
// then the caller is responsible for checking this case and
// setting an error if necessary.
if (!required || sawWhitespace) {
// Not an error.
return;
}
// Otherwise, whitespace is required; the end of the input has
// been reached without whitespace. This is an error.
ERROR(parseError, errorCode, index);
return;
}
// Input remains; process the next character if it's whitespace,
// exit the loop otherwise
if (isWhitespace(source[index])) {
sawWhitespace = true;
// Increment line number in parse error if we consume a newline
maybeAdvanceLine();
index++;
} else {
break;
}
}
if (!sawWhitespace && required) {
ERROR(parseError, errorCode, index);
}
}
/*
No pre, no post, for the same reason as `parseWhitespaceMaybeRequired()`.
*/
void Parser::parseRequiredWhitespace(UErrorCode& errorCode) {
parseWhitespaceMaybeRequired(true, errorCode);
normalizedInput += SPACE;
}
/*
No pre, no post, for the same reason as `parseWhitespaceMaybeRequired()`.
*/
void Parser::parseOptionalWhitespace(UErrorCode& errorCode) {
parseWhitespaceMaybeRequired(false, errorCode);
}
// Consumes a single character, signaling an error if `source[index]` != `c`
// No postcondition -- a message can end with a '}' token
void Parser::parseToken(UChar32 c, UErrorCode& errorCode) {
CHECK_BOUNDS(source, index, parseError, errorCode);
if (source[index] == c) {
index++;
normalizedInput += c;
return;
}
// Next character didn't match -- error out
ERROR(parseError, errorCode, index);
}
/*
Consumes a fixed-length token, signaling an error if the token isn't a prefix of
the string beginning at `source[index]`
No postcondition -- a message can end with a '}' token
*/
template <int32_t N>
void Parser::parseToken(const UChar32 (&token)[N], UErrorCode& errorCode) {
U_ASSERT(inBounds(source, index));
int32_t tokenPos = 0;
while (tokenPos < N - 1) {
if (source[index] != token[tokenPos]) {
ERROR(parseError, errorCode, index);
return;
}
normalizedInput += token[tokenPos];
index++;
tokenPos++;
}
}
/*
Consumes optional whitespace, possibly advancing `index` to `index'`,
then consumes a fixed-length token (signaling an error if the token isn't a prefix of
the string beginning at `source[index']`),
then consumes optional whitespace again
*/
template <int32_t N>
void Parser::parseTokenWithWhitespace(const UChar32 (&token)[N], UErrorCode& errorCode) {
// No need for error check or bounds check before parseOptionalWhitespace
parseOptionalWhitespace(errorCode);
// Establish precondition
CHECK_BOUNDS(source, index, parseError, errorCode);
parseToken(token);
parseOptionalWhitespace(errorCode);
// Guarantee postcondition
CHECK_BOUNDS(source, index, parseError, errorCode);
}
/*
Consumes optional whitespace, possibly advancing `index` to `index'`,
then consumes a single character (signaling an error if it doesn't match
`source[index']`),
then consumes optional whitespace again
*/
void Parser::parseTokenWithWhitespace(UChar32 c, UErrorCode& errorCode) {
// No need for error check or bounds check before parseOptionalWhitespace(errorCode)
parseOptionalWhitespace(errorCode);
// Establish precondition
CHECK_BOUNDS(source, index, parseError, errorCode);
parseToken(c, errorCode);
parseOptionalWhitespace(errorCode);
// Guarantee postcondition
CHECK_BOUNDS(source, index, parseError, errorCode);
}
/*
Consumes a non-empty sequence of `name-char`s, the first of which is
also a `name-start`.
that begins with a character `start` such that `isNameStart(start)`.
Returns this sequence.
(Matches the `name` nonterminal in the grammar.)
*/
UnicodeString Parser::parseName(UErrorCode& errorCode) {
UnicodeString name;
U_ASSERT(inBounds(source, index));
if (!isNameStart(source[index])) {
ERROR(parseError, errorCode, index);
return name;
}
while (isNameChar(source[index])) {
name += source[index];
normalizedInput += source[index];
index++;
if (!inBounds(source, index)) {
ERROR(parseError, errorCode, index);
break;
}
}
return name;
}
/*
Consumes a '$' followed by a `name`, returning a VariableName
with `name` as its name
(Matches the `variable` nonterminal in the grammar.)
*/
VariableName Parser::parseVariableName(UErrorCode& errorCode) {
VariableName result;
U_ASSERT(inBounds(source, index));
// If the '$' is missing, we don't want a binding
// for this variable to be created.
bool valid = source[index] == DOLLAR;
parseToken(DOLLAR, errorCode);
if (!inBounds(source, index)) {
ERROR(parseError, errorCode, index);
return result;
}
UnicodeString varName = parseName(errorCode);
// Set the name to "" if the variable wasn't
// declared correctly
if (!valid) {
varName.remove();
}
return VariableName(varName);
}
/*
Corresponds to the `identifier` nonterminal in the grammar
*/
UnicodeString Parser::parseIdentifier(UErrorCode& errorCode) {
U_ASSERT(inBounds(source, index));
UnicodeString result;
// The following is a hack to get around ambiguity in the grammar:
// identifier -> namespace ":" name
// vs.
// identifier -> name
// can't be distinguished without arbitrary lookahead.
// Instead, we treat the production as:
// identifier -> namespace *(":"name)
// and then check for multiple colons.
// Parse namespace
result += parseName(errorCode);
int32_t firstColon = -1;
while (inBounds(source, index) && source[index] == COLON) {
// Parse ':' separator
if (firstColon == -1) {
firstColon = index;
}
parseToken(COLON, errorCode);
result += COLON;
// Check for message ending with something like "foo:"
if (!inBounds(source, index)) {
ERROR(parseError, errorCode, index);
} else {
// Parse name part
result += parseName(errorCode);
}
}
// If there's at least one ':', scan from the first ':'
// to the end of the name to check for multiple ':'s
if (firstColon != -1) {
for (int32_t i = firstColon + 1; i < result.length(); i++) {
if (result[i] == COLON) {
ERROR(parseError, errorCode, i);
return {};
}
}
}
return result;
}
/*
Consumes a reference to a function, matching the ": identifier"
in the `function` nonterminal in the grammar.
Returns the function name.
*/
FunctionName Parser::parseFunction(UErrorCode& errorCode) {
U_ASSERT(inBounds(source, index));
if (!isFunctionStart(source[index])) {
ERROR(parseError, errorCode, index);
return FunctionName();
}
normalizedInput += source[index];
index++; // Consume the function start character
if (!inBounds(source, index)) {
ERROR(parseError, errorCode, index);
return FunctionName();
}
return parseIdentifier(errorCode);
}
/*
Precondition: source[index] == BACKSLASH
Consume an escaped character.
Generalized to handle `reserved-escape`, `text-escape`,
or `literal-escape`, depending on the `kind` argument.
Appends result to `str`
*/
void Parser::parseEscapeSequence(EscapeKind kind,
UnicodeString &str,
UErrorCode& errorCode) {
U_ASSERT(inBounds(source, index));
U_ASSERT(source[index] == BACKSLASH);
normalizedInput += BACKSLASH;
index++; // Skip the initial backslash
CHECK_BOUNDS(source, index, parseError, errorCode);
#define SUCCEED \
/* Append to the output string */ \
str += source[index]; \
/* Update normalizedInput */ \
normalizedInput += source[index]; \
/* Consume the character */ \
index++; \
/* Guarantee postcondition */ \
CHECK_BOUNDS(source, index, parseError, errorCode); \
return;
// Expect a '{', '|' or '}'
switch (source[index]) {
case LEFT_CURLY_BRACE:
case RIGHT_CURLY_BRACE: {
// Allowed in a `text-escape` or `reserved-escape`
switch (kind) {
case TEXT:
case RESERVED: {
SUCCEED;
}
default: {
break;
}
}
break;
}
case PIPE: {
// Allowed in a `literal-escape` or `reserved-escape`
switch (kind) {
case LITERAL:
case RESERVED: {
SUCCEED;
}
default: {
break;
}
}
break;
}
case BACKSLASH: {
// Allowed in any escape sequence
SUCCEED;
}
default: {
// No other characters are allowed here
break;
}
}
// If control reaches here, there was an error
ERROR(parseError, errorCode, index);
}
/*
Consume an escaped pipe or backslash, matching the `literal-escape`
nonterminal in the grammar
*/
void Parser::parseLiteralEscape(UnicodeString &str, UErrorCode& errorCode) {
parseEscapeSequence(LITERAL, str, errorCode);
}
/*
Consume and return a quoted literal, matching the `literal` nonterminal in the grammar.
*/
Literal Parser::parseQuotedLiteral(UErrorCode& errorCode) {
bool error = false;
UnicodeString contents;
if (U_SUCCESS(errorCode)) {
// Parse the opening '|'
parseToken(PIPE, errorCode);
if (!inBounds(source, index)) {
ERROR(parseError, errorCode, index);
error = true;
} else {
// Parse the contents
bool done = false;
while (!done) {
if (source[index] == BACKSLASH) {
parseLiteralEscape(contents, errorCode);
} else if (isQuotedChar(source[index])) {
contents += source[index];
normalizedInput += source[index];
index++; // Consume this character
maybeAdvanceLine();
} else {
// Assume the sequence of literal characters ends here
done = true;
}
if (!inBounds(source, index)) {
ERROR(parseError, errorCode, index);
error = true;
break;
}
}
}
}
if (error) {
return {};
}
// Parse the closing '|'
parseToken(PIPE, errorCode);
return Literal(true, contents);
}
// Parse (1*DIGIT)
UnicodeString Parser::parseDigits(UErrorCode& errorCode) {
if (U_FAILURE(errorCode)) {
return {};
}
U_ASSERT(isDigit(source[index]));
UnicodeString contents;
do {
contents += source[index];
normalizedInput += source[index];
index++;
if (!inBounds(source, index)) {
ERROR(parseError, errorCode, index);
return {};
}
} while (isDigit(source[index]));
return contents;
}
/*
Consume and return an unquoted literal, matching the `unquoted` nonterminal in the grammar.
*/
Literal Parser::parseUnquotedLiteral(UErrorCode& errorCode) {
if (U_FAILURE(errorCode)) {
return {};
}
// unquoted -> name
if (isNameStart(source[index])) {
return Literal(false, parseName(errorCode));
}
// unquoted -> number
// Parse the contents
UnicodeString contents;
// Parse the sign
if (source[index] == HYPHEN) {
contents += source[index];
normalizedInput += source[index];
index++;
}
if (!inBounds(source, index)) {
ERROR(parseError, errorCode, index);
return {};
}
// Parse the integer part
if (source[index] == ((UChar32)0x0030) /* 0 */) {
contents += source[index];
normalizedInput += source[index];
index++;
} else if (isDigit(source[index])) {
contents += parseDigits(errorCode);
} else {
// Error -- nothing else can start a number literal
ERROR(parseError, errorCode, index);
return {};
}
// Parse the decimal point if present
if (source[index] == PERIOD) {
contents += source[index];
normalizedInput += source[index];
index++;
if (!inBounds(source, index)) {
ERROR(parseError, errorCode, index);
return {};
}
// Parse the fraction part
if (isDigit(source[index])) {
contents += parseDigits(errorCode);
} else {
// '.' not followed by digit is a parse error
ERROR(parseError, errorCode, index);
return {};
}
}
if (!inBounds(source, index)) {
ERROR(parseError, errorCode, index);
return {};
}
// Parse the exponent part if present
if (source[index] == UPPERCASE_E || source[index] == LOWERCASE_E) {
contents += source[index];
normalizedInput += source[index];
index++;
if (!inBounds(source, index)) {
ERROR(parseError, errorCode, index);
return {};
}
// Parse sign if present
if (source[index] == PLUS || source[index] == HYPHEN) {
contents += source[index];
normalizedInput += source[index];
index++;
if (!inBounds(source, index)) {
ERROR(parseError, errorCode, index);
return {};
}
}
// Parse exponent digits
if (!isDigit(source[index])) {
ERROR(parseError, errorCode, index);
return {};
}
contents += parseDigits(errorCode);
}
return Literal(false, contents);
}
/*
Consume and return a literal, matching the `literal` nonterminal in the grammar.
*/
Literal Parser::parseLiteral(UErrorCode& errorCode) {
Literal result;
if (!inBounds(source, index)) {
ERROR(parseError, errorCode, index);
} else {
if (source[index] == PIPE) {
result = parseQuotedLiteral(errorCode);
} else {
result = parseUnquotedLiteral(errorCode);
}
// Guarantee postcondition
if (!inBounds(source, index)) {
ERROR(parseError, errorCode, index);
}
}
return result;
}
/*
Consume a @name-value pair, matching the `attribute` nonterminal in the grammar.
Adds the option to `options`
*/
template<class T>
void Parser::parseAttribute(AttributeAdder<T>& attrAdder, UErrorCode& errorCode) {
U_ASSERT(inBounds(source, index));
U_ASSERT(source[index] == AT);
// Consume the '@'
parseToken(AT, errorCode);
// Parse LHS
UnicodeString lhs = parseIdentifier(errorCode);
// Prepare to "backtrack" to resolve ambiguity
// about whether whitespace precedes another
// attribute, or the '=' sign
int32_t savedIndex = index;
parseOptionalWhitespace(errorCode);
Operand rand;
if (source[index] == EQUALS) {
// Parse '='
parseTokenWithWhitespace(EQUALS, errorCode);
UnicodeString rhsStr;
// Parse RHS, which is either a literal or variable
switch (source[index]) {
case DOLLAR: {
rand = Operand(parseVariableName(errorCode));
break;
}
default: {
// Must be a literal
rand = Operand(parseLiteral(errorCode));
break;
}
}
U_ASSERT(!rand.isNull());
} else {
// attribute -> "@" identifier [[s] "=" [s]]
// Use null operand, which `rand` is already set to
// "Backtrack" by restoring the whitespace (if there was any)
index = savedIndex;
}
attrAdder.addAttribute(lhs, std::move(rand), errorCode);
}
/*
Consume a name-value pair, matching the `option` nonterminal in the grammar.
Adds the option to `optionList`
*/
template<class T>
void Parser::parseOption(OptionAdder<T>& addOption, UErrorCode& errorCode) {
U_ASSERT(inBounds(source, index));
// Parse LHS
UnicodeString lhs = parseIdentifier(errorCode);
// Parse '='
parseTokenWithWhitespace(EQUALS, errorCode);
UnicodeString rhsStr;
Operand rand;
// Parse RHS, which is either a literal or variable
switch (source[index]) {
case DOLLAR: {
rand = Operand(parseVariableName(errorCode));
break;
}
default: {
// Must be a literal
rand = Operand(parseLiteral(errorCode));
break;
}
}
U_ASSERT(!rand.isNull());
// Finally, add the key=value mapping
// Use a local error code, check for duplicate option error and
// record it as with other errors
UErrorCode status = U_ZERO_ERROR;
addOption.addOption(lhs, std::move(rand), status);
if (U_FAILURE(status)) {
U_ASSERT(status == U_MF_DUPLICATE_OPTION_NAME_ERROR);
errors.setDuplicateOptionName(errorCode);
}
}
/*
Note: there are multiple overloads of parseOptions() for parsing
options within markup, vs. within an expression, vs. parsing
attributes. This should be refactored. TODO
*/
/*
Consume optional whitespace followed by a sequence of options
(possibly empty), separated by whitespace
*/
template <class T>
void Parser::parseOptions(OptionAdder<T>& addOption, UErrorCode& errorCode) {
// Early exit if out of bounds -- no more work is possible
CHECK_BOUNDS(source, index, parseError, errorCode);
/*
Arbitrary lookahead is required to parse option lists. To see why, consider
these rules from the grammar:
expression = "{" [s] (((literal / variable) [s annotation]) / annotation) [s] "}"
annotation = (function *(s option)) / reserved
And this example:
{:foo }
Derivation:
expression -> "{" [s] (((literal / variable) [s annotation]) / annotation) [s] "}"
-> "{" [s] annotation [s] "}"
-> "{" [s] ((function *(s option)) / reserved) [s] "}"
-> "{" [s] function *(s option) [s] "}"
In this example, knowing whether to expect a '}' or the start of another option
after the whitespace would require arbitrary lookahead -- in other words, which
rule should we apply?
*(s option) -> s option *(s option)
or
*(s option) ->
The same would apply to the example {:foo k=v } (note the trailing space after "v").
This is addressed using a form of backtracking and (to make the backtracking easier
to apply) a slight refactoring to the grammar.
This code is written as if the grammar is:
expression = "{" [s] (((literal / variable) ([s] / [s annotation])) / annotation) "}"
annotation = (function *(s option) [s]) / (reserved [s])
Parsing the `*(s option) [s]` sequence can be done within `parseOptions()`, meaning
that `parseExpression()` can safely require a '}' after `parseOptions()` finishes.
Note that when "backtracking" really just means early exit, since only whitespace
is involved and there's no state to save.
There is a separate but similar ambiguity as to whether the space precedes
an option or an attribute.
*/
while(true) {
// If the next character is not whitespace, that means we've already
// parsed the entire options list (which may have been empty) and there's
// no trailing whitespace. In that case, exit.
if (!isWhitespace(source[index])) {
break;
}
int32_t firstWhitespace = index;
// In any case other than an empty options list, there must be at least
// one whitespace character.
parseRequiredWhitespace(errorCode);
// Restore precondition
CHECK_BOUNDS(source, index, parseError, errorCode);
// If a name character follows, then at least one more option remains
// in the list.
// Otherwise, we've consumed all the options and any trailing whitespace,
// and can exit.
// Note that exiting is sort of like backtracking: "(s option)" doesn't apply,
// so we back out to [s].
if (!isNameStart(source[index])) {
// We've consumed all the options (meaning that either we consumed non-empty
// whitespace, or consumed at least one option.)
// Done.
// Remove the required whitespace from normalizedInput
normalizedInput.truncate(normalizedInput.length() - 1);
// "Backtrack" so as to leave the optional whitespace there
// when parsing attributes
index = firstWhitespace;
break;
}
parseOption(addOption, errorCode);
}
}
/*
Consume optional whitespace followed by a sequence of attributes
(possibly empty), separated by whitespace
*/
template<class T>
void Parser::parseAttributes(AttributeAdder<T>& attrAdder, UErrorCode& errorCode) {
// Early exit if out of bounds -- no more work is possible
if (!inBounds(source, index)) {
ERROR(parseError, errorCode, index);
return;
}
/*
Arbitrary lookahead is required to parse attribute lists, similarly to option lists.
(See comment in parseOptions()).
*/
while(true) {
// If the next character is not whitespace, that means we've already
// parsed the entire attributes list (which may have been empty) and there's
// no trailing whitespace. In that case, exit.
if (!isWhitespace(source[index])) {
break;
}
// In any case other than an empty attributes list, there must be at least
// one whitespace character.
parseRequiredWhitespace(errorCode);
// Restore precondition
if (!inBounds(source, index)) {
ERROR(parseError, errorCode, index);
break;
}
// If an '@' follows, then at least one more attribute remains
// in the list.
// Otherwise, we've consumed all the attributes and any trailing whitespace,
// and can exit.
// Note that exiting is sort of like backtracking: "(s attributes)" doesn't apply,
// so we back out to [s].
if (source[index] != AT) {
// We've consumed all the attributes (meaning that either we consumed non-empty
// whitespace, or consumed at least one attribute.)
// Done.
// Remove the whitespace from normalizedInput
normalizedInput.truncate(normalizedInput.length() - 1);
break;
}
parseAttribute(attrAdder, errorCode);
}
}
void Parser::parseReservedEscape(UnicodeString &str, UErrorCode& errorCode) {
parseEscapeSequence(RESERVED, str, errorCode);
}
/*
Consumes a non-empty sequence of reserved-chars, reserved-escapes, and
literals (as in 1*(reserved-char / reserved-escape / literal) in the `reserved-body` rule)
Appends it to `str`
*/
void Parser::parseReservedChunk(Reserved::Builder& result, UErrorCode& status) {
CHECK_ERROR(status);
bool empty = true;
UnicodeString chunk;
while(reservedChunkFollows(source[index])) {
empty = false;
// reserved-char
if (isReservedChar(source[index])) {
chunk += source[index];
normalizedInput += source[index];
// consume the char
index++;
// Restore precondition
CHECK_BOUNDS(source, index, parseError, status);
continue;
}
if (chunk.length() > 0) {
result.add(Literal(false, chunk), status);
chunk.setTo(u"", 0);
}
if (source[index] == BACKSLASH) {
// reserved-escape
parseReservedEscape(chunk, status);
result.add(Literal(false, chunk), status);
chunk.setTo(u"", 0);
} else if (source[index] == PIPE || isUnquotedStart(source[index])) {
result.add(parseLiteral(status), status);
} else {
// The reserved chunk ends here
break;
}
CHECK_ERROR(status); // Avoid looping infinitely
}
// Add the last chunk if necessary
if (chunk.length() > 0) {
result.add(Literal(false, chunk), status);
}
if (empty) {
ERROR(parseError, status, index);
}
}
/*
Consume a `reserved-start` character followed by a possibly-empty sequence
of non-empty sequences of reserved characters, separated by whitespace.
Matches the `reserved` nonterminal in the grammar
*/
Reserved Parser::parseReserved(UErrorCode& status) {
Reserved::Builder builder(status);
if (U_FAILURE(status)) {
return {};
}
U_ASSERT(inBounds(source, index));
// Require a `reservedStart` character
if (!isReservedStart(source[index])) {
ERROR(parseError, status, index);
return Reserved();
}
// Add the start char as a separate text chunk
UnicodeString firstCharString(source[index]);
builder.add(Literal(false, firstCharString), status);
if (U_FAILURE(status)) {
return {};
}
// Consume reservedStart
normalizedInput += source[index];
index++;
return parseReservedBody(builder, status);
}
Reserved Parser::parseReservedBody(Reserved::Builder& builder, UErrorCode& status) {
if (U_FAILURE(status)) {
return {};
}
/*
Arbitrary lookahead is required to parse a `reserved`, for similar reasons
to why it's required for parsing function annotations.
In the grammar:
annotation = (function *(s option)) / reserved
expression = "{" [s] (((literal / variable) [s annotation]) / annotation) [s] "}"
reserved = reserved-start reserved-body
reserved-body = *( [s] 1*(reserved-char / reserved-escape / literal))
When reading a whitespace character, it's ambiguous whether it's the optional
whitespace in this rule, or the optional whitespace that precedes a '}' in an
expression.
The ambiguity is resolved using the same grammar refactoring as shown in
the comment in `parseOptions()`.
*/
// Consume reserved characters / literals / reserved escapes
// until a character that can't be in a `reserved-body` is seen
while (true) {
/*
First, if there is whitespace, it means either a chunk follows it,
or this is the trailing whitespace before the '}' that terminates an
expression.
Next, if the next character can start a reserved-char, reserved-escape,
or literal, then parse a "chunk" of reserved things.
In any other case, we exit successfully, since per the refactored
grammar rule:
annotation = (function *(s option) [s]) / (reserved [s])
it's valid to consume whitespace after a `reserved`.
(`parseExpression()` is responsible for checking that the next
character is in fact a '}'.)
*/
if (!inBounds(source, index)) {
break;
}
int32_t numWhitespaceChars = 0;
int32_t savedIndex = index;
if (isWhitespace(source[index])) {
parseOptionalWhitespace(status);
numWhitespaceChars = index - savedIndex;
// Restore precondition
if (!inBounds(source, index)) {
break;
}
}
if (reservedChunkFollows(source[index])) {
parseReservedChunk(builder, status);
// Avoid looping infinitely
if (U_FAILURE(status) || !inBounds(source, index)) {
break;
}
} else {
if (numWhitespaceChars > 0) {
if (source[index] == LEFT_CURLY_BRACE) {
// Resolve even more ambiguity (space preceding another piece of
// a `reserved-body`, vs. space preceding an expression in `reserved-statement`
// "Backtrack"
index -= numWhitespaceChars;
break;
}
if (source[index] == RIGHT_CURLY_BRACE) {
// Not an error: just means there's no trailing whitespace
// after this `reserved`
break;
}
if (source[index] == AT) {
// Not an error, but we have to "backtrack" due to the ambiguity
// between an `s` preceding another reserved chunk
// and an `s` preceding an attribute list
index -= numWhitespaceChars;
break;
}
// Error: if there's whitespace, it must either be followed
// by a non-empty sequence or by '}'
ERROR(parseError, status, index);
break;
}
// If there was no whitespace, it's not an error,
// just the end of the reserved string
break;
}
}
return builder.build(status);
}
/*
Consume a function call or reserved string, matching the `annotation`
nonterminal in the grammar
Returns an `Operator` representing this (a reserved is a parse error)
*/
Operator Parser::parseAnnotation(UErrorCode& status) {
U_ASSERT(inBounds(source, index));
Operator::Builder ratorBuilder(status);
if (U_FAILURE(status)) {
return {};
}
if (isFunctionStart(source[index])) {
// Consume the function name
FunctionName func = parseFunction(status);
ratorBuilder.setFunctionName(std::move(func));
OptionAdder<Operator::Builder> addOptions(ratorBuilder);
// Consume the options (which may be empty)
parseOptions(addOptions, status);
} else {
// Must be reserved
// A reserved sequence is not a parse error, but might be a formatting error
Reserved rator = parseReserved(status);
ratorBuilder.setReserved(std::move(rator));
}
UErrorCode localStatus = U_ZERO_ERROR;
Operator result = ratorBuilder.build(localStatus);
// Either `setReserved` or `setFunctionName` was called,
// so there shouldn't be an error.
U_ASSERT(U_SUCCESS(localStatus));
return result;
}
/*
Consume a literal or variable (depending on `isVariable`),
followed by either required whitespace followed by an annotation,
or optional whitespace.
*/
void Parser::parseLiteralOrVariableWithAnnotation(bool isVariable,
Expression::Builder& builder,
UErrorCode& status) {
CHECK_ERROR(status);
U_ASSERT(inBounds(source, index));
Operand rand;
if (isVariable) {
rand = Operand(parseVariableName(status));
} else {
rand = Operand(parseLiteral(status));
}
builder.setOperand(std::move(rand));
/*
Parsing a literal or variable with an optional annotation requires arbitrary lookahead.
To see why, consider this rule from the grammar:
expression = "{" [s] (((literal / variable) [s annotation]) / annotation) [s] "}"
And this example:
{|foo| }
Derivation:
expression -> "{" [s] (((literal / variable) [s annotation]) / annotation) [s] "}"
-> "{" [s] ((literal / variable) [s annotation]) [s] "}"
-> "{" [s] (literal [s annotation]) [s] "}"
When reading the ' ' after the second '|', it's ambiguous whether that's the required
space before an annotation, or the optional space before the '}'.
To make this ambiguity easier to handle, this code is based on the same grammar
refactoring for the `expression` nonterminal that `parseOptions()` relies on. See
the comment in `parseOptions()` for details.
*/
if (isWhitespace(source[index])) {
int32_t firstWhitespace = index;
// If the next character is whitespace, either [s annotation] or [s] applies
// (the character is either the required space before an annotation, or optional
// trailing space after the literal or variable). It's still ambiguous which
// one does apply.
parseOptionalWhitespace(status);
// Restore precondition
CHECK_BOUNDS(source, index, parseError, status);
// This next check resolves the ambiguity between [s annotation] and [s]
bool isSAnnotation = isAnnotationStart(source[index]);
if (isSAnnotation) {
normalizedInput += SPACE;
}
if (isSAnnotation) {
// The previously consumed whitespace precedes an annotation
builder.setOperator(parseAnnotation(status));
} else {
// Either there's a right curly brace (will be consumed by the caller),
// or there's an error and the trailing whitespace should be
// handled by the caller. However, this is not an error
// here because we're just parsing `literal [s annotation]`.
index = firstWhitespace;
}
} else {
// Either there was never whitespace, or
// the previously consumed whitespace is the optional trailing whitespace;
// either the next character is '}' or the error will be handled by parseExpression.
// Do nothing, since the operand was already set
}
// At the end of this code, the next character should either be '}',
// whitespace followed by a '}',
// or end-of-input
}
/*
Consume an expression, matching the `expression` nonterminal in the grammar
*/
static void exprFallback(Expression::Builder& exprBuilder) {
// Construct a literal consisting just of The U+FFFD REPLACEMENT CHARACTER
// per https://github.com/unicode-org/message-format-wg/blob/main/spec/formatting.md#fallback-resolution
exprBuilder.setOperand(Operand(Literal(false, UnicodeString(REPLACEMENT))));
}
static Expression exprFallback(UErrorCode& status) {
Expression result;
if (U_SUCCESS(status)) {
Expression::Builder exprBuilder(status);
if (U_SUCCESS(status)) {
// Construct a literal consisting just of The U+FFFD REPLACEMENT CHARACTER
// per https://github.com/unicode-org/message-format-wg/blob/main/spec/formatting.md#fallback-resolution
exprBuilder.setOperand(Operand(Literal(false, UnicodeString(REPLACEMENT))));
UErrorCode status = U_ZERO_ERROR;
result = exprBuilder.build(status);
// An operand was set, so there can't be an error
U_ASSERT(U_SUCCESS(status));
}
}
return result;
}
Expression Parser::parseExpression(UErrorCode& status) {
if (U_FAILURE(status)) {
return {};
}
// Early return if out of input -- no more work is possible
U_ASSERT(inBounds(source, index));
// Parse opening brace
parseToken(LEFT_CURLY_BRACE, status);
// Optional whitespace after opening brace
parseOptionalWhitespace(status);
Expression::Builder exprBuilder(status);
// Restore precondition
if (!inBounds(source, index)) {
exprFallback(exprBuilder);
} else {
// literal '|', variable '$' or annotation
switch (source[index]) {
case PIPE: {
// Quoted literal
parseLiteralOrVariableWithAnnotation(false, exprBuilder, status);
break;
}
case DOLLAR: {
// Variable
parseLiteralOrVariableWithAnnotation(true, exprBuilder, status);
break;
}
default: {
if (isAnnotationStart(source[index])) {
Operator rator = parseAnnotation(status);
exprBuilder.setOperator(std::move(rator));
} else if (isUnquotedStart(source[index])) {
// Unquoted literal
parseLiteralOrVariableWithAnnotation(false, exprBuilder, status);
} else {
// Not a literal, variable or annotation -- error out
ERROR(parseError, status, index);
exprFallback(exprBuilder);
break;
}
break;
}
}
}
// Parse attributes
AttributeAdder attrAdder(exprBuilder);
parseAttributes(attrAdder, status);
// Parse optional space
// (the last [s] in e.g. "{" [s] literal [s annotation] *(s attribute) [s] "}")
parseOptionalWhitespace(status);
// Either an operand or operator (or both) must have been set already,
// so there can't be an error
UErrorCode localStatus = U_ZERO_ERROR;
Expression result = exprBuilder.build(localStatus);
U_ASSERT(U_SUCCESS(localStatus));
// Check for end-of-input and missing '}'
if (!inBounds(source, index)) {
ERROR(parseError, status, index);
} else {
// Otherwise, it's safe to check for the '}'
parseToken(RIGHT_CURLY_BRACE, status);
}
return result;
}
/*
Parse a .local declaration, matching the `local-declaration`
production in the grammar
*/
void Parser::parseLocalDeclaration(UErrorCode& status) {
// End-of-input here would be an error; even empty
// declarations must be followed by a body
CHECK_BOUNDS(source, index, parseError, status);
parseToken(ID_LOCAL, status);
parseRequiredWhitespace(status);
// Restore precondition
CHECK_BOUNDS(source, index, parseError, status);
VariableName lhs = parseVariableName(status);
parseTokenWithWhitespace(EQUALS, status);
// Restore precondition before calling parseExpression()
CHECK_BOUNDS(source, index, parseError, status);
Expression rhs = parseExpression(status);
// Add binding from lhs to rhs, unless there was an error
// (This ensures that if there was a correct lhs but a
// parse error in rhs, the fallback for uses of the
// lhs will be its own name rather than the rhs)
/* This affects the behavior of this test case, which the spec
is ambiguous about:
.local $bar {|foo|} {{{$bar}}}
Should `$bar` still be bound to a value although
its declaration is syntactically incorrect (missing the '=')?
This code says no, but it needs to change if
https://github.com/unicode-org/message-format-wg/issues/703
is resolved differently.
*/
CHECK_ERROR(status);
if (!errors.hasSyntaxError()) {
dataModel.addBinding(Binding(std::move(lhs), std::move(rhs)), status);
// Check if status is U_DUPLICATE_DECLARATION_ERROR
// and add that as an internal error if so
if (status == U_MF_DUPLICATE_DECLARATION_ERROR) {
status = U_ZERO_ERROR;
errors.addError(StaticErrorType::DuplicateDeclarationError, status);
}
}
}
/*
Parse an .input declaration, matching the `local-declaration`
production in the grammar
*/
void Parser::parseInputDeclaration(UErrorCode& status) {
// End-of-input here would be an error; even empty
// declarations must be followed by a body
CHECK_BOUNDS(source, index, parseError, status);
parseToken(ID_INPUT, status);
parseOptionalWhitespace(status);
// Restore precondition before calling parseExpression()
CHECK_BOUNDS(source, index, parseError, status);
// Save the index for error diagnostics
int32_t exprIndex = index;
Expression rhs = parseExpression(status);
// Here we have to check that the rhs is a variable-expression
if (!rhs.getOperand().isVariable()) {
// This case is a syntax error; report it at the beginning
// of the expression
ERROR(parseError, status, exprIndex);
return;
}
VariableName lhs = rhs.getOperand().asVariable();
// Add binding from lhs to rhs
// This just adds a new local variable that shadows the message
// argument referred to, which is harmless.
// When evaluating the RHS, the new local is not in scope
// and the message argument will be correctly referred to.
CHECK_ERROR(status);
if (!errors.hasSyntaxError()) {
dataModel.addBinding(Binding::input(std::move(lhs), std::move(rhs), status), status);
// Check if status is U_MF_DUPLICATE_DECLARATION_ERROR
// and add that as an internal error if so
if (status == U_MF_DUPLICATE_DECLARATION_ERROR) {
status = U_ZERO_ERROR;
errors.addError(StaticErrorType::DuplicateDeclarationError, status);
}
}
}
/*
Parses a `reserved-statement` per the grammar
*/
void Parser::parseUnsupportedStatement(UErrorCode& status) {
U_ASSERT(inBounds(source, index) && source[index] == PERIOD);
UnsupportedStatement::Builder builder(status);
CHECK_ERROR(status);
// Parse the keyword
UnicodeString keyword(PERIOD);
normalizedInput += UnicodeString(PERIOD);
index++;
keyword += parseName(status);
builder.setKeyword(keyword);
// Parse the body, which is optional
// Lookahead is required to distinguish the `s` in reserved-body
// from the `s` in `[s] expression`
// Next character may be:
// * whitespace (followed by either a reserved-body start or
// a '{')
// * a '{'
CHECK_BOUNDS(source, index, parseError, status);
if (source[index] != LEFT_CURLY_BRACE) {
if (!isWhitespace(source[index])) {
ERROR(parseError, status, index);
return;
}
// Expect a reserved-body start
int32_t savedIndex = index;
parseRequiredWhitespace(status);
CHECK_BOUNDS(source, index, parseError, status);
if (isReservedBodyStart(source[index])) {
// There is a reserved body
Reserved::Builder r(status);
builder.setBody(parseReservedBody(r, status));
} else {
// No body -- backtrack so we can parse 1*([s] expression)
index = savedIndex;
normalizedInput.truncate(normalizedInput.length() - 1);
}
// Otherwise, the next character must be a '{'
// to open the required expression (or optional whitespace)
if (source[index] != LEFT_CURLY_BRACE && !isWhitespace(source[index])) {
ERROR(parseError, status, index);
return;
}
}
// Finally, parse the expressions
// Need to look ahead to disambiguate a '{' beginning
// an expression from one beginning with a quoted pattern
int32_t expressionCount = 0;
while (source[index] == LEFT_CURLY_BRACE || isWhitespace(source[index])) {
parseOptionalWhitespace(status);
bool nextIsLbrace = source[index] == LEFT_CURLY_BRACE;
bool nextIsQuotedPattern = nextIsLbrace && inBounds(source, index + 1)
&& source[index + 1] == LEFT_CURLY_BRACE;
if (nextIsQuotedPattern) {
break;
}
builder.addExpression(parseExpression(status), status);
expressionCount++;
}
if (expressionCount <= 0) {
// At least one expression is required
ERROR(parseError, status, index);
return;
}
dataModel.addUnsupportedStatement(builder.build(status), status);
}
// Terrible hack to get around the ambiguity between `matcher` and `reserved-statement`
bool Parser::nextIsMatch() const {
for(int32_t i = 0; i < 6; i++) {
if (!inBounds(source, index + i) || source[index + i] != ID_MATCH[i]) {
return false;
}
}
return true;
}
/*
Consume a possibly-empty sequence of declarations separated by whitespace;
each declaration matches the `declaration` nonterminal in the grammar
Builds up an environment representing those declarations
*/
void Parser::parseDeclarations(UErrorCode& status) {
// End-of-input here would be an error; even empty
// declarations must be followed by a body
CHECK_BOUNDS(source, index, parseError, status);
while (source[index] == PERIOD) {
CHECK_BOUNDS(source, index + 1, parseError, status);
if (source[index + 1] == ID_LOCAL[1]) {
parseLocalDeclaration(status);
} else if (source[index + 1] == ID_INPUT[1]) {
parseInputDeclaration(status);
} else {
// Unsupported statement
// Lookahead is needed to disambiguate this from a `match`
if (!nextIsMatch()) {
parseUnsupportedStatement(status);
} else {
// Done parsing declarations
break;
}
}
// Avoid looping infinitely
CHECK_ERROR(status);
parseOptionalWhitespace(status);
// Restore precondition
CHECK_BOUNDS(source, index, parseError, status);
}
}
/*
Consume an escaped curly brace, or backslash, matching the `text-escape`
nonterminal in the grammar
*/
void Parser::parseTextEscape(UnicodeString &str, UErrorCode& status) {
parseEscapeSequence(TEXT, str, status);
}
/*
Consume a non-empty sequence of text characters and escaped text characters,
matching the `text` nonterminal in the grammar
No postcondition (a message can end with a text)
*/
UnicodeString Parser::parseText(UErrorCode& status) {
UnicodeString str;
if (!inBounds(source, index)) {
// Text can be empty
return str;
}
if (!(isTextChar(source[index] || source[index] == BACKSLASH))) {
// Error -- text is expected here
ERROR(parseError, status, index);
return str;
}
while (true) {
if (source[index] == BACKSLASH) {
parseTextEscape(str, status);
} else if (isTextChar(source[index])) {
normalizedInput += source[index];
str += source[index];
index++;
maybeAdvanceLine();
} else {
break;
}
if (!inBounds(source, index)) {
// OK for text to end a message
break;
}
}
return str;
}
/*
Consume an `nmtoken`, `literal`, or the string "*", matching
the `key` nonterminal in the grammar
*/
Key Parser::parseKey(UErrorCode& status) {
U_ASSERT(inBounds(source, index));
Key k; // wildcard by default
// Literal | '*'
switch (source[index]) {
case ASTERISK: {
index++;
normalizedInput += ASTERISK;
// Guarantee postcondition
if (!inBounds(source, index)) {
ERROR(parseError, status, index);
return k;
}
break;
}
default: {
// Literal
k = Key(parseLiteral(status));
break;
}
}
return k;
}
/*
Consume a non-empty sequence of `key`s separated by whitespace
Takes ownership of `keys`
*/
SelectorKeys Parser::parseNonEmptyKeys(UErrorCode& status) {
SelectorKeys result;
if (U_FAILURE(status)) {
return result;
}
U_ASSERT(inBounds(source, index));
/*
Arbitrary lookahead is required to parse key lists. To see why, consider
this rule from the grammar:
variant = key *(s key) [s] quoted-pattern
And this example:
when k1 k2 {a}
Derivation:
variant -> key *(s key) [s] quoted-pattern
-> key s key *(s key) quoted-pattern
After matching ' ' to `s` and 'k2' to `key`, it would require arbitrary lookahead
to know whether to expect the start of a pattern or the start of another key.
In other words: is the second whitespace sequence the required space in *(s key),
or the optional space in [s] quoted-pattern?
This is addressed using "backtracking" (similarly to `parseOptions()`).
*/
SelectorKeys::Builder keysBuilder(status);
if (U_FAILURE(status)) {
return result;
}
// Since the first key is required, it's simplest to parse it separately.
keysBuilder.add(parseKey(status), status);
// Restore precondition
if (!inBounds(source, index)) {
ERROR(parseError, status, index);
return result;
}
// We've seen at least one whitespace-key pair, so now we can parse
// *(s key) [s]
while (source[index] != LEFT_CURLY_BRACE || isWhitespace(source[index])) { // Try to recover from errors
bool wasWhitespace = isWhitespace(source[index]);
parseRequiredWhitespace(status);
if (!wasWhitespace) {
// Avoid infinite loop when parsing something like:
// when * @{!...
index++;
}
// Restore precondition
if (!inBounds(source, index)) {
ERROR(parseError, status, index);
return result;
}
// At this point, it's ambiguous whether we are inside (s key) or [s].
// This check resolves that ambiguity.
if (source[index] == LEFT_CURLY_BRACE) {
// A pattern follows, so what we just parsed was the optional
// trailing whitespace. All the keys have been parsed.
// Unpush the whitespace from `normalizedInput`
normalizedInput.truncate(normalizedInput.length() - 1);
break;
}
keysBuilder.add(parseKey(status), status);
}
return keysBuilder.build(status);
}
Pattern Parser::parseQuotedPattern(UErrorCode& status) {
U_ASSERT(inBounds(source, index));
parseToken(LEFT_CURLY_BRACE, status);
parseToken(LEFT_CURLY_BRACE, status);
Pattern p = parseSimpleMessage(status);
parseToken(RIGHT_CURLY_BRACE, status);
parseToken(RIGHT_CURLY_BRACE, status);
return p;
}
/*
Consume a `placeholder`, matching the nonterminal in the grammar
No postcondition (a markup can end a message)
*/
Markup Parser::parseMarkup(UErrorCode& status) {
U_ASSERT(inBounds(source, index + 1));
U_ASSERT(source[index] == LEFT_CURLY_BRACE);
Markup::Builder builder(status);
if (U_FAILURE(status)) {
return {};
}
// Consume the '{'
index++;
normalizedInput += LEFT_CURLY_BRACE;
parseOptionalWhitespace(status);
bool closing = false;
switch (source[index]) {
case NUMBER_SIGN: {
// Open or standalone; consume the '#'
normalizedInput += source[index];
index++;
break;
}
case SLASH: {
// Closing
normalizedInput += source[index];
closing = true;
index++;
break;
}
default: {
ERROR(parseError, status, index);
return {};
}
}
// Parse the markup identifier
builder.setName(parseIdentifier(status));
// Parse the options, which must begin with a ' '
// if present
if (inBounds(source, index) && isWhitespace(source[index])) {
OptionAdder<Markup::Builder> optionAdder(builder);
parseOptions(optionAdder, status);
}
// Parse the attributes, which also must begin
// with a ' '
if (inBounds(source, index) && isWhitespace(source[index])) {
AttributeAdder attrAdder(builder);
parseAttributes(attrAdder, status);
}
parseOptionalWhitespace(status);
bool standalone = false;
// Check if this is a standalone or not
if (!closing) {
if (inBounds(source, index) && source[index] == SLASH) {
standalone = true;
normalizedInput += SLASH;
index++;
}
}
parseToken(RIGHT_CURLY_BRACE, status);
if (standalone) {
builder.setStandalone();
} else if (closing) {
builder.setClose();
} else {
builder.setOpen();
}
return builder.build(status);
}
/*
Consume a `placeholder`, matching the nonterminal in the grammar
No postcondition (a placeholder can end a message)
*/
std::variant<Expression, Markup> Parser::parsePlaceholder(UErrorCode& status) {
U_ASSERT(source[index] == LEFT_CURLY_BRACE);
if (!inBounds(source, index)) {
ERROR(parseError, status, index);
return exprFallback(status);
}
// Check if it's markup or an expression
if (source[index + 1] == NUMBER_SIGN || source[index + 1] == SLASH) {
// Markup
return parseMarkup(status);
}
return parseExpression(status);
}
/*
Consume a `simple-message`, matching the nonterminal in the grammar
Postcondition: `index == source.length()` or U_FAILURE(status);
for a syntactically correct message, this will consume the entire input
*/
Pattern Parser::parseSimpleMessage(UErrorCode& status) {
Pattern::Builder result(status);
if (U_SUCCESS(status)) {
Expression expression;
while (inBounds(source, index)) {
switch (source[index]) {
case LEFT_CURLY_BRACE: {
// Must be placeholder
std::variant<Expression, Markup> piece = parsePlaceholder(status);
if (std::holds_alternative<Expression>(piece)) {
Expression expr = *std::get_if<Expression>(&piece);
result.add(std::move(expr), status);
} else {
Markup markup = *std::get_if<Markup>(&piece);
result.add(std::move(markup), status);
}
break;
}
default: {
// Must be text
result.add(parseText(status), status);
break;
}
}
if (source[index] == RIGHT_CURLY_BRACE) {
// End of quoted pattern
break;
}
// Don't loop infinitely
if (errors.hasSyntaxError()) {
break;
}
}
}
return result.build(status);
}
/*
Consume a `selectors` (matching the nonterminal in the grammar),
followed by a non-empty sequence of `variant`s (matching the nonterminal
in the grammar) preceded by whitespace
No postcondition (on return, `index` might equal `source.length()` with no syntax error
because a message can end with a variant)
*/
void Parser::parseSelectors(UErrorCode& status) {
CHECK_ERROR(status);
U_ASSERT(inBounds(source, index));
parseToken(ID_MATCH, status);
bool empty = true;
// Parse selectors
// "Backtracking" is required here. It's not clear if whitespace is
// (`[s]` selector) or (`[s]` variant)
while (isWhitespace(source[index]) || source[index] == LEFT_CURLY_BRACE) {
parseOptionalWhitespace(status);
// Restore precondition
CHECK_BOUNDS(source, index, parseError, status);
if (source[index] != LEFT_CURLY_BRACE) {
// This is not necessarily an error, but rather,
// means the whitespace we parsed was the optional
// whitespace preceding the first variant, not the
// optional whitespace preceding a subsequent expression.
break;
}
Expression expression;
expression = parseExpression(status);
empty = false;
dataModel.addSelector(std::move(expression), status);
CHECK_ERROR(status);
}
// At least one selector is required
if (empty) {
ERROR(parseError, status, index);
return;
}
#define CHECK_END_OF_INPUT \
if (((int32_t)index) >= source.length()) { \
break; \
} \
// Parse variants
while (isWhitespace(source[index]) || isKeyStart(source[index])) {
if (isWhitespace(source[index])) {
int32_t whitespaceStart = index;
parseOptionalWhitespace(status);
// Restore the precondition.
// Error out if we reached the end of input. The message
// cannot end with trailing whitespace if there are variants.
if (!inBounds(source, index)) {
// Use index of first whitespace for error message
index = whitespaceStart;
ERROR(parseError, status, index);
return;
}
}
// At least one key is required
SelectorKeys keyList(parseNonEmptyKeys(status));
CHECK_ERROR(status);
// parseNonEmptyKeys() consumes any trailing whitespace,
// so the pattern can be consumed next.
// Restore precondition before calling parsePattern()
// (which must return a non-null value)
CHECK_BOUNDS(source, index, parseError, status);
Pattern rhs = parseQuotedPattern(status);
dataModel.addVariant(std::move(keyList), std::move(rhs), status);
// Restore the precondition, *without* erroring out if we've
// reached the end of input. That's because it's valid for the
// message to end with a variant that has no trailing whitespace.
// Why do we need to check this condition twice inside the loop?
// Because if we don't check it here, the `isWhitespace()` call in
// the loop head will read off the end of the input string.
CHECK_END_OF_INPUT
}
}
/*
Consume a `body` (matching the nonterminal in the grammar),
No postcondition (on return, `index` might equal `source.length()` with no syntax error,
because a message can end with a body (trailing whitespace is optional)
*/
void Parser::errorPattern(UErrorCode& status) {
errors.addSyntaxError(status);
// Set to empty pattern
Pattern::Builder result = Pattern::Builder(status);
CHECK_ERROR(status);
// If still in bounds, then add the remaining input as a single text part
// to the pattern
/*
TODO: this behavior isn't documented in the spec, but it comes from
https://github.com/messageformat/messageformat/blob/e0087bff312d759b67a9129eac135d318a1f0ce7/packages/mf2-messageformat/src/__fixtures/test-messages.json#L236
and a pending pull request https://github.com/unicode-org/message-format-wg/pull/462 will clarify
whether this is the intent behind the spec
*/
UnicodeString partStr(LEFT_CURLY_BRACE);
while (inBounds(source, index)) {
partStr += source[index++];
}
// Add curly braces around the entire output (same comment as above)
partStr += RIGHT_CURLY_BRACE;
result.add(std::move(partStr), status);
dataModel.setPattern(result.build(status));
}
void Parser::parseBody(UErrorCode& status) {
CHECK_ERROR(status);
// Out-of-input is a syntax warning
if (!inBounds(source, index)) {
errorPattern(status);
return;
}
// Body must be either a pattern or selectors
switch (source[index]) {
case LEFT_CURLY_BRACE: {
// Pattern
dataModel.setPattern(parseQuotedPattern(status));
break;
}
case ID_MATCH[0]: {
// Selectors
parseSelectors(status);
return;
}
default: {
ERROR(parseError, status, index);
errorPattern(status);
return;
}
}
}
// -------------------------------------
// Parses the source pattern.
void Parser::parse(UParseError &parseErrorResult, UErrorCode& status) {
CHECK_ERROR(status);
bool simple = true;
// Message can be empty, so we need to only look ahead
// if we know it's non-empty
if (inBounds(source, index)) {
if (source[index] == PERIOD
|| (index < ((uint32_t) source.length() + 1)
&& source[index] == LEFT_CURLY_BRACE
&& source[index + 1] == LEFT_CURLY_BRACE)) {
// A complex message begins with a '.' or '{'
parseDeclarations(status);
parseBody(status);
simple = false;
}
}
if (simple) {
// Simple message
// For normalization, quote the pattern
normalizedInput += LEFT_CURLY_BRACE;
normalizedInput += LEFT_CURLY_BRACE;
dataModel.setPattern(parseSimpleMessage(status));
normalizedInput += RIGHT_CURLY_BRACE;
normalizedInput += RIGHT_CURLY_BRACE;
}
CHECK_ERROR(status);
// There are no errors; finally, check that the entire input was consumed
if (((int32_t)index) != source.length()) {
ERROR(parseError, status, index);
}
// Finally, copy the relevant fields of the internal `MessageParseError`
// into the `UParseError` argument
translateParseError(parseError, parseErrorResult);
}
Parser::~Parser() {}
} // namespace message2
U_NAMESPACE_END
#endif /* #if !UCONFIG_NO_MF2 */
#endif /* #if !UCONFIG_NO_FORMATTING */
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