github-pages-deploy-action/node_modules/graphql/language/lexer.js.flow
2020-03-06 22:45:40 -05:00

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// @flow strict
import { syntaxError } from '../error/syntaxError';
import { Token } from './ast';
import { type Source } from './source';
import { dedentBlockStringValue } from './blockString';
import { type TokenKindEnum, TokenKind } from './tokenKind';
/**
* Given a Source object, creates a Lexer for that source.
* A Lexer is a stateful stream generator in that every time
* it is advanced, it returns the next token in the Source. Assuming the
* source lexes, the final Token emitted by the lexer will be of kind
* EOF, after which the lexer will repeatedly return the same EOF token
* whenever called.
*/
export class Lexer {
source: Source;
/**
* The previously focused non-ignored token.
*/
lastToken: Token;
/**
* The currently focused non-ignored token.
*/
token: Token;
/**
* The (1-indexed) line containing the current token.
*/
line: number;
/**
* The character offset at which the current line begins.
*/
lineStart: number;
constructor(source: Source) {
const startOfFileToken = new Token(TokenKind.SOF, 0, 0, 0, 0, null);
this.source = source;
this.lastToken = startOfFileToken;
this.token = startOfFileToken;
this.line = 1;
this.lineStart = 0;
}
/**
* Advances the token stream to the next non-ignored token.
*/
advance(): Token {
this.lastToken = this.token;
const token = (this.token = this.lookahead());
return token;
}
/**
* Looks ahead and returns the next non-ignored token, but does not change
* the state of Lexer.
*/
lookahead(): Token {
let token = this.token;
if (token.kind !== TokenKind.EOF) {
do {
// Note: next is only mutable during parsing, so we cast to allow this.
token = token.next ?? ((token: any).next = readToken(this, token));
} while (token.kind === TokenKind.COMMENT);
}
return token;
}
}
/**
* @internal
*/
export function isPunctuatorTokenKind(kind: TokenKindEnum): boolean %checks {
return (
kind === TokenKind.BANG ||
kind === TokenKind.DOLLAR ||
kind === TokenKind.AMP ||
kind === TokenKind.PAREN_L ||
kind === TokenKind.PAREN_R ||
kind === TokenKind.SPREAD ||
kind === TokenKind.COLON ||
kind === TokenKind.EQUALS ||
kind === TokenKind.AT ||
kind === TokenKind.BRACKET_L ||
kind === TokenKind.BRACKET_R ||
kind === TokenKind.BRACE_L ||
kind === TokenKind.PIPE ||
kind === TokenKind.BRACE_R
);
}
function printCharCode(code) {
return (
// NaN/undefined represents access beyond the end of the file.
isNaN(code)
? TokenKind.EOF
: // Trust JSON for ASCII.
code < 0x007f
? JSON.stringify(String.fromCharCode(code))
: // Otherwise print the escaped form.
`"\\u${('00' + code.toString(16).toUpperCase()).slice(-4)}"`
);
}
/**
* Gets the next token from the source starting at the given position.
*
* This skips over whitespace until it finds the next lexable token, then lexes
* punctuators immediately or calls the appropriate helper function for more
* complicated tokens.
*/
function readToken(lexer: Lexer, prev: Token): Token {
const source = lexer.source;
const body = source.body;
const bodyLength = body.length;
const pos = positionAfterWhitespace(body, prev.end, lexer);
const line = lexer.line;
const col = 1 + pos - lexer.lineStart;
if (pos >= bodyLength) {
return new Token(TokenKind.EOF, bodyLength, bodyLength, line, col, prev);
}
const code = body.charCodeAt(pos);
// SourceCharacter
switch (code) {
// !
case 33:
return new Token(TokenKind.BANG, pos, pos + 1, line, col, prev);
// #
case 35:
return readComment(source, pos, line, col, prev);
// $
case 36:
return new Token(TokenKind.DOLLAR, pos, pos + 1, line, col, prev);
// &
case 38:
return new Token(TokenKind.AMP, pos, pos + 1, line, col, prev);
// (
case 40:
return new Token(TokenKind.PAREN_L, pos, pos + 1, line, col, prev);
// )
case 41:
return new Token(TokenKind.PAREN_R, pos, pos + 1, line, col, prev);
// .
case 46:
if (body.charCodeAt(pos + 1) === 46 && body.charCodeAt(pos + 2) === 46) {
return new Token(TokenKind.SPREAD, pos, pos + 3, line, col, prev);
}
break;
// :
case 58:
return new Token(TokenKind.COLON, pos, pos + 1, line, col, prev);
// =
case 61:
return new Token(TokenKind.EQUALS, pos, pos + 1, line, col, prev);
// @
case 64:
return new Token(TokenKind.AT, pos, pos + 1, line, col, prev);
// [
case 91:
return new Token(TokenKind.BRACKET_L, pos, pos + 1, line, col, prev);
// ]
case 93:
return new Token(TokenKind.BRACKET_R, pos, pos + 1, line, col, prev);
// {
case 123:
return new Token(TokenKind.BRACE_L, pos, pos + 1, line, col, prev);
// |
case 124:
return new Token(TokenKind.PIPE, pos, pos + 1, line, col, prev);
// }
case 125:
return new Token(TokenKind.BRACE_R, pos, pos + 1, line, col, prev);
// A-Z _ a-z
case 65:
case 66:
case 67:
case 68:
case 69:
case 70:
case 71:
case 72:
case 73:
case 74:
case 75:
case 76:
case 77:
case 78:
case 79:
case 80:
case 81:
case 82:
case 83:
case 84:
case 85:
case 86:
case 87:
case 88:
case 89:
case 90:
case 95:
case 97:
case 98:
case 99:
case 100:
case 101:
case 102:
case 103:
case 104:
case 105:
case 106:
case 107:
case 108:
case 109:
case 110:
case 111:
case 112:
case 113:
case 114:
case 115:
case 116:
case 117:
case 118:
case 119:
case 120:
case 121:
case 122:
return readName(source, pos, line, col, prev);
// - 0-9
case 45:
case 48:
case 49:
case 50:
case 51:
case 52:
case 53:
case 54:
case 55:
case 56:
case 57:
return readNumber(source, pos, code, line, col, prev);
// "
case 34:
if (body.charCodeAt(pos + 1) === 34 && body.charCodeAt(pos + 2) === 34) {
return readBlockString(source, pos, line, col, prev, lexer);
}
return readString(source, pos, line, col, prev);
}
throw syntaxError(source, pos, unexpectedCharacterMessage(code));
}
/**
* Report a message that an unexpected character was encountered.
*/
function unexpectedCharacterMessage(code) {
if (code < 0x0020 && code !== 0x0009 && code !== 0x000a && code !== 0x000d) {
return `Cannot contain the invalid character ${printCharCode(code)}.`;
}
if (code === 39) {
// '
return 'Unexpected single quote character (\'), did you mean to use a double quote (")?';
}
return `Cannot parse the unexpected character ${printCharCode(code)}.`;
}
/**
* Reads from body starting at startPosition until it finds a non-whitespace
* character, then returns the position of that character for lexing.
*/
function positionAfterWhitespace(
body: string,
startPosition: number,
lexer: Lexer,
): number {
const bodyLength = body.length;
let position = startPosition;
while (position < bodyLength) {
const code = body.charCodeAt(position);
// tab | space | comma | BOM
if (code === 9 || code === 32 || code === 44 || code === 0xfeff) {
++position;
} else if (code === 10) {
// new line
++position;
++lexer.line;
lexer.lineStart = position;
} else if (code === 13) {
// carriage return
if (body.charCodeAt(position + 1) === 10) {
position += 2;
} else {
++position;
}
++lexer.line;
lexer.lineStart = position;
} else {
break;
}
}
return position;
}
/**
* Reads a comment token from the source file.
*
* #[\u0009\u0020-\uFFFF]*
*/
function readComment(source, start, line, col, prev): Token {
const body = source.body;
let code;
let position = start;
do {
code = body.charCodeAt(++position);
} while (
!isNaN(code) &&
// SourceCharacter but not LineTerminator
(code > 0x001f || code === 0x0009)
);
return new Token(
TokenKind.COMMENT,
start,
position,
line,
col,
prev,
body.slice(start + 1, position),
);
}
/**
* Reads a number token from the source file, either a float
* or an int depending on whether a decimal point appears.
*
* Int: -?(0|[1-9][0-9]*)
* Float: -?(0|[1-9][0-9]*)(\.[0-9]+)?((E|e)(+|-)?[0-9]+)?
*/
function readNumber(source, start, firstCode, line, col, prev): Token {
const body = source.body;
let code = firstCode;
let position = start;
let isFloat = false;
if (code === 45) {
// -
code = body.charCodeAt(++position);
}
if (code === 48) {
// 0
code = body.charCodeAt(++position);
if (code >= 48 && code <= 57) {
throw syntaxError(
source,
position,
`Invalid number, unexpected digit after 0: ${printCharCode(code)}.`,
);
}
} else {
position = readDigits(source, position, code);
code = body.charCodeAt(position);
}
if (code === 46) {
// .
isFloat = true;
code = body.charCodeAt(++position);
position = readDigits(source, position, code);
code = body.charCodeAt(position);
}
if (code === 69 || code === 101) {
// E e
isFloat = true;
code = body.charCodeAt(++position);
if (code === 43 || code === 45) {
// + -
code = body.charCodeAt(++position);
}
position = readDigits(source, position, code);
code = body.charCodeAt(position);
}
// Numbers cannot be followed by . or NameStart
if (code === 46 || isNameStart(code)) {
throw syntaxError(
source,
position,
`Invalid number, expected digit but got: ${printCharCode(code)}.`,
);
}
return new Token(
isFloat ? TokenKind.FLOAT : TokenKind.INT,
start,
position,
line,
col,
prev,
body.slice(start, position),
);
}
/**
* Returns the new position in the source after reading digits.
*/
function readDigits(source, start, firstCode) {
const body = source.body;
let position = start;
let code = firstCode;
if (code >= 48 && code <= 57) {
// 0 - 9
do {
code = body.charCodeAt(++position);
} while (code >= 48 && code <= 57); // 0 - 9
return position;
}
throw syntaxError(
source,
position,
`Invalid number, expected digit but got: ${printCharCode(code)}.`,
);
}
/**
* Reads a string token from the source file.
*
* "([^"\\\u000A\u000D]|(\\(u[0-9a-fA-F]{4}|["\\/bfnrt])))*"
*/
function readString(source, start, line, col, prev): Token {
const body = source.body;
let position = start + 1;
let chunkStart = position;
let code = 0;
let value = '';
while (
position < body.length &&
!isNaN((code = body.charCodeAt(position))) &&
// not LineTerminator
code !== 0x000a &&
code !== 0x000d
) {
// Closing Quote (")
if (code === 34) {
value += body.slice(chunkStart, position);
return new Token(
TokenKind.STRING,
start,
position + 1,
line,
col,
prev,
value,
);
}
// SourceCharacter
if (code < 0x0020 && code !== 0x0009) {
throw syntaxError(
source,
position,
`Invalid character within String: ${printCharCode(code)}.`,
);
}
++position;
if (code === 92) {
// \
value += body.slice(chunkStart, position - 1);
code = body.charCodeAt(position);
switch (code) {
case 34:
value += '"';
break;
case 47:
value += '/';
break;
case 92:
value += '\\';
break;
case 98:
value += '\b';
break;
case 102:
value += '\f';
break;
case 110:
value += '\n';
break;
case 114:
value += '\r';
break;
case 116:
value += '\t';
break;
case 117: {
// uXXXX
const charCode = uniCharCode(
body.charCodeAt(position + 1),
body.charCodeAt(position + 2),
body.charCodeAt(position + 3),
body.charCodeAt(position + 4),
);
if (charCode < 0) {
const invalidSequence = body.slice(position + 1, position + 5);
throw syntaxError(
source,
position,
`Invalid character escape sequence: \\u${invalidSequence}.`,
);
}
value += String.fromCharCode(charCode);
position += 4;
break;
}
default:
throw syntaxError(
source,
position,
`Invalid character escape sequence: \\${String.fromCharCode(
code,
)}.`,
);
}
++position;
chunkStart = position;
}
}
throw syntaxError(source, position, 'Unterminated string.');
}
/**
* Reads a block string token from the source file.
*
* """("?"?(\\"""|\\(?!=""")|[^"\\]))*"""
*/
function readBlockString(source, start, line, col, prev, lexer): Token {
const body = source.body;
let position = start + 3;
let chunkStart = position;
let code = 0;
let rawValue = '';
while (position < body.length && !isNaN((code = body.charCodeAt(position)))) {
// Closing Triple-Quote (""")
if (
code === 34 &&
body.charCodeAt(position + 1) === 34 &&
body.charCodeAt(position + 2) === 34
) {
rawValue += body.slice(chunkStart, position);
return new Token(
TokenKind.BLOCK_STRING,
start,
position + 3,
line,
col,
prev,
dedentBlockStringValue(rawValue),
);
}
// SourceCharacter
if (
code < 0x0020 &&
code !== 0x0009 &&
code !== 0x000a &&
code !== 0x000d
) {
throw syntaxError(
source,
position,
`Invalid character within String: ${printCharCode(code)}.`,
);
}
if (code === 10) {
// new line
++position;
++lexer.line;
lexer.lineStart = position;
} else if (code === 13) {
// carriage return
if (body.charCodeAt(position + 1) === 10) {
position += 2;
} else {
++position;
}
++lexer.line;
lexer.lineStart = position;
} else if (
// Escape Triple-Quote (\""")
code === 92 &&
body.charCodeAt(position + 1) === 34 &&
body.charCodeAt(position + 2) === 34 &&
body.charCodeAt(position + 3) === 34
) {
rawValue += body.slice(chunkStart, position) + '"""';
position += 4;
chunkStart = position;
} else {
++position;
}
}
throw syntaxError(source, position, 'Unterminated string.');
}
/**
* Converts four hexadecimal chars to the integer that the
* string represents. For example, uniCharCode('0','0','0','f')
* will return 15, and uniCharCode('0','0','f','f') returns 255.
*
* Returns a negative number on error, if a char was invalid.
*
* This is implemented by noting that char2hex() returns -1 on error,
* which means the result of ORing the char2hex() will also be negative.
*/
function uniCharCode(a, b, c, d) {
return (
(char2hex(a) << 12) | (char2hex(b) << 8) | (char2hex(c) << 4) | char2hex(d)
);
}
/**
* Converts a hex character to its integer value.
* '0' becomes 0, '9' becomes 9
* 'A' becomes 10, 'F' becomes 15
* 'a' becomes 10, 'f' becomes 15
*
* Returns -1 on error.
*/
function char2hex(a) {
return a >= 48 && a <= 57
? a - 48 // 0-9
: a >= 65 && a <= 70
? a - 55 // A-F
: a >= 97 && a <= 102
? a - 87 // a-f
: -1;
}
/**
* Reads an alphanumeric + underscore name from the source.
*
* [_A-Za-z][_0-9A-Za-z]*
*/
function readName(source, start, line, col, prev): Token {
const body = source.body;
const bodyLength = body.length;
let position = start + 1;
let code = 0;
while (
position !== bodyLength &&
!isNaN((code = body.charCodeAt(position))) &&
(code === 95 || // _
(code >= 48 && code <= 57) || // 0-9
(code >= 65 && code <= 90) || // A-Z
(code >= 97 && code <= 122)) // a-z
) {
++position;
}
return new Token(
TokenKind.NAME,
start,
position,
line,
col,
prev,
body.slice(start, position),
);
}
// _ A-Z a-z
function isNameStart(code): boolean {
return (
code === 95 || (code >= 65 && code <= 90) || (code >= 97 && code <= 122)
);
}