site/node_modules/mathjax-full/ts/input/tex/physics/PhysicsMethods.ts

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/*************************************************************
*
* Copyright (c) 2018-2022 The MathJax Consortium
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/**
* @fileoverview Methods for TeX parsing of the physics package.
*
* @author v.sorge@mathjax.org (Volker Sorge)
*/
import {ParseMethod} from '../Types.js';
import BaseMethods from '../base/BaseMethods.js';
import TexParser from '../TexParser.js';
import TexError from '../TexError.js';
import {TEXCLASS, MmlNode} from '../../../core/MmlTree/MmlNode.js';
import ParseUtil from '../ParseUtil.js';
import NodeUtil from '../NodeUtil.js';
import {NodeFactory} from '../NodeFactory.js';
import {Macro} from '../Symbol.js';
let PhysicsMethods: Record<string, ParseMethod> = {};
/***********************
* Physics package section 2.1
* Automatic bracing
*/
/**
* Pairs open and closed fences.
* @type {{[fence: string]: string}}
*/
const pairs: {[fence: string]: string} = {
'(': ')',
'[': ']',
'{': '}',
'|': '|',
};
/**
* Regular expression for matching big fence arguments.
* @type {RegExp}
*/
const biggs: RegExp = /^(b|B)i(g{1,2})$/;
/**
* Automatic sizing of fences, e.g., \\qty(x). Some with content.
* @param {TexParser} parser The calling parser.
* @param {string} name The macro name.
* @param {string=} open Opening fence.
* @param {string=} close Closing fence.
* @param {boolean=} arg Fences contain an argument.
* @param {string=} named Name operator.
* @param {string=} variant A font for the mathvariant.
*/
PhysicsMethods.Quantity = function(parser: TexParser, name: string,
open: string = '(', close: string = ')',
arg: boolean = false, named: string = '',
variant: string = '') {
let star = arg ? parser.GetStar() : false;
let next = parser.GetNext();
let position = parser.i;
let big = null;
if (next === '\\') {
parser.i++;
big = parser.GetCS();
if (!big.match(biggs)) {
// empty
let empty = parser.create('node', 'mrow');
parser.Push(ParseUtil.fenced(parser.configuration, open, empty, close));
parser.i = position;
return;
}
next = parser.GetNext();
}
let right = pairs[next];
if (arg && next !== '{') {
throw new TexError('MissingArgFor', 'Missing argument for %1', parser.currentCS);
}
if (!right) {
let empty = parser.create('node', 'mrow');
parser.Push(ParseUtil.fenced(parser.configuration, open, empty, close));
parser.i = position;
return;
}
// Get the fences
if (named) {
const mml = parser.create('token', 'mi', {texClass: TEXCLASS.OP}, named);
if (variant) {
NodeUtil.setAttribute(mml, 'mathvariant', variant);
}
parser.Push(parser.itemFactory.create('fn', mml));
}
if (next === '{') {
let argument = parser.GetArgument(name);
next = arg ? open : '\\{';
right = arg ? close : '\\}';
// TODO: Make all these fenced expressions.
argument = star ? next + ' ' + argument + ' ' + right :
(big ?
'\\' + big + 'l' + next + ' ' + argument + ' ' + '\\' + big + 'r' + right :
'\\left' + next + ' ' + argument + ' ' + '\\right' + right);
parser.Push(new TexParser(argument, parser.stack.env,
parser.configuration).mml());
return;
}
if (arg) {
next = open;
right = close;
}
parser.i++;
parser.Push(parser.itemFactory.create('auto open')
.setProperties({open: next, close: right, big: big}));
};
/**
* The evaluate macro.
* @param {TexParser} parser The calling parser.
* @param {string} name The macro name.
*/
PhysicsMethods.Eval = function(parser: TexParser, name: string) {
let star = parser.GetStar();
let next = parser.GetNext();
if (next === '{') {
let arg = parser.GetArgument(name);
let replace = '\\left. ' +
(star ? '\\smash{' + arg + '}' : arg) +
' ' + '\\vphantom{\\int}\\right|';
parser.string = parser.string.slice(0, parser.i) + replace +
parser.string.slice(parser.i);
return;
}
if (next === '(' || next === '[') {
parser.i++;
parser.Push(parser.itemFactory.create('auto open')
.setProperties(
{open: next, close: '|',
smash: star, right: '\\vphantom{\\int}'}));
return;
}
throw new TexError('MissingArgFor', 'Missing argument for %1', parser.currentCS);
};
/**
* The anti/commutator and poisson macros.
* @param {TexParser} parser The calling parser.
* @param {string} name The macro name.
* @param {string=} open Opening fence.
* @param {string=} close Closing fence.
*/
PhysicsMethods.Commutator = function(parser: TexParser, name: string,
open: string = '[', close: string = ']') {
let star = parser.GetStar();
let next = parser.GetNext();
let big = null;
if (next === '\\') {
parser.i++;
big = parser.GetCS();
if (!big.match(biggs)) {
// Actually a commutator error arg1 error.
throw new TexError('MissingArgFor', 'Missing argument for %1', parser.currentCS);
}
next = parser.GetNext();
}
if (next !== '{') {
throw new TexError('MissingArgFor', 'Missing argument for %1', parser.currentCS);
}
let arg1 = parser.GetArgument(name);
let arg2 = parser.GetArgument(name);
let argument = arg1 + ',' + arg2;
argument = star ? open + ' ' + argument + ' ' + close :
(big ?
'\\' + big + 'l' + open + ' ' + argument + ' ' + '\\' + big + 'r' + close :
'\\left' + open + ' ' + argument + ' ' + '\\right' + close);
parser.Push(new TexParser(argument, parser.stack.env,
parser.configuration).mml());
};
/***********************
* Physics package section 2.2
* Vector notation
*/
let latinCap: [number, number] = [0x41, 0x5A];
let latinSmall: [number, number] = [0x61, 0x7A];
let greekCap: [number, number] = [0x391, 0x3A9];
let greekSmall: [number, number] = [0x3B1, 0x3C9];
let digits: [number, number] = [0x30, 0x39];
/**
* Checks if a value is in a given numerical interval.
* @param {number} value The value.
* @param {[number, number]} range The closed interval.
*/
function inRange(value: number, range: [number, number]) {
return (value >= range[0] && value <= range[1]);
}
/**
* Method to create a token for the vector commands. It creates a vector token
* with the specific vector font (e.g., bold) in case it is a Latin or capital
* Greek character, accent or small Greek character if command is starred. This
* is a replacement for the original token method in the node factory.
* @param {NodeFactory} factory The current node factory.
* @param {string} kind The type of token to create.
* @param {any} def The attributes for the node.
* @param {string} text The text contained in the token node.
* @return {MmlNode} The newly create token node.
*/
function createVectorToken(factory: NodeFactory, kind: string,
def: any, text: string): MmlNode {
let parser = factory.configuration.parser;
let token = NodeFactory.createToken(factory, kind, def, text);
let code: number = text.codePointAt(0);
if (text.length === 1 && !parser.stack.env.font &&
parser.stack.env.vectorFont &&
(inRange(code, latinCap) || inRange(code, latinSmall) ||
inRange(code, greekCap) || inRange(code, digits) ||
(inRange(code, greekSmall) && parser.stack.env.vectorStar) ||
NodeUtil.getAttribute(token, 'accent'))) {
NodeUtil.setAttribute(token, 'mathvariant', parser.stack.env.vectorFont);
}
return token;
}
/**
* Bold vector notation.
* @param {TexParser} parser The calling parser.
* @param {string} name The macro name.
*/
PhysicsMethods.VectorBold = function(parser: TexParser, name: string) {
let star = parser.GetStar();
let arg = parser.GetArgument(name);
let oldToken = parser.configuration.nodeFactory.get('token');
let oldFont = parser.stack.env.font;
delete parser.stack.env.font;
parser.configuration.nodeFactory.set('token', createVectorToken);
parser.stack.env.vectorFont = star ? 'bold-italic' : 'bold';
parser.stack.env.vectorStar = star;
let node = new TexParser(arg, parser.stack.env, parser.configuration).mml();
if (oldFont) {
parser.stack.env.font = oldFont;
}
delete parser.stack.env.vectorFont;
delete parser.stack.env.vectorStar;
parser.configuration.nodeFactory.set('token', oldToken);
parser.Push(node);
};
/**
* Macros that can have an optional star which is propagated.
* @param {TexParser} parser The calling parser.
* @param {string} name The macro name.
* @param {number} argcount Number of arguments.
* @param {string[]} ...parts List of parts from which to assemble the macro.
* If the original command is starred, a star will be injected at each part.
*/
PhysicsMethods.StarMacro = function(parser: TexParser, name: string,
argcount: number, ...parts: string[]) {
let star = parser.GetStar();
const args: string[] = [];
if (argcount) {
for (let i = args.length; i < argcount; i++) {
args.push(parser.GetArgument(name));
}
}
let macro = parts.join(star ? '*' : '');
macro = ParseUtil.substituteArgs(parser, args, macro);
parser.string = ParseUtil.addArgs(parser, macro, parser.string.slice(parser.i));
parser.i = 0;
ParseUtil.checkMaxMacros(parser);
};
/**
* Computes the application of a vector operation.
* @param {TexParser} parser The calling parser.
* @param {string} kind The type of stack item to parse the operator into.
* @param {string} name The macro name.
* @param {string} operator The operator expression.
* @param {string[]} ...fences List of opening fences that should be
* automatically sized and paired to its corresponding closing fence.
*/
let vectorApplication = function(
parser: TexParser, kind: string, name: string, operator: string,
fences: string[]) {
let op = new TexParser(operator, parser.stack.env,
parser.configuration).mml();
parser.Push(parser.itemFactory.create(kind, op));
let left = parser.GetNext();
let right = pairs[left];
if (!right) {
return;
}
let lfence = '', rfence = '', arg = '';
let enlarge = fences.indexOf(left) !== -1;
if (left === '{') {
arg = parser.GetArgument(name);
lfence = enlarge ? '\\left\\{' : '';
rfence = enlarge ? '\\right\\}' : '';
let macro = lfence + ' ' + arg + ' ' + rfence;
parser.string = macro + parser.string.slice(parser.i);
parser.i = 0;
return;
}
if (!enlarge) {
return;
}
parser.i++;
parser.Push(parser.itemFactory.create('auto open')
.setProperties({open: left, close: right}));
};
/**
* An operator that needs to be parsed (e.g., a Greek letter or nabla) and
* applied to a possibly fenced expression. By default automatic fences are
* parentheses and brakets, with braces being ignored.
* @param {TexParser} parser The calling parser.
* @param {string} name The macro name.
* @param {string} operator The operator expression.
* @param {string[]} ...fences List of opening fences that should be
* automatically sized and paired to its corresponding closing fence.
*/
PhysicsMethods.OperatorApplication = function(
parser: TexParser, name: string, operator: string,
...fences: string[]) {
vectorApplication(parser, 'fn', name, operator, fences);
};
/**
* A vector operator that needs to be parsed (e.g., a Greek letter or nabla with
* a crossproduct) and connected to a possibly fenced expression. By default
* automatic fences are parentheses and brakets.
* @param {TexParser} parser The calling parser.
* @param {string} name The macro name.
* @param {string} operator The operator expression.
* @param {string[]} ...fences List of opening fences that should be
* automatically sized and paired to its corresponding closing fence.
*/
PhysicsMethods.VectorOperator = function(
parser: TexParser, name: string, operator: string,
...fences: string[]) {
vectorApplication(parser, 'mml', name, operator, fences);
};
/***********************
* Physics package section 2.3
* Operators
*/
/**
* Operator expression with automatic fences and optional exponent.
* @param {TexParser} parser The calling parser.
* @param {string} name The macro name.
* @param {boolean=} opt Set to false if no optional exponent is allowed.
* @param {string=} id The name of the function if different from name.
*/
PhysicsMethods.Expression = function(parser: TexParser, name: string,
opt: boolean = true, id: string = '') {
id = id || name.slice(1);
const exp = opt ? parser.GetBrackets(name) : null;
let mml = parser.create('token', 'mi', {texClass: TEXCLASS.OP}, id);
if (exp) {
const sup = new TexParser(exp,
parser.stack.env, parser.configuration).mml();
mml = parser.create('node', 'msup', [mml, sup]);
}
parser.Push(parser.itemFactory.create('fn', mml));
if (parser.GetNext() !== '(') {
return;
}
parser.i++;
parser.Push(parser.itemFactory.create('auto open')
.setProperties({open: '(', close: ')'}));
};
/***********************
* Physics package section 2.4
* Quick quad text
*/
/**
* Quad text macros.
* @param {TexParser} parser The calling parser.
* @param {string} name The macro name.
* @param {string} text The text that is to be padded with quad spaces.
*/
PhysicsMethods.Qqtext = function(parser: TexParser, name: string,
text: string) {
let star = parser.GetStar();
let arg = text ? text : parser.GetArgument(name);
let replace = (star ? '' : '\\quad') + '\\text{' + arg + '}\\quad ';
parser.string = parser.string.slice(0, parser.i) + replace +
parser.string.slice(parser.i);
};
/***********************
* Physics package section 2.5
* Derivatives
*/
/**
* The differential and variation macros.
* @param {TexParser} parser The calling parser.
* @param {string} name The macro name.
* @param {string} op The operator. It will be parsed.
*/
PhysicsMethods.Differential = function(parser: TexParser, name: string,
op: string) {
const optArg = parser.GetBrackets(name);
const power = optArg != null ? '^{' + optArg + '}' : ' ';
const parens = parser.GetNext() === '(';
const braces = parser.GetNext() === '{';
let macro = op + power;
if (!(parens || braces)) {
macro += parser.GetArgument(name, true) || '';
let mml = new TexParser(macro, parser.stack.env,
parser.configuration).mml();
parser.Push(mml);
return;
}
if (braces) {
macro += parser.GetArgument(name);
const mml = new TexParser(macro, parser.stack.env,
parser.configuration).mml();
parser.Push(parser.create('node', 'TeXAtom', [mml], {texClass: TEXCLASS.OP}));
return;
}
parser.Push(new TexParser(macro, parser.stack.env,
parser.configuration).mml());
parser.i++;
parser.Push(parser.itemFactory.create('auto open')
.setProperties({open: '(', close: ')'}));
};
/**
* The derivative macro. Its behaviour depends on the number of arguments
* provided. In case of
* 1 argument: will be part of the denominator.
* 2 arguments: argument one is numerator, argument two is denominator.
* 3+ arguments: arguments above 2 will be part of the denominator and the
* exponent of the enumerator will depend on the number of denominator
* arguments. In particular, the optional exponent argument will be ignored!
* @param {TexParser} parser The calling parser.
* @param {string} name The macro name.
* @param {number} argMax The maximum number of arguments for the macro.
* @param {string} op The derivative operator.
*/
PhysicsMethods.Derivative = function(parser: TexParser, name: string,
argMax: number, op: string) {
const star = parser.GetStar();
const optArg = parser.GetBrackets(name);
let argCounter = 1;
const args = [];
args.push(parser.GetArgument(name));
while (parser.GetNext() === '{' && argCounter < argMax) {
args.push(parser.GetArgument(name));
argCounter++;
}
let ignore = false;
let power1 = ' ';
let power2 = ' ';
if (argMax > 2 && args.length > 2) {
power1 = '^{' + (args.length - 1) + '}';
ignore = true;
} else if (optArg != null) {
if (argMax > 2 && args.length > 1) {
ignore = true;
}
power1 = '^{' + optArg + '}';
power2 = power1;
}
const frac = star ? '\\flatfrac' : '\\frac';
const first = args.length > 1 ? args[0] : '';
const second = args.length > 1 ? args[1] : args[0];
let rest = '';
for (let i = 2, arg; arg = args[i]; i++) {
rest += op + ' ' + arg;
}
const macro = frac + '{' + op + power1 + first + '}' +
'{' + op + ' ' + second + power2 + ' ' + rest + '}';
parser.Push(new TexParser(macro, parser.stack.env,
parser.configuration).mml());
if (parser.GetNext() === '(') {
parser.i++;
parser.Push(parser.itemFactory.create('auto open')
.setProperties({open: '(', close: ')', ignore: ignore}));
}
};
/***********************
* Physics package section 2.6
* Dirac bra-ket notation
*/
/**
* The bra macro.
* @param {TexParser} parser The calling parser.
* @param {string} name The macro name.
*/
PhysicsMethods.Bra = function(parser: TexParser, name: string) {
let starBra = parser.GetStar();
let bra = parser.GetArgument(name);
let ket = '';
let hasKet = false;
let starKet = false;
if (parser.GetNext() === '\\') {
let saveI = parser.i;
parser.i++;
// This ensures that bra-ket also works if \let bound versions of \ket.
let cs = parser.GetCS();
let symbol = parser.lookup('macro', cs) as Macro;
if (symbol && symbol.symbol === 'ket') {
hasKet = true;
saveI = parser.i;
starKet = parser.GetStar();
if (parser.GetNext() === '{') {
ket = parser.GetArgument(cs, true);
} else {
parser.i = saveI;
starKet = false;
}
} else {
parser.i = saveI;
}
}
let macro = '';
if (hasKet) {
macro = (starBra || starKet) ?
`\\langle{${bra}}\\vert{${ket}}\\rangle` :
`\\left\\langle{${bra}}\\middle\\vert{${ket}}\\right\\rangle`;
} else {
macro = (starBra || starKet) ?
`\\langle{${bra}}\\vert` : `\\left\\langle{${bra}}\\right\\vert{${ket}}`;
}
parser.Push(new TexParser(macro, parser.stack.env,
parser.configuration).mml());
};
/**
* The ket macro.
* @param {TexParser} parser The calling parser.
* @param {string} name The macro name.
*/
PhysicsMethods.Ket = function(parser: TexParser, name: string) {
let star = parser.GetStar();
let ket = parser.GetArgument(name);
let macro = star ? `\\vert{${ket}}\\rangle` :
`\\left\\vert{${ket}}\\right\\rangle`;
parser.Push(new TexParser(macro, parser.stack.env,
parser.configuration).mml());
};
/**
* The braket macro.
* @param {TexParser} parser The calling parser.
* @param {string} name The macro name.
*/
PhysicsMethods.BraKet = function(parser: TexParser, name: string) {
let star = parser.GetStar();
let bra = parser.GetArgument(name);
let ket = null;
if (parser.GetNext() === '{') {
ket = parser.GetArgument(name, true);
}
let macro = '';
if (ket == null) {
macro = star ?
`\\langle{${bra}}\\vert{${bra}}\\rangle` :
`\\left\\langle{${bra}}\\middle\\vert{${bra}}\\right\\rangle`;
} else {
macro = star ?
`\\langle{${bra}}\\vert{${ket}}\\rangle` :
`\\left\\langle{${bra}}\\middle\\vert{${ket}}\\right\\rangle`;
}
parser.Push(new TexParser(macro, parser.stack.env,
parser.configuration).mml());
};
/**
* The ketbra macro.
* @param {TexParser} parser The calling parser.
* @param {string} name The macro name.
*/
PhysicsMethods.KetBra = function(parser: TexParser, name: string) {
let star = parser.GetStar();
let ket = parser.GetArgument(name);
let bra = null;
if (parser.GetNext() === '{') {
bra = parser.GetArgument(name, true);
}
let macro = '';
if (bra == null) {
macro = star ?
`\\vert{${ket}}\\rangle\\!\\langle{${ket}}\\vert` :
`\\left\\vert{${ket}}\\middle\\rangle\\!\\middle\\langle{${ket}}\\right\\vert`;
} else {
macro = star ?
`\\vert{${ket}}\\rangle\\!\\langle{${bra}}\\vert` :
`\\left\\vert{${ket}}\\middle\\rangle\\!\\middle\\langle{${bra}}\\right\\vert`;
}
parser.Push(new TexParser(macro, parser.stack.env,
parser.configuration).mml());
};
/**
* Generates the expanded braket LaTeX code for matrix operations.
* @param {[string, string, string]} [arg1, arg2, arg3] The three arguments
* <arg1|arg2|arg3>.
* @param {boolean} star1 No automatic sizing of fences.
* @param {boolean} star2 Automatic sizing of fences wrt. to arg1 & arg3 only.
*/
function outputBraket([arg1, arg2, arg3]: [string, string, string],
star1: boolean, star2: boolean) {
return (star1 && star2) ?
`\\left\\langle{${arg1}}\\middle\\vert{${arg2}}\\middle\\vert{${arg3}}\\right\\rangle` :
(star1 ? `\\langle{${arg1}}\\vert{${arg2}}\\vert{${arg3}}\\rangle` :
`\\left\\langle{${arg1}}\\right\\vert{${arg2}}\\left\\vert{${arg3}}\\right\\rangle`);
}
/**
* The expectation value macro.
* @param {TexParser} parser The calling parser.
* @param {string} name The macro name.
*/
PhysicsMethods.Expectation = function(parser: TexParser, name: string) {
let star1 = parser.GetStar();
let star2 = star1 && parser.GetStar();
let arg1 = parser.GetArgument(name);
let arg2 = null;
if (parser.GetNext() === '{') {
arg2 = parser.GetArgument(name, true);
}
let macro = (arg1 && arg2) ?
outputBraket([arg2, arg1, arg2], star1, star2) :
// Braces for semantics, similar to braket package.
(star1 ? `\\langle {${arg1}} \\rangle` :
`\\left\\langle {${arg1}} \\right\\rangle`);
parser.Push(new TexParser(macro, parser.stack.env,
parser.configuration).mml());
};
/**
* The matrix element macro.
* @param {TexParser} parser The calling parser.
* @param {string} name The macro name.
*/
PhysicsMethods.MatrixElement = function(parser: TexParser, name: string) {
const star1 = parser.GetStar();
const star2 = star1 && parser.GetStar();
const arg1 = parser.GetArgument(name);
const arg2 = parser.GetArgument(name);
const arg3 = parser.GetArgument(name);
const macro = outputBraket([arg1, arg2, arg3], star1, star2);
parser.Push(new TexParser(macro, parser.stack.env,
parser.configuration).mml());
};
/********************
* Physics package Section 2.7
* Matrix macros
*/
/**
* The matrix quantity macro.
* @param {TexParser} parser The calling parser.
* @param {string} name The macro name.
* @param {boolean=} small Use small matrix.
*/
PhysicsMethods.MatrixQuantity = function(parser: TexParser, name: string, small?: boolean) {
const star = parser.GetStar();
const next = parser.GetNext();
const array = small ? 'smallmatrix' : 'array';
let arg = '';
let open = '';
let close = '';
switch (next) {
case '{':
arg = parser.GetArgument(name);
break;
case '(':
parser.i++;
open = star ? '\\lgroup' : '(';
close = star ? '\\rgroup' : ')';
arg = parser.GetUpTo(name, ')');
break;
case '[':
parser.i++;
open = '[';
close = ']';
arg = parser.GetUpTo(name, ']');
break;
case '|':
parser.i++;
open = '|';
close = '|';
arg = parser.GetUpTo(name, '|');
break;
default:
open = '(';
close = ')';
break;
}
const macro = (open ? '\\left' : '') + open +
'\\begin{' + array + '}{} ' + arg + '\\end{' + array + '}' +
(open ? '\\right' : '') + close;
parser.Push(new TexParser(macro, parser.stack.env,
parser.configuration).mml());
};
/**
* Generation of identity matrices.
* @param {TexParser} parser The calling parser.
* @param {string} name The macro name.
*/
PhysicsMethods.IdentityMatrix = function(parser: TexParser, name: string) {
const arg = parser.GetArgument(name);
const size = parseInt(arg, 10);
if (isNaN(size)) {
throw new TexError('InvalidNumber', 'Invalid number');
}
if (size <= 1) {
parser.string = '1' + parser.string.slice(parser.i);
parser.i = 0;
return;
}
let zeros = Array(size).fill('0');
let columns = [];
for (let i = 0; i < size; i++) {
let row = zeros.slice();
row[i] = '1';
columns.push(row.join(' & '));
}
parser.string = columns.join('\\\\ ') + parser.string.slice(parser.i);
parser.i = 0;
};
/**
* Generation of matrices with fixed value.
* @param {TexParser} parser The calling parser.
* @param {string} name The macro name.
*/
PhysicsMethods.XMatrix = function(parser: TexParser, name: string) {
const star = parser.GetStar();
const arg1 = parser.GetArgument(name);
const arg2 = parser.GetArgument(name);
const arg3 = parser.GetArgument(name);
let n = parseInt(arg2, 10);
let m = parseInt(arg3, 10);
if (isNaN(n) || isNaN(m) || m.toString() !== arg3 || n.toString() !== arg2) {
throw new TexError('InvalidNumber', 'Invalid number');
}
n = n < 1 ? 1 : n;
m = m < 1 ? 1 : m;
// Elements
if (!star) {
const row = Array(m).fill(arg1).join(' & ');
const matrix = Array(n).fill(row).join('\\\\ ');
parser.string = matrix + parser.string.slice(parser.i);
parser.i = 0;
return;
}
let matrix = '';
if (n === 1 && m === 1) {
// Case 1: n=m=1, no index.
matrix = arg1;
} else if (n === 1) {
// Case 2: n=1, row vector, single index.
let row = [];
for (let i = 1; i <= m; i++) {
row.push(`${arg1}_{${i}}`);
}
matrix = row.join(' & ');
} else if (m === 1) {
// Case 3: m=1, column vector, single index.
let row = [];
for (let i = 1; i <= n; i++) {
row.push(`${arg1}_{${i}}`);
}
matrix = row.join('\\\\ ');
} else {
// Case 4: matrix, double index. Note the extra mrows for indices.
let rows = [];
for (let i = 1; i <= n; i++) {
let row = [];
for (let j = 1; j <= m; j++) {
row.push(`${arg1}_{{${i}}{${j}}}`);
}
rows.push(row.join(' & '));
}
matrix = rows.join('\\\\ ');
}
parser.string = matrix + parser.string.slice(parser.i);
parser.i = 0;
return;
};
/**
* Generation of Pauli matrices. Matrix 0 is the 2x2 identity.
* @param {TexParser} parser The calling parser.
* @param {string} name The macro name.
*/
PhysicsMethods.PauliMatrix = function(parser: TexParser, name: string) {
const arg = parser.GetArgument(name);
let matrix = arg.slice(1);
switch (arg[0]) {
case '0':
matrix += ' 1 & 0\\\\ 0 & 1';
break;
case '1':
case 'x':
matrix += ' 0 & 1\\\\ 1 & 0';
break;
case '2':
case 'y':
matrix += ' 0 & -i\\\\ i & 0';
break;
case '3':
case 'z':
matrix += ' 1 & 0\\\\ 0 & -1';
break;
default:
}
parser.string = matrix + parser.string.slice(parser.i);
parser.i = 0;
};
/**
* Generation of anti/diagonal matrices.
* @param {TexParser} parser The calling parser.
* @param {string} name The macro name.
* @param {boolean=} anti True if constructing anti-diagonal matrix.
*/
PhysicsMethods.DiagonalMatrix = function(parser: TexParser, name: string,
anti?: boolean) {
if (parser.GetNext() !== '{') {
return;
}
let startI = parser.i;
/* let arg =*/ parser.GetArgument(name);
let endI = parser.i;
parser.i = startI + 1;
let elements = [];
let element = '';
let currentI = parser.i;
while (currentI < endI) {
try {
element = parser.GetUpTo(name, ',');
} catch (e) {
parser.i = endI;
elements.push(parser.string.slice(currentI, endI - 1));
break;
}
if (parser.i >= endI) {
elements.push(parser.string.slice(currentI, endI));
break;
}
currentI = parser.i;
elements.push(element);
}
parser.string = makeDiagMatrix(elements, anti) + parser.string.slice(endI);
parser.i = 0;
};
/**
* Creates the a (anti)diagonal matrix string.
* @param {string[]} elements The elements on the diagonal.
* @param {boolean} anti True if constructing anti-diagonal matrix.
*/
function makeDiagMatrix(elements: string[], anti: boolean) {
let length = elements.length;
let matrix = [];
for (let i = 0; i < length; i++) {
matrix.push(Array(anti ? length - i : i + 1).join('&') +
'\\mqty{' + elements[i] + '}');
}
return matrix.join('\\\\ ');
}
/**
* Closes an automatic fence if one was opened.
* @param {TexParser} parser The calling parser.
* @param {string} fence The fence.
* @param {number} texclass The TeX class.
*/
PhysicsMethods.AutoClose = function(parser: TexParser, fence: string, _texclass: number) {
const mo = parser.create('token', 'mo', {stretchy: false}, fence);
const item = parser.itemFactory.create('mml', mo).
setProperties({autoclose: fence});
parser.Push(item);
};
/**
* Generates the vector nabla depending on the arrowdel option.
* @param {TexParser} parser The calling parser.
* @param {string} name The macro name.
*/
PhysicsMethods.Vnabla = function(parser: TexParser, _name: string) {
let argument = parser.options.physics.arrowdel ?
'\\vec{\\gradientnabla}' : '{\\gradientnabla}';
return parser.Push(new TexParser(argument, parser.stack.env,
parser.configuration).mml());
};
/**
* Generates the differential d depending on the italicdiff option.
* @param {TexParser} parser The calling parser.
* @param {string} name The macro name.
*/
PhysicsMethods.DiffD = function(parser: TexParser, _name: string) {
let argument = parser.options.physics.italicdiff ? 'd' : '{\\rm d}';
return parser.Push(new TexParser(argument, parser.stack.env,
parser.configuration).mml());
};
/**
* Methods taken from Base package.
*/
PhysicsMethods.Macro = BaseMethods.Macro;
PhysicsMethods.NamedFn = BaseMethods.NamedFn;
PhysicsMethods.Array = BaseMethods.Array;
export default PhysicsMethods;