LaTeX to CAS translator
This mockup demonstrates the concept of TeX to Computer Algebra System (CAS) conversion.
The demo-application converts LaTeX functions which directly translate to CAS counterparts.
Functions without explicit CAS support are available for translation via a DRMF package (under development).
The following LaTeX input ...
{\displaystyle \begin{Bmatrix} j_1 & j_2 & j_3\\ j_4 & j_5 & j_6 \end{Bmatrix} = \begin{Bmatrix} j_2 & j_1 & j_3\\ j_5 & j_4 & j_6 \end{Bmatrix} = \begin{Bmatrix} j_1 & j_3 & j_2\\ j_4 & j_6 & j_5 \end{Bmatrix} = \begin{Bmatrix} j_3 & j_2 & j_1\\ j_6 & j_5 & j_4 \end{Bmatrix} = \cdots }
... is translated to the CAS output ...
Semantic latex: \Wignersixjsym{j_1}{j_2}{j_3}{j_4}{j_5}{j_6} = \Wignersixjsym{j_2}{j_1}{j_3}{j_5}{j_4}{j_6} = \Wignersixjsym{j_1}{j_3}{j_2}{j_4}{j_6}{j_5} = \Wignersixjsym{j_3}{j_2}{j_1}{j_6}{j_5}{j_4} = \cdots
Confidence: 0.68720618419147
Mathematica
Translation: SixJSymbol[{Subscript[j, 1], Subscript[j, 2], Subscript[j, 3]}, {Subscript[j, 4], Subscript[j, 5], Subscript[j, 6]}] == SixJSymbol[{Subscript[j, 2], Subscript[j, 1], Subscript[j, 3]}, {Subscript[j, 5], Subscript[j, 4], Subscript[j, 6]}] == SixJSymbol[{Subscript[j, 1], Subscript[j, 3], Subscript[j, 2]}, {Subscript[j, 4], Subscript[j, 6], Subscript[j, 5]}] == SixJSymbol[{Subscript[j, 3], Subscript[j, 2], Subscript[j, 1]}, {Subscript[j, 6], Subscript[j, 5], Subscript[j, 4]}] == \[Ellipsis]
Information
Sub Equations
- SixJSymbol[{Subscript[j, 1], Subscript[j, 2], Subscript[j, 3]}, {Subscript[j, 4], Subscript[j, 5], Subscript[j, 6]}] = SixJSymbol[{Subscript[j, 2], Subscript[j, 1], Subscript[j, 3]}, {Subscript[j, 5], Subscript[j, 4], Subscript[j, 6]}]
- SixJSymbol[{Subscript[j, 2], Subscript[j, 1], Subscript[j, 3]}, {Subscript[j, 5], Subscript[j, 4], Subscript[j, 6]}] = SixJSymbol[{Subscript[j, 1], Subscript[j, 3], Subscript[j, 2]}, {Subscript[j, 4], Subscript[j, 6], Subscript[j, 5]}]
- SixJSymbol[{Subscript[j, 1], Subscript[j, 3], Subscript[j, 2]}, {Subscript[j, 4], Subscript[j, 6], Subscript[j, 5]}] = SixJSymbol[{Subscript[j, 3], Subscript[j, 2], Subscript[j, 1]}, {Subscript[j, 6], Subscript[j, 5], Subscript[j, 4]}]
- SixJSymbol[{Subscript[j, 3], Subscript[j, 2], Subscript[j, 1]}, {Subscript[j, 6], Subscript[j, 5], Subscript[j, 4]}] = \[Ellipsis]
Free variables
- Subscript[j, 1]
- Subscript[j, 2]
- Subscript[j, 3]
- Subscript[j, 4]
- Subscript[j, 5]
- Subscript[j, 6]
Symbol info
- 6j symbol; Example: \Wignersixjsym@@{j_{1}}{j_{2}}{j_{3}}{l_{1}}{l_{2}}{l_{3}}
Will be translated to: SixJSymbol[{$0, $1, $2}, {$3, $4, $5}] Relevant links to definitions: DLMF: http://dlmf.nist.gov/34.4#E1 Mathematica: https://reference.wolfram.com/language/ref/SixJSymbol.html
Tests
Symbolic
Numeric
SymPy
Translation:
Information
Symbol info
- (LaTeX -> SymPy) No translation possible for given token: Cannot extract information from feature set: \Wignersixjsym [\Wignersixjsym]
Tests
Symbolic
Numeric
Maple
Translation:
Information
Symbol info
- (LaTeX -> Maple) No translation possible for given token: Cannot extract information from feature set: \Wignersixjsym [\Wignersixjsym]
Tests
Symbolic
Numeric
Dependency Graph Information
Includes
Is part of
Complete translation information:
{
"id" : "FORMULA_c1ea7c65181ef5334ccec35239504824",
"formula" : "\\begin{Bmatrix}\n j_1 & j_2 & j_3\\\\\n j_4 & j_5 & j_6\n \\end{Bmatrix}\n =\n \\begin{Bmatrix}\n j_2 & j_1 & j_3\\\\\n j_5 & j_4 & j_6\n \\end{Bmatrix}\n=\n \\begin{Bmatrix}\n j_1 & j_3 & j_2\\\\\n j_4 & j_6 & j_5\n \\end{Bmatrix}\n=\n \\begin{Bmatrix}\n j_3 & j_2 & j_1\\\\\n j_6 & j_5 & j_4\n \\end{Bmatrix}\n= \\cdots",
"semanticFormula" : "\\Wignersixjsym{j_1}{j_2}{j_3}{j_4}{j_5}{j_6} = \\Wignersixjsym{j_2}{j_1}{j_3}{j_5}{j_4}{j_6} = \\Wignersixjsym{j_1}{j_3}{j_2}{j_4}{j_6}{j_5} = \\Wignersixjsym{j_3}{j_2}{j_1}{j_6}{j_5}{j_4} = \\cdots",
"confidence" : 0.687206184191471,
"translations" : {
"Mathematica" : {
"translation" : "SixJSymbol[{Subscript[j, 1], Subscript[j, 2], Subscript[j, 3]}, {Subscript[j, 4], Subscript[j, 5], Subscript[j, 6]}] == SixJSymbol[{Subscript[j, 2], Subscript[j, 1], Subscript[j, 3]}, {Subscript[j, 5], Subscript[j, 4], Subscript[j, 6]}] == SixJSymbol[{Subscript[j, 1], Subscript[j, 3], Subscript[j, 2]}, {Subscript[j, 4], Subscript[j, 6], Subscript[j, 5]}] == SixJSymbol[{Subscript[j, 3], Subscript[j, 2], Subscript[j, 1]}, {Subscript[j, 6], Subscript[j, 5], Subscript[j, 4]}] == \\[Ellipsis]",
"translationInformation" : {
"subEquations" : [ "SixJSymbol[{Subscript[j, 1], Subscript[j, 2], Subscript[j, 3]}, {Subscript[j, 4], Subscript[j, 5], Subscript[j, 6]}] = SixJSymbol[{Subscript[j, 2], Subscript[j, 1], Subscript[j, 3]}, {Subscript[j, 5], Subscript[j, 4], Subscript[j, 6]}]", "SixJSymbol[{Subscript[j, 2], Subscript[j, 1], Subscript[j, 3]}, {Subscript[j, 5], Subscript[j, 4], Subscript[j, 6]}] = SixJSymbol[{Subscript[j, 1], Subscript[j, 3], Subscript[j, 2]}, {Subscript[j, 4], Subscript[j, 6], Subscript[j, 5]}]", "SixJSymbol[{Subscript[j, 1], Subscript[j, 3], Subscript[j, 2]}, {Subscript[j, 4], Subscript[j, 6], Subscript[j, 5]}] = SixJSymbol[{Subscript[j, 3], Subscript[j, 2], Subscript[j, 1]}, {Subscript[j, 6], Subscript[j, 5], Subscript[j, 4]}]", "SixJSymbol[{Subscript[j, 3], Subscript[j, 2], Subscript[j, 1]}, {Subscript[j, 6], Subscript[j, 5], Subscript[j, 4]}] = \\[Ellipsis]" ],
"freeVariables" : [ "Subscript[j, 1]", "Subscript[j, 2]", "Subscript[j, 3]", "Subscript[j, 4]", "Subscript[j, 5]", "Subscript[j, 6]" ],
"tokenTranslations" : {
"\\Wignersixjsym" : "6j symbol; Example: \\Wignersixjsym@@{j_{1}}{j_{2}}{j_{3}}{l_{1}}{l_{2}}{l_{3}}\nWill be translated to: SixJSymbol[{$0, $1, $2}, {$3, $4, $5}]\nRelevant links to definitions:\nDLMF: http://dlmf.nist.gov/34.4#E1\nMathematica: https://reference.wolfram.com/language/ref/SixJSymbol.html"
}
},
"numericResults" : {
"overallResult" : "SKIPPED",
"numberOfTests" : 0,
"numberOfFailedTests" : 0,
"numberOfSuccessfulTests" : 0,
"numberOfSkippedTests" : 0,
"numberOfErrorTests" : 0,
"wasAborted" : false,
"crashed" : false,
"testCalculationsGroups" : [ ]
},
"symbolicResults" : {
"overallResult" : "SKIPPED",
"numberOfTests" : 0,
"numberOfFailedTests" : 0,
"numberOfSuccessfulTests" : 0,
"numberOfSkippedTests" : 0,
"numberOfErrorTests" : 0,
"crashed" : false,
"testCalculationsGroup" : [ ]
}
},
"SymPy" : {
"translation" : "",
"translationInformation" : {
"tokenTranslations" : {
"Error" : "(LaTeX -> SymPy) No translation possible for given token: Cannot extract information from feature set: \\Wignersixjsym [\\Wignersixjsym]"
}
},
"numericResults" : {
"overallResult" : "SKIPPED",
"numberOfTests" : 0,
"numberOfFailedTests" : 0,
"numberOfSuccessfulTests" : 0,
"numberOfSkippedTests" : 0,
"numberOfErrorTests" : 0,
"wasAborted" : false,
"crashed" : false,
"testCalculationsGroups" : [ ]
},
"symbolicResults" : {
"overallResult" : "SKIPPED",
"numberOfTests" : 0,
"numberOfFailedTests" : 0,
"numberOfSuccessfulTests" : 0,
"numberOfSkippedTests" : 0,
"numberOfErrorTests" : 0,
"crashed" : false,
"testCalculationsGroup" : [ ]
}
},
"Maple" : {
"translation" : "",
"translationInformation" : {
"tokenTranslations" : {
"Error" : "(LaTeX -> Maple) No translation possible for given token: Cannot extract information from feature set: \\Wignersixjsym [\\Wignersixjsym]"
}
},
"numericResults" : {
"overallResult" : "SKIPPED",
"numberOfTests" : 0,
"numberOfFailedTests" : 0,
"numberOfSuccessfulTests" : 0,
"numberOfSkippedTests" : 0,
"numberOfErrorTests" : 0,
"wasAborted" : false,
"crashed" : false,
"testCalculationsGroups" : [ ]
},
"symbolicResults" : {
"overallResult" : "SKIPPED",
"numberOfTests" : 0,
"numberOfFailedTests" : 0,
"numberOfSuccessfulTests" : 0,
"numberOfSkippedTests" : 0,
"numberOfErrorTests" : 0,
"crashed" : false,
"testCalculationsGroup" : [ ]
}
}
},
"positions" : [ ],
"includes" : [ "j_{3}", "\\begin{Bmatrix} j_1 & j_2 & j_3\\\\ j_4 & j_5 & j_6 \\end{Bmatrix} = \\begin{Bmatrix} j_2 & j_1 & j_3\\\\ j_5 & j_4 & j_6 \\end{Bmatrix}= \\begin{Bmatrix} j_1 & j_3 & j_2\\\\ j_4 & j_6 & j_5 \\end{Bmatrix}= \\begin{Bmatrix} j_3 & j_2 & j_1\\\\ j_6 & j_5 & j_4 \\end{Bmatrix}= \\cdots", "j", "\\begin{Bmatrix} j_1 & j_2 & j_3\\\\ j_4 & j_5 & j_6 \\end{Bmatrix}" ],
"isPartOf" : [ "\\begin{Bmatrix} j_1 & j_2 & j_3\\\\ j_4 & j_5 & j_6 \\end{Bmatrix} = \\begin{Bmatrix} j_2 & j_1 & j_3\\\\ j_5 & j_4 & j_6 \\end{Bmatrix}= \\begin{Bmatrix} j_1 & j_3 & j_2\\\\ j_4 & j_6 & j_5 \\end{Bmatrix}= \\begin{Bmatrix} j_3 & j_2 & j_1\\\\ j_6 & j_5 & j_4 \\end{Bmatrix}= \\cdots" ],
"definiens" : [ ]
}