Sage Embedding
Using the Sage Cell Server
This code snippet shows the essential PG code to embed a call to the Sage Cell Server from within a problem. Note that these are insertions, not a complete PG file. This code will have to be incorporated into the problem file on which you are working.
PG problem file | Explanation |
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loadMacros("PGstandard.pl", "MathObjects.pl", ); |
No special macros file is needed now although in the future |
########################################################### ## ## pg initializations and regular WeBWorK code $a11 = random(2,3,1/2); $a12 = 1; $a21 = random(-3,-1,1/2); $a22 = non_zero_random(-2,5,1/20); $A = Matrix([[$a11,$a12],[$a21,$a22]]); $A1 = Vector($a11,$a21); $x1 = non_zero_random(-2,2,1/20); $x1ans = Compute("$x1"); $x2 = non_zero_random(-2,2,1/10); $x2ans = Compute("$x2"); $x = Vector($x1,$x2); $b1 = $a11*$x1+$a12*$x2; $b2 = $a21*$x1+$a22*$x2; $b = Vector($b1,$b2); |
The WeBWorK set up for the problem is the same, but in addition you have
to consider how you will pass the problem parameters into Sage. For example,
if you want to pass
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BEGIN_TEXT <div id="sagecell"> \{ ans_rule(15) \} \{ans_rule(15) \}. <script type="application/sage"> b = matrix([[$b1],[$b2]]) bt = b.transpose() A=matrix([[$a11,$a12],[$a21,$a22]]) At =A.transpose() # Notice the correct exact answer is given by x = A\b # Finding when a vector b is in the span of other vectors in 2-space |
Special to the Sage embedding:
This <div> section contains the Sage code needed to implement the desired function.
The id attribute of the
We want to pass two answers from Sage to WeBWorK, so we need to include two
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~~@interact def _(x1=slider(-3,3,1/20,1), x2=slider(-3,3,1/20,1)): G = arrow((0,0),x1*At[0],rgbcolor=(0,0,1)) G += arrow(x1*At[0],x1*At[0]+x2*At[1],rgbcolor=(0,1,0)) G += arrow((0,0),($b1,$b2),rgbcolor=(1,0,0),width=5) G += text("A1",(x1*At[0][0]/2,x1*At[0][1]/2),fontsize=30,color='purple') G += text("A2",(x1*At[0][0]+x2*At[1][0]/2,x1*At[0][1]+x2*At[1][1]/2), fontsize=30,color='purple') G += text("b",($b1/2,$b2/2),fontsize=40,color='purple') G += point(x1*At[0],color='blue',pointsize=40) G += point(($b1,$b2),color='red',pointsize=30) G += point(x1*At[0]+x2*At[1],color='green',pointsize=40) G += point(($b1,$b2),color='red',pointsize=20) # Add fixed originals and dashed modified version of these show(G,frame=False) |
Main sage script: Working Sage code will work verbatim except for a couple of notational changes caused by conflicting syntax between perl and sage. In particular, since "@" is used for tables in perl and for interacts in sage, one will need to replace "@" with "~~@". Further, WeBWorK uses \( and \) to delimit latex and "$" for variables while Sage uses "$' to delimit latex. Therefore, changing each of Sage's latex delimiters to the \( and \) format averts any conflict. |
html('<input type=hidden size=15 name="\{ANS_NUM_TO_NAME(1)\}" id="\{ANS_NUM_TO_NAME(1)\}" value="%s">' %str(x1) ) html('<input type=hidden size=15 name="\{ANS_NUM_TO_NAME(2)\}" id="\{ANS_NUM_TO_NAME(2)\}" value="%s">' %str(x2) ) </script> </div> |
At the end of Sage code (usually an interact) you need to manually pass the answers you want from Sage back into WeBWorK by
using Sage to write the answer |
########################################################### ## ## single cell server script ## ## script that sends the Sage code above to the ## single cell server and writes the return into ## the webpage ## TEXT(MODES(TeX=>"", HTML=><<'SAGE_SCRIPT')); <script src="http://aleph.sagemath.org/static/jquery.min.js"></script> <script src="http://aleph.sagemath.org/embedded_sagecell.js"></script> <script> $(function () { sagecell.makeSagecell({inputLocation: '#sagecell', template: sagecell.templates.minimal, autoeval: true, evalButtonText: 'Reset the interactive display'}); }); </script> SAGE_SCRIPT |
This section writes the javascript into the webpage that feeds the correct |
#################################################### ## ## Lower WeBWorK text ## ## Problem display following the Sage cell ## Context()->texStrings; BEGIN_TEXT When you are comfortable with the coefficients that you have chosen, press the submit button below. END_TEXT Context()->normalStrings; ####################### # Answer Evaluation $showPartialCorrectAnswers = 1; ANS( $x1ans->cmp() ); ANS( $x2ans->cmp() ); |
Answer Evaluation: The answers are checked in the same order as the input boxes appear in the Sage section. Some tweaking may be required to get the Sage format agreeing with the WeBWorK format of the objects the evaluator is checking |
########################################################### ## ## Hint(s), delete or comment if not used ## Context()->texStrings; $showHint = 2; BEGIN_HINT By adjusting the sliders, you are changing the length of the corresponding vector. Remember that a negative coefficient makes the vector point in the opposite direction. END_HINT $showHint = 4; $x1low = $x1-1/3; $x1high = $x1+1/5; BEGIN_HINT Consider choosing a value for the first coefficient somewhere between $x1low and $x1high. END_HINT Context()->normalStrings; ########################################################### ## ## Solution, delete or comment if not used ## Context()->texStrings; BEGIN_SOLUTION Notice that \(($x1) *A_1 + ($x2) *A_2 = $b\) END_SOLUTION Context()->normalStrings; ENDDOCUMENT(); # This should be the last executable line in the problem. |
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Problem Techniques Index
More on how to embed applets in WeBWorK Questions