Manipulating Expressions

The functions for manipulating lists can also operate on most expressions. Be sure to quote the expression with Expr(). For example:

Remove( Expr( A + B + C + D ), 2 ); // results in the expression A + C + D

b = Substitute( Expr( Log( 2 ) ^ 2 / 2 ), 2, 3 ); /* returns the expression Log( 3 ) ^ 3 / 3*/

As with lists, remember that the first argument for in-place functions must be an L-value. An L-value is an entity such as a variable whose value can be set. In-place functions are those that operate on lists or expressions directly. They have From or Into in their names (for example, Remove From and Insert Into). They do not return a result; you have to show the expression to see the result.

polynomial = Expr( a * x ^ 2 + b * x + c );

Insert Into( polynomial, Expr( d * x ^ 3 ), 1 );

Show( polynomial );

polynomial = d * x ^ 3 + a * x ^ 2 + b * x + c

For the not-in-place functions, you must either state the expression directly or else quote a name that evaluates to an expression using NameExpr. Such functions do not have From or Into in their names. They return manipulated lists or expressions without changing the original list or expression given in the first argument.

cubic = Insert( Expr( a * x ^ 2 + b * x + c ), Expr( d * x ^ 3 ), 1 );

d * x ^ 3 + a * x ^ 2 + b * x + c

quadratic = Expr( a * x ^ 2 + b * x + c );

cubic = Insert( Name Expr( quadratic ), Expr( d * x ^ 3 ), 1 );

d * x ^ 3 + a * x ^ 2 + b * x + c

Substituting

Substituting is extremely powerful; please review the earlier discussion Substituting. Here are a few notes regarding substituting for expressions.

Substitute(pattern,name,replacement) substitutes for names in expressions

NameExpr() looks through the name but copies instead of evaluates:

a = Expr(

	Distribution( Column( x ), Normal Quantile Plot )

);

Show( Name Expr( a ) );

Name Expr(a) = Distribution(Column(x), Normal Quantile Plot);

Substitute() evaluates all its arguments, so they must be quoted correctly:

b = Substitute( Name Expr( a ), Expr( x ), Expr( :weight ) );

Show( Name Expr( b ) );

Name Expr(b) = Distribution(Column(:weight), Normal Quantile Plot);

SubstituteInto() needs an L-value, so the first argument is not quoted:

Substitute Into( a, Expr( x ), Expr( :weight ) );

Show( Name Expr( a ) );

Name Expr(a) = Distribution(Column(:weight), Normal Quantile Plot);

Substitute() is useful for changing parts of expressions, such as in the following example that tests the Is functions:

data = {1, {1, 2, 3}, [1 2 3], "abc", x, x( y )};

ops = {is number, is list, is matrix, is string, is name, is expr};

m = J( N Items( data ), N Items( ops ), 0 );

test = Expr(

	m[r, c] = _op( data[r] )

);

For( r = 1, r <= N Items( data ), r++,

	For( c = 1, c <= N Items( ops ), c++,

		Eval( Substitute( Name Expr( test ), Expr( _op ), ops[c] ) )

	)

);

Show( m );

m =

[1 0 0 0 0 0,

0 1 0 0 0 1,

0 0 1 0 0 0,

0 0 0 1 0 0,

0 0 0 0 1 1,

0 0 0 0 0 1];

You can use SubstituteInto() to have JMP solve quadratic equations. The following example solves 4x2 - 9 = 0:

/* FIND THE ROOTS FOR THE EQUATION:

a*x^2 + b*x + c = 0

The quadratic formula is x=(-b + - sqrt(b^2 - 4ac))/2a.

Use a list to store both the + and - results of the +- operation */

x = {Expr(

	(-b + Sqrt( b ^ 2 - 4 * a * c )) / (2 * a)

), Expr(

	(-b - Sqrt( b ^ 2 - 4 * a * c )) / (2 * a)

)};

Substitute Into( x, Expr( a ), 4, Expr( b ), 0, Expr( c ), -9 );

// plug in the coefficients

Show( x ); // see the result of substitution

Show( Eval Expr( x ) ); // see the solution

x = {Expr(((-0) + Sqrt(0 ^ 2 - 4 * 4 * -9)) / (2 * 4)), Expr(((-0) - Sqrt(0 ^ 2 - 4 * 4 * -9)) / (2 * 4))};

Eval Expr(x) = {1.5, -1.5};

The functions for manipulating lists and expressions are discussed in the previous section, Manipulating Lists, and summarized in Table 8.4.

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