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Function simplify #
Simplify an expression tree.
A list of rules are applied to an expression, repeating over the list until
no further changes are made.
It's possible to pass a custom set of rules to the function as second
argument. A rule can be specified as an object, string, or function:
const rules = [
{ l: 'n1*n3 + n2*n3', r: '(n1+n2)*n3' },
'n1*n3 + n2*n3 -> (n1+n2)*n3',
function (node) {
// ... return a new node or return the node unchanged
return node
}
]
String and object rules consist of a left and right pattern. The left is
used to match against the expression and the right determines what matches
are replaced with. The main difference between a pattern and a normal
expression is that variables starting with the following characters are
interpreted as wildcards:
- 'n' - Matches any node [Node]
- 'c' - Matches a constant literal (5 or 3.2) [ConstantNode]
- 'cl' - Matches a constant literal; same as c [ConstantNode]
- 'cd' - Matches a decimal literal (5 or -3.2) [ConstantNode or unaryMinus wrapping a ConstantNode]
- 'ce' - Matches a constant expression (-5 or √3) [Expressions consisting of only ConstantNodes, functions, and operators]
- 'v' - Matches a variable; anything not matched by c (-5 or x) [Node that is not a ConstantNode]
- 'vl' - Matches a variable literal (x or y) [SymbolNode]
- 'vd' - Matches a non-decimal expression; anything not matched by cd (x or √3) [Node that is not a ConstantNode or unaryMinus that is wrapping a ConstantNode]
- 've' - Matches a variable expression; anything not matched by ce (x or 2x) [Expressions that contain a SymbolNode or other non-constant term]
The default list of rules is exposed on the function as `simplify.rules`
and can be used as a basis to built a set of custom rules. Note that since
the `simplifyCore` function is in the default list of rules, by default
simplify will convert any function calls in the expression that have
operator equivalents to their operator forms.
To specify a rule as a string, separate the left and right pattern by '->'
When specifying a rule as an object, the following keys are meaningful:
- l - the left pattern
- r - the right pattern
- s - in lieu of l and r, the string form that is broken at -> to give them
- repeat - whether to repeat this rule until the expression stabilizes
- assuming - gives a context object, as in the 'context' option to
simplify. Every property in the context object must match the current
context in order, or else the rule will not be applied.
- imposeContext - gives a context object, as in the 'context' option to
simplify. Any settings specified will override the incoming context
for all matches of this rule.
For more details on the theory, see:
- [Strategies for simplifying math expressions (Stackoverflow)](https://stackoverflow.com/questions/7540227/strategies-for-simplifying-math-expressions)
- [Symbolic computation - Simplification (Wikipedia)](https://en.wikipedia.org/wiki/Symbolic_computation#Simplification)
An optional `options` argument can be passed as last argument of `simplify`.
Currently available options (defaults in parentheses):
- `consoleDebug` (false): whether to write the expression being simplified
and any changes to it, along with the rule responsible, to console
- `context` (simplify.defaultContext): an object giving properties of
each operator, which determine what simplifications are allowed. The
currently meaningful properties are commutative, associative,
total (whether the operation is defined for all arguments), and
trivial (whether the operation applied to a single argument leaves
that argument unchanged). The default context is very permissive and
allows almost all simplifications. Only properties differing from
the default need to be specified; the default context is used as a
fallback. Additional contexts `simplify.realContext` and
`simplify.positiveContext` are supplied to cause simplify to perform
just simplifications guaranteed to preserve all values of the expression
assuming all variables and subexpressions are real numbers or
positive real numbers, respectively. (Note that these are in some cases
more restrictive than the default context; for example, the default
context will allow `x/x` to simplify to 1, whereas
`simplify.realContext` will not, as `0/0` is not equal to 1.)
- `exactFractions` (true): whether to try to convert all constants to
exact rational numbers.
- `fractionsLimit` (10000): when `exactFractions` is true, constants will
be expressed as fractions only when both numerator and denominator
are smaller than `fractionsLimit`.
Syntax #
```js
math.simplify(expr)
math.simplify(expr, rules)
math.simplify(expr, rules)
math.simplify(expr, rules, scope)
math.simplify(expr, rules, scope, options)
math.simplify(expr, scope)
math.simplify(expr, scope, options)
```
Parameters #
Parameter | Type | Description
--------- | ---- | -----------
`expr` | Node | string | The expression to be simplified
`rules` | SimplifyRule[] | Optional list with custom rules
`scope` | Object | Optional scope with variables
`options` | SimplifyOptions | Optional configuration settings
Returns #
Type | Description
---- | -----------
Node | Returns the simplified form of `expr`
Throws #
Type | Description
---- | -----------
Examples #
```js
math.simplify('2 * 1 * x ^ (2 - 1)') // Node "2 * x"
math.simplify('2 * 3 * x', {x: 4}) // Node "24"
const f = math.parse('2 * 1 * x ^ (2 - 1)')
math.simplify(f) // Node "2 * x"
math.simplify('0.4 * x', {}, {exactFractions: true}) // Node "x * 2 / 5"
math.simplify('0.4 * x', {}, {exactFractions: false}) // Node "0.4 * x"
```
See also #
[simplifyCore](simplifyCore.html),
[derivative](derivative.html),
[evaluate](evaluate.html),
[parse](parse.html),
[rationalize](rationalize.html),
[resolve](resolve.html)