Metadata-Version: 2.1
Name: mathy-core
Version: 0.8.1
Summary: Computer Algebra System for working with math expressions
Home-page: https://mathy.ai
Author: Justin DuJardin
Author-email: justin@dujardinconsulting.com
License: All rights reserved
Keywords: math
Platform: UNKNOWN
Classifier: Programming Language :: Python :: 3
Classifier: License :: OSI Approved :: MIT License
Classifier: Operating System :: OS Independent
Classifier: Development Status :: 2 - Pre-Alpha
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# mathy_core: parse and manipulate math expressions

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Mathy core is a python package (_with type annotations_) for working with math problems. It has a tokenizer for converting plain text into tokens, a parser for converting tokens into expression trees, a rule-based system for manipulating the trees, a layout system for visualizing trees, and a set of problem generation functions that can be used to generate datasets for ML training.

## 🚀 Quickstart

You can install `mathy_core` from pip:

```bash
pip install mathy_core
```

## Examples

Consider a few examples to get a feel for what Mathy core does.

### Evaluate an expression

Arithmetic is a snap.

```python
from mathy_core import ExpressionParser

expression = ExpressionParser().parse("4 + 2")
assert expression.evaluate() == 6
```

### Evaluate with variables

Variable values can be specified when evaluating an expression.

```python
from mathy import ExpressionParser, MathExpression

expression: MathExpression = ExpressionParser().parse("4x + 2y")
assert expression.evaluate({"x": 2, "y": 5}) == 18
```

### Transform an expression

Expressions can be changed using rules based on the properties of numbers.

```python
from mathy import DistributiveFactorOutRule, ExpressionParser

input = "4x + 2x"
output = "(4 + 2) * x"
parser = ExpressionParser()

input_exp = parser.parse(input)
output_exp = parser.parse(output)

# Verify that the rule transforms the tree as expected
change = DistributiveFactorOutRule().apply_to(input_exp)
assert str(change.result) == output

# Verify that both trees evaluate to the same value
ctx = {"x": 3}
assert input_exp.evaluate(ctx) == output_exp.evaluate(ctx)
```

<!-- ### Visualize a Tree -- needs mathy plugin in docs.sh -->
<!-- ### Generate Problems -- needs example snippet -->

## Semantic Versioning

Before Mathy Core reaches v1.0 the project is not guaranteed to have a consistent API, which means that types and classes may move around or be removed. That said, we try to be predictable when it comes to breaking changes, so the project uses semantic versioning to help users avoid breakage.

Specifically, new releases increase the `patch` semver component for new features and fixes, and the `minor` component when there are breaking changes. If you don't know much about semver strings, they're usually formatted `{major}.{minor}.{patch}` so increasing the `patch` component means incrementing the last number.

Consider a few examples:

| From Version | To Version | Changes are Breaking |
| :----------: | :--------: | :------------------: |
|    0.2.0     |   0.2.1    |          No          |
|    0.3.2     |   0.3.6    |          No          |
|    0.3.1     |   0.3.17   |          No          |
|    0.2.2     |   0.3.0    |         Yes          |

If you are concerned about breaking changes, you can pin the version in your requirements so that it does not go beyond the current semver `minor` component, for example if the current version was `0.1.37`:

```
mathy_core>=0.1.37,<0.2.0
```

## 🎛 API

<!-- NOTE: The below code is auto-generated. Update source files to change API documentation. -->
<!-- AUTO_DOCZ_START -->

# mathy_core.tokenizer

## Tokenizer <kbd>class</kbd>

```python
Tokenizer(self, exclude_padding: bool = True)
```

The Tokenizer produces a list of tokens from an input string.

### eat_token <kbd>method</kbd>

```python
Tokenizer.eat_token(
    self,
    context: mathy_core.tokenizer.TokenContext,
    typeFn: Callable[[str], bool],
) -> str
```

Eat all of the tokens of a given type from the front of the stream
until a different type is hit, and return the text.

### identify_alphas <kbd>method</kbd>

```python
Tokenizer.identify_alphas(
    self,
    context: mathy_core.tokenizer.TokenContext,
) -> int
```

Identify and tokenize functions and variables.

### identify_constants <kbd>method</kbd>

```python
Tokenizer.identify_constants(
    self,
    context: mathy_core.tokenizer.TokenContext,
) -> int
```

Identify and tokenize a constant number.

### identify_operators <kbd>method</kbd>

```python
Tokenizer.identify_operators(
    self,
    context: mathy_core.tokenizer.TokenContext,
) -> bool
```

Identify and tokenize operators.

### is_alpha <kbd>method</kbd>

```python
Tokenizer.is_alpha(self, c: str) -> bool
```

Is this character a letter

### is_number <kbd>method</kbd>

```python
Tokenizer.is_number(self, c: str) -> bool
```

Is this character a number

### tokenize <kbd>method</kbd>

```python
Tokenizer.tokenize(self, buffer: str) -> List[mathy_core.tokenizer.Token]
```

Return an array of `Token`s from a given string input.
This throws an exception if an unknown token type is found in the input.

# mathy_core.parser

## ExpressionParser <kbd>class</kbd>

```python
ExpressionParser(self) -> None
```

Parser for converting text into binary trees. Trees encode the order of
operations for an input, and allow evaluating it to detemrine the expression
value.

### Grammar Rules

Symbols:

```
( )    == Non-terminal
{ }*   == 0 or more occurrences
{ }+   == 1 or more occurrences
{ }?   == 0 or 1 occurrences
[ ]    == Mandatory (1 must occur)
|      == logical OR
" "    == Terminal symbol (literal)
```

Non-terminals defined/parsed by Tokenizer:

```
(Constant) = anything that can be parsed by `float(in)`
(Variable) = any string containing only letters (a-z and A-Z)
```

Rules:

```
(Function)     = [ functionName ] "(" (AddExp) ")"
(Factor)       = { (Variable) | (Function) | "(" (AddExp) ")" }+ { { "^" }? (UnaryExp) }?
(FactorPrefix) = [ (Constant) { (Factor) }? | (Factor) ]
(UnaryExp)     = { "-" }? (FactorPrefix)
(ExpExp)       = (UnaryExp) { { "^" }? (UnaryExp) }?
(MultExp)      = (ExpExp) { { "*" | "/" }? (ExpExp) }*
(AddExp)       = (MultExp) { { "+" | "-" }? (MultExp) }*
(EqualExp)     = (AddExp) { { "=" }? (AddExp) }*
(start)        = (EqualExp)
```

### check <kbd>method</kbd>

```python
ExpressionParser.check(self, tokens: mathy_core.parser.TokenSet) -> bool
```

Check if the `self.current_token` is a member of a set Token types

Args: - `tokens` The set of Token types to check against

`Returns` True if the `current_token`'s type is in the set else False

### eat <kbd>method</kbd>

```python
ExpressionParser.eat(self, type: int) -> bool
```

Assign the next token in the queue to current_token if its type
matches that of the specified parameter. If the type does not match,
raise a syntax exception.

Args: - `type` The type that your syntax expects @current_token to be

### next <kbd>method</kbd>

```python
ExpressionParser.next(self) -> bool
```

Assign the next token in the queue to `self.current_token`.

Return True if there are still more tokens in the queue, or False if there
are no more tokens to look at.

### parse <kbd>method</kbd>

```python
ExpressionParser.parse(
    self,
    input_text: str,
) -> mathy_core.expressions.MathExpression
```

Parse a string representation of an expression into a tree
that can be later evaluated.

Returns : The evaluatable expression tree.

## TokenSet <kbd>class</kbd>

```python
TokenSet(self, source: int)
```

TokenSet objects are bitmask combinations for checking to see
if a token is part of a valid set.

### add <kbd>method</kbd>

```python
TokenSet.add(self, addTokens: int) -> 'TokenSet'
```

Add tokens to self set and return a TokenSet representing
their combination of flags. Value can be an integer or an instance
of `TokenSet`

### contains <kbd>method</kbd>

```python
TokenSet.contains(self, type: int) -> bool
```

Returns true if the given type is part of this set

# mathy_core.tree

## BinaryTreeNode <kbd>class</kbd>

```python
BinaryTreeNode(
    self,
    left: 'BinaryTreeNode' = None,
    right: 'BinaryTreeNode' = None,
    parent: 'BinaryTreeNode' = None,
    id: Optional[str] = None,
)
```

The binary tree node is the base node for all of our trees, and provides a
rich set of methods for constructing, inspecting, and modifying them.
The node itself defines the structure of the binary tree, having left and right
children, and a parent.

### clone <kbd>method</kbd>

```python
BinaryTreeNode.clone(self) -> ~NodeType
```

Create a clone of this tree

### get_children <kbd>method</kbd>

```python
BinaryTreeNode.get_children(self) -> List[~NodeType]
```

Get children as an array. If there are two children, the first object will
always represent the left child, and the second will represent the right.

### get_root <kbd>method</kbd>

```python
BinaryTreeNode.get_root(self: ~NodeType) -> ~NodeType
```

Return the root element of this tree

### get_sibling <kbd>method</kbd>

```python
BinaryTreeNode.get_sibling(self: ~NodeType) -> Optional[~NodeType]
```

Get the sibling node of this node. If there is no parent, or the node
has no sibling, the return value will be None.

### get_side <kbd>method</kbd>

```python
BinaryTreeNode.get_side(
    self,
    child: ~NodeType,
) -> Union[typing_extensions.Literal['left'], typing_extensions.Literal['right']]
```

Determine whether the given `child` is the left or right child of this
node

### is_leaf <kbd>method</kbd>

```python
BinaryTreeNode.is_leaf(self) -> bool
```

Is this node a leaf? A node is a leaf if it has no children.

### name

Human readable name for this node.

### rotate <kbd>method</kbd>

```python
BinaryTreeNode.rotate(self: ~NodeType) -> ~NodeType
```

Rotate a node, changing the structure of the tree, without modifying
the order of the nodes in the tree.

### set_left <kbd>method</kbd>

```python
BinaryTreeNode.set_left(
    self: ~NodeType,
    child: Optional[BinaryTreeNode] = None,
    clear_old_child_parent: bool = False,
) -> ~NodeType
```

Set the left node to the passed `child`

### set_right <kbd>method</kbd>

```python
BinaryTreeNode.set_right(
    self: ~NodeType,
    child: Optional[BinaryTreeNode] = None,
    clear_old_child_parent: bool = False,
) -> ~NodeType
```

Set the right node to the passed `child`

### set_side <kbd>method</kbd>

```python
BinaryTreeNode.set_side(
    self,
    child: ~NodeType,
    side: Union[typing_extensions.Literal['left'], typing_extensions.Literal['right']],
) -> ~NodeType
```

Set a new `child` on the given `side`

### visit_inorder <kbd>method</kbd>

```python
BinaryTreeNode.visit_inorder(
    self: ~NodeType,
    visit_fn: Callable[[~NodeType, int, ~VisitDataType], Optional[typing_extensions.Literal['stop']]],
    depth: int = 0,
    data: Optional[~VisitDataType] = None,
) -> Optional[typing_extensions.Literal['stop']]
```

Visit the tree inorder, which visits the left child, then the current node,
and then its right child.

_Left -> Visit -> Right_

This method accepts a function that will be invoked for each node in the
tree. The callback function is passed three arguments: the node being
visited, the current depth in the tree, and a user specified data parameter.

!!! info

    Traversals may be canceled by returning `STOP` from any visit function.

### visit_postorder <kbd>method</kbd>

```python
BinaryTreeNode.visit_postorder(
    self: ~NodeType,
    visit_fn: Callable[[~NodeType, int, ~VisitDataType], Optional[typing_extensions.Literal['stop']]],
    depth: int = 0,
    data: Optional[~VisitDataType] = None,
) -> Optional[typing_extensions.Literal['stop']]
```

Visit the tree postorder, which visits its left child, then its right child,
and finally the current node.

_Left -> Right -> Visit_

This method accepts a function that will be invoked for each node in the
tree. The callback function is passed three arguments: the node being
visited, the current depth in the tree, and a user specified data parameter.

!!! info

    Traversals may be canceled by returning `STOP` from any visit function.

### visit_preorder <kbd>method</kbd>

```python
BinaryTreeNode.visit_preorder(
    self: ~NodeType,
    visit_fn: Callable[[~NodeType, int, ~VisitDataType], Optional[typing_extensions.Literal['stop']]],
    depth: int = 0,
    data: Optional[~VisitDataType] = None,
) -> Optional[typing_extensions.Literal['stop']]
```

Visit the tree preorder, which visits the current node, then its left
child, and then its right child.

_Visit -> Left -> Right_

This method accepts a function that will be invoked for each node in the
tree. The callback function is passed three arguments: the node being
visited, the current depth in the tree, and a user specified data parameter.

!!! info

    Traversals may be canceled by returning `STOP` from any visit function.

## NodeType

Template type that inherits from BinaryTreeNode.

## VisitDataType

Template type of user data passed to visit functions.

# mathy_core.expressions

## AbsExpression <kbd>class</kbd>

```python
AbsExpression(
    self,
    child: mathy_core.expressions.MathExpression = None,
    child_on_left: bool = True,
)
```

Evaluates the absolute value of an expression.

## AddExpression <kbd>class</kbd>

```python
AddExpression(
    self,
    left: Optional[mathy_core.expressions.MathExpression] = None,
    right: Optional[mathy_core.expressions.MathExpression] = None,
)
```

Add one and two

## BinaryExpression <kbd>class</kbd>

```python
BinaryExpression(
    self,
    left: Optional[mathy_core.expressions.MathExpression] = None,
    right: Optional[mathy_core.expressions.MathExpression] = None,
)
```

An expression that operates on two sub-expressions

### get_priority <kbd>method</kbd>

```python
BinaryExpression.get_priority(self) -> int
```

Return a number representing the order of operations priority
of this node. This can be used to check if a node is `locked`
with respect to another node, i.e. the other node must be resolved
first during evaluation because of it's priority.

### to_math_ml_fragment <kbd>method</kbd>

```python
BinaryExpression.to_math_ml_fragment(self) -> str
```

Render this node as a MathML element fragment

## ConstantExpression <kbd>class</kbd>

```python
ConstantExpression(self, value: Optional[int, float] = None)
```

A Constant value node, where the value is accessible as `node.value`

## DivideExpression <kbd>class</kbd>

```python
DivideExpression(
    self,
    left: Optional[mathy_core.expressions.MathExpression] = None,
    right: Optional[mathy_core.expressions.MathExpression] = None,
)
```

Divide one by two

## EqualExpression <kbd>class</kbd>

```python
EqualExpression(
    self,
    left: Optional[mathy_core.expressions.MathExpression] = None,
    right: Optional[mathy_core.expressions.MathExpression] = None,
)
```

Evaluate equality of two expressions

### operate <kbd>method</kbd>

```python
EqualExpression.operate(
    self,
    one: Union[float, int],
    two: Union[float, int],
) -> Union[float, int]
```

This is where assignment of context variables might make sense. But context
is not present in the expression's `operate` method.

!!! warning

    TODO: Investigate this thoroughly.

## FunctionExpression <kbd>class</kbd>

```python
FunctionExpression(
    self,
    child: mathy_core.expressions.MathExpression = None,
    child_on_left: bool = True,
)
```

A Specialized UnaryExpression that is used for functions. The function name in
text (used by the parser and tokenizer) is derived from the name() method on the
class.

## MathExpression <kbd>class</kbd>

```python
MathExpression(
    self,
    id: str = None,
    left: 'MathExpression' = None,
    right: 'MathExpression' = None,
    parent: 'MathExpression' = None,
)
```

Math tree node with helpers for manipulating expressions.

`mathy:x+y=z`

### add_class <kbd>method</kbd>

```python
MathExpression.add_class(
    self,
    classes: Union[List[str], str],
) -> 'MathExpression'
```

Associate a class name with an expression. This class name will be
attached to nodes when the expression is converted to a capable output
format.

See `MathExpression.to_math_ml_fragment`

### all_changed <kbd>method</kbd>

```python
MathExpression.all_changed(self) -> None
```

Mark this node and all of its children as changed

### clear_classes <kbd>method</kbd>

```python
MathExpression.clear_classes(self) -> None
```

Clear all the classes currently set on the nodes in this expression.

### clone <kbd>method</kbd>

```python
MathExpression.clone(self) -> 'MathExpression'
```

A specialization of the clone method that can track and report a cloned
subtree node.

See `MathExpression.clone_from_root` for more details.

### clone_from_root <kbd>method</kbd>

```python
MathExpression.clone_from_root(
    self,
    node: 'MathExpression' = None,
) -> 'MathExpression'
```

Clone this node including the entire parent hierarchy that it has. This
is useful when you want to clone a subtree and still maintain the overall
hierarchy.

**Arguments**

- **node (MathExpression)**: The node to clone.

**Returns**

`(MathExpression)`: The cloned node.

### color

Color to use for this node when rendering it as changed with
`.terminal_text`

### evaluate <kbd>method</kbd>

```python
MathExpression.evaluate(
    self,
    context: Dict[str, Union[float, int]] = None,
) -> Union[float, int]
```

Evaluate the expression, resolving all variables to constant values

### find_id <kbd>method</kbd>

```python
MathExpression.find_id(
    self,
    id: str,
) -> Optional[MathExpression]
```

Find an expression by its unique ID.

Returns: The found `MathExpression` or `None`

### find_type <kbd>method</kbd>

```python
MathExpression.find_type(self, instanceType: Type[~NodeType]) -> List[~NodeType]
```

Find an expression in this tree by type.

- instanceType: The type to check for instances of

Returns the found `MathExpression` objects of the given type.

### make_ml_tag <kbd>method</kbd>

```python
MathExpression.make_ml_tag(
    self,
    tag: str,
    content: str,
    classes: List[str] = [],
) -> str
```

Make a MathML tag for the given content while respecting the node's given
classes.

**Arguments**

- **tag (str)**: The ML tag name to create.
- **content (str)**: The ML content to place inside of the tag.
  classes (List[str]) An array of classes to attach to this tag.

**Returns**

`(str)`: A MathML element with the given tag, content, and classes

### path_to_root <kbd>method</kbd>

```python
MathExpression.path_to_root(self) -> str
```

Generate a namespaced path key to from the current node to the root.
This key can be used to identify a node inside of a tree.

### raw

raw text representation of the expression.

### set_changed <kbd>method</kbd>

```python
MathExpression.set_changed(self) -> None
```

Mark this node as having been changed by the application of a Rule

### terminal_text

Text output of this node that includes terminal color codes that
highlight which nodes have been changed in this tree as a result of
a transformation.

### to_list <kbd>method</kbd>

```python
MathExpression.to_list(
    self,
    visit: str = 'preorder',
) -> List[MathExpression]
```

Convert this node hierarchy into a list.

### to_math_ml <kbd>method</kbd>

```python
MathExpression.to_math_ml(self) -> str
```

Convert this expression into a MathML container.

### to_math_ml_fragment <kbd>method</kbd>

```python
MathExpression.to_math_ml_fragment(self) -> str
```

Convert this single node into MathML.

### with_color <kbd>method</kbd>

```python
MathExpression.with_color(self, text: str, style: str = 'bright') -> str
```

Render a string that is colored if something has changed

## MultiplyExpression <kbd>class</kbd>

```python
MultiplyExpression(
    self,
    left: Optional[mathy_core.expressions.MathExpression] = None,
    right: Optional[mathy_core.expressions.MathExpression] = None,
)
```

Multiply one and two

## NegateExpression <kbd>class</kbd>

```python
NegateExpression(
    self,
    child: mathy_core.expressions.MathExpression = None,
    child_on_left: bool = True,
)
```

Negate an expression, e.g. `4` becomes `-4`

### to_math_ml_fragment <kbd>method</kbd>

```python
NegateExpression.to_math_ml_fragment(self) -> str
```

Convert this single node into MathML.

## PowerExpression <kbd>class</kbd>

```python
PowerExpression(
    self,
    left: Optional[mathy_core.expressions.MathExpression] = None,
    right: Optional[mathy_core.expressions.MathExpression] = None,
)
```

Raise one to the power of two

## SgnExpression <kbd>class</kbd>

```python
SgnExpression(
    self,
    child: mathy_core.expressions.MathExpression = None,
    child_on_left: bool = True,
)
```

### operate <kbd>method</kbd>

```python
SgnExpression.operate(self, value: Union[float, int]) -> Union[float, int]
```

Determine the sign of an value.

**Returns**

`(int)`: -1 if negative, 1 if positive, 0 if 0

## SubtractExpression <kbd>class</kbd>

```python
SubtractExpression(
    self,
    left: Optional[mathy_core.expressions.MathExpression] = None,
    right: Optional[mathy_core.expressions.MathExpression] = None,
)
```

Subtract one from two

## UnaryExpression <kbd>class</kbd>

```python
UnaryExpression(
    self,
    child: mathy_core.expressions.MathExpression = None,
    child_on_left: bool = True,
)
```

An expression that operates on one sub-expression

# mathy_core.rules.associative_property

## AssociativeSwapRule <kbd>class</kbd>

```python
AssociativeSwapRule(self, args, kwargs)
```

Associative Property
Addition: `(a + b) + c = a + (b + c)`

         (y) +            + (x)
            / \          / \
           /   \        /   \
      (x) +     c  ->  a     + (y)
         / \                / \
        /   \              /   \
       a     b            b     c

Multiplication: `(ab)c = a(bc)`

         (x) *            * (y)
            / \          / \
           /   \        /   \
      (y) *     c  <-  a     * (x)
         / \                / \
        /   \              /   \
       a     b            b     c

# mathy_core.rules.commutative_property

## CommutativeSwapRule <kbd>class</kbd>

```python
CommutativeSwapRule(self, preferred: bool = True)
```

Commutative Property
For Addition: `a + b = b + a`

         +                  +
        / \                / \
       /   \     ->       /   \
      /     \            /     \
     a       b          b       a

For Multiplication: `a * b = b * a`

         *                  *
        / \                / \
       /   \     ->       /   \
      /     \            /     \
     a       b          b       a

# mathy_core.rules.constants_simplify

## ConstantsSimplifyRule <kbd>class</kbd>

```python
ConstantsSimplifyRule(self, args, kwargs)
```

Given a binary operation on two constants, simplify to the resulting
constant expression

### get_type <kbd>method</kbd>

```python
ConstantsSimplifyRule.get_type(
    self,
    node: mathy_core.expressions.MathExpression,
) -> Optional[Tuple[str, mathy_core.expressions.ConstantExpression, mathy_core.expressions.ConstantExpression]]
```

Determine the configuration of the tree for this transformation.

Support the three types of tree configurations:

- Simple is where the node's left and right children are exactly
  constants linked by an add operation.
- Chained Right is where the node's left child is a constant, but the right
  child is another binary operation of the same type. In this case the left
  child of the next binary node is the target.

Structure:

- Simple
  - node(add),node.left(const),node.right(const)
- Chained Right
  - node(add),node.left(const),node.right(add),node.right.left(const)
- Chained Right Deep
  - node(add),node.left(const),node.right(add),node.right.left(const)

# mathy_core.rules.distributive_factor_out

## DistributiveFactorOutRule <kbd>class</kbd>

```python
DistributiveFactorOutRule(self, constants: bool = False)
```

Distributive Property
`ab + ac = a(b + c)`

The distributive property can be used to expand out expressions
to allow for simplification, as well as to factor out common properties
of terms.

**Factor out a common term**

This handles the `ab + ac` conversion of the distributive property, which
factors out a common term from the given two addition operands.

           +               *
          / \             / \
         /   \           /   \
        /     \    ->   /     \
       *       *       a       +
      / \     / \             / \
     a   b   a   c           b   c

### get_type <kbd>method</kbd>

```python
DistributiveFactorOutRule.get_type(
    self,
    node: mathy_core.expressions.MathExpression,
) -> Optional[Tuple[str, mathy_core.util.TermEx, mathy_core.util.TermEx]]
```

Determine the configuration of the tree for this transformation.

Support the three types of tree configurations:

- Simple is where the node's left and right children are exactly
  terms linked by an add operation.
- Chained Left is where the node's left child is a term, but the right
  child is another add operation. In this case the left child
  of the next add node is the target.
- Chained Right is where the node's right child is a term, but the left
  child is another add operation. In this case the right child
  of the child add node is the target.

Structure:

- Simple
  - node(add),node.left(term),node.right(term)
- Chained Left
  - node(add),node.left(term),node.right(add),node.right.left(term)
- Chained Right
  - node(add),node.right(term),node.left(add),node.left.right(term)

# mathy_core.rules.distributive_multiply_across

## DistributiveMultiplyRule <kbd>class</kbd>

```python
DistributiveMultiplyRule(self, args, kwargs)
```

Distributive Property
`a(b + c) = ab + ac`

The distributive property can be used to expand out expressions
to allow for simplification, as well as to factor out common properties of terms.

**Distribute across a group**

This handles the `a(b + c)` conversion of the distributive property, which
distributes `a` across both `b` and `c`.

_note: this is useful because it takes a complex Multiply expression and
replaces it with two simpler ones. This can expose terms that can be
combined for further expression simplification._

                             +
         *                  / \
        / \                /   \
       /   \              /     \
      a     +     ->     *       *
           / \          / \     / \
          /   \        /   \   /   \
         b     c      a     b a     c

# mathy_core.rules.variable_multiply

## VariableMultiplyRule <kbd>class</kbd>

```python
VariableMultiplyRule(self, args, kwargs)
```

This restates `x^b * x^d` as `x^(b + d)` which has the effect of isolating
the exponents attached to the variables, so they can be combined.

    1. When there are two terms with the same base being multiplied together, their
       exponents are added together. "x * x^3" = "x^4" because "x = x^1" so
       "x^1 * x^3 = x^(1 + 3) = x^4"

    TODO: 2. When there is a power raised to another power, they can be combined by
             multiplying the exponents together. "x^(2^2) = x^4"

The rule identifies terms with explicit and implicit powers, so the following
transformations are all valid:

Explicit powers: x^b \* x^d = x^(b+d)

          *
         / \
        /   \          ^
       /     \    =   / \
      ^       ^      x   +
     / \     / \        / \
    x   b   x   d      b   d

Implicit powers: x \* x^d = x^(1 + d)

        *
       / \
      /   \          ^
     /     \    =   / \
    x       ^      x   +
           / \        / \
          x   d      1   d

### get_type <kbd>method</kbd>

```python
VariableMultiplyRule.get_type(
    self,
    node: mathy_core.expressions.MathExpression,
) -> Optional[Tuple[str, mathy_core.util.TermEx, mathy_core.util.TermEx]]
```

Determine the configuration of the tree for this transformation.

Support two types of tree configurations:

- Simple is where the node's left and right children are exactly
  terms that can be multiplied together.
- Chained is where the node's left child is a term, but the right
  child is a continuation of a more complex term, as indicated by
  the presence of another Multiply node. In this case the left child
  of the next multiply node is the target.

Structure:

- Simple node(mult),node.left(term),node.right(term)
- Chained node(mult),node.left(term),node.right(mult),node.right.left(term)

# mathy_core.layout

## Tree Layout

In order to help visualize, understand, and debug math trees and transformations to
them, Mathy implements a
[Reingold-Tilford](https://reingold.co/tidier-drawings.pdf) layout
algorithm that works with expression trees. It produces beautiful trees like:

`mathy:(2x^3 + y)(14 + 2.3y)`

## TreeLayout <kbd>class</kbd>

```python
TreeLayout(self, args, kwargs)
```

Calculate a visual layout for input trees.

### layout <kbd>method</kbd>

```python
TreeLayout.layout(
    self,
    node: mathy_core.tree.BinaryTreeNode,
    unit_x_multiplier: float = 1.0,
    unit_y_multiplier: float = 1.0,
) -> 'TreeMeasurement'
```

Assign x/y values to all nodes in the tree, and return an object containing
the measurements of the tree.

Returns a TreeMeasurement object that describes the bounds of the tree

### transform <kbd>method</kbd>

```python
TreeLayout.transform(
    self,
    node: mathy_core.tree.BinaryTreeNode = None,
    x: float = 0,
    unit_x_multiplier: float = 1,
    unit_y_multiplier: float = 1,
    measure: Optional[TreeMeasurement] = None,
) -> 'TreeMeasurement'
```

Transform relative to absolute coordinates, and measure the bounds of the tree.

Return a measurement of the tree in output units.

## TreeMeasurement <kbd>class</kbd>

```python
TreeMeasurement(self) -> None
```

Summary of the rendered tree

# mathy_core.problems

## Problem Generation

Utility functions for helping generate input problems.

## DefaultType

Template type for a default return value

## gen_binomial_times_binomial <kbd>function</kbd>

```python
gen_binomial_times_binomial(
    op: str = '+',
    min_vars: int = 1,
    max_vars: int = 2,
    simple_variables: bool = True,
    powers_probability: float = 0.33,
    like_variables_probability: float = 1.0,
) -> Tuple[str, int]
```

Generate a binomial multiplied by another binomial.

**Example**

```
(2e + 12p)(16 + 7e)
```

`mathy:(2e + 12p)(16 + 7e)`

## gen_binomial_times_monomial <kbd>function</kbd>

```python
gen_binomial_times_monomial(
    op: str = '+',
    min_vars: int = 1,
    max_vars: int = 2,
    simple_variables: bool = True,
    powers_probability: float = 0.33,
    like_variables_probability: float = 1.0,
) -> Tuple[str, int]
```

Generate a binomial multiplied by a monomial.

**Example**

```
(4x^3 + y) * 2x
```

`mathy:(4x^3 + y) * 2x`

## gen_combine_terms_in_place <kbd>function</kbd>

```python
gen_combine_terms_in_place(
    min_terms: int = 16,
    max_terms: int = 26,
    easy: bool = True,
    powers: bool = False,
) -> Tuple[str, int]
```

Generate a problem that puts one pair of like terms next to each other
somewhere inside a large tree of unlike terms.

The problem is intended to be solved in a very small number of moves, making
training across many episodes relatively quick, and reducing the combinatorial
explosion of branches that need to be searched to solve the task.

The hope is that by focusing the agent on selecting the right moves inside of a
ridiculously large expression it will learn to select actions to combine like terms
invariant of the sequence length.

**Example**

```
4y + 12j + 73q + 19k + 13z + 56l + (24x + 12x) + 43n + 17j
```

`mathy:4y + 12j + 73q + 19k + 13z + 56l + (24x + 12x) + 43n + 17j`

## gen_commute_haystack <kbd>function</kbd>

```python
gen_commute_haystack(
    min_terms: int = 5,
    max_terms: int = 8,
    commute_blockers: int = 1,
    easy: bool = True,
    powers: bool = False,
) -> Tuple[str, int]
```

A problem with a bunch of terms that have no matches, and a single
set of two terms that do match, but are separated by one other term.
The challenge is to commute the terms to each other in one move.

**Example**

```
4y + 12j + 73q + 19k + 13z + 24x + 56l + 12x  + 43n + 17j"
                              ^-----------^
```

`mathy:4y + 12j + 73q + 19k + 13z + 24x + 56l + 12x + 43n + 17j`

## gen_move_around_blockers_one <kbd>function</kbd>

```python
gen_move_around_blockers_one(
    number_blockers: int,
    powers_probability: float = 0.5,
) -> Tuple[str, int]
```

Two like terms separated by (n) blocker terms.

**Example**

```
4x + (y + f) + x
```

`mathy:4x + (y + f) + x`

## gen_move_around_blockers_two <kbd>function</kbd>

```python
gen_move_around_blockers_two(
    number_blockers: int,
    powers_probability: float = 0.5,
) -> Tuple[str, int]
```

Two like terms with three blockers.

**Example**

```
7a + 4x + (2f + j) + x + 3d
```

`mathy:7a + 4x + (2f + j) + x + 3d`

## gen_simplify_multiple_terms <kbd>function</kbd>

```python
gen_simplify_multiple_terms(
    num_terms: int,
    optional_var: bool = False,
    op: Union[List[str], str] = '+',
    common_variables: bool = True,
    inner_terms_scaling: float = 0.3,
    powers_probability: float = 0.33,
    optional_var_probability: float = 0.8,
    noise_probability: float = 0.8,
    shuffle_probability: float = 0.66,
    share_var_probability: float = 0.5,
    grouping_noise_probability: float = 0.66,
    noise_terms: int = None,
) -> Tuple[str, int]
```

Generate a polynomial problem with like terms that need to be combined and
simplified.

**Example**

```
2a + 3j - 7b + 17.2a + j
```

`mathy:2a + 3j - 7b + 17.2a + j`

## get_blocker <kbd>function</kbd>

```python
get_blocker(
    num_blockers: int = 1,
    exclude_vars: Optional[List[str]] = None,
) -> str
```

Get a string of terms to place between target simplification terms
in order to challenge the agent's ability to use commutative/associative
rules to move terms around.

## get_rand_vars <kbd>function</kbd>

```python
get_rand_vars(
    num_vars: int,
    exclude_vars: Optional[List[str]] = None,
    common_variables: bool = False,
) -> List[str]
```

Get a list of random variables, excluding the given list of hold-out variables

## split_in_two_random <kbd>function</kbd>

```python
split_in_two_random(value: int) -> Tuple[int, int]
```

Split a given number into two smaller numbers that sum to it.
Returns: a tuple of (lower, higher) numbers that sum to the input

## use_pretty_numbers <kbd>function</kbd>

```python
use_pretty_numbers(enabled: bool = True) -> None
```

Determine if problems should include only pretty numbers or
a whole range of integers and floats. Using pretty numbers will
restrict the numbers that are generated to integers between 1 and 12. When not using pretty numbers, floats and large integers will
be included in the output from `rand_number`

<!-- AUTO_DOCZ_END -->

## Contributors

Mathy Core wouldn't be possible without the wonderful contributions of the following people:

<!-- ALL-CONTRIBUTORS-LIST:START - Do not remove or modify this section -->
<!-- prettier-ignore-start -->
<!-- markdownlint-disable -->
<table>
  <tr>
    <td align="center"><a target="_blank" href="https://www.justindujardin.com/"><img src="https://avatars0.githubusercontent.com/u/101493?v=4" width="100px;" alt=""/><br /><sub><b>Justin DuJardin</b></sub></a></td>
  </tr>
</table>

<!-- markdownlint-enable -->
<!-- prettier-ignore-end -->

<!-- ALL-CONTRIBUTORS-LIST:END -->

This project follows the [all-contributors](https://github.com/all-contributors/all-contributors) specification. Contributions of any kind welcome!


