A formal grammar-based dice parser and roller for D&D and other dice systems.
Project description
d20
A fast, powerful, and extensible dice engine for D&D, d20 systems, and any other system that needs dice!
Key Features
- Quick to start - just use
d20.roll()! - Optimized for speed and memory efficiency
- Highly extensible API for custom behaviour and dice stringification
- Built-in execution limits against malicious dice expressions
- Tree-based dice representation for easy traversal
Installing
Requires Python 3.6+.
python3 -m pip install -U d20
Quickstart
>>> import d20
>>> result = d20.roll("1d20+5")
>>> str(result)
'1d20 (10) + 5 = `15`'
>>> result.total
15
>>> result.crit
<CritType.NORMAL: 0>
>>> str(result.ast)
'1d20 + 5'
Dice Syntax
This is the grammar supported by the dice parser, roughly ordered in how tightly the grammar binds.
Numbers
These are the atoms used at the base of the syntax tree.
| Name | Syntax | Description | Examples |
|---|---|---|---|
| literal | INT, DECIMAL |
A literal number. | 1, 0.5, 3.14 |
| dice | INT? "d" INT |
A set of die. | d20, 3d6 |
| set | "(" (num ("," num)* ","?)? ")" |
A set of expressions. | (), (2,), (1, 3+3, 1d20) |
Note that (3d6) is equivalent to 3d6, but (3d6,) is the set containing the one element 3d6.
Set Operations
These operations can be performed on dice and sets.
Grammar
| Name | Syntax | Description | Examples |
|---|---|---|---|
| set_op | operation selector |
An operation on a set (see below). | kh3, ro<3 |
| selector | seltype INT |
A selection on a set (see below). | 3, h1, >2 |
Operators
Operators are always followed by a selector, and operate on the items in the set that match the selector.
| Syntax | Name | Description |
|---|---|---|
| k | keep | Keeps all matched values. |
| p | drop | Drops all matched values. |
| rr | reroll | Rerolls all matched values until none match. (Dice only) |
| ro | reroll once | Rerolls all matched values once. (Dice only) |
| ra | reroll and add | Rerolls all matched values once, keeping the original roll. (Dice only) |
| e | explode on | Rolls another die for each matched value. (Dice only) |
| mi | minimum | Sets the minimum value of each die. (Dice only) |
| ma | maximum | Sets the maximum value of each die. (Dice only) |
Selectors
Selectors select from the remaining kept values in a set.
| Syntax | Name | Description |
|---|---|---|
| X | literal | All values in this set that are literally this value. |
| hX | highest X | The highest X values in the set. |
| lX | lowest X | The lowest X values in the set. |
| >X | greater than X | All values in this set greater than X. |
| <X | less than X | All values in this set less than X. |
Unary Operations
| Syntax | Name | Description |
|---|---|---|
| +X | positive | Does nothing. |
| -X | negative | The negative value of X. |
Binary Operations
| Syntax | Name |
|---|---|
| X * Y | multiplication |
| X / Y | division |
| X // Y | int division |
| X % Y | modulo |
| X + Y | addition |
| X - Y | subtraction |
| X == Y | equality |
| X >= Y | greater/equal |
| X <= Y | less/equal |
| X > Y | greater than |
| X < Y | less than |
| X != Y | inequality |
Examples
>>> from d20 import roll
>>> r = roll("4d6kh3") # highest 3 of 4 6-sided dice
>>> r.total
14
>>> str(r)
'4d6kh3 (4, 4, **6**, ~~3~~) = `14`'
>>> r = roll("2d6ro<3") # roll 2d6s, then reroll any 1s or 2s once
>>> r.total
9
>>> str(r)
'2d6ro<3 (**~~1~~**, 3, **6**) = `9`'
>>> r = roll("8d6mi2") # roll 8d6s, with each die having a minimum roll of 2
>>> r.total
33
>>> str(r)
'8d6mi2 (1 -> 2, **6**, 4, 2, **6**, 2, 5, **6**) = `33`'
>>> r = roll("(1d4 + 1, 3, 2d6kl1)kh1") # the highest of 1d4+1, 3, and the lower of 2 d6s
>>> r.total
3
>>> str(r)
'(1d4 (2) + 1, ~~3~~, ~~2d6kl1 (2, 5)~~)kh1 = `3`'
Custom Stringifier
By default, d20 stringifies the result of each dice roll formatted in Markdown, which may not be useful in your application.
To change this behaviour, you can create a subclass of d20.Stringifier
(or d20.SimpleStringifier as a starting point), and implement the _str_* methods to customize how your dice tree is stringified.
Then, simply pass an instance of your stringifier into the roll() function!
>>> import d20
>>> class MyStringifier(d20.SimpleStringifier):
... def _stringify(self, node):
... if not node.kept:
... return 'X'
... return super()._stringify(node)
...
... def _str_expression(self, node):
... return f"The result of the roll {self._stringify(node.roll)} was {int(node.total)}"
>>> result = d20.roll("4d6e6kh3", stringifier=MyStringifier())
>>> str(result)
'The result of the roll 4d6e6kh3 (X, 5, 6!, 6!, X, X) was 17'
Annotations and Comments
Each dice node supports value annotations - i.e., a method to "tag" parts of a roll with some indicator. For example,
>>> from d20 import roll
>>> str(roll("3d6 [fire] + 1d4 [piercing]"))
'3d6 (3, 2, 2) [fire] + 1d4 (3) [piercing] = `10`'
>>> str(roll("-(1d8 + 3) [healing]"))
'-(1d8 (7) + 3) [healing] = `-10`'
>>> str(roll("(1 [one], 2 [two], 3 [three])"))
'(1 [one], 2 [two], 3 [three]) = `6`'
are all examples of valid annotations. Annotations are purely visual and do not affect the evaluation of the roll by default.
Additionally, when allow_comments=True is passed to roll(), the result of the roll may have a comment:
>>> from d20 import roll
>>> result = roll("1d20 I rolled a d20", allow_comments=True)
>>> str(result)
'1d20 (13) = `13`'
>>> result.comment
'I rolled a d20'
Note that while allow_comments is enabled, AST caching is disabled, which may lead to slightly worse performance.
Traversing Dice Results
The raw results of dice rolls are returned in Expression
objects, which can be accessed as such:
>>> from d20 import roll
>>> result = roll("3d6 + 1d4 + 3")
>>> str(result)
'3d6 (4, **6**, **6**) + 1d4 (**1**) + 3 = `20`'
>>> result.expr
<Expression roll=<BinOp left=<BinOp left=<Dice num=3 size=6 values=[<Die size=6 values=[<Literal 4>]>, <Die size=6 values=[<Literal 6>]>, <Die size=6 values=[<Literal 6>]>] operations=[]> op=+ right=<Dice num=1 size=4 values=[<Die size=4 values=[<Literal 1>]>] operations=[]>> op=+ right=<Literal 3>> comment=None>
or, in a easier-to-read format,
<Expression roll=
<BinOp left=
<BinOp left=
<Dice num=3 size=6 values=
[
<Die size=6 values=[<Literal 4>]>,
<Die size=6 values=[<Literal 6>]>,
<Die size=6 values=[<Literal 6>]>
]
operations=[]>
op=+
right=<Dice num=1 size=4 values=
[<Die size=4 values=[<Literal 1>]>]
operations=[]>
>
op=+
right=<Literal 3>
>
comment=None>
From here, Expression.children returns a tree of nodes representing the expression from left to right, each of which
may have children of their own. This can be used to easily search for specific dice, look for the left-most operand,
or modify the result by adding in resistances or other modifications.
Examples
Finding the left and right-most operands:
>>> from d20 import roll
>>> binop = roll("1 + 2 + 3 + 4")
>>> left = binop.expr
>>> while left.children:
... left = left.children[0]
>>> left
<Literal 1>
>>> right = binop.expr
>>> while right.children:
... right = right.children[-1]
>>> right
<Literal 4>
Searching for the d4:
>>> from d20 import roll, Dice, SimpleStringifier
>>> mixed = roll("-1d8 + 4 - (3, 1d4)kh1")
>>> str(mixed)
'-1d8 (**8**) + 4 - (3, ~~1d4 (3)~~)kh1 = `-7`'
>>> root = mixed.expr
>>> def dfs(node, predicate):
... if predicate(node):
... return node
... for branch in node.children:
... result = dfs(branch, predicate)
... if result:
... return result
... return None
>>> result = dfs(root, lambda node: isinstance(node, Dice) and node.num == 1 and node.size == 4)
>>> result
<Dice num=1 size=4 values=[<Die size=4 values=[<Literal 3>]>] operations=[]>
>>> SimpleStringifier().stringify(result)
'1d4 (3)'
As a note, even though a Dice object is the parent of Die objects, Dice.children returns an empty list, since it's
more common to look for the dice, and not each individual component of that dice.
Performance
By default, the parser caches the 256 most frequently used dice expressions in an LFU cache, allowing for a significant
speedup when rolling many of the same kinds of rolls. This caching is disabled when allow_comments is True.
With caching:
$ python3 -m timeit -s "from d20 import roll" "roll('1d20')"
10000 loops, best of 5: 21.6 usec per loop
$ python3 -m timeit -s "from d20 import roll" "roll('100d20')"
500 loops, best of 5: 572 usec per loop
$ python3 -m timeit -s "from d20 import roll; expr='1d20+'*50+'1d20'" "roll(expr)"
500 loops, best of 5: 732 usec per loop
$ python3 -m timeit -s "from d20 import roll" "roll('10d20rr<20')"
1000 loops, best of 5: 1.13 msec per loop
Without caching:
$ python3 -m timeit -s "from d20 import roll" "roll('1d20')"
5000 loops, best of 5: 61.6 usec per loop
$ python3 -m timeit -s "from d20 import roll" "roll('100d20')"
500 loops, best of 5: 620 usec per loop
$ python3 -m timeit -s "from d20 import roll; expr='1d20+'*50+'1d20'" "roll(expr)"
500 loops, best of 5: 2.1 msec per loop
$ python3 -m timeit -s "from d20 import roll" "roll('10d20rr<20')"
1000 loops, best of 5: 1.26 msec per loop
Documentation
TODO
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