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# Operators | |
## Pre-defined | |
First, note that pretty much any valid Julia function which | |
takes one or two scalars as input, and returns on scalar as output, | |
is likely to be a valid operator[^1]. | |
A selection of these and other valid operators are stated below. | |
**Binary** | |
- `+` | |
- `-` | |
- `*` | |
- `/` | |
- `^` | |
- `max` | |
- `min` | |
- `mod` | |
- `cond` | |
- Equal to `(x, y) -> x > 0 ? y : 0` | |
- `greater` | |
- Equal to `(x, y) -> x > y ? 1 : 0` | |
- `logical_or` | |
- Equal to `(x, y) -> (x > 0 || y > 0) ? 1 : 0` | |
- `logical_and` | |
- Equal to `(x, y) -> (x > 0 && y > 0) ? 1 : 0` | |
**Unary** | |
- `neg` | |
- `square` | |
- `cube` | |
- `exp` | |
- `abs` | |
- `log` | |
- `log10` | |
- `log2` | |
- `log1p` | |
- `sqrt` | |
- `sin` | |
- `cos` | |
- `tan` | |
- `sinh` | |
- `cosh` | |
- `tanh` | |
- `atan` | |
- `asinh` | |
- `acosh` | |
- `atanh_clip` | |
- Equal to `atanh(mod(x + 1, 2) - 1)` | |
- `erf` | |
- `erfc` | |
- `gamma` | |
- `relu` | |
- `round` | |
- `floor` | |
- `ceil` | |
- `round` | |
- `sign` | |
## Custom | |
Instead of passing a predefined operator as a string, | |
you can just define a custom function as Julia code. For example: | |
```python | |
PySRRegressor( | |
..., | |
unary_operators=["myfunction(x) = x^2"], | |
binary_operators=["myotherfunction(x, y) = x^2*y"], | |
extra_sympy_mappings={ | |
"myfunction": lambda x: x**2, | |
"myotherfunction": lambda x, y: x**2 * y, | |
}, | |
) | |
``` | |
Make sure that it works with | |
`Float32` as a datatype (for default precision, or `Float64` if you set `precision=64`). That means you need to write `1.5f3` | |
instead of `1.5e3`, if you write any constant numbers, or simply convert a result to `Float64(...)`. | |
PySR expects that operators not throw an error for any input value over the entire real line from `-3.4e38` to `+3.4e38`. | |
Thus, for invalid inputs, such as negative numbers to a `sqrt` function, you may simply return a `NaN` of the same type as the input. For example, | |
```julia | |
my_sqrt(x) = x >= 0 ? sqrt(x) : convert(typeof(x), NaN) | |
``` | |
would be a valid operator. The genetic algorithm | |
will preferentially selection expressions which avoid | |
any invalid values over the training dataset. | |
<!-- Footnote for 1: --> | |
<!-- (Will say "However, you may need to define a `extra_sympy_mapping`":) --> | |
[^1]: However, you will need to define a sympy equivalent in `extra_sympy_mapping` if you want to use a function not in the above list. | |