Crates.io | tgraph |
lib.rs | tgraph |
version | 0.2.2 |
source | src |
created_at | 2022-04-25 18:34:20.009628 |
updated_at | 2022-04-30 17:28:34.527556 |
description | A simple terminal graphing library |
homepage | |
repository | https://github.com/HipyCas/tgraph |
max_upload_size | |
id | 574043 |
size | 301,858 |
tgraph
:warning:
tgraph
is currently in active development, so interfaces and documentation are in a very early stage
Plain-simple Rust crate providing for drawing graphs in the terminal based on a function. It provides an interface for drawing the graph of a function by passing a Rust closure/function, also enabling you to draw multiple functions inside the same graph.
To draw a function, a wrapper that represents a graph is used. There are two types of graphs: a single function graph (Graph
) and a multiple function graph (MultiGraph
). Although you could just use MultiGraph
, for single functions Graph
is recommended, as MultiGraph
adds some code not needed just for one function.
Both structs provide the same interface. To create a graph (used Graph
for simplicity, for MultiGraph
see the docs), you use Graph::new(f, width: u32, height: Option<u32>)
where f
is the function/closure (further explained below) and height
is automatically set if None
is passed, or you can also use Graph::new_screen(f, height: Option<u32>)
which picks up the width of the screen. If you want to customize the graph with options, you can call Graph::with_options
and Graph::with_options_screen
respectively and pass a GraphOptions
struct as last parameter (see more in the Graph Customization section).
Functions that can be drawn are restricted to types that implement the tgraph::AsF64
trait, which allows the parameters of the function to be created from a f64
and the result of the function to be converted to a f64
, as drawing in the screen is made pixel by pixel. You can implement this trait to whichever type you want, meaning that a struct representing people can be drawn as part of a graph is you implement tgraph::AsF64
on it.
To write functions for the graph, a func!
macro is provided, which provides a easy and simple syntax to create function instances easier and provide a more straightforward use of functions in MultiGraph
(due to the fact that functions/closures with same types have different signatures, so you have to append as fn(X) -> Y
, where X
and Y
are the types of the input and output, respectively).
To draw the the graph, it is as simple as calling .draw()
on Graph
or MultiGraph
, and this will draw the graph to the terminal where the binary was executed. Another option that is available, is printing the instance, so if graph
is your Graph
or MultiGraph
instance, println!("{}", graph)
will print your graph to the screen too (note that debug print will not, just display print).
To customize how a graph is printed, you can use the GraphOptions
with Graph
or MultiGraphOptions
, which is a simple tupple struct wrapping a Vec<GraphOptions>
where each GraphOption
is associated to the function in the same position in the passed functions vector, for MultiGraph
. From here on, GraphOptions
will be explained, as MultiGraphOptions
currently only wraps the previous.
To customize the graph color, use the GraphOptions.color
field, which holds a wrapper struct (tgraph::ColorWrapper
) for the console_engine::Color
enum, passing a console_engine::Color
variant and calling .into()
to easily convert it into the wrapper type. The character used is controlled with the tgraph::Character
enum, which has a couple variants for predefined characters that we think fit good a graph representation and a variant to represent any character, that can easily be used by calling .into()
in a char or manually selecting a variant. The last option is showing or hiding the y-axis legend, which currently is only supported in Graph
under GraphOptions.height_legend
(one of the reasons while config interface will soon change).
Both GraphOptions
and MultiGraph
implement Default
, so you don't really have to worry about configuring it if not needed. GraphOptions
also makes use of the typed_builder
crate to offer a nice builder interface (for more info on it check the docs for the typed_builder
crate).
Single function graph:
Graph::with_options_screen(
func!(|x| 0.005 * (x * x) + 0.1 * x),
GraphOptions::builder()
.color(Color::DarkMagenta.into())
.build(),
)
.draw();
Multiple function graph:
println!(
"{}",
MultiGraph::new(
vec![
func!(x -> 10f64 -(x/5f64)),
func!(x -> f64::sin(x/2f64).abs() * 4f64),
func!(x -> x.ln()),
],
80,
None,
)
);
Comparing both examples, you can se the two ways to render the graph, as well as the different ways to declare a function using the func!
macro.