Crate udatatable

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Data collection Rust library for embedded systems, such as the Arduino.

Overview

This library enables the creation of an array of a generic type with a maximum capacity of rows. This crate is meant to be used with the ufmt crate in a no_std environment. It was specifically created for sensor data collection on small microcrontrollers, such as the Arduino.

All data is saved on the stack, so no heap allocations are required. Column names are defined for the row type when the data table is created. The data table can be appended to up to the maximum number of rows defined at compile time. The data table contents can be erased to reset the length to zero.

A uDataTable structure can be displayed with ufmt using the uDisplay or uDebug trait. The intent is to use the uDisplay trait to print the data in a csv format and the uDebug trait to print the headers and the length of the table. You must define the uDisplay and uDebug traits for the row type if your row type is not a primitive type.

The uDataTable structure can also be plotted with the optional plot feature. The plot method requires a function that takes a reference to the row type and returns an i32. The plot method will plot the values returned by the function for each row in the data table.

Usage

Add the following to your Cargo.toml file to use the udatatable crate.

[dependencies]
udatatable = "0.1"

Features

  • plot - Enables the plot method. This was made an option feature to allow you to keep your code size small if you don’t need the plot method.

Example

Create a data table, append rows, and display the contents. Note that the row type must implement the Copy, Default, uDebug, and uDisplay traits.

use ufmt::{uDebug, uDisplay, uWrite, uwrite, uwriteln, Formatter};
use udatatable::uDataTable;

// Define the row type
#[derive(Copy, Clone, Default)]
struct Row {
    a: u32,
    b: u32,
    c: u32,
}

// Define the uDisplay and uDebug traits for the row type
impl uDebug for Row {
    fn fmt<W>(&self, f: &mut Formatter<'_, W>) -> Result<(), W::Error>
    where
        W: uWrite + ?Sized,
    {
        uwrite!(f, "Row {{ a: {}, b: {}, c: {} }}", self.a, self.b, self.c)
    }
}

impl uDisplay for Row {
    fn fmt<W>(&self, f: &mut Formatter<'_, W>) -> Result<(), W::Error>
    where
        W: uWrite + ?Sized,
    {
        // The uDisplay trait is meant to print the data in a csv format
        uwrite!(f, "{}, {}, {}", self.a, self.b, self.c)
    }
}

// Create the data table
const N: usize = 10;
const M: usize = 3;
let mut table = uDataTable::<Row, N, M>::new(["a", "b", "c"]);

// Append rows to the data table
for i in 0..5 {
    let row = Row {
        a: i as u32,
        b: i as u32 * 2,
        c: i as u32 * 3,
    };
    if let Err(error) = table.append(row) {
        // handle the error
    }
}

assert_eq!(table.length(), 5);
assert_eq!(*table.headers(), ["a", "b", "c"]);
assert_eq!(table.get(0).unwrap().a, 0);
assert_eq!(table.get(0).unwrap().b, 0);
assert_eq!(table.get(0).unwrap().c, 0);
assert_eq!(table.get(1).unwrap().a, 1);
assert_eq!(table.get(1).unwrap().b, 2);
assert_eq!(table.get(1).unwrap().c, 3);
assert_eq!(table.get(2).unwrap().a, 2);
assert_eq!(table.get(2).unwrap().b, 4);
assert_eq!(table.get(2).unwrap().c, 6);

// Display the data table
let mut s = String::new();
ufmt::uwrite!(&mut s, "{}", table).ok();
assert_eq!(s, "\"a\",\"b\",\"c\"\n0, 0, 0\n1, 2, 3\n2, 4, 6\n3, 6, 9\n4, 8, 12\n");

// Display the data table with uDebug
let mut s = String::new();
ufmt::uwrite!(&mut s, "{:?}", table).ok();
assert_eq!(s, "uDataTable<[\"a\", \"b\", \"c\"], length: 5>");

#[cfg(feature = "plot")]
{
    // graph the data table for value `a`
    let mut s = String::new();
    table.plot(&mut s, |row| row.a as i32);
    assert_eq!(s, "4 |    *\n  |   *.\n  |  *..\n  | *...\n0 |*....\n");
}

Structs

Enums