React high-order useEffect wrappers

As I was increasingly upset with the lack of variable highlighting in Volar, I started doing some React experiments.

In particular, I found the useEffects hook API very annoying, because it fails to communicate the intent of what you’re trying to accomplish.

So, I order to mitigate this, I wrote a few wrappers:

import {DependencyList, useEffect} from 'react';

function onMount(fun: () => void) {
	useEffect(() => { fun(); }, []);
}

function onUmnount(fun: () => void) {
	useEffect(() => {
		return () => { fun(); };
	}, []);
}

function onMutate(dep: DependencyList, fun: () => void) {
	useEffect(() => { fun(); }, dep);
}

As far as I could test, they work really well, with the advantage that you can pass async functions to them:

function Foo() {
	const [name, setName] = useState('');

	onMount(async () => {
		console.log('hello async');
	});

	onUmnount(() => {
		console.log('unmounted');
	});

	onMutate([name], () => {
		console.log('updated', name);
	});

	return <div>Hello {name}</div>;
}

I’m somewhat tempted to create a library for this. And maybe other high-order wrappers.

Cross-compiling Rust in Windows

After making a lot of confusion with Rust cross-compiling, I finally managed to compile WinSafe x32 programs in my Windows x64. The root of the misunderstanding is that, in order to cross compile, you must have the following installed:

• MSVC build tools;
• Rust toolchain;
• Rust target.

Toolchain relevant commands:

rustup toolchain list
rustup toolchain install stable-i686-pc-windows-msvc
rustup toolchain uninstall stable-i686-pc-windows-msvc

Target relevant commands:

rustup target list | grep installed
rustup target add i686-pc-windows-msvc --toolchain stable
rustup target remove i686-pc-windows-msvc

To verify if you program has any linker issues, build and run:

rustup run stable-i686-pc-windows-msvc cargo run
rustup run stable-x86_64-pc-windows-msvc cargo run

Then finally the program can be built for release with:

RUSTFLAGS='-C target-feature=+crt-static' cargo build --release --target i686-pc-windows-msvc
RUSTFLAGS='-C target-feature=+crt-static' cargo build --release --target x86_64-pc-windows-msvc

I only found all that stuff after posting a question on StackOverflow and receiving this comment. The documentation was completely absent in providing any useful information.

Taking a screenshot in Windows with Go

I’ve tried to code a Windows screenshot utility before, following the example of the official Windows documentation I found it tricky though, so I just gave up at the time.

This Monday morning, after receiving a request to implement GetDIBits in WinSafe, I tried to implement it Windigo first. To my surprise, it went incredibly smooth. Go’s defer mechanism is much to praise.

Here’s the whole code

package main

import (
	"runtime"
	"unsafe"

	"github.com/rodrigocfd/windigo/win"
	"github.com/rodrigocfd/windigo/win/co"
)

func main() {
	runtime.LockOSThread()

	cxScreen := win.GetSystemMetrics(co.SM_CXSCREEN)
	cyScreen := win.GetSystemMetrics(co.SM_CYSCREEN)

	hdcScreen := win.HWND(0).GetDC()
	defer win.HWND(0).ReleaseDC(hdcScreen)

	hBmp := hdcScreen.CreateCompatibleBitmap(cxScreen, cyScreen)
	defer hBmp.DeleteObject()

	hdcMem := hdcScreen.CreateCompatibleDC()
	defer hdcMem.DeleteDC()

	hBmpOld := hdcMem.SelectObjectBitmap(hBmp)
	defer hdcMem.SelectObjectBitmap(hBmpOld)

	hdcMem.BitBlt(
		win.POINT{X: 0, Y: 0},
		win.SIZE{Cx: cxScreen, Cy: cyScreen},
		hdcScreen,
		win.POINT{X: 0, Y: 0},
		co.ROP_SRCCOPY,
	)

	bi := win.BITMAPINFO{
		BmiHeader: win.BITMAPINFOHEADER{
			BiWidth:       cxScreen,
			BiHeight:      cyScreen,
			BiPlanes:      1,
			BiBitCount:    32,
			BiCompression: co.BI_RGB,
		},
	}
	bi.BmiHeader.SetBiSize()

	bmpObj := win.BITMAP{}
	hBmp.GetObject(&bmpObj)
	bmpSize := bmpObj.CalcBitmapSize(bi.BmiHeader.BiBitCount)

	rawMem := win.GlobalAlloc(co.GMEM_FIXED|co.GMEM_ZEROINIT, bmpSize)
	defer rawMem.GlobalFree()

	bmpSlice := rawMem.GlobalLock(bmpSize)
	defer rawMem.GlobalUnlock()

	hdcScreen.GetDIBits(hBmp, 0, int(cyScreen), bmpSlice, &bi, co.DIB_RGB_COLORS)

	bfh := win.BITMAPFILEHEADER{}
	bfh.SetBfType()
	bfh.SetBfOffBits(uint32(unsafe.Sizeof(bfh) + unsafe.Sizeof(bi.BmiHeader)))
	bfh.SetBfSize(bfh.BfOffBits() + uint32(bmpSize))

	fo, _ := win.FileOpen("C:\\Temp\\foo.bmp", co.FILE_OPEN_RW_OPEN_OR_CREATE)
	defer fo.Close()

	fo.Write(bfh.Serialize())
	fo.Write(bi.BmiHeader.Serialize())
	fo.Write(bmpSlice)

	println("Done")
}

For reference, this example is now on GetDIBits documentation.

Generating React object keys with WeakMap

When iterating through an array in React, a key attribute is expected on the rendered elements, so a reordering is properly rendered. However, often the objects we’re rendering have no unique ID and using the plain index will give us a broken rendering when a reorder happens. So what should we use?

My first idea was to use the object itself as the key, but it must be a string or a number. Then, while researching the matter, I found a rather good solution: using a WeakMap object. I wasn’t even aware that such WeakMap existed, and turns out it’s perfect for the job.

A WeakMap is basically a Map which uses objects as keys. The difference from an ordinary Map is that the Map would retain the objects indefinitely – they would simply pile up, what can be seen as a memory leak –, while the WeakMap lets the objects being garbage collected when they are no longer referenced anywhere.

Given that concept imagine the following interface:

interface Person {
	name: string;
	age: number;
}

Now we have a React component which needs to render an array of Person. This is how we can write it:

interface Props {
	people: Person[];
}
	
function ThePeople(props: Props) {
	return <>
		{props.people.map(person =>
			<div key={getId(person)}>
				{person.name}, {person.age}
			</div>
		)}
	</>;
}

Note the getId function in the code above, which somewhat returns an unique ID for the object.

We’ll use a WeakMap to store the Person objects along with an auto-generated number, which will be its unique ID::

let currentId = 0;
let ids = new WeakMap<Object, number>();

export function getId(obj: Object): number {
	if (ids.has(obj)) {
		return ids.get(obj)!;
	} else {
		const newId = ++currentId;
		ids.set(obj, newId);
		return newId;
	}
}

For each object, the ID is set once, and it can be retrieved any number of times. This effectively eliminates the need of an alien _id field in our struct, and it also prevents the memory leaking of using an ordinary Map.

However, when using immutable state – which is basically the norm in React –, you’ll always have different objects, thus different IDs, and this will cause the loss of focus on elements. So, despite its ugliness, an _id attribute is still better. Or, if the list element won’t reorder, a simple index.

VSCode extension Personal Access Token

I received an user request for my Format Comment VSCode extension, which pleases me greatly.

Implementing the feature itself took me just a few minutes, then I spent the next hour trying to figure out how to setup the “Personal Access Token” to publish the extension to the marketplace. So, to avoid this waste of time to my future self, these are the steps:

1. Go to dev.azure.com/rodrigocfd to see the tokens;
2. If necessary, create another one, which will be a long string;
3. Organization must be set to “All Accessible Organizations”;
4. On the project directory, run vsce login rodrigocfd and paste the long string when prompted.

The Personal Access Token lasts at max 1 year, so this process will have to be made at least once a year

Using active/inactive system colors in Firefox

After the horrible Proton UI in Firefox v89, there was no difference between active/inactive window colors. The theme would simply remain static while you switched to other windows, which from the usability point of view, is absurd.

After digging a bit, I found an userChrome.css hack to use the system colors on Firefox window. As of Firefox 98, it appears to work well:

/* Show active colors on main menu bar */
/* https://superuser.com/a/1675508 */
#TabsToolbar,
#navigator-toolbox {
	background: -moz-accent-color !important;
	color: white;
}
#TabsToolbar:-moz-window-inactive,
#navigator-toolbox:-moz-window-inactive {
	background: unset !important;
	color: unset;
}

Just for the record: this is how you activate userChrome.css stuff.

Helix amp: sag, hum, ripple, bias and bias-x

I found a rather interesting video demonstrating the advanced amp parameters of the Line 6 Helix: sag, hum, ripple, bias and bias-x. As a summary, this is what I could infer to them:

• sag – lower is tighter and less dynamics; higher sounds muffled;
• hum – the literal ground hum of the amp;
• ripple – harmonic undertone audible on single notes; hard to hear in a mix;
• bias and bias-x – changes the overdrive character when used together.

Basically, these parameters make close to zero difference in clean tones. Crunch and high gain tones can change in thousands of ways, though.

Back to the tone chasing.