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Merge pull request 'fb driver' (#16) from aurlex/ableos-framebuffer:master into master

Reviewed-on: https://git.ablecorp.us/AbleOS/ableos/pulls/16
This commit is contained in:
able 2024-08-21 03:26:45 +00:00
commit db08a249e1
15 changed files with 411 additions and 15 deletions

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@ -336,8 +336,8 @@ fn run(release: bool, target: Target) -> Result<(), Error> {
"-drive", "file=target/disk.img,format=raw", "-drive", "file=target/disk.img,format=raw",
"-m", "4G", "-m", "4G",
"-smp", "cores=4", "-smp", "cores=4",
// "-enable-kvm", "-enable-kvm",
"-cpu", "Broadwell-v4", "-cpu", "host",
"-device", "isa-debug-exit,iobase=0xf4,iosize=0x04" "-device", "isa-debug-exit,iobase=0xf4,iosize=0x04"
]); ]);
} }

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@ -2,3 +2,4 @@ string := @use("rel:string.hb")
log := @use("rel:log.hb") log := @use("rel:log.hb")
memory := @use("rel:memory.hb") memory := @use("rel:memory.hb")
buffer := @use("rel:buffer.hb") buffer := @use("rel:buffer.hb")
math := @use("rel:math.hb")

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@ -0,0 +1,7 @@
abs := fn(x: int): int {
mask := x >> 31
return (x ^ mask) - mask
}
min := fn(a: int, b: int): int {
return b + (a - b & a - b >> 31)
}

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@ -0,0 +1,7 @@
color.blend
lib.composite
lib.screen2rect
lib.rect2screen
draw.tri_line

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@ -1,6 +1,6 @@
[package] [package]
name = "fb_driver" name = "fb_driver"
authors = ["able"] authors = ["able", "aurlex"]
[dependants.libraries] [dependants.libraries]

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@ -0,0 +1,27 @@
ColorBGRA := struct {b: u8, g: u8, r: u8, a: u8}
/* ALL the colo(u)rs you will ever need.
they dont work though, cause hblang bug (reg id leaked, again) */
WHITE := ColorBGRA.{b: 255, g: 255, r: 255, a: 255}
BLACK := ColorBGRA.{b: 0, g: 0, r: 0, a: 255}
GRAY := ColorBGRA.{b: 127, g: 127, r: 127, a: 255}
RED := ColorBGRA.{b: 0, g: 0, r: 205, a: 255}
GREEN := ColorBGRA.{b: 0, g: 205, r: 0, a: 255}
YELLOW := ColorBGRA.{b: 0, g: 205, r: 205, a: 255}
BLUE := ColorBGRA.{b: 205, g: 0, r: 0, a: 255}
MAGENTA := ColorBGRA.{b: 205, g: 0, r: 205, a: 255}
CYAN := ColorBGRA.{b: 205, g: 205, r: 0, a: 255}
LIGHTGRAY := ColorBGRA.{b: 229, g: 229, r: 229, a: 255}
LIGHTRED := ColorBGRA.{b: 0, g: 0, r: 255, a: 255}
LIGHTGREEN := ColorBGRA.{b: 0, g: 255, r: 0, a: 255}
LIGHTYELLOW := ColorBGRA.{b: 0, g: 255, r: 255, a: 255}
LIGHTBLUE := ColorBGRA.{b: 255, g: 0, r: 0, a: 255}
LIGHTMAGENTA := ColorBGRA.{b: 255, g: 0, r: 255, a: 255}
LIGHTCYAN := ColorBGRA.{b: 255, g: 255, r: 0, a: 255}
// i have no clue if this works. please don't me ask how it works. -aurlex
blend := fn(fg: ColorBGRA, bg: ColorBGRA): ColorBGRA {
s := fg + bg
m := s - ((fg ^ bg) & 16843008) & 16843008
return (m >> 8 | 16777216 * (s < fg)) * 255 | s - m
}

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@ -0,0 +1,113 @@
.{draw_pixel, screenidx, Transform, Point, Rect, Buffer, FB_WIDTH} := @use("rel:lib.hb")
ColorBGRA := @use("rel:color.hb").ColorBGRA
math := @use("../../../libraries/stn/src/lib.hb").math
/* draws a filled rectangle to the screen
will be optimised later */
rect_fill := fn(buffer: Buffer, pos: Point, tr: Transform, color: ColorBGRA): void {
n := 0
loop if n == tr.height * tr.width break else {
*(buffer.write + screenidx(.(n % tr.width + pos.x, n / tr.width + pos.y))) = color
n += 1
}
return
}
/* draws a wireframe rectangle to the screen
will also be optimised later */
rect_line := fn(buffer: Buffer, pos: Point, tr: Transform, color: ColorBGRA, thickness: int): void {
t := 0
y := 0
x := 0
loop if t == thickness break else {
y = pos.y
x = pos.x
loop if y == pos.y + tr.height break else {
*(buffer.write + pos.x + t + FB_WIDTH * y) = color;
*(buffer.write + pos.x + tr.width - t + FB_WIDTH * y) = color
y += 1
}
loop if x == pos.x + tr.width break else {
*(buffer.write + x + (pos.y + t) * FB_WIDTH) = color;
*(buffer.write + x + (pos.y + tr.height - t) * FB_WIDTH) = color
x += 1
}
t += 1
}
return
}
// do not use, use line() instead
line_low := fn(buffer: Buffer, p0: Point, p1: Point, color: ColorBGRA): void {
dx := p1.x - p0.x
dy := p1.y - p0.y
yi := 1
if dy < 0 {
yi = 0 - 1
dy = 0 - dy
}
D := 2 * dy - dx
y := p0.y
x := p0.x
loop if x == p1.x break else {
*(buffer.write + x + y * FB_WIDTH) = color
if D > 0 {
y += yi
D += 2 * (dy - dx)
} else {
D += 2 * dy
}
x += 1
}
return
}
// do not use, use line() instead
line_high := fn(buffer: Buffer, p0: Point, p1: Point, color: ColorBGRA): void {
dx := p1.x - p0.x
dy := p1.y - p0.y
xi := 1
if dy < 0 {
xi = 0 - 1
dx = 0 - dx
}
D := 2 * dx - dy
x := p0.x
y := p0.y
loop if y == p1.y break else {
*(buffer.write + x + y * FB_WIDTH) = color
if D > 0 {
x += xi
D += 2 * (dx - dy)
} else {
D += 2 * dx
}
y += 1
}
return
}
/* implementation of Bresenham's line algorithm
TODO: thickness, might need better math library */
line := fn(buffer: Buffer, p0: Point, p1: Point, color: ColorBGRA, thickness: int): void {
if math.abs(p1.y - p0.y) < math.abs(p1.x - p0.x) {
if p0.x > p1.x {
line_low(buffer, p1, p0, color)
} else {
line_low(buffer, p0, p1, color)
}
} else {
if p0.y > p1.y {
line_high(buffer, p1, p0, color)
} else {
line_high(buffer, p0, p1, color)
}
}
return
}
// theoretically draws a wireframe polygon to the screen. untested.
tri_line := fn(buffer: Buffer, p0: Point, p1: Point, p2: Point, color: ColorBGRA, thickness: int): void {
line(buffer, p0, p1, color, thickness)
line(buffer, p1, p2, color, thickness)
line(buffer, p2, p0, color, thickness)
return
}

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@ -0,0 +1,26 @@
.{rect_line} := @use("../draw.hb");
.{present, create_buffer, clear} := @use("../lib.hb")
/* expected result:
the impostor travels left and loops around the screen */
example := fn(): void {
// Creates a back buffer, which we write to, to avoid screen flickering
buffer := create_buffer()
x := 0
loop {
// draw all our shapes to the back buffer
rect_line(buffer, .(200 - x, 80), .(430, 380), .(0, 0, 255, 0), 1)
rect_line(buffer, .(630 - x, 120), .(120, 300), .(0, 0, 255, 0), 1)
rect_line(buffer, .(200 - x, 460), .(160, 270), .(0, 0, 255, 0), 1)
rect_line(buffer, .(470 - x, 460), .(160, 270), .(0, 0, 255, 0), 1)
rect_line(buffer, .(140 - x, 140), .(340, 250), .(255, 255, 0, 0), 1)
/* push the back buffer to the front buffer
this displays our image to the screen */
present(buffer)
// erase our old image
clear(buffer, .(0, 0, 0, 0))
x += 1
}
return
}

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@ -0,0 +1,27 @@
.{clear, create_buffer, present} := @use("../lib.hb");
.{ColorBGRA} := @use("../color.hb")
/* expected result:
the screen fades from green to cyan
then wraps back to green
note that this may happen too fast for you to notice... */
example := fn(): void {
// creates a back buffer, which we write to, to avoid screen flickering
buffer := create_buffer()
color := ColorBGRA.(0, 255, 0, 255)
/* have to explicitly say 0 is a u8, or we do something crazy to the colors.
looks like a compiler bug */
n := @as(i8, @as(u8, 0)) - 1
loop {
clear(buffer, color)
present(buffer)
/* because for some reason just comparing doesnt work.
also looks like a compiler bug */
if (color.b & 255) == 255 | (color.b & 255) == 0 {
n = 0 - n
}
color.b += n
}
return
}

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@ -0,0 +1,19 @@
.{front_buffer_ptr, front_buffer_copy, get_front_buffer, Buffer} := @use("../lib.hb");
example := fn(): void {
// you can get the raw frontbuffer pointer using
raw_buffer := front_buffer_ptr
// this buffer is the one that you write individual pixels to
// you can gete the copy frontbuffer pointer using
copy_buffer := copy_buffer_ptr
/* this buffer is used for massive writing
operations by taking advantage of
static copying */
// you can construct a buffer like so
buffer := Buffer.{write: raw_buffer, copy: copy_buffer}
// this is the operation that get_front_buffer does
same_buffer := get_front_buffer()
return
}

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@ -0,0 +1,25 @@
.{line} := @use("../draw.hb");
.{clear, create_buffer, present, FB_WIDTH, FB_HEIGHT, Point} := @use("../lib.hb")
/* expected result:
a 3d-looking blue set of lines
created on a blue background */
example := fn(): void {
// creates a back buffer, which we write to, to avoid screen flickering
buffer := create_buffer()
// fill the screen in blue
clear(buffer, .(100, 50, 0, 255))
p0 := Point.(0, 0 - 1)
p1 := Point.(0, FB_HEIGHT - 1)
loop if p0.y >= FB_HEIGHT break else {
// draw a line between p0 and p1
line(buffer, p0, p1, .(255, 180, 100, 255), 3)
p0.y += FB_HEIGHT >> 6
p1.x += FB_WIDTH >> 6
}
/* push the back buffer to the front buffer
this displays our image to the screen */
present(buffer)
return
}

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@ -0,0 +1,32 @@
.{rect_line} := @use("../draw.hb");
.{clear, create_buffer, present, Point, FB_HEIGHT, FB_WIDTH} := @use("../lib.hb")
/* expected result:
the white outline of a square bounces around the screen */
example := fn(): void {
// creates a back buffer, which we write to, to avoid screen flickering
buffer := create_buffer()
vel := Point.{x: 1, y: 1}
pos := Point.{x: 100, y: 100}
loop {
// draw the square at our current position
rect_line(buffer, pos, .(100, 100), .(255, 255, 255, 255), 3)
/* push the back buffer to the front buffer
this displays our image to the screen */
present(buffer)
// erase our old image
clear(buffer, .(0, 0, 0, 0))
// bounce the square if it touches the screen edges
if pos.x == 0 | pos.x == FB_WIDTH - 100 {
vel.x = 0 - vel.x
}
if pos.y == 0 | pos.y == FB_HEIGHT - 100 {
vel.y = 0 - vel.y
}
pos += vel
}
return
}

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@ -0,0 +1,20 @@
.{clear, create_buffer, present} := @use("../lib.hb")
/* expected result: (EPILEPSY WARNING)
the screen rapidly flashes red then black */
example := fn(): void {
// creates a back buffer, which we write to, to avoid screen flickering
buffer := create_buffer()
loop {
// screen go red
clear(buffer, .(0, 0, 255, 0))
// show the red
present(buffer)
// screen go black
clear(buffer, .(0, 255, 255, 0))
// show the black
present(buffer)
}
return
}

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@ -0,0 +1,100 @@
.{memory, log, math} := @use("../../../libraries/stn/src/lib.hb");
.{ColorBGRA, blend} := @use("rel:color.hb")
FB_WIDTH := 1024
FB_HEIGHT := 768
FB_PIXELS := FB_WIDTH * FB_HEIGHT
FB_BYTES := FB_PIXELS << 2
// actual enforced max copy size is (1 << 16) - 1, but this was faster
MAX_COPY_SIZE := 6144
// see stn.math.min, cant use here due to compiler bug (reg id leaked)
COPY_PIXELS := MAX_COPY_SIZE + (FB_BYTES - MAX_COPY_SIZE & FB_BYTES - MAX_COPY_SIZE >> 31) >> 2
PARTITIONS := FB_PIXELS / COPY_PIXELS
TOTAL_PAGES := 1 + FB_BYTES >> 12
Buffer := struct {write: ^ColorBGRA, copy: ^[ColorBGRA; COPY_PIXELS]}
Point := struct {x: int, y: int}
Transform := struct {width: int, height: int}
Rect := struct {p1: Point, p2: Point}
front_buffer_ptr := @as(^ColorBGRA, @bitcast(18446603339442421760))
front_buffer_copy := @as(^[ColorBGRA; COPY_PIXELS], @bitcast(front_buffer_ptr))
get_front_buffer := fn(): Buffer {
// trying to return front_buffer_ptr or front_buffer_copy causes reg id leak
return Buffer.{write: @as(^ColorBGRA, @bitcast(18446603339442421760)), copy: @as(^[ColorBGRA; COPY_PIXELS], @bitcast(18446603339442421760))}
}
/* this is separate to create_raw_buffer because returning a Buffer from
create_raw_buffer causes reg id leak */
create_buffer := fn(): Buffer {
ptr := create_raw_buffer()
ptr_copy := @as(^[ColorBGRA; COPY_PIXELS], @bitcast(ptr))
// same here, bitcasting inside the struct literal causes reg id leak
buffer := Buffer.{write: ptr, copy: ptr_copy}
return buffer
}
create_raw_buffer := fn(): ^ColorBGRA {
// helps to trace allocation bugs
log.info("Creating buffer. This will allocate.\0")
if TOTAL_PAGES <= 255 {
return @bitcast(memory.request_page(TOTAL_PAGES))
}
ptr := memory.request_page(255)
remaining := TOTAL_PAGES - 255
loop if remaining <= 0 break else {
if remaining < 255 {
memory.request_page(remaining)
} else {
memory.request_page(255)
}
remaining -= 255
}
return @bitcast(ptr)
}
// sets the buffer to the color. very fast.
clear := fn(buffer: Buffer, color: ColorBGRA): void {
n := 0
// write the first pixel chunk
loop if n >= COPY_PIXELS break else {
*(buffer.write + n) = color
n += 1
}
n = 1
// copy that pixel chunk through the buffer, taking advantage of memory copying
loop if n >= PARTITIONS break else {
*(buffer.copy + n) = *buffer.copy
n += 1
}
return
}
// only required to be called when using a back buffer. if using single-buffered rendering, do not call this.
present := fn(buffer: Buffer): void {
offset := 0
// copy chunks of the read buffer to the front buffer
loop if offset >= PARTITIONS break else {
*(front_buffer_copy + offset) = *(buffer.copy + offset)
offset += 1
}
return
}
// composites the contents of buffer1 into buffer2, accounting for alpha transparency
// i dont know if it works. i have not tested it. it probably doesnt work
composite := fn(buffer1: Buffer, buffer2: Buffer): void {
n := 0
loop if n == FB_PIXELS break else {
bg := *(buffer2.write + n);
*(buffer2.write + n) = blend(*(buffer1.write + n), bg)
n += 1
}
return
}
// really need to be able to inline this please - aurlex
screenidx := fn(pos: Point): int {
return pos.x + FB_WIDTH * pos.y
}
point2rect := fn(pos: Point, tr: Transform): Rect {
return .(pos, .(pos.x + tr.x, pos.y + tr.y))
}
rect2point := fn(rect: Rect): struct {point: Point, transform: Transform} {
return .(.(0, 0), .(0, 0))
}

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@ -1,15 +1,7 @@
frame_buffer := @as(^u8, @bitcast(18446603339442421760)) // change "lines.hb" to another example to see it onscreen
example := @use("examples/lines.hb").example
main := fn(): int { main := fn(): int {
color := 17 example()
loop {
len := 786432 * 4 + 1
loop if len == 0 break else {
fb := frame_buffer + len;
*fb = color
len -= 1
color += len
}
}
return 0 return 0
} }