# Drawing a line between two points

Here's what I got so far. I rewrote the code to simplify things a bit. Previous code wasn't actually the real, basic algorithm. It had fluff that I didn't need. I answered the question about pitch, and below you'll see some images of my test results.

``````local function Line (buf, x1, y1, x2, y2, color, pitch)

-- identify the first pixel
local n = x1 + y1 * pitch

-- // difference between starting and ending points
local dx = x2 - x1;
local dy = y2 - y1;

local m = dy / dx
local err = m - 1

if (dx > dy) then   -- // dx is the major axis
local j = y1
local i = x1
while i < x2 do
buf.buffer[j * pitch + i] = color
if (err >= 0) then
i = i + 1
err = err - 1
end
j = j + 1
err = err + m
end
else        -- // dy is the major axis
local j = x1
local i = y1
while i < y2 do
buf.buffer[i * pitch + j] = color
if (err >= 0) then
i = i + 1
err = err - 1
end
j = j + 1
err = err + m
end
end
end

-- (visdata[2][1][576], int isBeat, int *framebuffer, int *fbout, int w, int h
function LibAVSSuperScope:Render(visdata, isBeat, framebuffer, fbout, w, h)
local size = 5

Line (self.buffer, 0, 0, 24, 24, 0xffff00, 24)
do return end
end
``````

Edit: Oh I just realized something. 0,0 is in the lower left-hand corner. So the function's sort of working, but it's overlapping and slanted.

Edit2:

Yeah, this whole thing's broken. I'm plugging numbers into Line() and getting all sort of results. Let me show you some.

Here's `Line (self.buffer, 0, 0, 23, 23, 0x00ffff, 24 * 2)`

And here's `Line (self.buffer, 0, 1, 23, 23, 0x00ffff, 24 * 2)`

Edit: Wow, doing `Line (self.buffer, 0, 24, 24, 24, 0x00ffff, 24 * 2)` uses way too much CPU time.

Edit: Here's another image using this algorithm. The yellow dots are starting points.

``````Line (self.buffer, 0, 0, 24, 24, 0xff0000, 24)
Line (self.buffer, 0, 12, 23, 23, 0x00ff00, 24)
Line (self.buffer, 12, 0, 23, 23, 0x0000ff, 24)
``````

Edit: And yes, that blue line wraps around.

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What type of array is the data? if it's a byte array you have to keep in mind a single pixel is multiple bytes so you might have to multiply your pitch by the number of bytes per pixel. And ofcourse it should use the total width of the buffer, not just the line. – Doggett Nov 1 '10 at 23:50
It's just a single Lua number. I think it's 64bit. – Scott Nov 1 '10 at 23:55
I'm not writing raw data. – Scott Nov 1 '10 at 23:57
The Bresenham line algorithm is simpler, maybe you want to take a look at that. – Paul Beckingham Nov 2 '10 at 0:20
@Paul: That's what this is. – Scott Nov 2 '10 at 0:21

This one works.

``````Line (self.buffer, 0, 0, 23, 23, 0xff0000, 24 * 2)
Line (self.buffer, 0, 5, 23, 23, 0x00ff00, 24)
Line (self.buffer, 12, 0, 23, 23, 0x0000ff, 24)
``````

--

``````local function Line (buf, x0, y0, x1, y1, color, pitch)
local dx = x1 - x0;
local dy = y1 - y0;

buf.buffer[x0 + y0 * pitch] = color
if (dx ~= 0) then
local m = dy / dx;
local b = y0 - m*x0;
if x1 > x0 then
dx = 1
else
dx = -1
end
while x0 ~= x1 do
x0 = x0 + dx
y0 = math.floor(m*x0 + b + 0.5);
buf.buffer[x0 + y0 * pitch] = color
end

end
end
``````

Here's the spiral.

The one below dances around like a music visualization, but we're just feeding it random data. I think the line quality could be better.

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This is what I settled on. I just had to find valid information on that Bresenham algorithm. Thanks cs-unc for the information about various line algorithms, from simple to complex.

``````function LibBuffer:Line4(x0, y0, x1, y1, color, pitch)
local dx = x1 - x0;
local dy = y1 - y0;
local stepx, stepy

if dy < 0 then
dy = -dy
stepy = -1
else
stepy = 1
end

if dx < 0 then
dx = -dx
stepx = -1
else
stepx = 1
end

self.buffer[x0 + y0 * pitch] = color
if dx > dy then
local fraction = dy - bit.rshift(dx, 1)
while x0 ~= x1 do
if fraction >= 0 then
y0 = y0 + stepy
fraction = fraction - dx
end
x0 = x0 + stepx
fraction = fraction + dy
self.buffer[floor(y0) * pitch + floor(x0)] = color
end
else
local fraction = dx - bit.rshift(dy, 1)
while y0 ~= y1 do
if fraction >= 0 then
x0 = x0 + stepx
fraction = fraction - dy
end
y0 = y0 + stepy
fraction = fraction + dx
self.buffer[floor(y0) * pitch + floor(x0)] = color
end
end
end
``````

Here's what this one looks like.

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