Develop Reference

How to properly do centered zooming?

My problem is more generic than programming, however it involves some basic C codes, I hope this won't be closed in here.
I have a rounded target display, which will display an image, first centered and fitted:
Circle's radius is 360, that's fixed.
I need to add do zoom-in and out functionality (in case image is larger than target). In this example the above image is 1282x720, so it's well above the circle's size. (To fit into the circle, now it's roughly 313x176)
I would like to do a properly aligned "center-fixed zoom", i.e.: whatever is currently centered shall remain centered after the zoom operation.
Image is put into a component called scroller which has an option to set its offset, i.e. how many pixels shall it skip from top and left of its content. This scroller component is by default aligns its content to top-left corner.
I've put a red dot into the middle of the image, to be easier to follow.
So upon zooming in this happens (image is starting to be left-aligned):
Please note it is still in the middle vertically, as it's stills smaller in height than its container.
However on the next zooming-in step, the red centerpoint will slightly go downwards, as the image in this case has more height than container, hence it's also started being top-aligned:
Now, making it to stay always in center is easy:
I need to ask the scroller to scroll to
image_width/2 - 180, //horizontal skip
image_height/2 - 180 //vertical skip
In this case, if I zoom-in in 5 steps from fitted size to full size, scroller's skip numbers are these:
Step0 (fit): 0, 0
Step1: 73, 0
Step2: 170, 16
Step3: 267, 71
Step4: 364, 125
Step5 (original size): 461, 180
But I don't want the image to stay in center constantly, I'd rather do something similar what image editors are doing, i.e.: center point shall remain in center during zoom operation, than user can pan, and next zoom operation will keep the new center point in center.
How shall I do this?
Target language is C, and there is no additional 3rd party library which is usable, I'll need to do this manually.
Scroller is actually an elm_scroller.

You need to modify all four positions points, not only x2 and y2, think of them as a the sides of a rectangle, so to keep a centered zoom every side of the square needs to "grow" to de absolute center of the image.
X1 > Left , Y1 > Top
X2 > Right , Y2 > Bottom
#include <stdint.h>
#include <stdio.h>
typedef struct {
int32_t x;
int32_t y;
int32_t width;
int32_t heigth;
uint32_t o_width;
uint32_t o_heigth;
} IMG_C_POS;
void set_img_c_pos(IMG_C_POS * co, int32_t w, int32_t h){
co->o_heigth = h;
co->o_width = w;
co->heigth = h;
co->width = w;
co->x = 0;
co->y = 0;
}
void add_img_zoom(IMG_C_POS * co, uint16_t zoom){
uint32_t zoom_y = (co->o_heigth / 100) * (zoom / 2);
uint32_t zoom_x = (co->o_width / 100) * (zoom / 2);
co->heigth -= zoom_y;
co->width -= zoom_x;
co->x += zoom_x;
co->y += zoom_y;
}
void sub_img_zoom(IMG_C_POS * co, uint16_t zoom){
uint32_t zoom_y = (co->o_heigth / 100) * (zoom / 2);
uint32_t zoom_x = (co->o_width / 100) * (zoom / 2);
co->heigth += zoom_y;
co->width += zoom_x;
co->x -= zoom_x;
co->y -= zoom_y;
}
void img_new_center(IMG_C_POS * co, int16_t nx, int16_t ny){
int32_t oy = co->o_heigth / 2;
if(oy <= ny){
co->heigth += oy - ny;
co->y += oy - ny;
} else {
co->heigth -= oy - ny;
co->y -= oy - ny;
}
int32_t ox = co->o_width / 2;
if(ox <= nx){
co->width += ox - nx;
co->x += ox - nx;
} else {
co->width -= ox - nx;
co->x -= ox - nx;
}
}
void offset_img_center(IMG_C_POS * co, int16_t x_offset, int16_t y_offset){
if (y_offset != 0){
int32_t y_m_size = (co->o_heigth / 100) * y_offset;
co->heigth += y_m_size;
co->y += y_m_size;
}
if (x_offset != 0){
int32_t x_m_size = (co->o_width / 100) * x_offset;
co->width += x_m_size;
co->x += x_m_size;
}
}
int main(void) {
IMG_C_POS position;
set_img_c_pos(&position, 1282, 720);
sub_img_zoom(&position, 50);
img_new_center(&position, (1282 / 2) - 300, (720 / 2) + 100);
for (int i = 0; i < 4; i++){
printf("X1 -> %-5i Y1 -> %-5i X2 -> %-5i Y2 -> %-5i \n",
position.x, position.y, position.width, position.heigth
);
offset_img_center(&position, 4, -2);
add_img_zoom(&position, 20);
}
return 0;
}

Inconsistent performance when writing pixels to custom buffer (X11 / C)

I'm writing my own library based on X11 which uses only CPU rendering (GPU usage is not allowed!).Today I stumbled upon strange discovery. When I draw pixels like this:
const int ratio = 1;
for(int y = 0; y < XF_GetWindowHeight() / ratio; ++y)
for(int x = 0; x < XF_GetWindowWidth() / ratio; ++x)
XF_DrawPoint(x * ratio, y * ratio, 0xff0000); // function gets x, y and color
It completes after ~1.5ms every frame. But when I draw the same region but using fewer loop calls and drawing bigger rectangles instead of points (pixels) I get result of ~0.8ms.
const int ratio = 32;
for(int y = 0; y < XF_GetWindowHeight() / ratio; ++y)
for(int x = 0; x < XF_GetWindowWidth() / ratio; ++x)
// function gets x, y, w, h, color and if only draw outline (doesn't matter in this case)
XF_DrawRect(x * ratio, y * ratio, ratio, ratio, 0xff0000, false);
It seems strange to me, that even if the XF_DrawRect function is more complicated and both loops in the end are drawing the same amount of pixels, calling fewer loops seems to impact the performance greatly.
void XF_DrawPoint(int x, int y, uint32_t color)
*(h_lines[y] + x) = color; // h_lines is array with pointers to each row
void XF_DrawRect(int x, int y, int w, int h, uint32_t color, XF_Bool outline)
uint32_t *s = h_lines[y] + x;
int hz_count = 0;
while(h--) {
hz_count = w;
while(hz_count--) {
*s++ = color;
}
s += WINDOW_WIDTH - w;
}
So, as you can see, implementation of XF_DrawRect is more complex (there are some range checks at the beginning to trim the rectangle if it goes out of bounds, but it doesn't matter) then the XF_DrawPoint and still, there is ~2x improvement in speed, when drawing the same area.My question is: why?

How to do: for looping + increasing of radius each loop?

How do I create a clean and simple code that creates a circle of point/dots within the larger one? Or something similar (I can't post an image of what I want sorry). I was told to try using a for loop around the outside of my code and have the radius increase slightly each iteration of the loop. However, i don't know how to increase the radius?
This is the code I've been experimenting with so far:
size (400, 400);
background(255);
noStroke();
fill(0);
smooth();
translate(width/2, height/2);
int numpoints = 10;
float angleinc = 2 * PI / numpoints;
int radius = 100;
for (int i = 0; i < numpoints; i++) {
float x = cos(angleinc * i) * radius;
float y = sin(angleinc * i) * radius;
ellipse(x, y, 4, 4);
}
Please, any quick help would be appreciated. Also, I'm fairly new to processing and coding, so I'm not the best...

You'll have better luck if you break your problem down into smaller steps. Step one is creating a function that draws a single "ring" of smaller circles. You already have that step done, all you need to do is separate it into its own function:
void drawCircle(int outerRadius, int innerRadius) {
int numpoints = 10;
float angleinc = 2 * PI / numpoints;
for (int i = 0; i < numpoints; i++) {
float x = cos(angleinc * i) * outerRadius;
float y = sin(angleinc * i) * outerRadius;
ellipse(x, y, innerRadius, innerRadius);
}
}
Then, to draw a set of rings of increasing size, you simply call the function multiple times:
drawCircle(50, 8);
drawCircle(75, 12);
drawCircle(100, 16);
Which you can condense into a for loop:
for(int i = 2; i <= 4; i++){
drawCircle(25*i, 4*i);
}
The whole thing would look something like this:
void setup() {
size (400, 400);
}
void draw() {
background(255);
noStroke();
fill(0);
smooth();
translate(width/2, height/2);
for(int i = 2; i <= 4; i++){
drawCircle(25*i, 4*i);
}
}
void drawCircle(int outerRadius, int innerRadius) {
int numpoints = 10;
float angleinc = 2 * PI / numpoints;
for (int i = 0; i < numpoints; i++) {
float x = cos(angleinc * i) * outerRadius;
float y = sin(angleinc * i) * outerRadius;
ellipse(x, y, innerRadius, innerRadius);
}
}
This is just an example, and you'll have to play around with the numbers to make it look exactly like what you want, but the process is the same: break your problem down into smaller steps, isolate those steps into functions that do one thing, and then call those functions to accomplish your overall goal.

I hope i got your question right-
The formula of a circle around the origin is x=Rcos(angle) y=Rsin(angle) where angel is going between 0 to 2*pi
if you want to draw the circle around point lets say around (x',y'), the formula will be x= x' + Rcos(angle) y= y' + rsin(angle)
The code:
float epsilon = 0.0001f;
float R = 5.5.f;
for (float angle = 0.0; angle < 2*PI; angle += epsilon ) {
float x = x' + R*cos(angle);
float y = y' + R*sin(angle);
drawPoint(x,y);
if( /*condition for changing the radius*/ )
{
R = R*2; // or any change you want to do for R
}
}

It's probably easiest if you use two for loops: one for loop to draw the circle at a certain radius and another for loop which has the previous for loop in it which increases the radius.
int numCircles = 3;
//This for loop increases the radius and draws the circle with another for loop
for (int j = 0; j < numCircles; j++)
{
//This for loop draws the actual circle
for (int i = 0; i < numpoints; i++)
{
float x = cos(angleinc * i) * radius;
float y = sin(angleinc * i) * radius;
ellipse(x, y, 4, 4);
}
//(add code here that increases the radius)
}

How to generate a set of points that are equidistant from each other and lie on a circle

I am trying to generate an array of n points that are equidistant from each other and lie on a circle in C. Basically, I need to be able to pass a function the number of points that I would like to generate and get back an array of points.

It's been a really long time since I've done C/C++, so I've had a stab at this more to see how I got on with it, but here's some code that will calculate the points for you. (It's a VS2010 console application)
// CirclePoints.cpp : Defines the entry point for the console application.
//
#include "stdafx.h"
#include "stdio.h"
#include "math.h"
int _tmain()
{
int points = 8;
double radius = 100;
double step = ((3.14159265 * 2) / points);
double x, y, current = 0;
for (int i = 0; i < points; i++)
{
x = sin(current) * radius;
y = cos(current) * radius;
printf("point: %d x:%lf y:%lf\n", i, x, y);
current += step;
}
return 0;
}

Try something like this:
void make_circle(float *output, size_t num, float radius)
{
size_t i;
for(i = 0; i < num; i++)
{
const float angle = 2 * M_PI * i / num;
*output++ = radius * cos(angle);
*output++ = radius * sin(angle);
}
}
This is untested, there might be an off-by-one hiding in the angle step calculation but it should be close.
This assumes I understood the question correctly, of course.
UPDATE: Redid the angle computation to not be incrementing, to reduce float precision loss due to repeated addition.

Here's a solution, somewhat optimized, untested. Error can accumulate, but using double rather than float probably more than makes up for it except with extremely large values of n.
void make_circle(double *dest, size_t n, double r)
{
double x0 = cos(2*M_PI/n), y0 = sin(2*M_PI/n), x=x0, y=y0, tmp;
for (;;) {
*dest++ = r*x;
*dest++ = r*y;
if (!--n) break;
tmp = x*x0 - y*y0;
y = x*y0 + y*x0;
x = tmp;
}
}

You have to solve this in c language:
In an x-y Cartesian coordinate system, the circle with centre coordinates (a, b) and radius r is the set of all points (x, y) such that
(x - a)^2 + (y - b)^2 = r^2

Here's a javascript implementation that also takes an optional center point.
function circlePoints (radius, numPoints, centerX, centerY) {
centerX = centerX || 0;
centerY = centerY || 0;
var
step = (Math.PI * 2) / numPoints,
current = 0,
i = 0,
results = [],
x, y;
for (; i < numPoints; i += 1) {
x = centerX + Math.sin(current) * radius;
y = centerY + Math.cos(current) * radius;
results.push([x,y]);
console.log('point %d # x:%d, y:%d', i, x, y);
current += step;
}
return results;
}

Filling a polygon

I created this function that draws a simple polygon with n number of vertexes:
void polygon (int n)
{
double pI = 3.141592653589;
double area = min(width / 2, height / 2);
int X = 0, Y = area - 1;
double offset = Y;
int lastx, lasty;
double radius = sqrt(X * X + Y * Y);
double quadrant = atan2(Y, X);
int i;
for (i = 1; i <= n; i++)
{
lastx = X; lasty = Y;
quadrant = quadrant + pI * 2.0 / n;
X = round((double)radius * cos(quadrant));
Y = round((double)radius * sin(quadrant));
setpen((i * 255) / n, 0, 0, 0.0, 1); // r(interval) g b, a, size
moveto(offset + lastx, offset + lasty); // Moves line offset
lineto(offset + X, offset + Y); // Draws a line from offset
}
}
How can I fill it with a solid color?
I have no idea how can I modify my code in order to draw it filled.

The common approach to fill shapes is to find where the edges of the polygon cross either each x or each y coordinate. Usually, y coordinates are used, so that the filling can be done using horizontal lines. (On framebuffer devices like VGA, horizontal lines are faster than vertical lines, because they use consecutive memory/framebuffer addresses.)
In that vein,
void fill_regular_polygon(int center_x, int center_y, int vertices, int radius)
{
const double a = 2.0 * 3.14159265358979323846 / (double)vertices;
int i = 1;
int y, px, py, nx, ny;
if (vertices < 3 || radius < 1)
return;
px = 0;
py = -radius;
nx = (int)(0.5 + radius * sin(a));
ny = (int)(0.5 - radius * cos(a));
y = -radius;
while (y <= ny || ny > py) {
const int x = px + (nx - px) * (y - py) / (ny - py);
if (center_y + y >= 0 && center_y + y < height) {
if (center_x - x >= 0)
moveto(center_x - x, center_y + y);
else
moveto(0, center_y + y);
if (center_x + x < width)
lineto(center_x + x, center_y + y);
else
lineto(width - 1, center_y + y);
}
y++;
while (y > ny) {
if (nx < 0)
return;
i++;
px = nx;
py = ny;
nx = (int)(0.5 + radius * sin(a * (double)i));
ny = (int)(0.5 - radius * cos(a * (double)i));
}
}
}
Note that I only tested the above with a simple SVG generator, and compared the drawn lines to the polygon. Seems to work correctly, but use at your own risk; no guarantees.
For general shapes, use your favourite search engine to look for "polygon filling" algorithms. For example, this, this, this, and this.

There are 2 different ways to implement a solution:
Scan-line
Starting at the coordinate that is at the top (smallest y value), continue to scan down line by line (incrementing y) and see which edges intersect the line.
For convex polygons you find 2 points, (x1,y) and (x2,y). Simply draw a line between those on each scan-line.
For concave polygons this can also be a multiple of 2. Simply draw lines between each pair. After one pair, go to the next 2 coordinates. This will create a filled/unfilled/filled/unfilled pattern on that scan line which resolves to the correct overall solution.
In case you have self-intersecting polygons, you would also find coordinates that are equal to some of the polygon points, and you have to filter them out. After that, you should be in one of the cases above.
If you filtered out the polygon points during scan-lining, don't forget to draw them as well.
Flood-fill
The other option is to use flood-filling. It has to perform more work evaluating the border cases at every step per pixel, so this tends to turn out as a slower version. The idea is to pick a seed point within the polygon, and basically recursively extend up/down/left/right pixel by pixel until you hit a border.
The algorithm has to read and write the entire surface of the polygon, and does not cross self-intersection points. There can be considerable stack-buildup (for naive implementations at least) for large surfaces, and the reduced flexibility you have for the border condition is pixel-based (e.g. flooding into gaps when other things are drawn on top of the polygon). In this sense, this is not a mathematically correct solution, but it works well for many applications.

The most efficient solution is by decomposing the regular polygon in trapezoids (and one or two triangles).
By symmetry, the vertexes are vertically aligned and it is an easy matter to find the limiting abscissas (X + R cos(2πn/N) and X + R cos(2π(+1)N)).
You also have the ordinates (Y + R sin(2πn/N) and Y + R sin(2π(+1)N)) and it suffices to interpolate linearly between two vertexes by Y = Y0 + (Y1 - Y0) (X - X0) / (X1 - X0).
Filling in horizontal runs is a little more complex, as the vertices may not be aligned horizontally and there are more trapezoids.

Anyway, it seems that I / solved / this myself again, when not relying on assistance (or any attempt for it)
void polygon (int n)
{
double pI = 3.141592653589;
double area = min(width / 2, height / 2);
int X = 0, Y = area - 1;
double offset = Y;
int lastx, lasty;
while(Y-->0) {
double radius = sqrt(X * X + Y * Y);
double quadrant = atan2(Y, X);
int i;
for (i = 1; i <= n; i++)
{
lastx = X; lasty = Y;
quadrant = quadrant + pI * 2.0 / n;
X = round((double)radius * cos(quadrant));
Y = round((double)radius * sin(quadrant));
//setpen((i * 255) / n, 0, 0, 0.0, 1);
setpen(255, 0, 0, 0.0, 1); // just red
moveto(offset + lastx, offset + lasty);
lineto(offset + X, offset + Y);
} }
}
As you can see, it isn't very complex, which means it might not be the most efficient solution either.. but it is close enough.
It decrements radius and fills it by virtue of its smaller version with smaller radius.
On that way, precision plays an important role and the higher n is the less accuracy it will be filled with.