mt-polygon-simplification/lib/simplify-wasm/simplify.c

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#include <stdlib.h>
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// #include "debug.h"
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#define DIM 2
void copyCoordinate(double* from, double* to) {
for (int i = 0; i < DIM; i++) {
to[i] = from[i];
}
}
// extends array and copies point on the end. Returns new length
int push(double* array, int length, double* point) {
int newLength = length + DIM;
// realloc(array, newLength * sizeof(double));
copyCoordinate(point, array + length);
return newLength;
}
// square distance between 2 points
double getSqDist(double* p1, double* p2) {
double dx = p1[0] - p2[0],
dy = p1[1] - p2[1];
return dx * dx + dy * dy;
}
// square distance from a point to a segment
double getSqSegDist(double* p, double* p1, double* p2) {
double x = p1[0],
y = p1[1],
dx = p2[0] - x,
dy = p2[1] - y;
if (dx != 0 || dy != 0) {
double t = ((p[0] - x) * dx + (p[1] - y) * dy) / (dx * dx + dy * dy);
if (t > 1) {
x = p2[0];
y = p2[1];
} else if (t > 0) {
x += dx * t;
y += dy * t;
}
}
dx = p[0] - x;
dy = p[1] - y;
return dx * dx + dy * dy;
}
// basic distance-based simplification
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int simplifyRadialDist(double* points, int length, double sqTolerance, double* result) {
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double* prevPoint = points;
double* point;
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int resultLength = push(result, 0, points);
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for (int i = DIM; i < length; i += DIM) {
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point = points + i;
if (getSqDist(point, prevPoint) > sqTolerance) {
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resultLength = push(result, resultLength, point);
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prevPoint = point;
}
}
if (prevPoint != point) {
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resultLength = push(result, resultLength, point);
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}
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return resultLength;
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}
int simplifyDPStep(double* points, int first, int last, double sqTolerance, double* simplified, int lengthOfSimplified) {
double maxSqDist = sqTolerance;
int index;
for (int i = first + DIM; i < last; i += DIM) {
double sqDist = getSqSegDist(points + i, points + first, points + last);
if (sqDist > maxSqDist) {
index = i;
maxSqDist = sqDist;
}
}
if (maxSqDist > sqTolerance) {
if (index - first > DIM) lengthOfSimplified = simplifyDPStep(points, first, index, sqTolerance, simplified, lengthOfSimplified);
lengthOfSimplified = push(simplified, lengthOfSimplified, points + index);
if (last - index > DIM) lengthOfSimplified = simplifyDPStep(points, index, last, sqTolerance, simplified, lengthOfSimplified);
}
return lengthOfSimplified;
}
// simplification using Ramer-Douglas-Peucker algorithm
int simplifyDouglasPeucker(double* points, int length, double sqTolerance, double* simplified) {
int lengthOfSimplified;
lengthOfSimplified = push(simplified, 0, points);
lengthOfSimplified = simplifyDPStep(points, 0, length - DIM, sqTolerance, simplified, lengthOfSimplified);
lengthOfSimplified = push(simplified, lengthOfSimplified, points + length - DIM);
return lengthOfSimplified;
}
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int* simplify(double * points, int length, double tolerance, int highestQuality) {
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double sqTolerance = tolerance * tolerance;
double* resultRdDistance = NULL;
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double* result = NULL;
int resultLength;
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if (!highestQuality) {
resultRdDistance = malloc(length * sizeof(double));
length = simplifyRadialDist(points, length, sqTolerance, resultRdDistance);
points = resultRdDistance;
}
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result = malloc(length * sizeof(double));
resultLength = simplifyDouglasPeucker(points, length, sqTolerance, result);
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free(resultRdDistance);
int* resultInfo = malloc(2);
resultInfo[0] = (int) result;
resultInfo[1] = resultLength;
return resultInfo;
}