Triangular lattice generator

Former-commit-id: b3b2bdafacb2cc91b1ebb28ed48b1549451e528a
2018-08-23 11:38:58 +03:00 · 2018-08-23 11:38:58 +03:00 · e6217bd363
parent ca454669d1
commit e6217bd363
3 changed files with 324 additions and 48 deletions
--- a/qpms/lattices.h
+++ b/qpms/lattices.h
@ -2,23 +2,20 @@
 #define LATTICES_H
 #include <math.h>
 #include <stdbool.h>
-
+#include <assert.h>
 #include <stddef.h>
 #define M_SQRT3 1.7320508075688772935274463415058724
 #define M_SQRT3_2 (M_SQRT3/2)
 // This might be reduced to x, y only; not sure yet
 typedef struct {
 	double key; // distance key in a given lattice
 	double x, y, r, phi;
 } point2d;
 // fuck, I already had had suitable type
 #include "vectors.h"
 typedef cart2_t point2d;
 static inline point2d point2d_fromxy(const double x, const double y) {
 	point2d p;
 	p.x = x;
 	p.y = y;
 	p.r = sqrt(x*x+y*y);
 	p.phi = atan2(y, x);
 	return p;
 }
 /* 
@ -32,14 +29,30 @@ static inline point2d point2d_fromxy(const double x, const double y) {
 typedef struct {
 	size_t nrs; // number of different radii
 	double *rs; // the radii; of length nrs (largest contained radius == rs[nrs-1])
-	point2d **points_at_r; // of length nrs+1
+	point2d *base; 
 	ptrdiff_t *r_offsets; // of length nrs+1 (using relative offsets due to possible realloc's)
 	// the jth point of i-th radius is base[r_offsets[i]+j] or using the inline below..
 	/* // redundand (therefore removed) members
         * point2d *points; // redundant as it is the same as points_at_r[0]
 	 * size_t npoints;  // redundant as it is the same as points_at_r[nrs]-points_at_r[0]
 	 */ 
 } points2d_rordered_t;
 // returns a copy but scaled by a factor
 points2d_rordered_t *points2d_rordered_scale(const points2d_rordered_t *orig, double factor);
 void points2d_rordered_free(points2d_rordered_t *); // use only for result of points2d_rordered_scale
 static inline point2d points2d_rordered_get_point(const points2d_rordered_t *ps, int r_order, int i) {
 	assert(i >= 0);
 	assert(r_order < ps->nrs);
 	assert(i < (ps->r_offsets[r_order+1] - ps->r_offsets[r_order]));
 	return ps->base[ps->r_offsets[r_order] + i];
 }
 static inline double points2d_rordered_get_r(const points2d_rordered_t *ps, int r_order) {
 	assert(r_order < ps->nrs);
 	return ps->rs[r_order];
 }
 /* 
 * EQUILATERAL TRIANGULAR LATTICE
@ -68,10 +81,10 @@ typedef struct {
 } triangular_lattice_gen_t;
 triangular_lattice_gen_t *triangular_lattice_gen_init(double a, TriangularLatticeOrientation ori, bool include_origin); 
-const points2d_reordered_t * triangular_lattice_gen_getpoints(const triangular lattice_generator_t *g);
+const points2d_rordered_t * triangular_lattice_gen_getpoints(const triangular_lattice_gen_t *g);
-int triangular_lattice_gen_extend_to_r(triangular_lattice_generator_t *g, double r);
+int triangular_lattice_gen_extend_to_r(triangular_lattice_gen_t *g, double r);
-int triangular_lattice_gen_extend_to_steps(triangular_lattice_generator_t *g, int maxsteps);
+int triangular_lattice_gen_extend_to_steps(triangular_lattice_gen_t *g, int maxsteps);
-void triangular_lattice_gen_free(triangular_lattice_generator_t *g);
+void triangular_lattice_gen_free(triangular_lattice_gen_t *g);
 #if 0
--- a/qpms/lattices2d.c
+++ b/qpms/lattices2d.c
@ -1,5 +1,6 @@
 #include "lattices.h"
 #include <assert.h>
 #include <stdlib.h>
 typedef struct {
  int i, j;
@ -8,6 +9,39 @@ typedef struct {
 static inline int sqi(int x) { return x*x; }
 void points2d_rordered_free(points2d_rordered_t *p) {
  free(p->rs);
  free(p->base);
  free(p->r_offsets);
  free(p);
 }
 points2d_rordered_t *points2d_rordered_scale(const points2d_rordered_t *orig, const double f)
 {
  points2d_rordered_t *p = malloc(sizeof(points2d_rordered_t));
  if(0 == orig->nrs) { // orig is empty
    p->nrs = 0;
    p->rs = NULL;
    p->base = NULL;
    p->r_offsets = NULL;
    return p;
  }
  p->nrs = orig->nrs;
  p->rs = malloc(p->nrs*sizeof(double));
  p->r_offsets = malloc((p->nrs+1)*sizeof(ptrdiff_t));
  const double af = fabs(f);
  for(size_t i = 0; i < p->nrs; ++i) {
    p->rs[i] = orig->rs[i] * af;
    p->r_offsets[i] = orig->r_offsets[i];
  }
  p->r_offsets[p->nrs] = orig->r_offsets[p->nrs];
  for(size_t i = 0; i < p->r_offsets[p->nrs]; ++i)
    p->base[i] = point2d_fromxy(orig->base[i].x * f, orig->base[i].y * f);
 }
 /*
 * EQUILATERAL TRIANGULAR LATTICE
 */
@ -67,12 +101,27 @@ static inline int sqi(int x) { return x*x; }
 * The real area inside the web is (a*s)**2 * 3 * sqrt(3) / 2.
 * Area of a unit cell is a**2 * sqrt(3)/2.
 * Inside the web, but excluding the circumscribed circle, there is no more
- * than 3/4.*s*(s+1) lattice cells (FIXME pretty stupid but safe estimate).
+ * than 3/4.*s*(s+1) + 6*s lattice cells (FIXME pretty stupid but safe estimate).
 *
 * s-th layer circumscribes a circle of radius a * s * sqrt(3)/2.
 *
 */
 typedef struct triangular_lattice_gen_privstuff_t {
  intcoord2_t *pointlist_base; // allocated memory for the point "buffer"
  size_t pointlist_capacity; 
  // beginning and end of the point "buffer"
  // not 100% sure what type should I use here
  // (these are both relative to pointlist_base, due to possible realloc's)
  ptrdiff_t pointlist_beg, pointlist_n; // end of queue is at [(pointlist_beg+pointlist_n)%pointlist_capacity]
  int maxs; // the highest layer of the spider web generated (-1 by init, 0 is only origin (if applicable))
  // capacities of the arrays in ps
  size_t ps_rs_capacity;
  size_t ps_points_capacity; // this is the "base" array
  // TODO anything else?
 } triangular_lattice_gen_privstuff_t;
 static inline int trilat_r2_ij(const int i, const int j) {
  return sqi(i) + sqi(j) + i*j;
 }
@ -81,12 +130,8 @@ static inline int trilat_r2_coord(const intcoord2_t c) {
  return trilat_r2_ij(c.i, c.j);
 }
 static int trilat_cmp_intcoord2_by_r2(const void *p1, const void *p2) {
  // CHECK the sign is right
  return trilat_r2_coord(*(const intcoord2_t *)p1) - trilat_r2_coord(*(const intcoord2_t *)p2);
 }
-// Classify points into sextants (variant [a])
+// Classify points into sextants (variant [a] above)
 static int trilat_sextant_ij_a(const int i, const int j) {
  const int w = i + j;
  if (i >  0 && j >= 0) return  0;
@ -99,23 +144,155 @@ static int trilat_sextant_ij_a(const int i, const int j) {
  assert(0); // other options should be impossible
 }
-typedef struct {
+static inline size_t tlgp_pl_end(const triangular_lattice_gen_privstuff_t *p) {
-  intcoord2_t *pointlist_base; // allocated memory for the point "buffer"
+  return (p->pointlist_beg + p->pointlist_n) % p->pointlist_capacity;
-  size_t pointlist_capacity; 
+}
-  // beginning and end of the point "buffer"
+
-  // not 100% sure what type should I use here
+#if 0
-  // (these are both relative to pointlist_base, due to possible realloc's)
+static inline void tlgpl_end_inc(triangular_lattice_gen_privstuff_t *p) {
-  ptrdiff_t pointlist_beg, pointlist_end; 
+  p->p_pointlist_n += 1;
-  int maxs; // the highest layer of the spider web generated (-1 by init, 0 is only origin (if applicable))
+}
-  // capacities of the arrays in ps
+#endif
-  size_t ps_rs_capacity;
+
-  size_t ps_points_capacity; // this is the "base" array
+// Puts a point to the end of the point queue
-  // TODO anything else?
+static inline void trilatgen_pointlist_append_ij(triangular_lattice_gen_t *g, int i, int j) {
-} triangular_lattice_gen_t_privstuff_t;
+  intcoord2_t thepoint = {i, j};
  triangular_lattice_gen_privstuff_t *p = g->priv;
  assert(p->pointlist_n < p->pointlist_capacity);
  // the actual addition
  p->pointlist_base[tlgp_pl_end(p)] = thepoint;
  p->pointlist_n += 1;
 }
 // Arange the pointlist queue into a continuous chunk of memory, so that we can qsort() it
 static void trilatgen_pointlist_linearise(triangular_lattice_gen_t *g) {
  triangular_lattice_gen_privstuff_t *p = g->priv;
  assert(p->pointlist_n <= p->pointlist_capacity);
  if (p->pointlist_beg + p->pointlist_n <= p->pointlist_capacity)
    return;  // already linear, do nothing
  else if (p->pointlist_n == p->pointlist_capacity) { // full, therefore linear
    p->pointlist_beg = 0;
    return;
  } else { // non-linear; move "to the right"
    while (p->pointlist_beg < p->pointlist_capacity) {
      p->pointlist_base[tlgp_pl_end(p)] = p->pointlist_base[p->pointlist_beg];
      ++(p->pointlist_beg);
    }
    p->pointlist_beg = 0;
    return;
  }
 }
 static inline intcoord2_t trilatgen_pointlist_first(const triangular_lattice_gen_t *g) {
  return g->priv->pointlist_base[g->priv->pointlist_beg];
 }
 static inline void trilatgen_pointlist_deletefirst(triangular_lattice_gen_t *g) {
  triangular_lattice_gen_privstuff_t *p = g->priv;
  assert(p->pointlist_n > 0);
  ++p->pointlist_beg;
  if(p->pointlist_beg == p->pointlist_capacity) 
    p->pointlist_beg = 0;
  --(p->pointlist_n);
 }
 // TODO abort() and void or errorchecks and int?
 static int trilatgen_pointlist_extend_capacity(triangular_lattice_gen_t *g, size_t newcapacity) {
  triangular_lattice_gen_privstuff_t *p = g->priv;
  if (newcapacity <= p->pointlist_capacity)
    return 0;
  trilatgen_pointlist_linearise(g);
  intcoord2_t *newmem = realloc(p->pointlist_base, newcapacity * sizeof(intcoord2_t));
  if (newmem != NULL) {
    p->pointlist_base = newmem;
    p->pointlist_capacity = newcapacity;
    return 0;
  } else 
    abort();
 }
 // lower estimate for the number of lattice points inside the circumscribed hexagon, but outside the circle
 static inline size_t tlg_circumscribe_reserve(int maxs) {
  if (maxs <= 0) 
    return 0;
  return 3*maxs*(maxs+1)/4 + 6*maxs;
 }
 static inline size_t tlg_websize(int maxs) {
  if (maxs <= 0)
    return 0;
  else 
    return 3*maxs*(maxs+1); // does not include origin point!
 }
 static int trilatgen_ensure_pointlist_capacity(triangular_lattice_gen_t *g, int newmaxs) {
  return trilatgen_pointlist_extend_capacity(g,
        tlg_circumscribe_reserve(g->priv->maxs) // Space for those which are already in
      + tlg_websize(newmaxs) - tlg_websize(g->priv->maxs) // space for the new web layers
      + 1 // reserve for the origin
      );
 }
 static int trilatgen_ensure_ps_rs_capacity(triangular_lattice_gen_t *g, int maxs) {
  if (maxs < 0)
    return 0;
  size_t needed_capacity = 1 // reserve for origin
    + maxs*(maxs+1)/2; // stupid but safe estimate: number of points in a sextant of maxs-layered spider web
  if (needed_capacity <= g->priv->ps_rs_capacity)
    return 0; // probably does not happen, but fuck it
  double *newmem = realloc(g->ps.rs, needed_capacity * sizeof(double));
  if (newmem != NULL)  
    g->ps.rs = newmem; 
  else 
    abort();
  ptrdiff_t *newmem2 = realloc(g->ps.r_offsets, (needed_capacity + 1) * sizeof(ptrdiff_t));
  if (newmem2 != NULL)
    g->ps.r_offsets = newmem2;
  else 
    abort();
  g->priv->ps_rs_capacity = needed_capacity;
  return 0;
 }
 static int trilatgen_ensure_ps_points_capacity(triangular_lattice_gen_t *g, int maxs) {
  if (maxs < 0)
    return 0;
  size_t needed_capacity = 1 /*res. for origin */ + tlg_websize(maxs) /* stupid but safe */;
  if(needed_capacity <= g->priv->ps_points_capacity)
    return 0;
  point2d *newmem = realloc(g->ps.base, needed_capacity * sizeof(point2d));
  if (newmem != NULL) 
    g->ps.base = newmem;
  else
    abort();
  g->priv->ps_points_capacity = needed_capacity;
  return 0;
 }
 static int trilat_cmp_intcoord2_by_r2(const void *p1, const void *p2) {
  // CHECK the sign is right
  return trilat_r2_coord(*(const intcoord2_t *)p1) - trilat_r2_coord(*(const intcoord2_t *)p2);
 }
 static void trilatgen_sort_pointlist(triangular_lattice_gen_t *g) {
  trilatgen_pointlist_linearise(g);
  triangular_lattice_gen_privstuff_t *p = g->priv;
  qsort(p->pointlist_base + p->pointlist_beg, p->pointlist_n, sizeof(intcoord2_t), trilat_cmp_intcoord2_by_r2);
 }
 triangular_lattice_gen_t * triangular_lattice_gen_init(double a, TriangularLatticeOrientation ori, bool include_origin)
 {
-  triangular_lattice_gen_t *g = malloc(sizeof(triangular_latice_gen_t));
+  triangular_lattice_gen_t *g = malloc(sizeof(triangular_lattice_gen_t));
  g->orientation = ori;
  g->includes_origin = include_origin;
  g->ps.nrs = 0;
@ -127,13 +304,13 @@ triangular_lattice_gen_t * triangular_lattice_gen_init(double a, TriangularLatti
  g->priv->pointlist_capacity = 0;
  g->priv->pointlist_base = NULL;
  g->priv->pointlist_beg = 0;
-  g->priv->pointlist_end = 0;
+  g->priv->pointlist_n = 0;
  g->priv->ps_rs_capacity = 0;
  g->priv->ps_points_capacity = 0;
  return g;
 }
-void triangular_lattice_gen_free(triangular_lattice_get_t *g) {
+void triangular_lattice_gen_free(triangular_lattice_gen_t *g) {
  free(g->ps.rs);
  free(g->ps.base);
  free(g->ps.r_offsets);
@ -142,11 +319,12 @@ void triangular_lattice_gen_free(triangular_lattice_get_t *g) {
  free(g);
 }
-const points2d_reordered_t * triangular_lattice_gen_getpoints(const triangular_lattice_generator_t *g) {
+const points2d_rordered_t * triangular_lattice_gen_getpoints(const triangular_lattice_gen_t *g) {
  return &(g->ps);
 }
-int triangular_lattice_gen_extend_to_steps(triangular_lattice_generator_t * g, int maxsteps) {
+int triangular_lattice_gen_extend_to_steps(triangular_lattice_gen_t * g, int maxsteps) 
 {
  if (maxsteps <= g->priv->maxs)  // nothing needed
    return 0;
  // TODO FIXME: check for maximum possible maxsteps (not sure what it is)
@ -159,23 +337,58 @@ int triangular_lattice_gen_extend_to_steps(triangular_lattice_generator_t * g, i
  if(err) return err;
  if(g->includes_origin && g->priv->maxs < 0) // Add origin if not there yet
-    trilatgen_append_ij(g, 0, 0);
+    trilatgen_pointlist_append_ij(g, 0, 0);
  for (int s = g->priv->maxs + 1; s <= maxsteps; ++s) {
    int i, j; 
    // now go along the spider web layer as indicated in the lenghthy comment above
-    for (i = s, j = 0; i > 0; --i; ++j) trilatgen_append_ij(g,i,j);
+    for (i = s, j = 0; i > 0; --i, ++j) trilatgen_pointlist_append_ij(g,i,j);
-    for (i = 0, j = s; i + j > 0; --i) trilatgen_append_ij(g,i,j);
+    for (i = 0, j = s; i + j > 0; --i) trilatgen_pointlist_append_ij(g,i,j);
-    for (i = -s, j = s; j > 0; --j) trilatgen_append_ij(g,i,j);
+    for (i = -s, j = s; j > 0; --j) trilatgen_pointlist_append_ij(g,i,j);
-    for (i = -s, j = 0; i < 0; ++i, --j) trilatgen_append_ij(g,i,j);
+    for (i = -s, j = 0; i < 0; ++i, --j) trilatgen_pointlist_append_ij(g,i,j);
-    for (i = 0, j = -s; i + j < 0; ++i) trilatgen_append_ij(g,i,j);
+    for (i = 0, j = -s; i + j < 0; ++i) trilatgen_pointlist_append_ij(g,i,j);
-    for (i = s, j = -s; j < 0; ++j) trilatgen_append_ij(g,i,j);
+    for (i = s, j = -s; j < 0; ++j) trilatgen_pointlist_append_ij(g,i,j);
  }
  trilatgen_sort_pointlist(g);
-  // TODO doma a ted je potřeba vytahat potřebný počet bodů z fronty a naflákat je do ps.
+  // initialise first r_offset if needed
-
+  if (0 == g->ps.nrs)
-
+    g->ps.r_offsets[0] = 0;
  //ted je potřeba vytahat potřebný počet bodů z fronty a naflákat je do ps.
  // FIXME pohlídat si kapacitu datových typů
  int maxr2i = sqi(maxsteps) * 3 / 4;
  while (g->priv->pointlist_n > 0) { // This condition should probably be always true anyways.
    intcoord2_t coord = trilatgen_pointlist_first(g);
    int r2i_cur = trilat_r2_coord(coord);
    if(r2i_cur > maxr2i)
      break;
    g->ps.rs[g->ps.nrs] = sqrt(r2i_cur) * g->a;
    g->ps.r_offsets[g->ps.nrs+1] = g->ps.r_offsets[g->ps.nrs]; // the difference is the number of points on the circle
    while(1) {
      coord = trilatgen_pointlist_first(g);
      if(r2i_cur != trilat_r2_coord(coord))
        break;
      else {
        trilatgen_pointlist_deletefirst(g);
        point2d thepoint;
        switch (g->orientation) {
          case TRIANGULAR_HORIZONTAL:
            thepoint = point2d_fromxy((coord.i+.5*coord.j)*g->a, (M_SQRT3_2*coord.j)*g->a);
            break;
          case TRIANGULAR_VERTICAL:
            thepoint = point2d_fromxy((-M_SQRT3_2*coord.j)*g->a, (coord.i+.5*coord.j)*g->a);
            break;
          default:
            abort();
        }
        g->ps.base[g->ps.r_offsets[g->ps.nrs+1]] = thepoint;
        ++(g->ps.r_offsets[g->ps.nrs+1]);
      }
    }
  }
  g->priv->maxs = maxsteps;
  return 0;
 }
--- a/tests/lattice/2d_triangular_lattice.c
+++ b/tests/lattice/2d_triangular_lattice.c
@ -0,0 +1,50 @@
 #include <qpms/lattices.h>
 #include <stdio.h>
 void dump_points2d_rordered(const points2d_rordered_t *ps, char *filename) {
  FILE *f = fopen(filename, "w");
  for (size_t i = 0; i < ps->nrs; ++i) {
    fprintf(f, "# r = %.16g\n", ps->rs[i]);
    for (ptrdiff_t j = ps->r_offsets[i]; j < ps->r_offsets[i+1]; ++j)
      fprintf(f, "%.16g %.16g\n", ps->base[j].x, ps->base[j].y);
  }
  fclose(f);
 }
 int main() {
  triangular_lattice_gen_t *g = triangular_lattice_gen_init(5, TRIANGULAR_HORIZONTAL, false);
  dump_points2d_rordered(&(g->ps), "triang_h_empty.out");
  points2d_rordered_t *p = points2d_rordered_scale(&(g->ps), 1.5464);
  dump_points2d_rordered(p, "triang_h_empty_scaled.out");
  points2d_rordered_free(p);
  triangular_lattice_gen_free(g);
  g = triangular_lattice_gen_init(5, TRIANGULAR_HORIZONTAL, false);
  triangular_lattice_gen_extend_to_steps(g, 5);
  dump_points2d_rordered(&(g->ps), "triang_h_s5.out");
  triangular_lattice_gen_extend_to_steps(g, 20);
  dump_points2d_rordered(&(g->ps), "triang_h_s20.out");
  triangular_lattice_gen_extend_to_steps(g, 160);
  dump_points2d_rordered(&(g->ps), "triang_h_s160.out");
  triangular_lattice_gen_extend_to_steps(g, 20);
  dump_points2d_rordered(&(g->ps), "triang_h_s160_20.out");
  p = points2d_rordered_scale(&(g->ps), -.2);
  dump_points2d_rordered(p, "triang_h_s160_20_scaled.out");
  points2d_rordered_free(p);
  triangular_lattice_gen_free(g);
  g = triangular_lattice_gen_init(7, TRIANGULAR_HORIZONTAL, true);
  triangular_lattice_gen_extend_to_steps(g, 7);
  dump_points2d_rordered(&(g->ps), "triang_v_s7.out");
  p = points2d_rordered_scale(&(g->ps), 1/7.);
  triangular_lattice_gen_free(g);
  dump_points2d_rordered(p, "triang_v_s7_scaled_out");
  points2d_rordered_free(p);
  return 0;
 }