enumerate-balanced-ideals/old/coxeter.c

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#include "coxeter.h"
#include "queue.h"
#include <memory.h>
#include <gsl/gsl_linalg.h>
#include <gsl/gsl_blas.h>
static void applyGenerator(int i, double *x, double *y, int rank, double **schlaefliMatrix)
{
memcpy(y, x, rank*sizeof(double));
for(int j = 0; j < rank; j++)
y[i] -= schlaefliMatrix[i][j]*x[j];
}
static int check_equal_sector(gsl_matrix *x1, gsl_matrix *x2, gsl_matrix *yinv, gsl_matrix *schlaefli, gsl_vector *starting, gsl_vector *i1, gsl_vector *i2)
{
double scalarProduct;
int rank = x1->size1;
// calculate <y^{-1} * x1 * x2 * s, e_i> for all i, or identically the components of schlaefli*y^{-1}*x*s
gsl_blas_dgemv(CblasNoTrans, 1.0, x2, starting, 0.0, i1);
gsl_blas_dgemv(CblasNoTrans, 1.0, x1, i1, 0.0, i2);
gsl_blas_dgemv(CblasNoTrans, 1.0, yinv, i2, 0.0, i1);
gsl_blas_dgemv(CblasNoTrans, 1.0, schlaefli, i1, 0.0, i2);
for(int i = 0; i < rank; i++)
if(gsl_vector_get(i2, i) < 0)
return 0;
return 1;
}
static void invert(gsl_matrix *x, gsl_matrix *xinv)
{
int rank = x->size1;
gsl_matrix *xLU = gsl_matrix_alloc(rank, rank);
gsl_permutation *p = gsl_permutation_alloc(rank);
int s;
gsl_matrix_memcpy(xLU, x);
gsl_linalg_LU_decomp(xLU, p, &s);
gsl_linalg_LU_invert(xLU, p, xinv);
gsl_permutation_free(p);
gsl_matrix_free(xLU);
}
static void generate_schlaefli_matrix(semisimple_type_t type, gsl_matrix *mat)
{
gsl_matrix_set_zero(mat);
int offset = 0;
for(int k = 0; k < type.n; k++) {
if(type.factors[k].series == 'A') {
for(int i = 0; i < type.factors[k].rank; i++)
for(int j = 0; j < type.factors[k].rank; j++)
if(i == j)
gsl_matrix_set(mat, offset + i, offset + j, 2.0);
else if(i - j == 1 || i - j == -1)
gsl_matrix_set(mat, offset + i, offset + j, -1.0);
} else if(type.factors[k].series == 'B' || type.factors[k].series == 'C') {
for(int i = 0; i < type.factors[k].rank; i++)
for(int j = 0; j < type.factors[k].rank; j++)
if(i == j)
gsl_matrix_set(mat, offset + i, offset + j, 2.0);
else if(i == 0 && j == 1 || i == 1 && j == 0)
gsl_matrix_set(mat, offset + i, offset + j, -sqrt(2.0));
else if(i - j == 1 || i - j == -1)
gsl_matrix_set(mat, offset + i, offset + j, -1.0);
} else if(type.factors[k].series == 'D') {
for(int i = 0; i < type.factors[k].rank; i++)
for(int j = 0; j < type.factors[k].rank; j++)
if(i == j)
gsl_matrix_set(mat, offset + i, offset + j, 2.0);
else if(i > 0 && j > 0 && (i - j == 1 || i - j == -1) || i == 0 && j == 2 || i == 2 && j == 0)
gsl_matrix_set(mat, offset + i, offset + j, -1.0);
} else if(type.factors[k].series == 'F') {
ERROR(type.factors[k].rank != 4, "A Coxeter group of type %c%d does not exist or is not implemented!\n", type.factors[k].series, type.factors[k].rank);
for(int i = 0; i < 4; i++)
gsl_matrix_set(mat, offset + i, offset + i, 2.0);
for(int i = 0; i < 3; i++) {
gsl_matrix_set(mat, offset + i, offset + i + 1, i == 1 ? -sqrt(2.0) : -1.0);
gsl_matrix_set(mat, offset + i + 1, offset + i, i == 1 ? -sqrt(2.0) : -1.0);
}
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} else if(type.factors[k].series == 'G') {
ERROR(type.factors[k].rank != 2, "A Coxeter group of type %c%d does not exist or is not implemented!\n", type.factors[k].series, type.factors[k].rank);
gsl_matrix_set(mat, offset + 0, offset + 0, 2.0);
gsl_matrix_set(mat, offset + 0, offset + 1, -sqrt(3.0));
gsl_matrix_set(mat, offset + 1, offset + 0, -sqrt(3.0));
gsl_matrix_set(mat, offset + 1, offset + 1, 2.0);
} else {
ERROR(1, "A Coxeter group of type %c%d does not exist or is not implemented!\n", type.factors[k].series, type.factors[k].rank);
}
offset += type.factors[k].rank;
}
}
int coxeter_rank(semisimple_type_t type)
{
int rank = 0;
for(int i = 0; i < type.n; i++)
rank += type.factors[i].rank;
return rank;
}
int coxeter_order(semisimple_type_t type)
{
int order = 1;
for(int i = 0; i < type.n; i++) {
if(type.factors[i].series == 'A') { // (rank+1)!
for(int j = 1; j <= type.factors[i].rank + 1; j++)
order *= j;
} else if(type.factors[i].series == 'B' || type.factors[i].series == 'C') { // 2^rank * rank!
for(int j = 1; j <= type.factors[i].rank; j++)
order *= 2*j;
} else if(type.factors[i].series == 'D') { // 2^(rank-1) * rank!
for(int j = 2; j <= type.factors[i].rank; j++)
order *= 2*j;
} else if(type.factors[i].series == 'E') {
if(type.factors[i].rank == 6)
order *= 51840;
else if(type.factors[i].rank == 7)
order *= 2903040;
else if(type.factors[i].rank == 8)
order *= 696729600;
else
ERROR(1, "A Coxeter group of type %c%d does not exist or is not implemented!\n", type.factors[i].series, type.factors[i].rank);
} else if(type.factors[i].series == 'F') {
ERROR(type.factors[i].rank != 4, "A Coxeter group of type %c%d does not exist or is not implemented!\n", type.factors[i].series, type.factors[i].rank);
order *= 1152;
} else if(type.factors[i].series == 'G') {
ERROR(type.factors[i].rank != 2, "A Coxeter group of type %c%d does not exist or is not implemented!\n", type.factors[i].series, type.factors[i].rank);
order *= 12;
} else if(type.factors[i].series == 'H') {
if(type.factors[i].rank == 2)
order *= 10;
else if(type.factors[i].rank == 3)
order *= 120;
else if(type.factors[i].rank == 4)
order *= 14400;
else
ERROR(1, "A Coxeter group of type %c%d does not exist or is not implemented!\n", type.factors[i].series, type.factors[i].rank);
} else {
ERROR(1, "A Coxeter group of type %c%d does not exist or is not implemented!\n", type.factors[i].series, type.factors[i].rank);
}
}
return order;
}
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int coxeter_hyperplanes(semisimple_type_t type)
{
int hyperplanes = 0;
for(int i = 0; i < type.n; i++) {
if(type.factors[i].series == 'A') // rank*(rank+1)/2
hyperplanes += (type.factors[i].rank * (type.factors[i].rank + 1)) / 2;
else if(type.factors[i].series == 'B' || type.factors[i].series == 'C') // rank * rank
hyperplanes += type.factors[i].rank * type.factors[i].rank;
else if(type.factors[i].series == 'D') // rank * (rank - 1)
hyperplanes += type.factors[i].rank * (type.factors[i].rank - 1);
else if(type.factors[i].series == 'E') {
if(type.factors[i].rank == 6)
hyperplanes += 36;
else if(type.factors[i].rank == 7)
hyperplanes += 63;
else if(type.factors[i].rank == 8)
hyperplanes += 120;
else
ERROR(1, "A Coxeter group of type %c%d does not exist or is not implemented!\n", type.factors[i].series, type.factors[i].rank);
} else if(type.factors[i].series == 'F') {
ERROR(type.factors[i].rank != 4, "A Coxeter group of type %c%d does not exist or is not implemented!\n", type.factors[i].series, type.factors[i].rank);
hyperplanes += 24;
} else if(type.factors[i].series == 'G') {
ERROR(type.factors[i].rank != 2, "A Coxeter group of type %c%d does not exist or is not implemented!\n", type.factors[i].series, type.factors[i].rank);
hyperplanes += 6;
} else {
ERROR(1, "A Coxeter group of type %c%d does not exist or is not implemented!\n", type.factors[i].series, type.factors[i].rank);
}
}
return hyperplanes;
}
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unsigned long opposition_involution(semisimple_type_t type, unsigned long theta)
{
int offset = 0;
unsigned long result = 0;
for(int i = 0; i < type.n; i++) {
unsigned long current = (theta >> offset) & ((1 << type.factors[i].rank) - 1);
unsigned long iota_current;
if(type.factors[i].series == 'B' || type.factors[i].series == 'C' || type.factors[i].series == 'F' || type.factors[i].series == 'G') {
iota_current = current;
} else if(type.factors[i].series == 'A') {
iota_current = 0;
for(int j = 0; j < type.factors[i].rank; j++)
iota_current += ((current >> j) & 1) << (type.factors[i].rank - 1 - j);
} else if(type.factors[i].series == 'D') {
if(type.factors[i].rank % 2 == 0) {
iota_current = current;
} else {
ERROR(1, "The opposition involution for type %c%d is not yet implemented!\n", type.factors[i].series, type.factors[i].rank);
}
} else if(type.factors[i].series == 'E') {
ERROR(1, "The opposition involution for En is not yet implemented!\n");
}
result += iota_current << offset;
offset += type.factors[i].rank;
}
return result;
}
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static void generate_starting_vector(int rank, gsl_matrix *schlaefli, gsl_vector *result)
{
gsl_matrix *schlaefliLU = gsl_matrix_alloc(rank, rank);
gsl_vector *diagonal = gsl_vector_alloc(rank);
gsl_permutation *p = gsl_permutation_alloc(rank);
int s;
for(int i = 0; i < rank; i++)
gsl_vector_set(diagonal, i, 1.0);
gsl_matrix_memcpy(schlaefliLU, schlaefli);
gsl_linalg_LU_decomp(schlaefliLU, p, &s);
gsl_linalg_LU_solve(schlaefliLU, p, diagonal, result);
gsl_permutation_free(p);
gsl_vector_free(diagonal);
gsl_matrix_free(schlaefliLU);
}
void generate_coxeter_graph(semisimple_type_t type, int *result)
{
int rank = coxeter_rank(type);
int order = coxeter_order(type);
int element_count;
gsl_matrix *schlaefliMatrix = gsl_matrix_alloc(rank, rank);
gsl_vector *startingVector = gsl_vector_alloc(rank);
gsl_matrix *generators = (gsl_matrix*)malloc(rank*sizeof(gsl_matrix));
double *generators_data = (double*)malloc(rank*rank*rank*sizeof(double));
gsl_matrix *elements = (gsl_matrix*)malloc(order*sizeof(gsl_matrix));
double *elements_data = (double*)malloc(rank*rank*order*sizeof(double));
gsl_matrix *inverses = (gsl_matrix*)malloc(order*sizeof(gsl_matrix));
double *inverses_data = (double*)malloc(rank*rank*order*sizeof(double));
gsl_vector *i1 = gsl_vector_alloc(rank);
gsl_vector *i2 = gsl_vector_alloc(rank);
gsl_matrix *current_element = gsl_matrix_alloc(rank, rank);
queue_t queue;
int current;
for(int i = 0; i < rank; i++)
generators[i] = gsl_matrix_view_array(generators_data + i*rank*rank, rank, rank).matrix;
for(int i = 0; i < order; i++)
elements[i] = gsl_matrix_view_array(elements_data + i*rank*rank, rank, rank).matrix;
for(int i = 0; i < order; i++)
inverses[i] = gsl_matrix_view_array(inverses_data + i*rank*rank, rank, rank).matrix;
generate_schlaefli_matrix(type, schlaefliMatrix);
generate_starting_vector(rank, schlaefliMatrix, startingVector);
for(int i = 0; i < rank; i++) {
gsl_matrix_set_identity(&generators[i]);
for(int j = 0; j < rank; j++)
if(i == j)
gsl_matrix_set(&generators[i], i, j, -1.0);
else
gsl_matrix_set(&generators[i], i, j, -gsl_matrix_get(schlaefliMatrix, i, j));
// gsl_matrix_fprintf(stdout, &generators[i], "%f");
// printf("\n");
}
queue_init(&queue);
queue_put(&queue, 0);
element_count = 1;
gsl_matrix_set_identity(&elements[0]);
gsl_matrix_set_identity(&inverses[0]);
while((current = queue_get(&queue)) != -1) {
for(int i = 0; i < rank; i++) {
int j;
for(j = 0; j < element_count; j++) {
if(check_equal_sector(&generators[i], &elements[current], &inverses[j], schlaefliMatrix, startingVector, i1, i2)) { // generators[i] * elements[current] = elements[j]
result[rank*current + i] = j;
break;
}
}
// if no existing element equals generators[i] * elements[current], create one
if(j == element_count) {
ERROR(element_count >= order, "Got more elements than the order of the group should be!\n");
gsl_blas_dgemm(CblasNoTrans, CblasNoTrans, 1.0, &generators[i], &elements[current], 0.0, &elements[element_count]);
invert(&elements[element_count], &inverses[element_count]);
result[rank*current + i] = element_count;
queue_put(&queue, element_count);
element_count++;
}
}
}
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ERROR(element_count != order, "Something went wrong building the Coxeter group. Found %d elements, %d expected\n", element_count, order);
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/*
for(int i = 0; i < order; i++) {
printf("%d: ", i);
for(int j = 0; j < rank; j++)
printf("%d ", result[rank*i + j]);
printf("\n");
}
*/
gsl_vector_free(startingVector);
gsl_vector_free(i1);
gsl_vector_free(i2);
gsl_matrix_free(schlaefliMatrix);
gsl_matrix_free(current_element);
free(generators);
free(elements);
free(generators_data);
free(elements_data);
}