void idle(void) {
static int frames;
static float time;
float ifps;
vec3 v;
vec4 q0,q1,q2;
matrix m;
ifps = 1.0 / getfps();
if(!my_pause) angle += ifps * 360.0 / 4.0;
v_set(sin(angle * DEG2RAD / 3),cos(angle * DEG2RAD / 7),2,light);
v_set(0,0,1,v);
q_set(v,psi,q0);
v_set(0,1,0,v);
q_set(v,phi,q1);
q_multiply(q0,q1,q2);
q_to_matrix(q2,m);
v_set(dist,0,0,camera);
v_transform(camera,m,camera);
v_add(camera,mesh,camera);
frames++;
time += ifps;
if(time > 1.0) {
printf("%d frames %.2f fps\n",frames,(float)frames / time);
frames = 0;
time = 0;
}
}
// Swaps q[a] with q[b]
void swap( vertex_t *v
, uint16_t *q
, uint16_t a
, uint16_t b
)
{
uint16_t s = 0;
s = q[a];
q_set(v, q, a, q[b]);
q_set(v, q, b, s);
}
/*
* Check whether b is of the form a * X - a * Y
* for a non-zero rational a and two products X and Y.
* If so return X in *r1 and Y in *r2
*/
bool arith_buffer_is_equality(arith_buffer_t *b, pprod_t **r1, pprod_t **r2) {
mlist_t *p, *q;
pprod_t *x, *y;
rational_t a;
bool is_eq;
is_eq = false;
if (b->nterms == 2) {
p = b->list;
q = p->next;
x = p->prod;
y = p->prod;
if (x != empty_pp) {
*r1 = x;
*r2 = y;
q_init(&a);
q_set(&a, &p->coeff);
q_add(&a, &q->coeff);
is_eq = q_is_zero(&a);
q_clear(&a);
}
}
return is_eq;
}
/*
* Add a * r to b
*/
void arith_buffer_add_mono(arith_buffer_t *b, rational_t *a, pprod_t *r) {
mlist_t *p, *aux;
mlist_t **q;
if (q_is_zero(a)) return;
q = &b->list;
p = *q;
assert(p == b->list);
while (pprod_precedes(p->prod, r)) {
q = &p->next;
p = *q;
}
// p points to a monomial with p->prod >= r, *q == p
// q is &b->list if p is first in the list
// q is &p0->next otherwise, where p0 = predecessor of p
if (p->prod == r) {
q_add(&p->coeff, a);
} else {
assert(pprod_precedes(r, p->prod));
aux = alloc_list_elem(b->store);
aux->next = p;
q_set(&aux->coeff, a);
aux->prod = r;
*q = aux;
b->nterms ++;
}
}
/*
* Get the constant term of p and copy it in c
* - p must be normalized
*/
void monarray_constant(monomial_t *p, rational_t *c) {
if (p->var == const_idx) {
q_set(c, &p->coeff);
} else {
q_clear(c);
}
}
/*
* Test 4: a is large, b is large
*/
static void test_big_big(void) {
rational_t a, b, c;
uint32_t i, j;
q_init(&a);
q_init(&b);
q_init(&c);
for (i=0; i<NBIGS; i++) {
q_set_from_string(&b, large_divisor[i]);
for (j=0; j<NBIGS; j++) {
q_set_from_string(&a, large_signed[j]);
q_set(&c, &a);
q_integer_div(&a, &b);
q_integer_rem(&c, &b);
printf("div[%s, %s]: quotient = ", large_signed[j], large_divisor[i]);
q_print(stdout, &a);
printf(", remainder = ");
q_print(stdout, &c);
printf("\n");
}
printf("\n");
}
q_clear(&a);
q_clear(&b);
q_clear(&c);
}
/*
* Test 2: a is large, b is small
*/
static void test_big_small(void) {
rational_t a, b, c;
uint32_t i;
int32_t y;
q_init(&a);
q_init(&b);
q_init(&c);
for (y=1; y<8; y++) {
q_set32(&b, y);
for (i=0; i<NBIGS; i++) {
q_set_from_string(&a, large_signed[i]);
q_set(&c, &a);
q_integer_div(&a, &b);
q_integer_rem(&c, &b);
printf("div[%s, %"PRId32"]: quotient = ", large_signed[i], y);
q_print(stdout, &a);
printf(", remainder = ");
q_print(stdout, &c);
printf("\n");
}
printf("\n");
}
q_clear(&a);
q_clear(&b);
q_clear(&c);
}
/* The q_space parameter must have enough storage capacity for 7 quaternion structures */
void mol_rotate(cVector *axis, cVector *origin, float phi, quaternion *q_space, cTetrahedron *target)
{
int i;
quaternion *to_rotate, *q_target;
cVector *ptr_axis;
to_rotate = q_space++;
q_target = q_space++;
ptr_axis = (cVector *) malloc(sizeof(cVector));
for(i = 0; i < 5; i++)
{
v_set(ptr_axis, axis->x, axis->y, axis->z);
q_set(q_target, 0, 0, 0, 0);
to_rotate->s = 0;
to_rotate->v.x = target->cAtoms[i].v.x;
to_rotate->v.y = target->cAtoms[i].v.y;
to_rotate->v.z = target->cAtoms[i].v.z;
q_rotate(to_rotate, ptr_axis, origin, phi, q_space, q_target);
target->cAtoms[i].v.x = q_target->v.x;
target->cAtoms[i].v.y = q_target->v.y;
target->cAtoms[i].v.z = q_target->v.z;
}
free(ptr_axis);
}
/*
* Copy the content of buffer b into f
*/
static void set_normal_form(normal_form_t *f, poly_buffer_t *b) {
monomial_t *mono;
uint32_t i, n;
n = poly_buffer_nterms(b);
mono = poly_buffer_mono(b);
assert(n <= f->size);
for (i=0; i<n; i++) {
f->mono[i].var = mono[i].var;
q_set(&f->mono[i].coeff, &mono[i].coeff);
}
f->mono[i].var = max_idx; // end marker
f->nterms = n;
f->hash = hash_monarray(f->mono, n);
}
/*
* Add poly to buffer b
*/
void arith_buffer_add_monarray(arith_buffer_t *b, monomial_t *poly, pprod_t **pp) {
mlist_t *p, *aux;
mlist_t **q;
pprod_t *r1;
assert(good_pprod_array(poly, pp));
q = &b->list;
p = *q;
while (poly->var < max_idx) {
// poly points to a pair (coeff, x_i)
// r1 = power product for x_i
r1 = *pp;
while (pprod_precedes(p->prod, r1)) {
q = &p->next;
p = *q;
}
// p points to monomial whose prod is >= r1 in the deg-lex order
// q is either &b->list or &p0->next where p0 is the predecessor
// of p in the list
if (p->prod == r1) {
q_add(&p->coeff, &poly->coeff);
q = &p->next;
p = *q;
} else {
assert(pprod_precedes(r1, p->prod));
aux = alloc_list_elem(b->store);
aux->next = p;
q_set(&aux->coeff, &poly->coeff);
aux->prod = r1;
*q = aux;
q = &aux->next;
b->nterms ++;
}
// move to the next monomial of poly
poly ++;
pp ++;
}
}
/*
* Copy p into q:
* - p must be terminated by the end marked
* - q must be large enough to store the result (including end marker)
*/
uint32_t copy_monarray(monomial_t *p, monomial_t *p1) {
uint32_t n;
int32_t v;
v = p1->var;
n = 0;
while (v != max_idx) {
p->var = v;
q_set(&p->coeff, &p1->coeff);
n ++;
p ++;
p1 ++;
v = p1->var;
}
p->var = max_idx;
return n;
}
/*
* Allocate a polynomial_t object and copy a into it.
* - a must be normalized.
* - no side effect.
*/
polynomial_t *monarray_copy_to_poly(monomial_t *a, uint32_t n) {
polynomial_t *p;
uint32_t i;
if (n >= MAX_POLY_SIZE) {
out_of_memory();
}
p = (polynomial_t *) safe_malloc(sizeof(polynomial_t) + (n + 1) * sizeof(monomial_t));
p->nterms = n;
for (i=0; i<n; i++) {
p->mono[i].var = a[i].var;
q_init(&p->mono[i].coeff);
q_set(&p->mono[i].coeff, &a[i].coeff);
}
// end-marker
p->mono[i].var = max_idx;
q_init(&p->mono[i].coeff);
return p;
}
/*
* Add r * b1 to b
*/
void arith_buffer_add_pp_times_buffer(arith_buffer_t *b, arith_buffer_t *b1, pprod_t *r) {
mlist_t *p, *aux, *p1;
mlist_t **q;
pprod_t *r1;
q = &b->list;
p = *q;
p1 = b1->list;
while (p1->next != NULL) {
r1 = pprod_mul(b->ptbl, p1->prod, r);
while (pprod_precedes(p->prod, r1)) {
q = &p->next;
p = *q;
}
if (p->prod == r1) {
q_add(&p->coeff, &p1->coeff);
// q = p;
// p = p->next;
q = &p->next;
p = *q;
} else {
assert(pprod_precedes(r1, p->prod));
aux = alloc_list_elem(b->store);
aux->next = p;
q_set(&aux->coeff, &p1->coeff);
aux->prod = r1;
// q->next = aux;
// q = aux;
*q = aux;
q = &aux->next;
b->nterms ++;
}
p1 = p1->next;
}
}
/*
* Phase and period of p
* - p is c + (a_1/b_1) x_1 + ... + (a_n/b_n) x_n where
* a_i/b_i is an irreducible fraction
* - let D = gcd(a_1,..., a_n) and L = lcm(b_1,...,b_n)
* then period = D/L and phase = c - floor(c/period) * period
*/
void monarray_period_and_phase(monomial_t *p, rational_t *period, rational_t *phase) {
rational_t aux;
monomial_t *c;
int32_t v;
/*
* c := the constant monomial of p or NULL if p's constant is zero
*/
c = NULL;
v = p->var;
if (v == const_idx) {
c = p;
p ++;
v = p->var;
}
if (v < max_idx) {
/*
* p is not a constant: compute D and L
* we use period for D and phase for L
*/
q_get_num(period, &p->coeff); // D := |a_1|
if (q_is_neg(period)) {
q_neg(period);
}
q_get_den(phase, &p->coeff); // L := b_1
q_init(&aux);
for (;;) {
p ++;
v = p->var;
if (v >= max_idx) break;
q_get_num(&aux, &p->coeff);
q_gcd(period, &aux); // D := gcd(D, a_i)
q_get_den(&aux, &p->coeff);
q_lcm(phase, &aux); // L := lcm(L, b_i)
}
assert(q_is_pos(period) && q_is_pos(phase));
q_div(period, phase); // period := D/L
/*
* Phase: constant modulo D/L
*/
if (c == NULL) {
q_clear(phase); // no constant: phase = 0
} else {
q_set(&aux, &c->coeff);
q_div(&aux, period);
q_floor(&aux); // aux = floor(c/period)
q_set(phase, &c->coeff);
q_submul(phase, &aux, period); // phase = c - aux * period
assert(q_is_nonneg(phase) && q_lt(phase, period));
}
q_clear(&aux);
} else {
/*
* p is constant: period := 0, phase = constant coeff
*/
q_clear(period);
if (c == NULL) {
q_clear(phase);
} else {
q_set(phase, &c->coeff);
}
}
}
