int get_cd_track(int cd_id, struct current_tracks_st* dest){
MYSQL_RES* pRes;
MYSQL_ROW rowData;
int res, i = 0, num_tracks = 0;
char qs[250];
if (!connected) return 0;
memset(dest, 0, sizeof(CURRENT_TRACKS_ST));
dest->cd_id = -1;
sprintf(qs, c2s("select track_id, title from track where track.cd_id = %d order by track_id"), cd_id);
res = mysql_query(&mysql, qs);
if (res){
fprintf(stderr, c2s("Select error %d: %s\n"), MS_ENO(&mysql), MS_EMSG(&mysql));
return 0;
} else {
pRes = mysql_use_result(&mysql);
if (pRes){
if ( (num_tracks = (int)mysql_num_rows(pRes)) > 0){
while ((rowData = mysql_fetch_row(pRes))){
strcpy(dest->track[i], rowData[1]);
i++;
}
dest->cd_id = cd_id;
}
mysql_free_result(pRes);
}
}
return num_tracks;
}
int find_cds(char* search_str, struct cd_search_st* dest){
MYSQL_RES* pRes;
MYSQL_ROW rowData;
int res, i = 0, num_rows = 0;
char qs[250], ss[250];
if (!connected) return 0;
memset(dest, -1, sizeof(CD_SEARCH_ST));
mysql_escape_string(ss, search_str, strlen(search_str));
sprintf(qs, c2s("select distinct artist.id, id.id from artist, cd where artist.id = cd.artist_id and (artist.name like '%%%s%%' or cd.title like '%%%s%%' or cd.catalogue like '%%%s%%'"),ss,ss,ss);
res = mysql_query(&mysql, qs);
if (res){
fprintf(stderr, c2s("Select error %d: %s\n"), MS_ENO(&mysql), MS_EMSG(&mysql));
} else {
pRes = mysql_use_result(&mysql);
if (pRes){
num_rows = (int)mysql_num_rows(pRes);
if (num_rows > 0){
while ((rowData = mysql_fetch_row(pRes)) && i < MAX_CD_RESULT){
sscanf(rowData[1], "%d", &dest->cd_id[i]);
i++;
}
}
mysql_free_result(pRes);
}
}
return num_rows;
}
int get_cd(int cd_id, struct current_cd_st* dest){
MYSQL_RES* pRes;
MYSQL_ROW rowData;
int res;
char qs[250];
if (!connected) return 0;
memset(dest, 0, sizeof(CURRENT_CD_ST));
dest->artist_id = -1;
sprintf(qs, c2s("select artist.id, cd.id, artist.name, cd.title, cd.catalogue from artist, cd where artist.id=cd.artist_id and cd.id = %d"), cd_id);
res = mysql_query(&mysql, qs);
if (res){
fprintf(stderr, c2s("Select error %d: %s\n"), MS_ENO(&mysql), MS_EMSG(&mysql));
return 0;
} else {
pRes = mysql_use_result(&mysql);
if (pRes){
if (mysql_num_rows(pRes) > 0){
if ((rowData = mysql_fetch_row(pRes))){
sscanf(rowData[0], "%d", &dest->artist_id);
sscanf(rowData[1], "%d", &dest->cd_id);
strcpy(dest->artist_name, rowData[2]);
strcpy(dest->title, rowData[3]);
strcpy(dest->catalogue, rowData[4]);
}
}
mysql_free_result(pRes);
}
}
if (dest->artist_id != -1)
return 1;
return 0;
}
int add_cd(char* artist, char* title, char* catalogue, int *cd_id){
MYSQL_RES* pRes;
MYSQL_ROW rowData;
int res, artist_id = -1, new_cd_id = -1;
char is[250], es[250];
if (!connected) {
return 0;
}
artist_id = get_artist_id(artist);
mysql_escape_string(es, title, strlen(title));
sprintf(is, c2s("insert into cd(title,artist_id, catalogue) values('%s', '%d', '%s')"), es, artist_id, catalogue);
res = mysql_query(&mysql, is);
if (res){
fprintf(stderr, c2s("Insert error %d: %s\n"), MS_ENO(&mysql), MS_EMSG(&mysql));
return 0;
}
res = mysql_query(&mysql, c2s("select last_insert_id()"));
if (res){
fprintf(stderr, c2s("Select error %d: %s\n"), MS_ENO(&mysql), MS_EMSG(&mysql));
return 0;
} else {
pRes = mysql_use_result(&mysql);
if (pRes){
if ((rowData = mysql_fetch_row(pRes))){
sscanf(rowData[0], "%d", &new_cd_id);
}
mysql_free_result(pRes);
}
}
*cd_id = new_cd_id;
if (new_cd_id != -1) return 1;
return 0;
}
void solve(){
// memset(dp, INF, sizeof(dp));
std::deque<int> a;
SS = c2s(S);
ST = c2s(T);
printf("SS = %x\n", SS);
printf("ST = %x\n", ST);
a.push_back(SS);
printf("a.size = %d\n", (int)a.size());
dp[SS] = 1;
int oo = 20000;
CHESS ct, nt;
int cs, ns;
do {
// oo --;
cs = a.front();
a.pop_front();
s2c(cs, ct);
if (fp[cs]) continue;
fp[cs] = true;
if (cs == ST) break;
// print_chess(ct);
// printf("step of %x: %d\n", cs, dp[cs]);
for (int d=0; d<4; d++) {
if (! get_nt(ct, d, nt) ) continue;
int ns = c2s(nt);
// print_chess(nt);
if (dp[ns] == 0 or dp[cs]+1 < dp[ns]){
dp[ns] = dp[cs]+1;
};
// printf("ns = %x, fp[ns]= %d\n", ns, fp[ns]);
if (! fp[ns]) a.push_back(ns);
};
// printf("a.size = %d\n", static_cast<int>(a.size()));
} while ( oo > 0 && a.size() > 0 );
printf("oo = %d\n", oo);
printf("a.size = %d\n", static_cast<int>(a.size()));
printf("dp.size = %d\n", static_cast<int>(dp.size()));
printf("step: %d\n", dp[cs]-1);
print_chess(ct);
printf("\n\n");
show_step();
}
int database_start(char* name, char*password){
if (!connected){
mysql_init(&mysql);
if (!mysql_real_connect(&mysql, c2s("127.0.0.1"), name, password,c2s("blpcd"), 0, NULL, 0)){
fprintf(stderr, "Database connection failure:%d, %s\n", mysql_errno(&mysql), mysql_error(&mysql));
connected = 0;
} else {
connected = 1;
}
}
return connected;
}
static void emit_data_primtype(Ctype *ctype, Node *val) {
switch (ctype->type) {
case CTYPE_FLOAT: {
float v = val->fval;
emit(".long %d", *(int *)&v);
break;
}
case CTYPE_DOUBLE:
emit(".quad %ld", *(long *)&val->fval);
break;
case CTYPE_BOOL:
emit(".byte %d", !!eval_intexpr(val));
break;
case CTYPE_CHAR:
emit(".byte %d", eval_intexpr(val));
break;
case CTYPE_SHORT:
emit(".short %d", eval_intexpr(val));
break;
case CTYPE_INT:
emit(".long %d", eval_intexpr(val));
break;
case CTYPE_LONG:
case CTYPE_LLONG:
case CTYPE_PTR:
if (val->type == AST_GVAR)
emit(".quad %s", val->varname);
else
emit(".quad %d", eval_intexpr(val));
break;
default:
error("don't know how to handle\n <%s>\n <%s>", c2s(ctype), a2s(val));
}
}
static void emit_save_literal(Node *node, Ctype *totype, int off) {
switch (totype->type) {
case CTYPE_BOOL: emit("movb $%d, %d(%%rbp)", !!node->ival, off); break;
case CTYPE_CHAR: emit("movb $%d, %d(%%rbp)", node->ival, off); break;
case CTYPE_SHORT: emit("movw $%d, %d(%%rbp)", node->ival, off); break;
case CTYPE_INT: emit("movl $%d, %d(%%rbp)", node->ival, off); break;
case CTYPE_LONG:
case CTYPE_LLONG:
case CTYPE_PTR: {
unsigned long ival = node->ival;
emit("movl $%lu, %d(%%rbp)", ival & ((1L << 32) - 1), off);
emit("movl $%lu, %d(%%rbp)", ival >> 32, off + 4);
break;
}
case CTYPE_FLOAT: {
float fval = node->fval;
int *p = (int *)&fval;
emit("movl $%u, %d(%%rbp)", *p, off);
break;
}
case CTYPE_DOUBLE: {
long *p = (long *)&node->fval;
emit("movl $%lu, %d(%%rbp)", *p & ((1L << 32) - 1), off);
emit("movl $%lu, %d(%%rbp)", *p >> 32, off + 4);
break;
}
default:
error("internal error: <%s> <%s> <%d>", a2s(node), c2s(totype), off);
}
}
static SCM pg_error_msg(SCM res) {
struct pg_res *pgr;
scm_assert_smob_type(pg_res_tag, res);
pgr = (struct pg_res *)SCM_SMOB_DATA(res);
if ((pgr->status != PGRES_FATAL_ERROR) &&
(pgr->status != PGRES_NONFATAL_ERROR)) return SCM_BOOL_F;
return c2s(PQresultErrorMessage(pgr->res));
}
void print_chess(CHESS c){
printf("chess: %x\n", c2s(c));
for (int i = 0; i < SIZE*SIZE; ++i)
{
printf("%d ", c[i/SIZE][i%SIZE]);
if (i%SIZE == 3) printf("\n");
};
}
int exfat_find_used_sectors(const struct exfat* ef, off_t* a, off_t* b)
{
cluster_t ca, cb;
if (*a == 0 && *b == 0)
ca = cb = EXFAT_FIRST_DATA_CLUSTER - 1;
else
{
ca = s2c(ef, *a);
cb = s2c(ef, *b);
}
if (find_used_clusters(ef, &ca, &cb) != 0)
return 1;
if (*a != 0 || *b != 0)
*a = c2s(ef, ca);
*b = c2s(ef, cb) + (CLUSTER_SIZE(*ef->sb) - 1) / SECTOR_SIZE(*ef->sb);
return 0;
}
static char *get_load_inst(Ctype *ctype) {
switch (ctype->size) {
case 1: return "movsbq";
case 2: return "movswq";
case 4: return "movslq";
case 8: return "mov";
default:
error("Unknown data size: %s: %d", c2s(ctype), ctype->size);
}
}
void show_step(){
int cs = ST;
CHESS ct;
s2c(cs, ct);
int steps[dp[ST]-1];
int oo = 100;
while(cs != SS && oo > 0){
oo --;
for (int d = 0; d < 4; d++)
{
CHESS tt;
get_nt(ct, d, tt);
int ts = c2s(tt);
if (dp[ts] == dp[cs] - 1){
// printf("%x to %x with direction: %c\n", cs, c2s(tt), DIR_NAME[d]);
// print_chess(tt);
steps[ dp[cs] -2 ] = REVERSE_DIR[d];
// printf("%d\n", dp[cs]);
cs = c2s(tt);
s2c(cs, ct);
}
}
}
cs = SS;
for (int i = 0; i < dp[ST]-1; ++i) {
s2c(cs, ct);
int d = steps[i];
CHESS tt;
get_nt(ct, d, tt);
cs = c2s(tt);
// printf("move: %c\n", DIR_NAME[d]);
// print_chess(tt);
printf("%c", DIR_NAME[d]);
}
printf("\n");
}
int add_tracks(struct current_tracks_st* tracks){
int res, i;
char is[250], es[250];
if (!connected) return 0;
i = 0;
while (tracks->track[i][0]){
mysql_escape_string(es, tracks->track[i], strlen(tracks->track[i]));
sprintf(is, c2s("insert into track(cd_id, track_id, title) values(%d,%d,'%s')"), tracks->cd_id, i+1, es);
res = mysql_query(&mysql, is);
if (res){
fprintf(stderr, c2s("Insert error %d: %s\n"), MS_ENO(&mysql), MS_EMSG(&mysql));
return 0;
}
i++;
}
return i;
}
static char *get_int_reg(Ctype *ctype, char r) {
assert(r == 'a' || r == 'c');
switch (ctype->size) {
case 1: return (r == 'a') ? "al" : "cl";
case 2: return (r == 'a') ? "ax" : "cx";
case 4: return (r == 'a') ? "eax" : "ecx";
case 8: return (r == 'a') ? "rax" : "rcx";
default:
error("Unknown data size: %s: %d", c2s(ctype), ctype->size);
}
}
int delete_cd(int cd_id){
int res;
char qs[250];
int artist_id = -1, num_rows;
MYSQL_RES* pRes;
MYSQL_ROW rowData;
if (!connected) return 0;
sprintf(qs, c2s("select artist_id from cd where artist_id = (select artist_id from cd where id = '%d')"),cd_id);
res = mysql_query(&mysql, qs);
if (res){
fprintf(stderr, c2s("Select error %d: %s\n"), MS_ENO(&mysql), MS_EMSG(&mysql));
return 0;
} else {
pRes = mysql_use_result(&mysql);
if (pRes){
num_rows = (int)mysql_num_rows(pRes);
if (num_rows == 1){
rowData = mysql_fetch_row(pRes);
sscanf(rowData[0], "%d", &artist_id);
}
mysql_free_result(pRes);
}
}
sprintf(qs, c2s("delete from track where cd_id = '%d'"),cd_id);
res = mysql_query(&mysql, qs);
if (res){
fprintf(stderr, c2s("Delete error (track)%d: %s\n"), MS_ENO(&mysql), MS_EMSG(&mysql));
return 0;
}
sprintf(qs, c2s("delete from cd where id = '%d'"),cd_id);
res = mysql_query(&mysql, qs);
if (res){
fprintf(stderr, c2s("Delete error (cd)%d: %s\n"), MS_ENO(&mysql), MS_EMSG(&mysql));
return 0;
}
if (artist_id != -1){
sprintf(qs,c2s("Delete from artist where id = '%d'"),artist_id);
res = mysql_query(&mysql, qs);
if (res){
fprintf(stderr, c2s("Delete error (artist)%d: %s\n"), MS_ENO(&mysql), MS_EMSG(&mysql));
return 0;
}
}
return 1;
}
static Img *vtxt2img(Gfx *g, Txt *t, const char *fmt, va_list ap)
{
char s[Bufsize + 1];
vsnprintf(s, Bufsize + 1, fmt, ap);
SDL_Surface *srf = TTF_RenderUTF8_Blended(t->font, s, c2s(t->color));
if (!srf)
return NULL;
SDL_Texture *tex = SDL_CreateTextureFromSurface(g->rend, srf);
SDL_FreeSurface(srf);
if (!tex)
return NULL;
Img *i = xalloc(1, sizeof(*i));
i->tex = tex;
return i;
}
bool NaiadFoamBox::Intersect(const Ray &ray, float *tHit, float *rayEpsilon,
DifferentialGeometry *dg) const {
if (ray.zbuffer) return false;
if (ray.hitFoam) return false;
//std::cout << parent.GetPtr()->FoamPlane().size() << std::endl;
float t;
if (bb.IntersectP(ray,&t)) {
Point phit = ray(t);
PerspectiveCamera * cam = PerspectiveCamera::cur_cam;
Transform c2w;
cam->CameraToWorld.Interpolate(0.f, &c2w);
Transform w2c = Inverse(c2w);
Transform c2s = cam->CameraToScreen;
Transform s2r = cam->ScreenToRaster;
Point cPos = w2c(phit);
Point rPos = s2r(c2s(cPos));
int x = (int)(rPos.x + 0.5);
int y = (int)(rPos.y + 0.5);
int w = cam->film->xResolution;
int h = cam->film->yResolution;
if (x > 0 && y > 0 && x < w && y < h) {
ray.hitFoam = true;
/*printf("%i %i %i %i\n", x, y, w ,h);
std::cout << parent << std::endl;
std::cout << parent->parent << std::endl;
std::cout << parent->parent->foamPlane[0] << std::endl;
std::cout << parent->parent->foamPlane.size() << std::endl;
std::cout << x + y*w << std::endl;*/
//std::cout << NaiadFoam::cur->FoamPlane().size() << std::endl;
ray.alphaFoam = NaiadFoam::cur->FoamPlane()[x + y*w];
}
return false;
/*
for (int i = 0; i < particles.size(); i+=100) {
if (particles[i].Intersect(ray, tHit, rayEpsilon, dg)) {
return false;
}
}*/
}
return false;
}
int get_artist_id(char* artist){
MYSQL_RES* pRes;
MYSQL_ROW rowData;
int res, artist_id = -1;
char is[250], qs[250], es[250];
if (!connected) {
return 0;
}
mysql_escape_string(es, artist, strlen(artist));
sprintf(qs, c2s("select id from artist where name = '%s'"), es);
res = mysql_query(&mysql, qs);
if (res){
fprintf(stderr, c2s("Select error %d: %s\n"), MS_ENO(&mysql), MS_EMSG(&mysql));
return 0;
} else {
pRes = mysql_use_result(&mysql);
if (pRes){
if (mysql_num_rows(pRes) > 0){
if ((rowData = mysql_fetch_row(pRes))){
sscanf(rowData[0], "%d", &artist_id);
}
}
mysql_free_result(pRes);
}
}
if (artist_id != -1) return 1;
sprintf(is, c2s("insert into artist(name) values ('%s')"), es);
res = mysql_query(&mysql, is);
if (res){
fprintf(stderr, c2s("Insert error %d: %s\n"), MS_ENO(&mysql), MS_EMSG(&mysql));
return 0;
}
res = mysql_query(&mysql, c2s("select last_insert_id()"));
if (res){
fprintf(stderr, c2s("Select error %d: %s\n"), MS_ENO(&mysql), MS_EMSG(&mysql));
return 0;
} else {
pRes = mysql_use_result(&mysql);
if (pRes){
if ((rowData = mysql_fetch_row(pRes))){
sscanf(rowData[0], "%d", &artist_id);
}
mysql_free_result(pRes);
}
}
return artist_id;
}
static SCM pg_format_sql(SCM conn, SCM obj) {
struct pg_conn *pgc;
SCM out;
if (SCM_SMOB_PREDICATE(time_tag, obj)) {
out = format_time(obj, c2s("'%Y-%m-%d %H:%M:%S'"));
}
else if (scm_boolean_p(obj) == SCM_BOOL_T) {
if (scm_is_true(obj)) out = c2s("'t'");
else out = c2s("'f'");
}
else if (scm_is_number(obj)) {
out = scm_number_to_string(obj,
scm_from_signed_integer(10));
}
else if (scm_is_symbol(obj)) {
out = pg_format_sql(conn, scm_symbol_to_string(obj));
}
else if (scm_is_string(obj)) {
if (scm_string_null_p(obj) == SCM_BOOL_T) out = c2s("NULL");
else {
char *src = scm_to_utf8_string(obj);
scm_assert_smob_type(pg_conn_tag, conn);
pgc = (struct pg_conn *)SCM_SMOB_DATA(conn);
scm_lock_mutex(pgc->mutex);
char *sql = PQescapeLiteral(pgc->conn,
src, strlen(src));
out = safe_from_utf8(sql);
scm_unlock_mutex(pgc->mutex);
free(src);
PQfreemem(sql);
}
}
else if (scm_is_null(obj)) out = c2s("NULL");
else out = c2s("NULL");
scm_remember_upto_here_1(out);
scm_remember_upto_here_2(conn, obj);
return out;
}
/*
* Cluster to absolute offset.
*/
off_t exfat_c2o(const struct exfat* ef, cluster_t cluster)
{
return s2o(ef, c2s(ef, cluster));
}
bool NaiadFoamParticle::Intersect(const Ray &rayInc, float *tHit, float *rayEpsilon,
DifferentialGeometry *dg) const {
/*const float X0 = ray.o.x;
const float Y0 = ray.o.y;
const float Z0 = ray.o.z;
const float Xd = ray.d.x;
const float Yd = ray.d.y;
const float Zd = ray.d.z;
const float Xc = pos.x;
const float Yc = pos.y;
const float Zc = pos.z;
const float B = 2.0f * (Xd * (X0 - Xc) + Yd * (Y0 - Yc) + Zd * (Z0 - Zc));
const float C = (X0-Xc)*(X0-Xc) + (Y0-Yc)*(Y0-Yc) + (Z0-Zc)*(Z0-Zc) - r*r;
const float discriminant = B*B - 4*C;
if (discriminant < 0.0f)
return false;
const float t0 = (- B - sqrt(discriminant)) / 2.0f;
const float t1 = (- B + sqrt(discriminant)) / 2.0f;
if (t0 < 0 || t0 != t0) {
return true;
}*/
Matrix4x4 w2o_m;
w2o_m.m[0][3] = -pos.x;
w2o_m.m[1][3] = -pos.y;
w2o_m.m[2][3] = -pos.z;
Transform w2o = Transform(w2o_m);
const float thetaMin = -M_PI;
const float thetaMax = 0;
const float phiMax = 2.f*M_PI;
float phi;
Point phit;
// Transform _Ray_ to object space
Ray ray;
w2o(rayInc, &ray);
// Compute quadratic sphere coefficients
float A = ray.d.x*ray.d.x + ray.d.y*ray.d.y + ray.d.z*ray.d.z;
float B = 2 * (ray.d.x*ray.o.x + ray.d.y*ray.o.y + ray.d.z*ray.o.z);
float C = ray.o.x*ray.o.x + ray.o.y*ray.o.y +
ray.o.z*ray.o.z - r*r;
// Solve quadratic equation for _t_ values
float t0, t1;
if (!Quadratic(A, B, C, &t0, &t1))
return false;
// Compute intersection distance along ray
if (t0 > ray.maxt || t1 < ray.mint)
return false;
float thit = t0;
if (t0 < ray.mint) {
thit = t1;
if (thit > ray.maxt) return false;
}
// Compute sphere hit position and $\phi$
phit = ray(thit);
rayInc.hitFoam = true;
PerspectiveCamera * cam = PerspectiveCamera::cur_cam;
Transform c2w;
cam->CameraToWorld.Interpolate(0.f, &c2w);
Transform w2c = Inverse(c2w);
Transform c2s = cam->CameraToScreen;
Transform s2r = cam->ScreenToRaster;
Point cPos = w2c(phit);
Point rPos = s2r(c2s(cPos));
int x = (int)(rPos.x + 0.5);
int y = (int)(rPos.y + 0.5);
int w = cam->film->xResolution;
int h = cam->film->yResolution;
if (x > 0 && y > 0 && x < w && y < h) {
rayInc.hitFoam = true;
/*printf("%i %i %i %i\n", x, y, w ,h);
std::cout << parent << std::endl;
std::cout << parent->parent << std::endl;
std::cout << parent->parent->foamPlane[0] << std::endl;
std::cout << parent->parent->foamPlane.size() << std::endl;
std::cout << x + y*w << std::endl;*/
//std::cout << NaiadFoam::cur->FoamPlane().size() << std::endl;
rayInc.alphaFoam = NaiadFoam::cur->FoamPlane()[x + y*w];
}
/*if (phit.x == 0.f && phit.y == 0.f) phit.x = 1e-5f * r;
phi = atan2f(phit.y, phit.x);
if (phi < 0.) phi += 2.f*M_PI;
// Find parametric representation of sphere hit
float u = phi / phiMax;
float theta = acosf(Clamp(phit.z / r, -1.f, 1.f));
float v = (theta - thetaMin) / (thetaMax - thetaMin);
// Compute sphere $\dpdu$ and $\dpdv$
float zradius = sqrtf(phit.x*phit.x + phit.y*phit.y);
float invzradius = 1.f / zradius;
float cosphi = phit.x * invzradius;
float sinphi = phit.y * invzradius;
Vector dpdu(-phiMax * phit.y, phiMax * phit.x, 0);
Vector dpdv = (thetaMax-thetaMin) *
Vector(phit.z * cosphi, phit.z * sinphi,
-r * sinf(theta));
// Compute sphere $\dndu$ and $\dndv$
Vector d2Pduu = -phiMax * phiMax * Vector(phit.x, phit.y, 0);
Vector d2Pduv = (thetaMax - thetaMin) * phit.z * phiMax *
Vector(-sinphi, cosphi, 0.);
Vector d2Pdvv = -(thetaMax - thetaMin) * (thetaMax - thetaMin) *
Vector(phit.x, phit.y, phit.z);
// Compute coefficients for fundamental forms
float E = Dot(dpdu, dpdu);
float F = Dot(dpdu, dpdv);
float G = Dot(dpdv, dpdv);
Vector N = Normalize(Cross(dpdu, dpdv));
float e = Dot(N, d2Pduu);
float f = Dot(N, d2Pduv);
float g = Dot(N, d2Pdvv);
// Compute $\dndu$ and $\dndv$ from fundamental form coefficients
float invEGF2 = 1.f / (E*G - F*F);
Normal dndu = Normal((f*F - e*G) * invEGF2 * dpdu +
(e*F - f*E) * invEGF2 * dpdv);
Normal dndv = Normal((g*F - f*G) * invEGF2 * dpdu +
(f*F - g*E) * invEGF2 * dpdv);
//std::cout << "Got here?" << std::endl;
Matrix4x4 o2w_m;
o2w_m.m[0][3] = pos.x;
o2w_m.m[1][3] = pos.y;
o2w_m.m[2][3] = pos.z;
Transform o2w = Transform(o2w_m);
// Initialize _DifferentialGeometry_ from parametric information
*dg = DifferentialGeometry(o2w(phit), o2w(dpdu), o2w(dpdv),
o2w(dndu), o2w(dndv), u, v, parent);
dg->mult = 1.f;*/
// Update _tHit_ for quadric intersection
//*tHit = thit;
// Compute _rayEpsilon_ for quadric intersection
//*rayEpsilon = 5e-4f * *tHit;
return true;
}
