#include <string.h>
#include <math.h>
#include <assert.h>
+#if defined(__WATCOMC__) || defined(_MSC_VER) || defined(__DJGPP__)
+#include <malloc.h>
+#else
+#include <alloca.h>
+#endif
#include "3dgfx.h"
#include "gfxutil.h"
#include "polyfill.h"
#define STACK_SIZE 8
typedef float g3d_matrix[16];
-#define MAX_VBUF_SIZE 256
#define MAX_LIGHTS 4
+#define IMM_VBUF_SIZE 256
+
struct light {
float x, y, z;
float r, g, b;
uint16_t *pixels;
int vport[4];
+
+ /* immediate mode */
+ int imm_prim;
+ int imm_numv, imm_pcount;
+ struct g3d_vertex imm_curv;
+ struct g3d_vertex imm_vbuf[IMM_VBUF_SIZE];
};
+static void imm_flush(void);
static void xform4_vec3(const float *mat, float *vec);
static void xform3_vec3(const float *mat, float *vec);
static void shade(struct g3d_vertex *v);
}
void g3d_draw_indexed(int prim, const struct g3d_vertex *varr, int varr_size,
- const int16_t *iarr, int iarr_size)
+ const uint16_t *iarr, int iarr_size)
{
- int i, j, nfaces;
+ int i, j, vnum, nfaces;
struct pvertex pv[16];
struct g3d_vertex v[16];
- int vnum = prim; /* primitive vertex counts correspond to enum values */
int mvtop = st->mtop[G3D_MODELVIEW];
int ptop = st->mtop[G3D_PROJECTION];
+ struct g3d_vertex *tmpv;
+
+ tmpv = alloca(prim * 6 * sizeof *tmpv);
/* calc the normal matrix */
memcpy(st->norm_mat, st->mat[G3D_MODELVIEW][mvtop], 16 * sizeof(float));
st->norm_mat[12] = st->norm_mat[13] = st->norm_mat[14] = 0.0f;
- nfaces = (iarr ? iarr_size : varr_size) / vnum;
+ nfaces = (iarr ? iarr_size : varr_size) / prim;
for(j=0; j<nfaces; j++) {
vnum = prim; /* reset vnum for each iteration */
if(st->opt & G3D_LIGHTING) {
shade(v + i);
}
+ if(st->opt & G3D_TEXTURE_GEN) {
+ v[i].u = v[i].nx * 0.5 + 0.5;
+ v[i].v = v[i].ny * 0.5 + 0.5;
+ }
xform4_vec3(st->mat[G3D_PROJECTION][ptop], &v[i].x);
}
/* clipping */
for(i=0; i<6; i++) {
- struct g3d_vertex tmpv[16];
memcpy(tmpv, v, vnum * sizeof *v);
if(clip_frustum(v, &vnum, tmpv, vnum, i) < 0) {
int32_t ay = pv[1].y - pv[0].y;
int32_t bx = pv[2].x - pv[0].x;
int32_t by = pv[2].y - pv[0].y;
- int32_t cross_z = ax * (by >> 8) - ay * (bx >> 8);
+ int32_t cross_z = (ax >> 4) * (by >> 4) - (ay >> 4) * (bx >> 4);
int sign = (cross_z >> 31) & 1;
if(!(sign ^ st->frontface)) {
}
}
+void g3d_begin(int prim)
+{
+ st->imm_prim = prim;
+ st->imm_pcount = prim;
+ st->imm_numv = 0;
+}
+
+void g3d_end(void)
+{
+ imm_flush();
+}
+
+static void imm_flush(void)
+{
+ int numv = st->imm_numv;
+ st->imm_numv = 0;
+ g3d_draw_indexed(st->imm_prim, st->imm_vbuf, numv, 0, 0);
+}
+
+void g3d_vertex(float x, float y, float z)
+{
+ struct g3d_vertex *vptr = st->imm_vbuf + st->imm_numv++;
+ *vptr = st->imm_curv;
+ vptr->x = x;
+ vptr->y = y;
+ vptr->z = z;
+ vptr->w = 1.0f;
+
+ if(!--st->imm_pcount) {
+ if(st->imm_numv >= IMM_VBUF_SIZE - st->imm_prim) {
+ imm_flush();
+ }
+ st->imm_pcount = st->imm_prim;
+ }
+}
+
+void g3d_normal(float x, float y, float z)
+{
+ st->imm_curv.nx = x;
+ st->imm_curv.ny = y;
+ st->imm_curv.nz = z;
+}
+
+void g3d_color3b(unsigned char r, unsigned char g, unsigned char b)
+{
+ st->imm_curv.r = r;
+ st->imm_curv.g = g;
+ st->imm_curv.b = b;
+ st->imm_curv.a = 255;
+}
+
+void g3d_color4b(unsigned char r, unsigned char g, unsigned char b, unsigned char a)
+{
+ st->imm_curv.r = r;
+ st->imm_curv.g = g;
+ st->imm_curv.b = b;
+ st->imm_curv.a = a;
+}
+
+void g3d_color3f(float r, float g, float b)
+{
+ int ir = r * 255.0f;
+ int ig = g * 255.0f;
+ int ib = b * 255.0f;
+ st->imm_curv.r = ir > 255 ? 255 : ir;
+ st->imm_curv.g = ig > 255 ? 255 : ig;
+ st->imm_curv.b = ib > 255 ? 255 : ib;
+ st->imm_curv.a = 255;
+}
+
+void g3d_color4f(float r, float g, float b, float a)
+{
+ int ir = r * 255.0f;
+ int ig = g * 255.0f;
+ int ib = b * 255.0f;
+ int ia = a * 255.0f;
+ st->imm_curv.r = ir > 255 ? 255 : ir;
+ st->imm_curv.g = ig > 255 ? 255 : ig;
+ st->imm_curv.b = ib > 255 ? 255 : ib;
+ st->imm_curv.a = ia > 255 ? 255 : ia;
+}
+
+void g3d_texcoord(float u, float v)
+{
+ st->imm_curv.u = u;
+ st->imm_curv.v = v;
+}
+
static void xform4_vec3(const float *mat, float *vec)
{
float x = mat[0] * vec[0] + mat[4] * vec[1] + mat[8] * vec[2] + mat[12];