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Quake BSP renderer for PS1
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ps1bsp/draw.h

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#ifndef __DRAW_H__
#define __DRAW_H__
#include "common.h"
#include "display.h"
#include <inline_c.h>
static INLINE void draw_triangle_lit(SVECTOR *verts, u_long *ot)
{
// Draw a single triangle
const SVECTOR *v0 = &verts[0];
const SVECTOR *v1 = &verts[1];
const SVECTOR *v2 = &verts[2];
// Naively draw the triangle with GTE, nothing special or optimized about this
gte_ldv3(v0, v1, v2);
gte_rtpt(); // Rotation, translation, perspective projection
// Draw a flat-shaded untextured colored triangle
POLY_G3 *poly = (POLY_G3*)mem_prim(sizeof(POLY_G3));
setPolyG3(poly);
gte_stsxy3_g3(poly);
poly->r0 = poly->g0 = poly->b0 = (uint8_t)v0->pad;
poly->r1 = poly->g1 = poly->b1 = (uint8_t)v1->pad;
poly->r2 = poly->g2 = poly->b2 = (uint8_t)v2->pad;
addPrim(ot, poly);
++polyCount;
}
static INLINE void draw_trianglestrip_lit(SVECTOR *verts, u_char numVerts, u_long *ot)
{
// Draw the face as a triangle strip
const SVECTOR *v0, *v1, *v2;
const SVECTOR *head = verts;
const SVECTOR *tail = verts + numVerts;
u_char reverse = 0;
v2 = head++; // Initialize first vertex to index 0 and set head to index 1
u_char numTris = numVerts - 2;
for (u_char triIdx = 0; triIdx < numTris; ++triIdx)
{
if (reverse ^= 1)
{
v0 = v2;
v1 = head;
v2 = --tail;
}
else
{
v0 = v1;
v1 = ++head;
v2 = tail;
}
// Naively draw the triangle with GTE, nothing special or optimized about this
gte_ldv3(v0, v1, v2);
gte_rtpt(); // Rotation, translation, perspective projection
// Draw a flat-shaded untextured colored triangle
POLY_G3 *poly = (POLY_G3*)mem_prim(sizeof(POLY_G3));
setPolyG3(poly);
gte_stsxy3_g3(poly);
poly->r0 = poly->g0 = poly->b0 = (uint8_t)v0->pad;
poly->r1 = poly->g1 = poly->b1 = (uint8_t)v1->pad;
poly->r2 = poly->g2 = poly->b2 = (uint8_t)v2->pad;
addPrim(ot, poly);
++polyCount;
}
}
static INLINE void draw_quadstrip_lit(SVECTOR *verts, u_char numVerts, u_long *ot)
{
// Draw the face as a quad strip
const SVECTOR *v0, *v1, *v2, *v3;
const SVECTOR *head = verts;
const SVECTOR *tail = verts + numVerts;
// Initialize the first two vertices
v2 = --tail;
v3 = head++;
// Normally a quad strip would have (N-2)/2 quads, but we might end up with a sole triangle at the end which will be drawn as a collapsed quad
u_char numQuads = (numVerts - 1) >> 1;
for (u_char quadIdx = 0; quadIdx < numQuads; ++quadIdx)
{
v0 = v2;
v1 = v3;
v2 = --tail;
v3 = head++;
// Naively draw the quad with GTE, nothing special or optimized about this
gte_ldv3(v0, v1, v2);
gte_rtpt(); // Rotation, translation, perspective projection
// Draw a flat-shaded untextured colored quad
POLY_G4 *poly = (POLY_G4*)mem_prim(sizeof(POLY_G4));
setPolyG4(poly);
gte_stsxy3_g3(poly);
// Transform the fourth vertex to complete the quad
gte_ldv0(v3);
gte_rtps();
gte_stsxy(&poly->x3);
poly->r0 = poly->g0 = poly->b0 = (uint8_t)v0->pad;
poly->r1 = poly->g1 = poly->b1 = (uint8_t)v1->pad;
poly->r2 = poly->g2 = poly->b2 = (uint8_t)v2->pad;
poly->r3 = poly->g3 = poly->b3 = (uint8_t)v3->pad;
addPrim(ot, poly);
++polyCount;
}
}
static INLINE void draw_triangle_textured(STVECTOR *verts, u_short tpage, u_long *ot)
{
// Draw a single textured triangle
const STVECTOR *v0 = &verts[0];
const STVECTOR *v1 = &verts[1];
const STVECTOR *v2 = &verts[2];
// Naively draw the triangle with GTE, nothing special or optimized about this
gte_ldv3(v0, v1, v2);
gte_rtpt(); // Rotation, translation, perspective projection
// Draw a gouraud shaded textured triangle
POLY_GT3 *poly = (POLY_GT3*)mem_prim(sizeof(POLY_GT3));
setPolyGT3(poly);
gte_stsxy3_gt3(poly);
// Texture UVs
setUV3(poly, v0->u, v0->v, v1->u, v1->v, v2->u, v2->v);
poly->clut = quake_clut;
poly->tpage = tpage;
poly->r0 = poly->g0 = poly->b0 = (uint8_t)v0->pad;
poly->r1 = poly->g1 = poly->b1 = (uint8_t)v1->pad;
poly->r2 = poly->g2 = poly->b2 = (uint8_t)v2->pad;
addPrim(ot, poly);
++polyCount;
}
static INLINE void draw_quadstrip_textured(const ps1bsp_vertex_t *vertices, const ps1bsp_polyvertex_t *polyVerts, u_char numVerts, u_short tpage, u_long *ot)
{
const ps1bsp_polyvertex_t *v0, *v1, *v2, *v3;
u_char i0, i1, i2, i3;
u_char head = 0;
u_char tail = numVerts;
// Initialize the first two vertices
i2 = --tail;
i3 = head++;
// Normally a quad strip would have (N-2)/2 quads, but we might end up with a sole triangle at the end which will be drawn as a collapsed quad
// NOTE: testing has shown that the PS1 is faster just rendering quads and accepting the odd collapsed quad, rather than being clever with pointer comparisons and drawing a single triangle at the end.
u_char numQuads = (numVerts - 1) >> 1;
for (u_char quadIdx = 0; quadIdx < numQuads; ++quadIdx)
{
i0 = i2;
i1 = i3;
i2 = --tail;
i3 = head++;
v0 = &polyVerts[i0];
v1 = &polyVerts[i1];
v2 = &polyVerts[i2];
v3 = &polyVerts[i3];
// Transform the first three vertices
gte_ldv3(&vertices[v0->index], &vertices[v1->index], &vertices[v2->index]);
gte_rtpt(); // Rotation, translation, perspective projection
// Draw a gouraud shaded textured quad
POLY_GT4 *poly = (POLY_GT4*)mem_prim(sizeof(POLY_GT4));
setPolyGT4(poly);
gte_stsxy3_gt3(poly);
// Transform the fourth vertex to complete the quad
gte_ldv0(&vertices[v3->index]);
gte_rtps();
gte_stsxy(&poly->x3);
// Texture UVs
setUV4(poly, v0->u, v0->v, v1->u, v1->v, v2->u, v2->v, v3->u, v3->v);
poly->clut = quake_clut;
poly->tpage = tpage;
// Vertex color lighting
poly->r0 = poly->g0 = poly->b0 = (uint8_t)v0->light;
poly->r1 = poly->g1 = poly->b1 = (uint8_t)v1->light;
poly->r2 = poly->g2 = poly->b2 = (uint8_t)v2->light;
poly->r3 = poly->g3 = poly->b3 = (uint8_t)v3->light;
addPrim(ot, poly);
++polyCount;
}
}
static INLINE void draw_quadstrip_water(const ps1bsp_vertex_t *vertices, const ps1bsp_polyvertex_t *polyVerts, u_char numVerts, u_short tpage, u_long *ot)
{
// Draw the face as a quad strip
const ps1bsp_polyvertex_t *v0, *v1, *v2, *v3;
u_char i0, i1, i2, i3;
u_char head = 0;
u_char tail = numVerts;
// Initialize the first two vertices
i2 = --tail;
i3 = head++;
// Normally a quad strip would have (N-2)/2 quads, but we might end up with a sole triangle at the end which will be drawn as a collapsed quad
u_char numQuads = (numVerts - 1) >> 1;
for (u_char quadIdx = 0; quadIdx < numQuads; ++quadIdx)
{
i0 = i2;
i1 = i3;
i2 = --tail;
i3 = head++;
v0 = &polyVerts[i0];
v1 = &polyVerts[i1];
v2 = &polyVerts[i2];
v3 = &polyVerts[i3];
// Transform the first three vertices
gte_ldv3(&vertices[v0->index], &vertices[v1->index], &vertices[v2->index]);
gte_rtpt(); // Rotation, translation, perspective projection
// Draw a flat-shaded textured quad
POLY_FT4 *poly = (POLY_FT4*)mem_prim(sizeof(POLY_FT4));
setPolyFT4(poly);
gte_stsxy3_ft3(poly);
// Transform the fourth vertex to complete the quad
gte_ldv0(&vertices[v3->index]);
gte_rtps();
gte_stsxy(&poly->x3);
// Texture UVs
setUV4(poly, v0->u, v0->v, v1->u, v1->v, v2->u, v2->v, v3->u, v3->v);
poly->clut = quake_clut;
poly->tpage = tpage;
// Unlit
poly->r0 = poly->g0 = poly->b0 = 255;
addPrim(ot, poly);
++polyCount;
}
}
#endif // __DRAW_H__