SRB2/src/hardware/hw_model.c
toaster 417f17ebdd Do a bunch of stuff to the MD2/3 sprite2 support to get it back to feature parity with before, without going back to being hacky as fuck.
* Store the number of frames per sprite2 run in the spr2frames struct.
* Reintroduce P_GetModelSprite2, to allow for the sprite2 defaulting system to be used to full advantage even in GL.
* Instead of splitting the SUPER and normal SPR2 stuff within the same cell of the struct, have them exist in different cells just like in the "normal" sprite2 structs.
* Allow for just providing spr2 frames in order without specifying which "normal" sprite2 frame it's supposed to replace.

Also:
* Fix FF_VERTICALFLIP-ignoring regression.
* Fix whitespace adjustment in win_dll.c
* Remove bracket in P_GetSkinSprite2 because I realised it was extraneous while making sure P_GetModelSprite2 worked with it.
2019-11-02 17:52:54 +00:00

737 lines
16 KiB
C

/*
From the 'Wizard2' engine by Spaddlewit Inc. ( http://www.spaddlewit.com )
An experimental work-in-progress.
Donated to Sonic Team Junior and adapted to work with
Sonic Robo Blast 2. The license of this code matches whatever
the licensing is for Sonic Robo Blast 2.
*/
#include "../doomdef.h"
#include "../doomtype.h"
#include "../info.h"
#include "../z_zone.h"
#include "hw_model.h"
#include "hw_md2load.h"
#include "hw_md3load.h"
#include "hw_md2.h"
#include "u_list.h"
#include <string.h>
static float PI = (3.1415926535897932384626433832795f);
static float U_Deg2Rad(float deg)
{
return deg * ((float)PI / 180.0f);
}
vector_t vectorXaxis = { 1.0f, 0.0f, 0.0f };
vector_t vectorYaxis = { 0.0f, 1.0f, 0.0f };
vector_t vectorZaxis = { 0.0f, 0.0f, 1.0f };
void VectorRotate(vector_t *rotVec, const vector_t *axisVec, float angle)
{
float ux, uy, uz, vx, vy, vz, wx, wy, wz, sa, ca;
angle = U_Deg2Rad(angle);
// Rotate the point (x,y,z) around the vector (u,v,w)
ux = axisVec->x * rotVec->x;
uy = axisVec->x * rotVec->y;
uz = axisVec->x * rotVec->z;
vx = axisVec->y * rotVec->x;
vy = axisVec->y * rotVec->y;
vz = axisVec->y * rotVec->z;
wx = axisVec->z * rotVec->x;
wy = axisVec->z * rotVec->y;
wz = axisVec->z * rotVec->z;
sa = sinf(angle);
ca = cosf(angle);
rotVec->x = axisVec->x*(ux + vy + wz) + (rotVec->x*(axisVec->y*axisVec->y + axisVec->z*axisVec->z) - axisVec->x*(vy + wz))*ca + (-wy + vz)*sa;
rotVec->y = axisVec->y*(ux + vy + wz) + (rotVec->y*(axisVec->x*axisVec->x + axisVec->z*axisVec->z) - axisVec->y*(ux + wz))*ca + (wx - uz)*sa;
rotVec->z = axisVec->z*(ux + vy + wz) + (rotVec->z*(axisVec->x*axisVec->x + axisVec->y*axisVec->y) - axisVec->z*(ux + vy))*ca + (-vx + uy)*sa;
}
void UnloadModel(model_t *model)
{
// Wouldn't it be great if C just had destructors?
int i;
for (i = 0; i < model->numMeshes; i++)
{
mesh_t *mesh = &model->meshes[i];
if (mesh->frames)
{
int j;
for (j = 0; j < mesh->numFrames; j++)
{
if (mesh->frames[j].normals)
Z_Free(mesh->frames[j].normals);
if (mesh->frames[j].tangents)
Z_Free(mesh->frames[j].tangents);
if (mesh->frames[j].vertices)
Z_Free(mesh->frames[j].vertices);
if (mesh->frames[j].colors)
Z_Free(mesh->frames[j].colors);
}
Z_Free(mesh->frames);
}
else if (mesh->tinyframes)
{
int j;
for (j = 0; j < mesh->numFrames; j++)
{
if (mesh->tinyframes[j].normals)
Z_Free(mesh->tinyframes[j].normals);
if (mesh->tinyframes[j].tangents)
Z_Free(mesh->tinyframes[j].tangents);
if (mesh->tinyframes[j].vertices)
Z_Free(mesh->tinyframes[j].vertices);
}
if (mesh->indices)
Z_Free(mesh->indices);
Z_Free(mesh->tinyframes);
}
if (mesh->uvs)
Z_Free(mesh->uvs);
if (mesh->lightuvs)
Z_Free(mesh->lightuvs);
}
if (model->meshes)
Z_Free(model->meshes);
if (model->tags)
Z_Free(model->tags);
if (model->materials)
Z_Free(model->materials);
DeleteVBOs(model);
Z_Free(model);
}
tag_t *GetTagByName(model_t *model, char *name, int frame)
{
if (frame < model->maxNumFrames)
{
tag_t *iterator = &model->tags[frame * model->numTags];
int i;
for (i = 0; i < model->numTags; i++)
{
if (!stricmp(iterator[i].name, name))
return &iterator[i];
}
}
return NULL;
}
//
// LoadModel
//
// Load a model and
// convert it to the
// internal format.
//
model_t *LoadModel(const char *filename, int ztag)
{
model_t *model;
// What type of file?
const char *extension = NULL;
int i;
for (i = (int)strlen(filename)-1; i >= 0; i--)
{
if (filename[i] != '.')
continue;
extension = &filename[i];
break;
}
if (!extension)
{
CONS_Printf("Model %s is lacking a file extension, unable to determine type!\n", filename);
return NULL;
}
if (!strcmp(extension, ".md3"))
{
if (!(model = MD3_LoadModel(filename, ztag, false)))
return NULL;
}
else if (!strcmp(extension, ".md3s")) // MD3 that will be converted in memory to use full floats
{
if (!(model = MD3_LoadModel(filename, ztag, true)))
return NULL;
}
else if (!strcmp(extension, ".md2"))
{
if (!(model = MD2_LoadModel(filename, ztag, false)))
return NULL;
}
else if (!strcmp(extension, ".md2s"))
{
if (!(model = MD2_LoadModel(filename, ztag, true)))
return NULL;
}
else
{
CONS_Printf("Unknown model format: %s\n", extension);
return NULL;
}
model->mdlFilename = (char*)Z_Malloc(strlen(filename)+1, ztag, 0);
strcpy(model->mdlFilename, filename);
Optimize(model);
GeneratePolygonNormals(model, ztag);
LoadModelSprite2(model);
if (!model->spr2frames)
LoadModelInterpolationSettings(model);
// Default material properties
for (i = 0 ; i < model->numMaterials; i++)
{
material_t *material = &model->materials[i];
material->ambient[0] = 0.7686f;
material->ambient[1] = 0.7686f;
material->ambient[2] = 0.7686f;
material->ambient[3] = 1.0f;
material->diffuse[0] = 0.5863f;
material->diffuse[1] = 0.5863f;
material->diffuse[2] = 0.5863f;
material->diffuse[3] = 1.0f;
material->specular[0] = 0.4902f;
material->specular[1] = 0.4902f;
material->specular[2] = 0.4902f;
material->specular[3] = 1.0f;
material->shininess = 25.0f;
}
return model;
}
void HWR_ReloadModels(void)
{
size_t i;
INT32 s;
for (s = 0; s < MAXSKINS; s++)
{
if (md2_playermodels[s].model)
LoadModelSprite2(md2_playermodels[s].model);
}
for (i = 0; i < NUMSPRITES; i++)
{
if (md2_models[i].model)
LoadModelInterpolationSettings(md2_models[i].model);
}
}
void LoadModelInterpolationSettings(model_t *model)
{
INT32 i;
INT32 numframes = model->meshes[0].numFrames;
char *framename = model->framenames;
if (!framename)
return;
#define GET_OFFSET \
memcpy(&interpolation_flag, framename + offset, 2); \
model->interpolate[i] = (!memcmp(interpolation_flag, MODEL_INTERPOLATION_FLAG, 2));
for (i = 0; i < numframes; i++)
{
int offset = (strlen(framename) - 4);
char interpolation_flag[3];
memset(&interpolation_flag, 0x00, 3);
// find the +i on the frame name
// ANIM+i00
// so the offset is (frame name length - 4)
GET_OFFSET;
// maybe the frame had three digits?
// ANIM+i000
// so the offset is (frame name length - 5)
if (!model->interpolate[i])
{
offset--;
GET_OFFSET;
}
framename += 16;
}
#undef GET_OFFSET
}
void LoadModelSprite2(model_t *model)
{
INT32 i;
modelspr2frames_t *spr2frames = NULL;
INT32 numframes = model->meshes[0].numFrames;
char *framename = model->framenames;
if (!framename)
return;
for (i = 0; i < numframes; i++)
{
char prefix[6];
char name[5];
char interpolation_flag[3];
char framechars[4];
UINT8 frame = 0;
UINT8 spr2idx;
boolean interpolate = false;
memset(&prefix, 0x00, 6);
memset(&name, 0x00, 5);
memset(&interpolation_flag, 0x00, 3);
memset(&framechars, 0x00, 4);
if (strlen(framename) >= 9)
{
boolean super;
char *modelframename = framename;
memcpy(&prefix, modelframename, 5);
modelframename += 5;
memcpy(&name, modelframename, 4);
modelframename += 4;
// Oh look
memcpy(&interpolation_flag, modelframename, 2);
if (!memcmp(interpolation_flag, MODEL_INTERPOLATION_FLAG, 2))
{
interpolate = true;
modelframename += 2;
}
memcpy(&framechars, modelframename, 3);
if ((super = (!memcmp(prefix, "SUPER", 5))) || (!memcmp(prefix, "SPR2_", 5)))
{
spr2idx = 0;
while (spr2idx < free_spr2)
{
if (!memcmp(spr2names[spr2idx], name, 4))
{
if (!spr2frames)
spr2frames = (modelspr2frames_t*)Z_Calloc(sizeof(modelspr2frames_t)*NUMPLAYERSPRITES*2, PU_STATIC, NULL);
if (super)
spr2idx |= FF_SPR2SUPER;
if (framechars[0])
{
frame = atoi(framechars);
if (spr2frames[spr2idx].numframes < frame+1)
spr2frames[spr2idx].numframes = frame+1;
}
else
{
frame = spr2frames[spr2idx].numframes;
spr2frames[spr2idx].numframes++;
}
spr2frames[spr2idx].frames[frame] = i;
spr2frames[spr2idx].interpolate = interpolate;
break;
}
spr2idx++;
}
}
}
framename += 16;
}
if (model->spr2frames)
Z_Free(model->spr2frames);
model->spr2frames = spr2frames;
}
//
// GenerateVertexNormals
//
// Creates a new normal for a vertex using the average of all of the polygons it belongs to.
//
void GenerateVertexNormals(model_t *model)
{
int i;
for (i = 0; i < model->numMeshes; i++)
{
int j;
mesh_t *mesh = &model->meshes[i];
if (!mesh->frames)
continue;
for (j = 0; j < mesh->numFrames; j++)
{
mdlframe_t *frame = &mesh->frames[j];
int memTag = PU_STATIC;
float *newNormals = (float*)Z_Malloc(sizeof(float)*3*mesh->numTriangles*3, memTag, 0);
int k;
float *vertPtr = frame->vertices;
float *oldNormals;
M_Memcpy(newNormals, frame->normals, sizeof(float)*3*mesh->numTriangles*3);
/* if (!systemSucks)
{
memTag = Z_GetTag(frame->tangents);
float *newTangents = (float*)Z_Malloc(sizeof(float)*3*mesh->numTriangles*3, memTag);
M_Memcpy(newTangents, frame->tangents, sizeof(float)*3*mesh->numTriangles*3);
}*/
for (k = 0; k < mesh->numVertices; k++)
{
float x, y, z;
int vCount = 0;
vector_t normal;
int l;
float *testPtr = frame->vertices;
x = *vertPtr++;
y = *vertPtr++;
z = *vertPtr++;
normal.x = normal.y = normal.z = 0;
for (l = 0; l < mesh->numVertices; l++)
{
float testX, testY, testZ;
testX = *testPtr++;
testY = *testPtr++;
testZ = *testPtr++;
if (fabsf(x - testX) > FLT_EPSILON
|| fabsf(y - testY) > FLT_EPSILON
|| fabsf(z - testZ) > FLT_EPSILON)
continue;
// Found a vertex match! Add it...
normal.x += frame->normals[3 * l + 0];
normal.y += frame->normals[3 * l + 1];
normal.z += frame->normals[3 * l + 2];
vCount++;
}
if (vCount > 1)
{
// Vector::Normalize(&normal);
newNormals[3 * k + 0] = (float)normal.x;
newNormals[3 * k + 1] = (float)normal.y;
newNormals[3 * k + 2] = (float)normal.z;
/* if (!systemSucks)
{
Vector::vector_t tangent;
Vector::Tangent(&normal, &tangent);
newTangents[3 * k + 0] = tangent.x;
newTangents[3 * k + 1] = tangent.y;
newTangents[3 * k + 2] = tangent.z;
}*/
}
}
oldNormals = frame->normals;
frame->normals = newNormals;
Z_Free(oldNormals);
/* if (!systemSucks)
{
float *oldTangents = frame->tangents;
frame->tangents = newTangents;
Z_Free(oldTangents);
}*/
}
}
}
typedef struct materiallist_s
{
struct materiallist_s *next;
struct materiallist_s *prev;
material_t *material;
} materiallist_t;
static boolean AddMaterialToList(materiallist_t **head, material_t *material)
{
materiallist_t *node, *newMatNode;
for (node = *head; node; node = node->next)
{
if (node->material == material)
return false;
}
// Didn't find it, so add to the list
newMatNode = (materiallist_t*)Z_Malloc(sizeof(materiallist_t), PU_CACHE, 0);
newMatNode->material = material;
ListAdd(newMatNode, (listitem_t**)head);
return true;
}
//
// Optimize
//
// Groups triangles from meshes in the model
// Only works for models with 1 frame
//
void Optimize(model_t *model)
{
int numMeshes = 0;
int i;
materiallist_t *matListHead = NULL;
int memTag;
mesh_t *newMeshes;
materiallist_t *node;
if (model->numMeshes <= 1)
return; // No need
for (i = 0; i < model->numMeshes; i++)
{
mesh_t *curMesh = &model->meshes[i];
if (curMesh->numFrames > 1)
return; // Can't optimize models with > 1 frame
if (!curMesh->frames)
return; // Don't optimize tinyframe models (no need)
// We are condensing to 1 mesh per material, so
// the # of materials we use will be the new
// # of meshes
if (AddMaterialToList(&matListHead, curMesh->frames[0].material))
numMeshes++;
}
memTag = PU_STATIC;
newMeshes = (mesh_t*)Z_Calloc(sizeof(mesh_t) * numMeshes, memTag, 0);
i = 0;
for (node = matListHead; node; node = node->next)
{
material_t *curMat = node->material;
mesh_t *newMesh = &newMeshes[i];
mdlframe_t *curFrame;
int uvCount;
int vertCount;
int colorCount;
// Find all triangles with this material and count them
int numTriangles = 0;
int j;
for (j = 0; j < model->numMeshes; j++)
{
mesh_t *curMesh = &model->meshes[j];
if (curMesh->frames[0].material == curMat)
numTriangles += curMesh->numTriangles;
}
newMesh->numFrames = 1;
newMesh->numTriangles = numTriangles;
newMesh->numVertices = numTriangles * 3;
newMesh->uvs = (float*)Z_Malloc(sizeof(float)*2*numTriangles*3, memTag, 0);
// if (node->material->lightmap)
// newMesh->lightuvs = (float*)Z_Malloc(sizeof(float)*2*numTriangles*3, memTag, 0);
newMesh->frames = (mdlframe_t*)Z_Calloc(sizeof(mdlframe_t), memTag, 0);
curFrame = &newMesh->frames[0];
curFrame->material = curMat;
curFrame->normals = (float*)Z_Malloc(sizeof(float)*3*numTriangles*3, memTag, 0);
// if (!systemSucks)
// curFrame->tangents = (float*)Z_Malloc(sizeof(float)*3*numTriangles*3, memTag, 0);
curFrame->vertices = (float*)Z_Malloc(sizeof(float)*3*numTriangles*3, memTag, 0);
curFrame->colors = (char*)Z_Malloc(sizeof(char)*4*numTriangles*3, memTag, 0);
// Now traverse the meshes of the model, adding in
// vertices/normals/uvs that match the current material
uvCount = 0;
vertCount = 0;
colorCount = 0;
for (j = 0; j < model->numMeshes; j++)
{
mesh_t *curMesh = &model->meshes[j];
if (curMesh->frames[0].material == curMat)
{
float *dest;
float *src;
char *destByte;
char *srcByte;
M_Memcpy(&newMesh->uvs[uvCount],
curMesh->uvs,
sizeof(float)*2*curMesh->numTriangles*3);
/* if (node->material->lightmap)
{
M_Memcpy(&newMesh->lightuvs[uvCount],
curMesh->lightuvs,
sizeof(float)*2*curMesh->numTriangles*3);
}*/
uvCount += 2*curMesh->numTriangles*3;
dest = (float*)newMesh->frames[0].vertices;
src = (float*)curMesh->frames[0].vertices;
M_Memcpy(&dest[vertCount],
src,
sizeof(float)*3*curMesh->numTriangles*3);
dest = (float*)newMesh->frames[0].normals;
src = (float*)curMesh->frames[0].normals;
M_Memcpy(&dest[vertCount],
src,
sizeof(float)*3*curMesh->numTriangles*3);
/* if (!systemSucks)
{
dest = (float*)newMesh->frames[0].tangents;
src = (float*)curMesh->frames[0].tangents;
M_Memcpy(&dest[vertCount],
src,
sizeof(float)*3*curMesh->numTriangles*3);
}*/
vertCount += 3 * curMesh->numTriangles * 3;
destByte = (char*)newMesh->frames[0].colors;
srcByte = (char*)curMesh->frames[0].colors;
if (srcByte)
{
M_Memcpy(&destByte[colorCount],
srcByte,
sizeof(char)*4*curMesh->numTriangles*3);
}
else
{
memset(&destByte[colorCount],
255,
sizeof(char)*4*curMesh->numTriangles*3);
}
colorCount += 4 * curMesh->numTriangles * 3;
}
}
i++;
}
CONS_Printf("Model::Optimize(): Model reduced from %d to %d meshes.\n", model->numMeshes, numMeshes);
model->meshes = newMeshes;
model->numMeshes = numMeshes;
}
void GeneratePolygonNormals(model_t *model, int ztag)
{
int i;
for (i = 0; i < model->numMeshes; i++)
{
int j;
mesh_t *mesh = &model->meshes[i];
if (!mesh->frames)
continue;
for (j = 0; j < mesh->numFrames; j++)
{
int k;
mdlframe_t *frame = &mesh->frames[j];
const float *vertices = frame->vertices;
vector_t *polyNormals;
frame->polyNormals = (vector_t*)Z_Malloc(sizeof(vector_t) * mesh->numTriangles, ztag, 0);
polyNormals = frame->polyNormals;
for (k = 0; k < mesh->numTriangles; k++)
{
// Vector::Normal(vertices, polyNormals);
vertices += 3 * 3;
polyNormals++;
}
}
}
}
//
// Reload
//
// Reload VBOs
//
#if 0
static void Reload(void)
{
/* model_t *node;
for (node = modelHead; node; node = node->next)
{
int i;
for (i = 0; i < node->numMeshes; i++)
{
mesh_t *mesh = &node->meshes[i];
if (mesh->frames)
{
int j;
for (j = 0; j < mesh->numFrames; j++)
CreateVBO(mesh, &mesh->frames[j]);
}
else if (mesh->tinyframes)
{
int j;
for (j = 0; j < mesh->numFrames; j++)
CreateVBO(mesh, &mesh->tinyframes[j]);
}
}
}*/
}
#endif
void DeleteVBOs(model_t *model)
{
(void)model;
/* for (int i = 0; i < model->numMeshes; i++)
{
mesh_t *mesh = &model->meshes[i];
if (mesh->frames)
{
for (int j = 0; j < mesh->numFrames; j++)
{
mdlframe_t *frame = &mesh->frames[j];
if (!frame->vboID)
continue;
bglDeleteBuffers(1, &frame->vboID);
frame->vboID = 0;
}
}
else if (mesh->tinyframes)
{
for (int j = 0; j < mesh->numFrames; j++)
{
tinyframe_t *frame = &mesh->tinyframes[j];
if (!frame->vboID)
continue;
bglDeleteBuffers(1, &frame->vboID);
frame->vboID = 0;
}
}
}*/
}