#include #include // clang-format off Mtx gMtxClear = { 65536, 0, 1, 0, 0, 65536, 0, 1, 0, 0, 0, 0, 0, 0, 0, 0, }; MtxF gMtxFClear = { 1.0f, 0.0f, 0.0f, 0.0f, 0.0f, 1.0f, 0.0f, 0.0f, 0.0f, 0.0f, 1.0f, 0.0f, 0.0f, 0.0f, 0.0f, 1.0f, }; // clang-format on MtxF* sMatrixStack; // "Matrix_stack" MtxF* sCurrentMatrix; // "Matrix_now" void Matrix_Init(GameState* gameState) { sCurrentMatrix = GameState_Alloc(gameState, 20 * sizeof(MtxF), "../sys_matrix.c", 153); sMatrixStack = sCurrentMatrix; } void Matrix_Push(void) { Matrix_MtxFCopy(sCurrentMatrix + 1, sCurrentMatrix); sCurrentMatrix++; } void Matrix_Pull(void) { sCurrentMatrix--; if (sCurrentMatrix < sMatrixStack) { __assert("Matrix_now >= Matrix_stack", "../sys_matrix.c", 176); } } void Matrix_Get(MtxF* dest) { Matrix_MtxFCopy(dest, sCurrentMatrix); } void Matrix_Put(MtxF* src) { Matrix_MtxFCopy(sCurrentMatrix, src); } MtxF* Matrix_GetCurrent(void) { return sCurrentMatrix; } void Matrix_Mult(MtxF* mf, u8 mode) { MtxF* cmf = Matrix_GetCurrent(); if (mode == MTXMODE_APPLY) { SkinMatrix_MtxFMtxFMult(cmf, mf, cmf); } else { Matrix_MtxFCopy(sCurrentMatrix, mf); } } void Matrix_Translate(f32 x, f32 y, f32 z, u8 mode) { MtxF* cmf = sCurrentMatrix; f32 tx; f32 ty; if (mode == MTXMODE_APPLY) { tx = cmf->xx; ty = cmf->yx; cmf->wx += tx * x + ty * y + cmf->zx * z; tx = cmf->xy; ty = cmf->yy; cmf->wy += tx * x + ty * y + cmf->zy * z; tx = cmf->xz; ty = cmf->yz; cmf->wz += tx * x + ty * y + cmf->zz * z; tx = cmf->xw; ty = cmf->yw; cmf->ww += tx * x + ty * y + cmf->zw * z; } else { SkinMatrix_SetTranslate(cmf, x, y, z); } } void Matrix_Scale(f32 x, f32 y, f32 z, u8 mode) { MtxF* cmf = sCurrentMatrix; if (mode == MTXMODE_APPLY) { cmf->xx *= x; cmf->xy *= x; cmf->xz *= x; cmf->yx *= y; cmf->yy *= y; cmf->yz *= y; cmf->zx *= z; cmf->zy *= z; cmf->zz *= z; cmf->xw *= x; cmf->yw *= y; cmf->zw *= z; } else { SkinMatrix_SetScale(cmf, x, y, z); } } void Matrix_RotateX(f32 x, u8 mode) { MtxF* cmf; f32 sin; f32 cos; f32 temp1; f32 temp2; if (mode == MTXMODE_APPLY) { if (x != 0) { cmf = sCurrentMatrix; sin = sinf(x); cos = cosf(x); temp1 = cmf->yx; temp2 = cmf->zx; cmf->yx = temp1 * cos + temp2 * sin; cmf->zx = temp2 * cos - temp1 * sin; temp1 = cmf->yy; temp2 = cmf->zy; cmf->yy = temp1 * cos + temp2 * sin; cmf->zy = temp2 * cos - temp1 * sin; temp1 = cmf->yz; temp2 = cmf->zz; cmf->yz = temp1 * cos + temp2 * sin; cmf->zz = temp2 * cos - temp1 * sin; temp1 = cmf->yw; temp2 = cmf->zw; cmf->yw = temp1 * cos + temp2 * sin; cmf->zw = temp2 * cos - temp1 * sin; } } else { cmf = sCurrentMatrix; if (x != 0) { sin = sinf(x); cos = cosf(x); } else { sin = 0.0f; cos = 1.0f; } cmf->xy = 0.0f; cmf->xz = 0.0f; cmf->xw = 0.0f; cmf->yx = 0.0f; cmf->yw = 0.0f; cmf->zx = 0.0f; cmf->zw = 0.0f; cmf->wx = 0.0f; cmf->wy = 0.0f; cmf->wz = 0.0f; cmf->xx = 1.0f; cmf->ww = 1.0f; cmf->yy = cos; cmf->zz = cos; cmf->yz = sin; cmf->zy = -sin; } } void Matrix_RotateY(f32 y, u8 mode) { MtxF* cmf; f32 sin; f32 cos; f32 temp1; f32 temp2; if (mode == MTXMODE_APPLY) { if (y != 0) { cmf = sCurrentMatrix; sin = sinf(y); cos = cosf(y); temp1 = cmf->xx; temp2 = cmf->zx; cmf->xx = temp1 * cos - temp2 * sin; cmf->zx = temp1 * sin + temp2 * cos; temp1 = cmf->xy; temp2 = cmf->zy; cmf->xy = temp1 * cos - temp2 * sin; cmf->zy = temp1 * sin + temp2 * cos; temp1 = cmf->xz; temp2 = cmf->zz; cmf->xz = temp1 * cos - temp2 * sin; cmf->zz = temp1 * sin + temp2 * cos; temp1 = cmf->xw; temp2 = cmf->zw; cmf->xw = temp1 * cos - temp2 * sin; cmf->zw = temp1 * sin + temp2 * cos; } } else { cmf = sCurrentMatrix; if (y != 0) { sin = sinf(y); cos = cosf(y); } else { sin = 0.0f; cos = 1.0f; } cmf->xy = 0.0f; cmf->xw = 0.0f; cmf->yx = 0.0f; cmf->yz = 0.0f; cmf->yw = 0.0f; cmf->zy = 0.0f; cmf->zw = 0.0f; cmf->wx = 0.0f; cmf->wy = 0.0f; cmf->wz = 0.0f; cmf->yy = 1.0f; cmf->ww = 1.0f; cmf->xx = cos; cmf->zz = cos; cmf->xz = -sin; cmf->zx = sin; } } void Matrix_RotateZ(f32 z, u8 mode) { MtxF* cmf; f32 sin; f32 cos; f32 temp1; f32 temp2; if (mode == MTXMODE_APPLY) { if (z != 0) { cmf = sCurrentMatrix; sin = sinf(z); cos = cosf(z); temp1 = cmf->xx; temp2 = cmf->yx; cmf->xx = temp1 * cos + temp2 * sin; cmf->yx = temp2 * cos - temp1 * sin; temp1 = cmf->xy; temp2 = cmf->yy; cmf->xy = temp1 * cos + temp2 * sin; cmf->yy = temp2 * cos - temp1 * sin; temp1 = cmf->xz; temp2 = cmf->yz; cmf->xz = temp1 * cos + temp2 * sin; cmf->yz = temp2 * cos - temp1 * sin; temp1 = cmf->xw; temp2 = cmf->yw; cmf->xw = temp1 * cos + temp2 * sin; cmf->yw = temp2 * cos - temp1 * sin; } } else { cmf = sCurrentMatrix; if (z != 0) { sin = sinf(z); cos = cosf(z); } else { sin = 0.0f; cos = 1.0f; } cmf->xz = 0.0f; cmf->xw = 0.0f; cmf->yz = 0.0f; cmf->yw = 0.0f; cmf->zx = 0.0f; cmf->zy = 0.0f; cmf->zw = 0.0f; cmf->wx = 0.0f; cmf->wy = 0.0f; cmf->wz = 0.0f; cmf->zz = 1.0f; cmf->ww = 1.0f; cmf->xx = cos; cmf->yy = cos; cmf->xy = sin; cmf->yx = -sin; } } /* * Rotates the top of the matrix stack by `z` degrees, then * rotates that matrix by `y` degrees, then rotates that matrix * by `x` degrees. (roll-pitch-yaw) * Original Name: Matrix_RotateXYZ, changed to reflect rotation order. */ void Matrix_RotateRPY(s16 x, s16 y, s16 z, u8 mode) { MtxF* cmf = sCurrentMatrix; f32 temp1; f32 temp2; f32 sin; f32 cos; if (mode == MTXMODE_APPLY) { sin = Math_Sins(z); cos = Math_Coss(z); temp1 = cmf->xx; temp2 = cmf->yx; cmf->xx = temp1 * cos + temp2 * sin; cmf->yx = temp2 * cos - temp1 * sin; temp1 = cmf->xy; temp2 = cmf->yy; cmf->xy = temp1 * cos + temp2 * sin; cmf->yy = temp2 * cos - temp1 * sin; temp1 = cmf->xz; temp2 = cmf->yz; cmf->xz = temp1 * cos + temp2 * sin; cmf->yz = temp2 * cos - temp1 * sin; temp1 = cmf->xw; temp2 = cmf->yw; cmf->xw = temp1 * cos + temp2 * sin; cmf->yw = temp2 * cos - temp1 * sin; if (y != 0) { sin = Math_Sins(y); cos = Math_Coss(y); temp1 = cmf->xx; temp2 = cmf->zx; cmf->xx = temp1 * cos - temp2 * sin; cmf->zx = temp1 * sin + temp2 * cos; temp1 = cmf->xy; temp2 = cmf->zy; cmf->xy = temp1 * cos - temp2 * sin; cmf->zy = temp1 * sin + temp2 * cos; temp1 = cmf->xz; temp2 = cmf->zz; cmf->xz = temp1 * cos - temp2 * sin; cmf->zz = temp1 * sin + temp2 * cos; temp1 = cmf->xw; temp2 = cmf->zw; cmf->xw = temp1 * cos - temp2 * sin; cmf->zw = temp1 * sin + temp2 * cos; } if (x != 0) { sin = Math_Sins(x); cos = Math_Coss(x); temp1 = cmf->yx; temp2 = cmf->zx; cmf->yx = temp1 * cos + temp2 * sin; cmf->zx = temp2 * cos - temp1 * sin; temp1 = cmf->yy; temp2 = cmf->zy; cmf->yy = temp1 * cos + temp2 * sin; cmf->zy = temp2 * cos - temp1 * sin; temp1 = cmf->yz; temp2 = cmf->zz; cmf->yz = temp1 * cos + temp2 * sin; cmf->zz = temp2 * cos - temp1 * sin; temp1 = cmf->yw; temp2 = cmf->zw; cmf->yw = temp1 * cos + temp2 * sin; cmf->zw = temp2 * cos - temp1 * sin; } } else { SkinMatrix_SetRotateRPY(cmf, x, y, z); } } /* * Roll-pitch-yaw rotation and position */ void Matrix_JointPosition(Vec3f* position, Vec3s* rotation) { MtxF* cmf = sCurrentMatrix; f32 sin; f32 cos; f32 temp1; f32 temp2; sin = Math_Sins(rotation->z); cos = Math_Coss(rotation->z); temp1 = cmf->xx; temp2 = cmf->yx; cmf->wx += temp1 * position->x + temp2 * position->y + cmf->zx * position->z; cmf->xx = temp1 * cos + temp2 * sin; cmf->yx = temp2 * cos - temp1 * sin; temp1 = cmf->xy; temp2 = cmf->yy; cmf->wy += temp1 * position->x + temp2 * position->y + cmf->zy * position->z; cmf->xy = temp1 * cos + temp2 * sin; cmf->yy = temp2 * cos - temp1 * sin; temp1 = cmf->xz; temp2 = cmf->yz; cmf->wz += temp1 * position->x + temp2 * position->y + cmf->zz * position->z; cmf->xz = temp1 * cos + temp2 * sin; cmf->yz = temp2 * cos - temp1 * sin; temp1 = cmf->xw; temp2 = cmf->yw; cmf->ww += temp1 * position->x + temp2 * position->y + cmf->zw * position->z; cmf->xw = temp1 * cos + temp2 * sin; cmf->yw = temp2 * cos - temp1 * sin; if (rotation->y != 0) { sin = Math_Sins(rotation->y); cos = Math_Coss(rotation->y); temp1 = cmf->xx; temp2 = cmf->zx; cmf->xx = temp1 * cos - temp2 * sin; cmf->zx = temp1 * sin + temp2 * cos; temp1 = cmf->xy; temp2 = cmf->zy; cmf->xy = temp1 * cos - temp2 * sin; cmf->zy = temp1 * sin + temp2 * cos; temp1 = cmf->xz; temp2 = cmf->zz; cmf->xz = temp1 * cos - temp2 * sin; cmf->zz = temp1 * sin + temp2 * cos; temp1 = cmf->xw; temp2 = cmf->zw; cmf->xw = temp1 * cos - temp2 * sin; cmf->zw = temp1 * sin + temp2 * cos; } if (rotation->x != 0) { sin = Math_Sins(rotation->x); cos = Math_Coss(rotation->x); temp1 = cmf->yx; temp2 = cmf->zx; cmf->yx = temp1 * cos + temp2 * sin; cmf->zx = temp2 * cos - temp1 * sin; temp1 = cmf->yy; temp2 = cmf->zy; cmf->yy = temp1 * cos + temp2 * sin; cmf->zy = temp2 * cos - temp1 * sin; temp1 = cmf->yz; temp2 = cmf->zz; cmf->yz = temp1 * cos + temp2 * sin; cmf->zz = temp2 * cos - temp1 * sin; temp1 = cmf->yw; temp2 = cmf->zw; cmf->yw = temp1 * cos + temp2 * sin; cmf->zw = temp2 * cos - temp1 * sin; } } #ifdef NON_MATCHING // regalloc differences void func_800D1694(f32 x, f32 y, f32 z, Vec3s* vec) { MtxF* cmf = sCurrentMatrix; f32 sp30; f32 sp2C; f32 sp28; f32 sp24; sp30 = Math_Sins(vec->y); sp2C = Math_Coss(vec->y); cmf->xx = sp2C; cmf->xz = -sp30; cmf->wx = x; cmf->wy = y; cmf->wz = z; cmf->xw = 0.0f; cmf->yw = 0.0f; cmf->zw = 0.0f; cmf->ww = 1.0f; if (vec->x != 0) { sp24 = Math_Sins(vec->x); sp28 = Math_Coss(vec->x); cmf->zy = -sp24; cmf->yy = sp28; cmf->zz = sp2C * sp28; cmf->yz = sp2C * sp24; cmf->zx = sp30 * sp28; cmf->yx = sp30 * sp24; } else { cmf->zz = sp2C; cmf->zx = sp30; cmf->zy = 0.0f; cmf->yz = 0.0f; cmf->yx = 0.0f; cmf->yy = 1.0f; } if (vec->z != 0) { sp24 = Math_Sins(vec->z); sp28 = Math_Coss(vec->z); sp30 = cmf->xx; sp2C = cmf->yx; cmf->xx = sp30 * sp28 + sp2C * sp24; cmf->yx = sp2C * sp28 - sp30 * sp24; sp30 = cmf->xz; sp2C = cmf->yz; cmf->xz = sp30 * sp28 + sp2C * sp24; cmf->yz = sp2C * sp28 - sp30 * sp24; sp2C = cmf->yy; cmf->xy = sp2C * sp24; cmf->yy = sp2C * sp28; } else { cmf->xy = 0.0f; } } #else #pragma GLOBAL_ASM("asm/non_matchings/code/sys_matrix/func_800D1694.s") #endif Mtx* Matrix_MtxFToMtx(MtxF* src, Mtx* dest) { s32 temp; u16* m1 = (u16*)&dest->m[0][0]; u16* m2 = (u16*)&dest->m[2][0]; temp = src->xx * 0x10000; m1[0] = (temp >> 0x10); m1[16 + 0] = temp & 0xFFFF; temp = src->xy * 0x10000; m1[1] = (temp >> 0x10); m1[16 + 1] = temp & 0xFFFF; temp = src->xz * 0x10000; m1[2] = (temp >> 0x10); m1[16 + 2] = temp & 0xFFFF; temp = src->xw * 0x10000; m1[3] = (temp >> 0x10); m1[16 + 3] = temp & 0xFFFF; temp = src->yx * 0x10000; m1[4] = (temp >> 0x10); m1[16 + 4] = temp & 0xFFFF; temp = src->yy * 0x10000; m1[5] = (temp >> 0x10); m1[16 + 5] = temp & 0xFFFF; temp = src->yz * 0x10000; m1[6] = (temp >> 0x10); m1[16 + 6] = temp & 0xFFFF; temp = src->yw * 0x10000; m1[7] = (temp >> 0x10); m1[16 + 7] = temp & 0xFFFF; temp = src->zx * 0x10000; m1[8] = (temp >> 0x10); m1[16 + 8] = temp & 0xFFFF; temp = src->zy * 0x10000; m1[9] = (temp >> 0x10); m2[9] = temp & 0xFFFF; temp = src->zz * 0x10000; m1[10] = (temp >> 0x10); m2[10] = temp & 0xFFFF; temp = src->zw * 0x10000; m1[11] = (temp >> 0x10); m2[11] = temp & 0xFFFF; temp = src->wx * 0x10000; m1[12] = (temp >> 0x10); m2[12] = temp & 0xFFFF; temp = src->wy * 0x10000; m1[13] = (temp >> 0x10); m2[13] = temp & 0xFFFF; temp = src->wz * 0x10000; m1[14] = (temp >> 0x10); m2[14] = temp & 0xFFFF; temp = src->ww * 0x10000; m1[15] = (temp >> 0x10); m2[15] = temp & 0xFFFF; return dest; } Mtx* Matrix_ToMtx(Mtx* dest, char* file, s32 line) { return Matrix_MtxFToMtx(Matrix_CheckFloats(sCurrentMatrix, file, line), dest); } Mtx* Matrix_NewMtx(GraphicsContext* gfxCtx, char* file, s32 line) { return Matrix_ToMtx(Graph_Alloc(gfxCtx, sizeof(Mtx)), file, line); } Mtx* Matrix_SkinMatrix_MtxFToNewMtx(MtxF* src, GraphicsContext* gfxCtx) { return Matrix_MtxFToMtx(src, Graph_Alloc(gfxCtx, sizeof(Mtx))); } void Matrix_MultVec3f(Vec3f* src, Vec3f* dest) { MtxF* cmf = sCurrentMatrix; dest->x = cmf->wx + (cmf->xx * src->x + cmf->yx * src->y + cmf->zx * src->z); dest->y = cmf->wy + (cmf->xy * src->x + cmf->yy * src->y + cmf->zy * src->z); dest->z = cmf->wz + (cmf->xz * src->x + cmf->yz * src->y + cmf->zz * src->z); } void Matrix_MtxFCopy(MtxF* dest, MtxF* src) { dest->xx = src->xx; dest->xy = src->xy; dest->xz = src->xz; dest->xw = src->xw; dest->yx = src->yx; dest->yy = src->yy; dest->yz = src->yz; dest->yw = src->yw; dest->xx = src->xx; dest->xy = src->xy; dest->xz = src->xz; dest->xw = src->xw; dest->yx = src->yx; dest->yy = src->yy; dest->yz = src->yz; dest->yw = src->yw; dest->zx = src->zx; dest->zy = src->zy; dest->zz = src->zz; dest->zw = src->zw; dest->wx = src->wx; dest->wy = src->wy; dest->wz = src->wz; dest->ww = src->ww; dest->zx = src->zx; dest->zy = src->zy; dest->zz = src->zz; dest->zw = src->zw; dest->wx = src->wx; dest->wy = src->wy; dest->wz = src->wz; dest->ww = src->ww; } void Matrix_MtxToMtxF(Mtx* src, MtxF* dest) { u16* m1 = (u16*)&src->m[0][0]; u16* m2 = (u16*)&src->m[2][0]; dest->xx = ((m1[0] << 0x10) | m2[0]) * (1 / 65536.0f); dest->xy = ((m1[1] << 0x10) | m2[1]) * (1 / 65536.0f); dest->xz = ((m1[2] << 0x10) | m2[2]) * (1 / 65536.0f); dest->xw = ((m1[3] << 0x10) | m2[3]) * (1 / 65536.0f); dest->yx = ((m1[4] << 0x10) | m2[4]) * (1 / 65536.0f); dest->yy = ((m1[5] << 0x10) | m2[5]) * (1 / 65536.0f); dest->yz = ((m1[6] << 0x10) | m2[6]) * (1 / 65536.0f); dest->yw = ((m1[7] << 0x10) | m2[7]) * (1 / 65536.0f); dest->zx = ((m1[8] << 0x10) | m2[8]) * (1 / 65536.0f); dest->zy = ((m1[9] << 0x10) | m2[9]) * (1 / 65536.0f); dest->zz = ((m1[10] << 0x10) | m2[10]) * (1 / 65536.0f); dest->zw = ((m1[11] << 0x10) | m2[11]) * (1 / 65536.0f); dest->wx = ((m1[12] << 0x10) | m2[12]) * (1 / 65536.0f); dest->wy = ((m1[13] << 0x10) | m2[13]) * (1 / 65536.0f); dest->wz = ((m1[14] << 0x10) | m2[14]) * (1 / 65536.0f); dest->ww = ((m1[15] << 0x10) | m2[15]) * (1 / 65536.0f); } void Matrix_MultVec3fExt(Vec3f* src, Vec3f* dest, MtxF* mf) { dest->x = mf->wx + (mf->xx * src->x + mf->yx * src->y + mf->zx * src->z); dest->y = mf->wy + (mf->xy * src->x + mf->yy * src->y + mf->zy * src->z); dest->z = mf->wz + (mf->xz * src->x + mf->yz * src->y + mf->zz * src->z); } void Matrix_Reverse(MtxF* mf) { f32 temp; temp = mf->xy; mf->xy = mf->yx; mf->yx = temp; temp = mf->xz; mf->xz = mf->zx; mf->zx = temp; temp = mf->yz; mf->yz = mf->zy; mf->zy = temp; } #ifdef NON_MATCHING void func_800D1FD4(MtxF* mf) { MtxF* cmf = sCurrentMatrix; f32 temp; temp = sqrtf(SQ(cmf->xx) + SQ(cmf->xy) + SQ(cmf->xz)); cmf->xx = mf->xx * temp; cmf->xy = mf->xy * temp; cmf->xz = mf->xz * temp; temp = sqrtf(SQ(cmf->yx) + SQ(cmf->yy) + SQ(cmf->yz)); cmf->yx = mf->yx * temp; cmf->yy = mf->yy * temp; cmf->yz = mf->yz * temp; temp = sqrtf(SQ(cmf->zx) + SQ(cmf->zy) + SQ(cmf->zz)); cmf->zx = mf->zx * temp; cmf->zy = mf->zy * temp; cmf->zz = mf->zz * temp; } #else #pragma GLOBAL_ASM("asm/non_matchings/code/sys_matrix/func_800D1FD4.s") #endif #ifdef NON_MATCHING // same differences as func_800D2264 void func_800D20CC(MtxF* mf, Vec3s* vec, s32 flag) { vec->x = Math_atan2f(-mf->zy, sqrtf(SQ(mf->zx) + SQ(mf->zz))) * (32768 / M_PI); if ((vec->x == 0x4000) || (vec->x == -0x4000)) { vec->z = 0; vec->y = Math_atan2f(-mf->xz, mf->xx) * (32768 / M_PI); return; } vec->y = Math_atan2f(mf->zx, mf->zz) * (32768 / M_PI); if (!flag) { vec->z = Math_atan2f(mf->xy, mf->yy) * (32768 / M_PI); } else { vec->z = Math_atan2f(mf->xy / sqrtf(SQ(mf->xx) + SQ(mf->xz) + SQ(mf->xy)), mf->yy / sqrtf(SQ(mf->yx) + SQ(mf->yz) + SQ(mf->yy))) * (32768 / M_PI); } } #else #pragma GLOBAL_ASM("asm/non_matchings/code/sys_matrix/func_800D20CC.s") #endif #ifdef NON_MATCHING // same differences as func_800D20CC void func_800D2264(MtxF* mf, Vec3s* vec, s32 flag) { vec->y = Math_atan2f(-mf->xz, sqrtf(SQ(mf->xx) + SQ(mf->xy))) * (32768 / M_PI); if ((vec->y == 0x4000) || (vec->y == -0x4000)) { vec->x = 0; vec->z = Math_atan2f(-mf->yx, mf->yy) * (32768 / M_PI); return; } vec->z = Math_atan2f(mf->xy, mf->xx) * (32768 / M_PI); if (!flag) { vec->x = Math_atan2f(mf->yz, mf->zz) * (32768 / M_PI); } else { vec->x = Math_atan2f(mf->yz / sqrtf(SQ(mf->yx) + SQ(mf->yy) + SQ(mf->yz)), mf->zz / sqrtf(SQ(mf->zx) + SQ(mf->zy) + SQ(mf->zz))) * (32768 / M_PI); } } #else #pragma GLOBAL_ASM("asm/non_matchings/code/sys_matrix/func_800D2264.s") #endif #ifdef NON_MATCHING // regalloc differences void func_800D23FC(f32 f, Vec3f* vec, u8 mode) { MtxF* cmf; f32 sin; f32 cos; f32 rCos; f32 temp1; f32 temp2; f32 temp3; f32 temp4; if (mode == MTXMODE_APPLY) { if (f != 0) { cmf = sCurrentMatrix; sin = sinf(f); cos = cosf(f); temp1 = cmf->xx; temp2 = cmf->yx; temp3 = cmf->zx; temp4 = (vec->x * temp1 + vec->y * temp2 + vec->z * temp3) * (1.0f - cos); cmf->xx = temp1 * cos + vec->x * temp4 + sin * (temp2 * vec->z - temp3 * vec->y); cmf->yx = temp2 * cos + vec->y * temp4 + sin * (temp3 * vec->x - temp1 * vec->z); cmf->zx = temp3 * cos + vec->z * temp4 + sin * (temp1 * vec->y - temp2 * vec->x); temp1 = cmf->xy; temp2 = cmf->yy; temp3 = cmf->zy; temp4 = (vec->x * temp1 + vec->y * temp2 + vec->z * temp3) * (1.0f - cos); cmf->xy = temp1 * cos + vec->x * temp4 + sin * (temp2 * vec->z - temp3 * vec->y); cmf->yy = temp2 * cos + vec->y * temp4 + sin * (temp3 * vec->x - temp1 * vec->z); cmf->zy = temp3 * cos + vec->z * temp4 + sin * (temp1 * vec->y - temp2 * vec->x); temp1 = cmf->xz; temp2 = cmf->yz; temp3 = cmf->zz; temp4 = (vec->x * temp1 + vec->y * temp2 + vec->z * temp3) * (1.0f - cos); cmf->xz = temp1 * cos + vec->x * temp4 + sin * (temp2 * vec->z - temp3 * vec->y); cmf->yz = temp2 * cos + vec->y * temp4 + sin * (temp3 * vec->x - temp1 * vec->z); cmf->zz = temp3 * cos + vec->z * temp4 + sin * (temp1 * vec->y - temp2 * vec->x); } } else { cmf = sCurrentMatrix; if (f != 0) { sin = sinf(f); cos = cosf(f); rCos = 1.0f - cos; cmf->xx = vec->x * vec->x * rCos + cos; cmf->yy = vec->y * vec->y * rCos + cos; cmf->zz = vec->z * vec->z * rCos + cos; temp1 = vec->x * rCos * vec->y; temp2 = vec->z * sin; cmf->xy = temp1 + temp2; cmf->yx = temp1 - temp2; temp1 = vec->x * rCos * vec->z; temp2 = vec->y * sin; cmf->xz = temp1 - temp2; cmf->zx = temp1 + temp2; temp1 = vec->y * rCos * vec->z; temp2 = vec->x * sin; cmf->yz = temp1 + temp2; cmf->zy = temp1 - temp2; cmf->xw = 0.0f; cmf->yw = 0.0f; cmf->zw = 0.0f; cmf->wx = 0.0f; cmf->wy = 0.0f; cmf->wz = 0.0f; cmf->ww = 1.0f; } else { cmf->xy = 0.0f; cmf->xz = 0.0f; cmf->xw = 0.0f; cmf->yx = 0.0f; cmf->yz = 0.0f; cmf->yw = 0.0f; cmf->zx = 0.0f; cmf->zy = 0.0f; cmf->zw = 0.0f; cmf->wx = 0.0f; cmf->wy = 0.0f; cmf->wz = 0.0f; cmf->xx = 1.0f; cmf->yy = 1.0f; cmf->zz = 1.0f; cmf->ww = 1.0f; } } } #else #pragma GLOBAL_ASM("asm/non_matchings/code/sys_matrix/func_800D23FC.s") #endif MtxF* Matrix_CheckFloats(MtxF* mf, char* file, s32 line) { s32 i, j; for (i = 0; i < 4; i++) { for (j = 0; j < 4; j++) { if (!(-32768.0f <= mf->mf[i][j]) || !(mf->mf[i][j] < 32768.0f)) { osSyncPrintf("%s %d: [%s] =\n" "/ %12.6f %12.6f %12.6f %12.6f \\\n" "| %12.6f %12.6f %12.6f %12.6f |\n" "| %12.6f %12.6f %12.6f %12.6f |\n" "\\ %12.6f %12.6f %12.6f %12.6f /\n", file, line, "mf", mf->xx, mf->yx, mf->zx, mf->wx, mf->xy, mf->yy, mf->zy, mf->wy, mf->xz, mf->yz, mf->zz, mf->wz, mf->xw, mf->yw, mf->zw, mf->ww); Fault_AddHungupAndCrash(file, line); } } } return mf; } void func_800D2A34(MtxF* mf, f32 arg1, f32 arg2, f32 arg3, f32 arg4) { mf->xy = 0.0f; mf->xz = 0.0f; mf->xw = 0.0f; mf->yx = 0.0f; mf->yz = 0.0f; mf->yw = 0.0f; mf->zx = 0.0f; mf->zy = 0.0f; mf->zw = 0.0f; mf->xx = arg1; mf->yy = arg1; mf->zz = arg1; mf->wx = arg2; mf->wy = arg3; mf->wz = arg4; mf->ww = 1.0f; } void func_800D2A98(Mtx* mtx, f32 arg1, f32 arg2, f32 arg3, f32 arg4) { MtxF mf; func_800D2A34(&mf, arg1, arg2, arg3, arg4); guMtxF2L(&mf, mtx); } void func_800D2AE4(Mtx* mtx, f32 arg1, f32 arg2, f32 arg3, f32 arg4) { u16* m1 = (u16*)&mtx->m[0][0]; u16* m2 = (u16*)&mtx->m[2][0]; u32 temp; temp = (s32)(arg1 * 65536.0f); m2[0] = temp & 0xFFFF; m1[0] = (temp >> 16) & 0xFFFF; temp = (s32)(arg1 * 65536.0f); m1[5] = (temp >> 16) & 0xFFFF; m2[5] = temp & 0xFFFF; temp = (s32)(arg1 * 65536.0f); m1[10] = (temp >> 16) & 0xFFFF; m2[10] = temp & 0xFFFF; temp = (s32)(arg2 * 65536.0f); m1[12] = (temp >> 16) & 0xFFFF; m2[12] = temp & 0xFFFF; temp = (s32)(arg3 * 65536.0f); m1[13] = (temp >> 16) & 0xFFFF; m2[13] = temp & 0xFFFF; temp = (s32)(arg4 * 65536.0f); m1[14] = (temp >> 16) & 0xFFFF; m2[14] = temp & 0xFFFF; m1[1] = 0; m1[2] = 0; m1[3] = 0; m1[4] = 0; m1[6] = 0; m1[7] = 0; m1[8] = 0; m1[9] = 0; m1[11] = 0; m1[15] = 1; m2[1] = 0; m2[2] = 0; m2[3] = 0; m2[4] = 0; m2[6] = 0; m2[7] = 0; m2[8] = 0; m2[9] = 0; m2[11] = 0; m2[15] = 0; } void func_800D2BD0(Mtx* mtx, f32 arg1, f32 arg2, f32 arg3, f32 arg4, f32 arg5, f32 arg6) { u16* m1 = (u16*)&mtx->m[0][0]; u16* m2 = (u16*)&mtx->m[2][0]; u32 temp; temp = (s32)(arg1 * 65536.0f); m1[0] = (temp >> 16) & 0xFFFF; m2[0] = temp & 0xFFFF; temp = (s32)(arg2 * 65536.0f); m1[5] = (temp >> 16) & 0xFFFF; m2[5] = temp & 0xFFFF; temp = (s32)(arg3 * 65536.0f); m1[10] = (temp >> 16) & 0xFFFF; m2[10] = temp & 0xFFFF; temp = (s32)(arg4 * 65536.0f); m1[12] = (temp >> 16) & 0xFFFF; m2[12] = temp & 0xFFFF; temp = (s32)(arg5 * 65536.0f); m1[13] = (temp >> 16) & 0xFFFF; m2[13] = temp & 0xFFFF; temp = (s32)(arg6 * 65536.0f); m1[14] = (temp >> 16) & 0xFFFF; m2[14] = temp & 0xFFFF; m1[1] = 0; m1[2] = 0; m1[3] = 0; m1[4] = 0; m1[6] = 0; m1[7] = 0; m1[8] = 0; m1[9] = 0; m1[11] = 0; m1[15] = 1; m2[1] = 0; m2[2] = 0; m2[3] = 0; m2[4] = 0; m2[6] = 0; m2[7] = 0; m2[8] = 0; m2[9] = 0; m2[11] = 0; m2[15] = 0; } #ifdef NON_MATCHING // minor ordering and regalloc differences void func_800D2CEC(Mtx* mtx, f32 arg1, f32 arg2, f32 arg3, f32 arg4, f32 arg5, f32 arg6) { u16* m1 = (u16*)&mtx->m[0][0]; u16* m2 = (u16*)&mtx->m[2][0]; u32 temp; mtx->m[0][1] = 0; mtx->m[2][1] = 0; mtx->m[0][3] = 0; mtx->m[2][3] = 0; mtx->m[0][4] = 0; temp = (s32)(arg1 * 65536.0f); m1[0] = temp & 0xFFFF; mtx->m[2][0] = temp << 16; temp = (s32)(arg2 * 65536.0f); mtx->m[0][2] = temp >> 16; mtx->m[2][2] = temp & 0xFFFF; m1[1] = 0; mtx->m[2][4] = 0; temp = (s32)(arg3 * 65536.0f); mtx->m[1][1] = temp; m1[11] = 0; mtx->m[3][1] = temp << 16; temp = (s32)(arg4 * 65536.0f); m1[12] = (temp >> 16) & 0xFFFF; m2[12] = temp & 0xFFFF; temp = (s32)(arg5 * 65536.0f); m1[13] = (temp >> 16) & 0xFFFF; m2[13] = temp & 0xFFFF; temp = (s32)(arg6 * 65536.0f); m1[14] = (temp >> 16) & 0xFFFF; mtx->m[3][3] = temp << 16; m1[15] = 1; } #else #pragma GLOBAL_ASM("asm/non_matchings/code/sys_matrix/func_800D2CEC.s") #endif