#include "global.h" #include "vt.h" #include "overlays/effects/ovl_Effect_Ss_HitMark/z_eff_ss_hitmark.h" typedef s32 (*ColChkResetFunc)(GlobalContext*, Collider*); typedef void (*ColChkBloodFunc)(GlobalContext*, Collider*, Vec3f*); typedef void (*ColChkApplyFunc)(GlobalContext*, CollisionCheckContext*, Collider*); typedef void (*ColChkVsFunc)(GlobalContext*, CollisionCheckContext*, Collider*, Collider*); typedef s32 (*ColChkLineFunc)(GlobalContext*, CollisionCheckContext*, Collider*, Vec3f*, Vec3f*); typedef struct { /* 0 */ u8 blood; /* 1 */ u8 effect; } HitInfo; // size = 0x2 typedef enum { /* 0 */ BLOOD_NONE, /* 1 */ BLOOD_BLUE, /* 2 */ BLOOD_GREEN, /* 3 */ BLOOD_WATER, /* 4 */ BLOOD_RED, /* 5 */ BLOOD_RED2 } ColChkBloodType; typedef enum { /* 0 */ HIT_WHITE, /* 1 */ HIT_DUST, /* 2 */ HIT_RED, /* 3 */ HIT_SOLID, /* 4 */ HIT_WOOD, /* 5 */ HIT_NONE } ColChkHitType; typedef enum { /* 0 */ MASSTYPE_IMMOVABLE, /* 1 */ MASSTYPE_HEAVY, /* 2 */ MASSTYPE_NORMAL } ColChkMassType; /** * Draws a red triangle with vertices vA, vB, and vC. */ void Collider_DrawRedPoly(GraphicsContext* gfxCtx, Vec3f* vA, Vec3f* vB, Vec3f* vC) { Collider_DrawPoly(gfxCtx, vA, vB, vC, 255, 0, 0); } /** * Draws the triangle with vertices vA, vB, and vC and with the specified color. */ void Collider_DrawPoly(GraphicsContext* gfxCtx, Vec3f* vA, Vec3f* vB, Vec3f* vC, u8 r, u8 g, u8 b) { Vtx* vtxTbl; Vtx* vtx; f32 nx; f32 ny; f32 nz; f32 originDist; OPEN_DISPS(gfxCtx, "../z_collision_check.c", 713); gSPMatrix(POLY_OPA_DISP++, &gMtxClear, G_MTX_NOPUSH | G_MTX_LOAD | G_MTX_MODELVIEW); gDPSetPrimColor(POLY_OPA_DISP++, 0x00, 0xFF, r, g, b, 50); gDPPipeSync(POLY_OPA_DISP++); gDPSetRenderMode(POLY_OPA_DISP++, G_RM_FOG_SHADE_A, G_RM_AA_ZB_OPA_SURF2); gSPTexture(POLY_OPA_DISP++, 0, 0, 0, G_TX_RENDERTILE, G_OFF); gDPPipeSync(POLY_OPA_DISP++); gDPSetCombineLERP(POLY_OPA_DISP++, SHADE, 0, PRIMITIVE, 0, SHADE, 0, PRIMITIVE, 0, 0, 0, 0, COMBINED, 0, 0, 0, COMBINED); gSPClearGeometryMode(POLY_OPA_DISP++, G_CULL_BOTH); gSPSetGeometryMode(POLY_OPA_DISP++, G_LIGHTING); gDPPipeSync(POLY_OPA_DISP++); vtxTbl = Graph_Alloc(gfxCtx, 3 * sizeof(Vtx)); ASSERT(vtxTbl != NULL, "vtx_tbl != NULL", "../z_collision_check.c", 726); vtxTbl[0].n.ob[0] = vA->x; vtxTbl[0].n.ob[1] = vA->y; vtxTbl[0].n.ob[2] = vA->z; vtxTbl[1].n.ob[0] = vB->x; vtxTbl[1].n.ob[1] = vB->y; vtxTbl[1].n.ob[2] = vB->z; vtxTbl[2].n.ob[0] = vC->x; vtxTbl[2].n.ob[1] = vC->y; vtxTbl[2].n.ob[2] = vC->z; Math3D_DefPlane(vA, vB, vC, &nx, &ny, &nz, &originDist); for (vtx = vtxTbl; vtx < vtxTbl + 3; vtx++) { vtx->n.flag = 0; vtx->n.tc[0] = 0; vtx->n.tc[1] = 0; vtx->n.n[0] = (u8)(s32)nx & 0xFF; vtx->n.n[1] = (u8)(s32)ny & 0xFF; vtx->n.n[2] = (u8)(s32)nz & 0xFF; vtx->n.a = 255; } gSPVertex(POLY_OPA_DISP++, vtxTbl, 3, 0); gSP1Triangle(POLY_OPA_DISP++, 0, 1, 2, 0); CLOSE_DISPS(gfxCtx, "../z_collision_check.c", 757); } s32 Collider_InitBase(GlobalContext* globalCtx, Collider* collider) { static Collider init = { NULL, NULL, NULL, NULL, AT_NONE, AC_NONE, OC1_NONE, OC2_NONE, COLTYPE_HIT3, COLSHAPE_INVALID, }; *collider = init; return 1; } s32 Collider_DestroyBase(GlobalContext* globalCtx, Collider* collider) { return 1; } /** * Uses default OC2_TYPE_1 and COLTYPE_HIT0 */ s32 Collider_SetBaseToActor(GlobalContext* globalCtx, Collider* collider, ColliderInitToActor* src) { collider->actor = src->actor; collider->atFlags = src->atFlags; collider->acFlags = src->acFlags; collider->ocFlags1 = src->ocFlags1; collider->ocFlags2 = OC2_TYPE_1; collider->shape = src->shape; return 1; } /** * Uses default OC2_TYPE_1 */ s32 Collider_SetBaseType1(GlobalContext* globalCtx, Collider* collider, Actor* actor, ColliderInitType1* src) { collider->actor = actor; collider->colType = src->colType; collider->atFlags = src->atFlags; collider->acFlags = src->acFlags; collider->ocFlags1 = src->ocFlags1; collider->ocFlags2 = OC2_TYPE_1; collider->shape = src->shape; return 1; } s32 Collider_SetBase(GlobalContext* globalCtx, Collider* collider, Actor* actor, ColliderInit* src) { collider->actor = actor; collider->colType = src->colType; collider->atFlags = src->atFlags; collider->acFlags = src->acFlags; collider->ocFlags1 = src->ocFlags1; collider->ocFlags2 = src->ocFlags2; collider->shape = src->shape; return 1; } void Collider_ResetATBase(GlobalContext* globalCtx, Collider* collider) { collider->at = NULL; collider->atFlags &= ~(AT_HIT | AT_BOUNCED); } void Collider_ResetACBase(GlobalContext* globalCtx, Collider* collider) { collider->ac = NULL; collider->acFlags &= ~(AC_HIT | AC_BOUNCED); } void Collider_ResetOCBase(GlobalContext* globalCtx, Collider* collider) { collider->oc = NULL; collider->ocFlags1 &= ~OC1_HIT; collider->ocFlags2 &= ~OC2_HIT_PLAYER; } s32 Collider_InitTouch(GlobalContext* globalCtx, ColliderTouch* touch) { static ColliderTouch init = { 0x00000000, 0, 0 }; *touch = init; return 1; } s32 Collider_DestroyTouch(GlobalContext* globalCtx, ColliderTouch* touch) { return 1; } s32 Collider_SetTouch(GlobalContext* globalCtx, ColliderTouch* dest, ColliderTouch* src) { dest->dmgFlags = src->dmgFlags; dest->effect = src->effect; dest->damage = src->damage; return 1; } void Collider_ResetATInfo_Unk(GlobalContext* globalCtx, ColliderInfo* info) { } s32 Collider_InitBump(GlobalContext* globalCtx, ColliderBump* bump) { static ColliderBump init = { 0xFFCFFFFF, 0, 0, { 0, 0, 0 } }; *bump = init; return 1; } s32 Collider_DestroyBump(GlobalContext* globalCtx, ColliderBump* bump) { return 1; } s32 Collider_SetBump(GlobalContext* globalCtx, ColliderBump* bump, ColliderBumpInit* init) { bump->dmgFlags = init->dmgFlags; bump->effect = init->effect; bump->defense = init->defense; return 1; } s32 Collider_InitInfo(GlobalContext* globalCtx, ColliderInfo* info) { static ColliderInfo init = { { 0, 0, 0 }, { 0xFFCFFFFF, 0, 0, { 0, 0, 0 } }, ELEMTYPE_UNK0, TOUCH_NONE, BUMP_NONE, OCELEM_NONE, NULL, NULL, NULL, NULL, }; *info = init; Collider_InitTouch(globalCtx, &info->toucher); Collider_InitBump(globalCtx, &info->bumper); return 1; } s32 Collider_DestroyInfo(GlobalContext* globalCtx, ColliderInfo* info) { Collider_DestroyTouch(globalCtx, &info->toucher); Collider_DestroyBump(globalCtx, &info->bumper); return 1; } s32 Collider_SetInfo(GlobalContext* globalCtx, ColliderInfo* info, ColliderInfoInit* infoInit) { info->elemType = infoInit->elemType; Collider_SetTouch(globalCtx, &info->toucher, &infoInit->toucher); Collider_SetBump(globalCtx, &info->bumper, &infoInit->bumper); info->toucherFlags = infoInit->toucherFlags; info->bumperFlags = infoInit->bumperFlags; info->ocElemFlags = infoInit->ocElemFlags; return 1; } void Collider_ResetATInfo(GlobalContext* globalCtx, ColliderInfo* info) { info->atHit = NULL; info->atHitInfo = NULL; info->toucherFlags &= ~TOUCH_HIT; info->toucherFlags &= ~TOUCH_DREW_HITMARK; Collider_ResetATInfo_Unk(globalCtx, info); } void Collider_ResetACInfo(GlobalContext* globalCtx, ColliderInfo* info) { info->bumper.hitPos.x = info->bumper.hitPos.y = info->bumper.hitPos.z = 0; info->bumperFlags &= ~BUMP_HIT; info->bumperFlags &= ~BUMP_DRAW_HITMARK; info->acHit = NULL; info->acHitInfo = NULL; } void Collider_ResetOCInfo(GlobalContext* globalCtx, ColliderInfo* info) { info->ocElemFlags &= ~OCELEM_HIT; } s32 Collider_InitJntSphElementDim(GlobalContext* globalCtx, ColliderJntSphElementDim* dim) { static ColliderJntSphElementDim init = { { { 0, 0, 0 }, 0 }, { { 0, 0, 0 }, 0 }, 0.0f, 0, }; *dim = init; return 1; } s32 Collider_DestroyJntSphElementDim(GlobalContext* globalCtx, ColliderJntSphElementDim* element) { return 1; } s32 Collider_SetJntSphElementDim(GlobalContext* globalCtx, ColliderJntSphElementDim* dest, ColliderJntSphElementDimInit* src) { dest->limb = src->limb; dest->modelSphere = src->modelSphere; dest->scale = src->scale * 0.01f; return 1; } s32 Collider_InitJntSphElement(GlobalContext* globalCtx, ColliderJntSphElement* element) { Collider_InitInfo(globalCtx, &element->info); Collider_InitJntSphElementDim(globalCtx, &element->dim); return 1; } s32 Collider_DestroyJntSphElement(GlobalContext* globalCtx, ColliderJntSphElement* element) { Collider_DestroyInfo(globalCtx, &element->info); Collider_DestroyJntSphElementDim(globalCtx, &element->dim); return 1; } s32 Collider_SetJntSphElement(GlobalContext* globalCtx, ColliderJntSphElement* dest, ColliderJntSphElementInit* src) { Collider_SetInfo(globalCtx, &dest->info, &src->info); Collider_SetJntSphElementDim(globalCtx, &dest->dim, &src->dim); return 1; } s32 Collider_ResetJntSphElementAT(GlobalContext* globalCtx, ColliderJntSphElement* collider) { Collider_ResetATInfo(globalCtx, &collider->info); return 1; } s32 Collider_ResetJntSphElementAC(GlobalContext* globalCtx, ColliderJntSphElement* collider) { Collider_ResetACInfo(globalCtx, &collider->info); return 1; } s32 Collider_ResetJntSphElementOC(GlobalContext* globalCtx, ColliderJntSphElement* collider) { Collider_ResetOCInfo(globalCtx, &collider->info); return 1; } /** * Initializes a ColliderJntSph to default values */ s32 Collider_InitJntSph(GlobalContext* globalCtx, ColliderJntSph* collider) { Collider_InitBase(globalCtx, &collider->base); collider->count = 0; collider->elements = NULL; return 1; } /** * Destroys a dynamically allocated ColliderJntSph */ s32 Collider_FreeJntSph(GlobalContext* globalCtx, ColliderJntSph* collider) { ColliderJntSphElement* element; Collider_DestroyBase(globalCtx, &collider->base); for (element = collider->elements; element < collider->elements + collider->count; element++) { Collider_DestroyJntSphElement(globalCtx, element); } collider->count = 0; if (collider->elements != NULL) { ZeldaArena_FreeDebug(collider->elements, "../z_collision_check.c", 1393); } collider->elements = NULL; return 1; } /** * Destroys a preallocated ColliderJntSph */ s32 Collider_DestroyJntSph(GlobalContext* globalCtx, ColliderJntSph* collider) { ColliderJntSphElement* element; Collider_DestroyBase(globalCtx, &collider->base); for (element = collider->elements; element < collider->elements + collider->count; element++) { Collider_DestroyJntSphElement(globalCtx, element); } collider->count = 0; collider->elements = NULL; return 1; } /** * Sets up the ColliderJntSph using the values in src, sets it to the actor specified in src, and dynamically allocates * the element array. Uses default OC2_TYPE_1 and COLTYPE_HIT0. Unused. */ s32 Collider_SetJntSphToActor(GlobalContext* globalCtx, ColliderJntSph* dest, ColliderJntSphInitToActor* src) { ColliderJntSphElement* destElem; ColliderJntSphElementInit* srcElem; Collider_SetBaseToActor(globalCtx, &dest->base, &src->base); dest->count = src->count; dest->elements = ZeldaArena_MallocDebug(src->count * sizeof(ColliderJntSphElement), "../z_collision_check.c", 1443); if (dest->elements == NULL) { dest->count = 0; osSyncPrintf(VT_FGCOL(RED)); osSyncPrintf("ClObjJntSph_set():zelda_malloc()出来ません。\n"); // "Can not." osSyncPrintf(VT_RST); return 0; } for (destElem = dest->elements, srcElem = src->elements; destElem < dest->elements + dest->count; destElem++, srcElem++) { Collider_InitJntSphElement(globalCtx, destElem); Collider_SetJntSphElement(globalCtx, destElem, srcElem); } return 1; } /** * Sets up the ColliderJntSph using the values in src and dynamically allocates the element array. Uses default * OC2_TYPE_1. Only used by En_Nwc, an unused and unfinished actor. */ s32 Collider_SetJntSphAllocType1(GlobalContext* globalCtx, ColliderJntSph* dest, Actor* actor, ColliderJntSphInitType1* src) { ColliderJntSphElement* destElem; ColliderJntSphElementInit* srcElem; Collider_SetBaseType1(globalCtx, &dest->base, actor, &src->base); dest->count = src->count; dest->elements = ZeldaArena_MallocDebug(src->count * sizeof(ColliderJntSphElement), "../z_collision_check.c", 1490); if (dest->elements == NULL) { dest->count = 0; osSyncPrintf(VT_FGCOL(RED)); osSyncPrintf("ClObjJntSph_set3():zelda_malloc_出来ません。\n"); // "Can not." osSyncPrintf(VT_RST); return 0; } for (destElem = dest->elements, srcElem = src->elements; destElem < dest->elements + dest->count; destElem++, srcElem++) { Collider_InitJntSphElement(globalCtx, destElem); Collider_SetJntSphElement(globalCtx, destElem, srcElem); } return 1; } /** * Sets up the ColliderJntSph using the values in src and dynamically allocates the element array. * Unused. */ s32 Collider_SetJntSphAlloc(GlobalContext* globalCtx, ColliderJntSph* dest, Actor* actor, ColliderJntSphInit* src) { ColliderJntSphElement* destElem; ColliderJntSphElementInit* srcElem; Collider_SetBase(globalCtx, &dest->base, actor, &src->base); dest->count = src->count; dest->elements = ZeldaArena_MallocDebug(src->count * sizeof(ColliderJntSphElement), "../z_collision_check.c", 1551); if (dest->elements == NULL) { dest->count = 0; osSyncPrintf(VT_FGCOL(RED)); osSyncPrintf("ClObjJntSph_set5():zelda_malloc出来ません\n"); // "Can not." osSyncPrintf(VT_RST); return 0; } for (destElem = dest->elements, srcElem = src->elements; destElem < dest->elements + dest->count; destElem++, srcElem++) { Collider_InitJntSphElement(globalCtx, destElem); Collider_SetJntSphElement(globalCtx, destElem, srcElem); } return 1; } /** * Sets up the ColliderJntSph using the values in src, placing the element array in elements. */ s32 Collider_SetJntSph(GlobalContext* globalCtx, ColliderJntSph* dest, Actor* actor, ColliderJntSphInit* src, ColliderJntSphElement* elements) { ColliderJntSphElement* destElem; ColliderJntSphElementInit* srcElem; Collider_SetBase(globalCtx, &dest->base, actor, &src->base); dest->count = src->count; dest->elements = elements; ASSERT(dest->elements != NULL, "pclobj_jntsph->elem_tbl != NULL", "../z_collision_check.c", 1603); for (destElem = dest->elements, srcElem = src->elements; destElem < dest->elements + dest->count; destElem++, srcElem++) { Collider_InitJntSphElement(globalCtx, destElem); Collider_SetJntSphElement(globalCtx, destElem, srcElem); } return 1; } /** * Resets the collider's AT collision flags. */ s32 Collider_ResetJntSphAT(GlobalContext* globalCtx, Collider* collider) { ColliderJntSphElement* element; ColliderJntSph* jntSph = (ColliderJntSph*)collider; Collider_ResetATBase(globalCtx, &jntSph->base); for (element = jntSph->elements; element < jntSph->elements + jntSph->count; element++) { Collider_ResetJntSphElementAT(globalCtx, element); } return 1; } /** * Resets the collider's AC collision flags. */ s32 Collider_ResetJntSphAC(GlobalContext* globalCtx, Collider* collider) { ColliderJntSphElement* element; ColliderJntSph* jntSph = (ColliderJntSph*)collider; Collider_ResetACBase(globalCtx, &jntSph->base); for (element = jntSph->elements; element < jntSph->elements + jntSph->count; element++) { Collider_ResetJntSphElementAC(globalCtx, element); } return 1; } /** * Resets the collider's OC collision flags. */ s32 Collider_ResetJntSphOC(GlobalContext* globalCtx, Collider* collider) { ColliderJntSphElement* element; ColliderJntSph* jntSph = (ColliderJntSph*)collider; Collider_ResetOCBase(globalCtx, &jntSph->base); for (element = jntSph->elements; element < jntSph->elements + jntSph->count; element++) { Collider_ResetJntSphElementOC(globalCtx, element); } return 1; } s32 Collider_InitCylinderDim(GlobalContext* globalCtx, Cylinder16* dim) { Cylinder16 init = { 0, 0, 0, { 0, 0, 0 } }; *dim = init; return 1; } s32 Collider_DestroyCylinderDim(GlobalContext* globalCtx, Cylinder16* dim) { return 1; } s32 Collider_SetCylinderDim(GlobalContext* globalCtx, Cylinder16* dest, Cylinder16* src) { *dest = *src; return 1; } /** * Initializes a ColliderCylinder to default values */ s32 Collider_InitCylinder(GlobalContext* globalCtx, ColliderCylinder* collider) { Collider_InitBase(globalCtx, &collider->base); Collider_InitInfo(globalCtx, &collider->info); Collider_InitCylinderDim(globalCtx, &collider->dim); return 1; } /** * Destroys a ColliderCylinder */ s32 Collider_DestroyCylinder(GlobalContext* globalCtx, ColliderCylinder* collider) { Collider_DestroyBase(globalCtx, &collider->base); Collider_DestroyInfo(globalCtx, &collider->info); Collider_DestroyCylinderDim(globalCtx, &collider->dim); return 1; } /** * Sets up the ColliderCylinder using the values in src and sets it to the actor specified in src. Uses default * OC2_TYPE_1 and COLTYPE_0. Used only by DekuJr, who sets it to himself anyways. */ s32 Collider_SetCylinderToActor(GlobalContext* globalCtx, ColliderCylinder* collider, ColliderCylinderInitToActor* src) { Collider_SetBaseToActor(globalCtx, &collider->base, &src->base); Collider_SetInfo(globalCtx, &collider->info, &src->info); Collider_SetCylinderDim(globalCtx, &collider->dim, &src->dim); return 1; } /** * Sets up the ColliderCylinder using the values in src. Uses default OC2_TYPE_1 */ s32 Collider_SetCylinderType1(GlobalContext* globalCtx, ColliderCylinder* collider, Actor* actor, ColliderCylinderInitType1* src) { Collider_SetBaseType1(globalCtx, &collider->base, actor, &src->base); Collider_SetInfo(globalCtx, &collider->info, &src->info); Collider_SetCylinderDim(globalCtx, &collider->dim, &src->dim); return 1; } /** * Sets up the ColliderCylinder using the values in src. */ s32 Collider_SetCylinder(GlobalContext* globalCtx, ColliderCylinder* collider, Actor* actor, ColliderCylinderInit* src) { Collider_SetBase(globalCtx, &collider->base, actor, &src->base); Collider_SetInfo(globalCtx, &collider->info, &src->info); Collider_SetCylinderDim(globalCtx, &collider->dim, &src->dim); return 1; } /** * Resets the collider's AT collision flags. */ s32 Collider_ResetCylinderAT(GlobalContext* globalCtx, Collider* collider) { ColliderCylinder* cylinder = (ColliderCylinder*)collider; Collider_ResetATBase(globalCtx, &cylinder->base); Collider_ResetATInfo(globalCtx, &cylinder->info); return 1; } /** * Resets the collider's AC collision flags. */ s32 Collider_ResetCylinderAC(GlobalContext* globalCtx, Collider* collider) { ColliderCylinder* cylinder = (ColliderCylinder*)collider; Collider_ResetACBase(globalCtx, &cylinder->base); Collider_ResetACInfo(globalCtx, &cylinder->info); return 1; } /** * Resets the collider's OC collision flags. */ s32 Collider_ResetCylinderOC(GlobalContext* globalCtx, Collider* collider) { ColliderCylinder* cylinder = (ColliderCylinder*)collider; Collider_ResetOCBase(globalCtx, &cylinder->base); Collider_ResetOCInfo(globalCtx, &cylinder->info); return 1; } s32 Collider_InitTrisElementDim(GlobalContext* globalCtx, TriNorm* dim) { static TriNorm init = { { { 0.0f, 0.0f, 0.0f }, { 0.0f, 0.0f, 0.0f }, { 0.0f, 0.0f, 0.0f } }, { { 0.0f, 0.0f, 0.0f }, 0.0f }, }; *dim = init; return 1; } s32 Collider_DestroyTrisElementDim(GlobalContext* globalCtx, TriNorm* dim) { return 1; } s32 Collider_SetTrisElementDim(GlobalContext* globalCtx, TriNorm* dest, ColliderTrisElementDimInit* src) { Vec3f* destVtx; Vec3f* srcVtx; f32 nx; f32 ny; f32 nz; f32 originDist; for (destVtx = dest->vtx, srcVtx = src->vtx; destVtx < dest->vtx + 3; destVtx++, srcVtx++) { *destVtx = *srcVtx; } Math3D_DefPlane(&src->vtx[0], &src->vtx[1], &src->vtx[2], &nx, &ny, &nz, &originDist); dest->plane.normal.x = nx; dest->plane.normal.y = ny; dest->plane.normal.z = nz; dest->plane.originDist = originDist; return 1; } s32 Collider_InitTrisElement(GlobalContext* globalCtx, ColliderTrisElement* collider) { Collider_InitInfo(globalCtx, &collider->info); Collider_InitTrisElementDim(globalCtx, &collider->dim); return 1; } s32 Collider_DestroyTrisElement(GlobalContext* globalCtx, ColliderTrisElement* collider) { Collider_DestroyInfo(globalCtx, &collider->info); Collider_DestroyTrisElementDim(globalCtx, &collider->dim); return 1; } s32 Collider_SetTrisElement(GlobalContext* globalCtx, ColliderTrisElement* dest, ColliderTrisElementInit* src) { Collider_SetInfo(globalCtx, &dest->info, &src->info); Collider_SetTrisElementDim(globalCtx, &dest->dim, &src->dim); return 1; } s32 Collider_ResetTrisElementAT(GlobalContext* globalCtx, ColliderTrisElement* element) { Collider_ResetATInfo(globalCtx, &element->info); return 1; } s32 Collider_ResetTrisElementAC(GlobalContext* globalCtx, ColliderTrisElement* element) { Collider_ResetACInfo(globalCtx, &element->info); return 1; } s32 Collider_ResetTrisElementOC(GlobalContext* globalCtx, ColliderTrisElement* element) { Collider_ResetOCInfo(globalCtx, &element->info); return 1; } /** * Initializes a ColliderTris to default values */ s32 Collider_InitTris(GlobalContext* globalCtx, ColliderTris* tris) { Collider_InitBase(globalCtx, &tris->base); tris->count = 0; tris->elements = 0; return 1; } /** * Destroys a dynamically allocated ColliderTris * Unused */ s32 Collider_FreeTris(GlobalContext* globalCtx, ColliderTris* tris) { ColliderTrisElement* element; Collider_DestroyBase(globalCtx, &tris->base); for (element = tris->elements; element < tris->elements + tris->count; element++) { Collider_DestroyTrisElement(globalCtx, element); } tris->count = 0; if (tris->elements != NULL) { ZeldaArena_FreeDebug(tris->elements, "../z_collision_check.c", 2099); } tris->elements = NULL; return 1; } /** * Destroys a preallocated ColliderTris */ s32 Collider_DestroyTris(GlobalContext* globalCtx, ColliderTris* tris) { ColliderTrisElement* element; Collider_DestroyBase(globalCtx, &tris->base); for (element = tris->elements; element < tris->elements + tris->count; element++) { Collider_DestroyTrisElement(globalCtx, element); } tris->count = 0; tris->elements = NULL; return 1; } /** * Sets up the ColliderTris using the values in src and dynamically allocates the element array. Uses default OC2_TYPE_1 * Unused. */ s32 Collider_SetTrisAllocType1(GlobalContext* globalCtx, ColliderTris* dest, Actor* actor, ColliderTrisInitType1* src) { ColliderTrisElement* destElem; ColliderTrisElementInit* srcElem; Collider_SetBaseType1(globalCtx, &dest->base, actor, &src->base); dest->count = src->count; dest->elements = ZeldaArena_MallocDebug(dest->count * sizeof(ColliderTrisElement), "../z_collision_check.c", 2156); if (dest->elements == NULL) { dest->count = 0; osSyncPrintf(VT_FGCOL(RED)); osSyncPrintf("ClObjTris_set3():zelda_malloc()出来ません\n"); // "Can not." osSyncPrintf(VT_RST); return 0; } for (destElem = dest->elements, srcElem = src->elements; destElem < dest->elements + dest->count; destElem++, srcElem++) { Collider_InitTrisElement(globalCtx, destElem); Collider_SetTrisElement(globalCtx, destElem, srcElem); } return 1; } /** * Sets up the ColliderTris using the values in src and dynamically allocates the element array. * Unused */ s32 Collider_SetTrisAlloc(GlobalContext* globalCtx, ColliderTris* dest, Actor* actor, ColliderTrisInit* src) { ColliderTrisElement* destElem; ColliderTrisElementInit* srcElem; Collider_SetBase(globalCtx, &dest->base, actor, &src->base); dest->count = src->count; dest->elements = ZeldaArena_MallocDebug(dest->count * sizeof(ColliderTrisElement), "../z_collision_check.c", 2207); if (dest->elements == NULL) { osSyncPrintf(VT_FGCOL(RED)); osSyncPrintf("ClObjTris_set5():zelda_malloc出来ません\n"); // "Can not." osSyncPrintf(VT_RST); dest->count = 0; return 0; } for (destElem = dest->elements, srcElem = src->elements; destElem < dest->elements + dest->count; destElem++, srcElem++) { Collider_InitTrisElement(globalCtx, destElem); Collider_SetTrisElement(globalCtx, destElem, srcElem); } return 1; } /** * Sets up the ColliderTris using the values in src, placing the element array in elements. */ s32 Collider_SetTris(GlobalContext* globalCtx, ColliderTris* dest, Actor* actor, ColliderTrisInit* src, ColliderTrisElement* elements) { ColliderTrisElement* destElem; ColliderTrisElementInit* srcElem; Collider_SetBase(globalCtx, &dest->base, actor, &src->base); dest->count = src->count; dest->elements = elements; ASSERT(dest->elements != NULL, "pclobj_tris->elem_tbl != NULL", "../z_collision_check.c", 2258); for (destElem = dest->elements, srcElem = src->elements; destElem < dest->elements + dest->count; destElem++, srcElem++) { Collider_InitTrisElement(globalCtx, destElem); Collider_SetTrisElement(globalCtx, destElem, srcElem); } return 1; } /** * Resets the collider's AT collision flags. */ s32 Collider_ResetTrisAT(GlobalContext* globalCtx, Collider* collider) { ColliderTrisElement* element; ColliderTris* tris = (ColliderTris*)collider; Collider_ResetATBase(globalCtx, &tris->base); for (element = tris->elements; element < tris->elements + tris->count; element++) { Collider_ResetTrisElementAT(globalCtx, element); } return 1; } /** * Resets the collider's AC collision flags. */ s32 Collider_ResetTrisAC(GlobalContext* globalCtx, Collider* collider) { ColliderTrisElement* element; ColliderTris* tris = (ColliderTris*)collider; Collider_ResetACBase(globalCtx, &tris->base); for (element = tris->elements; element < tris->elements + tris->count; element++) { Collider_ResetTrisElementAC(globalCtx, element); } return 1; } /** * Resets the collider's OC collision flags. */ s32 Collider_ResetTrisOC(GlobalContext* globalCtx, Collider* collider) { ColliderTrisElement* element; ColliderTris* tris = (ColliderTris*)collider; Collider_ResetOCBase(globalCtx, &tris->base); for (element = tris->elements; element < tris->elements + tris->count; element++) { Collider_ResetTrisElementOC(globalCtx, element); } return 1; } s32 Collider_InitQuadDim(GlobalContext* globalCtx, ColliderQuadDim* dim) { static ColliderQuadDim init = { { { 0.0f, 0.0f, 0.0f }, { 0.0f, 0.0f, 0.0f }, { 0.0f, 0.0f, 0.0f }, { 0.0f, 0.0f, 0.0f } }, { 0, 0, 0 }, { 0, 0, 0 }, 1.0E38f, }; *dim = init; return 1; } s32 Collider_DestroyQuadDim(GlobalContext* globalCtx, ColliderQuadDim* dim) { return 1; } s32 Collider_ResetQuadACDist(GlobalContext* globalCtx, ColliderQuadDim* dim) { dim->acDist = 1.0E38f; return 1; } void Collider_SetQuadMidpoints(ColliderQuadDim* dim) { dim->dcMid.x = (dim->quad[3].x + dim->quad[2].x) * 0.5f; dim->dcMid.y = (dim->quad[3].y + dim->quad[2].y) * 0.5f; dim->dcMid.z = (dim->quad[3].z + dim->quad[2].z) * 0.5f; dim->baMid.x = (dim->quad[1].x + dim->quad[0].x) * 0.5f; dim->baMid.y = (dim->quad[1].y + dim->quad[0].y) * 0.5f; dim->baMid.z = (dim->quad[1].z + dim->quad[0].z) * 0.5f; } s32 Collider_SetQuadDim(GlobalContext* globalCtx, ColliderQuadDim* dest, ColliderQuadDimInit* src) { dest->quad[0] = src->quad[0]; dest->quad[1] = src->quad[1]; dest->quad[2] = src->quad[2]; dest->quad[3] = src->quad[3]; Collider_SetQuadMidpoints(dest); return 1; } /** * Initializes a ColliderQuad to default values. */ s32 Collider_InitQuad(GlobalContext* globalCtx, ColliderQuad* collider) { Collider_InitBase(globalCtx, &collider->base); Collider_InitInfo(globalCtx, &collider->info); Collider_InitQuadDim(globalCtx, &collider->dim); return 1; } /** * Destroys a ColliderQuad. */ s32 Collider_DestroyQuad(GlobalContext* globalCtx, ColliderQuad* collider) { Collider_DestroyBase(globalCtx, &collider->base); Collider_DestroyInfo(globalCtx, &collider->info); Collider_DestroyQuadDim(globalCtx, &collider->dim); return 1; } /** * Sets up the ColliderQuad using the values in src. Uses the default OC2_TYPE_1 */ s32 Collider_SetQuadType1(GlobalContext* globalCtx, ColliderQuad* collider, Actor* actor, ColliderQuadInitType1* src) { Collider_SetBaseType1(globalCtx, &collider->base, actor, &src->base); Collider_SetInfo(globalCtx, &collider->info, &src->info); Collider_SetQuadDim(globalCtx, &collider->dim, &src->dim); return 1; } /** * Sets up the ColliderQuad using the values in src. */ s32 Collider_SetQuad(GlobalContext* globalCtx, ColliderQuad* collider, Actor* actor, ColliderQuadInit* src) { Collider_SetBase(globalCtx, &collider->base, actor, &src->base); Collider_SetInfo(globalCtx, &collider->info, &src->info); Collider_SetQuadDim(globalCtx, &collider->dim, &src->dim); return 1; } /** * Resets the collider's AT collision flags. */ s32 Collider_ResetQuadAT(GlobalContext* globalCtx, Collider* collider) { ColliderQuad* quad = (ColliderQuad*)collider; Collider_ResetATBase(globalCtx, &quad->base); Collider_ResetATInfo(globalCtx, &quad->info); Collider_ResetQuadACDist(globalCtx, &quad->dim); return 1; } /** * Resets the collider's AC collision flags. */ s32 Collider_ResetQuadAC(GlobalContext* globalCtx, Collider* collider) { ColliderQuad* quad = (ColliderQuad*)collider; Collider_ResetACBase(globalCtx, &quad->base); Collider_ResetACInfo(globalCtx, &quad->info); return 1; } /** * Resets the collider's OC collision flags. */ s32 Collider_ResetQuadOC(GlobalContext* globalCtx, Collider* collider) { ColliderQuad* quad = (ColliderQuad*)collider; Collider_ResetOCBase(globalCtx, &quad->base); Collider_ResetOCInfo(globalCtx, &quad->info); return 1; } /** * For quad colliders with AT_NEAREST, resets the previous AC collider it hit if the current element is closer, * otherwise returns false. Used on player AT colliders to prevent multiple collisions from registering. */ s32 Collider_QuadSetNearestAC(GlobalContext* globalCtx, ColliderQuad* quad, Vec3f* hitPos) { f32 acDist; Vec3f dcMid; if (!(quad->info.toucherFlags & TOUCH_NEAREST)) { return true; } Math_Vec3s_ToVec3f(&dcMid, &quad->dim.dcMid); acDist = Math3D_Vec3fDistSq(&dcMid, hitPos); if (acDist < quad->dim.acDist) { quad->dim.acDist = acDist; if (quad->info.atHit != NULL) { Collider_ResetACBase(globalCtx, quad->info.atHit); } if (quad->info.atHitInfo != NULL) { Collider_ResetACInfo(globalCtx, quad->info.atHitInfo); } return true; } return false; } /** * Initializes an OcLine to default values * OcLines are entirely unused. */ s32 Collider_InitLine(GlobalContext* globalCtx, OcLine* line) { Vec3f init = { 0.0f, 0.0f, 0.0f }; Math_Vec3f_Copy(&line->line.a, &init); Math_Vec3f_Copy(&line->line.b, &init); return 1; } /** * Destroys an OcLine * OcLines are entirely unused. */ s32 Collider_DestroyLine(GlobalContext* globalCtx, OcLine* line) { return 1; } /** * Sets up an OcLine with endpoints a and b. * OcLines are entirely unused. */ s32 Collider_SetLinePoints(GlobalContext* GlobalContext, OcLine* ocLine, Vec3f* a, Vec3f* b) { Math_Vec3f_Copy(&ocLine->line.a, a); Math_Vec3f_Copy(&ocLine->line.b, b); return 1; } /** * Sets up an OcLine using the values in src. * OcLines are entirely unused. */ s32 Collider_SetLine(GlobalContext* globalCtx, OcLine* dest, OcLine* src) { dest->ocFlags = src->ocFlags; Collider_SetLinePoints(globalCtx, dest, &src->line.a, &src->line.b); return 1; } /** * Resets the OcLine's collision flags. * OcLines are entirely unused. */ s32 Collider_ResetLineOC(GlobalContext* globalCtx, OcLine* line) { line->ocFlags &= ~OCLINE_HIT; return 1; } /** * Initializes CollisionCheckContext. Clears all collider arrays, disables SAC, and sets flags for drawing colliders. */ void CollisionCheck_InitContext(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx) { colChkCtx->sacFlags = 0; CollisionCheck_ClearContext(globalCtx, colChkCtx); AREG(21) = true; AREG(22) = true; AREG(23) = true; } void CollisionCheck_DestroyContext(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx) { } /** * Clears all collider lists in CollisionCheckContext when not in SAC mode. */ void CollisionCheck_ClearContext(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx) { Collider** col; OcLine** line; if (!(colChkCtx->sacFlags & 1)) { colChkCtx->colATCount = 0; colChkCtx->colACCount = 0; colChkCtx->colOCCount = 0; colChkCtx->colLineCount = 0; for (col = colChkCtx->colAT; col < colChkCtx->colAT + COLLISION_CHECK_AT_MAX; col++) { *col = NULL; } for (col = colChkCtx->colAC; col < colChkCtx->colAC + COLLISION_CHECK_AC_MAX; col++) { *col = NULL; } for (col = colChkCtx->colOC; col < colChkCtx->colOC + COLLISION_CHECK_OC_MAX; col++) { *col = NULL; } for (line = colChkCtx->colLine; line < colChkCtx->colLine + COLLISION_CHECK_OC_LINE_MAX; line++) { *line = NULL; } } } /** * Enables SAC, an alternate collision check mode that allows direct management of collider lists. Unused. */ void CollisionCheck_EnableSAC(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx) { colChkCtx->sacFlags |= 1; } /** * Disables SAC, an alternate collision check mode that allows direct management of collider lists. Unused. */ void CollisionCheck_DisableSAC(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx) { colChkCtx->sacFlags &= ~1; } /** * Draws a collider of any shape. * Math3D_DrawSphere and Math3D_DrawCylinder are noops, so JntSph and Cylinder are not drawn. */ void Collider_Draw(GlobalContext* globalCtx, Collider* collider) { ColliderJntSph* jntSph; ColliderCylinder* cylinder; ColliderTris* tris; ColliderQuad* quad; s32 i; if (collider == NULL) { return; } switch (collider->shape) { case COLSHAPE_JNTSPH: jntSph = (ColliderJntSph*)collider; for (i = 0; i < jntSph->count; i++) { Math3D_DrawSphere(globalCtx, &jntSph->elements[i].dim.worldSphere); } break; case COLSHAPE_CYLINDER: cylinder = (ColliderCylinder*)collider; Math3D_DrawCylinder(globalCtx, &cylinder->dim); break; case COLSHAPE_TRIS: tris = (ColliderTris*)collider; for (i = 0; i < tris->count; i++) { Collider_DrawRedPoly(globalCtx->state.gfxCtx, &tris->elements[i].dim.vtx[0], &tris->elements[i].dim.vtx[1], &tris->elements[i].dim.vtx[2]); } break; case COLSHAPE_QUAD: quad = (ColliderQuad*)collider; Collider_DrawRedPoly(globalCtx->state.gfxCtx, &quad->dim.quad[2], &quad->dim.quad[3], &quad->dim.quad[1]); Collider_DrawRedPoly(globalCtx->state.gfxCtx, &quad->dim.quad[1], &quad->dim.quad[0], &quad->dim.quad[2]); break; } } /** * Draws collision if AREG(15) and other AREGs are set. AREG(21) draws AT colliders, AREG(22) draws AC colliders, * AREG(23) draws OC colliders, AREG(24) draws dynapolys, and AREG(25) draws bg polys */ void CollisionCheck_DrawCollision(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx) { Collider* collider; s32 i; if (AREG(15)) { if (AREG(21)) { for (i = 0; i < colChkCtx->colATCount; i++) { Collider_Draw(globalCtx, colChkCtx->colAT[i]); } } if (AREG(22)) { for (i = 0; i < colChkCtx->colACCount; i++) { Collider_Draw(globalCtx, colChkCtx->colAC[i]); } } if (AREG(23)) { for (i = 0; i < colChkCtx->colOCCount; i++) { collider = colChkCtx->colOC[i]; if (collider->ocFlags1 & OC1_ON) { Collider_Draw(globalCtx, collider); } } } if (AREG(24)) { BgCheck_DrawDynaCollision(globalCtx, &globalCtx->colCtx); } if (AREG(25)) { BgCheck_DrawStaticCollision(globalCtx, &globalCtx->colCtx); } } } static ColChkResetFunc sATResetFuncs[] = { Collider_ResetJntSphAT, Collider_ResetCylinderAT, Collider_ResetTrisAT, Collider_ResetQuadAT, }; /** * Sets collider as an AT (attack) for the current frame, which will be checked against ACs (attack colliders) * The last argument takes a Collider, so pass collider.base rather than the raw collider. */ s32 CollisionCheck_SetAT(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* collider) { s32 index; if (FrameAdvance_IsEnabled(globalCtx) == true) { return -1; } ASSERT(collider->shape <= COLSHAPE_QUAD, "pcl_obj->data_type <= CL_DATA_LBL_SWRD", "../z_collision_check.c", 2997); sATResetFuncs[collider->shape](globalCtx, collider); if (collider->actor != NULL && collider->actor->update == NULL) { return -1; } if (colChkCtx->colATCount >= COLLISION_CHECK_AT_MAX) { // "Index exceeded and cannot add more" osSyncPrintf("CollisionCheck_setAT():インデックスがオーバーして追加不能\n"); return -1; } if (colChkCtx->sacFlags & 1) { return -1; } index = colChkCtx->colATCount; colChkCtx->colAT[colChkCtx->colATCount++] = collider; return index; } /** * Unused. Sets collider as an AT (attack) for the current frame, which will be checked against ACs (attack colliders). * If CollisionCheck_SAC is enabled, the collider will be inserted into the list at the specified index, otherwise it * will be inserted into the next slot */ s32 CollisionCheck_SetAT_SAC(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* collider, s32 index) { ASSERT(collider->shape <= COLSHAPE_QUAD, "pcl_obj->data_type <= CL_DATA_LBL_SWRD", "../z_collision_check.c", 3037); if (FrameAdvance_IsEnabled(globalCtx) == true) { return -1; } sATResetFuncs[collider->shape](globalCtx, collider); if (collider->actor != NULL && collider->actor->update == NULL) { return -1; } if (colChkCtx->sacFlags & 1) { if (!(index < colChkCtx->colATCount)) { // "You are trying to register a location that is larger than the total number of data." osSyncPrintf("CollisionCheck_setAT_SAC():全データ数より大きいところに登録しようとしている。\n"); return -1; } colChkCtx->colAT[index] = collider; } else { if (!(colChkCtx->colATCount < COLLISION_CHECK_AT_MAX)) { // "Index exceeded and cannot add more" osSyncPrintf("CollisionCheck_setAT():インデックスがオーバーして追加不能\n"); return -1; } index = colChkCtx->colATCount; colChkCtx->colAT[colChkCtx->colATCount++] = collider; } return index; } static ColChkResetFunc sACResetFuncs[] = { Collider_ResetJntSphAC, Collider_ResetCylinderAC, Collider_ResetTrisAC, Collider_ResetQuadAC, }; /** * Sets collider as an AC (attack collider) for the current frame, allowing it to detect ATs (attacks) * The last argument takes a Collider, so pass collider.base rather than the raw collider. */ s32 CollisionCheck_SetAC(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* collider) { s32 index; if (FrameAdvance_IsEnabled(globalCtx) == true) { return -1; } ASSERT(collider->shape <= COLSHAPE_QUAD, "pcl_obj->data_type <= CL_DATA_LBL_SWRD", "../z_collision_check.c", 3114); sACResetFuncs[collider->shape](globalCtx, collider); if (collider->actor != NULL && collider->actor->update == NULL) { return -1; } if (colChkCtx->colACCount >= COLLISION_CHECK_AC_MAX) { // "Index exceeded and cannot add more" osSyncPrintf("CollisionCheck_setAC():インデックスがオーバして追加不能\n"); return -1; } if (colChkCtx->sacFlags & 1) { return -1; } index = colChkCtx->colACCount; colChkCtx->colAC[colChkCtx->colACCount++] = collider; return index; } /** * Unused. Sets collider as an AC (attack collider) for the current frame, allowing it to detect ATs (attacks). * If CollisionCheck_SAC is enabled, the collider will be inserted into the list at the specified index, otherwise it * will be inserted into the next slot */ s32 CollisionCheck_SetAC_SAC(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* collider, s32 index) { ASSERT(collider->shape <= COLSHAPE_QUAD, "pcl_obj->data_type <= CL_DATA_LBL_SWRD", "../z_collision_check.c", 3153); if (FrameAdvance_IsEnabled(globalCtx) == true) { return -1; } sACResetFuncs[collider->shape](globalCtx, collider); if (collider->actor != NULL && collider->actor->update == NULL) { return -1; } if (colChkCtx->sacFlags & 1) { if (!(index < colChkCtx->colACCount)) { // "You are trying to register a location that is larger than the total number of data." osSyncPrintf("CollisionCheck_setAC_SAC():全データ数より大きいところに登録しようとしている。\n"); return -1; } colChkCtx->colAC[index] = collider; } else { if (!(colChkCtx->colACCount < COLLISION_CHECK_AC_MAX)) { // "Index exceeded and cannot add more" osSyncPrintf("CollisionCheck_setAC():インデックスがオーバして追加不能\n"); return -1; } index = colChkCtx->colACCount; colChkCtx->colAC[colChkCtx->colACCount++] = collider; } return index; } static ColChkResetFunc sOCResetFuncs[] = { Collider_ResetJntSphOC, Collider_ResetCylinderOC, Collider_ResetTrisOC, Collider_ResetQuadOC, }; /** * Sets collider as an OC (object collider) for the current frame, allowing it to detect other OCs * The last argument takes a Collider, so pass collider.base rather than the raw collider. */ s32 CollisionCheck_SetOC(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* collider) { s32 index; if (FrameAdvance_IsEnabled(globalCtx) == true) { return -1; } ASSERT(collider->shape <= COLSHAPE_QUAD, "pcl_obj->data_type <= CL_DATA_LBL_SWRD", "../z_collision_check.c", 3229); sOCResetFuncs[collider->shape](globalCtx, collider); if (collider->actor != NULL && collider->actor->update == NULL) { return -1; } if (colChkCtx->colOCCount >= COLLISION_CHECK_OC_MAX) { // "Index exceeded and cannot add more" osSyncPrintf("CollisionCheck_setOC():インデックスがオーバして追加不能\n"); return -1; } if (colChkCtx->sacFlags & 1) { return -1; } index = colChkCtx->colOCCount; colChkCtx->colOC[colChkCtx->colOCCount++] = collider; return index; } /** * Unused. Sets collider as an OC (object collider) for the current frame, allowing it to detect other OCs * If CollisionCheck_SAC is enabled, the collider will be inserted into the list at the specified index, otherwise it * will be inserted into the next slot */ s32 CollisionCheck_SetOC_SAC(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* collider, s32 index) { if (FrameAdvance_IsEnabled(globalCtx) == true) { return -1; } ASSERT(collider->shape <= COLSHAPE_QUAD, "pcl_obj->data_type <= CL_DATA_LBL_SWRD", "../z_collision_check.c", 3274); sOCResetFuncs[collider->shape](globalCtx, collider); if (collider->actor != NULL && collider->actor->update == NULL) { return -1; } if (colChkCtx->sacFlags & 1) { if (!(index < colChkCtx->colOCCount)) { // "You are trying to register a location that is larger than the total number of data." osSyncPrintf("CollisionCheck_setOC_SAC():全データ数より大きいところに登録しようとしている。\n"); return -1; } //! @bug Should be colOC colChkCtx->colAT[index] = collider; } else { if (!(colChkCtx->colOCCount < COLLISION_CHECK_OC_MAX)) { // "Index exceeded and cannot add more" osSyncPrintf("CollisionCheck_setOC():インデックスがオーバして追加不能\n"); return -1; } index = colChkCtx->colOCCount; colChkCtx->colOC[colChkCtx->colOCCount++] = collider; } return index; } /** * Sets a line as an OC collider for this frame. * OC lines are entirely unused, and do not even have collision check functions. */ s32 CollisionCheck_SetOCLine(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, OcLine* collider) { s32 index; if (FrameAdvance_IsEnabled(globalCtx) == true) { return -1; } Collider_ResetLineOC(globalCtx, collider); if (!(colChkCtx->colLineCount < COLLISION_CHECK_OC_LINE_MAX)) { // "Index exceeded and cannot add more" osSyncPrintf("CollisionCheck_setOCLine():インデックスがオーバして追加不能\n"); return -1; } index = colChkCtx->colLineCount; colChkCtx->colLine[colChkCtx->colLineCount++] = collider; return index; } /** * Skips AT elements that are off. */ s32 CollisionCheck_SkipTouch(ColliderInfo* info) { if (!(info->toucherFlags & TOUCH_ON)) { return 1; } return 0; } /** * Skips AC elements that are off. */ s32 CollisionCheck_SkipBump(ColliderInfo* info) { if (!(info->bumperFlags & BUMP_ON)) { return 1; } return 0; } /** * If the AT element has no dmgFlags in common with the AC element, no collision happens. */ s32 CollisionCheck_NoSharedFlags(ColliderInfo* atInfo, ColliderInfo* acInfo) { if (!(atInfo->toucher.dmgFlags & acInfo->bumper.dmgFlags)) { return 1; } return 0; } /** * Spawns no blood drops. * Used by collider types HIT1, HIT3, HIT5, METAL, NONE, WOOD, HARD, and TREE */ void CollisionCheck_NoBlood(GlobalContext* globalCtx, Collider* collider, Vec3f* v) { } /** * Spawns blue blood drops. * Used by collider types HIT0 and HIT8. */ void CollisionCheck_BlueBlood(GlobalContext* globalCtx, Collider* collider, Vec3f* v) { static EffectSparkInit D_8015D8A0; s32 effectIndex; D_8015D8A0.position.x = v->x; D_8015D8A0.position.y = v->y; D_8015D8A0.position.z = v->z; D_8015D8A0.uDiv = 5; D_8015D8A0.vDiv = 5; D_8015D8A0.colorStart[0].r = 10; D_8015D8A0.colorStart[0].g = 10; D_8015D8A0.colorStart[0].b = 200; D_8015D8A0.colorStart[0].a = 255; D_8015D8A0.colorStart[1].r = 0; D_8015D8A0.colorStart[1].g = 0; D_8015D8A0.colorStart[1].b = 128; D_8015D8A0.colorStart[1].a = 255; D_8015D8A0.colorStart[2].r = 0; D_8015D8A0.colorStart[2].g = 0; D_8015D8A0.colorStart[2].b = 128; D_8015D8A0.colorStart[2].a = 255; D_8015D8A0.colorStart[3].r = 0; D_8015D8A0.colorStart[3].g = 0; D_8015D8A0.colorStart[3].b = 128; D_8015D8A0.colorStart[3].a = 255; D_8015D8A0.colorEnd[0].r = 0; D_8015D8A0.colorEnd[0].g = 0; D_8015D8A0.colorEnd[0].b = 32; D_8015D8A0.colorEnd[0].a = 0; D_8015D8A0.colorEnd[1].r = 0; D_8015D8A0.colorEnd[1].g = 0; D_8015D8A0.colorEnd[1].b = 32; D_8015D8A0.colorEnd[1].a = 0; D_8015D8A0.colorEnd[2].r = 0; D_8015D8A0.colorEnd[2].g = 0; D_8015D8A0.colorEnd[2].b = 64; D_8015D8A0.colorEnd[2].a = 0; D_8015D8A0.colorEnd[3].r = 0; D_8015D8A0.colorEnd[3].g = 0; D_8015D8A0.colorEnd[3].b = 64; D_8015D8A0.colorEnd[3].a = 0; D_8015D8A0.timer = 0; D_8015D8A0.duration = 16; D_8015D8A0.speed = 8.0f; D_8015D8A0.gravity = -1.0f; Effect_Add(globalCtx, &effectIndex, EFFECT_SPARK, 0, 1, &D_8015D8A0); } /** * Spawns green blood drops. * Used by collider types HIT2 and HIT6. No actor has type HIT2. */ void CollisionCheck_GreenBlood(GlobalContext* globalCtx, Collider* collider, Vec3f* v) { static EffectSparkInit D_8015DD68; s32 effectIndex; D_8015DD68.position.x = v->x; D_8015DD68.position.y = v->y; D_8015DD68.position.z = v->z; D_8015DD68.uDiv = 5; D_8015DD68.vDiv = 5; D_8015DD68.colorStart[0].r = 10; D_8015DD68.colorStart[0].g = 200; D_8015DD68.colorStart[0].b = 10; D_8015DD68.colorStart[0].a = 255; D_8015DD68.colorStart[1].r = 0; D_8015DD68.colorStart[1].g = 128; D_8015DD68.colorStart[1].b = 0; D_8015DD68.colorStart[1].a = 255; D_8015DD68.colorStart[2].r = 0; D_8015DD68.colorStart[2].g = 128; D_8015DD68.colorStart[2].b = 0; D_8015DD68.colorStart[2].a = 255; D_8015DD68.colorStart[3].r = 0; D_8015DD68.colorStart[3].g = 128; D_8015DD68.colorStart[3].b = 0; D_8015DD68.colorStart[3].a = 255; D_8015DD68.colorEnd[0].r = 0; D_8015DD68.colorEnd[0].g = 32; D_8015DD68.colorEnd[0].b = 0; D_8015DD68.colorEnd[0].a = 0; D_8015DD68.colorEnd[1].r = 0; D_8015DD68.colorEnd[1].g = 32; D_8015DD68.colorEnd[1].b = 0; D_8015DD68.colorEnd[1].a = 0; D_8015DD68.colorEnd[2].r = 0; D_8015DD68.colorEnd[2].g = 64; D_8015DD68.colorEnd[2].b = 0; D_8015DD68.colorEnd[2].a = 0; D_8015DD68.colorEnd[3].r = 0; D_8015DD68.colorEnd[3].g = 64; D_8015DD68.colorEnd[3].b = 0; D_8015DD68.colorEnd[3].a = 0; D_8015DD68.timer = 0; D_8015DD68.duration = 16; D_8015DD68.speed = 8.0f; D_8015DD68.gravity = -1.0f; Effect_Add(globalCtx, &effectIndex, EFFECT_SPARK, 0, 1, &D_8015DD68); } /** * Spawns a burst of water. * Used by collider type HIT4, which no actor has. */ void CollisionCheck_WaterBurst(GlobalContext* globalCtx, Collider* collider, Vec3f* pos) { EffectSsSibuki_SpawnBurst(globalCtx, pos); CollisionCheck_SpawnWaterDroplets(globalCtx, pos); } /** * Spawns red blood drops. * Used by collider type HIT7, which no actor has. */ void CollisionCheck_RedBlood(GlobalContext* globalCtx, Collider* collider, Vec3f* v) { CollisionCheck_SpawnRedBlood(globalCtx, v); } /** * Spawns red blood drops. * Unused. */ void CollisionCheck_RedBloodUnused(GlobalContext* globalCtx, Collider* collider, Vec3f* v) { CollisionCheck_SpawnRedBlood(globalCtx, v); } /** * Plays sound effects and displays hitmarks for solid-type AC colliders (METAL, WOOD, HARD, and TREE) */ void CollisionCheck_HitSolid(GlobalContext* globalCtx, ColliderInfo* info, Collider* collider, Vec3f* hitPos) { s32 flags = info->toucherFlags & TOUCH_SFX_NONE; if (flags == TOUCH_SFX_NORMAL && collider->colType != COLTYPE_METAL) { EffectSsHitMark_SpawnFixedScale(globalCtx, EFFECT_HITMARK_WHITE, hitPos); if (collider->actor == NULL) { Audio_PlaySoundGeneral(NA_SE_IT_SHIELD_BOUND, &D_801333D4, 4, &D_801333E0, &D_801333E0, &D_801333E8); } else { Audio_PlaySoundGeneral(NA_SE_IT_SHIELD_BOUND, &collider->actor->projectedPos, 4, &D_801333E0, &D_801333E0, &D_801333E8); } } else if (flags == TOUCH_SFX_NORMAL) { // collider->colType == COLTYPE_METAL EffectSsHitMark_SpawnFixedScale(globalCtx, EFFECT_HITMARK_METAL, hitPos); if (collider->actor == NULL) { CollisionCheck_SpawnShieldParticlesMetal(globalCtx, hitPos); } else { CollisionCheck_SpawnShieldParticlesMetalSound(globalCtx, hitPos, &collider->actor->projectedPos); } } else if (flags == TOUCH_SFX_HARD) { EffectSsHitMark_SpawnFixedScale(globalCtx, EFFECT_HITMARK_WHITE, hitPos); if (collider->actor == NULL) { Audio_PlaySoundGeneral(NA_SE_IT_SHIELD_BOUND, &D_801333D4, 4, &D_801333E0, &D_801333E0, &D_801333E8); } else { Audio_PlaySoundGeneral(NA_SE_IT_SHIELD_BOUND, &collider->actor->projectedPos, 4, &D_801333E0, &D_801333E0, &D_801333E8); } } else if (flags == TOUCH_SFX_WOOD) { EffectSsHitMark_SpawnFixedScale(globalCtx, EFFECT_HITMARK_DUST, hitPos); if (collider->actor == NULL) { Audio_PlaySoundGeneral(NA_SE_IT_REFLECTION_WOOD, &D_801333D4, 4, &D_801333E0, &D_801333E0, &D_801333E8); } else { Audio_PlaySoundGeneral(NA_SE_IT_REFLECTION_WOOD, &collider->actor->projectedPos, 4, &D_801333E0, &D_801333E0, &D_801333E8); } } } /** * Plays a hit sound effect for AT colliders attached to Player based on the AC element's elemType. */ s32 CollisionCheck_SwordHitAudio(Collider* at, ColliderInfo* acInfo) { if (at->actor != NULL && at->actor->category == ACTORCAT_PLAYER) { if (acInfo->elemType == ELEMTYPE_UNK0) { Audio_PlaySoundGeneral(NA_SE_IT_SWORD_STRIKE, &at->actor->projectedPos, 4, &D_801333E0, &D_801333E0, &D_801333E8); } else if (acInfo->elemType == ELEMTYPE_UNK1) { Audio_PlaySoundGeneral(NA_SE_IT_SWORD_STRIKE_HARD, &at->actor->projectedPos, 4, &D_801333E0, &D_801333E0, &D_801333E8); } else if (acInfo->elemType == ELEMTYPE_UNK2) { Audio_PlaySoundGeneral(NA_SE_PL_WALK_GROUND - SFX_FLAG, &at->actor->projectedPos, 4, &D_801333E0, &D_801333E0, &D_801333E8); } else if (acInfo->elemType == ELEMTYPE_UNK3) { Audio_PlaySoundGeneral(NA_SE_PL_WALK_GROUND - SFX_FLAG, &at->actor->projectedPos, 4, &D_801333E0, &D_801333E0, &D_801333E8); } } return 1; } static ColChkBloodFunc sBloodFuncs[] = { CollisionCheck_NoBlood, CollisionCheck_BlueBlood, CollisionCheck_GreenBlood, CollisionCheck_WaterBurst, CollisionCheck_RedBlood, CollisionCheck_RedBloodUnused, }; static HitInfo sHitInfo[] = { { BLOOD_BLUE, HIT_WHITE }, { BLOOD_NONE, HIT_DUST }, { BLOOD_GREEN, HIT_DUST }, { BLOOD_NONE, HIT_WHITE }, { BLOOD_WATER, HIT_NONE }, { BLOOD_NONE, HIT_RED }, { BLOOD_GREEN, HIT_WHITE }, { BLOOD_RED, HIT_WHITE }, { BLOOD_BLUE, HIT_RED }, { BLOOD_NONE, HIT_SOLID }, { BLOOD_NONE, HIT_NONE }, { BLOOD_NONE, HIT_SOLID }, { BLOOD_NONE, HIT_SOLID }, { BLOOD_NONE, HIT_WOOD }, }; /** * Handles hitmarks, blood, and sound effects for each AC collision, determined by the AC collider's colType */ void CollisionCheck_HitEffects(GlobalContext* globalCtx, Collider* at, ColliderInfo* atInfo, Collider* ac, ColliderInfo* acInfo, Vec3f* hitPos) { if (acInfo->bumperFlags & BUMP_NO_HITMARK) { return; } if (!(atInfo->toucherFlags & TOUCH_AT_HITMARK) && atInfo->toucherFlags & TOUCH_DREW_HITMARK) { return; } if (ac->actor != NULL) { sBloodFuncs[sHitInfo[ac->colType].blood](globalCtx, ac, hitPos); } if (ac->actor != NULL) { if (sHitInfo[ac->colType].effect == HIT_SOLID) { CollisionCheck_HitSolid(globalCtx, atInfo, ac, hitPos); } else if (sHitInfo[ac->colType].effect == HIT_WOOD) { if (at->actor == NULL) { CollisionCheck_SpawnShieldParticles(globalCtx, hitPos); Audio_PlaySoundGeneral(NA_SE_IT_REFLECTION_WOOD, &D_801333D4, 4, &D_801333E0, &D_801333E0, &D_801333E8); } else { CollisionCheck_SpawnShieldParticlesWood(globalCtx, hitPos, &at->actor->projectedPos); } } else if (sHitInfo[ac->colType].effect != HIT_NONE) { EffectSsHitMark_SpawnFixedScale(globalCtx, sHitInfo[ac->colType].effect, hitPos); if (!(acInfo->bumperFlags & BUMP_NO_SWORD_SFX)) { CollisionCheck_SwordHitAudio(at, acInfo); } } } else { EffectSsHitMark_SpawnFixedScale(globalCtx, EFFECT_HITMARK_WHITE, hitPos); if (ac->actor == NULL) { Audio_PlaySoundGeneral(NA_SE_IT_SHIELD_BOUND, &D_801333D4, 4, &D_801333E0, &D_801333E0, &D_801333E8); } else { Audio_PlaySoundGeneral(NA_SE_IT_SHIELD_BOUND, &ac->actor->projectedPos, 4, &D_801333E0, &D_801333E0, &D_801333E8); } } } /** * Sets the flags to indicate an attack bounced off an AC_HARD collider. */ void CollisionCheck_SetBounce(Collider* at, Collider* ac) { at->atFlags |= AT_BOUNCED; ac->acFlags |= AC_BOUNCED; } /** * Performs the AC collision between the AT element and AC element that collided. */ s32 CollisionCheck_SetATvsAC(GlobalContext* globalCtx, Collider* at, ColliderInfo* atInfo, Vec3f* atPos, Collider* ac, ColliderInfo* acInfo, Vec3f* acPos, Vec3f* hitPos) { if (ac->acFlags & AC_HARD && at->actor != NULL && ac->actor != NULL) { CollisionCheck_SetBounce(at, ac); } if (!(acInfo->bumperFlags & BUMP_NO_AT_INFO)) { at->atFlags |= AT_HIT; at->at = ac->actor; atInfo->atHit = ac; atInfo->atHitInfo = acInfo; atInfo->toucherFlags |= TOUCH_HIT; if (at->actor != NULL) { at->actor->colChkInfo.atHitEffect = acInfo->bumper.effect; } } ac->acFlags |= AC_HIT; ac->ac = at->actor; acInfo->acHit = at; acInfo->acHitInfo = atInfo; acInfo->bumperFlags |= BUMP_HIT; if (ac->actor != NULL) { ac->actor->colChkInfo.acHitEffect = atInfo->toucher.effect; } acInfo->bumper.hitPos.x = hitPos->x; acInfo->bumper.hitPos.y = hitPos->y; acInfo->bumper.hitPos.z = hitPos->z; if (!(atInfo->toucherFlags & TOUCH_AT_HITMARK) && ac->colType != COLTYPE_METAL && ac->colType != COLTYPE_WOOD && ac->colType != COLTYPE_HARD) { acInfo->bumperFlags |= BUMP_DRAW_HITMARK; } else { CollisionCheck_HitEffects(globalCtx, at, atInfo, ac, acInfo, hitPos); atInfo->toucherFlags |= TOUCH_DREW_HITMARK; } return 1; } /** * AC overlap check. Calculates the center of each collider element and the point of contact. */ void CollisionCheck_AC_JntSphVsJntSph(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* colAT, Collider* colAC) { ColliderJntSph* at = (ColliderJntSph*)colAT; ColliderJntSphElement* atItem; ColliderJntSph* ac = (ColliderJntSph*)colAC; ColliderJntSphElement* acElem; f32 overlapSize; f32 centerDist; if (at->count > 0 && at->elements != NULL && ac->count > 0 && ac->elements != NULL) { for (atItem = at->elements; atItem < at->elements + at->count; atItem++) { if (CollisionCheck_SkipTouch(&atItem->info) == 1) { continue; } for (acElem = ac->elements; acElem < ac->elements + ac->count; acElem++) { if (CollisionCheck_SkipBump(&acElem->info) == 1) { continue; } if (CollisionCheck_NoSharedFlags(&atItem->info, &acElem->info) == 1) { continue; } if (Math3D_SphVsSphOverlapCenter(&atItem->dim.worldSphere, &acElem->dim.worldSphere, &overlapSize, ¢erDist) == 1) { f32 acToHit; Vec3f hitPos; Vec3f atPos; Vec3f acPos; atPos.x = atItem->dim.worldSphere.center.x; atPos.y = atItem->dim.worldSphere.center.y; atPos.z = atItem->dim.worldSphere.center.z; acPos.x = acElem->dim.worldSphere.center.x; acPos.y = acElem->dim.worldSphere.center.y; acPos.z = acElem->dim.worldSphere.center.z; if (!IS_ZERO(centerDist)) { acToHit = acElem->dim.worldSphere.radius / centerDist; hitPos.x = (((atPos.x - acPos.x) * acToHit) + acPos.x); hitPos.y = (((atPos.y - acPos.y) * acToHit) + acPos.y); hitPos.z = (((atPos.z - acPos.z) * acToHit) + acPos.z); } else { Math_Vec3f_Copy(&hitPos, &atPos); } CollisionCheck_SetATvsAC(globalCtx, &at->base, &atItem->info, &atPos, &ac->base, &acElem->info, &acPos, &hitPos); if (!(ac->base.ocFlags2 & OC2_FIRST_ONLY)) { return; } } } } } } /** * AC overlap check. Calculates the center of each collider element and the point of contact. */ void CollisionCheck_AC_JntSphVsCyl(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* colAT, Collider* colAC) { ColliderJntSph* at = (ColliderJntSph*)colAT; ColliderJntSphElement* atItem; ColliderCylinder* ac = (ColliderCylinder*)colAC; f32 overlapSize; f32 centerDist; if (at->count > 0 && at->elements != NULL && ac->dim.radius > 0 && ac->dim.height > 0) { if (CollisionCheck_SkipBump(&ac->info) == 1) { return; } for (atItem = at->elements; atItem < at->elements + at->count; atItem++) { if (CollisionCheck_SkipTouch(&atItem->info) == 1) { continue; } if (CollisionCheck_NoSharedFlags(&atItem->info, &ac->info) == 1) { continue; } if (Math3D_SphVsCylOverlapCenterDist(&atItem->dim.worldSphere, &ac->dim, &overlapSize, ¢erDist)) { Vec3f hitPos; Vec3f atPos; Vec3f acPos; f32 acToHit; atPos.x = atItem->dim.worldSphere.center.x; atPos.y = atItem->dim.worldSphere.center.y; atPos.z = atItem->dim.worldSphere.center.z; acPos.x = ac->dim.pos.x; acPos.y = ac->dim.pos.y; acPos.z = ac->dim.pos.z; if (!IS_ZERO(centerDist)) { acToHit = ac->dim.radius / centerDist; if (acToHit <= 1.0f) { hitPos.x = ((atPos.x - acPos.x) * acToHit) + acPos.x; hitPos.y = ((atPos.y - acPos.y) * acToHit) + acPos.y; hitPos.z = ((atPos.z - acPos.z) * acToHit) + acPos.z; } else { Math_Vec3f_Copy(&hitPos, &atPos); } } else { Math_Vec3f_Copy(&hitPos, &atPos); } CollisionCheck_SetATvsAC(globalCtx, &at->base, &atItem->info, &atPos, &ac->base, &ac->info, &acPos, &hitPos); return; } } } } /** * AC overlap check. Calculates the center of each collider element and the point of contact. */ void CollisionCheck_AC_CylVsJntSph(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* colAT, Collider* colAC) { ColliderCylinder* at = (ColliderCylinder*)colAT; ColliderJntSph* ac = (ColliderJntSph*)colAC; f32 overlapSize; f32 centerDist; ColliderJntSphElement* acElem; if (ac->count > 0 && ac->elements != NULL && at->dim.radius > 0 && at->dim.height > 0) { if (CollisionCheck_SkipTouch(&at->info) == 1) { return; } for (acElem = ac->elements; acElem < ac->elements + ac->count; acElem++) { if (CollisionCheck_SkipBump(&acElem->info) == 1) { continue; } if (CollisionCheck_NoSharedFlags(&at->info, &acElem->info) == 1) { continue; } if (Math3D_SphVsCylOverlapCenterDist(&acElem->dim.worldSphere, &at->dim, &overlapSize, ¢erDist)) { Vec3f hitPos; Vec3f atPos; Vec3f acPos; f32 acToHit; atPos.x = at->dim.pos.x; atPos.y = at->dim.pos.y; atPos.z = at->dim.pos.z; acPos.x = acElem->dim.worldSphere.center.x; acPos.y = acElem->dim.worldSphere.center.y; acPos.z = acElem->dim.worldSphere.center.z; if (!IS_ZERO(centerDist)) { acToHit = acElem->dim.worldSphere.radius / centerDist; if (acToHit <= 1.0f) { hitPos.x = ((atPos.x - acPos.x) * acToHit) + acPos.x; hitPos.y = ((atPos.y - acPos.y) * acToHit) + acPos.y; hitPos.z = ((atPos.z - acPos.z) * acToHit) + acPos.z; } else { Math_Vec3f_Copy(&hitPos, &atPos); } } else { Math_Vec3f_Copy(&hitPos, &atPos); } CollisionCheck_SetATvsAC(globalCtx, &at->base, &at->info, &atPos, &ac->base, &acElem->info, &acPos, &hitPos); if (!(ac->base.ocFlags2 & OC2_FIRST_ONLY)) { break; } } } } } /** * AC overlap check. Calculates the center of each collider element and the point of contact. */ void CollisionCheck_AC_JntSphVsTris(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* colAT, Collider* colAC) { ColliderJntSph* at = (ColliderJntSph*)colAT; ColliderJntSphElement* atSph; ColliderTris* ac = (ColliderTris*)colAC; ColliderTrisElement* acTri; Vec3f hitPos; if (at->count > 0 && at->elements != NULL && ac->count > 0 && ac->elements != NULL) { for (atSph = at->elements; atSph < at->elements + at->count; atSph++) { if (CollisionCheck_SkipTouch(&atSph->info) == 1) { continue; } for (acTri = ac->elements; acTri < ac->elements + ac->count; acTri++) { if (CollisionCheck_SkipBump(&acTri->info) == 1) { continue; } if (CollisionCheck_NoSharedFlags(&atSph->info, &acTri->info) == 1) { continue; } if (Math3D_TriVsSphIntersect(&atSph->dim.worldSphere, &acTri->dim, &hitPos) == 1) { Vec3f atPos; Vec3f acPos; atPos.x = atSph->dim.worldSphere.center.x; atPos.y = atSph->dim.worldSphere.center.y; atPos.z = atSph->dim.worldSphere.center.z; acPos.x = (acTri->dim.vtx[0].x + acTri->dim.vtx[1].x + acTri->dim.vtx[2].x) * (1.0f / 3); acPos.y = (acTri->dim.vtx[0].y + acTri->dim.vtx[1].y + acTri->dim.vtx[2].y) * (1.0f / 3); acPos.z = (acTri->dim.vtx[0].z + acTri->dim.vtx[1].z + acTri->dim.vtx[2].z) * (1.0f / 3); CollisionCheck_SetATvsAC(globalCtx, &at->base, &atSph->info, &atPos, &ac->base, &acTri->info, &acPos, &hitPos); return; } } } } } /** * AC overlap check. Calculates the center of each collider element and the point of contact. */ void CollisionCheck_AC_TrisVsJntSph(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* colAT, Collider* colAC) { ColliderTris* at = (ColliderTris*)colAT; ColliderTrisElement* atItem; ColliderJntSph* ac = (ColliderJntSph*)colAC; ColliderJntSphElement* acElem; Vec3f hitPos; if (ac->count > 0 && ac->elements != NULL && at->count > 0 && at->elements != NULL) { for (acElem = ac->elements; acElem < ac->elements + ac->count; acElem++) { if (CollisionCheck_SkipBump(&acElem->info) == 1) { continue; } for (atItem = at->elements; atItem < at->elements + at->count; atItem++) { if (CollisionCheck_SkipTouch(&atItem->info) == 1) { continue; } if (CollisionCheck_NoSharedFlags(&atItem->info, &acElem->info) == 1) { continue; } if (Math3D_TriVsSphIntersect(&acElem->dim.worldSphere, &atItem->dim, &hitPos) == 1) { Vec3f atPos; Vec3f acPos; Math_Vec3s_ToVec3f(&acPos, &acElem->dim.worldSphere.center); atPos.x = (atItem->dim.vtx[0].x + atItem->dim.vtx[1].x + atItem->dim.vtx[2].x) * (1.0f / 3); atPos.y = (atItem->dim.vtx[0].y + atItem->dim.vtx[1].y + atItem->dim.vtx[2].y) * (1.0f / 3); atPos.z = (atItem->dim.vtx[0].z + atItem->dim.vtx[1].z + atItem->dim.vtx[2].z) * (1.0f / 3); CollisionCheck_SetATvsAC(globalCtx, &at->base, &atItem->info, &atPos, &ac->base, &acElem->info, &acPos, &hitPos); if (!(ac->base.ocFlags2 & OC2_FIRST_ONLY)) { return; } } } } } } /** * AC overlap check. Calculates the center of each collider element and the point of contact. */ void CollisionCheck_AC_JntSphVsQuad(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* colAT, Collider* colAC) { static TriNorm D_8015E230; static TriNorm D_8015E268; ColliderJntSph* at = (ColliderJntSph*)colAT; ColliderQuad* ac = (ColliderQuad*)colAC; Vec3f hitPos; ColliderJntSphElement* atItem; if (at->count > 0 && at->elements != NULL) { if (CollisionCheck_SkipBump(&ac->info) == 1) { return; } Math3D_TriNorm(&D_8015E230, &ac->dim.quad[2], &ac->dim.quad[3], &ac->dim.quad[1]); Math3D_TriNorm(&D_8015E268, &ac->dim.quad[1], &ac->dim.quad[0], &ac->dim.quad[2]); for (atItem = at->elements; atItem < at->elements + at->count; atItem++) { if (CollisionCheck_SkipTouch(&atItem->info) == 1) { continue; } if (CollisionCheck_NoSharedFlags(&atItem->info, &ac->info) == 1) { continue; } if (Math3D_TriVsSphIntersect(&atItem->dim.worldSphere, &D_8015E230, &hitPos) == 1 || Math3D_TriVsSphIntersect(&atItem->dim.worldSphere, &D_8015E268, &hitPos) == 1) { Vec3f atPos; Vec3f acPos; Math_Vec3s_ToVec3f(&atPos, &atItem->dim.worldSphere.center); acPos.x = (ac->dim.quad[0].x + (ac->dim.quad[1].x + (ac->dim.quad[3].x + ac->dim.quad[2].x))) / 4.0f; acPos.y = (ac->dim.quad[0].y + (ac->dim.quad[1].y + (ac->dim.quad[3].y + ac->dim.quad[2].y))) / 4.0f; acPos.z = (ac->dim.quad[0].z + (ac->dim.quad[1].z + (ac->dim.quad[3].z + ac->dim.quad[2].z))) / 4.0f; CollisionCheck_SetATvsAC(globalCtx, &at->base, &atItem->info, &atPos, &ac->base, &ac->info, &acPos, &hitPos); return; } } } } /** * AC overlap check. Calculates the center of each collider element and the point of contact. */ void CollisionCheck_AC_QuadVsJntSph(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* colAT, Collider* colAC) { static TriNorm D_8015E2A0; static TriNorm D_8015E2D8; ColliderJntSph* ac = (ColliderJntSph*)colAC; Vec3f hitPos; ColliderQuad* at = (ColliderQuad*)colAT; ColliderJntSphElement* acElem; if (ac->count > 0 && ac->elements != NULL) { if (CollisionCheck_SkipTouch(&at->info) == 1) { return; } Math3D_TriNorm(&D_8015E2A0, &at->dim.quad[2], &at->dim.quad[3], &at->dim.quad[1]); Math3D_TriNorm(&D_8015E2D8, &at->dim.quad[2], &at->dim.quad[1], &at->dim.quad[0]); for (acElem = ac->elements; acElem < ac->elements + ac->count; acElem++) { if (CollisionCheck_SkipBump(&acElem->info) == 1) { continue; } if (CollisionCheck_NoSharedFlags(&at->info, &acElem->info) == 1) { continue; } if (Math3D_TriVsSphIntersect(&acElem->dim.worldSphere, &D_8015E2A0, &hitPos) == 1 || Math3D_TriVsSphIntersect(&acElem->dim.worldSphere, &D_8015E2D8, &hitPos) == 1) { if (Collider_QuadSetNearestAC(globalCtx, at, &hitPos)) { Vec3f atPos; Vec3f acPos; acPos.x = acElem->dim.worldSphere.center.x; acPos.y = acElem->dim.worldSphere.center.y; acPos.z = acElem->dim.worldSphere.center.z; atPos.x = (at->dim.quad[0].x + (at->dim.quad[1].x + (at->dim.quad[3].x + at->dim.quad[2].x))) / 4.0f; atPos.y = (at->dim.quad[0].y + (at->dim.quad[1].y + (at->dim.quad[3].y + at->dim.quad[2].y))) / 4.0f; atPos.z = (at->dim.quad[0].z + (at->dim.quad[1].z + (at->dim.quad[3].z + at->dim.quad[2].z))) / 4.0f; CollisionCheck_SetATvsAC(globalCtx, &at->base, &at->info, &atPos, &ac->base, &acElem->info, &acPos, &hitPos); if (!(ac->base.ocFlags2 & OC2_FIRST_ONLY)) { return; } } } } } } /** * AC overlap check. Calculates the center of each collider element and the point of contact. */ void CollisionCheck_AC_CylVsCyl(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* colAT, Collider* colAC) { ColliderCylinder* at = (ColliderCylinder*)colAT; ColliderCylinder* ac = (ColliderCylinder*)colAC; f32 deadSpace; f32 centerDistXZ; Vec3f hitPos; if (at->dim.radius > 0 && at->dim.height > 0 && ac->dim.radius > 0 && ac->dim.height > 0) { if (CollisionCheck_SkipBump(&ac->info) == 1) { return; } if (CollisionCheck_SkipTouch(&at->info) == 1) { return; } if (CollisionCheck_NoSharedFlags(&at->info, &ac->info) == 1) { return; } if (Math3D_CylOutsideCylDist(&at->dim, &ac->dim, &deadSpace, ¢erDistXZ) == 1) { Vec3f atPos; Vec3f acPos; f32 acToHit; Math_Vec3s_ToVec3f(&atPos, &at->dim.pos); Math_Vec3s_ToVec3f(&acPos, &ac->dim.pos); if (!IS_ZERO(centerDistXZ)) { acToHit = ac->dim.radius / centerDistXZ; hitPos.y = (f32)ac->dim.pos.y + ac->dim.yShift + ac->dim.height * 0.5f; hitPos.x = ((f32)at->dim.pos.x - ac->dim.pos.x) * acToHit + ac->dim.pos.x; hitPos.z = ((f32)at->dim.pos.z - ac->dim.pos.z) * acToHit + ac->dim.pos.z; } else { Math_Vec3s_ToVec3f(&hitPos, &ac->dim.pos); } CollisionCheck_SetATvsAC(globalCtx, &at->base, &at->info, &atPos, &ac->base, &ac->info, &acPos, &hitPos); } } } /** * AC overlap check. Calculates the center of each collider element and the point of contact. */ void CollisionCheck_AC_CylVsTris(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* colAT, Collider* colAC) { ColliderCylinder* at = (ColliderCylinder*)colAT; ColliderTris* ac = (ColliderTris*)colAC; ColliderTrisElement* acElem; Vec3f hitPos; if (at->dim.radius > 0 && at->dim.height > 0 && ac->count > 0 && ac->elements != NULL) { if (CollisionCheck_SkipTouch(&at->info) == 1) { return; } for (acElem = ac->elements; acElem < ac->elements + ac->count; acElem++) { if (CollisionCheck_SkipBump(&acElem->info) == 1) { continue; } if (CollisionCheck_NoSharedFlags(&at->info, &acElem->info) == 1) { continue; } if (Math3D_CylTriVsIntersect(&at->dim, &acElem->dim, &hitPos) == 1) { Vec3f atpos; Vec3f acPos; Math_Vec3s_ToVec3f(&atpos, &at->dim.pos); acPos.x = (acElem->dim.vtx[0].x + acElem->dim.vtx[1].x + acElem->dim.vtx[2].x) * (1.0f / 3); acPos.y = (acElem->dim.vtx[0].y + acElem->dim.vtx[1].y + acElem->dim.vtx[2].y) * (1.0f / 3); acPos.z = (acElem->dim.vtx[0].z + acElem->dim.vtx[1].z + acElem->dim.vtx[2].z) * (1.0f / 3); CollisionCheck_SetATvsAC(globalCtx, &at->base, &at->info, &atpos, &ac->base, &acElem->info, &acPos, &hitPos); return; } } } } /** * AC overlap check. Calculates the center of each collider element and the point of contact. */ void CollisionCheck_AC_TrisVsCyl(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* colAT, Collider* colAC) { static Vec3f D_8015E310; ColliderTris* at = (ColliderTris*)colAT; ColliderTrisElement* atItem; ColliderCylinder* ac = (ColliderCylinder*)colAC; Vec3f atPos; Vec3f acPos; if (ac->dim.radius > 0 && ac->dim.height > 0 && at->count > 0 && at->elements != NULL) { if (CollisionCheck_SkipBump(&ac->info) == 1) { return; } for (atItem = at->elements; atItem < at->elements + at->count; atItem++) { if (CollisionCheck_SkipTouch(&atItem->info) == 1) { continue; } if (CollisionCheck_NoSharedFlags(&atItem->info, &ac->info) == 1) { continue; } if (Math3D_CylTriVsIntersect(&ac->dim, &atItem->dim, &D_8015E310) == 1) { atPos.x = (atItem->dim.vtx[0].x + atItem->dim.vtx[1].x + atItem->dim.vtx[2].x) * (1.0f / 3); atPos.y = (atItem->dim.vtx[0].y + atItem->dim.vtx[1].y + atItem->dim.vtx[2].y) * (1.0f / 3); atPos.z = (atItem->dim.vtx[0].z + atItem->dim.vtx[1].z + atItem->dim.vtx[2].z) * (1.0f / 3); Math_Vec3s_ToVec3f(&acPos, &ac->dim.pos); CollisionCheck_SetATvsAC(globalCtx, &at->base, &atItem->info, &atPos, &ac->base, &ac->info, &acPos, &D_8015E310); return; } } } } /** * AC overlap check. Calculates the center of each collider element and the point of contact. */ void CollisionCheck_AC_CylVsQuad(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* colAT, Collider* colAC) { static TriNorm D_8015E320; static TriNorm D_8015E358; static Vec3f D_8015E390; ColliderCylinder* at = (ColliderCylinder*)colAT; ColliderQuad* ac = (ColliderQuad*)colAC; if (at->dim.height > 0 && at->dim.radius > 0) { if (CollisionCheck_SkipTouch(&at->info) == 1 || CollisionCheck_SkipBump(&ac->info) == 1) { return; } if (CollisionCheck_NoSharedFlags(&at->info, &ac->info) == 1) { return; } Math3D_TriNorm(&D_8015E320, &ac->dim.quad[2], &ac->dim.quad[3], &ac->dim.quad[1]); Math3D_TriNorm(&D_8015E358, &ac->dim.quad[1], &ac->dim.quad[0], &ac->dim.quad[2]); if (Math3D_CylTriVsIntersect(&at->dim, &D_8015E320, &D_8015E390) == 1) { Vec3f atPos1; Vec3f acPos1; Math_Vec3s_ToVec3f(&atPos1, &at->dim.pos); acPos1.x = (ac->dim.quad[0].x + (ac->dim.quad[1].x + (ac->dim.quad[3].x + ac->dim.quad[2].x))) / 4.0f; acPos1.y = (ac->dim.quad[0].y + (ac->dim.quad[1].y + (ac->dim.quad[3].y + ac->dim.quad[2].y))) / 4.0f; acPos1.z = (ac->dim.quad[0].z + (ac->dim.quad[1].z + (ac->dim.quad[3].z + ac->dim.quad[2].z))) / 4.0f; CollisionCheck_SetATvsAC(globalCtx, &at->base, &at->info, &atPos1, &ac->base, &ac->info, &acPos1, &D_8015E390); } else if (Math3D_CylTriVsIntersect(&at->dim, &D_8015E358, &D_8015E390) == 1) { Vec3f atPos2; Vec3f acPos2; Math_Vec3s_ToVec3f(&atPos2, &at->dim.pos); acPos2.x = (ac->dim.quad[0].x + (ac->dim.quad[1].x + (ac->dim.quad[3].x + ac->dim.quad[2].x))) / 4.0f; acPos2.y = (ac->dim.quad[0].y + (ac->dim.quad[1].y + (ac->dim.quad[3].y + ac->dim.quad[2].y))) / 4.0f; acPos2.z = (ac->dim.quad[0].z + (ac->dim.quad[1].z + (ac->dim.quad[3].z + ac->dim.quad[2].z))) / 4.0f; CollisionCheck_SetATvsAC(globalCtx, &at->base, &at->info, &atPos2, &ac->base, &ac->info, &acPos2, &D_8015E390); } } } static s8 sBssDummy0; static s8 sBssDummy1; /** * AC overlap check. Calculates the center of each collider element and the point of contact. */ void CollisionCheck_AC_QuadVsCyl(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* colAT, Collider* colAC) { static TriNorm D_8015E3A0; static TriNorm D_8015E3D8; static Vec3f D_8015E410; ColliderQuad* at = (ColliderQuad*)colAT; ColliderCylinder* ac = (ColliderCylinder*)colAC; if (ac->dim.height > 0 && ac->dim.radius > 0) { if (CollisionCheck_SkipBump(&ac->info) == 1 || CollisionCheck_SkipTouch(&at->info) == 1) { return; } if (CollisionCheck_NoSharedFlags(&at->info, &ac->info) == 1) { return; } Math3D_TriNorm(&D_8015E3A0, &at->dim.quad[2], &at->dim.quad[3], &at->dim.quad[1]); Math3D_TriNorm(&D_8015E3D8, &at->dim.quad[2], &at->dim.quad[1], &at->dim.quad[0]); if (Math3D_CylTriVsIntersect(&ac->dim, &D_8015E3A0, &D_8015E410) == 1) { if (Collider_QuadSetNearestAC(globalCtx, at, &D_8015E410)) { Vec3f atPos1; Vec3f acPos1; atPos1.x = (at->dim.quad[0].x + (at->dim.quad[1].x + (at->dim.quad[3].x + at->dim.quad[2].x))) / 4.0f; atPos1.y = (at->dim.quad[0].y + (at->dim.quad[1].y + (at->dim.quad[3].y + at->dim.quad[2].y))) / 4.0f; atPos1.z = (at->dim.quad[0].z + (at->dim.quad[1].z + (at->dim.quad[3].z + at->dim.quad[2].z))) / 4.0f; Math_Vec3s_ToVec3f(&acPos1, &ac->dim.pos); CollisionCheck_SetATvsAC(globalCtx, &at->base, &at->info, &atPos1, &ac->base, &ac->info, &acPos1, &D_8015E410); return; } } if (Math3D_CylTriVsIntersect(&ac->dim, &D_8015E3D8, &D_8015E410) == 1) { if (Collider_QuadSetNearestAC(globalCtx, at, &D_8015E410)) { Vec3f atPos2; Vec3f acPos2; atPos2.x = (at->dim.quad[0].x + (at->dim.quad[1].x + (at->dim.quad[3].x + at->dim.quad[2].x))) / 4.0f; atPos2.y = (at->dim.quad[0].y + (at->dim.quad[1].y + (at->dim.quad[3].y + at->dim.quad[2].y))) / 4.0f; atPos2.z = (at->dim.quad[0].z + (at->dim.quad[1].z + (at->dim.quad[3].z + at->dim.quad[2].z))) / 4.0f; Math_Vec3s_ToVec3f(&acPos2, &ac->dim.pos); CollisionCheck_SetATvsAC(globalCtx, &at->base, &at->info, &atPos2, &ac->base, &ac->info, &acPos2, &D_8015E410); } } } } static s8 sBssDummy3; static s8 sBssDummy4; static s8 sBssDummy5; static s8 sBssDummy6; /** * AC overlap check. Calculates the center of each collider element and the point of contact. */ void CollisionCheck_AC_TrisVsTris(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* colAT, Collider* colAC) { static Vec3f D_8015E420; ColliderTris* at = (ColliderTris*)colAT; ColliderTrisElement* atItem; ColliderTris* ac = (ColliderTris*)colAC; ColliderTrisElement* acElem; if (ac->count > 0 && ac->elements != NULL && at->count > 0 && at->elements != NULL) { for (acElem = ac->elements; acElem < ac->elements + ac->count; acElem++) { if (CollisionCheck_SkipBump(&acElem->info) == 1) { continue; } for (atItem = at->elements; atItem < at->elements + at->count; atItem++) { if (CollisionCheck_SkipTouch(&atItem->info) == 1) { continue; } if (CollisionCheck_NoSharedFlags(&atItem->info, &acElem->info) == 1) { continue; } if (Math3D_TriVsTriIntersect(&atItem->dim, &acElem->dim, &D_8015E420) == 1) { Vec3f atPos; Vec3f acPos; atPos.x = (atItem->dim.vtx[0].x + atItem->dim.vtx[1].x + atItem->dim.vtx[2].x) * (1.0f / 3); atPos.y = (atItem->dim.vtx[0].y + atItem->dim.vtx[1].y + atItem->dim.vtx[2].y) * (1.0f / 3); atPos.z = (atItem->dim.vtx[0].z + atItem->dim.vtx[1].z + atItem->dim.vtx[2].z) * (1.0f / 3); acPos.x = (acElem->dim.vtx[0].x + acElem->dim.vtx[1].x + acElem->dim.vtx[2].x) * (1.0f / 3); acPos.y = (acElem->dim.vtx[0].y + acElem->dim.vtx[1].y + acElem->dim.vtx[2].y) * (1.0f / 3); acPos.z = (acElem->dim.vtx[0].z + acElem->dim.vtx[1].z + acElem->dim.vtx[2].z) * (1.0f / 3); CollisionCheck_SetATvsAC(globalCtx, &at->base, &atItem->info, &atPos, &ac->base, &acElem->info, &acPos, &D_8015E420); return; } } } } } static s8 sBssDummy7; static s8 sBssDummy8; static s8 sBssDummy9; static s8 sBssDummy10; /** * AC overlap check. Calculates the center of each collider element and the point of contact. */ void CollisionCheck_AC_TrisVsQuad(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* colAT, Collider* colAC) { static Vec3f D_8015E430; static TriNorm D_8015E440; static TriNorm D_8015E478; ColliderTris* at = (ColliderTris*)colAT; ColliderTrisElement* atItem; ColliderQuad* ac = (ColliderQuad*)colAC; if (at->count > 0 && at->elements != NULL) { if (CollisionCheck_SkipBump(&ac->info) == 1) { return; } Math3D_TriNorm(&D_8015E440, &ac->dim.quad[2], &ac->dim.quad[3], &ac->dim.quad[1]); Math3D_TriNorm(&D_8015E478, &ac->dim.quad[1], &ac->dim.quad[0], &ac->dim.quad[2]); for (atItem = at->elements; atItem < at->elements + at->count; atItem++) { if (CollisionCheck_SkipTouch(&atItem->info) == 1) { continue; } if (CollisionCheck_NoSharedFlags(&atItem->info, &ac->info) == 1) { continue; } if (Math3D_TriVsTriIntersect(&D_8015E440, &atItem->dim, &D_8015E430) == 1 || Math3D_TriVsTriIntersect(&D_8015E478, &atItem->dim, &D_8015E430) == 1) { Vec3f atPos; Vec3f acPos; atPos.x = (atItem->dim.vtx[0].x + atItem->dim.vtx[1].x + atItem->dim.vtx[2].x) * (1.0f / 3); atPos.y = (atItem->dim.vtx[0].y + atItem->dim.vtx[1].y + atItem->dim.vtx[2].y) * (1.0f / 3); atPos.z = (atItem->dim.vtx[0].z + atItem->dim.vtx[1].z + atItem->dim.vtx[2].z) * (1.0f / 3); acPos.x = (ac->dim.quad[0].x + (ac->dim.quad[1].x + (ac->dim.quad[3].x + ac->dim.quad[2].x))) / 4.0f; acPos.y = (ac->dim.quad[0].y + (ac->dim.quad[1].y + (ac->dim.quad[3].y + ac->dim.quad[2].y))) / 4.0f; acPos.z = (ac->dim.quad[0].z + (ac->dim.quad[1].z + (ac->dim.quad[3].z + ac->dim.quad[2].z))) / 4.0f; CollisionCheck_SetATvsAC(globalCtx, &at->base, &atItem->info, &atPos, &ac->base, &ac->info, &acPos, &D_8015E430); return; } } } } /** * AC overlap check. Calculates the center of each collider element and the point of contact. */ void CollisionCheck_AC_QuadVsTris(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* colAT, Collider* colAC) { static Vec3f D_8015E4B0; static TriNorm D_8015E4C0; static TriNorm D_8015E4F8; ColliderQuad* at = (ColliderQuad*)colAT; ColliderTris* ac = (ColliderTris*)colAC; ColliderTrisElement* acElem; if (ac->count > 0 && ac->elements != NULL) { if (CollisionCheck_SkipTouch(&at->info) == 1) { return; } Math3D_TriNorm(&D_8015E4C0, &at->dim.quad[2], &at->dim.quad[3], &at->dim.quad[1]); Math3D_TriNorm(&D_8015E4F8, &at->dim.quad[1], &at->dim.quad[0], &at->dim.quad[2]); for (acElem = ac->elements; acElem < ac->elements + ac->count; acElem++) { if (CollisionCheck_SkipBump(&acElem->info) == 1) { continue; } if (CollisionCheck_NoSharedFlags(&at->info, &acElem->info) == 1) { continue; } if (Math3D_TriVsTriIntersect(&D_8015E4C0, &acElem->dim, &D_8015E4B0) == 1 || Math3D_TriVsTriIntersect(&D_8015E4F8, &acElem->dim, &D_8015E4B0) == 1) { if (Collider_QuadSetNearestAC(globalCtx, at, &D_8015E4B0)) { Vec3f atPos; Vec3f acPos; acPos.x = (acElem->dim.vtx[0].x + acElem->dim.vtx[1].x + acElem->dim.vtx[2].x) * (1.0f / 3); acPos.y = (acElem->dim.vtx[0].y + acElem->dim.vtx[1].y + acElem->dim.vtx[2].y) * (1.0f / 3); acPos.z = (acElem->dim.vtx[0].z + acElem->dim.vtx[1].z + acElem->dim.vtx[2].z) * (1.0f / 3); atPos.x = (at->dim.quad[0].x + (at->dim.quad[1].x + (at->dim.quad[3].x + at->dim.quad[2].x))) / 4.0f; atPos.y = (at->dim.quad[0].y + (at->dim.quad[1].y + (at->dim.quad[3].y + at->dim.quad[2].y))) / 4.0f; atPos.z = (at->dim.quad[0].z + (at->dim.quad[1].z + (at->dim.quad[3].z + at->dim.quad[2].z))) / 4.0f; CollisionCheck_SetATvsAC(globalCtx, &at->base, &at->info, &atPos, &ac->base, &acElem->info, &acPos, &D_8015E4B0); return; } } } } } /** * AC overlap check. Calculates the center of each collider element and the point of contact. */ void CollisionCheck_AC_QuadVsQuad(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* colAT, Collider* colAC) { static TriNorm D_8015E530[2]; static Vec3f D_8015E598; static TriNorm D_8015E5A8[2]; ColliderQuad* at = (ColliderQuad*)colAT; ColliderQuad* ac = (ColliderQuad*)colAC; s32 i; s32 j; if (CollisionCheck_SkipTouch(&at->info) == 1) { return; } if (CollisionCheck_SkipBump(&ac->info) == 1) { return; } if (CollisionCheck_NoSharedFlags(&at->info, &ac->info) == 1) { return; } Math3D_TriNorm(&D_8015E5A8[0], &at->dim.quad[2], &at->dim.quad[3], &at->dim.quad[1]); Math3D_TriNorm(&D_8015E5A8[1], &at->dim.quad[2], &at->dim.quad[1], &at->dim.quad[0]); Math3D_TriNorm(&D_8015E530[0], &ac->dim.quad[2], &ac->dim.quad[3], &ac->dim.quad[1]); Math3D_TriNorm(&D_8015E530[1], &ac->dim.quad[2], &ac->dim.quad[1], &ac->dim.quad[0]); for (i = 0; i < 2; i++) { for (j = 0; j < 2; j++) { if (Math3D_TriVsTriIntersect(&D_8015E5A8[j], &D_8015E530[i], &D_8015E598) == 1) { if (Collider_QuadSetNearestAC(globalCtx, at, &D_8015E598)) { Vec3f atPos; Vec3f acPos; atPos.x = (at->dim.quad[0].x + (at->dim.quad[1].x + (at->dim.quad[3].x + at->dim.quad[2].x))) / 4.0f; atPos.y = (at->dim.quad[0].y + (at->dim.quad[1].y + (at->dim.quad[3].y + at->dim.quad[2].y))) / 4.0f; atPos.z = (at->dim.quad[0].z + (at->dim.quad[1].z + (at->dim.quad[3].z + at->dim.quad[2].z))) / 4.0f; acPos.x = (ac->dim.quad[0].x + (ac->dim.quad[1].x + (ac->dim.quad[3].x + ac->dim.quad[2].x))) / 4.0f; acPos.y = (ac->dim.quad[0].y + (ac->dim.quad[1].y + (ac->dim.quad[3].y + ac->dim.quad[2].y))) / 4.0f; acPos.z = (ac->dim.quad[0].z + (ac->dim.quad[1].z + (ac->dim.quad[3].z + ac->dim.quad[2].z))) / 4.0f; CollisionCheck_SetATvsAC(globalCtx, &at->base, &at->info, &atPos, &ac->base, &ac->info, &acPos, &D_8015E598); return; } } } } } /** * Sets a ColliderJntSph's hit effects */ void CollisionCheck_SetJntSphHitFX(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* collider) { ColliderJntSph* jntSph = (ColliderJntSph*)collider; ColliderJntSphElement* element; Vec3f hitPos; for (element = jntSph->elements; element < jntSph->elements + jntSph->count; element++) { if ((element->info.bumperFlags & BUMP_DRAW_HITMARK) && (element->info.acHitInfo != NULL) && !(element->info.acHitInfo->toucherFlags & TOUCH_DREW_HITMARK)) { Math_Vec3s_ToVec3f(&hitPos, &element->info.bumper.hitPos); CollisionCheck_HitEffects(globalCtx, element->info.acHit, element->info.acHitInfo, &jntSph->base, &element->info, &hitPos); element->info.acHitInfo->toucherFlags |= TOUCH_DREW_HITMARK; return; } } } /** * Sets a ColliderCylinder's hit effects */ void CollisionCheck_SetCylHitFX(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* collider) { ColliderCylinder* cylinder = (ColliderCylinder*)collider; Vec3f hitPos; if ((cylinder->info.bumperFlags & BUMP_DRAW_HITMARK) && (cylinder->info.acHitInfo != NULL) && !(cylinder->info.acHitInfo->toucherFlags & TOUCH_DREW_HITMARK)) { Math_Vec3s_ToVec3f(&hitPos, &cylinder->info.bumper.hitPos); CollisionCheck_HitEffects(globalCtx, cylinder->info.acHit, cylinder->info.acHitInfo, &cylinder->base, &cylinder->info, &hitPos); cylinder->info.acHitInfo->toucherFlags |= TOUCH_DREW_HITMARK; } } /** * Sets a ColliderTris's hit effects */ void CollisionCheck_SetTrisHitFX(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* collider) { ColliderTris* tris = (ColliderTris*)collider; ColliderTrisElement* element; Vec3f hitPos; for (element = tris->elements; element < tris->elements + tris->count; element++) { if ((element->info.bumperFlags & BUMP_DRAW_HITMARK) && (element->info.acHitInfo != NULL) && !(element->info.acHitInfo->toucherFlags & TOUCH_DREW_HITMARK)) { Math_Vec3s_ToVec3f(&hitPos, &element->info.bumper.hitPos); CollisionCheck_HitEffects(globalCtx, element->info.acHit, element->info.acHitInfo, &tris->base, &element->info, &hitPos); element->info.acHitInfo->toucherFlags |= TOUCH_DREW_HITMARK; return; } } } /** * Sets a ColliderQuad's hit effects */ void CollisionCheck_SetQuadHitFX(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* collider) { ColliderQuad* quad = (ColliderQuad*)collider; Vec3f hitPos; if ((quad->info.bumperFlags & BUMP_DRAW_HITMARK) && (quad->info.acHitInfo != NULL) && !(quad->info.acHitInfo->toucherFlags & TOUCH_DREW_HITMARK)) { Math_Vec3s_ToVec3f(&hitPos, &quad->info.bumper.hitPos); CollisionCheck_HitEffects(globalCtx, quad->info.acHit, quad->info.acHitInfo, &quad->base, &quad->info, &hitPos); quad->info.acHitInfo->toucherFlags |= TOUCH_DREW_HITMARK; } } static ColChkApplyFunc sColChkApplyFuncs[] = { CollisionCheck_SetJntSphHitFX, CollisionCheck_SetCylHitFX, CollisionCheck_SetTrisHitFX, CollisionCheck_SetQuadHitFX, }; /** * Handles hit effects for each AC collider that had an AC collision. Spawns hitmarks and plays sound effects. */ void CollisionCheck_SetHitEffects(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx) { Collider** col; for (col = colChkCtx->colAC; col < colChkCtx->colAC + colChkCtx->colACCount; col++) { Collider* colAC = *col; if (colAC != NULL && colAC->acFlags & AC_ON) { if (colAC->actor != NULL && colAC->actor->update == NULL) { continue; } sColChkApplyFuncs[colAC->shape](globalCtx, colChkCtx, colAC); } } } static ColChkVsFunc sACVsFuncs[4][4] = { { CollisionCheck_AC_JntSphVsJntSph, CollisionCheck_AC_JntSphVsCyl, CollisionCheck_AC_JntSphVsTris, CollisionCheck_AC_JntSphVsQuad }, { CollisionCheck_AC_CylVsJntSph, CollisionCheck_AC_CylVsCyl, CollisionCheck_AC_CylVsTris, CollisionCheck_AC_CylVsQuad }, { CollisionCheck_AC_TrisVsJntSph, CollisionCheck_AC_TrisVsCyl, CollisionCheck_AC_TrisVsTris, CollisionCheck_AC_TrisVsQuad }, { CollisionCheck_AC_QuadVsJntSph, CollisionCheck_AC_QuadVsCyl, CollisionCheck_AC_QuadVsTris, CollisionCheck_AC_QuadVsQuad }, }; /** * Iterates through all AC colliders, performing AC collisions with the AT collider. */ void CollisionCheck_AC(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* colAT) { Collider** col; for (col = colChkCtx->colAC; col < colChkCtx->colAC + colChkCtx->colACCount; col++) { Collider* colAC = *col; if (colAC != NULL && colAC->acFlags & AC_ON) { if (colAC->actor != NULL && colAC->actor->update == NULL) { continue; } if ((colAC->acFlags & colAT->atFlags & AC_TYPE_ALL) && (colAT != colAC)) { if (!(colAT->atFlags & AT_SELF) && colAT->actor != NULL && colAC->actor == colAT->actor) { continue; } sACVsFuncs[colAT->shape][colAC->shape](globalCtx, colChkCtx, colAT, colAC); } } } } /** * Iterates through all AT colliders, testing them for AC collisions with each AC collider, setting the info regarding * the collision for each AC and AT collider that collided. Then spawns hitmarks and plays sound effects for each * successful collision. To collide, an AT collider must share a type (AC_TYPE_PLAYER, AC_TYPE_ENEMY, or AC_TYPE_OTHER) * with the AC collider and the toucher and bumper elements that overlapped must share a dmgFlag. */ void CollisionCheck_AT(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx) { Collider** col; if (colChkCtx->colATCount == 0 || colChkCtx->colACCount == 0) { return; } for (col = colChkCtx->colAT; col < colChkCtx->colAT + colChkCtx->colATCount; col++) { Collider* colAT = *col; if (colAT != NULL && colAT->atFlags & AT_ON) { if (colAT->actor != NULL && colAT->actor->update == NULL) { continue; } CollisionCheck_AC(globalCtx, colChkCtx, colAT); } } CollisionCheck_SetHitEffects(globalCtx, colChkCtx); } /** * Get mass type. Immobile colliders cannot be pushed, while heavy colliders can only be pushed by heavy and immobile * colliders. */ s32 CollisionCheck_GetMassType(u8 mass) { if (mass == MASS_IMMOVABLE) { return MASSTYPE_IMMOVABLE; } if (mass == MASS_HEAVY) { return MASSTYPE_HEAVY; } return MASSTYPE_NORMAL; } /** * Sets OC collision flags for OC collider overlaps. If both colliders are attached to actors and can push, * also performs an elastic collision where both colliders are moved apart in proportion to their masses. */ void CollisionCheck_SetOCvsOC(Collider* left, ColliderInfo* leftInfo, Vec3f* leftPos, Collider* right, ColliderInfo* rightInfo, Vec3f* rightPos, f32 overlap) { f32 pad; f32 leftDispRatio; f32 rightDispRatio; f32 xzDist; f32 leftMass; f32 rightMass; f32 totalMass; f32 inverseTotalMass; f32 xDelta; f32 zDelta; Actor* leftActor = left->actor; Actor* rightActor = right->actor; s32 leftMassType; s32 rightMassType; left->ocFlags1 |= OC1_HIT; left->oc = rightActor; leftInfo->ocElemFlags |= OCELEM_HIT; if (right->ocFlags2 & OC2_TYPE_PLAYER) { left->ocFlags2 |= OC2_HIT_PLAYER; } right->oc = leftActor; right->ocFlags1 |= OC1_HIT; rightInfo->ocElemFlags |= OCELEM_HIT; if (left->ocFlags2 & OC2_TYPE_PLAYER) { right->ocFlags2 |= OC2_HIT_PLAYER; } if (leftActor == NULL || rightActor == NULL || left->ocFlags1 & OC1_NO_PUSH || right->ocFlags1 & OC1_NO_PUSH) { return; } rightMassType = CollisionCheck_GetMassType(leftActor->colChkInfo.mass); leftMassType = CollisionCheck_GetMassType(rightActor->colChkInfo.mass); leftMass = leftActor->colChkInfo.mass; rightMass = rightActor->colChkInfo.mass; totalMass = leftMass + rightMass; if (IS_ZERO(totalMass)) { leftMass = rightMass = 1.0f; totalMass = 2.0f; } xDelta = rightPos->x - leftPos->x; zDelta = rightPos->z - leftPos->z; xzDist = sqrtf(SQ(xDelta) + SQ(zDelta)); if (rightMassType == MASSTYPE_IMMOVABLE) { if (leftMassType == MASSTYPE_IMMOVABLE) { return; } else { // leftMassType == MASS_HEAVY | MASS_NORMAL leftDispRatio = 0; rightDispRatio = 1; } } else if (rightMassType == MASSTYPE_HEAVY) { if (leftMassType == MASSTYPE_IMMOVABLE) { leftDispRatio = 1; rightDispRatio = 0; } else if (leftMassType == MASSTYPE_HEAVY) { leftDispRatio = 0.5f; rightDispRatio = 0.5f; } else { // leftMassType == MASS_NORMAL leftDispRatio = 0; rightDispRatio = 1; } } else { // rightMassType == MASS_NORMAL if (leftMassType == MASSTYPE_NORMAL) { inverseTotalMass = 1 / totalMass; leftDispRatio = rightMass * inverseTotalMass; rightDispRatio = leftMass * inverseTotalMass; } else { // leftMassType == MASS_HEAVY | MASS_IMMOVABLE leftDispRatio = 1; rightDispRatio = 0; } } if (!IS_ZERO(xzDist)) { xDelta *= overlap / xzDist; zDelta *= overlap / xzDist; leftActor->colChkInfo.displacement.x += -xDelta * leftDispRatio; leftActor->colChkInfo.displacement.z += -zDelta * leftDispRatio; rightActor->colChkInfo.displacement.x += xDelta * rightDispRatio; rightActor->colChkInfo.displacement.z += zDelta * rightDispRatio; } else if (!(overlap == 0.0f)) { leftActor->colChkInfo.displacement.x += -overlap * leftDispRatio; rightActor->colChkInfo.displacement.x += overlap * rightDispRatio; } else { leftActor->colChkInfo.displacement.x -= leftDispRatio; rightActor->colChkInfo.displacement.x += rightDispRatio; } } /** * OC overlap check for two JntSphs */ void CollisionCheck_OC_JntSphVsJntSph(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* l, Collider* r) { ColliderJntSph* left = (ColliderJntSph*)l; ColliderJntSphElement* leftElem; ColliderJntSph* right = (ColliderJntSph*)r; ColliderJntSphElement* rightElem; f32 overlap; if (left->count > 0 && left->elements != NULL && right->count > 0 && right->elements != NULL) { for (leftElem = left->elements; leftElem < left->elements + left->count; leftElem++) { if (!(leftElem->info.ocElemFlags & OCELEM_ON)) { continue; } for (rightElem = right->elements; rightElem < right->elements + right->count; rightElem++) { if (!(rightElem->info.ocElemFlags & OCELEM_ON)) { continue; } if (Math3D_SphVsSphOverlap(&leftElem->dim.worldSphere, &rightElem->dim.worldSphere, &overlap) == 1) { Vec3f leftPos; Vec3f rightPos; Math_Vec3s_ToVec3f(&leftPos, &leftElem->dim.worldSphere.center); Math_Vec3s_ToVec3f(&rightPos, &rightElem->dim.worldSphere.center); CollisionCheck_SetOCvsOC(&left->base, &leftElem->info, &leftPos, &right->base, &rightElem->info, &rightPos, overlap); } } } } } /** * OC overlap check for a JntSph and Cylinder */ void CollisionCheck_OC_JntSphVsCyl(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* l, Collider* r) { ColliderJntSph* left = (ColliderJntSph*)l; ColliderJntSphElement* leftElem; ColliderCylinder* right = (ColliderCylinder*)r; f32 overlap; if (left->count > 0 && left->elements != NULL) { if ((right->base.ocFlags1 & OC1_ON) && (right->info.ocElemFlags & OCELEM_ON)) { for (leftElem = left->elements; leftElem < left->elements + left->count; leftElem++) { if (!(leftElem->info.ocElemFlags & OCELEM_ON)) { continue; } if (Math3D_SphVsCylOverlapDist(&leftElem->dim.worldSphere, &right->dim, &overlap) == 1) { Vec3f leftPos; Vec3f rightPos; Math_Vec3s_ToVec3f(&leftPos, &leftElem->dim.worldSphere.center); Math_Vec3s_ToVec3f(&rightPos, &right->dim.pos); CollisionCheck_SetOCvsOC(&left->base, &leftElem->info, &leftPos, &right->base, &right->info, &rightPos, overlap); } } } } } /** * OC overlap check for a Cylinder and JntSph */ void CollisionCheck_OC_CylVsJntSph(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* l, Collider* r) { CollisionCheck_OC_JntSphVsCyl(globalCtx, colChkCtx, r, l); } /** * OC overlap check for two Cylinders */ void CollisionCheck_OC_CylVsCyl(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* l, Collider* r) { ColliderCylinder* left = (ColliderCylinder*)l; ColliderCylinder* right = (ColliderCylinder*)r; f32 deadSpace; if ((left->base.ocFlags1 & OC1_ON) && (right->base.ocFlags1 & OC1_ON)) { if ((left->info.ocElemFlags & OCELEM_ON) && (right->info.ocElemFlags & OCELEM_ON)) { if (Math3D_CylOutsideCyl(&left->dim, &right->dim, &deadSpace) == 1) { Vec3f leftPos; Vec3f rightPos; Math_Vec3s_ToVec3f(&leftPos, &left->dim.pos); Math_Vec3s_ToVec3f(&rightPos, &right->dim.pos); CollisionCheck_SetOCvsOC(&left->base, &left->info, &leftPos, &right->base, &right->info, &rightPos, deadSpace); } } } } /** * Skip any OC colliders that are off */ s32 CollisionCheck_SkipOC(Collider* collider) { if (!(collider->ocFlags1 & OC1_ON)) { return 1; } return 0; } /** * Checks for OC compatibility. There are three conditions: * First, each collider must have an OC flag corresponding to the other's OC type. * Second, OC2_UNK1 and OC2_UNK2 can't collide with each other (has something to do with horses?) * Third, the colliders can't collide if they belong to the same actor */ s32 CollisionCheck_Incompatible(Collider* left, Collider* right) { if (!(left->ocFlags1 & right->ocFlags2 & OC1_TYPE_ALL) || !(left->ocFlags2 & right->ocFlags1 & OC1_TYPE_ALL) || ((left->ocFlags2 & OC2_UNK1) && (right->ocFlags2 & OC2_UNK2)) || ((right->ocFlags2 & OC2_UNK1) && (left->ocFlags2 & OC2_UNK2))) { return 1; } if (left->actor == right->actor) { return 1; } return 0; } static ColChkVsFunc sOCVsFuncs[4][4] = { { CollisionCheck_OC_JntSphVsJntSph, CollisionCheck_OC_JntSphVsCyl, NULL, NULL }, { CollisionCheck_OC_CylVsJntSph, CollisionCheck_OC_CylVsCyl, NULL, NULL }, { NULL, NULL, NULL, NULL }, { NULL, NULL, NULL, NULL }, }; /** * Iterates through all OC colliders and collides them with all subsequent OC colliders on the list. During an OC * collision, colliders with overlapping elements move away from each other so that their elements no longer overlap. * The relative amount each collider is pushed is determined by the collider's mass. Only JntSph and Cylinder colliders * can collide, and each collider must have the OC flag corresponding to the other's OC type. Additionally, OC2_UNK1 * cannot collide with OC2_UNK2, nor can two colliders that share an actor. */ void CollisionCheck_OC(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx) { Collider** left; Collider** right; ColChkVsFunc vsFunc; for (left = colChkCtx->colOC; left < colChkCtx->colOC + colChkCtx->colOCCount; left++) { if (*left == NULL || CollisionCheck_SkipOC(*left) == 1) { continue; } for (right = left + 1; right < colChkCtx->colOC + colChkCtx->colOCCount; right++) { if (*right == NULL || CollisionCheck_SkipOC(*right) == 1 || CollisionCheck_Incompatible(*left, *right) == 1) { continue; } vsFunc = sOCVsFuncs[(*left)->shape][(*right)->shape]; if (vsFunc == NULL) { // "Not compatible" osSyncPrintf("CollisionCheck_OC():未対応 %d, %d\n", (*left)->shape, (*right)->shape); continue; } vsFunc(globalCtx, colChkCtx, *left, *right); } } } /** * Initializes CollisionCheckInfo to default values */ void CollisionCheck_InitInfo(CollisionCheckInfo* info) { static CollisionCheckInfo init = { NULL, { 0.0f, 0.0f, 0.0f }, 10, 10, 0, 50, 8, 0, 0, 0, 0, }; *info = init; } /** * Resets ColisionCheckInfo fields other than DamageTable, mass, and dim. */ void CollisionCheck_ResetDamage(CollisionCheckInfo* info) { info->damage = 0; info->damageEffect = 0; info->atHitEffect = 0; info->acHitEffect = 0; info->displacement.x = info->displacement.y = info->displacement.z = 0.0f; } /** * Sets up CollisionCheckInfo using the values in init. Does not set a damage table or the unused unk_14. * Unused, as all actors that don't set a damage table set their CollisionCheckInfo manually */ void CollisionCheck_SetInfoNoDamageTable(CollisionCheckInfo* info, CollisionCheckInfoInit* init) { info->health = init->health; info->cylRadius = init->cylRadius; info->cylHeight = init->cylHeight; info->mass = init->mass; } /** * Sets up CollisionCheckInfo using the values in init. Does not set the unused unk_14 */ void CollisionCheck_SetInfo(CollisionCheckInfo* info, DamageTable* damageTable, CollisionCheckInfoInit* init) { info->health = init->health; info->damageTable = damageTable; info->cylRadius = init->cylRadius; info->cylHeight = init->cylHeight; info->mass = init->mass; } /** * Sets up CollisionCheckInfo using the values in init. Sets the unused unk_14 */ void CollisionCheck_SetInfo2(CollisionCheckInfo* info, DamageTable* damageTable, CollisionCheckInfoInit2* init) { info->health = init->health; info->damageTable = damageTable; info->cylRadius = init->cylRadius; info->cylHeight = init->cylHeight; info->cylYShift = init->cylYShift; info->mass = init->mass; } /** * Sets up CollisionCheckInfo using the values in Init and a preset damage table. Sets the unused unk_14. * Unused, as all actors that use a preset damage table set their CollisionCheckInfo manually. */ void CollisionCheck_SetInfoGetDamageTable(CollisionCheckInfo* info, s32 index, CollisionCheckInfoInit2* init) { CollisionCheck_SetInfo2(info, DamageTable_Get(index), init); } /** * Apply AC damage effect */ void CollisionCheck_ApplyDamage(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* collider, ColliderInfo* info) { DamageTable* tbl; f32 damage; if (collider->actor == NULL || !(collider->acFlags & AC_HIT)) { return; } if (!(info->bumperFlags & BUMP_HIT) || info->bumperFlags & BUMP_NO_DAMAGE) { return; } ASSERT(info->acHitInfo != NULL, "pclobj_elem->ac_hit_elem != NULL", "../z_collision_check.c", 6493); tbl = collider->actor->colChkInfo.damageTable; if (tbl == NULL) { damage = (f32)info->acHitInfo->toucher.damage - info->bumper.defense; if (damage < 0) { damage = 0; } } else { s32 i; u32 flags = info->acHitInfo->toucher.dmgFlags; for (i = 0; i < 0x20; i++, flags >>= 1) { if (flags == 1) { break; } } damage = tbl->table[i] & 0xF; collider->actor->colChkInfo.damageEffect = tbl->table[i] >> 4 & 0xF; } if (!(collider->acFlags & AC_HARD)) { collider->actor->colChkInfo.damage += damage; } } /** * Apply ColliderJntSph AC damage effect */ void CollisionCheck_ApplyDamageJntSph(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* collider) { ColliderJntSph* jntSph = (ColliderJntSph*)collider; s32 i; if (jntSph->count > 0 && jntSph->elements != NULL) { for (i = 0; i < jntSph->count; i++) { CollisionCheck_ApplyDamage(globalCtx, colChkCtx, &jntSph->base, &jntSph->elements[i].info); } } } /** * Apply ColliderCylinder AC damage effect */ void CollisionCheck_ApplyDamageCyl(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* collider) { ColliderCylinder* cylinder = (ColliderCylinder*)collider; CollisionCheck_ApplyDamage(globalCtx, colChkCtx, &cylinder->base, &cylinder->info); } /** * Apply ColliderTris AC damage effect */ void CollisionCheck_ApplyDamageTris(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* collider) { ColliderTris* tris = (ColliderTris*)collider; s32 i; for (i = 0; i < tris->count; i++) { CollisionCheck_ApplyDamage(globalCtx, colChkCtx, collider, &tris->elements[i].info); } } /** * Apply ColliderQuad AC damage effect */ void CollisionCheck_ApplyDamageQuad(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* collider) { ColliderQuad* quad = (ColliderQuad*)collider; CollisionCheck_ApplyDamage(globalCtx, colChkCtx, &quad->base, &quad->info); } static ColChkApplyFunc sApplyDamageFuncs[4] = { CollisionCheck_ApplyDamageJntSph, CollisionCheck_ApplyDamageCyl, CollisionCheck_ApplyDamageTris, CollisionCheck_ApplyDamageQuad, }; /** * For all AC colliders, sets any damage effects from collisions with AT colliders to their corresponding actor's * CollisionCheckInfo. */ void CollisionCheck_Damage(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx) { s32 i; for (i = 0; i < colChkCtx->colACCount; i++) { Collider* collider = colChkCtx->colAC[i]; if (collider == NULL) { continue; } if (collider->acFlags & AC_NO_DAMAGE) { continue; } sApplyDamageFuncs[collider->shape](globalCtx, colChkCtx, collider); } } /** * Checks if the line ab intersects any of the ColliderJntSph's elements */ s32 CollisionCheck_LineOC_JntSph(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* collider, Vec3f* a, Vec3f* b) { static Linef D_8015E610; ColliderJntSph* jntSph = (ColliderJntSph*)collider; s32 i; for (i = 0; i < jntSph->count; i++) { ColliderJntSphElement* element = &jntSph->elements[i]; if (!(element->info.ocElemFlags & OCELEM_ON)) { continue; } D_8015E610.a = *a; D_8015E610.b = *b; if (Math3D_LineVsSph(&element->dim.worldSphere, &D_8015E610) == 1) { return true; } } return false; } /** * Checks if the line segment ab intersects the ColliderCylinder */ s32 CollisionCheck_LineOC_Cyl(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Collider* collider, Vec3f* a, Vec3f* b) { static Vec3f D_8015E628; static Vec3f D_8015E638; ColliderCylinder* cylinder = (ColliderCylinder*)collider; if (!(cylinder->info.ocElemFlags & OCELEM_ON)) { return false; } if (Math3D_CylVsLineSeg(&cylinder->dim, a, b, &D_8015E628, &D_8015E638) != 0) { return true; } return false; } static ColChkLineFunc sOCLineCheckFuncs[4] = { CollisionCheck_LineOC_JntSph, CollisionCheck_LineOC_Cyl, NULL, NULL, }; /** * Checks if the line segment ab intersects any OC colliders, excluding those attached to actors * on the exclusion list. Returns true if there are any intersections and false otherwise. */ s32 CollisionCheck_LineOC(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Vec3f* a, Vec3f* b, Actor** exclusions, s32 numExclusions) { ColChkLineFunc lineCheck; Collider** col; s32 i; s32 exclude; s32 result = 0; for (col = colChkCtx->colOC; col < colChkCtx->colOC + colChkCtx->colOCCount; col++) { if (CollisionCheck_SkipOC(*col) == 1) { continue; } exclude = 0; for (i = 0; i < numExclusions; i++) { if ((*col)->actor == exclusions[i]) { exclude = 1; break; } } if (exclude == 1) { continue; } lineCheck = sOCLineCheckFuncs[(*col)->shape]; if (lineCheck == NULL) { // "type %d not supported" osSyncPrintf("CollisionCheck_generalLineOcCheck():未対応 %dタイプ\n", (*col)->shape); } else { result = lineCheck(globalCtx, colChkCtx, (*col), a, b); if (result) { break; } } } return result; } /** * Checks if the line segment ab intersects any OC colliders. Returns true if there are any intersections and false * otherwise. Unused. */ s32 CollisionCheck_LineOCCheckAll(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Vec3f* a, Vec3f* b) { return CollisionCheck_LineOC(globalCtx, colChkCtx, a, b, NULL, 0); } /** * Checks if the line segment ab intersects any OC colliders, excluding those attached to actors on the exclusion list. * Returns true if there are any intersections and false otherwise. */ s32 CollisionCheck_LineOCCheck(GlobalContext* globalCtx, CollisionCheckContext* colChkCtx, Vec3f* a, Vec3f* b, Actor** exclusions, s32 numExclusions) { return CollisionCheck_LineOC(globalCtx, colChkCtx, a, b, exclusions, numExclusions); } /** * Moves the ColliderCylinder's position to the actor's position */ void Collider_UpdateCylinder(Actor* actor, ColliderCylinder* collider) { collider->dim.pos.x = actor->world.pos.x; collider->dim.pos.y = actor->world.pos.y; collider->dim.pos.z = actor->world.pos.z; } /** * Sets the ColliderCylinder's position */ void Collider_SetCylinderPosition(ColliderCylinder* collider, Vec3s* pos) { collider->dim.pos.x = pos->x; collider->dim.pos.y = pos->y; collider->dim.pos.z = pos->z; } /** * Sets the ColliderQuad's vertices */ void Collider_SetQuadVertices(ColliderQuad* collider, Vec3f* a, Vec3f* b, Vec3f* c, Vec3f* d) { Math_Vec3f_Copy(&collider->dim.quad[2], c); Math_Vec3f_Copy(&collider->dim.quad[3], d); Math_Vec3f_Copy(&collider->dim.quad[0], a); Math_Vec3f_Copy(&collider->dim.quad[1], b); Collider_SetQuadMidpoints(&collider->dim); } /** * Sets the specified ColliderTrisElement's vertices */ void Collider_SetTrisVertices(ColliderTris* collider, s32 index, Vec3f* a, Vec3f* b, Vec3f* c) { ColliderTrisElement* element = &collider->elements[index]; f32 nx; f32 ny; f32 nz; f32 originDist; Math_Vec3f_Copy(&element->dim.vtx[0], a); Math_Vec3f_Copy(&element->dim.vtx[1], b); Math_Vec3f_Copy(&element->dim.vtx[2], c); Math3D_DefPlane(a, b, c, &nx, &ny, &nz, &originDist); element->dim.plane.normal.x = nx; element->dim.plane.normal.y = ny; element->dim.plane.normal.z = nz; element->dim.plane.originDist = originDist; } /** * Sets the specified ColliderTrisElement's dim using the values in src */ void Collider_SetTrisDim(GlobalContext* globalCtx, ColliderTris* collider, s32 index, ColliderTrisElementDimInit* src) { ColliderTrisElement* element = &collider->elements[index]; Collider_SetTrisElementDim(globalCtx, &element->dim, src); } // Due to an unknown reason, bss ordering changed between the 2 static Vec3f variables in the function below. // In order to reproduce this behavior, we need a specific number of bss variables in the file before that point. // For this, we introduce a certain amount of dummy variables throughout the file, which we fit inside padding added // by the compiler between structs like TriNorm and/or Vec3f, so they don't take space in bss. static s8 sBssDummy11; static s8 sBssDummy12; static s8 sBssDummy13; static s8 sBssDummy14; /** * Updates the world spheres for all of the collider's JntSph elements attached to the specified limb */ void Collider_UpdateSpheres(s32 limb, ColliderJntSph* collider) { static Vec3f D_8015E648; static Vec3f D_8015CF00; // bss ordering changes here s32 i; for (i = 0; i < collider->count; i++) { if (limb == collider->elements[i].dim.limb) { D_8015E648.x = collider->elements[i].dim.modelSphere.center.x; D_8015E648.y = collider->elements[i].dim.modelSphere.center.y; D_8015E648.z = collider->elements[i].dim.modelSphere.center.z; Matrix_MultVec3f(&D_8015E648, &D_8015CF00); collider->elements[i].dim.worldSphere.center.x = D_8015CF00.x; collider->elements[i].dim.worldSphere.center.y = D_8015CF00.y; collider->elements[i].dim.worldSphere.center.z = D_8015CF00.z; collider->elements[i].dim.worldSphere.radius = collider->elements[i].dim.modelSphere.radius * collider->elements[i].dim.scale; } } } /** * Spawns red blood droplets. * No actor has a collision type that spawns red blood. */ void CollisionCheck_SpawnRedBlood(GlobalContext* globalCtx, Vec3f* v) { static EffectSparkInit D_8015CF10; s32 effectIndex; D_8015CF10.position.x = v->x; D_8015CF10.position.y = v->y; D_8015CF10.position.z = v->z; D_8015CF10.uDiv = 5; D_8015CF10.vDiv = 5; D_8015CF10.colorStart[0].r = 128; D_8015CF10.colorStart[0].g = 0; D_8015CF10.colorStart[0].b = 64; D_8015CF10.colorStart[0].a = 255; D_8015CF10.colorStart[1].r = 128; D_8015CF10.colorStart[1].g = 0; D_8015CF10.colorStart[1].b = 64; D_8015CF10.colorStart[1].a = 255; D_8015CF10.colorStart[2].r = 255; D_8015CF10.colorStart[2].g = 128; D_8015CF10.colorStart[2].b = 0; D_8015CF10.colorStart[2].a = 255; D_8015CF10.colorStart[3].r = 255; D_8015CF10.colorStart[3].g = 128; D_8015CF10.colorStart[3].b = 0; D_8015CF10.colorStart[3].a = 255; D_8015CF10.colorEnd[0].r = 64; D_8015CF10.colorEnd[0].g = 0; D_8015CF10.colorEnd[0].b = 32; D_8015CF10.colorEnd[0].a = 0; D_8015CF10.colorEnd[1].r = 64; D_8015CF10.colorEnd[1].g = 0; D_8015CF10.colorEnd[1].b = 32; D_8015CF10.colorEnd[1].a = 0; D_8015CF10.colorEnd[2].r = 128; D_8015CF10.colorEnd[2].g = 0; D_8015CF10.colorEnd[2].b = 64; D_8015CF10.colorEnd[2].a = 0; D_8015CF10.colorEnd[3].r = 128; D_8015CF10.colorEnd[3].g = 0; D_8015CF10.colorEnd[3].b = 64; D_8015CF10.colorEnd[3].a = 0; D_8015CF10.timer = 0; D_8015CF10.duration = 16; D_8015CF10.speed = 8.0f; D_8015CF10.gravity = -1.0f; Effect_Add(globalCtx, &effectIndex, EFFECT_SPARK, 0, 1, &D_8015CF10); } /** * Spawns water droplets. * No actor has a collision type that spawns water droplets. */ void CollisionCheck_SpawnWaterDroplets(GlobalContext* globalCtx, Vec3f* v) { static EffectSparkInit D_8015D3D8; s32 effectIndex; D_8015D3D8.position.x = v->x; D_8015D3D8.position.y = v->y; D_8015D3D8.position.z = v->z; D_8015D3D8.uDiv = 5; D_8015D3D8.vDiv = 5; D_8015D3D8.colorStart[0].r = 255; D_8015D3D8.colorStart[0].g = 255; D_8015D3D8.colorStart[0].b = 255; D_8015D3D8.colorStart[0].a = 255; D_8015D3D8.colorStart[1].r = 100; D_8015D3D8.colorStart[1].g = 100; D_8015D3D8.colorStart[1].b = 100; D_8015D3D8.colorStart[1].a = 100; D_8015D3D8.colorStart[2].r = 100; D_8015D3D8.colorStart[2].g = 100; D_8015D3D8.colorStart[2].b = 100; D_8015D3D8.colorStart[2].a = 100; D_8015D3D8.colorStart[3].r = 100; D_8015D3D8.colorStart[3].g = 100; D_8015D3D8.colorStart[3].b = 100; D_8015D3D8.colorStart[3].a = 100; D_8015D3D8.colorEnd[0].r = 50; D_8015D3D8.colorEnd[0].g = 50; D_8015D3D8.colorEnd[0].b = 50; D_8015D3D8.colorEnd[0].a = 50; D_8015D3D8.colorEnd[1].r = 50; D_8015D3D8.colorEnd[1].g = 50; D_8015D3D8.colorEnd[1].b = 50; D_8015D3D8.colorEnd[1].a = 50; D_8015D3D8.colorEnd[2].r = 50; D_8015D3D8.colorEnd[2].g = 50; D_8015D3D8.colorEnd[2].b = 50; D_8015D3D8.colorEnd[2].a = 50; D_8015D3D8.colorEnd[3].r = 0; D_8015D3D8.colorEnd[3].g = 0; D_8015D3D8.colorEnd[3].b = 0; D_8015D3D8.colorEnd[3].a = 0; D_8015D3D8.timer = 0; D_8015D3D8.duration = 16; D_8015D3D8.speed = 8.0f; D_8015D3D8.gravity = -1.0f; Effect_Add(globalCtx, &effectIndex, EFFECT_SPARK, 0, 1, &D_8015D3D8); } /** * Spawns streaks of light from hits against solid objects */ void CollisionCheck_SpawnShieldParticles(GlobalContext* globalCtx, Vec3f* v) { static EffectShieldParticleInit initMetal = { 16, { 0, 0, 0 }, { 0, 200, 255, 255 }, { 255, 255, 255, 255 }, { 255, 255, 128, 255 }, { 255, 255, 0, 255 }, { 255, 64, 0, 200 }, { 255, 0, 0, 255 }, 2.1f, 35.0f, 30.0f, 8, { 0, 0, 0, { 0, 128, 255 }, false, 300 }, true, }; s32 effectIndex; initMetal.position.x = v->x; initMetal.position.y = v->y; initMetal.position.z = v->z; initMetal.lightPoint.x = initMetal.position.x; initMetal.lightPoint.y = initMetal.position.y; initMetal.lightPoint.z = initMetal.position.z; Effect_Add(globalCtx, &effectIndex, EFFECT_SHIELD_PARTICLE, 0, 1, &initMetal); } /** * Spawns streaks of light and makes a metallic sound */ void CollisionCheck_SpawnShieldParticlesMetal(GlobalContext* globalCtx, Vec3f* v) { CollisionCheck_SpawnShieldParticles(globalCtx, v); Audio_PlaySoundGeneral(NA_SE_IT_SHIELD_REFLECT_SW, &D_801333D4, 4, &D_801333E0, &D_801333E0, &D_801333E8); } /** * Spawns streaks of light and makes a metallic sound at the specified position */ void CollisionCheck_SpawnShieldParticlesMetalSound(GlobalContext* globalCtx, Vec3f* v, Vec3f* pos) { CollisionCheck_SpawnShieldParticles(globalCtx, v); Audio_PlaySoundGeneral(NA_SE_IT_SHIELD_REFLECT_SW, pos, 4, &D_801333E0, &D_801333E0, &D_801333E8); } /** * Spawns streaks of light and makes a metallic sound */ void CollisionCheck_SpawnShieldParticlesMetal2(GlobalContext* globalCtx, Vec3f* v) { CollisionCheck_SpawnShieldParticlesMetal(globalCtx, v); } /** * Spawns streaks of light and makes a wooden sound */ void CollisionCheck_SpawnShieldParticlesWood(GlobalContext* globalCtx, Vec3f* v, Vec3f* actorPos) { static EffectShieldParticleInit initWood = { 16, { 0, 0, 0 }, { 0, 200, 255, 255 }, { 255, 255, 255, 255 }, { 255, 255, 128, 255 }, { 255, 255, 0, 255 }, { 255, 64, 0, 200 }, { 255, 0, 0, 255 }, 2.1f, 35.0f, 30.0f, 8, { 0, 0, 0, { 0, 128, 255 }, false, 300 }, false, }; s32 effectIndex; initWood.position.x = v->x; initWood.position.y = v->y; initWood.position.z = v->z; initWood.lightPoint.x = initWood.position.x; initWood.lightPoint.y = initWood.position.y; initWood.lightPoint.z = initWood.position.z; Effect_Add(globalCtx, &effectIndex, EFFECT_SHIELD_PARTICLE, 0, 1, &initWood); Audio_PlaySoundGeneral(NA_SE_IT_REFLECTION_WOOD, actorPos, 4, &D_801333E0, &D_801333E0, &D_801333E8); } /** * Determines if the line segment connecting itemPos and itemProjPos intersects the side of a cylinder with the given * radius, height, and offset at actorPos. Returns 3 if either endpoint is inside the cylinder, otherwise returns the * number of points of intersection with the side of the cylinder. The locations of those points are put in out1 and * out2, with out1 being closer to itemPos. Line segments that pass through both bases of the cylinder are not detected. */ s32 CollisionCheck_CylSideVsLineSeg(f32 radius, f32 height, f32 offset, Vec3f* actorPos, Vec3f* itemPos, Vec3f* itemProjPos, Vec3f* out1, Vec3f* out2) { Vec3f actorToItem; Vec3f actorToItemProj; Vec3f itemStep; f32 frac1; f32 frac2; u32 intersect2; u32 intersect1; u32 test1; u32 test2; f32 radSqDiff; f32 actorDotItemXZ; f32 zero = 0.0f; f32 closeDist; s32 pad1; s32 pad2; actorToItem.x = itemPos->x - actorPos->x; actorToItem.y = itemPos->y - actorPos->y - offset; actorToItem.z = itemPos->z - actorPos->z; actorToItemProj.x = itemProjPos->x - actorPos->x; actorToItemProj.y = itemProjPos->y - actorPos->y - offset; actorToItemProj.z = itemProjPos->z - actorPos->z; itemStep.x = actorToItemProj.x - actorToItem.x; itemStep.y = actorToItemProj.y - actorToItem.y; itemStep.z = actorToItemProj.z - actorToItem.z; if ((actorToItem.y > 0.0f) && (actorToItem.y < height) && (sqrtf(SQXZ(actorToItem)) < radius)) { return 3; } if ((actorToItemProj.y > 0.0f) && (actorToItemProj.y < height) && (sqrtf(SQXZ(actorToItemProj)) < radius)) { return 3; } radSqDiff = SQXZ(actorToItem) - SQ(radius); if (!IS_ZERO(SQXZ(itemStep))) { actorDotItemXZ = DOTXZ(2.0f * itemStep, actorToItem); if (SQ(actorDotItemXZ) < (4.0f * SQXZ(itemStep) * radSqDiff)) { return 0; } if (SQ(actorDotItemXZ) - (4.0f * SQXZ(itemStep) * radSqDiff) > zero) { intersect1 = intersect2 = 1; } else { intersect1 = 1; intersect2 = 0; } closeDist = sqrtf(SQ(actorDotItemXZ) - (4.0f * SQXZ(itemStep) * radSqDiff)); if (intersect1 == 1) { frac1 = (closeDist - actorDotItemXZ) / (2.0f * SQXZ(itemStep)); } if (intersect2 == 1) { frac2 = (-actorDotItemXZ - closeDist) / (2.0f * SQXZ(itemStep)); } } else if (!IS_ZERO(DOTXZ(2.0f * itemStep, actorToItem))) { intersect1 = 1; intersect2 = 0; frac1 = -radSqDiff / DOTXZ(2.0f * itemStep, actorToItem); } else { if (radSqDiff <= 0.0f) { test1 = (0.0f < actorToItem.y) && (actorToItem.y < height); test2 = (0.0f < actorToItemProj.y) && (actorToItemProj.y < height); if (test1 && test2) { *out1 = actorToItem; *out2 = actorToItemProj; return 2; } if (test1) { *out1 = actorToItem; return 1; } if (test2) { *out1 = actorToItemProj; return 1; } } return 0; } if (intersect2 == 0) { if (frac1 < 0.0f || 1.0f < frac1) { return 0; } } else { test1 = (frac1 < 0.0f || 1.0f < frac1); test2 = (frac2 < 0.0f || 1.0f < frac2); if (test1 && test2) { return 0; } if (test1) { intersect1 = 0; } if (test2) { intersect2 = 0; } } if ((intersect1 == 1) && ((frac1 * itemStep.y + actorToItem.y < 0.0f) || (height < frac1 * itemStep.y + actorToItem.y))) { intersect1 = 0; } if ((intersect2 == 1) && ((frac2 * itemStep.y + actorToItem.y < 0.0f) || (height < frac2 * itemStep.y + actorToItem.y))) { intersect2 = 0; } if (intersect1 == 0 && intersect2 == 0) { return 0; } else if ((intersect1 == 1) && (intersect2 == 1)) { out1->x = frac1 * itemStep.x + actorToItem.x + actorPos->x; out1->y = frac1 * itemStep.y + actorToItem.y + actorPos->y; out1->z = frac1 * itemStep.z + actorToItem.z + actorPos->z; out2->x = frac2 * itemStep.x + actorToItem.x + actorPos->x; out2->y = frac2 * itemStep.y + actorToItem.y + actorPos->y; out2->z = frac2 * itemStep.z + actorToItem.z + actorPos->z; return 2; } else if (intersect1 == 1) { out1->x = frac1 * itemStep.x + actorToItem.x + actorPos->x; out1->y = frac1 * itemStep.y + actorToItem.y + actorPos->y; out1->z = frac1 * itemStep.z + actorToItem.z + actorPos->z; return 1; } else if (intersect2 == 1) { out1->x = frac2 * itemStep.x + actorToItem.x + actorPos->x; out1->y = frac2 * itemStep.y + actorToItem.y + actorPos->y; out1->z = frac2 * itemStep.z + actorToItem.z + actorPos->z; return 1; } return 1; } /** * Gets damage from a sword strike using generic values, and returns 0 if the attack is * not sword-type. Used by bosses to require that a sword attack deal the killing blow. */ u8 CollisionCheck_GetSwordDamage(s32 dmgFlags) { u8 damage = 0; if (dmgFlags & 0x00400100) { damage = 1; } else if (dmgFlags & 0x03000242) { damage = 2; } else if (dmgFlags & 0x48800400) { damage = 4; } else if (dmgFlags & 0x04000000) { damage = 8; } KREG(7) = damage; return damage; }