#include "global.h" f32 Math_CosS(s16 angle) { return coss(angle) * SHT_MINV; } f32 Math_SinS(s16 angle) { return sins(angle) * SHT_MINV; } /** * Changes pValue by step (scaled by the update rate) towards target, setting it equal when the target is reached. * Returns true when target is reached, false otherwise. */ s32 Math_ScaledStepToS(s16* pValue, s16 target, s16 step) { if (step != 0) { f32 updateScale = R_UPDATE_RATE * 0.5f; if ((s16)(*pValue - target) > 0) { step = -step; } *pValue += (s16)(step * updateScale); if (((s16)(*pValue - target) * step) >= 0) { *pValue = target; return true; } } else if (target == *pValue) { return true; } return false; } /** * Changes pValue by step towards target, setting it equal when the target is reached. * Returns true when target is reached, false otherwise. */ s32 Math_StepToS(s16* pValue, s16 target, s16 step) { if (step != 0) { if (target < *pValue) { step = -step; } *pValue += step; if (((*pValue - target) * step) >= 0) { *pValue = target; return true; } } else if (target == *pValue) { return true; } return false; } /** * Changes pValue by step towards target, setting it equal when the target is reached. * Returns true when target is reached, false otherwise. */ s32 Math_StepToF(f32* pValue, f32 target, f32 step) { if (step != 0.0f) { if (target < *pValue) { step = -step; } *pValue += step; if (((*pValue - target) * step) >= 0) { *pValue = target; return true; } } else if (target == *pValue) { return true; } return false; } /** * Changes pValue by step. If pvalue reaches limit angle or its opposite, sets it equal to limit angle. * Returns true when limit angle or its opposite is reached, false otherwise. */ s32 Math_StepUntilAngleS(s16* pValue, s16 limit, s16 step) { s16 orig = *pValue; *pValue += step; if (((s16)(*pValue - limit) * (s16)(orig - limit)) <= 0) { *pValue = limit; return true; } return false; } /** * Changes pValue by step. If pvalue reaches limit, sets it equal to limit. * Returns true when limit is reached, false otherwise. */ s32 Math_StepUntilS(s16* pValue, s16 limit, s16 step) { s16 orig = *pValue; *pValue += step; if (((*pValue - limit) * (orig - limit)) <= 0) { *pValue = limit; return true; } return false; } /** * Changes pValue by step towards target angle, setting it equal when the target is reached. * Returns true when target is reached, false otherwise. */ s32 Math_StepToAngleS(s16* pValue, s16 target, s16 step) { s32 diff = target - *pValue; if (diff < 0) { step = -step; } if (diff >= 0x8000) { step = -step; diff = -0xFFFF - -diff; } else if (diff <= -0x8000) { diff += 0xFFFF; step = -step; } if (step != 0) { *pValue += step; if ((diff * step) <= 0) { *pValue = target; return true; } } else if (target == *pValue) { return true; } return false; } /** * Changes pValue by step. If pvalue reaches limit, sets it equal to limit. * Returns true when limit is reached, false otherwise. */ s32 Math_StepUntilF(f32* pValue, f32 limit, f32 step) { f32 orig = *pValue; *pValue += step; if (((*pValue - limit) * (orig - limit)) <= 0) { *pValue = limit; return true; } return false; } /** * Changes pValue toward target by incrStep if pValue is smaller and by decrStep if it is greater, setting it equal when * target is reached. Returns true when target is reached, false otherwise. */ s32 Math_AsymStepToF(f32* pValue, f32 target, f32 incrStep, f32 decrStep) { f32 step = (target >= *pValue) ? incrStep : decrStep; if (step != 0.0f) { if (target < *pValue) { step = -step; } *pValue += step; if (((*pValue - target) * step) >= 0) { *pValue = target; return 1; } } else if (target == *pValue) { return 1; } return 0; } void func_80077D10(f32* arg0, s16* arg1, Input* input) { f32 relX = input->rel.stick_x; f32 relY = input->rel.stick_y; *arg0 = sqrtf(SQ(relX) + SQ(relY)); *arg0 = (60.0f < *arg0) ? 60.0f : *arg0; *arg1 = Math_Atan2S(relY, -relX); } s16 Rand_S16Offset(s16 base, s16 range) { return (s16)(Rand_ZeroOne() * range) + base; } s16 Rand_S16OffsetStride(s16 base, s16 stride, s16 range) { return (s16)(Rand_ZeroOne() * range) * stride + base; } void Math_Vec3f_Copy(Vec3f* dest, Vec3f* src) { dest->x = src->x; dest->y = src->y; dest->z = src->z; } void Math_Vec3s_ToVec3f(Vec3f* dest, Vec3s* src) { dest->x = src->x; dest->y = src->y; dest->z = src->z; } void Math_Vec3f_Sum(Vec3f* a, Vec3f* b, Vec3f* dest) { dest->x = a->x + b->x; dest->y = a->y + b->y; dest->z = a->z + b->z; } void Math_Vec3f_Diff(Vec3f* a, Vec3f* b, Vec3f* dest) { dest->x = a->x - b->x; dest->y = a->y - b->y; dest->z = a->z - b->z; } void Math_Vec3s_DiffToVec3f(Vec3f* dest, Vec3s* a, Vec3s* b) { dest->x = a->x - b->x; dest->y = a->y - b->y; dest->z = a->z - b->z; } void Math_Vec3f_Scale(Vec3f* vec, f32 scaleF) { vec->x *= scaleF; vec->y *= scaleF; vec->z *= scaleF; } f32 Math_Vec3f_DistXYZ(Vec3f* a, Vec3f* b) { f32 dx = b->x - a->x; f32 dy = b->y - a->y; f32 dz = b->z - a->z; return sqrtf(SQ(dx) + SQ(dy) + SQ(dz)); } f32 Math_Vec3f_DistXYZAndStoreDiff(Vec3f* a, Vec3f* b, Vec3f* dest) { dest->x = b->x - a->x; dest->y = b->y - a->y; dest->z = b->z - a->z; return sqrtf(SQ(dest->x) + SQ(dest->y) + SQ(dest->z)); } f32 Math_Vec3f_DistXZ(Vec3f* a, Vec3f* b) { f32 dx = b->x - a->x; f32 dz = b->z - a->z; return sqrtf(SQ(dx) + SQ(dz)); } f32 Math_Vec3f_DiffY(Vec3f* a, Vec3f* b) { return b->y - a->y; } s16 Math_Vec3f_Yaw(Vec3f* a, Vec3f* b) { f32 dx = b->x - a->x; f32 dz = b->z - a->z; return Math_Atan2S(dz, dx); } s16 Math_Vec3f_Pitch(Vec3f* a, Vec3f* b) { return Math_Atan2S(Math_Vec3f_DistXZ(a, b), a->y - b->y); } void IChain_Apply_u8(u8* ptr, InitChainEntry* ichain); void IChain_Apply_s8(u8* ptr, InitChainEntry* ichain); void IChain_Apply_u16(u8* ptr, InitChainEntry* ichain); void IChain_Apply_s16(u8* ptr, InitChainEntry* ichain); void IChain_Apply_u32(u8* ptr, InitChainEntry* ichain); void IChain_Apply_s32(u8* ptr, InitChainEntry* ichain); void IChain_Apply_f32(u8* ptr, InitChainEntry* ichain); void IChain_Apply_f32div1000(u8* ptr, InitChainEntry* ichain); void IChain_Apply_Vec3f(u8* ptr, InitChainEntry* ichain); void IChain_Apply_Vec3fdiv1000(u8* ptr, InitChainEntry* ichain); void IChain_Apply_Vec3s(u8* ptr, InitChainEntry* ichain); void (*sInitChainHandlers[])(u8* ptr, InitChainEntry* ichain) = { IChain_Apply_u8, IChain_Apply_s8, IChain_Apply_u16, IChain_Apply_s16, IChain_Apply_u32, IChain_Apply_s32, IChain_Apply_f32, IChain_Apply_f32div1000, IChain_Apply_Vec3f, IChain_Apply_Vec3fdiv1000, IChain_Apply_Vec3s, }; void Actor_ProcessInitChain(Actor* actor, InitChainEntry* ichain) { do { sInitChainHandlers[ichain->type]((u8*)actor, ichain); } while ((ichain++)->cont); } void IChain_Apply_u8(u8* ptr, InitChainEntry* ichain) { *(u8*)(ptr + ichain->offset) = ichain->value; } void IChain_Apply_s8(u8* ptr, InitChainEntry* ichain) { *(s8*)(ptr + ichain->offset) = ichain->value; } void IChain_Apply_u16(u8* ptr, InitChainEntry* ichain) { *(u16*)(ptr + ichain->offset) = ichain->value; } void IChain_Apply_s16(u8* ptr, InitChainEntry* ichain) { *(s16*)(ptr + ichain->offset) = ichain->value; } void IChain_Apply_u32(u8* ptr, InitChainEntry* ichain) { *(u32*)(ptr + ichain->offset) = ichain->value; } void IChain_Apply_s32(u8* ptr, InitChainEntry* ichain) { *(s32*)(ptr + ichain->offset) = ichain->value; } void IChain_Apply_f32(u8* ptr, InitChainEntry* ichain) { *(f32*)(ptr + ichain->offset) = ichain->value; } void IChain_Apply_f32div1000(u8* ptr, InitChainEntry* ichain) { *(f32*)(ptr + ichain->offset) = ichain->value / 1000.0f; } void IChain_Apply_Vec3f(u8* ptr, InitChainEntry* ichain) { Vec3f* vec = (Vec3f*)(ptr + ichain->offset); f32 val = ichain->value; vec->z = val; vec->y = val; vec->x = val; } void IChain_Apply_Vec3fdiv1000(u8* ptr, InitChainEntry* ichain) { Vec3f* vec = (Vec3f*)(ptr + ichain->offset); f32 val; osSyncPrintf("pp=%x data=%f\n", vec, ichain->value / 1000.0f); val = ichain->value / 1000.0f; vec->z = val; vec->y = val; vec->x = val; } void IChain_Apply_Vec3s(u8* ptr, InitChainEntry* ichain) { Vec3s* vec = (Vec3s*)(ptr + ichain->offset); s16 val = ichain->value; vec->z = val; vec->y = val; vec->x = val; } /** * Changes pValue by step towards target. If this step is more than fraction of the remaining distance, step by that * instead, with a minimum step of minStep. Returns remaining distance to target. */ f32 Math_SmoothStepToF(f32* pValue, f32 target, f32 fraction, f32 step, f32 minStep) { if (*pValue != target) { f32 stepSize = (target - *pValue) * fraction; if ((stepSize >= minStep) || (stepSize <= -minStep)) { if (stepSize > step) { stepSize = step; } if (stepSize < -step) { stepSize = -step; } *pValue += stepSize; } else { if (stepSize < minStep) { *pValue += minStep; stepSize = minStep; if (target < *pValue) { *pValue = target; } } if (stepSize > -minStep) { *pValue += -minStep; if (*pValue < target) { *pValue = target; } } } } return fabsf(target - *pValue); } /** * Changes pValue by step towards target. If step is more than fraction of the remaining distance, step by that instead. */ void Math_ApproachF(f32* pValue, f32 target, f32 fraction, f32 step) { if (*pValue != target) { f32 stepSize = (target - *pValue) * fraction; if (stepSize > step) { stepSize = step; } else if (stepSize < -step) { stepSize = -step; } *pValue += stepSize; } } /** * Changes pValue by step towards zero. If step is more than fraction of the remaining distance, step by that instead. */ void Math_ApproachZeroF(f32* pValue, f32 fraction, f32 step) { f32 stepSize = *pValue * fraction; if (stepSize > step) { stepSize = step; } else if (stepSize < -step) { stepSize = -step; } *pValue -= stepSize; } /** * Changes pValue by step towards target angle in degrees. If this step is more than fraction of the remaining distance, * step by that instead, with a minimum step of minStep. Returns the value of the step taken. */ f32 Math_SmoothStepToDegF(f32* pValue, f32 target, f32 fraction, f32 step, f32 minStep) { f32 stepSize = 0.0f; f32 diff = target - *pValue; if (*pValue != target) { if (diff > 180.0f) { diff = -(360.0f - diff); } else if (diff < -180.0f) { diff = 360.0f + diff; } stepSize = diff * fraction; if ((stepSize >= minStep) || (stepSize <= -minStep)) { if (stepSize > step) { stepSize = step; } if (stepSize < -step) { stepSize = -step; } *pValue += stepSize; } else { if (stepSize < minStep) { stepSize = minStep; *pValue += stepSize; if (*pValue > target) { *pValue = target; } } if (stepSize > -minStep) { stepSize = -minStep; *pValue += stepSize; if (*pValue < target) { *pValue = target; } } } } if (*pValue >= 360.0f) { *pValue -= 360.0f; } if (*pValue < 0.0f) { *pValue += 360.0f; } return stepSize; } /** * Changes pValue by step towards target. If this step is more than 1/scale of the remaining distance, step by that * instead, with a minimum step of minStep. Returns remaining distance to target. */ s16 Math_SmoothStepToS(s16* pValue, s16 target, s16 scale, s16 step, s16 minStep) { s16 stepSize = 0; s16 diff = target - *pValue; if (*pValue != target) { stepSize = diff / scale; if ((stepSize > minStep) || (stepSize < -minStep)) { if (stepSize > step) { stepSize = step; } if (stepSize < -step) { stepSize = -step; } *pValue += stepSize; } else { if (diff >= 0) { *pValue += minStep; if ((s16)(target - *pValue) <= 0) { *pValue = target; } } else { *pValue -= minStep; if ((s16)(target - *pValue) >= 0) { *pValue = target; } } } } return diff; } /** * Changes pValue by step towards target. If step is more than 1/scale of the remaining distance, step by that instead. */ void Math_ApproachS(s16* pValue, s16 target, s16 scale, s16 maxStep) { s16 diff = target - *pValue; diff /= scale; if (diff > maxStep) { *pValue += maxStep; } else if (diff < -maxStep) { *pValue -= maxStep; } else { *pValue += diff; } } void Color_RGBA8_Copy(Color_RGBA8* dst, Color_RGBA8* src) { dst->r = src->r; dst->g = src->g; dst->b = src->b; dst->a = src->a; } void func_80078884(u16 sfxId) { Audio_PlaySoundGeneral(sfxId, &D_801333D4, 4, &D_801333E0, &D_801333E0, &D_801333E8); } void func_800788CC(u16 sfxId) { Audio_PlaySoundGeneral(sfxId, &D_801333D4, 4, &D_801333E0, &D_801333E0, &D_801333E8); } void func_80078914(Vec3f* arg0, u16 sfxId) { Audio_PlaySoundGeneral(sfxId, arg0, 4, &D_801333E0, &D_801333E0, &D_801333E8); }