// Minecart.cpp
// Implements the cMinecart class representing a minecart in the world
// Handles physics when a minecart is on any type of rail (overrides simulator in Entity.cpp)
// Indiana Jones!
#include "Globals.h"
#include "Minecart.h"
#include "../World.h"
#include "../ClientHandle.h"
#include "../Chunk.h"
#include "Player.h"
#include "../BoundingBox.h"
#define MAX_SPEED 8
#define MAX_SPEED_NEGATIVE -MAX_SPEED
class cMinecartCollisionCallback :
public cEntityCallback
{
public:
cMinecartCollisionCallback(Vector3d a_Pos, double a_Height, double a_Width, int a_UniqueID, int a_AttacheeUniqueID) :
m_DoesInteserct(false),
m_CollidedEntityPos(0, 0, 0),
m_Pos(a_Pos),
m_Height(a_Height),
m_Width(a_Width),
m_UniqueID(a_UniqueID),
m_AttacheeUniqueID(a_AttacheeUniqueID)
{
}
virtual bool Item(cEntity * a_Entity) override
{
ASSERT(a_Entity != NULL);
if (!a_Entity->IsPlayer() && !a_Entity->IsMob() && !a_Entity->IsMinecart() && !a_Entity->IsBoat())
{
return false;
}
else if ((a_Entity->GetUniqueID() == m_UniqueID) || (a_Entity->GetUniqueID() == m_AttacheeUniqueID))
{
return false;
}
cBoundingBox bbEntity(a_Entity->GetPosition(), a_Entity->GetWidth() / 2, a_Entity->GetHeight());
cBoundingBox bbMinecart(Vector3d(m_Pos.x, floor(m_Pos.y), m_Pos.z), m_Width / 2, m_Height);
if (bbEntity.DoesIntersect(bbMinecart))
{
m_CollidedEntityPos = a_Entity->GetPosition();
m_DoesInteserct = true;
return true;
}
return false;
}
bool FoundIntersection(void) const
{
return m_DoesInteserct;
}
Vector3d GetCollidedEntityPosition(void) const
{
return m_CollidedEntityPos;
}
protected:
bool m_DoesInteserct;
Vector3d m_CollidedEntityPos;
Vector3d m_Pos;
double m_Height, m_Width;
int m_UniqueID;
int m_AttacheeUniqueID;
};
cMinecart::cMinecart(ePayload a_Payload, double a_X, double a_Y, double a_Z) :
super(etMinecart, a_X, a_Y, a_Z, 0.98, 0.7),
m_Payload(a_Payload),
m_LastDamage(0),
m_DetectorRailPosition(0, 0, 0),
m_bIsOnDetectorRail(false)
{
SetMass(20.f);
SetMaxHealth(6);
SetHealth(6);
SetWidth(1);
SetHeight(0.9);
}
void cMinecart::SpawnOn(cClientHandle & a_ClientHandle)
{
a_ClientHandle.SendSpawnVehicle(*this, 10, (char)m_Payload); // 10 = Minecarts
a_ClientHandle.SendEntityMetadata(*this);
}
void cMinecart::HandlePhysics(float a_Dt, cChunk & a_Chunk)
{
if (IsDestroyed()) // Mainly to stop detector rails triggering again after minecart is dead
{
return;
}
int PosY = POSY_TOINT;
if ((PosY <= 0) || (PosY >= cChunkDef::Height))
{
// Outside the world, just process normal falling physics
super::HandlePhysics(a_Dt, a_Chunk);
BroadcastMovementUpdate();
return;
}
int RelPosX = POSX_TOINT - a_Chunk.GetPosX() * cChunkDef::Width;
int RelPosZ = POSZ_TOINT - a_Chunk.GetPosZ() * cChunkDef::Width;
cChunk * Chunk = a_Chunk.GetRelNeighborChunkAdjustCoords(RelPosX, RelPosZ);
if (Chunk == NULL)
{
// Inside an unloaded chunk, bail out all processing
return;
}
BLOCKTYPE InsideType;
NIBBLETYPE InsideMeta;
Chunk->GetBlockTypeMeta(RelPosX, PosY, RelPosZ, InsideType, InsideMeta);
if (!IsBlockRail(InsideType))
{
Chunk->GetBlockTypeMeta(RelPosX, PosY + 1, RelPosZ, InsideType, InsideMeta); // When an descending minecart hits a flat rail, it goes through the ground; check for this
if (IsBlockRail(InsideType)) AddPosY(1); // Push cart upwards
}
bool WasDetectorRail = false;
if (IsBlockRail(InsideType))
{
if (InsideType == E_BLOCK_RAIL)
{
SnapToRail(InsideMeta);
}
else
{
SnapToRail(InsideMeta & 0x07);
}
switch (InsideType)
{
case E_BLOCK_RAIL: HandleRailPhysics(InsideMeta, a_Dt); break;
case E_BLOCK_ACTIVATOR_RAIL: break;
case E_BLOCK_POWERED_RAIL: HandlePoweredRailPhysics(InsideMeta); break;
case E_BLOCK_DETECTOR_RAIL:
{
HandleDetectorRailPhysics(InsideMeta, a_Dt);
WasDetectorRail = true;
break;
}
default: VERIFY(!"Unhandled rail type despite checking if block was rail!"); break;
}
AddPosition(GetSpeed() * (a_Dt / 1000)); // Commit changes; as we use our own engine when on rails, this needs to be done, whereas it is normally in Entity.cpp
}
else
{
// Not on rail, default physics
SetPosY(floor(GetPosY()) + 0.35); // HandlePhysics overrides this if minecart can fall, else, it is to stop ground clipping minecart bottom when off-rail
super::HandlePhysics(a_Dt, *Chunk);
}
if (m_bIsOnDetectorRail && !Vector3i(POSX_TOINT, POSY_TOINT, POSZ_TOINT).Equals(m_DetectorRailPosition))
{
m_World->SetBlock(m_DetectorRailPosition.x, m_DetectorRailPosition.y, m_DetectorRailPosition.z, E_BLOCK_DETECTOR_RAIL, m_World->GetBlockMeta(m_DetectorRailPosition) & 0x07);
m_bIsOnDetectorRail = false;
}
else if (WasDetectorRail)
{
m_bIsOnDetectorRail = true;
m_DetectorRailPosition = Vector3i(POSX_TOINT, POSY_TOINT, POSZ_TOINT);
}
// Broadcast positioning changes to client
BroadcastMovementUpdate();
}
void cMinecart::HandleRailPhysics(NIBBLETYPE a_RailMeta, float a_Dt)
{
/*
NOTE: Please bear in mind that taking away from negatives make them even more negative,
adding to negatives make them positive, etc.
*/
switch (a_RailMeta)
{
case E_META_RAIL_ZM_ZP: // NORTHSOUTH
{
SetYaw(270);
SetPosY(floor(GetPosY()) + 0.55);
SetSpeedY(0); // Don't move vertically as on ground
SetSpeedX(0); // Correct diagonal movement from curved rails
// Execute both the entity and block collision checks
bool BlckCol = TestBlockCollision(a_RailMeta), EntCol = TestEntityCollision(a_RailMeta);
if (EntCol || BlckCol) return;
if (GetSpeedZ() != 0) // Don't do anything if cart is stationary
{
if (GetSpeedZ() > 0)
{
// Going SOUTH, slow down
AddSpeedZ(-0.1);
}
else
{
// Going NORTH, slow down
AddSpeedZ(0.1);
}
}
break;
}
case E_META_RAIL_XM_XP: // EASTWEST
{
SetYaw(180);
SetPosY(floor(GetPosY()) + 0.55);
SetSpeedY(0);
SetSpeedZ(0);
bool BlckCol = TestBlockCollision(a_RailMeta), EntCol = TestEntityCollision(a_RailMeta);
if (EntCol || BlckCol) return;
if (GetSpeedX() != 0)
{
if (GetSpeedX() > 0)
{
AddSpeedX(-0.1);
}
else
{
AddSpeedX(0.1);
}
}
break;
}
case E_META_RAIL_ASCEND_ZM: // ASCEND NORTH
{
SetYaw(270);
SetSpeedX(0);
if (GetSpeedZ() >= 0)
{
// SpeedZ POSITIVE, going SOUTH
if (GetSpeedZ() <= MAX_SPEED) // Speed limit
{
AddSpeedZ(0.5); // Speed up
SetSpeedY(-GetSpeedZ()); // Downward movement is negative (0 minus positive numbers is negative)
}
}
else
{
// SpeedZ NEGATIVE, going NORTH
AddSpeedZ(1); // Slow down
SetSpeedY(-GetSpeedZ()); // Upward movement is positive (0 minus negative number is positive number)
}
break;
}
case E_META_RAIL_ASCEND_ZP: // ASCEND SOUTH
{
SetYaw(270);
SetSpeedX(0);
if (GetSpeedZ() > 0)
{
// SpeedZ POSITIVE, going SOUTH
AddSpeedZ(-1); // Slow down
SetSpeedY(GetSpeedZ()); // Upward movement positive
}
else
{
if (GetSpeedZ() >= MAX_SPEED_NEGATIVE) // Speed limit
{
// SpeedZ NEGATIVE, going NORTH
AddSpeedZ(-0.5); // Speed up
SetSpeedY(GetSpeedZ()); // Downward movement negative
}
}
break;
}
case E_META_RAIL_ASCEND_XM: // ASCEND EAST
{
SetYaw(180);
SetSpeedZ(0);
if (GetSpeedX() >= 0)
{
if (GetSpeedX() <= MAX_SPEED)
{
AddSpeedX(0.5);
SetSpeedY(-GetSpeedX());
}
}
else
{
AddSpeedX(1);
SetSpeedY(-GetSpeedX());
}
break;
}
case E_META_RAIL_ASCEND_XP: // ASCEND WEST
{
SetYaw(180);
SetSpeedZ(0);
if (GetSpeedX() > 0)
{
AddSpeedX(-1);
SetSpeedY(GetSpeedX());
}
else
{
if (GetSpeedX() >= MAX_SPEED_NEGATIVE)
{
AddSpeedX(-0.5);
SetSpeedY(GetSpeedX());
}
}
break;
}
case E_META_RAIL_CURVED_ZM_XM: // Ends pointing NORTH and WEST
{
SetYaw(315); // Set correct rotation server side
SetPosY(floor(GetPosY()) + 0.55); // Levitate dat cart
SetSpeedY(0);
TestBlockCollision(a_RailMeta);
TestEntityCollision(a_RailMeta);
// SnapToRail handles turning
break;
}
case E_META_RAIL_CURVED_ZM_XP: // Curved NORTH EAST
{
SetYaw(225);
SetPosY(floor(GetPosY()) + 0.55);
SetSpeedY(0);
TestBlockCollision(a_RailMeta);
TestEntityCollision(a_RailMeta);
break;
}
case E_META_RAIL_CURVED_ZP_XM: // Curved SOUTH WEST
{
SetYaw(135);
SetPosY(floor(GetPosY()) + 0.55);
SetSpeedY(0);
TestBlockCollision(a_RailMeta);
TestEntityCollision(a_RailMeta);
break;
}
case E_META_RAIL_CURVED_ZP_XP: // Curved SOUTH EAST
{
SetYaw(45);
SetPosY(floor(GetPosY()) + 0.55);
SetSpeedY(0);
TestBlockCollision(a_RailMeta);
TestEntityCollision(a_RailMeta);
break;
}
default:
{
ASSERT(!"Unhandled rail meta!"); // Dun dun DUN!
break;
}
}
}
void cMinecart::HandlePoweredRailPhysics(NIBBLETYPE a_RailMeta)
{
// Initialise to 'slow down' values
int AccelDecelSpeed = -2;
int AccelDecelNegSpeed = 2;
if ((a_RailMeta & 0x8) == 0x8)
{
// Rail powered - set variables to 'speed up' values
AccelDecelSpeed = 1;
AccelDecelNegSpeed = -1;
}
switch (a_RailMeta & 0x07)
{
case E_META_RAIL_ZM_ZP: // NORTHSOUTH
{
SetYaw(270);
SetPosY(floor(GetPosY()) + 0.55);
SetSpeedY(0);
SetSpeedX(0);
bool BlckCol = TestBlockCollision(a_RailMeta), EntCol = TestEntityCollision(a_RailMeta);
if (EntCol || BlckCol) return;
if (GetSpeedZ() != 0)
{
if (GetSpeedZ() > 0)
{
AddSpeedZ(AccelDecelSpeed);
}
else
{
AddSpeedZ(AccelDecelNegSpeed);
}
}
break;
}
case E_META_RAIL_XM_XP: // EASTWEST
{
SetYaw(180);
SetPosY(floor(GetPosY()) + 0.55);
SetSpeedY(0);
SetSpeedZ(0);
bool BlckCol = TestBlockCollision(a_RailMeta), EntCol = TestEntityCollision(a_RailMeta);
if (EntCol || BlckCol) return;
if (GetSpeedX() != 0)
{
if (GetSpeedX() > 0)
{
AddSpeedX(AccelDecelSpeed);
}
else
{
AddSpeedX(AccelDecelNegSpeed);
}
}
break;
}
case E_META_RAIL_ASCEND_XM: // ASCEND EAST
{
SetYaw(180);
SetSpeedZ(0);
if (GetSpeedX() >= 0)
{
if (GetSpeedX() <= MAX_SPEED)
{
AddSpeedX(AccelDecelSpeed);
SetSpeedY(-GetSpeedX());
}
}
else
{
AddSpeedX(AccelDecelNegSpeed);
SetSpeedY(-GetSpeedX());
}
break;
}
case E_META_RAIL_ASCEND_XP: // ASCEND WEST
{
SetYaw(180);
SetSpeedZ(0);
if (GetSpeedX() > 0)
{
AddSpeedX(AccelDecelSpeed);
SetSpeedY(GetSpeedX());
}
else
{
if (GetSpeedX() >= MAX_SPEED_NEGATIVE)
{
AddSpeedX(AccelDecelNegSpeed);
SetSpeedY(GetSpeedX());
}
}
break;
}
case E_META_RAIL_ASCEND_ZM: // ASCEND NORTH
{
SetYaw(270);
SetSpeedX(0);
if (GetSpeedZ() >= 0)
{
if (GetSpeedZ() <= MAX_SPEED)
{
AddSpeedZ(AccelDecelSpeed);
SetSpeedY(-GetSpeedZ());
}
}
else
{
AddSpeedZ(AccelDecelNegSpeed);
SetSpeedY(-GetSpeedZ());
}
break;
}
case E_META_RAIL_ASCEND_ZP: // ASCEND SOUTH
{
SetYaw(270);
SetSpeedX(0);
if (GetSpeedZ() > 0)
{
AddSpeedZ(AccelDecelSpeed);
SetSpeedY(GetSpeedZ());
}
else
{
if (GetSpeedZ() >= MAX_SPEED_NEGATIVE)
{
AddSpeedZ(AccelDecelNegSpeed);
SetSpeedY(GetSpeedZ());
}
}
break;
}
default: ASSERT(!"Unhandled powered rail metadata!"); break;
}
}
void cMinecart::HandleDetectorRailPhysics(NIBBLETYPE a_RailMeta, float a_Dt)
{
m_World->SetBlockMeta(m_DetectorRailPosition, a_RailMeta | 0x08);
// No special handling
HandleRailPhysics(a_RailMeta & 0x07, a_Dt);
}
void cMinecart::HandleActivatorRailPhysics(NIBBLETYPE a_RailMeta, float a_Dt)
{
HandleRailPhysics(a_RailMeta & 0x07, a_Dt);
}
void cMinecart::SnapToRail(NIBBLETYPE a_RailMeta)
{
switch (a_RailMeta)
{
case E_META_RAIL_ASCEND_XM:
case E_META_RAIL_ASCEND_XP:
case E_META_RAIL_XM_XP:
{
SetSpeedZ(0);
SetPosZ(floor(GetPosZ()) + 0.5);
break;
}
case E_META_RAIL_ASCEND_ZM:
case E_META_RAIL_ASCEND_ZP:
case E_META_RAIL_ZM_ZP:
{
SetSpeedX(0);
SetPosX(floor(GetPosX()) + 0.5);
break;
}
// Curved rail physics: once minecart has reached more than half of the block in the direction that it is travelling in, jerk it in the direction of curvature
case E_META_RAIL_CURVED_ZM_XM:
{
if (GetPosZ() > floor(GetPosZ()) + 0.5)
{
if (GetSpeedZ() > 0)
{
SetSpeedX(-GetSpeedZ() * 0.7);
}
SetSpeedZ(0);
SetPosZ(floor(GetPosZ()) + 0.5);
}
else if (GetPosX() > floor(GetPosX()) + 0.5)
{
if (GetSpeedX() > 0)
{
SetSpeedZ(-GetSpeedX() * 0.7);
}
SetSpeedX(0);
SetPosX(floor(GetPosX()) + 0.5);
}
SetSpeedY(0);
break;
}
case E_META_RAIL_CURVED_ZM_XP:
{
if (GetPosZ() > floor(GetPosZ()) + 0.5)
{
if (GetSpeedZ() > 0)
{
SetSpeedX(GetSpeedZ() * 0.7);
}
SetSpeedZ(0);
SetPosZ(floor(GetPosZ()) + 0.5);
}
else if (GetPosX() < floor(GetPosX()) + 0.5)
{
if (GetSpeedX() < 0)
{
SetSpeedZ(GetSpeedX() * 0.7);
}
SetSpeedX(0);
SetPosX(floor(GetPosX()) + 0.5);
}
SetSpeedY(0);
break;
}
case E_META_RAIL_CURVED_ZP_XM:
{
if (GetPosZ() < floor(GetPosZ()) + 0.5)
{
if (GetSpeedZ() < 0)
{
SetSpeedX(GetSpeedZ() * 0.7);
}
SetSpeedZ(0);
SetPosZ(floor(GetPosZ()) + 0.5);
}
else if (GetPosX() > floor(GetPosX()) + 0.5)
{
if (GetSpeedX() > 0)
{
SetSpeedZ(GetSpeedX() * 0.7);
}
SetSpeedX(0);
SetPosX(floor(GetPosX()) + 0.5);
}
SetSpeedY(0);
break;
}
case E_META_RAIL_CURVED_ZP_XP:
{
if (GetPosZ() < floor(GetPosZ()) + 0.5)
{
if (GetSpeedZ() < 0)
{
SetSpeedX(-GetSpeedZ() * 0.7);
}
SetSpeedZ(0);
SetPosZ(floor(GetPosZ()) + 0.5);
}
else if (GetPosX() < floor(GetPosX()) + 0.5)
{
if (GetSpeedX() < 0)
{
SetSpeedZ(-GetSpeedX() * 0.7);
}
SetSpeedX(0);
SetPosX(floor(GetPosX()) + 0.5);
}
SetSpeedY(0);
break;
}
default: break;
}
}
bool cMinecart::TestBlockCollision(NIBBLETYPE a_RailMeta)
{
switch (a_RailMeta)
{
case E_META_RAIL_ZM_ZP:
{
if (GetSpeedZ() > 0)
{
BLOCKTYPE Block = m_World->GetBlock(POSX_TOINT, POSY_TOINT, (int)ceil(GetPosZ()));
if (!IsBlockRail(Block) && cBlockInfo::IsSolid(Block))
{
// We could try to detect a block in front based purely on coordinates, but xoft made a bounding box system - why not use? :P
cBoundingBox bbBlock(Vector3d(POSX_TOINT, POSY_TOINT, (int)ceil(GetPosZ())), 0.5, 1);
cBoundingBox bbMinecart(Vector3d(GetPosX(), floor(GetPosY()), GetPosZ()), GetWidth() / 2, GetHeight());
if (bbBlock.DoesIntersect(bbMinecart))
{
SetSpeed(0, 0, 0);
SetPosZ(floor(GetPosZ()) + 0.4);
return true;
}
}
}
else if (GetSpeedZ() < 0)
{
BLOCKTYPE Block = m_World->GetBlock(POSX_TOINT, POSY_TOINT, POSZ_TOINT - 1);
if (!IsBlockRail(Block) && cBlockInfo::IsSolid(Block))
{
cBoundingBox bbBlock(Vector3d(POSX_TOINT, POSY_TOINT, POSZ_TOINT - 1), 0.5, 1);
cBoundingBox bbMinecart(Vector3d(GetPosX(), floor(GetPosY()), GetPosZ() - 1), GetWidth() / 2, GetHeight());
if (bbBlock.DoesIntersect(bbMinecart))
{
SetSpeed(0, 0, 0);
SetPosZ(floor(GetPosZ()) + 0.65);
return true;
}
}
}
break;
}
case E_META_RAIL_XM_XP:
{
if (GetSpeedX() > 0)
{
BLOCKTYPE Block = m_World->GetBlock((int)ceil(GetPosX()), POSY_TOINT, POSZ_TOINT);
if (!IsBlockRail(Block) && cBlockInfo::IsSolid(Block))
{
cBoundingBox bbBlock(Vector3d((int)ceil(GetPosX()), POSY_TOINT, POSZ_TOINT), 0.5, 1);
cBoundingBox bbMinecart(Vector3d(GetPosX(), floor(GetPosY()), GetPosZ()), GetWidth() / 2, GetHeight());
if (bbBlock.DoesIntersect(bbMinecart))
{
SetSpeed(0, 0, 0);
SetPosX(floor(GetPosX()) + 0.4);
return true;
}
}
}
else if (GetSpeedX() < 0)
{
BLOCKTYPE Block = m_World->GetBlock(POSX_TOINT - 1, POSY_TOINT, POSZ_TOINT);
if (!IsBlockRail(Block) && cBlockInfo::IsSolid(Block))
{
cBoundingBox bbBlock(Vector3d(POSX_TOINT - 1, POSY_TOINT, POSZ_TOINT), 0.5, 1);
cBoundingBox bbMinecart(Vector3d(GetPosX() - 1, floor(GetPosY()), GetPosZ()), GetWidth() / 2, GetHeight());
if (bbBlock.DoesIntersect(bbMinecart))
{
SetSpeed(0, 0, 0);
SetPosX(floor(GetPosX()) + 0.65);
return true;
}
}
}
break;
}
case E_META_RAIL_CURVED_ZM_XM:
case E_META_RAIL_CURVED_ZM_XP:
case E_META_RAIL_CURVED_ZP_XM:
case E_META_RAIL_CURVED_ZP_XP:
{
BLOCKTYPE BlockXM = m_World->GetBlock(POSX_TOINT - 1, POSY_TOINT, POSZ_TOINT);
BLOCKTYPE BlockXP = m_World->GetBlock(POSX_TOINT + 1, POSY_TOINT, POSZ_TOINT);
BLOCKTYPE BlockZM = m_World->GetBlock(POSX_TOINT, POSY_TOINT, POSZ_TOINT - 1);
BLOCKTYPE BlockZP = m_World->GetBlock(POSX_TOINT, POSY_TOINT, POSZ_TOINT + 1);
if (
(!IsBlockRail(BlockXM) && cBlockInfo::IsSolid(BlockXM)) ||
(!IsBlockRail(BlockXP) && cBlockInfo::IsSolid(BlockXP)) ||
(!IsBlockRail(BlockZM) && cBlockInfo::IsSolid(BlockZM)) ||
(!IsBlockRail(BlockZP) && cBlockInfo::IsSolid(BlockZP))
)
{
SetSpeed(0, 0, 0);
SetPosition(POSX_TOINT + 0.5, GetPosY(), POSZ_TOINT + 0.5);
return true;
}
break;
}
default: break;
}
return false;
}
bool cMinecart::TestEntityCollision(NIBBLETYPE a_RailMeta)
{
cMinecartCollisionCallback MinecartCollisionCallback(GetPosition(), GetHeight(), GetWidth(), GetUniqueID(), ((m_Attachee == NULL) ? -1 : m_Attachee->GetUniqueID()));
int ChunkX, ChunkZ;
cChunkDef::BlockToChunk(POSX_TOINT, POSZ_TOINT, ChunkX, ChunkZ);
m_World->ForEachEntityInChunk(ChunkX, ChunkZ, MinecartCollisionCallback);
if (!MinecartCollisionCallback.FoundIntersection())
{
return false;
}
switch (a_RailMeta)
{
case E_META_RAIL_ZM_ZP:
{
if (MinecartCollisionCallback.GetCollidedEntityPosition().z >= GetPosZ())
{
if ((-GetSpeedZ() * 0.4) < 0.01)
{
AddSpeedZ(-4);
}
else
{
SetSpeedZ(-GetSpeedZ() * 0.4);
}
}
else
{
if ((GetSpeedZ() * 0.4) < 0.01)
{
AddSpeedZ(4);
}
else
{
SetSpeedZ(GetSpeedZ() * 0.4);
}
}
return true;
}
case E_META_RAIL_XM_XP:
{
if (MinecartCollisionCallback.GetCollidedEntityPosition().x >= GetPosX())
{
if ((-GetSpeedX() * 0.4) < 0.01)
{
AddSpeedX(-4);
}
else
{
SetSpeedX(-GetSpeedX() * 0.4);
}
}
else
{
if ((GetSpeedX() * 0.4) < 0.01)
{
AddSpeedX(4);
}
else
{
SetSpeedX(GetSpeedX() * 0.4);
}
}
return true;
}
case E_META_RAIL_CURVED_ZM_XM:
case E_META_RAIL_CURVED_ZP_XP:
{
Vector3d Distance = MinecartCollisionCallback.GetCollidedEntityPosition() - Vector3d(GetPosX(), 0, GetPosZ());
// Prevent division by small numbers
Distance.z = std::max(Distance.z, 0.001);
/* Check to which side the minecart is to be pushed.
Let's consider a z-x-coordinate system where the minecart is the center (0/0).
The minecart moves along the line z = -x, the perpendicular line to this is z = x.
In order to decide to which side the minecart is to be pushed, it must be checked on what side of the perpendicular line the pushing entity is located. */
if (
((Distance.z > 0) && ((Distance.x / Distance.z) >= 1)) ||
((Distance.z < 0) && ((Distance.x / Distance.z) <= 1))
)
{
if ((-GetSpeedX() * 0.4 / sqrt(2)) < 0.01)
{
AddSpeedX(-4 / sqrt(2));
AddSpeedZ(4 / sqrt(2));
}
else
{
SetSpeedX(-GetSpeedX() * 0.4);
SetSpeedZ(GetSpeedZ() * 0.4);
}
}
else if ((GetSpeedX() * 0.4 / sqrt(2)) < 0.01)
{
AddSpeedX(4 / sqrt(2));
AddSpeedZ(-4 / sqrt(2));
}
else
{
SetSpeedX(GetSpeedX() * 0.4);
SetSpeedZ(-GetSpeedZ() * 0.4);
}
break;
}
case E_META_RAIL_CURVED_ZM_XP:
case E_META_RAIL_CURVED_ZP_XM:
{
Vector3d Distance = MinecartCollisionCallback.GetCollidedEntityPosition() - Vector3d(GetPosX(), 0, GetPosZ());
// Prevent division by small numbers
Distance.z = std::max(Distance.z, 0.001);
/* Check to which side the minecart is to be pushed.
Let's consider a z-x-coordinate system where the minecart is the center (0/0).
The minecart moves along the line z = x, the perpendicular line to this is z = -x.
In order to decide to which side the minecart is to be pushed, it must be checked on what side of the perpendicular line the pushing entity is located. */
if (
((Distance.z > 0) && ((Distance.x / Distance.z) <= -1)) ||
((Distance.z < 0) && ((Distance.x / Distance.z) >= -1))
)
{
if ((GetSpeedX() * 0.4) < 0.01)
{
AddSpeedX(4 / sqrt(2));
AddSpeedZ(4 / sqrt(2));
}
else
{
SetSpeedX(GetSpeedX() * 0.4);
SetSpeedZ(GetSpeedZ() * 0.4);
}
}
else if ((-GetSpeedX() * 0.4) < 0.01)
{
AddSpeedX(-4 / sqrt(2));
AddSpeedZ(-4 / sqrt(2));
}
else
{
SetSpeedX(-GetSpeedX() * 0.4);
SetSpeedZ(-GetSpeedZ() * 0.4);
}
break;
}
default: break;
}
return false;
}
bool cMinecart::DoTakeDamage(TakeDamageInfo & TDI)
{
if ((TDI.Attacker != NULL) && TDI.Attacker->IsPlayer() && ((cPlayer *)TDI.Attacker)->IsGameModeCreative())
{
Destroy();
TDI.FinalDamage = GetMaxHealth(); // Instant hit for creative
SetInvulnerableTicks(0);
return super::DoTakeDamage(TDI); // No drops for creative
}
m_LastDamage = TDI.FinalDamage;
if (!super::DoTakeDamage(TDI))
{
return false;
}
m_World->BroadcastEntityMetadata(*this);
if (GetHealth() <= 0)
{
Destroy();
cItems Drops;
switch (m_Payload)
{
case mpNone:
{
Drops.push_back(cItem(E_ITEM_MINECART, 1, 0));
break;
}
case mpChest:
{
Drops.push_back(cItem(E_ITEM_CHEST_MINECART, 1, 0));
break;
}
case mpFurnace:
{
Drops.push_back(cItem(E_ITEM_FURNACE_MINECART, 1, 0));
break;
}
case mpTNT:
{
Drops.push_back(cItem(E_ITEM_MINECART_WITH_TNT, 1, 0));
break;
}
case mpHopper:
{
Drops.push_back(cItem(E_ITEM_MINECART_WITH_HOPPER, 1, 0));
break;
}
default:
{
ASSERT(!"Unhandled minecart type when spawning pickup!");
return true;
}
}
m_World->SpawnItemPickups(Drops, GetPosX(), GetPosY(), GetPosZ());
}
return true;
}
void cMinecart::Destroyed()
{
if (m_bIsOnDetectorRail)
{
m_World->SetBlock(m_DetectorRailPosition.x, m_DetectorRailPosition.y, m_DetectorRailPosition.z, E_BLOCK_DETECTOR_RAIL, m_World->GetBlockMeta(m_DetectorRailPosition) & 0x07);
}
}
////////////////////////////////////////////////////////////////////////////////
// cRideableMinecart:
cRideableMinecart::cRideableMinecart(double a_X, double a_Y, double a_Z, const cItem & a_Content, int a_Height) :
super(mpNone, a_X, a_Y, a_Z),
m_Content(a_Content),
m_Height(a_Height)
{
}
void cRideableMinecart::OnRightClicked(cPlayer & a_Player)
{
if (m_Attachee != NULL)
{
if (m_Attachee->GetUniqueID() == a_Player.GetUniqueID())
{
// This player is already sitting in, they want out.
a_Player.Detach();
return;
}
if (m_Attachee->IsPlayer())
{
// Another player is already sitting in here, cannot attach
return;
}
// Detach whatever is sitting in this minecart now:
m_Attachee->Detach();
}
// Attach the player to this minecart
a_Player.AttachTo(this);
}
////////////////////////////////////////////////////////////////////////////////
// cMinecartWithChest:
cMinecartWithChest::cMinecartWithChest(double a_X, double a_Y, double a_Z) :
super(mpChest, a_X, a_Y, a_Z)
{
}
void cMinecartWithChest::SetSlot(size_t a_Idx, const cItem & a_Item)
{
ASSERT(a_Idx < ARRAYCOUNT(m_Items));
m_Items[a_Idx] = a_Item;
}
void cMinecartWithChest::OnRightClicked(cPlayer & a_Player)
{
// Show the chest UI window to the player
// TODO
}
////////////////////////////////////////////////////////////////////////////////
// cMinecartWithFurnace:
cMinecartWithFurnace::cMinecartWithFurnace(double a_X, double a_Y, double a_Z) :
super(mpFurnace, a_X, a_Y, a_Z),
m_FueledTimeLeft(-1),
m_IsFueled(false)
{
}
void cMinecartWithFurnace::OnRightClicked(cPlayer & a_Player)
{
if (a_Player.GetEquippedItem().m_ItemType == E_ITEM_COAL)
{
if (!a_Player.IsGameModeCreative())
{
a_Player.GetInventory().RemoveOneEquippedItem();
}
if (!m_IsFueled) // We don't want to change the direction by right clicking it.
{
AddSpeed(a_Player.GetLookVector().x, 0, a_Player.GetLookVector().z);
}
m_IsFueled = true;
m_FueledTimeLeft = m_FueledTimeLeft + 600; // The minecart will be active 600 more ticks.
m_World->BroadcastEntityMetadata(*this);
}
}
void cMinecartWithFurnace::Tick(float a_Dt, cChunk & a_Chunk)
{
super::Tick(a_Dt, a_Chunk);
if (m_IsFueled)
{
m_FueledTimeLeft--;
if (m_FueledTimeLeft < 0)
{
m_IsFueled = false;
m_World->BroadcastEntityMetadata(*this);
return;
}
if (GetSpeed().Length() > 6)
{
return;
}
AddSpeed(GetSpeed() / 4);
}
}
////////////////////////////////////////////////////////////////////////////////
// cMinecartWithTNT:
cMinecartWithTNT::cMinecartWithTNT(double a_X, double a_Y, double a_Z) :
super(mpTNT, a_X, a_Y, a_Z)
{
}
// TODO: Make it activate when passing over activator rail
////////////////////////////////////////////////////////////////////////////////
// cMinecartWithHopper:
cMinecartWithHopper::cMinecartWithHopper(double a_X, double a_Y, double a_Z) :
super(mpHopper, a_X, a_Y, a_Z)
{
}
// TODO: Make it suck up blocks and travel further than any other cart and physics and put and take blocks
// AND AVARYTHING!!