// Update is called once per frame
void UpdateLadder()
{
m_heroBoxComputed = false;
// prevent any crash
if (m_player == null || m_motor == null)
{
return;
}
// Handle dynamic of controlled hero
if (m_isControlling)
{
Settings oSettings = GetSettings();
// update default jump dir
float fX = m_player.m_inputs.m_axisX.GetRawValue();
if (fX > 0f)
{
m_defaultExitDir = true;
}
else if (fX < 0f)
{
m_defaultExitDir = false;
}
// handle jump exit first
if (!string.IsNullOrEmpty(m_player.m_jump.m_button))
{
bool bJump = Input.GetButton(m_player.m_jump.m_button);
m_releaseJump |= !bJump;
if (m_releaseJump && bJump && GetSettings().m_canJump)
{
ReleaseControl(true);
return;
}
}
// update velocity
m_motor.m_velocity.x = 0f;
m_motor.m_velocity.y = APInput.Update(m_motor.m_velocity.y, oSettings.m_maxSpeed * m_player.m_inputs.m_axisY.GetRawValue(), true, oSettings.m_acceleration, oSettings.m_deceleration, Time.deltaTime);
// Handle exit and move
HandleExit();
m_motor.Move();
}
else
{
if (m_timeForNextCatch > 0f)
{
m_timeForNextCatch -= Time.deltaTime;
}
TryTakecontrol();
}
}
void HandleHorizontalMove()
{
m_sliding = false;
float maxSpeed = ComputeMaxSpeed();
// compute horizontal velocity from input
float fMoveDir = m_inputs.m_axisX.GetRawValue() != 0f ? Mathf.Sign(m_inputs.m_axisX.GetRawValue()) : (m_motor.FaceRight ? 1f : -1f);
// compute slope factor
m_speedFactor = 1f;
if (m_onGround)
{
float fGroundAngle = Mathf.Rad2Deg * Mathf.Acos(m_motor.GetGroundNormal().y);
fGroundAngle = fMoveDir != Mathf.Sign(m_motor.GetGroundNormal().x) ? fGroundAngle : -fGroundAngle;
m_speedFactor = Mathf.Clamp01(m_basic.m_slopeSpeedMultiplier.Evaluate(fGroundAngle));
}
// Compute move direction
Vector2 hrzMoveDir = new Vector2(fMoveDir, 0f);
float absAxisX = Mathf.Abs(m_inputs.m_axisX.GetRawValue());
float hrzMoveLength = absAxisX * maxSpeed * m_speedFactor;
// align this velocity on ground plane if we touch the ground
bool bCrouched = IsCrouched();
bool bAttacking = IsAttacking();
if (m_onGround)
{
float fDot = Vector2.Dot(hrzMoveDir, m_motor.GetGroundNormal());
if (Mathf.Abs(fDot) > float.Epsilon)
{
Vector3 perpAxis = Vector3.Cross(hrzMoveDir, m_motor.GetGroundNormal());
hrzMoveDir = Vector3.Cross(m_motor.GetGroundNormal(), perpAxis);
hrzMoveDir.Normalize();
}
// cancel input if needed
if (bCrouched || bAttacking)
{
hrzMoveLength = 0f;
}
}
// handle dynamic
if (m_onGround)
{
float fDynFriction, fStaticFriction;
ComputeFrictions(out fDynFriction, out fStaticFriction);
// update sliding status
if (fDynFriction < 1f)
{
m_sliding = true;
}
float fVelOnMove = Vector2.Dot(m_motor.m_velocity, hrzMoveDir);
float fDirLength = fVelOnMove;
if (m_sliding)
{
// dynamic is different while sliding
if (!bCrouched && !bAttacking && absAxisX > 0f)
{
float fDiffMax = maxSpeed - fVelOnMove;
if (fDiffMax > 0f)
{
fDirLength = fVelOnMove + Mathf.Min(fDiffMax, absAxisX * fDynFriction * Time.deltaTime * 20f);
}
}
else
{
fDirLength = ApplyDamping(fVelOnMove, fStaticFriction);
}
}
else
{
// raise deceleration for crouched/attack
float fDecel = (bCrouched || bAttacking) ? m_basic.m_deceleration * 2f : m_basic.m_deceleration;
fDirLength = APInput.Update(fVelOnMove, hrzMoveLength, true, m_basic.m_acceleration, fDecel, Time.deltaTime);
}
ClampValueWithDamping(ref fDirLength, m_maxAirVelDamping, -maxSpeed, maxSpeed);
m_motor.m_velocity = hrzMoveDir * (fDirLength);
m_groundSpeed = Mathf.Abs(fDirLength);
}
else
{
// in air dynamic
float fVelOnMove = Vector2.Dot(m_motor.m_velocity, hrzMoveDir);
float fDiffVel = (hrzMoveLength - fVelOnMove);
float fMaxAccel = m_basic.m_airPower * Time.deltaTime;
fDiffVel = Mathf.Clamp(fDiffVel, -fMaxAccel, fMaxAccel);
m_motor.m_velocity += hrzMoveDir * fDiffVel;
ClampValueWithDamping(ref m_motor.m_velocity.x, m_maxAirVelDamping, -m_basic.m_maxAirSpeed, m_basic.m_maxAirSpeed);
ClampValueWithDamping(ref m_motor.m_velocity.y, m_maxAirVelDamping, -m_basic.m_maxFallSpeed, m_basic.m_maxFallSpeed);
m_groundSpeed = 0f;
}
}
