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colobot/src/object/auto/autopowercaptor.cpp

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/*
* This file is part of the Colobot: Gold Edition source code
* Copyright (C) 2001-2021, Daniel Roux, EPSITEC SA & TerranovaTeam
* http://epsitec.ch; http://colobot.info; http://github.com/colobot
*
* This program is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
* See the GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see http://gnu.org/licenses
*/
#include "object/auto/autopowercaptor.h"
#include "common/make_unique.h"
#include "level/parser/parserline.h"
#include "level/parser/parserparam.h"
#include "math/geometry.h"
#include "object/object_manager.h"
#include "object/old_object.h"
#include "object/interface/carrier_object.h"
#include "object/interface/powered_object.h"
#include "object/interface/transportable_object.h"
#include "sound/sound.h"
#include "ui/controls/interface.h"
#include "ui/controls/window.h"
// Object's constructor.
CAutoPowerCaptor::CAutoPowerCaptor(COldObject* object) : CAuto(object)
{
m_channelSound = -1;
Init();
}
// Object's destructor.
CAutoPowerCaptor::~CAutoPowerCaptor()
{
}
// Destroys the object.
void CAutoPowerCaptor::DeleteObject(bool bAll)
{
if ( m_channelSound != -1 )
{
m_sound->FlushEnvelope(m_channelSound);
m_sound->AddEnvelope(m_channelSound, 0.0f, 1.0f, 1.0f, SOPER_STOP);
m_channelSound = -1;
}
CAuto::DeleteObject(bAll);
}
// Initialize the object.
void CAutoPowerCaptor::Init()
{
Math::Matrix* mat;
m_time = 0.0f;
m_timeVirus = 0.0f;
m_lastParticle = 0.0f;
mat = m_object->GetWorldMatrix(0);
m_pos = Math::Transform(*mat, glm::vec3(22.0f, 4.0f, 0.0f));
m_phase = APAP_WAIT; // waiting ...
m_progress = 0.0f;
m_speed = 1.0f/1.0f;
CAuto::Init();
}
// Reception of lightning.
void CAutoPowerCaptor::StartLightning()
{
m_phase = APAP_LIGHTNING;
m_progress = 0.0f;
m_speed = 1.0f/2.0f;
}
// Management of an event.
bool CAutoPowerCaptor::EventProcess(const Event &event)
{
glm::vec3 pos, speed;
glm::vec2 dim;
int i;
CAuto::EventProcess(event);
if ( m_engine->GetPause() ) return true;
if ( event.type != EVENT_FRAME ) return true;
m_progress += event.rTime*m_speed;
m_timeVirus -= event.rTime;
if ( m_object->GetVirusMode() ) // contaminated by a virus?
{
if ( m_timeVirus <= 0.0f )
{
m_timeVirus = 0.1f+Math::Rand()*0.3f;
}
return true;
}
EventProgress(event.rTime);
if ( m_phase == APAP_LIGHTNING )
{
if ( m_progress < 1.0f )
{
if ( m_lastParticle+m_engine->ParticleAdapt(0.05f) <= m_time )
{
m_lastParticle = m_time;
for ( i=0 ; i<10 ; i++ )
{
pos = m_object->GetPosition();
pos.x += (Math::Rand()-0.5f)*m_progress*40.0f;
pos.z += (Math::Rand()-0.5f)*m_progress*40.0f;
pos.y += 50.0f-m_progress*50.0f;
speed.x = (Math::Rand()-0.5f)*20.0f;
speed.z = (Math::Rand()-0.5f)*20.0f;
speed.y = 5.0f+Math::Rand()*5.0f;
dim.x = 2.0f;
dim.y = dim.x;
m_particle->CreateParticle(pos, speed, dim, Gfx::PARTIBLITZ, 1.0f, 20.0f, 0.5f);
}
}
}
else
{
m_phase = APAP_CHARGE;
m_progress = 0.0f;
m_speed = 1.0f/2.0f;
}
}
if ( m_phase == APAP_CHARGE )
{
if ( m_progress < 1.0f )
{
if ( m_lastParticle+m_engine->ParticleAdapt(0.05f) <= m_time )
{
m_lastParticle = m_time;
for ( i=0 ; i<2 ; i++ )
{
pos = m_object->GetPosition();
pos.y += 16.0f;
speed.x = (Math::Rand()-0.5f)*10.0f;
speed.z = (Math::Rand()-0.5f)*10.0f;
speed.y = -Math::Rand()*30.0f;
dim.x = 1.0f;
dim.y = dim.x;
m_particle->CreateParticle(pos, speed, dim, Gfx::PARTIBLITZ, 1.0f, 0.0f, 0.0f);
}
}
ChargeObject(event.rTime);
}
else
{
m_phase = APAP_WAIT;
m_progress = 0.0f;
m_speed = 1.0f/1.0f;
}
}
return true;
}
// Creates all the interface when the object is selected.
bool CAutoPowerCaptor::CreateInterface(bool bSelect)
{
Ui::CWindow* pw;
glm::vec2 pos, ddim;
float ox, oy, sx, sy;
CAuto::CreateInterface(bSelect);
if ( !bSelect ) return true;
pw = static_cast< Ui::CWindow* >(m_interface->SearchControl(EVENT_WINDOW0));
if ( pw == nullptr ) return false;
ox = 3.0f/640.0f;
oy = 3.0f/480.0f;
sx = 33.0f/640.0f;
sy = 33.0f/480.0f;
pos.x = ox+sx*0.0f;
pos.y = oy+sy*0;
ddim.x = 66.0f/640.0f;
ddim.y = 66.0f/480.0f;
pw->CreateGroup(pos, ddim, 113, EVENT_OBJECT_TYPE);
pos.x = ox+sx*10.2f;
pos.y = oy+sy*0.5f;
ddim.x = 33.0f/640.0f;
ddim.y = 33.0f/480.0f;
pw->CreateButton(pos, ddim, 41, EVENT_OBJECT_LIMIT);
return true;
}
// Returns an error due the state of the automation.
Error CAutoPowerCaptor::GetError()
{
if ( m_object->GetVirusMode() )
{
return ERR_BAT_VIRUS;
}
return ERR_OK;
}
// Load all objects under the lightning rod.
void CAutoPowerCaptor::ChargeObject(float rTime)
{
glm::vec3 sPos = m_object->GetPosition();
for (CObject* obj : CObjectManager::GetInstancePointer()->GetAllObjects())
{
glm::vec3 oPos = obj->GetPosition();
float dist = glm::distance(oPos, sPos);
if ( dist > 20.0f ) continue;
if (! IsObjectBeingTransported(obj) && obj->Implements(ObjectInterfaceType::PowerContainer) )
{
CPowerContainerObject* powerContainer = dynamic_cast<CPowerContainerObject*>(obj);
if (powerContainer->IsRechargeable())
{
float energy = powerContainer->GetEnergy();
energy += rTime/2.0f;
if ( energy > 1.0f ) energy = 1.0f;
powerContainer->SetEnergy(energy);
}
}
if (obj->Implements(ObjectInterfaceType::Powered))
{
CObject* power = dynamic_cast<CPoweredObject&>(*obj).GetPower();
if ( power != nullptr && power->Implements(ObjectInterfaceType::PowerContainer) )
{
CPowerContainerObject* powerContainer = dynamic_cast<CPowerContainerObject*>(power);
if (powerContainer->IsRechargeable())
{
float energy = powerContainer->GetEnergy();
energy += rTime/2.0f;
if ( energy > 1.0f ) energy = 1.0f;
powerContainer->SetEnergy(energy);
}
}
}
if (obj->Implements(ObjectInterfaceType::Carrier))
{
CObject* power = dynamic_cast<CCarrierObject&>(*obj).GetCargo();
if ( power != nullptr && power->Implements(ObjectInterfaceType::PowerContainer) )
{
CPowerContainerObject* powerContainer = dynamic_cast<CPowerContainerObject*>(power);
if (powerContainer->IsRechargeable())
{
float energy = powerContainer->GetEnergy();
energy += rTime/2.0f;
if ( energy > 1.0f ) energy = 1.0f;
powerContainer->SetEnergy(energy);
}
}
}
}
}
// Saves all parameters of the controller.
bool CAutoPowerCaptor::Write(CLevelParserLine* line)
{
if ( m_phase == APAP_WAIT ) return false;
line->AddParam("aExist", MakeUnique<CLevelParserParam>(true));
CAuto::Write(line);
line->AddParam("aPhase", MakeUnique<CLevelParserParam>(static_cast<int>(m_phase)));
line->AddParam("aProgress", MakeUnique<CLevelParserParam>(m_progress));
line->AddParam("aSpeed", MakeUnique<CLevelParserParam>(m_speed));
return true;
}
// Restores all parameters of the controller.
bool CAutoPowerCaptor::Read(CLevelParserLine* line)
{
if ( !line->GetParam("aExist")->AsBool(false) ) return false;
CAuto::Read(line);
m_phase = static_cast< AutoPowerCaptorPhase >(line->GetParam("aPhase")->AsInt(APAP_WAIT));
m_progress = line->GetParam("aProgress")->AsFloat(0.0f);
m_speed = line->GetParam("aSpeed")->AsFloat(1.0f);
m_lastParticle = 0.0f;
return true;
}
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