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c0bf973c58ab53c2bc8f02feb38304f7407a24e4
maszyna/EvLaunch.cpp
tmj-fstate 457de678c3 basic scenery data export in legacy text format
2018-06-13 16:51:57 +02:00

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/*
This Source Code Form is subject to the
terms of the Mozilla Public License, v.
2.0. If a copy of the MPL was not
distributed with this file, You can
obtain one at
http://mozilla.org/MPL/2.0/.
*/
/*
MaSzyna EU07 locomotive simulator
Copyright (C) 2001-2004 Marcin Wozniak and others
*/
#include "stdafx.h"
#include "EvLaunch.h"
#include "Globals.h"
#include "Logs.h"
#include "Event.h"
#include "MemCell.h"
#include "Timer.h"
#include "parser.h"
#include "Console.h"
#include "world.h"
#include "utilities.h"
//---------------------------------------------------------------------------
// encodes expected key in a short, where low byte represents the actual key,
// and the high byte holds modifiers: 0x1 = shift, 0x2 = ctrl, 0x4 = alt
int vk_to_glfw_key( int const Keycode ) {
#ifdef _WIN32
auto const code = VkKeyScan( Keycode );
char key = code & 0xff;
char shiftstate = ( code & 0xff00 ) >> 8;
if( (key >= 'A') && (key <= 'Z') ) {
key = GLFW_KEY_A + key - 'A';
}
else if( ( key >= '0' ) && ( key <= '9' ) ) {
key = GLFW_KEY_0 + key - '0';
}
return key + ( shiftstate << 8 );
#endif
}
bool TEventLauncher::Load(cParser *parser)
{ // wczytanie wyzwalacza zdarzeń
std::string token;
parser->getTokens();
*parser >> dRadius; // promień działania
if (dRadius > 0.0)
dRadius *= dRadius; // do kwadratu, pod warunkiem, że nie jest ujemne
parser->getTokens(); // klawisz sterujący
*parser >> token;
if (token != "none")
{
if( token.size() == 1 )
iKey = vk_to_glfw_key( token[ 0 ] );
else
iKey = vk_to_glfw_key(stol_def( token, 0 )); // a jak więcej, to jakby numer klawisza jest
}
parser->getTokens();
*parser >> DeltaTime;
if (DeltaTime < 0)
DeltaTime = -DeltaTime; // dla ujemnego zmieniamy na dodatni
else if (DeltaTime > 0)
{ // wartość dodatnia oznacza wyzwalanie o określonej godzinie
iMinute = int(DeltaTime) % 100; // minuty są najmłodszymi cyframi dziesietnymi
iHour = int(DeltaTime - iMinute) / 100; // godzina to setki
DeltaTime = 0; // bez powtórzeń
// potentially shift the provided time by requested offset
auto const timeoffset { static_cast<int>( Global.ScenarioTimeOffset * 60 ) };
if( timeoffset != 0 ) {
auto const adjustedtime { clamp_circular( iHour * 60 + iMinute + timeoffset, 24 * 60 ) };
iHour = ( adjustedtime / 60 ) % 24;
iMinute = adjustedtime % 60;
}
WriteLog(
"EventLauncher at "
+ std::to_string( iHour ) + ":"
+ ( iMinute < 10 ? "0" : "" ) + to_string( iMinute ) ); // wyświetlenie czasu
}
parser->getTokens();
*parser >> token;
asEvent1Name = token; // pierwszy event
parser->getTokens();
*parser >> token;
asEvent2Name = token; // drugi event
if ((asEvent2Name == "end") || (asEvent2Name == "condition"))
{ // drugiego eventu może nie być, bo są z tym problemy, ale ciii...
token = asEvent2Name; // rozpoznane słowo idzie do dalszego przetwarzania
asEvent2Name = "none"; // a drugiego eventu nie ma
}
else
{ // gdy są dwa eventy
parser->getTokens();
*parser >> token;
//str = AnsiString(token.c_str());
}
if (token == "condition")
{ // obsługa wyzwalania warunkowego
parser->getTokens();
*parser >> token;
asMemCellName = token;
parser->getTokens();
*parser >> token;
szText = token;
if (token != "*") //*=nie brać command pod uwagę
iCheckMask |= conditional_memstring;
parser->getTokens();
*parser >> token;
if (token != "*") //*=nie brać wartości 1. pod uwagę
{
iCheckMask |= conditional_memval1;
fVal1 = atof(token.c_str());
}
else
fVal1 = 0;
parser->getTokens();
*parser >> token;
if (token.compare("*") != 0) //*=nie brać wartości 2. pod uwagę
{
iCheckMask |= conditional_memval2;
fVal2 = atof(token.c_str());
}
else
fVal2 = 0;
parser->getTokens(); // słowo zamykające
*parser >> token;
}
return true;
}
bool TEventLauncher::check_conditions()
{ //"renderowanie" wyzwalacza
auto bCond { false };
if (iKey != 0) {
if( iKey > 255 ) {
// key and modifier
auto const modifier = ( iKey & 0xff00 ) >> 8;
bCond = ( Console::Pressed( iKey & 0xff ) )
&& ( ( modifier & 1 ) ? Global.shiftState : true )
&& ( ( modifier & 2 ) ? Global.ctrlState : true );
}
else {
// just key
bCond = ( Console::Pressed( iKey & 0xff ) ); // czy klawisz wciśnięty
}
}
if (DeltaTime > 0)
{
if (UpdatedTime > DeltaTime)
{
UpdatedTime = 0; // naliczanie od nowa
bCond = true;
}
else
UpdatedTime += Timer::GetDeltaTime(); // aktualizacja naliczania czasu
}
else
{ // jeśli nie cykliczny, to sprawdzić czas
if (simulation::Time.data().wHour == iHour)
{
if (simulation::Time.data().wMinute == iMinute)
{ // zgodność czasu uruchomienia
if (UpdatedTime < 10)
{
UpdatedTime = 20; // czas do kolejnego wyzwolenia?
bCond = true;
}
}
}
else
UpdatedTime = 1;
}
if (bCond) // jeśli spełniony został warunek
{
if ((iCheckMask != 0) && MemCell) // sprawdzanie warunku na komórce pamięci
bCond = MemCell->Compare(szText, fVal1, fVal2, iCheckMask);
}
return bCond; // sprawdzanie dRadius w Ground.cpp
}
// sprawdzenie, czy jest globalnym wyzwalaczem czasu
bool TEventLauncher::IsGlobal() const {
return ( ( DeltaTime == 0 )
&& ( iHour >= 0 )
&& ( iMinute >= 0 )
&& ( dRadius < 0.0 ) ); // bez ograniczenia zasięgu
}
// radius() subclass details, calculates node's bounding radius
float
TEventLauncher::radius_() {
return std::sqrt( dRadius );
}
// serialize() subclass details, sends content of the subclass to provided stream
void
TEventLauncher::serialize_( std::ostream &Output ) const {
// TODO: implement
}
// deserialize() subclass details, restores content of the subclass from provided stream
void
TEventLauncher::deserialize_( std::istream &Input ) {
// TODO: implement
}
// export() subclass details, sends basic content of the class in legacy (text) format to provided stream
void
TEventLauncher::export_as_text_( std::ostream &Output ) const {
// header
Output << "eventlauncher ";
// location
Output
<< location().x << ' '
<< location().y << ' '
<< location().z << ' ';
// activation radius
Output
<< ( dRadius > 0 ? std::sqrt( dRadius ) : dRadius ) << ' ';
// activation key
if( iKey != 0 ) {
auto const key { iKey & 0xff };
auto const modifier { ( iKey & 0xff00 ) >> 8 };
if( ( key >= GLFW_KEY_A ) && ( key <= GLFW_KEY_Z ) ) {
Output << static_cast<char>(( 'A' + key - GLFW_KEY_A + ( ( modifier & 1 ) == 0 ? 32 : 0 ) )) << ' ';
}
else if( ( key >= GLFW_KEY_0 ) && ( key <= GLFW_KEY_9 ) ) {
Output << static_cast<char>(( '0' + key - GLFW_KEY_0 )) << ' ';
}
}
else {
Output << "none ";
}
// activation interval or hour
if( DeltaTime != 0 ) {
// cyclical launcher
Output << -DeltaTime << ' ';
}
else {
// single activation at specified time
if( ( iHour < 0 )
&& ( iMinute < 0 ) ) {
Output << DeltaTime << ' ';
}
else {
// NOTE: activation hour might be affected by user-requested time offset
auto const timeoffset{ static_cast<int>( Global.ScenarioTimeOffset * 60 ) };
auto const adjustedtime{ clamp_circular( iHour * 60 + iMinute - timeoffset, 24 * 60 ) };
Output
<< ( adjustedtime / 60 ) % 24
<< ( adjustedtime % 60 )
<< ' ';
}
}
// associated event(s)
Output << ( asEvent1Name.empty() ? "none" : asEvent1Name ) << ' ';
Output << ( asEvent2Name.empty() ? "none" : asEvent2Name ) << ' ';
if( false == asMemCellName.empty() ) {
// conditional event
Output
<< "condition "
<< asMemCellName << ' '
<< szText << ' '
<< ( ( iCheckMask & conditional_memval1 ) != 0 ? to_string( fVal1 ) : "*" ) << ' '
<< ( ( iCheckMask & conditional_memval2 ) != 0 ? to_string( fVal2 ) : "*" ) << ' ';
}
// footer
Output
<< "end"
<< "\n";
}
//---------------------------------------------------------------------------
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