//========= Copyright © 1996-2005, Valve Corporation, All rights reserved. ============// // // Purpose: Hint node utilities and functions // // $NoKeywords: $ //=============================================================================// // @TODO (toml 03-04-03): there is far too much duplicate code in here #include "cbase.h" #include "ai_hint.h" #include "ai_network.h" #include "ai_node.h" #include "ai_basenpc.h" #include "ai_networkmanager.h" #include "ndebugoverlay.h" #include "animation.h" #include "tier1/strtools.h" #include "mapentities_shared.h" // memdbgon must be the last include file in a .cpp file!!! #include "tier0/memdbgon.h" #define REPORTFAILURE(text) if ( hintCriteria.HasFlag( bits_HINT_NODE_REPORT_FAILURES ) ) \ NDebugOverlay::Text( GetAbsOrigin(), text, false, 60 ) //================================================== // CHintCriteria //================================================== CHintCriteria::CHintCriteria( void ) { m_iFirstHintType = HINT_NONE; m_iLastHintType = HINT_NONE; m_strGroup = NULL_STRING; m_strGenericType = NULL_STRING; m_iFlags = 0; m_HintTypes.Purge(); m_pfnFilter = NULL; m_pFilterContext = NULL; } //----------------------------------------------------------------------------- // Purpose: Destructor //----------------------------------------------------------------------------- CHintCriteria::~CHintCriteria( void ) { m_zoneInclude.Purge(); m_zoneExclude.Purge(); m_HintTypes.Purge(); } //----------------------------------------------------------------------------- // Purpose: Sets the hint type for this search criteria // Input : nHintType - the hint type for this search criteria //----------------------------------------------------------------------------- void CHintCriteria::SetHintType( int nHintType ) { m_iFirstHintType = nHintType; m_iLastHintType = HINT_NONE; m_HintTypes.Purge(); } //----------------------------------------------------------------------------- // Purpose: Add another type of hint that matches the search criteria //----------------------------------------------------------------------------- void CHintCriteria::AddHintType( int hintType ) { m_HintTypes.AddToTail( hintType ); } int CHintCriteria::NumHintTypes() const { return m_HintTypes.Count(); } int CHintCriteria::GetHintType( int idx ) const { return m_HintTypes[ idx ]; } bool CHintCriteria::MatchesSingleHintType() const { if ( m_HintTypes.Count() != 0 ) { return false; } if ( m_iFirstHintType != HINT_ANY && m_iLastHintType == HINT_NONE ) { return true; } return false; } //----------------------------------------------------------------------------- // Purpose: //----------------------------------------------------------------------------- bool CHintCriteria::MatchesHintType( int hintType, string_t iszGenericType ) const { int c = m_HintTypes.Count(); for ( int i = 0; i < c; ++i ) { if ( m_HintTypes[i] == hintType ) return true; } // See if we're trying to filter the nodes if ( GetFirstHintType() != HINT_ANY ) { if( GetLastHintType() == HINT_NONE ) { // Searching for a single type of hint. if( GetFirstHintType() != hintType ) return false; } else { // This search is for a range of hint types. if( hintType < GetFirstHintType() || hintType > GetLastHintType() ) return false; if ( hintType == HINT_GENERIC && iszGenericType != m_strGenericType ) { return false; } } return true; } return false; } //----------------------------------------------------------------------------- // Allows us to search for nodes within a range of consecutive types. //----------------------------------------------------------------------------- void CHintCriteria::SetHintTypeRange( int firstType, int lastType ) { if( lastType < firstType ) { DevMsg( 2, "Hint Type Range is backwards - Fixing up.\n" ); int temp; temp = firstType; firstType = lastType; lastType = temp; } m_iFirstHintType = firstType; m_iLastHintType = lastType; m_HintTypes.Purge(); } //----------------------------------------------------------------------------- // Purpose: // Input : bitmask - //----------------------------------------------------------------------------- void CHintCriteria::SetFlag( int bitmask ) { m_iFlags |= bitmask; } //----------------------------------------------------------------------------- // Purpose: // Input : bitmask - //----------------------------------------------------------------------------- void CHintCriteria::ClearFlag( int bitmask ) { m_iFlags &= ~bitmask; } //----------------------------------------------------------------------------- // Purpose: // Input : group - //----------------------------------------------------------------------------- void CHintCriteria::SetGroup( string_t group ) { m_strGroup = group; } //----------------------------------------------------------------------------- // Purpose: Adds a zone to a zone list // Input : list - the list of zones to add the new zone to // &position - the origin point of the zone // radius - the radius of the zone //----------------------------------------------------------------------------- void CHintCriteria::AddZone( zoneList_t &list, const Vector &position, float radius ) { int id = list.AddToTail(); list[id].position = position; list[id].radiussqr = radius*radius; } //----------------------------------------------------------------------------- // Purpose: Adds an include zone to the search criteria // Input : &position - the origin point of the zone // radius - the radius of the zone //----------------------------------------------------------------------------- void CHintCriteria::AddIncludePosition( const Vector &position, float radius ) { AddZone( m_zoneInclude, position, radius ); } //----------------------------------------------------------------------------- // Purpose: Adds an exclude zone to the search criteria // Input : &position - the origin point of the zone // radius - the radius of the zone //----------------------------------------------------------------------------- void CHintCriteria::AddExcludePosition( const Vector &position, float radius ) { AddZone( m_zoneExclude, position, radius ); } //----------------------------------------------------------------------------- // Purpose: Test to see if this position falls within any of the zones in the list // Input : *zone - list of zones to test against // &testPosition - position to test with // Output : Returns true on success, false on failure. //----------------------------------------------------------------------------- inline bool CHintCriteria::InZone( const zoneList_t &zone, const Vector &testPosition ) const { int numZones = zone.Count(); //Iterate through all zones in the list for ( int i = 0; i < numZones; i++ ) { if ( ((zone[i].position) - testPosition).LengthSqr() < (zone[i].radiussqr) ) return true; } return false; } //----------------------------------------------------------------------------- // Purpose: Determine if a point within our include list // Input : &testPosition - position to test with // Output : Returns true on success, false on failure. //----------------------------------------------------------------------------- bool CHintCriteria::InIncludedZone( const Vector &testPosition ) const { return InZone( m_zoneInclude, testPosition ); } //----------------------------------------------------------------------------- // Purpose: Determine if a point within our exclude list // Input : &testPosition - position to test with // Output : Returns true on success, false on failure. //----------------------------------------------------------------------------- bool CHintCriteria::InExcludedZone( const Vector &testPosition ) const { return InZone( m_zoneExclude, testPosition ); } //----------------------------------------------------------------------------- // Init static variables //----------------------------------------------------------------------------- CAIHintVector CAI_HintManager::gm_AllHints; CUtlMap< int, CAIHintVector > CAI_HintManager::gm_TypedHints( 0, 0, DefLessFunc( int ) ); CAI_Hint* CAI_HintManager::gm_pLastFoundHints[ CAI_HintManager::HINT_HISTORY ]; int CAI_HintManager::gm_nFoundHintIndex = 0; CAI_Hint *CAI_HintManager::AddFoundHint( CAI_Hint *hint ) { if ( hint ) { CAI_HintManager::gm_nFoundHintIndex = ( CAI_HintManager::gm_nFoundHintIndex + 1 ) & CAI_HintManager::HINT_HISTORY_MASK; gm_pLastFoundHints[ CAI_HintManager::gm_nFoundHintIndex ] = hint; } return hint; } int CAI_HintManager::GetFoundHintCount() { return CAI_HintManager::HINT_HISTORY; } CAI_Hint *CAI_HintManager::GetFoundHint( int index ) { return gm_pLastFoundHints[ ( CAI_HintManager::gm_nFoundHintIndex + index ) & CAI_HintManager::HINT_HISTORY_MASK ]; } CAI_Hint *CAI_HintManager::GetLastFoundHint() { for ( int i = 0; i < CAI_HintManager::HINT_HISTORY; ++i ) { // Walk backward int slot = ( ( CAI_HintManager::gm_nFoundHintIndex - i ) & CAI_HintManager::HINT_HISTORY_MASK ); if ( gm_pLastFoundHints[ slot ] ) return gm_pLastFoundHints[ slot ]; } return NULL; } void CAI_HintManager::ResetFoundHints() { Q_memset( gm_pLastFoundHints, 0, sizeof( gm_pLastFoundHints ) ); CAI_HintManager::gm_nFoundHintIndex = 0; } bool CAI_HintManager::IsInFoundHintList( CAI_Hint *hint ) { for ( int i = 0; i < CAI_HintManager::HINT_HISTORY; ++i ) { if ( gm_pLastFoundHints[ i ] == hint ) return true; } return false; } //----------------------------------------------------------------------------- int CAI_HintManager::FindAllHints( CAI_BaseNPC *pNPC, const Vector &position, const CHintCriteria &hintCriteria, CUtlVector *pResult ) { // If we have no hints, bail int c = CAI_HintManager::gm_AllHints.Count(); if ( !c ) return NULL; // Remove the nearest flag. It makes now sense with random. bool hadNearest = hintCriteria.HasFlag( bits_HINT_NODE_NEAREST ); (const_cast(hintCriteria)).ClearFlag( bits_HINT_NODE_NEAREST ); // Now loop till we find a valid hint or return to the start CAI_Hint *pTestHint; for ( int i = 0; i < c; ++i ) { pTestHint = CAI_HintManager::gm_AllHints[ i ]; Assert( pTestHint ); if ( pTestHint->HintMatchesCriteria( pNPC, hintCriteria, position, NULL ) ) pResult->AddToTail( pTestHint ); } if ( hadNearest ) (const_cast(hintCriteria)).SetFlag( bits_HINT_NODE_NEAREST ); return pResult->Count(); } //----------------------------------------------------------------------------- // Purpose: Finds a random hint within the requested radious of the npc // Builds a list of all suitable hints and chooses randomly from amongst them. // Input : *pNPC - // nHintType - // nFlags - // flMaxDist - // Output : CAI_Hint //----------------------------------------------------------------------------- CAI_Hint *CAI_HintManager::FindHintRandom( CAI_BaseNPC *pNPC, const Vector &position, const CHintCriteria &hintCriteria ) { CUtlVector hintList; if ( FindAllHints( pNPC, position, hintCriteria, &hintList ) > 0 ) { // Pick one randomly return ( CAI_HintManager::AddFoundHint( hintList[ random->RandomInt( 0, hintList.Count() - 1 ) ] ) ); } // start at the top of the list for the next search CAI_HintManager::ResetFoundHints(); return NULL; } // #define HINT_PROFILING 1 #if defined( HINT_PROFILING ) static void AppendTimer( int idx, char *buf, size_t bufsize, CFastTimer& timer ) { char s[ 32 ]; Q_snprintf( s, sizeof( s ), "%d %6.3f ms", idx, timer.GetDuration().GetMillisecondsF() ); Q_strncat( buf, s, bufsize ); } #endif //----------------------------------------------------------------------------- // Purpose: // Input : *hintCriteria - // Output : CAI_Hint //----------------------------------------------------------------------------- CAI_Hint *CAI_HintManager::FindHint( CAI_BaseNPC *pNPC, const Vector &position, const CHintCriteria &hintCriteria ) { #if defined( HINT_PROFILING ) CFastTimer timer; timer.Start(); #endif bool singleType = hintCriteria.MatchesSingleHintType(); bool lookingForNearest = hintCriteria.HasFlag( bits_HINT_NODE_NEAREST ); bool bIgnoreHintType = true; CUtlVector< CAIHintVector * > lists; if ( singleType ) { int slot = CAI_HintManager::gm_TypedHints.Find( hintCriteria.GetFirstHintType() ); if ( slot != CAI_HintManager::gm_TypedHints.InvalidIndex() ) { lists.AddToTail( &CAI_HintManager::gm_TypedHints[ slot ] ); } } else { int typeCount = hintCriteria.NumHintTypes(); if ( typeCount > 0 ) { for ( int listType = 0; listType < typeCount; ++listType ) { int slot = CAI_HintManager::gm_TypedHints.Find( hintCriteria.GetHintType( listType ) ); if ( slot != CAI_HintManager::gm_TypedHints.InvalidIndex() ) { lists.AddToTail( &CAI_HintManager::gm_TypedHints[ slot ] ); } } } else { // Still need to check hint type in this case lists.AddToTail( &CAI_HintManager::gm_AllHints ); bIgnoreHintType = false; } } CAI_Hint *pBestHint = NULL; int visited = 0; int listCount = lists.Count(); if ( listCount == 0 ) return NULL; // Try the fast match path int i, count; // Start with hint after the last one used CAI_Hint *pTestHint = NULL; float flBestDistance = MAX_TRACE_LENGTH; if ( !lookingForNearest ) { // Fast check of previous results count = CAI_HintManager::GetFoundHintCount(); for ( i = 0; i < count; ++i ) { pTestHint = CAI_HintManager::GetFoundHint( i ); if ( pTestHint ) { Assert( dynamic_cast(pTestHint) != NULL ); ++visited; if ( pTestHint->HintMatchesCriteria( pNPC, hintCriteria, position, &flBestDistance ) ) { #if defined( HINT_PROFILING ) Msg( "fast result visited %d\n", visited ); #endif return pTestHint; } } } } // Longer search, reset best distance flBestDistance = MAX_TRACE_LENGTH; for ( int listNum = 0; listNum < listCount; ++listNum ) { CAIHintVector *list = lists[ listNum ]; count = list->Count(); // ------------------------------------------- // If we have no hints, bail // ------------------------------------------- if ( !count ) continue; // Now loop till we find a valid hint or return to the start for ( i = 0 ; i < count; ++i ) { pTestHint = list->Element( i ); Assert( pTestHint ); ++visited; Assert( dynamic_cast(pTestHint) != NULL ); if ( pTestHint->HintMatchesCriteria( pNPC, hintCriteria, position, &flBestDistance, false, bIgnoreHintType ) ) { // If we were searching for the nearest, just note that this is now the nearest node if ( lookingForNearest ) { pBestHint = pTestHint; } else { // If we're not looking for the nearest, we're done CAI_HintManager::AddFoundHint( pTestHint ); #if defined( HINT_PROFILING ) Msg( "visited %d\n", visited ); #endif return pTestHint; } } } } // Return the nearest node that we found if ( pBestHint ) { CAI_HintManager::AddFoundHint( pBestHint ); } #if defined( HINT_PROFILING ) timer.End(); Msg( "visited %d\n", visited ); if ( !pBestHint ) { Msg( "%i search failed for [%d] at pos %.3f %.3f %.3f [%.4f msec ~ %.4f msec per node]\n", gpGlobals->tickcount, pNPC ? pNPC->entindex() : -1, position.x, position.y, position.z, timer.GetDuration().GetMillisecondsF(), timer.GetDuration().GetMillisecondsF()/MAX( (float)visited, 1.0f ) ); } #endif return pBestHint; } //----------------------------------------------------------------------------- // Purpose: Searches for a hint node that this NPC cares about. If one is // claims that hint node for this NPC so that no other NPCs // try to use it. // // Input : nFlags - Search criterea. Can currently be one or more of the following: // bits_HINT_NODE_VISIBLE - searches for visible hint nodes. // bits_HINT_NODE_RANDOM - calls through the FindHintRandom and builds list of all matching // nodes and picks randomly from among them. Note: Depending on number of hint nodes, this // could be slower, so use with care. // // Output : Returns pointer to hint node if available hint node was found that matches the // given criterea that this NPC also cares about. Otherwise, returns NULL //----------------------------------------------------------------------------- CAI_Hint* CAI_HintManager::FindHint( CAI_BaseNPC *pNPC, Hint_e nHintType, int nFlags, float flMaxDist, const Vector *pMaxDistFrom ) { assert( pNPC != NULL ); if ( pNPC == NULL ) return NULL; CHintCriteria hintCriteria; hintCriteria.SetHintType( nHintType ); hintCriteria.SetFlag( nFlags ); // Using the NPC's hint group? if ( nFlags & bits_HINT_NODE_USE_GROUP ) { hintCriteria.SetGroup( pNPC->GetHintGroup() ); } // Add the search position Vector vecPosition = ( pMaxDistFrom != NULL ) ? (*pMaxDistFrom) : pNPC->GetAbsOrigin(); hintCriteria.AddIncludePosition( vecPosition, flMaxDist ); // If asking for a random node, use random logic instead if ( nFlags & bits_HINT_NODE_RANDOM ) return FindHintRandom( pNPC, vecPosition, hintCriteria ); return FindHint( pNPC, vecPosition, hintCriteria ); } //----------------------------------------------------------------------------- // Purpose: Position only search // Output : CAI_Hint //----------------------------------------------------------------------------- CAI_Hint *CAI_HintManager::FindHint( const Vector &position, const CHintCriteria &hintCriteria ) { return FindHint( NULL, position, hintCriteria ); } //----------------------------------------------------------------------------- // Purpose: NPC only search // Output : CAI_Hint //----------------------------------------------------------------------------- CAI_Hint *CAI_HintManager::FindHint( CAI_BaseNPC *pNPC, const CHintCriteria &hintCriteria ) { assert( pNPC != NULL ); if ( pNPC == NULL ) return NULL; return FindHint( pNPC, pNPC->GetAbsOrigin(), hintCriteria ); } //------------------------------------------------------------------------------ // Purpose : // Input : // Output : //------------------------------------------------------------------------------ CAI_Hint* CAI_HintManager::CreateHint( HintNodeData *pNodeData, const char *pMapData ) { // Reset last found hint if new node is added CAI_HintManager::ResetFoundHints(); CAI_Hint *pHint = (CAI_Hint*)CreateEntityByName("ai_hint"); if ( pHint ) { // First, parse the mapdata chunk we were passed if ( pMapData ) { CEntityMapData entData( (char*)pMapData ); pHint->ParseMapData( &entData ); // Restore the desired classname (parsing the mapdata stomps it) pHint->SetClassname( "ai_hint" ); } pHint->SetName( pNodeData->strEntityName ); pHint->SetAbsOrigin( pNodeData->vecPosition ); memcpy( &(pHint->m_NodeData), pNodeData, sizeof(HintNodeData) ); DispatchSpawn( pHint ); return pHint; } return NULL; } //------------------------------------------------------------------------------ void CAI_HintManager::AddHint( CAI_Hint *pHint ) { // --------------------------------- // Add to linked list of hints // --------------------------------- CAI_HintManager::gm_AllHints.AddToTail( pHint ); CAI_HintManager::AddHintByType( pHint ); } void CAI_Hint::SetHintType( int hintType, bool force /*= false*/ ) { if ( !force && hintType == m_NodeData.nHintType ) return; CAI_HintManager::RemoveHintByType( this ); m_NodeData.nHintType = hintType; CAI_HintManager::AddHintByType( this ); } void CAI_HintManager::AddHintByType( CAI_Hint *pHint ) { Hint_e type = pHint->HintType(); int slot = CAI_HintManager::gm_TypedHints.Find( type ); if ( slot == CAI_HintManager::gm_TypedHints.InvalidIndex() ) { slot = CAI_HintManager::gm_TypedHints.Insert( type); } CAI_HintManager::gm_TypedHints[ slot ].AddToTail( pHint ); } void CAI_HintManager::RemoveHintByType( CAI_Hint *pHintToRemove ) { int slot = CAI_HintManager::gm_TypedHints.Find( pHintToRemove->HintType() ); if ( slot != CAI_HintManager::gm_TypedHints.InvalidIndex() ) { CAI_HintManager::gm_TypedHints[ slot ].FindAndRemove( pHintToRemove ); } } //------------------------------------------------------------------------------ void CAI_HintManager::RemoveHint( CAI_Hint *pHintToRemove ) { // -------------------------------------- // Remove from linked list of hints // -------------------------------------- gm_AllHints.FindAndRemove( pHintToRemove ); RemoveHintByType( pHintToRemove ); if ( CAI_HintManager::IsInFoundHintList( pHintToRemove ) ) { CAI_HintManager::ResetFoundHints(); } } //----------------------------------------------------------------------------- // Purpose: // Input : *token - // Output : int //----------------------------------------------------------------------------- int CAI_HintManager::GetFlags( const char *token ) { int len = strlen( token ); if ( len <= 0 ) { return bits_HINT_NODE_NONE; } char *lowercase = (char *)_alloca( len + 1 ); Q_strncpy( lowercase, token, len+1 ); strlwr( lowercase ); if ( strstr( "none", lowercase ) ) { return bits_HINT_NODE_NONE; } int bits = 0; if ( strstr( "visible", lowercase ) ) { bits |= bits_HINT_NODE_VISIBLE; } if ( strstr( "nearest", lowercase ) ) { bits |= bits_HINT_NODE_NEAREST; } if ( strstr( "random", lowercase ) ) { bits |= bits_HINT_NODE_RANDOM; } // Can't be nearest and random, defer to nearest if ( ( bits & bits_HINT_NODE_NEAREST ) && ( bits & bits_HINT_NODE_RANDOM ) ) { // Remove random bits &= ~bits_HINT_NODE_RANDOM; DevMsg( "HINTFLAGS:%s, inconsistent, the nearest node is never a random hint node, treating as nearest request!\n", token ); } return bits; } //----------------------------------------------------------------------------- // Purpose: //----------------------------------------------------------------------------- CAI_Hint *CAI_HintManager::GetFirstHint( AIHintIter_t *pIter ) { if ( !gm_AllHints.Count() ) { *pIter = (AIHintIter_t)gm_AllHints.InvalidIndex(); return NULL; } *pIter = (AIHintIter_t)0; return gm_AllHints[0]; } //----------------------------------------------------------------------------- // Purpose: //----------------------------------------------------------------------------- CAI_Hint *CAI_HintManager::GetNextHint( AIHintIter_t *pIter ) { if ( (int)*pIter != gm_AllHints.InvalidIndex() ) { int i = ( (int)*pIter ) + 1; if ( gm_AllHints.Count() <= i ) { *pIter = (AIHintIter_t)gm_AllHints.InvalidIndex(); return NULL; } *pIter = (AIHintIter_t)i; return gm_AllHints[i]; } return NULL; } //----------------------------------------------------------------------------- // Purpose: //----------------------------------------------------------------------------- void CAI_HintManager::DumpHints() { AIHintIter_t iter; CAI_Hint *pCurHint = GetFirstHint( &iter ); while (pCurHint) { const Vector &v = pCurHint->GetAbsOrigin(); Msg( "(%.1f, %.1f, %.1f) -- Node ID: %d; WC id %d; type %d\n", v.x, v.y, v.z, pCurHint->GetNodeId(), pCurHint->GetWCId(), pCurHint->HintType() ); pCurHint = GetNextHint( &iter ); } } //----------------------------------------------------------------------------- // Purpose: //----------------------------------------------------------------------------- void CAI_HintManager::ValidateHints() { #ifdef _DEBUG int nTyped = 0; FOR_EACH_VEC( gm_AllHints, i ) { Assert( dynamic_cast(gm_AllHints[i]) != NULL ); } for ( int i = gm_TypedHints.FirstInorder(); i != gm_TypedHints.InvalidIndex(); i = gm_TypedHints.NextInorder( i ) ) { FOR_EACH_VEC( gm_TypedHints[i], j ) { nTyped++; Assert( dynamic_cast(gm_TypedHints[i][j]) != NULL ); } } Assert( gm_AllHints.Count() == nTyped ); #endif } //------------------------------------------------------------------------------ // Purpose : // Input : // Output : //------------------------------------------------------------------------------ void CAI_HintManager::DrawHintOverlays(float flDrawDuration) { int c = gm_AllHints.Count(); for ( int i = 0; i < c; ++i ) { CAI_Hint *pHint = gm_AllHints[ i ]; int r = 0; int g = 0; int b = 255; Vector vHintPos; if (pHint->m_NodeData.nNodeID != NO_NODE) { vHintPos = g_pBigAINet->GetNode(pHint->m_NodeData.nNodeID)->GetPosition(g_pAINetworkManager->GetEditOps()->m_iHullDrawNum); } else { vHintPos = pHint->GetAbsOrigin(); } if ( pHint->GetNodeId() != NO_NODE ) NDebugOverlay::Text( vHintPos + Vector(0,6,8), CFmtStr("(%d), (%d)", pHint->HintType(), pHint->GetNodeId()), true, flDrawDuration ); else NDebugOverlay::Text( vHintPos + Vector(0,6,8), CFmtStr("(%d)", pHint->HintType()), true, flDrawDuration ); // If node is currently locked if (pHint->m_NodeData.iDisabled) { r = 100; g = 100; b = 100; } else if (pHint->m_hHintOwner != NULL) { r = 255; g = 0; b = 0; CBaseEntity* pOwner = pHint->User(); if (pOwner) { char owner[255]; Q_strncpy(owner,pOwner->GetDebugName(),sizeof(owner)); Vector loc = vHintPos; loc.x+=6; loc.y+=6; loc.z+=6; NDebugOverlay::Text( loc, owner, true, flDrawDuration ); NDebugOverlay::Line( vHintPos, pOwner->WorldSpaceCenter(), 128, 128, 128, false, 0); } } else if (pHint->IsLocked()) { r = 200; g = 150; b = 10; } NDebugOverlay::Box(vHintPos, Vector(-3,-3,-3), Vector(3,3,3), r,g,b,0,flDrawDuration); // Draw line in facing direction Vector offsetDir = 12.0 * Vector(cos(DEG2RAD(pHint->Yaw())),sin(DEG2RAD(pHint->Yaw())),0); NDebugOverlay::Line(vHintPos, vHintPos+offsetDir, r,g,b,false,flDrawDuration); } } //################################################################## // > CAI_Hint //################################################################## LINK_ENTITY_TO_CLASS( ai_hint, CAI_Hint ); BEGIN_DATADESC( CAI_Hint ) DEFINE_EMBEDDED( m_NodeData ), // m_nTargetNodeID (reset on load) DEFINE_FIELD( m_hHintOwner, FIELD_EHANDLE), DEFINE_FIELD( m_flNextUseTime, FIELD_TIME), DEFINE_FIELD( m_vecForward, FIELD_VECTOR), DEFINE_KEYFIELD( m_nodeFOV, FIELD_FLOAT, "nodeFOV" ), DEFINE_THINKFUNC( EnableThink ), // Inputs DEFINE_INPUTFUNC( FIELD_VOID, "EnableHint", InputEnableHint ), DEFINE_INPUTFUNC( FIELD_VOID, "DisableHint", InputDisableHint ), // Outputs DEFINE_OUTPUT( m_OnNPCStartedUsing, "OnNPCStartedUsing" ), DEFINE_OUTPUT( m_OnNPCStoppedUsing, "OnNPCStoppedUsing" ), END_DATADESC( ); //------------------------------------------------------------------------------ // Purpose : //------------------------------------------------------------------------------ void CAI_Hint::InputEnableHint( inputdata_t &inputdata ) { m_NodeData.iDisabled = false; } //------------------------------------------------------------------------------ // Purpose : //------------------------------------------------------------------------------ void CAI_Hint::InputDisableHint( inputdata_t &inputdata ) { m_NodeData.iDisabled = true; } //------------------------------------------------------------------------------ // Purpose : // Input : // Output : //------------------------------------------------------------------------------ void CAI_Hint::Spawn( void ) { // Cache off the forward vector GetVectors( &m_vecForward, NULL, NULL ); if( m_nodeFOV != 360 ) { // As a micro-optimization, leave the FOV at 360 to save us // a dot product later when checking node FOV. m_nodeFOV = cos( DEG2RAD(m_nodeFOV/2) ); } SetSolid( SOLID_NONE ); } void CAI_Hint::Activate() { BaseClass::Activate(); CAI_HintManager::AddHint( this ); } void CAI_Hint::UpdateOnRemove( void ) { CAI_HintManager::RemoveHint( this ); BaseClass::UpdateOnRemove(); } //------------------------------------------------------------------------------ // Purpose : If connected to a node returns node position, otherwise // returns local hint position // // NOTE: Assumes not using multiple AI networks // Input : // Output : //------------------------------------------------------------------------------ void CAI_Hint::GetPosition(CBaseCombatCharacter *pBCC, Vector *vPosition) { if ( m_NodeData.nNodeID != NO_NODE ) { *vPosition = g_pBigAINet->GetNodePosition( pBCC, m_NodeData.nNodeID ); } else { *vPosition = GetAbsOrigin(); } } //----------------------------------------------------------------------------- // Purpose: // Input : hull - // *vPosition - //----------------------------------------------------------------------------- void CAI_Hint::GetPosition( Hull_t hull, Vector *vPosition ) { if ( m_NodeData.nNodeID != NO_NODE ) { *vPosition = g_pBigAINet->GetNodePosition( hull, m_NodeData.nNodeID ); } else { *vPosition = GetAbsOrigin(); } } //------------------------------------------------------------------------------ // Purpose : If connected to a node returns node direction, otherwise // returns local hint direction // // NOTE: Assumes not using multiple AI networks // Input : // Output : //------------------------------------------------------------------------------ Vector CAI_Hint::GetDirection( ) { return UTIL_YawToVector( Yaw() ); } //------------------------------------------------------------------------------ // Purpose : If connected to a node returns node yaw, otherwise // returns local hint yaw // // NOTE: Assumes not using multiple AI networks // Input : // Output : //------------------------------------------------------------------------------ float CAI_Hint::Yaw(void) { if (m_NodeData.nNodeID != NO_NODE) { return g_pBigAINet->GetNodeYaw(m_NodeData.nNodeID ); } else { return GetLocalAngles().y; } } //------------------------------------------------------------------------------ // Purpose : Returns if this is something that's interesting to look at // // NOTE: Assumes not using multiple AI networks // Input : // Output : //------------------------------------------------------------------------------ bool CAI_Hint::IsViewable(void) { if (m_NodeData.iDisabled) { return false; } switch( HintType() ) { case HINT_WORLD_VISUALLY_INTERESTING: case HINT_WORLD_VISUALLY_INTERESTING_DONT_AIM: case HINT_WORLD_VISUALLY_INTERESTING_STEALTH: return true; } return false; } //----------------------------------------------------------------------------- //----------------------------------------------------------------------------- bool CAI_Hint::IsInNodeFOV( CBaseEntity *pOther ) { if( m_nodeFOV == 360 ) { return true; } #if 0 NDebugOverlay::Line( GetAbsOrigin(), GetAbsOrigin() + m_vecForward * 16, 255, 255, 0, false, 1 ); #endif Vector vecToNPC = pOther->GetAbsOrigin() - GetAbsOrigin(); VectorNormalize( vecToNPC ); float flDot = DotProduct( vecToNPC, m_vecForward ); if( flDot > m_nodeFOV ) { #if 0 NDebugOverlay::Line( GetAbsOrigin(), pOther->GetAbsOrigin(), 0, 255, 0, false, 1 ); #endif return true; } #if 0 NDebugOverlay::Line( GetAbsOrigin(), pOther->GetAbsOrigin(), 255, 0, 0, false, 1 ); #endif return false; } //----------------------------------------------------------------------------- // Purpose: Locks the node for use by an AI for hints // Output : Returns true if the node was available for locking, false on failure. //----------------------------------------------------------------------------- bool CAI_Hint::Lock( CBaseEntity* pNPC ) { if ( m_hHintOwner != pNPC && m_hHintOwner != NULL ) return false; m_hHintOwner = pNPC; return true; } //----------------------------------------------------------------------------- // Purpose: Unlocks the node, making it available for hint use by other AIs. // after the given delay time //----------------------------------------------------------------------------- void CAI_Hint::Unlock( float delay ) { m_hHintOwner = NULL; m_flNextUseTime = gpGlobals->curtime + delay; } //----------------------------------------------------------------------------- // Purpose: Returns true is hint node is open for use // Input : // Output : //----------------------------------------------------------------------------- bool CAI_Hint::IsLockedBy( CBaseEntity *pNPC ) { return (m_hHintOwner == pNPC); }; //----------------------------------------------------------------------------- // Purpose: Returns true is hint node is open for use // Input : // Output : //----------------------------------------------------------------------------- bool CAI_Hint::IsLocked( void ) { if (m_NodeData.iDisabled) { return true; } if (gpGlobals->curtime < m_flNextUseTime) { return true; } if (m_hHintOwner != NULL) { return true; } return false; }; //----------------------------------------------------------------------------- // Purpose: Return true if pTestHint passes the criteria specified in hintCriteria //----------------------------------------------------------------------------- bool CAI_Hint::HintMatchesCriteria( CAI_BaseNPC *pNPC, const CHintCriteria &hintCriteria, const Vector &position, float *flNearestDistance, bool bIgnoreLock, bool bIgnoreHintType ) { // Cannot be locked if ( !bIgnoreLock && IsLocked() ) { REPORTFAILURE( "Node is locked." ); return false; } if ( !bIgnoreHintType && !hintCriteria.MatchesHintType( HintType() ) ) { return false; } if ( GetMinState() > NPC_STATE_IDLE || GetMaxState() < NPC_STATE_COMBAT ) { if ( pNPC && ( pNPC->GetState() < GetMinState() || pNPC->GetState() > GetMaxState() ) ) { REPORTFAILURE( "NPC not in correct state." ); return false; } } // See if we're filtering by group name if ( hintCriteria.GetGroup() != NULL_STRING ) { AssertIsValidString( GetGroup() ); AssertIsValidString( hintCriteria.GetGroup() ); if ( GetGroup() == NULL_STRING || GetGroup() != hintCriteria.GetGroup() ) { Assert(GetGroup() == NULL_STRING || strcmp( STRING(GetGroup()), STRING(hintCriteria.GetGroup())) != 0 ); REPORTFAILURE( "Doesn't match NPC hint group." ); return false; } } // If we're watching for include zones, test it if ( ( hintCriteria.HasIncludeZones() ) && ( hintCriteria.InIncludedZone( GetAbsOrigin() ) == false ) ) { REPORTFAILURE( "Not inside include zones." ); return false; } // If we're watching for exclude zones, test it if ( ( hintCriteria.HasExcludeZones() ) && ( hintCriteria.InExcludedZone( GetAbsOrigin() ) ) ) { REPORTFAILURE( "Inside exclude zones." ); return false; } // See if the class handles this hint type if ( ( pNPC != NULL ) && ( pNPC->FValidateHintType( this ) == false ) ) { REPORTFAILURE( "NPC doesn't know how to handle that type." ); return false; } // Test against generic filter if ( !hintCriteria.PassesFilter( this ) ) { REPORTFAILURE( "Failed filter test" ); return false; } int nRadius = GetRadius(); if ( nRadius != 0 ) { // Calculate our distance float distance = (GetAbsOrigin() - position).LengthSqr(); if ( distance > nRadius * nRadius ) { REPORTFAILURE( "NPC is not within the node's radius." ); return false; } } if ( hintCriteria.HasFlag(bits_HINT_NPC_IN_NODE_FOV) ) { if ( pNPC == NULL ) { AssertMsg(0,"Hint node attempted to verify NPC in node FOV without NPC!\n"); } else { if( !IsInNodeFOV(pNPC) ) { REPORTFAILURE( "NPC Not in hint's FOV" ); return false; } } } if ( hintCriteria.HasFlag( bits_HINT_NODE_IN_AIMCONE ) ) { if ( pNPC == NULL ) { AssertMsg( 0, "Hint node attempted to find node in aimcone without specifying NPC!\n" ); } else { if( !pNPC->FInAimCone( GetAbsOrigin() ) ) { REPORTFAILURE( "Hint isn't in NPC's aimcone" ); return false; } } } if ( hintCriteria.HasFlag( bits_HINT_NODE_IN_VIEWCONE ) ) { if ( pNPC == NULL ) { AssertMsg( 0, "Hint node attempted to find node in viewcone without specifying NPC!\n" ); } else { if( !pNPC->FInViewCone( this ) ) { REPORTFAILURE( "Hint isn't in NPC's viewcone" ); return false; } } } if ( hintCriteria.HasFlag( bits_HINT_NOT_CLOSE_TO_ENEMY ) ) { if ( pNPC == NULL ) { AssertMsg( 0, "Hint node attempted to find node not close to enemy without specifying NPC!\n" ); } else { if( pNPC->GetEnemy() ) { float flDistHintToEnemySqr = GetAbsOrigin().DistToSqr( pNPC->GetEnemy()->GetAbsOrigin() ) ; if( flDistHintToEnemySqr < Square( 30.0f * 12.0f ) ) { REPORTFAILURE( "Hint takes NPC close to Enemy" ); return false; } } } } { AI_PROFILE_SCOPE( HINT_FVisible ); // See if we're requesting a visible node if ( hintCriteria.HasFlag( bits_HINT_NODE_VISIBLE ) ) { if ( pNPC == NULL ) { //NOTENOTE: If you're hitting this, you've asked for a visible node without specifing an NPC! AssertMsg( 0, "Hint node attempted to find visible node without specifying NPC!\n" ); } else { if( m_NodeData.nNodeID == NO_NODE ) { // This is just an info_hint, not a node. if( !pNPC->FVisible( this ) ) { REPORTFAILURE( "Hint isn't visible to NPC." ); return false; } } else { // This hint associated with a node. trace_t tr; Vector vHintPos; GetPosition(pNPC,&vHintPos); AI_TraceLine ( pNPC->EyePosition(), vHintPos + pNPC->GetViewOffset(), pNPC->GetAITraceMask_BrushOnly(), pNPC, COLLISION_GROUP_NONE, &tr ); if ( tr.fraction != 1.0f ) { REPORTFAILURE( "Node isn't visible to NPC." ); return false; } } } } } // Check for clear if requested if ( hintCriteria.HasFlag( bits_HINT_NODE_CLEAR ) ) { if ( pNPC == NULL ) { //NOTENOTE: If you're hitting this, you've asked for a clear node without specifing an NPC! AssertMsg( 0, "Hint node attempted to find clear node without specifying NPC!\n" ); } else { trace_t tr; // Can my bounding box fit there? Vector vStep( 0, 0, pNPC->StepHeight() ); AI_TraceHull ( GetAbsOrigin() + vStep, GetAbsOrigin(), pNPC->WorldAlignMins(), pNPC->WorldAlignMaxs() - vStep, MASK_SOLID, pNPC, COLLISION_GROUP_NONE, &tr ); if ( tr.fraction < 0.95 ) { REPORTFAILURE( "Node isn't clear." ); return false; } } } // See if this is our next, closest node if ( hintCriteria.HasFlag( bits_HINT_NODE_NEAREST ) ) { Assert( flNearestDistance ); // Calculate our distance float distance = (GetAbsOrigin() - position).Length(); // Must be closer than the current best if ( distance > *flNearestDistance ) { REPORTFAILURE( "Not the nearest node." ); return false; } // Remember the distance *flNearestDistance = distance; } if ( hintCriteria.HasFlag(bits_HINT_HAS_LOS_TO_PLAYER|bits_HAS_EYEPOSITION_LOS_TO_PLAYER) ) { CBasePlayer *pPlayer = AI_GetSinglePlayer(); if( pPlayer != NULL ) { Vector vecDest = GetAbsOrigin(); if( hintCriteria.HasFlag(bits_HAS_EYEPOSITION_LOS_TO_PLAYER) ) { vecDest += pNPC->GetDefaultEyeOffset(); } if( !pPlayer->FVisible(vecDest) ) { REPORTFAILURE( "Do not have LOS to player" ); return false; } } } if ( hintCriteria.HasFlag( bits_HINT_HAS_NO_EYEPOSITION_LOS_TO_ENEMY ) ) { CBaseEntity *pEnemy = pNPC->GetEnemy(); if( pEnemy != NULL ) { Vector vecDest = GetAbsOrigin(); vecDest += pNPC->GetNodeViewOffset(); if( pEnemy->FVisible(vecDest) ) { REPORTFAILURE( "Has LOS to enemy" ); return false; } } } // Must either be visible or not if requested if ( hintCriteria.HasFlag( bits_HINT_NODE_NOT_VISIBLE_TO_PLAYER|bits_HINT_NODE_VISIBLE_TO_PLAYER ) ) { bool bWasSeen = false; // Test all potential seers for ( int i = 1; i <= gpGlobals->maxClients; i++ ) { CBasePlayer *pPlayer = UTIL_PlayerByIndex(i); if ( pPlayer ) { // Only spawn if the player's looking away from me Vector vLookDir = pPlayer->EyeDirection3D(); Vector vTargetDir = GetAbsOrigin() - pPlayer->EyePosition(); VectorNormalize(vTargetDir); float fDotPr = DotProduct(vLookDir,vTargetDir); if ( fDotPr > 0 ) { trace_t tr; UTIL_TraceLine( pPlayer->EyePosition(), GetAbsOrigin(), MASK_SOLID_BRUSHONLY, pPlayer, COLLISION_GROUP_NONE, &tr); if ( tr.fraction == 1.0 ) { if ( hintCriteria.HasFlag( bits_HINT_NODE_NOT_VISIBLE_TO_PLAYER ) ) { REPORTFAILURE( "Node is visible to player." ); return false; } bWasSeen = true; } } } } if ( !bWasSeen && hintCriteria.HasFlag( bits_HINT_NODE_VISIBLE_TO_PLAYER ) ) { REPORTFAILURE( "Node isn't visible to player." ); return false; } } return true; } //----------------------------------------------------------------------------- // Purpose: Draw any debug text overlays // Input : // Output : Current text offset from the top //----------------------------------------------------------------------------- int CAI_Hint::DrawDebugTextOverlays(void) { int text_offset = BaseClass::DrawDebugTextOverlays(); if (m_debugOverlays & OVERLAY_TEXT_BIT) { char tempstr[512]; Q_snprintf(tempstr,sizeof(tempstr),"%s (%i)", GetHintTypeDescription( HintType() ), HintType()); EntityText(text_offset,tempstr,0); text_offset++; Q_snprintf(tempstr,sizeof(tempstr),"delay %f", MAX( 0.0f, m_flNextUseTime - gpGlobals->curtime ) ) ; EntityText(text_offset,tempstr,0); text_offset++; if ( m_NodeData.iDisabled ) { Q_snprintf(tempstr,sizeof(tempstr),"DISABLED" ); EntityText(text_offset,tempstr,0); text_offset++; } } return text_offset; } //----------------------------------------------------------------------------- // Purpose: Constructor // Input : // Output : //----------------------------------------------------------------------------- CAI_Hint::CAI_Hint(void) { m_flNextUseTime = 0; m_nTargetNodeID = NO_NODE; } //----------------------------------------------------------------------------- // Purpose: Destructor // Input : // Output : //----------------------------------------------------------------------------- CAI_Hint::~CAI_Hint(void) { } //----------------------------------------------------------------------------- // Purpose: Sometimes FValidateHint, etc. will want to examine the underlying node to // see if it's truly suitable ( e.g., in the same air/ground network of nodes? ) // Output : C_AINode * //----------------------------------------------------------------------------- CAI_Node *CAI_Hint::GetNode( void ) { if ( m_NodeData.nNodeID != NO_NODE ) { return g_pBigAINet->GetNode( m_NodeData.nNodeID, false ); } return NULL; } //----------------------------------------------------------------------------- //----------------------------------------------------------------------------- void CAI_Hint::DisableForSeconds( float flSeconds ) { Unlock( flSeconds ); } //----------------------------------------------------------------------------- //----------------------------------------------------------------------------- void CAI_Hint::EnableThink() { SetDisabled( false ); SetThink( NULL ); } void CAI_Hint::FixupTargetNode() { if ( m_NodeData.nTargetWCNodeID != -1 ) m_nTargetNodeID = g_pAINetworkManager->GetEditOps()->GetNodeIdFromWCId( m_NodeData.nTargetWCNodeID ); else m_nTargetNodeID = NO_NODE; } void CAI_Hint::OnRestore() { BaseClass::OnRestore(); m_NodeData.nNodeID = g_pAINetworkManager->GetEditOps()->GetNodeIdFromWCId( m_NodeData.nWCNodeID ); FixupTargetNode(); CAI_Node *pNode = GetNode(); if ( !pNode ) { if ( m_NodeData.nWCNodeID > 0 ) DevMsg("Warning: AI hint has incorrect or no AI node\n"); } else { m_NodeData.vecPosition = pNode->GetOrigin(); Teleport( &m_NodeData.vecPosition, NULL, NULL ); pNode->SetHint( this ); } } //----------------------------------------------------------------------------- // Purpose: //----------------------------------------------------------------------------- void CAI_Hint::NPCStartedUsing( CAI_BaseNPC *pNPC ) { m_OnNPCStartedUsing.Set( pNPC, pNPC, this ); } //----------------------------------------------------------------------------- // Purpose: //----------------------------------------------------------------------------- void CAI_Hint::NPCStoppedUsing( CAI_BaseNPC *pNPC ) { m_OnNPCStoppedUsing.Set( pNPC, pNPC, this ); } CON_COMMAND(ai_dump_hints, "") { CAI_HintManager::ValidateHints(); CAI_HintManager::DumpHints(); } //----------------------------------------------------------------------------- // // hints - these MUST coincide with the HINTS listed under Hint_e // //----------------------------------------------------------------------------- struct hinttypedescs_t { Hint_e iType; const char *pszDesc; }; hinttypedescs_t g_pszHintDescriptions[] = { { HINT_NONE, "None" }, //{ HINT_NOT_USED_WORLD_DOOR, "Obsolete / Unused" }, { HINT_WORLD_WINDOW, "World: Window" }, //{ HINT_NOT_USED_WORLD_BUTTON, "Obsolete / Unused" }, //{ HINT_NOT_USED_WORLD_MACHINERY, "Obsolete / Unused" }, //{ HINT_NOT_USED_WORLD_LEDGE, "Obsolete / Unused" }, //{ HINT_NOT_USED_WORLD_LIGHT_SOURCE, "Obsolete / Unused" }, //{ HINT_NOT_USED_WORLD_HEAT_SOURCE, "Obsolete / Unused" }, //{ HINT_NOT_USED_WORLD_BLINKING_LIGHT, "Obsolete / Unused" }, //{ HINT_NOT_USED_WORLD_BRIGHT_COLORS, "Obsolete / Unused" }, //{ HINT_NOT_USED_WORLD_HUMAN_BLOOD, "Obsolete / Unused" }, //{ HINT_NOT_USED_WORLD_ALIEN_BLOOD, "Obsolete / Unused" }, { HINT_WORLD_WORK_POSITION, "Act Busy" }, { HINT_WORLD_VISUALLY_INTERESTING, "World: Visually Interesting" }, { HINT_WORLD_VISUALLY_INTERESTING_DONT_AIM, "World: Visually Interesting (Don't Aim)" }, { HINT_WORLD_INHIBIT_COMBINE_MINES, "World: Inhibit Combine Mines" }, { HINT_WORLD_VISUALLY_INTERESTING_STEALTH, "World: Visually Interesting (Stealth)" }, { HINT_TACTICAL_COVER_MED, "Tactical: Cover Medium" }, { HINT_TACTICAL_COVER_LOW, "Tactical: Cover Low" }, //{ HINT_NOT_USED_TACTICAL_SPAWN, "Tactical: Spawn" }, { HINT_TACTICAL_PINCH, "Tactical: Pinch" }, //{ HINT_NOT_USED_TACTICAL_GUARD, "Obsolete / Unused" }, { HINT_TACTICAL_ENEMY_DISADVANTAGED, "Tactical: Enemy Disadvantage" }, //{ HINT_NOT_USED_HEALTH_KIT, "Obsolete / Unused" }, { HINT_TACTICAL_HIGH_GROUND, "Tactical: High Ground" }, //{ HINT_NOT_USED_URBAN_STREETCORNER, "Obsolete / Unused" }, //{ HINT_NOT_USED_URBAN_STREETLAMP, "Obsolete / Unused" }, //{ HINT_NOT_USED_URBAN_DARK_SPOT, "Obsolete / Unused" }, //{ HINT_NOT_USED_URBAN_POSTER, "Obsolete / Unused" }, //{ HINT_NOT_USED_URBAN_SHELTER, "Obsolete / Unused" }, //{ HINT_NOT_USED_ASSASSIN_SECLUDED, "Obsolete / Unused" }, //{ HINT_NOT_USED_ASSASSIN_RAFTERS, "Obsolete / Unused" }, //{ HINT_NOT_USED_ASSASSIN_GROUND, "Obsolete / Unused" }, //{ HINT_NOT_USED_ASSASSIN_MONKEYBARS, "Obsolete / Unused" }, { HINT_ANTLION_BURROW_POINT, "Antlion: Burrow Point" }, { HINT_ANTLION_THUMPER_FLEE_POINT, "Antlion: Thumper Flee Point" }, //{ HINT_HEADCRAB_BURROW_POINT, "Obsolete / Unused" }, //{ HINT_NOT_USED_ROLLER_PATROL_POINT, "Obsolete / Unused" }, //{ HINT_NOT_USED_ROLLER_CLEANUP_POINT, "Obsolete / Unused" }, //{ HINT_NOT_USED_PSTORM_ROCK_SPAWN, "Obsolete / Unused" }, { HINT_CROW_FLYTO_POINT, "Crow: Flyto Point" }, //{ HINT_BUG_PATROL_POINT, "Obsolete / Unused" }, { HINT_FOLLOW_WAIT_POINT, "Follow: Wait Point" }, { HINT_JUMP_OVERRIDE, "Jump Override" }, { HINT_PLAYER_SQUAD_TRANSITON_POINT, "Squad Transition Point" }, { HINT_NPC_EXIT_POINT, "Act Busy: Exit Point" }, { HINT_STRIDER_NODE, "Strider" }, { HINT_PLAYER_ALLY_MOVE_AWAY_DEST, "Ally MoveAway Point" }, { HINT_CSTRIKE_HOSTAGE_ESCAPE, "CS Port: Hostage Escape" }, }; //----------------------------------------------------------------------------- // Purpose: //----------------------------------------------------------------------------- const char *GetHintTypeDescription( Hint_e iHintType ) { for ( int i = 0; i < ARRAYSIZE(g_pszHintDescriptions); i++ ) { if ( g_pszHintDescriptions[i].iType == iHintType ) return g_pszHintDescriptions[i].pszDesc; } return "Obsolete / Unused"; } //----------------------------------------------------------------------------- // Purpose: //----------------------------------------------------------------------------- const char *GetHintTypeDescription( CAI_Hint *pHint ) { return GetHintTypeDescription( pHint->HintType() ); } //----------------------------------------------------------------------------- // Purpose: Debug command to drop hints into the world //----------------------------------------------------------------------------- void CC_ai_drop_hint( const CCommand &args ) { CBasePlayer *pPlayer = ToBasePlayer( UTIL_GetCommandClient() ); if ( !pPlayer ) return; if ( args.ArgC() < 2 ) { Msg("Invalid hint type specified. Format: ai_drop_hint \nValid hint types:\n"); for ( int i = 0; i < ARRAYSIZE(g_pszHintDescriptions); i++ ) { Msg("%d : %s\n", g_pszHintDescriptions[i].iType, g_pszHintDescriptions[i].pszDesc ); } return; } HintNodeData nodeData; nodeData.strEntityName = MAKE_STRING("ai_drop_hint"); nodeData.vecPosition = pPlayer->EyePosition(); nodeData.nHintType = atoi( args[1] ); nodeData.nNodeID = NO_NODE; nodeData.strGroup = NULL_STRING; nodeData.iDisabled = false; nodeData.iszActivityName = NULL_STRING; nodeData.fIgnoreFacing = HIF_DEFAULT; nodeData.minState = NPC_STATE_IDLE; nodeData.maxState = NPC_STATE_COMBAT; nodeData.nRadius = 0; CAI_Hint *pHint = CAI_HintManager::CreateHint( &nodeData, NULL ); if ( pHint ) { ((CBaseEntity *)pHint)->Activate(); pHint->KeyValue( "nodeFOV", "360" ); pHint->m_debugOverlays |= (OVERLAY_TEXT_BIT | OVERLAY_BBOX_BIT); } } ConCommand ai_drop_hint( "ai_drop_hint", CC_ai_drop_hint, "Drop an ai_hint at the player's current eye position.", FCVAR_CHEAT );