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libcm/cmGr.c

2870 wiersze
72 KiB
C
Czysty Wina Historia

#include "cmGlobal.h"
#include "cmFloatTypes.h"
#include "cmRpt.h"
#include "cmErr.h"
#include "cmCtx.h"
#include "cmMem.h"
#include "cmMallocDebug.h"
#include "cmLinkedHeap.h"
#include "cmGr.h"
#include "cmGrDevCtx.h"
// cmGr_t state flags
enum
{
kDirtyGrFl = 0x01 // the cmGr object is dirty
};
typedef struct cmGrObj_str
{
unsigned id; //
cmGrObjFunc_t f; //
cmGrVExt_t wext; // world coord's contained within this object (children of this object are contained by these extents)
unsigned wlimitFlags; // kLeftGrFl | kRightGrFl | kTopGrFl | kBottomGrFl
cmGrVExt_t wlimitExt; // limit extents for wext (ext's with set flags always define the associated wext value)
struct cmGrObj_str* parent;
struct cmGrObj_str* children;
struct cmGrObj_str* rsib;
struct cmGrObj_str* lsib;
} cmGrObj_t;
typedef struct cmGrSync_str
{
cmGrH_t grH;
unsigned flags; // kGrXXXSyncGrFl
struct cmGrSync_str* link;
} cmGrSync_t;
typedef struct cmGrColorMap_str
{
const cmChar_t* label;
unsigned id;
cmGrColor_t* map;
unsigned cnt;
struct cmGrColorMap_str* link;
} cmGrColorMap_t;
typedef struct cmGrKeyMap_str
{
unsigned idx; // index of this keymap entry (used for debugging)
char ascii; // printible ascii character associated with this keycode or 0 if not printable
cmGrKeyCodeId_t keycode; // cmGr keycode
} cmGrKeyMap_t;
typedef struct
{
cmCtx_t ctx;
cmErr_t err;
unsigned id; // user definable id
cmLHeapH_t lhH;
unsigned cfgFlags;
unsigned stateFlags;
cmGrObj_t* msDnObj; // obj under last ms dn
cmGrPPt_t msDnPPt; // last ms dn loc'n
cmGrVPt_t msDnVPt; // last ms dn in same coords as msDnObj->vext (inside msDnObj->parent->wxt)
cmGrVPt_t msVPt; // cur ms pt in same coords as msDnObj->vext (inside msDnObj->parent->wxt)
cmGrVSz_t msDnVOffs;
bool selValidFl;
cmGrVPt_t sel0Pt;
cmGrVPt_t sel1Pt;
cmGrVPt_t localPt;
cmGrVPt_t globalPt;
cmGrVExt_t vext; // view virtual extents
cmGrPExt_t pext; // view physical extents
cmGrObj_t* objs; // object tree
cmGrObj_t* rootObj; // current root object
unsigned char* img; // temporary image inversion buffer
cmGrCbFunc_t cbFunc; //
void* cbArg; //
cmGrSync_t* syncs; //
cmGrColorMap_t* maps; // color maps
} cmGr_t;
cmGrH_t cmGrNullHandle = cmSTATIC_NULL_HANDLE;
cmGrObjH_t cmGrObjNullHandle = cmSTATIC_NULL_HANDLE;
cmGrKeyMap_t _cmGrKeyMap[] =
{
{ 0, 0, 0 },
{ 1, 0, 0 },
{ 2, 0, 0 },
{ 3, 0, 0 },
{ 4, 0, 0 },
{ 5, 0, kHomeGrId},
{ 6, 0, kPageUpGrId},
{ 7, 0, kEndGrId},
{ 8, 8, kBackSpaceGrId },
{ 9, 9, kTabGrId },
{ 10, 0, kPageDownGrId},
{ 11, 0, kLeftGrId},
{ 12, 0, kUpGrId},
{ 13, 13, kEnterGrId },
{ 14, 0, kRightGrId},
{ 15, 0, kDownGrId},
{ 16, 0, kInsertGrId},
{ 17, 0, kPrintGrId},
{ 18, 0, kScrollLockGrId},
{ 19, 0, kPauseGrId},
{ 20, 0, kMenuGrId},
{ 21, 0, kLShiftGrId},
{ 22, 0, kRShiftGrId},
{ 23, 0, kLCtrlGrId},
{ 24, 0, kRCtrlGrId},
{ 25, 0, kLAltGrId},
{ 26, 0, kRAltGrId},
{ 27, 27, kEscapeGrId },
{ 28, 0, kLSuperGrId},
{ 29, 0, kRSuperGrId},
{ 30, 0, kNumLockGrId},
{ 31, 0, kCapsLockGrId},
{ 32, 32, kSpaceGrId },
{ 33, 33, kExclMarkGrId },
{ 34, 34, kDQuoteGrId },
{ 35, 35, kPoundGrId },
{ 36, 36, kDollarGrId },
{ 37, 37, kPercentGrId },
{ 38, 38, kAmpersandGrId },
{ 39, 39, kApostropheGrId },
{ 40, 40, kLParenGrId },
{ 41, 41, kRParenGrId },
{ 42, 42, kAsteriskGrId },
{ 43, 43, kPlusGrId },
{ 44, 44, kCommaGrId },
{ 45, 45, kHyphenGrId },
{ 46, 46, kPeriodGrId },
{ 47, 47, kForwardSlashGrId },
{ 48, 48, k0GrId },
{ 49, 49, k1GrId },
{ 50, 50, k2GrId },
{ 51, 51, k3GrId },
{ 52, 52, k4GrId },
{ 53, 53, k5GrId },
{ 54, 54, k6GrId },
{ 55, 55, k7GrId },
{ 56, 56, k8GrId },
{ 57, 57, k9GrId },
{ 58, 58, kColonGrId },
{ 59, 59, kSemiColonGrId },
{ 60, 60, kLesserGrId },
{ 61, 61, kEqualGrId },
{ 62, 62, kGreaterGrId },
{ 63, 63, kQMarkGrId },
{ 64, 64, kAtGrId },
{ 65, 65, kA_GrId },
{ 66, 66, kB_GrId },
{ 67, 67, kC_GrId },
{ 68, 68, kD_GrId },
{ 69, 69, kE_GrId },
{ 70, 70, kF_GrId },
{ 71, 71, kG_GrId },
{ 72, 72, kH_GrId },
{ 73, 73, kI_GrId },
{ 74, 74, kJ_GrId },
{ 75, 75, kK_GrId },
{ 76, 76, kL_GrId },
{ 77, 77, kM_GrId },
{ 78, 78, kN_GrId },
{ 79, 79, kO_GrId },
{ 80, 80, kP_GrId },
{ 81, 81, kQ_GrId },
{ 82, 82, kR_GrId },
{ 83, 83, kS_GrId },
{ 84, 84, kT_GrId },
{ 85, 85, kU_GrId },
{ 86, 86, kV_GrId },
{ 87, 87, kW_GrId },
{ 88, 88, kX_GrId },
{ 89, 89, kY_GrId },
{ 90, 90, kZ_GrId },
{ 91, 91, kLBracketGrId },
{ 92, 92, kBackSlashGrId },
{ 93, 93, kRBracketGrId },
{ 94, 94, kCaretGrId },
{ 95, 95, kUnderScoreGrId },
{ 96, 96, kAccentGrId },
{ 97, 97, ka_GrId },
{ 98, 98, kb_GrId },
{ 99, 99, kc_GrId },
{ 100, 100, kd_GrId },
{ 101, 101, ke_GrId },
{ 102, 102, kf_GrId },
{ 103, 103, kg_GrId },
{ 104, 104, kh_GrId },
{ 105, 105, ki_GrId },
{ 106, 106, kj_GrId },
{ 107, 107, kk_GrId },
{ 108, 108, kl_GrId },
{ 109, 109, km_GrId },
{ 110, 110, kn_GrId },
{ 111, 111, ko_GrId },
{ 112, 112, kp_GrId },
{ 113, 113, kq_GrId },
{ 114, 114, kr_GrId },
{ 115, 115, ks_GrId },
{ 116, 116, kt_GrId },
{ 117, 117, ku_GrId },
{ 118, 118, kv_GrId },
{ 119, 119, kw_GrId },
{ 120, 120, kx_GrId },
{ 121, 121, ky_GrId },
{ 122, 122, kz_GrId },
{ 123, 123, kLBraceGrId },
{ 124, 124, kPipeGrId },
{ 125, 125, kRBraceGrId },
{ 126, 126, kTildeGrId },
{ 127, 127, kDeleteGrId },
{ 128, 42, kNP_MultGrId },
{ 129, 43, kNP_PlusGrId },
{ 130, 45, kNP_MinusGrId },
{ 131, 46, kNP_DecPtGrId},
{ 132, 47, kNP_DivGrId},
{ 133, 48, kNP_0GrId},
{ 134, 49, kNP_1GrId},
{ 135, 50, kNP_2GrId},
{ 136, 51, kNP_3GrId},
{ 137, 52, kNP_4GrId},
{ 138, 53, kNP_5GrId},
{ 139, 54, kNP_6GrId},
{ 140, 55, kNP_7GrId},
{ 141, 56, kNP_8GrId},
{ 142, 57, kNP_9GrId},
{ 143, 61, kNP_EqualGrId},
{ 144, 13, kNP_EnterGrId},
{ 145, 0, kFunc_1GrId},
{ 146, 0, kFunc_2GrId},
{ 147, 0, kFunc_3GrId},
{ 148, 0, kFunc_4GrId},
{ 149, 0, kFunc_5GrId},
{ 150, 0, kFunc_6GrId},
{ 151, 0, kFunc_7GrId},
{ 152, 0, kFunc_8GrId},
{ 153, 0, kFunc_9GrId},
{ 154, 0, kFunc_10GrId},
{ 155, 0, kFunc_11GrId},
{ 156, 0, kFunc_12GrId},
{ 157, 0, kBrightUpGrId},
{ 158, 0, kBrightDnGrId},
{ 159, 0, kAudio_PrevGrId},
{ 160, 0, kAudio_PlayGrId},
{ 161, 0, kAudio_NextGrId},
{ 162, 0, kAudio_MuteGrId},
{ 163, 0, kAudio_DnGrId },
{ 164, 0, kAudio_UpGrId },
{ 165, 0, kEjectGrId },
{ cmInvalidIdx, 0, cmInvalidId}
};
void _cmGrKeyMapValidate()
{
unsigned i;
for(i=0; _cmGrKeyMap[i].idx != cmInvalidIdx; ++i)
{
assert( _cmGrKeyMap[i].idx == i );
}
}
cmGrKeyMap_t* _cmGrFindKeyMap( unsigned keycode )
{
// printable ascii codes match their indexes
if( 32 <= keycode && keycode <= 126 )
return _cmGrKeyMap + keycode;
unsigned i;
for(i=0; i<32; ++i)
if( _cmGrKeyMap[i].keycode == keycode )
return _cmGrKeyMap + i;
for(i=127; _cmGrKeyMap[i].idx != cmInvalidIdx; ++i)
if( _cmGrKeyMap[i].keycode == keycode )
return _cmGrKeyMap + i;
assert(0);
return NULL;
}
bool _cmGrSetViewExtents( cmGr_t* p, cmGrV_t minx, cmGrV_t miny, cmGrV_t maxx, cmGrV_t maxy );
bool _cmGrSetViewExtentsE( cmGr_t* p, const cmGrVExt_t* e )
{ return _cmGrSetViewExtents(p, cmGrVExtMinX(e), cmGrVExtMinY(e), cmGrVExtMaxX(e), cmGrVExtMaxY(e) ); }
//====================================================================================================
// Expand cmGrVExt_t e0 to hold e1.
// Return true if e0 is actually changed.
bool cmGrVExtExpandToContain(cmGrVExt_t* e0, const cmGrVExt_t* e1)
{
bool fl = false;
if( cmGrVExtIsNullOrEmpty(e0) )
{
*e0 = *e1;
return true;
}
assert( cmGrVExtIsNorm(e0) && cmGrVExtIsNorm(e1) );
// min-x
if( cmGrVExtMinX(e0) > cmGrVExtMinX(e1) )
{
cmGrVExtSetMinX(e0, cmGrVExtMinX(e1));
fl = true;
}
// min-y
if( cmGrVExtMinY(e0) > cmGrVExtMinY(e1) )
{
cmGrVExtSetMinY(e0, cmGrVExtMinY(e1));
fl = true;
}
// max-y
if( cmGrVExtMaxY(e0) < cmGrVExtMaxY(e1) )
{
cmGrVExtSetMaxY(e0, cmGrVExtMaxY(e1));
fl = true;
}
// max-x
if( cmGrVExtMaxX(e0) < cmGrVExtMaxX(e1) )
{
cmGrVExtSetMaxX(e0, cmGrVExtMaxX(e1));
fl = true;
}
return fl;
}
bool cmGrVExtContain( const cmGrVExt_t* e0, cmGrVExt_t* e1 )
{
bool fl = false;
assert( cmGrVExtIsNorm(e0) && cmGrVExtIsNorm(e1) );
// e1 must be able to fit inside e0
assert( e1->sz.w <= e0->sz.w && e1->sz.h <= e0->sz.h );
// if left edge of e1 is to left of e0
if( cmGrVExtMinX(e1) < cmGrVExtMinX(e0) )
{
cmGrVExtSetMinX(e1,cmGrVExtMinX(e0));
fl = true;
}
// if right edge of e1 is to right of e0
if( cmGrVExtMaxX(e1) > cmGrVExtMaxX(e0) )
{
cmGrVExtSetMaxX(e1,cmGrVExtMaxX(e0));
fl = true;
}
// if the bottom edge of e1 is below the bottom edge of e0
if( cmGrVExtMinY(e1) < cmGrVExtMinY(e0) )
{
cmGrVExtSetMinY(e1,cmGrVExtMinY(e0));
fl = true;
}
// if top edge of e1 is above the top edge of e0
if( cmGrVExtMaxY(e1) > cmGrVExtMaxY(e0) )
{
cmGrVExtSetMaxY(e1,cmGrVExtMaxY(e0));
fl = true;
}
return fl;
}
void cmGrPExtIntersect( cmGrPExt_t* r, const cmGrPExt_t* e0, const cmGrPExt_t* e1 )
{
if( cmGrPExtR(e0) < cmGrPExtL(e1) || cmGrPExtL(e0) > cmGrPExtR(e1)
|| cmGrPExtB(e0) < cmGrPExtT(e1) || cmGrPExtT(e0) > cmGrPExtB(e1) )
{
cmGrPExtSetEmpty(r);
return;
}
cmGrPExtSetD(r,
cmMax( cmGrPExtL(e0), cmGrPExtL(e1) ),
cmMax( cmGrPExtT(e0), cmGrPExtT(e1) ),
cmMin( cmGrPExtR(e0), cmGrPExtR(e1) ),
cmMin( cmGrPExtB(e0), cmGrPExtB(e1) ) );
}
void cmGrVExtIntersect( cmGrVExt_t* r, const cmGrVExt_t* e0, const cmGrVExt_t* e1 )
{
if( cmGrVExtMaxX(e0) < cmGrVExtMinX(e1) || cmGrVExtMinX(e0) > cmGrVExtMaxX(e1)
|| cmGrVExtMaxY(e0) < cmGrVExtMinY(e1) || cmGrVExtMinY(e0) > cmGrVExtMaxY(e1) )
{
cmGrVExtSetEmpty(r);
return;
}
cmGrVExtSetD(r,
cmMax( cmGrVExtMinX(e0), cmGrVExtMinX(e1) ),
cmMax( cmGrVExtMinY(e0), cmGrVExtMinY(e1) ),
cmMin( cmGrVExtMaxX(e0), cmGrVExtMaxX(e1) ),
cmMin( cmGrVExtMaxY(e0), cmGrVExtMaxY(e1) ) );
}
//====================================================================================================
//====================================================================================================
cmGr_t* _cmGrHandleToPtr( cmGrH_t h )
{
cmGr_t* p = (cmGr_t*)h.h;
assert( p != NULL );
return p;
}
cmGrObj_t* _cmGrObjHandleToPtr( cmGrObjH_t h )
{
cmGrObj_t* p = (cmGrObj_t*)h.h;
assert( p != NULL );
return p;
}
//====================================================================================================
unsigned cmGrColorMapCount( cmGrH_t grH )
{
cmGr_t* p = _cmGrHandleToPtr(grH);
cmGrColorMap_t* cmp = p->maps;
unsigned n = 0;
for(; cmp!=NULL; cmp=cmp->link)
++n;
return n;
}
cmGrColorMap_t* _cmGrColorMapFromIndex( cmGr_t* p, unsigned idx )
{
unsigned i = 0;
cmGrColorMap_t* cmp = p->maps;
for(; cmp!=NULL; ++i,cmp=cmp->link)
if( i == idx )
break;
return cmp;
}
cmGrColorMap_t* _cmGrColorMapFromId( cmGr_t* p, unsigned id )
{
cmGrColorMap_t* cmp = p->maps;
for(; cmp!=NULL; cmp=cmp->link)
if( cmp->id == id )
break;
return cmp;
}
unsigned cmGrColorMapId( cmGrH_t grH, unsigned mapIdx )
{
cmGr_t* p = _cmGrHandleToPtr(grH);
cmGrColorMap_t* cmp;
if((cmp = _cmGrColorMapFromIndex(p,mapIdx)) == NULL )
return cmInvalidId;
return cmp->id;
}
const cmChar_t* cmGrColorMapLabel( cmGrH_t grH, unsigned id )
{
cmGr_t* p = _cmGrHandleToPtr(grH);
cmGrColorMap_t* cmp;
if((cmp = _cmGrColorMapFromId(p,id)) == NULL )
return NULL;
return cmp->label;
}
unsigned _cmGrColorMapRegister( cmGr_t* p, cmChar_t* label, const cmGrColor_t* array, unsigned cnt )
{
// locate an available id
unsigned id = 0;
while( _cmGrColorMapFromId(p,id)!=NULL )
++id;
cmGrColorMap_t* cmp = cmLhAllocZ(p->lhH,cmGrColorMap_t,1);
cmp->label = cmLhAllocStr(p->lhH,label);
cmp->id = id;
cmp->map = cmLhAllocZ(p->lhH,cmGrColor_t,cnt);
cmp->cnt = cnt;
cmp->link = p->maps;
p->maps = cmp;
memcpy(cmp->map,array,sizeof(cmGrColor_t)*cnt);
return id;
}
unsigned cmGrColorMapRegister( cmGrH_t grH, cmChar_t* label, const cmGrColor_t* array, unsigned cnt )
{ return _cmGrColorMapRegister( _cmGrHandleToPtr(grH),label, array, cnt ); }
cmGrColor_t* cmGrColorMap( cmGrH_t grH, unsigned mapId )
{
cmGr_t* p = _cmGrHandleToPtr(grH);
cmGrColorMap_t* cmp;
if((cmp = _cmGrColorMapFromId(p,mapId)) == NULL )
return NULL;
return cmp->map;
}
unsigned cmGrColorMapEleCount( cmGrH_t grH, unsigned mapId )
{
cmGr_t* p = _cmGrHandleToPtr(grH);
cmGrColorMap_t* cmp;
if((cmp = _cmGrColorMapFromId(p,mapId)) == NULL )
return cmInvalidId;
return cmp->cnt;
}
void _cmGrRgbInitDefaultColorMap( cmGr_t* p )
{
unsigned map[] =
{
0x000000, // black
0x00008b, // dark blue
0x0000ff, // blue
0x008080, // teal
0x00ffff, // cyan
0x00ff7f, // spring green
0x00ff00, // green
0x7cfc00, // lawn green
0xffff00, // yellow
0xff7f7f, // pink
0xff00ff, // magenta
0xff007f, //
0xff0000, // red
0x7f0000, //
0xffffff // white
};
unsigned n = sizeof(map)/sizeof(unsigned);
_cmGrColorMapRegister(p,"default",map,n);
}
//====================================================================================================
// Object Callback Functions
//====================================================================================================
void _cmGrObjSetupFuncArgs( cmGrObjFuncArgs_t* a, cmGr_t* p, cmGrObj_t* op )
{
cmGrH_t h;
cmGrObjH_t oh;
h.h = p;
oh.h = op;
a->ctx = &p->ctx;
a->grH = h;
a->objH = oh;
a->msDnPPt = p->msDnPPt;
a->msDnVPt = p->msDnVPt;
a->msDnVOffs = p->msDnVOffs;
a->msVPt = p->msVPt;
oh.h = p->msDnObj;
a->msDnObjH = oh;
}
cmGrRC_t _cmGrObjCbCreate( cmGr_t* p, cmGrObj_t* op )
{
cmGrRC_t rc = kOkGrRC;
if( op->f.createCbFunc != NULL )
{
cmGrObjFuncArgs_t a;
_cmGrObjSetupFuncArgs(&a,p,op);
a.cbArg = op->f.createCbArg;
if((rc = op->f.createCbFunc(&a)) != kOkGrRC )
rc = cmErrMsg(&p->err,kAppErrGrRC,"An application object (id=%i) failed on 'create'",op->id);
}
return rc;
}
void _cmGrObjCbDestroy( cmGr_t* p, cmGrObj_t* op )
{
if( op->f.destroyCbFunc != NULL )
{
cmGrObjFuncArgs_t a;
_cmGrObjSetupFuncArgs(&a,p,op);
a.cbArg = op->f.destroyCbArg;
op->f.destroyCbFunc(&a);
}
}
void _cmGrObjCbRender( cmGr_t* p, cmGrDcH_t dcH, const cmGrObj_t* op )
{
if( op->f.renderCbFunc != NULL )
{
cmGrObjFuncArgs_t a;
_cmGrObjSetupFuncArgs(&a,p,(cmGrObj_t*)op);
a.cbArg = op->f.renderCbArg;
op->f.renderCbFunc(&a, dcH );
}
}
int _cmGrObjCbDistance( cmGr_t* p, const cmGrObj_t* op, int px, int py )
{
int d = INT_MAX;
if( op->f.distanceCbFunc != NULL )
{
cmGrObjFuncArgs_t a;
_cmGrObjSetupFuncArgs(&a,p,(cmGrObj_t*)op);
a.cbArg = op->f.distanceCbArg;
d = op->f.distanceCbFunc(&a,px,py);
}
return d;
}
bool _cmGrObjCbEvent( cmGr_t* p, cmGrObj_t* op, unsigned flags, unsigned key, int px, int py )
{
bool fl = false;
if( op->f.eventCbFunc != NULL )
{
cmGrObjFuncArgs_t a;
_cmGrObjSetupFuncArgs(&a,p,op);
a.cbArg = op->f.eventCbArg;
fl = op->f.eventCbFunc(&a,flags,key,px,py);
}
return fl;
}
void _cmGrObjCbVExt( cmGr_t* p, const cmGrObj_t* op, cmGrVExt_t* vext )
{
if( op->f.vextCbFunc == NULL )
cmGrVExtSetEmpty(vext);
else
{
cmGrObjFuncArgs_t a;
_cmGrObjSetupFuncArgs(&a,p,(cmGrObj_t*)op);
a.cbArg = op->f.vextCbArg;
op->f.vextCbFunc(&a,vext);
}
}
bool _cmGrObjCbIsInside( cmGr_t* p, const cmGrObj_t* op, unsigned evtFlags, int px, int py, cmGrV_t vx, cmGrV_t vy )
{
bool fl = false;
if( op->f.isInsideCbFunc != NULL )
{
cmGrObjFuncArgs_t a;
_cmGrObjSetupFuncArgs(&a,p,(cmGrObj_t*)op);
a.cbArg = op->f.isInsideCbArg;
fl = op->f.isInsideCbFunc(&a,evtFlags,px,py,vx,vy);
}
return fl;
}
//====================================================================================================
// Object Private Functions
//====================================================================================================
// Return true if pp is an ancestor (parent,grand-parent,great-grand-parent,...) of cp.
bool _cmGrObjIsAncestor( cmGrObj_t* pp, cmGrObj_t* cp )
{
cmGrObj_t* tp = cp->parent;
for(; tp != NULL; tp=tp->parent )
if( tp == pp )
break;
return tp!=NULL;
}
// Append 'op' as the right-most child of 'pp'.
void _cmGrObjAppendChild( cmGrObj_t* pp, cmGrObj_t* cp)
{
cp->parent = pp;
if( pp->children == NULL )
{
pp->children = cp;
cp->lsib = NULL;
cp->rsib = NULL;
}
else
{
cmGrObj_t* op = pp->children;
while( op->rsib != NULL )
op = op->rsib;
op->rsib = cp;
cp->rsib = NULL;
cp->lsib = op;
}
}
// Insert 'op' on the left of 'rp'.
void _cmGrObjInsertOnLeft( cmGrObj_t* op, cmGrObj_t* rp )
{
op->parent = rp->parent;
op->rsib = rp;
op->lsib = rp->lsib;
if( rp->lsib == NULL )
{
assert( rp->parent == rp->parent->children);
rp->parent->children = op;
}
else
{
rp->lsib->rsib = op;
}
rp->lsib = op;
}
// Insert 'op' on the right of 'lp'.
// 'pp' is the parent of 'lp'. 'pp' must be given explicitely to cover
// the case where lp is NULL - in which case the new parent for op
// cannot be determined from lp.
void _cmGrObjInsertOnRight( cmGrObj_t* op, cmGrObj_t* lp, cmGrObj_t* pp )
{
op->parent = pp;
if( lp == NULL )
{
assert( pp != NULL && pp->children==NULL );
pp->children = op;
op->lsib = NULL;
op->rsib = NULL;
return;
}
assert( lp->parent == pp );
op->lsib = lp;
op->rsib = lp->rsib;
if( lp->rsib != NULL )
lp->rsib->lsib = op;
lp->rsib = op;
}
// Unlink 'op' from the tree but leave it's children attached.
void _cmGrObjUnlink( cmGrObj_t * op )
{
if( op->parent != NULL && op->parent->children == op )
op->parent->children = op->parent->children->rsib;
if( op->rsib != NULL )
op->rsib->lsib = op->lsib;
if( op->lsib != NULL )
op->lsib->rsib = op->rsib;
op->parent = NULL;
op->rsib = NULL;
op->lsib = NULL;
}
// Free 'op' and all of its children.
// 'op' must be unlinked before calling this function
cmGrRC_t _cmGrObjFree( cmGr_t* p, cmGrObj_t* op )
{
cmGrRC_t rc = kOkGrRC;
// go to the deepest child
if( op->children != NULL )
if((rc = _cmGrObjFree(p,op->children)) != kOkGrRC )
return rc;
// go right
if( op->rsib != NULL )
if((rc = _cmGrObjFree(p,op->rsib)) != kOkGrRC )
return rc;
// inform the application that we are destroying this object
_cmGrObjCbDestroy(p,op);
_cmGrObjUnlink(op);
cmMemFree(op);
return rc;
}
cmGrRC_t _cmGrObjUnlinkAndFree( cmGr_t* p, cmGrObj_t* op )
{
cmGrRC_t rc = kOkGrRC;
cmGrObj_t* rsib = op->rsib;
cmGrObj_t* par = op->parent;
_cmGrObjUnlink(op);
// if the free fails ...
if((rc = _cmGrObjFree(p,op)) != kOkGrRC )
{
// ... then restore the objects position
if( rsib == NULL )
_cmGrObjInsertOnLeft(op,rsib);
else
_cmGrObjAppendChild(par,op);
}
return rc;
}
// Return kL,T,R,BGrFl indicating which directions of wext are in violation of op->wlimitExt.
// Return's 0 if no limits are in violation
unsigned _cmGrObjWorldLimitsTestViolation( const cmGrObj_t* op, const cmGrVExt_t* wext )
{
unsigned violFlags = 0;
if( cmIsFlag( op->wlimitFlags, kLeftGrFl) )
if( cmGrVExtMinX(wext) < cmGrVExtMinX(&op->wlimitExt) )
violFlags = kLeftGrFl;
if( cmIsFlag( op->wlimitFlags, kTopGrFl) )
if( cmGrVExtMaxY(wext) < cmGrVExtMaxY(&op->wlimitExt) )
violFlags = kTopGrFl;
if( cmIsFlag( op->wlimitFlags, kRightGrFl) )
if( cmGrVExtMaxX(wext) > cmGrVExtMaxX(&op->wlimitExt) )
violFlags = kRightGrFl;
if( cmIsFlag( op->wlimitFlags, kBottomGrFl) )
if( cmGrVExtMinY(wext) > cmGrVExtMinY(&op->wlimitExt) )
violFlags = kBottomGrFl;
return violFlags;
}
// If op has world extent limits then apply them to 'ext'.
// Extent directions in 'ext' which do not have limits in 'op' are unchanged.
// Extent directions in 'ext' which have limits are set to the limit.
void _cmGrObjApplyExtLimits( cmGrObj_t* op, cmGrVExt_t* ext )
{
if( cmIsFlag(op->wlimitFlags,kLeftGrFl) )
cmGrVExtSetMinX(ext,cmGrVExtMinX(&op->wlimitExt));
if( cmIsFlag(op->wlimitFlags,kBottomGrFl) )
cmGrVExtSetMinY(ext,cmGrVExtMinY(&op->wlimitExt));
if( cmIsFlag(op->wlimitFlags,kTopGrFl) )
cmGrVExtSetMaxY(ext,cmGrVExtMaxY(&op->wlimitExt));
if( cmIsFlag(op->wlimitFlags,kRightGrFl) )
cmGrVExtSetMaxX(ext,cmGrVExtMaxX(&op->wlimitExt));
}
// Return the outside extents of the children of 'op'.
// Returns false if there are no children and leaves wext set to NULL.
bool _cmGrObjChildExts( cmGr_t* p, const cmGrObj_t* op, cmGrVExt_t* ext )
{
cmGrVExtSetNull(ext);
op = op->children;
if( op == NULL )
return false;
_cmGrObjCbVExt(p,op,ext);
for(op=op->rsib; op!=NULL; op=op->rsib)
{
cmGrVExt_t e;
_cmGrObjCbVExt(p,op,&e);
cmGrVExtExpandToContain(ext,&e);
}
return true;
}
cmGrRC_t _cmGrObjSetWorldExt( cmGr_t* p, cmGrObj_t* op, const cmGrVExt_t* wext );
// The world extents changed to 'ref_wext' on an object.
// Examine all 'sync'ed' objects and expand them to be contained by 'ref_wext'.
cmGrRC_t _cmGrSyncWorldExtentsExpand( cmGr_t* p, const cmGrVExt_t* ref_wext )
{
cmGrRC_t rc = kOkGrRC;
// apply changes to synch targets
cmGrSync_t* sp = p->syncs;
for(; sp!=NULL; sp=sp->link)
if( cmIsFlag(sp->flags,kWorldSyncGrFl) )
{
// get the target ROOT object
cmGrObj_t* top = _cmGrObjHandleToPtr(cmGrRootObjH(sp->grH));
bool fl = false;
cmGrVExt_t top_wext = top->wext;
//printf("sync %i ",top->id);
//cmGrVExtPrint("top_wext",&top_wext);
//cmGrVExtPrint("ref_wext",ref_wext);
// if horz sync was requested ...
if( !fl && cmIsFlag(sp->flags,kHorzSyncGrFl) )
{
if( cmGrVExtIsNullOrEmpty(&top_wext) )
{
cmGrVExtSetMinX(&top_wext,cmGrVExtMinX(ref_wext));
cmGrVExtSetMaxX(&top_wext,cmGrVExtMaxX(ref_wext));
fl = true;
}
else
{
// ... and the target needs to expand and can expand
if( cmGrVExtMinX(&top_wext) > cmGrVExtMinX(ref_wext) && cmIsNotFlag(top->wlimitFlags,kLeftGrFl) )
{
cmGrVExtSetMinX(&top_wext,cmGrVExtMinX(ref_wext)); // .. expand the view
fl = true;
}
if( cmGrVExtMaxX(&top_wext) < cmGrVExtMaxX(ref_wext) && cmIsNotFlag(top->wlimitFlags,kRightGrFl) )
{
cmGrVExtSetMaxX(&top_wext,cmGrVExtMaxX(ref_wext));
fl = true;
}
}
}
// if vert sync was requested ...
if( !fl && cmIsFlag(sp->flags,kVertSyncGrFl) )
{
if( cmGrVExtIsNullOrEmpty(&top_wext) )
{
cmGrVExtSetMinY(&top_wext,cmGrVExtMinY(ref_wext));
cmGrVExtSetMaxY(&top_wext,cmGrVExtMaxY(ref_wext));
fl = true;
}
else
{
if( cmGrVExtMinY(&top_wext) > cmGrVExtMinY(ref_wext) && cmIsNotFlag(top->wlimitFlags,kBottomGrFl))
{
cmGrVExtSetMinY(&top_wext,cmGrVExtMinY(ref_wext));
fl = true;
}
if( cmGrVExtMaxY(&top_wext) < cmGrVExtMaxY(ref_wext) && cmIsNotFlag(top->wlimitFlags,kTopGrFl) )
{
cmGrVExtSetMaxY(&top_wext,cmGrVExtMaxY(ref_wext));
fl = true;
}
}
}
// If fl is set then top_wext contains an expanded world view
if( fl )
{
//cmGrVExtPrint("out top_wext",&top_wext);
// this call may result in a recursion back into this function
if((rc = _cmGrObjSetWorldExt( _cmGrHandleToPtr(sp->grH), top, &top_wext )) != kOkGrRC )
goto errLabel;
}
}
errLabel:
return rc;
}
cmGrRC_t _cmGrObjSetWorldExt( cmGr_t* p, cmGrObj_t* op, const cmGrVExt_t* wext )
{
cmGrRC_t rc = kOkGrRC;
cmGrVExt_t ce;
cmGrVExt_t we = *wext; // make a copy of the new extents to override the 'const' on 'wext'.
// apply the world ext limits to 'we'.
_cmGrObjApplyExtLimits(op,&we);
assert(cmGrVExtIsNorm(&we)); // assert w/h are positive
// get the extents around all children
if( _cmGrObjChildExts(p, op, &ce ) )
{
// if 'ce' is not entirely inside 'we'
if( cmGrVExtIsExtInside(&we,&ce) == false )
return cmErrMsg(&p->err,kExtsErrGrRC,"The change in world extents would have resulted in child objects outside the requested world extents.");
}
// if world extents are actually changing
if( !cmGrVExtIsEqual(&op->wext,&we) )
{
// update the world extents for this object
op->wext = we;
//op->stateFlags = cmSetFlag(op->stateFlags,kDirtyObjFl);
//cmGrVExtPrint(cmTsPrintf("set w: %i ",op->id),&we);
// if this is the root object
if( p->rootObj == op )
{
// this call may result in recursion back into this function
// if two cmGr's are mutual sync targets - an infinite loop
// should be avoided by the cmGrVExtIsEqual() test above.
rc = _cmGrSyncWorldExtentsExpand(p, wext );
}
}
return rc;
}
void _cmGrObjReport( cmGr_t* p, cmGrObj_t* op, cmRpt_t* rpt )
{
cmGrVExt_t vext;
cmRptPrintf(rpt,"id:0x%x \n",op->id);
_cmGrObjCbVExt( p, op, &vext);
cmGrVExtRpt(&vext,rpt);
cmRptPrintf(rpt,"\n");
}
void _cmGrObjReportR( cmGr_t* p, cmGrObj_t* op, cmRpt_t* rpt)
{
_cmGrObjReport(p, op,rpt);
if( op->children != NULL )
_cmGrObjReport(p,op->children,rpt);
if( op->rsib != NULL )
_cmGrObjReport(p,op->rsib,rpt);
}
//====================================================================================================
cmGrRC_t cmGrObjCreate( cmGrH_t h, cmGrObjH_t* ohp, cmGrObjH_t parentH, cmGrObjFunc_t* f, unsigned id, unsigned flags, const cmGrVExt_t* wext )
{
cmGrRC_t rc;
if((rc = cmGrObjDestroy(h,ohp)) != kOkGrRC )
return rc;
cmGr_t* p = _cmGrHandleToPtr(h);
// allocate the new object
cmGrObj_t* op = cmMemAllocZ(cmGrObj_t,1);
op->id = id;
op->f = *f;
if( wext != NULL )
{
op->wext = *wext;
if( cmGrVExtIsNotNull(wext) )
cmGrVExtNorm(&op->wext);
}
// if an explicit parent was not provided
// then assign the root object as the parent
if( cmGrObjIsValid(h,parentH) == false )
parentH.h = p->rootObj;
// insert the object into the tree
if( cmGrObjIsValid(h,parentH) )
_cmGrObjAppendChild(_cmGrObjHandleToPtr(parentH),op);
else
{
// no root object exits - so make this obj the root
assert(p->objs == NULL );
p->objs = op;
}
ohp->h = op;
// Notify the application that an object was created.
if((rc = _cmGrObjCbCreate(p,op)) != kOkGrRC )
goto errLabel;
if( f->vextCbFunc != NULL )
{
cmGrVExt_t vext;
cmGrVExtSetEmpty(&vext);
// get the local virtual extents for the new object
cmGrObjLocalVExt(h, *ohp, &vext );
if( cmGrVExtIsNotNullOrEmpty(&vext) )
{
// expand the parents world to contain the new object
if( op->parent != NULL )
{
cmGrVExt_t parent_wext = op->parent->wext;
if( cmGrVExtExpandToContain(&parent_wext,&vext) )
_cmGrObjSetWorldExt(p,op->parent,&parent_wext);
assert( cmGrVExtIsExtInside(&op->parent->wext,&vext) );
}
// if cfg'd to expand the view to contain new objects then do so here
if( op->parent!=NULL && op->parent->parent==NULL && cmIsFlag(p->cfgFlags,kExpandViewGrFl) && cmGrVExtIsExtInside(&p->vext,&vext) == false )
{
cmGrVExt_t v = p->vext;
if( cmGrVExtExpandToContain(&v,&vext) )
_cmGrSetViewExtentsE(p,&v);
assert( cmGrVExtIsExtInside(&op->parent->wext,&p->vext));
}
// if the new object is inside the view extents then mark
// the object as dirty
//if( cmGrVExtIsExtInside(&p->vext,&vext) )
// op->stateFlags = cmSetFlag(op->stateFlags,kDirtyObjFl);
}
}
errLabel:
if( rc != kOkGrRC )
cmGrObjDestroy(h,ohp);
return rc;
}
cmGrRC_t _cmGrObjDestroy( cmGr_t* p, cmGrObj_t* op )
{
if( op == NULL )
return kOkGrRC;
return _cmGrObjUnlinkAndFree( p, op);
}
cmGrRC_t cmGrObjDestroy( cmGrH_t h, cmGrObjH_t* ohp )
{
cmGrRC_t rc = kOkGrRC;
if( ohp==NULL || cmGrObjIsValid(h,*ohp) == false )
return kOkGrRC;
cmGrObj_t* op = _cmGrObjHandleToPtr(*ohp);
if((rc = _cmGrObjDestroy(_cmGrHandleToPtr(h),op)) != kOkGrRC )
return rc;
ohp->h = NULL;
return rc;
}
cmGrRC_t cmGrObjIsValid( cmGrH_t h, cmGrObjH_t oh )
{ return h.h!=NULL && oh.h != NULL; }
unsigned cmGrObjId( cmGrObjH_t oh )
{ return _cmGrObjHandleToPtr(oh)->id; }
void cmGrObjSetId( cmGrObjH_t oh, unsigned id )
{
cmGrObj_t* op = _cmGrObjHandleToPtr(oh);
op->id = id;
}
cmGrObjH_t cmGrObjParent( cmGrObjH_t oh )
{
cmGrObjH_t poh;
poh.h = _cmGrObjHandleToPtr(oh)->parent;
return poh;
}
cmGrRC_t cmGrObjSetWorldExt( cmGrH_t h, cmGrObjH_t oh, const cmGrVExt_t* wext )
{
cmGr_t* p = _cmGrHandleToPtr(h);
cmGrObj_t* op = _cmGrObjHandleToPtr(oh);
return _cmGrObjSetWorldExt(p,op,wext);
}
void cmGrObjWorldExt( cmGrObjH_t oh, cmGrVExt_t* wext )
{
cmGrObj_t* op = _cmGrObjHandleToPtr(oh);
*wext = op->wext;
}
cmGrRC_t cmGrObjSetWorldLimitExt( cmGrH_t h, cmGrObjH_t oh, const cmGrVExt_t* vext, unsigned limitFlags )
{
cmGrRC_t rc = kOkGrRC;
cmGrObj_t* op = _cmGrObjHandleToPtr(oh);
// store the current world extents
cmGrVExt_t lext = op->wlimitExt;
unsigned lfl = op->wlimitFlags;
// set the new limits
op->wlimitExt = *vext;
op->wlimitFlags = limitFlags;
cmGrVExtNorm(&op->wlimitExt);
// attempt to apply the current world extents with the new limits
// (this may fail if their are child objects out of range of the new extents)
if( cmGrVExtIsNotNull(&op->wext ) )
{
if((rc = cmGrObjSetWorldExt(h,oh,&op->wext)) != kOkGrRC )
{
// we failed - restore the old limits
op->wlimitExt = lext;
op->wlimitFlags = lfl;
}
}
return rc;
}
void cmGrObjWorldLimitExt( cmGrObjH_t oh, cmGrVExt_t* vext, unsigned* limitFlags )
{
cmGrObj_t* op = _cmGrObjHandleToPtr(oh);
if( vext != NULL )
*vext = op->wlimitExt;
if( limitFlags != NULL )
*limitFlags = op->wlimitFlags;
}
void cmGrObjSetCreateCb( cmGrObjH_t oh, cmGrCreateObjCb_t cbFunc, void* cbArg )
{
cmGrObj_t* op = _cmGrObjHandleToPtr(oh);
op->f.createCbFunc = cbFunc;
op->f.createCbArg = cbArg;
}
void cmGrObjSetDestroyCb( cmGrObjH_t oh, cmGrDestroyObjCb_t cbFunc, void* cbArg )
{
cmGrObj_t* op = _cmGrObjHandleToPtr(oh);
op->f.destroyCbFunc = cbFunc;
op->f.destroyCbArg = cbArg;
}
void cmGrObjSetRenderCb( cmGrObjH_t oh, cmGrRenderObjCb_t cbFunc, void* cbArg )
{
cmGrObj_t* op = _cmGrObjHandleToPtr(oh);
op->f.renderCbFunc = cbFunc;
op->f.renderCbArg = cbArg;
}
void cmGrObjSetDistanceCb( cmGrObjH_t oh, cmGrDistanceObjCb_t cbFunc, void* cbArg )
{
cmGrObj_t* op = _cmGrObjHandleToPtr(oh);
op->f.distanceCbFunc = cbFunc;
op->f.distanceCbArg = cbArg;
}
void cmGrObjSetEventCb( cmGrObjH_t oh, cmGrEventObjCb_t cbFunc, void* cbArg )
{
cmGrObj_t* op = _cmGrObjHandleToPtr(oh);
op->f.eventCbFunc = cbFunc;
op->f.eventCbArg = cbArg;
}
void cmGrObjSetVExtCb( cmGrObjH_t oh, cmGrVExtObjCb_t cbFunc, void* cbArg )
{
cmGrObj_t* op = _cmGrObjHandleToPtr(oh);
op->f.vextCbFunc = cbFunc;
op->f.vextCbArg = cbArg;
}
void cmGrObjSetIsInsideCb( cmGrObjH_t oh, cmGrIsInsideObjCb_t cbFunc, void* cbArg )
{
cmGrObj_t* op = _cmGrObjHandleToPtr(oh);
op->f.isInsideCbFunc = cbFunc;
op->f.isInsideCbArg = cbArg;
}
cmGrCreateObjCb_t cmGrObjCreateCbFunc( cmGrObjH_t oh )
{
cmGrObj_t* op = _cmGrObjHandleToPtr(oh);
return op->f.createCbFunc;
}
cmGrDestroyObjCb_t cmGrObjDestroyCbFunc( cmGrObjH_t oh )
{
cmGrObj_t* op = _cmGrObjHandleToPtr(oh);
return op->f.destroyCbFunc;
}
cmGrRenderObjCb_t cmGrObjRenderCbFunc( cmGrObjH_t oh )
{
cmGrObj_t* op = _cmGrObjHandleToPtr(oh);
return op->f.renderCbFunc;
}
cmGrDistanceObjCb_t cmGrObjDistanceCbFunc( cmGrObjH_t oh )
{
cmGrObj_t* op = _cmGrObjHandleToPtr(oh);
return op->f.distanceCbFunc;
}
cmGrEventObjCb_t cmGrObjEventCbFunc( cmGrObjH_t oh )
{
cmGrObj_t* op = _cmGrObjHandleToPtr(oh);
return op->f.eventCbFunc;
}
cmGrVExtObjCb_t cmGrObjVExtCbFunc( cmGrObjH_t oh )
{
cmGrObj_t* op = _cmGrObjHandleToPtr(oh);
return op->f.vextCbFunc;
}
cmGrIsInsideObjCb_t cmGrObjIsInsideCbFunc( cmGrObjH_t oh )
{
cmGrObj_t* op = _cmGrObjHandleToPtr(oh);
return op->f.isInsideCbFunc;
}
void* cmGrObjCreateCbArg( cmGrObjH_t oh )
{
cmGrObj_t* op = _cmGrObjHandleToPtr(oh);
return op->f.createCbArg;
}
void* cmGrObjDestroyCbArg( cmGrObjH_t oh )
{
cmGrObj_t* op = _cmGrObjHandleToPtr(oh);
return op->f.createCbArg;
}
void* cmGrObjRenderCbArg( cmGrObjH_t oh )
{
cmGrObj_t* op = _cmGrObjHandleToPtr(oh);
return op->f.destroyCbArg;
}
void* cmGrObjDistanceCbArg( cmGrObjH_t oh )
{
cmGrObj_t* op = _cmGrObjHandleToPtr(oh);
return op->f.distanceCbArg;
}
void* cmGrObjEventCbArg( cmGrObjH_t oh )
{
cmGrObj_t* op = _cmGrObjHandleToPtr(oh);
return op->f.eventCbArg;
}
void* cmGrObjVExtCbArg( cmGrObjH_t oh )
{
cmGrObj_t* op = _cmGrObjHandleToPtr(oh);
return op->f.vextCbArg;
}
void* cmGrObjIsInsideCbArg( cmGrObjH_t oh )
{
cmGrObj_t* op = _cmGrObjHandleToPtr(oh);
return op->f.isInsideCbArg;
}
void cmGrObjLocalVExt( cmGrH_t h, cmGrObjH_t oh, cmGrVExt_t* vext )
{
cmGrObj_t* op = _cmGrObjHandleToPtr(oh);
return _cmGrObjCbVExt( _cmGrHandleToPtr(h), op, vext);
}
cmGrObj_t* _cmGrObjIdToHandle( cmGrObj_t* op, unsigned id )
{
cmGrObj_t* rp = NULL;
if( op->id == id )
return op;
if( op->children != NULL )
if((rp = _cmGrObjIdToHandle(op->children,id)) != NULL )
return rp;
if( op->rsib != NULL )
if((rp = _cmGrObjIdToHandle(op->rsib,id)) != NULL )
return rp;
return NULL;
}
cmGrObjH_t cmGrObjIdToHandle( cmGrH_t h, unsigned id )
{
cmGr_t* p = _cmGrHandleToPtr(h);
cmGrObjH_t oh = cmGrObjNullHandle;
cmGrObj_t* op;
if((op = _cmGrObjIdToHandle(p->objs,id)) != NULL )
oh.h = op;
return oh;
}
// Move 'aoH' such that it is above 'boH' in the z-order.
// This means that 'boH' must be drawn before 'aoH'.
// This algorithm is designed to not break object hierarchies
// when moving objects. It achieves this by only moving
// the ancestor objects of boH and aoH at the level where
// they do not share a common ancestor.
void cmGrObjDrawAbove( cmGrObjH_t boH, cmGrObjH_t aoH )
{
cmGrObj_t* bp = _cmGrObjHandleToPtr(boH);
cmGrObj_t* ap = _cmGrObjHandleToPtr(aoH);
cmGrObj_t* rp = bp;
// set rp to the root object
while( rp->parent != NULL )
rp=rp->parent;
while(1)
{
cmGrObj_t* a[] = {NULL,NULL};
cmGrObj_t* bpp = NULL;
cmGrObj_t* app = NULL;
unsigned i = 0;
rp = rp->children;
for(; rp!=NULL; rp=rp->rsib)
{
if( bp==rp || _cmGrObjIsAncestor(rp,bp) )
{
assert( a[i]==NULL );
bpp = rp;
a[i++] = rp;
if( i==2 )
break;
}
if( ap==rp || _cmGrObjIsAncestor(rp,ap) )
{
assert( a[i]==NULL );
app = rp;
a[i++] = rp;
if( i==2 )
break;
}
}
assert( rp != NULL && i==2 );
// bpp and app share the same ancestor - keep looking
// for the level where the they do not share same ancestor
if( bpp == app )
rp = bpp;
else
{
// if bp is not already being drawn before ap
if( a[0] != bpp )
{
_cmGrObjUnlink(app);
_cmGrObjInsertOnRight(app,bpp,bpp->parent);
}
return;
}
}
}
void cmGrObjReport( cmGrH_t h, cmGrObjH_t oh, cmRpt_t* rpt )
{
cmGrObj_t* op = _cmGrObjHandleToPtr(oh);
_cmGrObjReport(_cmGrHandleToPtr(h),op,rpt);
}
void cmGrObjReportR( cmGrH_t h, cmGrObjH_t oh, cmRpt_t* rpt )
{
cmGrObj_t* op = _cmGrObjHandleToPtr(oh);
_cmGrObjReportR(_cmGrHandleToPtr(h),op,rpt);
}
//====================================================================================================
//====================================================================================================
#define _cmGr_X_VperP(p) (p->vext.sz.w / (p->pext.sz.w-1) )
#define _cmGr_Y_VperP(p) (p->vext.sz.h / (p->pext.sz.h-1) )
#define _cmGr_X_PperV(p) ((p->pext.sz.w-1) / p->vext.sz.w )
#define _cmGr_Y_PperV(p) ((p->pext.sz.h-1) / p->vext.sz.h )
int _cmGr_X_VtoP( cmGr_t* p, cmGrV_t vx )
{ return p->pext.loc.x + lround( (vx - p->vext.loc.x) * _cmGr_X_PperV(p)); }
int _cmGr_Y_VtoP(cmGr_t* p, cmGrV_t vy )
{ return p->pext.loc.y + (p->pext.sz.h-1) + lround(-(vy - p->vext.loc.y) * _cmGr_Y_PperV(p) ); }
cmGrV_t _cmGr_X_PtoV( cmGr_t* p, int px )
{ return p->vext.loc.x + (px - p->pext.loc.x) * _cmGr_X_VperP(p); }
cmGrV_t _cmGr_Y_PtoV( cmGr_t* p, int py )
{ return p->vext.loc.y + (p->pext.loc.y + (p->pext.sz.h-1) - py) * _cmGr_Y_VperP(p); }
#define _cmGrParentToLocalX( op, vext, x ) (op)->wext.loc.x + ((x) - (vext).loc.x) * (op)->wext.sz.w / (vext).sz.w
#define _cmGrParentToLocalY( op, vext, y ) (op)->wext.loc.y + ((y) - (vext).loc.y) * (op)->wext.sz.h / (vext).sz.h
#define _cmGrLocalToParentX( op, vext, x ) (vext).loc.x + ((x) - (op)->wext.loc.x) * (vext).sz.w / (op)->wext.sz.w
#define _cmGrLocalToParentY( op, vext, y ) (vext).loc.y + ((y) - (op)->wext.loc.y) * (vext).sz.h / (op)->wext.sz.h
// On input x,y are in the same coord's as op->vext.
// On output pt is converted to op's internal coord system (i.e. the pt is inside op->wext)
// Using pt as the src and dst is always safe. (i.e. _cmGrLocalToParent(p,op,pt->x,pt->y,pt) is safe.)
bool _cmGrParentToLocal( cmGr_t* p, cmGrObj_t* op, cmGrV_t x, cmGrV_t y, cmGrVPt_t* pt )
{
cmGrVExt_t vext;
_cmGrObjCbVExt(p,op,&vext);
if( cmGrVExtIsNullOrEmpty(&vext) )
return false;
pt->x = _cmGrParentToLocalX( op, vext, x);
pt->y = _cmGrParentToLocalY( op, vext, y );
//pt->x = op->wext.loc.x + (x - vext.loc.x) * op->wext.sz.w / vext.sz.w;
//pt->y = op->wext.loc.y + (y - vext.loc.y) * op->wext.sz.h / vext.sz.h;
return true;
}
// On input x,y are in the same coords as op->wext.
// On output pt is converted to be in the same coord's as op->vext (i.e.the pt is inside op->parent->wext)
// Using pt as the src and dst is always safe. (i.e. _cmGrLocalToParent(p,op,pt->x,pt->y,pt) is safe.)
void _cmGrLocalToParent( cmGr_t* p, cmGrObj_t* op, cmGrV_t x, cmGrV_t y, cmGrVPt_t* pt )
{
cmGrVExt_t vext;
_cmGrObjCbVExt(p,op,&vext);
pt->x = _cmGrLocalToParentX(op,vext, x);
pt->y = _cmGrLocalToParentY(op,vext, y);
//pt->x = vext.loc.x + (x - op->wext.loc.x) * vext.sz.w / op->wext.sz.w;
//pt->y = vext.loc.y + (y - op->wext.loc.y) * vext.sz.h / op->wext.sz.h;
}
// On input x is in coord's inside op->wext.
// Return is in phys coord's
int _cmGrX_VtoP( cmGr_t* p, cmGrObj_t* op, cmGrV_t x )
{
cmGrVExt_t vext;
for(; op->parent != NULL; op=op->parent )
{
_cmGrObjCbVExt(p,op,&vext);
x = _cmGrLocalToParentX(op->parent,vext,x);
}
return _cmGr_X_VtoP(p,x);
}
// On input y is in coord's inside op->wext.
// Return is in phys coord's
int _cmGrY_VtoP( cmGr_t* p, cmGrObj_t* op, cmGrV_t y )
{
cmGrVExt_t vext;
for(; op->parent != NULL; op=op->parent )
{
_cmGrObjCbVExt(p,op,&vext);
y = _cmGrLocalToParentY(op->parent,vext,y);
}
return _cmGr_Y_VtoP(p,y);
}
// On input x,y are coord's inside op->wext.
// On output rp is in physical coord's
void _cmGrXY_VtoP( cmGr_t* p, cmGrObj_t* op, cmGrV_t x, cmGrV_t y, cmGrPPt_t* rp )
{
cmGrVPt_t pt;
cmGrVPtSet(&pt,x,y);
for(; op->parent != NULL; op=op->parent )
_cmGrLocalToParent(p,op->parent,pt.x,pt.y,&pt);
rp->x = _cmGr_X_VtoP(p,pt.x);
rp->y = _cmGr_Y_VtoP(p,pt.y);
}
// pt is converted from the root obj coord system to be in the same coord's
// as op->vext (inside of op->parent->wext)
void _cmGrXY_GlobalToLocal( cmGr_t* p, cmGrObj_t* op, cmGrVPt_t* pt )
{
if( op->parent != NULL )
_cmGrXY_GlobalToLocal(p,op->parent,pt);
// convert from parent coord to child coords
_cmGrParentToLocal(p,op,pt->x,pt->y,pt);
}
// On input x,y are in physical coordindates.
// On output rp is inside op->parent->wext (the same coord's as op->vext)
void _cmGrXY_PtoV( cmGr_t* p, cmGrObj_t* op, int px, int py, cmGrVPt_t* rp )
{
// convert the phys points to points in the root coord system
rp->x = _cmGr_X_PtoV(p,px);
rp->y = _cmGr_Y_PtoV(p,py);
_cmGrXY_GlobalToLocal(p, op, rp );
}
int cmGrX_VtoP( cmGrH_t hh, cmGrObjH_t oh, cmGrV_t x )
{
cmGr_t* p = _cmGrHandleToPtr(hh);
cmGrObj_t* op = _cmGrObjHandleToPtr(oh);
return _cmGrX_VtoP(p,op,x);
}
int cmGrY_VtoP( cmGrH_t hh, cmGrObjH_t oh, cmGrV_t y )
{
cmGr_t* p = _cmGrHandleToPtr(hh);
cmGrObj_t* op = _cmGrObjHandleToPtr(oh);
return _cmGrY_VtoP(p,op,y);
}
void cmGrXY_VtoP( cmGrH_t h, cmGrObjH_t oh, cmGrV_t x, cmGrV_t y, cmGrPPt_t* rp )
{ _cmGrXY_VtoP(_cmGrHandleToPtr(h), _cmGrObjHandleToPtr(oh), x, y, rp ); }
void cmGrXYWH_VtoP( cmGrH_t hh, cmGrObjH_t oh, cmGrV_t x, cmGrV_t y, cmGrV_t w, cmGrV_t h, cmGrPExt_t* pext )
{
cmGr_t* p = _cmGrHandleToPtr(hh);
cmGrObj_t* op = _cmGrObjHandleToPtr(oh);
cmGrPPt_t pt0,pt1;
_cmGrXY_VtoP(p,op,x, y, &pt0);
_cmGrXY_VtoP(p,op,x+w,y+h,&pt1);
cmGrPExtSetD(pext,pt0.x,pt0.y,pt1.x,pt1.y);
}
void cmGrVExt_VtoP( cmGrH_t hh, cmGrObjH_t oh, const cmGrVExt_t* vext, cmGrPExt_t* pext )
{ cmGrXYWH_VtoP(hh,oh,vext->loc.x,vext->loc.y,vext->sz.w,vext->sz.h,pext); }
void cmGrXY_PtoV( cmGrH_t h, cmGrObjH_t oh, int x, int y, cmGrVPt_t* rp )
{ _cmGrXY_PtoV(_cmGrHandleToPtr(h), _cmGrObjHandleToPtr(oh), x, y, rp ); }
void cmGrXYWH_PtoV( cmGrH_t hh, cmGrObjH_t oh, int x, int y, int w, int h, cmGrVExt_t* vext )
{
cmGr_t* p = _cmGrHandleToPtr(hh);
cmGrObj_t* op = _cmGrObjHandleToPtr(oh);
cmGrVPt_t pt0,pt1;
_cmGrXY_PtoV(p,op,x,y,&pt0);
_cmGrXY_PtoV(p,op,x+w-1,y+h-1,&pt1);
cmGrVExtSetD(vext,pt0.x,pt0.y,pt1.x,pt1.y);
}
void cmGrPExt_PtoV( cmGrH_t hh, cmGrObjH_t oh, const cmGrPExt_t* pext, cmGrVExt_t* vext )
{ cmGrXYWH_PtoV(hh,oh,pext->loc.x,pext->loc.y,pext->sz.w,pext->sz.h,vext); }
void cmGrDrawVLine( cmGrH_t h, cmGrDcH_t dcH, cmGrObjH_t oh, cmGrV_t x0, cmGrV_t y0, cmGrV_t x1, cmGrV_t y1 )
{
cmGrPPt_t loc0;
cmGrPPt_t loc1;
cmGrXY_VtoP(h,oh,x0,y0,&loc0);
cmGrXY_VtoP(h,oh,x1,y1,&loc1);
cmGrDcDrawLine(dcH,loc0.x,loc0.y,loc1.x,loc1.y);
}
void cmGrDrawVRect( cmGrH_t hh, cmGrDcH_t dcH, cmGrObjH_t oh, cmGrV_t x, cmGrV_t y, cmGrV_t w, cmGrV_t h )
{
cmGrDrawVLine(hh,dcH,oh,x, y, x, y+h);
cmGrDrawVLine(hh,dcH,oh,x, y+h,x+w,y+h);
cmGrDrawVLine(hh,dcH,oh,x+w,y+h,x+w,y);
cmGrDrawVLine(hh,dcH,oh,x+w,y, x, y);
}
//====================================================================================================
//====================================================================================================
cmGrRC_t _cmGrDestroy( cmGr_t* p )
{
cmGrRC_t rc = kOkGrRC;
if( p->objs != NULL )
{
// destroy the root object and all of it's children
if((rc = _cmGrObjDestroy(p,p->objs)) != kOkGrRC )
return rc;
}
cmGrSync_t* sp = p->syncs;
while( sp != NULL )
{
cmGrH_t h;
h.h = p;
cmGrSync_t* np = sp->link;
// break sync with any mutually sync'ed gr's to prevent
// attempted calls to this gr.
cmGrSetSync( sp->grH, h, 0 );
cmMemFree(sp);
sp = np;
}
p->syncs = NULL;
cmLHeapDestroy(&p->lhH);
cmMemPtrFree(&p->img);
cmMemFree(p);
return rc;
}
void _cmGrObjRootVExt( cmGrObjFuncArgs_t* args, cmGrVExt_t* vext )
{
// the root object's virtual extent is the same as it's world extent
cmGrObjWorldExt( args->objH, vext );
}
bool _cmGrObjRootIsInside( cmGrObjFuncArgs_t* args, unsigned evtFlags, int px, int py, cmGrV_t vx, cmGrV_t vy )
{
cmGrVExt_t vext;
_cmGrObjRootVExt(args,&vext);
return cmGrVExtIsXyInside(&vext,vx,vy);
}
void _cmGrSetCfgFlags( cmGr_t* p, unsigned flags )
{
p->cfgFlags = flags;
// kSelectHorzFl and kSelectVertFl are mutually exclusive
if( cmIsFlag(p->cfgFlags,kSelectHorzGrFl) )
p->cfgFlags = cmClrFlag(p->cfgFlags,kSelectVertGrFl);
}
void _cmGrCallback( cmGr_t* p, cmGrCbId_t id, unsigned eventFlags, cmGrKeyCodeId_t keycode )
{
if( p->cbFunc != NULL )
{
cmGrH_t h;
h.h = p;
p->cbFunc(p->cbArg,h,id,eventFlags,keycode);
}
}
cmGrRC_t cmGrCreate( cmCtx_t* ctx, cmGrH_t* hp, unsigned id, unsigned cfgFlags, cmGrCbFunc_t cbFunc, void* cbArg, const cmGrVExt_t* wext )
{
cmGrRC_t rc = kOkGrRC;
cmGrVExt_t null_ext;
cmGrObjH_t rootObjH = cmGrObjNullHandle;
if(( rc = cmGrDestroy(hp)) != kOkGrRC )
return rc;
// create the cmGr_t
cmGr_t* p = cmMemAllocZ(cmGr_t,1);
p->ctx = *ctx;
p->id = id;
p->stateFlags = kDirtyGrFl;
p->cbFunc = cbFunc;
p->cbArg = cbArg;
_cmGrSetCfgFlags(p,cfgFlags);
if( wext == NULL )
{
cmGrVExtSetNull(&null_ext);
wext = &null_ext;
}
cmErrSetup(&p->err,&ctx->rpt,"cmGr");
if( cmLHeapIsValid( p->lhH = cmLHeapCreate(8192,ctx)) == false )
{
rc = cmErrMsg(&p->err,kLHeapFailGrRC,"Linked heap create failed.");
goto errLabel;
}
cmGrVExtSetEmpty(&p->vext);
cmGrPExtSetEmpty(&p->pext);
hp->h = p;
// create the root object
cmGrObjFunc_t funcs;
memset(&funcs,0,sizeof(funcs));
funcs.vextCbFunc = _cmGrObjRootVExt;
funcs.isInsideCbFunc = _cmGrObjRootIsInside;
if((rc = cmGrObjCreate(*hp, &rootObjH, cmGrObjNullHandle, &funcs, cmInvalidId, 0, wext )) != kOkGrRC )
{
rc = cmErrMsg(&p->err,kRootObjCreateFailGrRC,"The root object creation failed.");
goto errLabel;
}
// create the default color map
_cmGrRgbInitDefaultColorMap(p);
p->objs = _cmGrObjHandleToPtr(rootObjH);
p->rootObj = p->objs;
_cmGrCallback(p,kCreateCbGrId,0,kInvalidKeyCodeGrId);
errLabel:
if( rc != kOkGrRC )
{
_cmGrDestroy(p);
hp->h = NULL;
}
return rc;
}
cmGrRC_t cmGrDestroy( cmGrH_t* hp )
{
cmGrRC_t rc = kOkGrRC;
if( hp==NULL || cmGrIsValid(*hp) == false )
return kOkGrRC;
cmGr_t* p = _cmGrHandleToPtr(*hp);
if((rc = _cmGrDestroy(p)) != kOkGrRC )
goto errLabel;
hp->h = NULL;
errLabel:
return rc;
}
// Destroy all objects (except the root object)
cmGrRC_t _cmGrObjDestroyAll( cmGr_t* p )
{
cmGrObj_t* op = p->objs;
if( op != NULL )
{
op = op->children;
while( op != NULL )
{
cmGrObj_t* np = op->rsib;
_cmGrObjUnlinkAndFree(p,op);
op = np;
}
}
return kOkGrRC;
}
cmGrRC_t cmGrClear( cmGrH_t h )
{
cmGrRC_t rc;
cmGr_t* p = _cmGrHandleToPtr(h);
if((rc = _cmGrObjDestroyAll(p)) != kOkGrRC )
return rc;
p->rootObj = p->objs;
p->stateFlags = kDirtyGrFl;
cmGrVExtSetEmpty(&p->vext);
p->msDnObj = NULL;
cmGrPPtSet(&p->msDnPPt,0,0);
cmGrVPtSet(&p->msDnVPt,0,0);
cmGrVPtSet(&p->msVPt,0,0);
cmGrVSzSet(&p->msDnVOffs,0,0);
p->selValidFl = false;
cmGrVPtSet(&p->sel0Pt,0,0);
cmGrVPtSet(&p->sel1Pt,0,0);
cmGrVPtSet(&p->localPt,0,0);
cmGrVPtSet(&p->globalPt,0,0);
cmGrVExtSetNull(&p->rootObj->wext);
return rc;
}
cmGrObjH_t cmGrRootObjH( cmGrH_t h )
{
cmGr_t* p = _cmGrHandleToPtr(h);
cmGrObjH_t oh;
oh.h = p->rootObj;
return oh;
}
unsigned cmGrCfgFlags( cmGrH_t h )
{
cmGr_t* p = _cmGrHandleToPtr(h);
return p->cfgFlags;
}
void cmGrSetCfgFlags( cmGrH_t h, unsigned cfgFlags )
{
cmGr_t* p = _cmGrHandleToPtr(h);
_cmGrSetCfgFlags(p,cfgFlags);
}
void _cmGrObjDraw( cmGr_t* p, cmGrObj_t* op, cmGrDcH_t dcH )
{
_cmGrObjCbRender(p,dcH,op);
if( op->children != NULL )
_cmGrObjDraw(p,op->children,dcH);
if( op->rsib != NULL )
_cmGrObjDraw(p,op->rsib,dcH);
}
void _cmInvertImage( cmGr_t* p, cmGrDcH_t dcH, const cmGrPExt_t* pext )
{
if( cmGrPExtIsNullOrEmpty(pext) )
return;
cmGrPExt_t r;
cmGrPExtIntersect( &r, pext, &p->pext );
unsigned n = r.sz.w * r.sz.h * 3;
if( n > 0 )
{
unsigned i;
p->img = cmMemResizeZ(unsigned char,p->img,n);
//p->dd.read_image(p->ddUser, p->img, r.loc.x, r.loc.y, r.sz.w, r.sz.h );
cmGrDcReadImage( dcH, p->img, &r );
for(i=0; i<n; ++i)
p->img[i] = 255 - p->img[i];
//p->dd.draw_image(p->ddUser, p->img, r.loc.x, r.loc.y, r.sz.w, r.sz.h);
cmGrDcDrawImage( dcH, p->img, &r);
}
}
cmGrRC_t cmGrDraw( cmGrH_t h, cmGrDcH_t dcH )
{
cmGr_t* p = _cmGrHandleToPtr(h);
_cmGrObjDraw(p,p->rootObj,dcH);
cmGrPExt_t pext;
cmGrVExt_t vext;
cmGrSelectExtents(h,&vext,&pext);
if( cmGrPExtIsNotNull(&pext))
{
if( pext.sz.w<=1 && pext.sz.h<=1 )
{
cmGrPExt_t ipext;
if( !cmIsFlag(p->cfgFlags,kSelectHorzGrFl) )
{
cmGrPExtSet(&ipext,p->pext.loc.x,pext.loc.y,p->pext.sz.w,1);
_cmInvertImage(p,dcH,&ipext);
}
if( !cmIsFlag(p->cfgFlags,kSelectVertGrFl) )
{
cmGrPExtSet(&ipext,pext.loc.x,p->pext.loc.y,1,p->pext.sz.h);
_cmInvertImage(p,dcH,&ipext);
}
}
else
{
_cmInvertImage(p,dcH,&pext);
}
}
return kOkGrRC;
}
bool _cmGrSetViewExtents( cmGr_t* p, cmGrV_t minx, cmGrV_t miny, cmGrV_t maxx, cmGrV_t maxy )
{
cmGrVExt_t vext;
// load a vext with the new view extents
cmGrVExtSetD(&vext,minx,miny,maxx,maxy);
// if the view ext is not changing
if( cmGrVExtIsEqual(&p->vext,&vext) )
return false;
// the root object must exist
assert( p->rootObj != NULL );
// the view extents must be in the world extents
if( cmGrVExtIsExtInside(&p->rootObj->wext,&vext)==false )
{
cmErrMsg(&p->err,kInvalidCoordsGrRC,"View extent is not inside the world extents.");
return false;
}
//cmGrVExtPrint("set vw:",&vext);
p->vext = vext;
p->stateFlags = cmSetFlag(p->stateFlags,kDirtyGrFl);
_cmGrCallback(p, kViewExtCbGrId,0,kInvalidKeyCodeGrId );
// apply changes to synch target
cmGrSync_t* sp = p->syncs;
for(; sp!=NULL; sp=sp->link)
if( cmIsFlag(sp->flags,kViewSyncGrFl) )
{
cmGrViewExtents( sp->grH, &vext );
bool fl = false;
if( cmIsFlag(sp->flags,kHorzSyncGrFl) )
{
fl = true;
vext.loc.x = p->vext.loc.x;
vext.sz.w = p->vext.sz.w;
}
if( cmIsFlag(sp->flags,kVertSyncGrFl) )
{
fl = true;
vext.loc.y = p->vext.loc.y;
vext.sz.h = p->vext.sz.h;
}
if( fl )
cmGrSetViewExtentsE( sp->grH, &vext );
}
//printf("s:%p %f %f %f %f\n",p,p->vext.loc.x, p->vext.loc.y, p->vext.sz.w, p->vext.sz.h );
return true;
}
bool _cmGrSetScrollH( cmGr_t* p, int x )
{
assert( p->rootObj != NULL );
cmGrV_t vx = p->rootObj->wext.loc.x + (x * p->vext.sz.w / p->pext.sz.w);
return _cmGrSetViewExtents(p,vx, p->vext.loc.y, vx+p->vext.sz.w, p->vext.loc.y+p->vext.sz.h);
}
int _cmGrScrollH( cmGr_t* p )
{ return round((p->vext.loc.x - p->rootObj->wext.loc.x) * p->pext.sz.w / p->vext.sz.w); }
bool _cmGrSetScrollV( cmGr_t* p, int y )
{
assert( p->rootObj != NULL );
cmGrV_t vy = p->rootObj->wext.loc.y + (y * p->vext.sz.h / p->pext.sz.h);
return _cmGrSetViewExtents(p, p->vext.loc.x, vy, p->vext.loc.x+p->vext.sz.w, vy + p->vext.sz.h);
}
int _cmGrScrollV( cmGr_t* p )
{ return round((p->vext.loc.y - p->rootObj->wext.loc.y) * p->pext.sz.h / p->vext.sz.h); }
void _cmGrSetSelectPoints(cmGr_t* p, const cmGrVPt_t* pt0, const cmGrVPt_t* pt1)
{
bool deltaFl = false;
p->selValidFl = true;
if( pt0 != NULL )
{
if( cmGrVPtIsNotEqual(&p->sel0Pt,pt0) )
{
p->sel0Pt = *pt0;
deltaFl = true;
}
if( pt1 == NULL && cmGrVPtIsNotEqual(&p->sel1Pt,pt0) )
{
p->sel1Pt = *pt0;
deltaFl = true;
}
}
if( pt1 != NULL && cmGrVPtIsNotEqual(&p->sel1Pt,pt1) )
{
p->sel1Pt = *pt1;
deltaFl = true;
}
if( !deltaFl )
return;
_cmGrCallback(p,kSelectExtCbGrId,0,kInvalidKeyCodeGrId);
// apply changes to synch target
cmGrSync_t* sp = p->syncs;
for(; sp!=NULL; sp=sp->link)
if( cmIsFlag(sp->flags,kSelectSyncGrFl) )
{
cmGrVPt_t pt0, pt1;
cmGrSelectPoints(sp->grH, &pt0, &pt1 );
bool fl = false;
if( cmIsFlag(sp->flags,kHorzSyncGrFl) )
{
fl = true;
pt0.x = p->sel0Pt.x;
pt1.x = p->sel1Pt.x;
}
if( cmIsFlag(sp->flags,kVertSyncGrFl) )
{
fl = true;
pt0.y = p->sel0Pt.y;
pt1.y = p->sel1Pt.y;
}
if( fl )
cmGrSetSelectPoints( sp->grH, &pt0, &pt1 );
}
}
void _cmGrScrollExtents( cmGr_t* p, cmGrPSz_t* tot, cmGrPSz_t* vis, cmGrPSz_t* max, cmGrPPt_t* pos )
{
assert( p->rootObj != NULL );
if( tot != NULL )
{
tot->w = round(p->rootObj->wext.sz.w * p->pext.sz.w / p->vext.sz.w);
tot->h = round(p->rootObj->wext.sz.h * p->pext.sz.h / p->vext.sz.h);
}
if( vis != NULL )
{
vis->w = round(p->vext.sz.w * p->pext.sz.w / p->vext.sz.w);
vis->h = round(p->vext.sz.h * p->pext.sz.h / p->vext.sz.h);
}
if( max != NULL )
{
max->w = tot->w - vis->w;
max->h = tot->h - vis->h;
}
if( pos != NULL )
{
pos->x = _cmGrScrollH(p);
pos->y = _cmGrScrollV(p);
}
}
// vx,vy are in the same coord's as op->vext
cmGrObj_t* _cmGrFindObjRec( cmGr_t* p, cmGrObj_t* op, unsigned evtFlags, int px, int py, cmGrV_t vx, cmGrV_t vy )
{
cmGrObj_t* rop = NULL;
cmGrObj_t* top;
cmGrVExt_t vext;
// get the location of op inside op->parent->wext
_cmGrObjCbVExt(p,op,&vext);
// is vx,vy inside op - this is equiv to: cmGrVExtIsXyInside(&vext,vx,vy)
if( _cmGrObjCbIsInside(p,op,evtFlags,px,py,vx,vy) )
rop = op;
if( op->children != NULL )
{
cmGrVPt_t pt;
if( _cmGrParentToLocal(p,op,vx,vy,&pt) )
if((top = _cmGrFindObjRec(p,op->children,evtFlags,px,py,vx,vy)) != NULL )
rop = top;
}
if( op->rsib != NULL )
if((top = _cmGrFindObjRec(p,op->rsib,evtFlags,px,py,vx,vy)) != NULL )
rop = top;
return rop;
}
cmGrObj_t* _cmGrEventMsDown( cmGr_t* p, unsigned evtFlags, cmGrKeyCodeId_t key, int px, int py, cmGrV_t gx, cmGrV_t gy )
{
// store the phys loc. of the ms dn event
cmGrPPtSet(&p->msDnPPt,px,py);
// get a pointer to an object
cmGrObj_t* op = _cmGrFindObjRec(p, p->rootObj, evtFlags, px, py, gx, gy );
// if the mouse did not go down in an object that accepts mouse down events
// or the object was a root object
if( op == NULL || op->parent == NULL )
return NULL;
// store the object and coord's where the mouse went down.
cmGrVExt_t vext;
p->msDnObj = op; // set the msDnObj
// convert the phys ms dn point to the virt point inside op->parent.wext
_cmGrXY_PtoV(p, op->parent, px, py, &p->msDnVPt );
p->msVPt = p->msDnVPt; // set the current ms virt pt
p->localPt = p->msDnVPt; // set the current local pt
// notifiy the app of the local coord's
_cmGrCallback(p,kLocalPtCbGrId,0,kInvalidKeyCodeGrId);
// get the ms down obj virt extents
_cmGrObjCbVExt(p,op,&vext);
// store the offset from the lower left to the ms dn point
p->msDnVOffs.w = p->msDnVPt.x - vext.loc.x;
p->msDnVOffs.h = p->msDnVPt.y - vext.loc.y;
// notify the object that the mouse went down
if(_cmGrObjCbEvent(p,op,evtFlags,key,px,py))
return op;
return NULL;
}
cmGrObj_t* _cmGrEventMsUp( cmGr_t* p, unsigned evtFlags, cmGrKeyCodeId_t key, int px, int py, cmGrV_t gx, cmGrV_t gy )
{
bool fl = false;
cmGrObj_t* op = NULL;
cmGrPPt_t upPPt;
cmGrPPtSet(&upPPt,px,py);
// if a click occured ...
if( cmGrPPtIsEqual(&p->msDnPPt,&upPPt ) )
{
// ... and the click is in a non-root object which accepts click events ...
if( p->msDnObj!= NULL && p->msDnObj->parent!=NULL && _cmGrObjCbIsInside(p,p->msDnObj,evtFlags | kMsClickGrFl, px, py, gx, gy) )
{
// ... then generate a click event
unsigned newEvtFlags = cmClrFlag(evtFlags,kMsUpGrFl) | kMsClickGrFl;
fl = _cmGrObjCbEvent(p,p->msDnObj,newEvtFlags,key,px,py);
op = p->msDnObj;
}
else // ... else if the click occurred in the root object
//if( p->msDnObj==NULL || p->msDnObj->parent==NULL)
{
cmGrVPt_t pt;
cmGrVPtSet(&pt,gx,gy);
bool shFl = cmIsFlag(evtFlags,kShiftKeyGrFl);
_cmGrSetSelectPoints( p, shFl ? NULL : &pt, shFl ? &pt : NULL );
}
}
// if op is NULL then there was no-mouse down object to match with
// this mouse-up event - find an object to match with the mouse-up event
if( op == NULL )
op = _cmGrFindObjRec(p, p->rootObj, evtFlags, px, py, gx, gy );
// if a mouse-up object was found then
if( op != NULL && op->parent != NULL)
{
// notify the object under the mouse that the mouse went up
if( _cmGrObjCbEvent(p,op,evtFlags,key,px,py) )
fl = true;
// convert the phys ms dn point to the virt point inside op->parent.wext
_cmGrXY_PtoV(p, op->parent, px, py, &p->msVPt );
}
_cmGrCallback(p,kFocusCbGrId,0,kInvalidKeyCodeGrId);
p->msDnObj = NULL;
return fl ? op : NULL;
}
cmGrObj_t* _cmGrEventMsMove( cmGr_t* p, unsigned evtFlags, cmGrKeyCodeId_t key, int px, int py, cmGrV_t gx, cmGrV_t gy )
{
bool fl = false;
cmGrObj_t* op = _cmGrFindObjRec(p, p->rootObj, evtFlags, px, py, gx, gy );
if( op != NULL && op->parent != NULL )
{
fl = _cmGrObjCbEvent(p,op,evtFlags,key,px,py);
}
return fl ? op : NULL;
}
cmGrObj_t* _cmGrEventMsDrag( cmGr_t* p, unsigned evtFlags, cmGrKeyCodeId_t key, int px, int py, cmGrV_t gx, cmGrV_t gy )
{
bool fl = false;
cmGrObj_t* op = _cmGrFindObjRec(p, p->rootObj, evtFlags, px, py, gx, gy );
if( op != NULL && op->parent != NULL )
{
// set the current virtual point
_cmGrXY_PtoV(p, p->msDnObj->parent, px, py, &p->msVPt );
// callback the dragged object
fl = _cmGrObjCbEvent(p,p->msDnObj,evtFlags,key,px,py);
// if the px,py is outside the root phys extents then scroll
if( !cmGrPExtIsXyInside(&p->pext,px,py) )
{
bool hFl = false, vFl=false;
cmGrPSz_t tot,vis,max;
cmGrPPt_t pos;
_cmGrScrollExtents(p, &tot, &vis, &max, &pos );
if( px < cmGrPExtL(&p->pext) )
hFl = _cmGrSetScrollH(p, cmMax(0, _cmGrScrollH(p) - (cmGrPExtL(&p->pext) - px)));
else
if( px > cmGrPExtR(&p->pext) )
hFl = _cmGrSetScrollH(p, cmMin(max.w, _cmGrScrollH(p) + (px - cmGrPExtR(&p->pext))));
if( py < cmGrPExtT(&p->pext) )
vFl = _cmGrSetScrollV(p, cmMax(0, _cmGrScrollV(p) - (cmGrPExtT(&p->pext) - py)));
else
if( py > cmGrPExtB(&p->pext) )
vFl = _cmGrSetScrollV(p, cmMin(max.h, _cmGrScrollV(p) + (py - cmGrPExtB(&p->pext))));
fl = fl || vFl || hFl;
}
}
return fl ? op : NULL;
}
bool cmGrEvent( cmGrH_t h, unsigned evtFlags, cmGrKeyCodeId_t key, int px, int py )
{
bool fl = false;
cmGrObj_t* op = NULL;
cmGr_t* p = _cmGrHandleToPtr(h);
cmGrVPtSet(&p->localPt,0,0);
// convert the phys points to points in the root coord system
cmGrV_t gx = _cmGr_X_PtoV(p,px);
cmGrV_t gy = _cmGr_Y_PtoV(p,py);
// set the global point
cmGrVPtSet(&p->globalPt,gx,gy);
// inform the app of the possibly new global point
_cmGrCallback(p,kGlobalPtCbGrId,0,kInvalidKeyCodeGrId);
switch( evtFlags & kEvtMask)
{
case kKeyUpGrFl:
_cmGrCallback(p,kKeyUpCbGrId,evtFlags,key);
break;
case kKeyDnGrFl:
_cmGrCallback(p,kKeyDnCbGrId,evtFlags,key);
break;
case kMsDownGrFl:
op = _cmGrEventMsDown(p,evtFlags,key,px,py,gx,gy);
break;
case kMsUpGrFl: // handle mouse-up, mouse-click, and focus events
op = _cmGrEventMsUp(p,evtFlags,key,px,py,gx,gy);
break;
case kMsMoveGrFl:
op = _cmGrEventMsMove(p,evtFlags,key,px,py,gx,gy);
break;
case kMsDragGrFl:
op = _cmGrEventMsDrag(p,evtFlags,key,px,py,gx,gy);
break;
}
if( op != NULL )
{
// convert gx,gy to be inside op->wext
cmGrVPtSet(&p->localPt,gx,gy);
_cmGrXY_GlobalToLocal(p,op,&p->localPt);
_cmGrCallback(p,kLocalPtCbGrId,0,kInvalidKeyCodeGrId);
fl = true;
}
return fl;
}
bool cmGrEvent1( cmGrH_t h, unsigned flags, cmGrKeyCodeId_t key, int px, int py )
{
bool fl = false;
cmGr_t* p = _cmGrHandleToPtr(h);
cmGrObj_t* op;
cmGrVPtSet(&p->localPt,0,0);
// convert the phys points to points in the root coord system
cmGrV_t gx = _cmGr_X_PtoV(p,px);
cmGrV_t gy = _cmGr_Y_PtoV(p,py);
cmGrVPtSet(&p->globalPt,gx,gy);
_cmGrCallback(p,kGlobalPtCbGrId,0,kInvalidKeyCodeGrId);
// find the obj under the mouse
if((op = _cmGrFindObjRec(p,p->rootObj,flags&kEvtMask,px,py,gx,gy)) != NULL )
{
// convert gx,gy to be inside op->wext
cmGrVPtSet(&p->localPt,gx,gy);
_cmGrXY_GlobalToLocal(p,op,&p->localPt);
_cmGrCallback(p,kLocalPtCbGrId,0,kInvalidKeyCodeGrId);
}
if( (flags&kEvtMask)==kKeyUpGrFl )
_cmGrCallback(p,kKeyUpCbGrId,flags,key);
if( (flags&kEvtMask)==kKeyDnGrFl )
_cmGrCallback(p,kKeyDnCbGrId,flags,key);
if( op != NULL )
{
switch( flags & kEvtMask )
{
case kMsDownGrFl:
// store the phys loc. of the ms dn event
cmGrPPtSet(&p->msDnPPt,px,py);
if( op != NULL )
{
// if the click was in not in the root object
if( op->parent != NULL )
{
// store the object and coord's where the mouse went down.
cmGrVExt_t vext;
p->msDnObj = op; // set the msDnObj
// convert the phys ms dn point to the virt point inside op->parent.wext
_cmGrXY_PtoV(p, op->parent, px, py, &p->msDnVPt );
// set the current ms virt pt
p->msVPt = p->msDnVPt;
// get the ms down obj virt extents
_cmGrObjCbVExt(p,op,&vext);
// store the offset from the lower left to the ms dn point
p->msDnVOffs.w = p->msDnVPt.x - vext.loc.x;
p->msDnVOffs.h = p->msDnVPt.y - vext.loc.y;
// notify the object that the mouse went down
fl = _cmGrObjCbEvent(p,op,flags,key,px,py);
}
}
break;
case kMsUpGrFl:
{
cmGrPPt_t upPPt;
cmGrPPtSet(&upPPt,px,py);
bool clickFl = cmGrPPtIsEqual(&p->msDnPPt,&upPPt );
// if a click occured ...
if( clickFl )
{
// ... and the click is in a non-root object ...
if( p->msDnObj!= NULL && p->msDnObj->parent!=NULL )
{
// ... then generate a click event
unsigned evtFlags = cmClrFlag(flags,kMsUpGrFl) | kMsClickGrFl;
fl = _cmGrObjCbEvent(p,op,evtFlags,key,px,py);
}
else // ... else if the click occurred in the root object
{
cmGrVPt_t pt;
cmGrVPtSet(&pt,gx,gy);
bool shFl = cmIsFlag(flags,kShiftKeyGrFl);
_cmGrSetSelectPoints( p, shFl ? NULL : &pt, shFl ? &pt : NULL );
}
}
// notify the object under the mouse that the mouse went up
if( _cmGrObjCbEvent(p,op,flags,key,px,py) )
fl = true;
_cmGrCallback(p,kFocusCbGrId,0,kInvalidKeyCodeGrId);
p->msDnObj = NULL;
}
break;
case kMsMoveGrFl:
fl = _cmGrObjCbEvent(p,op,flags,key,px,py);
break;
case kMsWheelGrFl:
break;
case kMsDragGrFl:
if( p->msDnObj != NULL )
{
// set the current virtual point
_cmGrXY_PtoV(p, p->msDnObj->parent, px, py, &p->msVPt );
// callback the dragged object
fl = _cmGrObjCbEvent(p,p->msDnObj,flags,key,px,py);
// if the px,py is outside the root phys extents then scroll
if( !cmGrPExtIsXyInside(&p->pext,px,py) )
{
bool hFl = false, vFl=false;
cmGrPSz_t tot,vis,max;
cmGrPPt_t pos;
cmGrScrollExtents(h, &tot, &vis, &max, &pos );
if( px < cmGrPExtL(&p->pext) )
hFl = _cmGrSetScrollH(p, cmMax(0, _cmGrScrollH(p) - (cmGrPExtL(&p->pext) - px)));
else
if( px > cmGrPExtR(&p->pext) )
hFl = _cmGrSetScrollH(p, cmMin(max.w, _cmGrScrollH(p) + (px - cmGrPExtR(&p->pext))));
if( py < cmGrPExtT(&p->pext) )
vFl = _cmGrSetScrollV(p, cmMax(0, _cmGrScrollV(p) - (cmGrPExtT(&p->pext) - py)));
else
if( py > cmGrPExtB(&p->pext) )
vFl = _cmGrSetScrollV(p, cmMin(max.h, _cmGrScrollV(p) + (py - cmGrPExtB(&p->pext))));
fl = fl || vFl || hFl;
}
}
break;
case kKeyDnGrFl:
case kKeyUpGrFl:
//fl = _cmGrObjCbEvent(p,p->msDnObj,flags,key,px,py);
break;
}
}
return fl;
}
bool cmGrIsValid( cmGrH_t h )
{ return h.h != NULL; }
unsigned cmGrId( cmGrH_t h )
{
cmGr_t* p = _cmGrHandleToPtr(h);
return p->id;
}
const cmGrVPt_t* cmGrGlobalPt( cmGrH_t h )
{
cmGr_t* p = _cmGrHandleToPtr(h);
return &p->globalPt;
}
const cmGrVPt_t* cmGrLocalPt( cmGrH_t h )
{
cmGr_t* p = _cmGrHandleToPtr(h);
return &p->localPt;
}
bool cmGrSetViewExtents( cmGrH_t h, cmGrV_t minx, cmGrV_t miny, cmGrV_t maxx, cmGrV_t maxy )
{ return _cmGrSetViewExtents( _cmGrHandleToPtr(h), minx,miny,maxx,maxy); }
bool cmGrSetViewExtentsE( cmGrH_t h, const cmGrVExt_t* e )
{ return cmGrSetViewExtents( h, cmGrVExtMinX(e), cmGrVExtMinY(e), cmGrVExtMaxX(e), cmGrVExtMaxY(e) ); }
void cmGrViewExtents( cmGrH_t h, cmGrVExt_t* vext )
{
cmGr_t* p = _cmGrHandleToPtr(h);
*vext = p->vext;
//printf("g0:%p %f %f %f %f\n",p,p->vext.loc.x, p->vext.loc.y, p->vext.sz.w, p->vext.sz.h );
//printf("g1:%p %f %f %f %f\n",p,vext->loc.x, vext->loc.y, vext->sz.w, vext->sz.h );
}
bool cmGrSetPhysExtents( cmGrH_t hh, int x, int y, int w, int h )
{
cmGr_t* p = _cmGrHandleToPtr(hh);
cmGrPExt_t pext;
cmGrPExtSet(&pext,x,y,w,h);
assert( cmGrPExtIsNull(&pext)==false );
if( cmGrPExtIsEqual(&pext,&p->pext) )
return false;
p->pext = pext;
p->stateFlags = cmSetFlag(p->stateFlags,kDirtyGrFl);
_cmGrCallback(p,kPhysExtCbGrId,0,kInvalidKeyCodeGrId);
//cmGrPExtPrint("pext",&p->pext);
return true;
}
bool cmGrSetPhysExtentsE(cmGrH_t h, const cmGrPExt_t* e )
{ return cmGrSetPhysExtents(h, cmGrPExtL(e), cmGrPExtT(e), cmGrPExtW(e), cmGrPExtH(e) ); }
void cmGrPhysExtents( cmGrH_t h, cmGrPExt_t* exts )
{
cmGr_t* p = _cmGrHandleToPtr(h);
*exts = p->pext;
}
void cmGrScrollExtents( cmGrH_t h, cmGrPSz_t* tot, cmGrPSz_t* vis, cmGrPSz_t* max, cmGrPPt_t* pos )
{
cmGr_t* p = _cmGrHandleToPtr(h);
_cmGrScrollExtents(p,tot,vis,max,pos);
}
bool cmGrSetScrollH( cmGrH_t h, int x )
{ return _cmGrSetScrollH( _cmGrHandleToPtr(h), x ); }
int cmGrScrollH( cmGrH_t h )
{ return _cmGrScrollH( _cmGrHandleToPtr(h) ); }
bool cmGrSetScrollV( cmGrH_t h, int y )
{ return _cmGrSetScrollV( _cmGrHandleToPtr(h), y ); }
int cmGrScrollV( cmGrH_t h )
{ return _cmGrScrollV( _cmGrHandleToPtr(h) ); }
bool cmGrSelectExtents( cmGrH_t h, cmGrVExt_t* vext, cmGrPExt_t* pext )
{
cmGrPPt_t pt0,pt1;
cmGr_t* p = _cmGrHandleToPtr(h);
if( !p->selValidFl )
{
cmGrVExtSetNull(vext);
cmGrPExtSetNull(pext);
return false;
}
if( p->sel0Pt.x == p->sel1Pt.x && p->sel0Pt.y == p->sel1Pt.y )
cmGrVExtSet(vext, p->sel0Pt.x, p->sel0Pt.y, 0, 0);
else
{
cmGrV_t gx0=p->sel0Pt.x, gy0=p->sel0Pt.y;
cmGrV_t gx1=p->sel1Pt.x, gy1=p->sel1Pt.y;
if( cmIsFlag(p->cfgFlags,kSelectHorzGrFl) )
{
gy0 = cmGrVExtMaxY(&p->rootObj->wext);
gy1 = cmGrVExtMinY(&p->rootObj->wext);
}
else
if( cmIsFlag(p->cfgFlags,kSelectVertGrFl ) )
{
gx0 = cmGrVExtMinX(&p->rootObj->wext);
gx1 = cmGrVExtMaxX(&p->rootObj->wext);
}
cmGrVExtSetD(vext,cmMin(gx0,gx1),cmMin(gy0,gy1),cmMax(gx0,gx1),cmMax(gy0,gy1));
}
_cmGrXY_VtoP(p, p->rootObj, vext->loc.x, vext->loc.y, &pt0 );
_cmGrXY_VtoP(p, p->rootObj, vext->loc.x + vext->sz.w, vext->loc.y + vext->sz.h, &pt1 );
cmGrPExtSetD(pext,cmMin(pt0.x,pt1.x),cmMin(pt0.y,pt1.y),cmMax(pt0.x,pt1.x),cmMax(pt0.y,pt1.y));
//printf("%f %f %f %f\n",vext->loc.x,vext->loc.y,vext->sz.w,vext->sz.h);
//printf("%i %i %i %i\n",pext->loc.x,pext->loc.y,pext->sz.w,pext->sz.h);
return true;
}
void cmGrSetSelectPoints( cmGrH_t h, const cmGrVPt_t* pt0, const cmGrVPt_t* pt1 )
{
cmGr_t* p = _cmGrHandleToPtr(h);
_cmGrSetSelectPoints(p,pt0,pt1);
}
void cmGrSelectPoints( cmGrH_t h, cmGrVPt_t* pt0, cmGrVPt_t* pt1 )
{
cmGr_t* p = _cmGrHandleToPtr(h);
if( pt0 != NULL )
*pt0 = p->sel0Pt;
if( pt1 != NULL )
*pt1 = p->sel1Pt;
}
void cmGrZoom( cmGrH_t h, unsigned flags )
{
cmGr_t* p = _cmGrHandleToPtr(h);
bool hfl = cmIsFlag(flags,kXAxisGrFl);
bool vfl = cmIsFlag(flags,kYAxisGrFl);
bool inFl = cmIsFlag(flags,kZoomInGrFl);
bool allFl = cmIsFlag(flags,kShowAllGrFl);
double magn = 3.0;
double ratio = inFl ? 1.0/magn : magn;
cmGrVPt_t c;
cmGrVExt_t z;
cmGrVExt_t v;
cmGrVExt_t w;
cmGrVExtSetNull(&z);
cmGrViewExtents( h,&v); // get the current view extents
cmGrObjWorldExt( cmGrRootObjH(h),&w); // get the current world extents
// if show all was requested ...
if( allFl )
{
// .. then the world ext's become the view extents.
cmGrVExtSetD(&z,
hfl ? cmGrVExtMinX(&w) : cmGrVExtMinX(&v),
vfl ? cmGrVExtMinY(&w) : cmGrVExtMinY(&v),
hfl ? cmGrVExtMaxX(&w) : cmGrVExtMaxX(&v),
vfl ? cmGrVExtMaxY(&w) : cmGrVExtMaxY(&v));
}
else
{
// if the selection flag is not set or the selection pt/area is not valid
if( cmIsNotFlag(flags,kSelectGrFl) || p->selValidFl==false )
{
// center the zoom on the current view
c.x = v.loc.x + v.sz.w/2;
c.y = v.loc.y + v.sz.h/2;
}
else
{
// if the selection area is a point
if( p->sel0Pt.x == p->sel1Pt.x && p->sel0Pt.y == p->sel1Pt.y )
{
// center the zoom on the current view
c.x = p->sel0Pt.x;
c.y = p->sel1Pt.y;
}
else
{
cmGrPExt_t dum;
// The selection area exist - make it the new view area
// Note that f the selection area is greater than the
// current view area then this may not be a magnification.
cmGrSelectExtents(h,&z,&dum);
}
}
// if no zoom area has been created then create
// one centered on 'c'.
if( cmGrVExtIsNull(&z) )
{
cmGrVExt_t t;
cmGrV_t zw = v.sz.w * ratio / 2;
cmGrV_t zh = v.sz.h * ratio / 2;
cmGrVExtSetD(&t,
hfl ? c.x-zw : cmGrVExtMinX(&v),
vfl ? c.y-zh : cmGrVExtMinY(&v),
hfl ? c.x+zw : cmGrVExtMaxX(&v),
vfl ? c.y+zh : cmGrVExtMaxY(&v));
cmGrVExtIntersect(&z,&t,&w);
}
}
//cmGrVExtPrint("w:",&w);
//cmGrVExtPrint("z:",&z);
//cmGrVExtPrint("v:",&v);
assert( cmGrVExtIsNorm(&z));
cmGrSetViewExtentsE(h,&z);
}
void cmGrSetSync( cmGrH_t h, cmGrH_t syncGrH, unsigned flags )
{
cmGr_t* p = _cmGrHandleToPtr(h);
// attempt to locate syncGrH on the sync list
cmGrSync_t* pp = NULL;
cmGrSync_t* sp = p->syncs;
for(; sp != NULL; sp=sp->link)
{
if( cmHandlesAreEqual(sp->grH,syncGrH) )
break;
pp = sp;
}
// if the handle was not found ...
if( sp == NULL )
{
// ... and a valid flags value was given ...
if( flags != 0 )
{
// ... then create a new sync target.
sp = cmMemAllocZ(cmGrSync_t,1);
sp->grH = syncGrH;
sp->flags = flags;
sp->link = p->syncs;
p->syncs = sp;
}
}
else // ... otherwise syncGrH is already a sync target
{
// if flags is non-zero then update the target sync flags
if( flags != 0 )
sp->flags = flags;
else
{
// otherwise delete the sync recd assoc'd with syncGrH
if( pp == NULL )
p->syncs = sp->link;
else
pp->link = sp->link;
cmMemFree(sp);
}
}
}
void cmGrReport( cmGrH_t h,cmRpt_t* r )
{
cmGr_t* p = _cmGrHandleToPtr(h);
cmRpt_t* rpt = r==NULL ? p->err.rpt : r;
cmRptPrintf(rpt,"cfg:0x%x state:0x%x\n",p->cfgFlags, p->stateFlags);
//cmRptPrintf(rpt,"World: "); cmGrVExtMaxXpt(&p->wext,rpt); cmRptPrintf(rpt,"\n");
cmRptPrintf(rpt,"View: "); cmGrVExtRpt(&p->vext,rpt); cmRptPrintf(rpt,"\n");
cmRptPrintf(rpt,"Phys: "); cmGrPExtRpt(&p->pext,rpt); cmRptPrintf(rpt,"\n");
_cmGrObjReportR(p,p->rootObj,rpt);
}
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