src/rt/RpictSimulManager.h

/* RCSid $Id: RpictSimulManager.h,v 2.10 2024/10/10 21:02:52 greg Exp $ */
/*
 *  RpictSimulManager.h
 *
 *      Rpict simulation manager class declaration
 *
 *  Created by Greg Ward on 07/11/2024.
 */

#ifndef RpictSimulManager_h
#define RpictSimulManager_h

#include "RtraceSimulManager.h"
#include "view.h"
#include "depthcodec.h"

/// Data type flags for pixel access and output
enum RenderDataType {
        RDTnone=0,
        RDTscolor=0x1, RDTrgb=0x2, RDTxyz=0x3, RDTscolr=0x4, RDTrgbe=0x5, RDTxyze=0x6,
        RDTcolorM=0x7,
        RDTdfloat=0x8, RDTdshort=0x10,
        RDTdepthM=0x18
};

#define RDTcolorT(f)    RenderDataType((f) & RDTcolorM)
#define RDTdepthT(f)    RenderDataType((f) & RDTdepthM)
#define RDTcommonE(f)   (RDTcolorT(f) >= RDTscolr)
#define RDTnewCT(f,c)   RenderDataType((f) & ~RDTcolorM | (c) & RDTcolorM)
#define RDTnewDT(f,d)   RenderDataType((f) & ~RDTdepthM | (d) & RDTdepthM)

/// Pixel accessor (read/write to caller's buffer with possible conversion)
class PixelAccess {
        union {
                COLORV *        f;
                COLRV *         b;
        }               pbase;          // pixel base pointer
        union {
                float *         f;
                short *         s;
        }               dbase;          // depth base pointer
        long            rowStride;      // # values to next y position
        int             dtyp;           // data type flags
        RGBPRIMP        primp;          // color primaries if tristimulus
        bool            swap2d;         // need to swap 16-bit depths?
        const COLORV *  CF3(int x, int y) const {
                                return pbase.f + (rowStride*y + x)*3;
                        }
        COLORV *        CF3(int x, int y) {
                                return pbase.f + (rowStride*y + x)*3;
                        }
        const COLRV *   CB3(int x, int y) const {
                                return pbase.b + (rowStride*y + x)*4;
                        }
        COLRV *         CB3(int x, int y) {
                                return pbase.b + (rowStride*y + x)*4;
                        }
        const COLORV *  SCF(int x, int y) const {
                                return pbase.f + (rowStride*y + x)*NCSAMP;
                        }
        COLORV *        SCF(int x, int y) {
                                return pbase.f + (rowStride*y + x)*NCSAMP;
                        }
        const COLRV *   SCB(int x, int y) const {
                                return pbase.b + (rowStride*y + x)*(NCSAMP+1);
                        }
        COLRV *         SCB(int x, int y) {
                                return pbase.b + (rowStride*y + x)*(NCSAMP+1);
                        }
        void            EncodeDepth16(int x, int y, float z) {
                                short * sp = dbase.s + rowStride*y + x;
                                *sp = depth2code(z, refDepth);
                                if (swap2d) swap16((char *)sp, 1);
                        }
        float           DecodeDepth16(int x, int y) const {
                                short   sv = dbase.s[rowStride*y + x];
                                if (swap2d) swap16((char *)&sv, 1);
                                return code2depth(sv, refDepth);
                        }
public:
        double          refDepth;       // reference depth
                        PixelAccess() {
                                refDepth = 1.;
                                swap2d = !nativebigendian();
                                Init();
                        }
                        PixelAccess(COLORV *rp, int ystride, float *zp=NULL) {
                                refDepth = 1.;
                                swap2d = !nativebigendian();
                                Init(rp, ystride, zp);
                        }
                        PixelAccess(COLRV *bp, int ystride, float *zp=NULL) {
                                refDepth = 1.;
                                swap2d = !nativebigendian();
                                Init(bp, ystride, zp);
                        }
                        PixelAccess(COLRV *bp, int ystride, short *dp) {
                                refDepth = 1.;
                                swap2d = !nativebigendian();
                                Init(bp, ystride, dp);
                        }
                        PixelAccess(COLORV *rp, int ystride, short *dp) {
                                refDepth = 1.;
                                swap2d = !nativebigendian();
                                Init(rp, ystride, dp);
                        }
        void            Init() {
                                pbase.f = NULL; dbase.f = NULL;
                                rowStride = 0;
                                primp = NULL;
                                dtyp = 0;
                        }
                        /// Initializers default to rendering color space
        void            Init(COLORV *rp, int ystride, float *zp=NULL) {
                                pbase.f = rp; dbase.f = zp;
                                rowStride = ystride;
                                if (NCSAMP > 3) {
                                        dtyp = RDTscolor; primp = NULL;
                                } else {
                                        dtyp = RDTrgb; primp = stdprims;
                                }
                                if (zp) dtyp |= RDTdfloat;
                        }
        void            Init(COLRV *bp, int ystride, float *zp=NULL) {
                                pbase.b = bp; dbase.f = zp;
                                rowStride = ystride;
                                if (NCSAMP > 3) {
                                        dtyp = RDTscolr; primp = NULL;
                                } else {
                                        dtyp = RDTrgbe; primp = stdprims;
                                }
                                if (zp) dtyp |= RDTdfloat;
                        }
        void            Init(COLRV *bp, int ystride, short *dp) {
                                pbase.b = bp; dbase.s = dp;
                                rowStride = ystride;
                                if (NCSAMP > 3) {
                                        dtyp = RDTscolr; primp = NULL;
                                } else {
                                        dtyp = RDTrgbe; primp = stdprims;
                                }
                                if (dp) dtyp |= RDTdshort;
                        }
        void            Init(COLORV *rp, int ystride, short *dp) {
                                pbase.f = rp; dbase.s = dp;
                                rowStride = ystride;
                                if (NCSAMP > 3) {
                                        dtyp = RDTscolor; primp = NULL;
                                } else {
                                        dtyp = RDTrgb; primp = stdprims;
                                }
                                if (dp) dtyp |= RDTdshort;
                        }
                        /// Set color space after non-empty initialization
        bool            SetColorSpace(RenderDataType cs, RGBPRIMP pr=NULL);
                        /// Get color space
        RenderDataType  ColorSpace() const {
                                return RDTcolorT(dtyp);
                        }
                        /// Get color primaries (NULL if spectral)
        RGBPRIMP        Primaries() const {
                                return primp;
                        }
                        /// Number of represented color/spectral components
        int             NC() const {
                                switch (ColorSpace()) {
                                case RDTrgb: case RDTrgbe:
                                case RDTxyz: case RDTxyze:
                                        return 3;
                                case RDTscolor: case RDTscolr:
                                        return NCSAMP;
                                default:;
                                }
                                return 0;
                        }
                        /// Get depth type
        RenderDataType  DepthType() const {
                                return RDTdepthT(dtyp);
                        }
                        /// Get row stride
        long            GetRowStride() const {
                                return rowStride;
                        }
                        /// Assign a pixel value (& depth) from rendered ray value
        bool            SetPixel(int x, int y, const RAY *rp);
                        /// Assign pixel color (& depth) -- may re-represent either/both
        bool            SetPixel(int x, int y, const COLORV *pv, float z=0) {
                                if (NC() == 3) {
                                        if (RDTcommonE(dtyp))
                                                setcolr(CB3(x,y), pv[RED], pv[GRN], pv[BLU]);
                                        else
                                                copycolor(CF3(x,y), pv);
                                } else if (RDTcommonE(dtyp))
                                        scolor_scolr(SCB(x,y), pv);
                                else
                                        copyscolor(SCF(x,y), pv);
                                if (DepthType() == RDTdfloat)
                                        dbase.f[rowStride*y + x] = z;
                                else if (DepthType() == RDTdshort)
                                        EncodeDepth16(x, y, z);
                                return true;
                        }
                        /// Retrieve pixel color (& depth) -- may convert either/both
        bool            GetPixel(int x, int y, COLORV *pv, float *zp=NULL) const {
                                if (NC() == 3) {
                                        if (RDTcommonE(dtyp))
                                                colr_color(pv, CB3(x,y));
                                        else
                                                copycolor(pv, CF3(x,y));
                                } else if (RDTcommonE(dtyp))
                                        scolr_scolor(pv, SCB(x,y));
                                else
                                        copyscolor(pv, SCF(x,y));
                                if (!zp) return true;
                                if (DepthType() == RDTdfloat)
                                        *zp = dbase.f[rowStride*y + x];
                                else if (DepthType() == RDTdshort)
                                        *zp = DecodeDepth16(x, y);
                                else
                                        *zp = .0f;
                                return true;
                        }
                        /// Copy pixel from one location to another (no conversion)
        bool            CopyPixel(int dx, int dy, int sx, int sy) {
                                if ((dx==sx) & (dy==sy)) return true;
                                const int       nc = NC();
                                if (nc == 3) {
                                        if (RDTcommonE(dtyp))
                                                copycolr(CB3(dx,dy), CB3(sx,sy));
                                        else
                                                copycolor(CF3(dx,dy), CF3(sx,sy));
                                } else if (RDTcommonE(dtyp))
                                        copyscolr(SCB(dx,dy), SCB(sx,sy));
                                else
                                        copyscolor(SCF(dx,dy), SCF(sx,sy));
                                switch (DepthType()) {
                                case RDTdfloat:
                                        dbase.f[rowStride*dy + dx] =
                                                        dbase.f[rowStride*sy + sx];
                                        break;
                                case RDTdshort:
                                        dbase.s[rowStride*dy + dx] =
                                                        dbase.s[rowStride*sy + sx];
                                        break;
                                default:;
                                }
                                return true;
                        }
};

/// Call-back function for progress reporting
typedef void    ProgReportCB(double pct);

/// rpict-like simulation manager (at most one such object)
class RpictSimulManager : protected RtraceSimulManager {
        static RayReportCall    RtCall;                 // our callback for cooked rays
        VIEW                    vw;                     // frame view
        VIEW                    pvw;                    // previous view
        int                     hvres[2];               // overall picture dimensions
        int                     tgsize[2];              // tile grid size
        int                     thvres[2];              // tile dimensions
        VIEW                    tvw, ptvw;              // this tile's view (& previous)
        PixelAccess             pacc;                   // pixel accessor
        char                    dunit[32];              // depth with units (if any)
        ABitMap2                doneMap;                // which tile pixels are done
        COLORV *                barPix;                 // current render bar pixels
        float *                 barDepth;               // current render bar depths
        bool                    SetTile(const int ti[2]);
        bool                    RenderRect(const int x0 = 0, const int y0 = 0);
        bool                    ComputePixel(int x, int y);
        bool                    BelowSampThresh(const int x, const int y,
                                                        const int noff[4][2]) const;
        void                    FillSquare(const int x, const int y, const int noff[4][2]);
        void                    NewBar(int ht = 0);
        bool                    LowerBar(int v, int ytop);
        bool                    RenderBelow(int ytop, const int vstep, FILE *pfp,
                                                        const int dt, FILE *dfp=NULL);
public:
        ProgReportCB *          prCB;                   // progress report call-back
        RGBPRIMP                prims;                  // output primaries (NULL if spectral)
        int                     frameNo;                // frame number (0 if not sequence)
                                RpictSimulManager(const char *octn = NULL) :
                                                        RtraceSimulManager(RtCall, this, octn) {
                                        tvw.type = vw.type = 0;
                                        hvres[0] = hvres[1] = 0;
                                        thvres[0] = thvres[1] = 0;
                                        pacc.refDepth = 1.; dunit[0] = '1'; dunit[1] = '\0';
                                        barPix = NULL; barDepth = NULL;
                                        prCB = NULL;
                                        prims = NULL;
                                        frameNo = 0;
                                }
                                ~RpictSimulManager() {
                                        delete [] barPix; delete [] barDepth;
                                }
                                /// Load octree and prepare renderer
        bool                    LoadOctree(const char *octn) {
                                        return RtraceSimulManager::LoadOctree(octn);
                                }
                                /// Prepare header from previous input (or clear)
        bool                    NewHeader(const char *inspec=NULL) {
                                        return RtraceSimulManager::NewHeader(inspec);
                                }
                                /// Add a string to header (adds newline if none)
        bool                    AddHeader(const char *str) {
                                        return RtraceSimulManager::AddHeader(str);
                                }
                                /// Append program line to header
        bool                    AddHeader(int ac, char *av[]) {
                                        return RtraceSimulManager::AddHeader(ac, av);
                                }
                                /// Get current header length in bytes
        int                     GetHeadLen() const {
                                        return RtraceSimulManager::GetHeadLen();
                                }
                                /// Get header lines if any
        const char *            GetHeadStr() const {
                                        return RtraceSimulManager::GetHeadStr();
                                }
                                /// Look for specific header keyword, return value
        const char *            GetHeadStr(const char *key, bool inOK = false) const {
                                        return RtraceSimulManager::GetHeadStr(key, inOK);
                                }
                                /// Set number of computation threads (0 => #cores)
        int                     SetThreadCount(int nt = 0) {
                                        return RtraceSimulManager::SetThreadCount(nt);
                                }
                                /// Check thread count (1 means no multi-threading)
        int                     NThreads() const {
                                        return RtraceSimulManager::NThreads();
                                }
                                /// How many threads are currently unoccupied?
        int                     ThreadsAvailable() const {
                                        return RtraceSimulManager::ThreadsAvailable();
                                }
                                /// Are we ready?
        bool                    Ready() const {
                                        return RtraceSimulManager::Ready();
                                }
                                /// Assign reference depth string (e.g., "2.5/meter")
        bool                    SetReferenceDepth(const char *dstr) {
                                        double  dref = atof(dstr);
                                        if (dref <= .0) return false;
                                        strlcpy(dunit, dstr, sizeof(dunit));
                                        pacc.refDepth = dref;
                                        return true;
                                }
        bool                    SetReferenceDepth(double dref, const char *unit=NULL) {
                                        if (dref <= .0) return false;
                                        if (unit) sprintf(dunit, "%g/%s", dref, unit);
                                        else sprintf(dunit, "%g", dref);
                                        pacc.refDepth = dref;
                                        return true;
                                }
                                /// Return reference depth
        double                  GetReferenceDepth(char *du=NULL) const {
                                        if (du) strcpy(du, dunit);
                                        return pacc.refDepth;
                                }
                                /// Set up rendering frame (call after octree loaded)
                                /// Overall dimensions may be adjusted for view,
                                /// optional pixel aspect ratio and tile grid
                                /// Increments frameNo if >0
        bool                    NewFrame(const VIEW &v, int xydim[2], double *ap=NULL,
                                                const int *tgrid=NULL);
                                /// Get current view if set
        const VIEW *            GetView() const {
                                        if (!vw.type) return NULL;
                                        return &vw;
                                }
                                /// Writeable previous view (for motion blur)
        VIEW &                  PreView() {
                                        return pvw;
                                }
                                /// Get current picture width
        int                     GetWidth() const {
                                        return hvres[0];
                                }
                                /// Get current picture height
        int                     GetHeight() const {
                                        return hvres[1];
                                }
                                /// Tile width
        int                     TWidth() const {
                                        return thvres[0];
                                }
                                /// Tile height
        int                     THeight() const {
                                        return thvres[1];
                                }
                                /// Render the specified tile in frame
                                /// Tile pixels are contiguous unless ystride != 0
                                /// Tiles numbered from lower-left at (0,0)
                                /// Pixel type influenced by this->prims assignment
        bool                    RenderTile(COLORV *rp, int ystride=0, float *zp=NULL,
                                                const int *tile=NULL);
                                /// Same but store as common-exponent COLR or SCOLR
        bool                    RenderTile(COLRV *bp, int ystride=0, float *zp=NULL,
                                                const int *tile=NULL);
                                /// Same but also use 16-bit encoded depth buffer
        bool                    RenderTile(COLRV *bp, int ystride, short *dp,
                                                const int *tile=NULL);
                                /// Back to float color with 16-bit depth
        bool                    RenderTile(COLORV *rp, int ystride, short *dp,
                                                const int *tile=NULL);
                                /// Render and write a frame to the named file
                                /// Include any header lines set prior to call
                                /// Picture file must not exist
                                /// Write pixels to stdout if !pfname
                                /// Write depth to a command if dfname[0]=='!'
        RenderDataType          RenderFrame(const char *pfname,
                                                RenderDataType dt=RDTrgbe,
                                                const char *dfname=NULL);
                                /// Resume partially finished rendering
                                /// Picture file must exist with valid header
        RenderDataType          ResumeFrame(const char *pfname,
                                                const char *dfname=NULL);
                                /// Prepare new picture (and depth) output
                                /// Called by RenderFrame() after NewFrame()
        RenderDataType          NewOutput(FILE *pdfp[2], const char *pfname,
                                                RenderDataType dt=RDTrgbe,
                                                const char *dfname=NULL);
                                /// Reopen existing picture (and depth) file
                                /// Called by ResumeFrame()
                                /// File pointers @ end of header (before res.)
        RenderDataType          ReopenOutput(FILE *pdfp[2], const char *pfname,
                                                const char *dfname=NULL);
                                /// Close octree, free data, return status
        int                     Cleanup(bool everything = false) {
                                        NewBar();
                                        tvw.type = vw.type = 0;
                                        hvres[0] = hvres[1] = 0;
                                        thvres[0] = thvres[1] = 0;
                                        prims = NULL;
                                        frameNo = 0;
                                        return RtraceSimulManager::Cleanup(everything);
                                }
};

#endif /* RpictSimulManager_h */
Revision:	2.11
Committed:	Wed Oct 23 23:40:41 2024 UTC (12 months ago) by greg
Content type:	text/plain
Branch:	MAIN
CVS Tags:	rad6R0, HEAD
Changes since 2.10:	+5 -1 lines
Log Message:	feat: Added GetHeadLen() method for efficiency
#	User	Rev	Content
1	greg	2.11	/* RCSid $Id: RpictSimulManager.h,v 2.10 2024/10/10 21:02:52 greg Exp $ */
2	greg	2.1	/*
3			* RpictSimulManager.h
4			*
5			* Rpict simulation manager class declaration
6			*
7			* Created by Greg Ward on 07/11/2024.
8			*/
9
10			#ifndef RpictSimulManager_h
11			#define RpictSimulManager_h
12
13			#include "RtraceSimulManager.h"
14			#include "view.h"
15			#include "depthcodec.h"
16
17			/// Data type flags for pixel access and output
18			enum RenderDataType {
19			RDTnone=0,
20			RDTscolor=0x1, RDTrgb=0x2, RDTxyz=0x3, RDTscolr=0x4, RDTrgbe=0x5, RDTxyze=0x6,
21			RDTcolorM=0x7,
22			RDTdfloat=0x8, RDTdshort=0x10,
23			RDTdepthM=0x18
24			};
25
26			#define RDTcolorT(f) RenderDataType((f) & RDTcolorM)
27			#define RDTdepthT(f) RenderDataType((f) & RDTdepthM)
28			#define RDTcommonE(f) (RDTcolorT(f) >= RDTscolr)
29	greg	2.2	#define RDTnewCT(f,c) RenderDataType((f) & ~RDTcolorM \| (c) & RDTcolorM)
30			#define RDTnewDT(f,d) RenderDataType((f) & ~RDTdepthM \| (d) & RDTdepthM)
31	greg	2.1
32			/// Pixel accessor (read/write to caller's buffer with possible conversion)
33			class PixelAccess {
34			union {
35			COLORV * f;
36			COLRV * b;
37			} pbase; // pixel base pointer
38			union {
39			float * f;
40			short * s;
41			} dbase; // depth base pointer
42			long rowStride; // # values to next y position
43			int dtyp; // data type flags
44			RGBPRIMP primp; // color primaries if tristimulus
45	greg	2.9	bool swap2d; // need to swap 16-bit depths?
46	greg	2.2	const COLORV * CF3(int x, int y) const {
47			return pbase.f + (rowStridey + x)3;
48			}
49	greg	2.1	COLORV * CF3(int x, int y) {
50			return pbase.f + (rowStridey + x)3;
51			}
52	greg	2.2	const COLRV * CB3(int x, int y) const {
53			return pbase.b + (rowStridey + x)4;
54			}
55			COLRV * CB3(int x, int y) {
56			return pbase.b + (rowStridey + x)4;
57			}
58			const COLORV * SCF(int x, int y) const {
59			return pbase.f + (rowStridey + x)NCSAMP;
60	greg	2.1	}
61			COLORV * SCF(int x, int y) {
62			return pbase.f + (rowStridey + x)NCSAMP;
63			}
64	greg	2.2	const COLRV * SCB(int x, int y) const {
65			return pbase.b + (rowStridey + x)(NCSAMP+1);
66	greg	2.1	}
67			COLRV * SCB(int x, int y) {
68			return pbase.b + (rowStridey + x)(NCSAMP+1);
69			}
70	greg	2.9	void EncodeDepth16(int x, int y, float z) {
71			short * sp = dbase.s + rowStride*y + x;
72			*sp = depth2code(z, refDepth);
73			if (swap2d) swap16((char *)sp, 1);
74			}
75			float DecodeDepth16(int x, int y) const {
76			short sv = dbase.s[rowStride*y + x];
77			if (swap2d) swap16((char *)&sv, 1);
78			return code2depth(sv, refDepth);
79			}
80	greg	2.1	public:
81			double refDepth; // reference depth
82			PixelAccess() {
83			refDepth = 1.;
84	greg	2.9	swap2d = !nativebigendian();
85	greg	2.1	Init();
86			}
87			PixelAccess(COLORV rp, int ystride, float zp=NULL) {
88			refDepth = 1.;
89	greg	2.9	swap2d = !nativebigendian();
90	greg	2.1	Init(rp, ystride, zp);
91			}
92			PixelAccess(COLRV bp, int ystride, float zp=NULL) {
93			refDepth = 1.;
94	greg	2.9	swap2d = !nativebigendian();
95	greg	2.1	Init(bp, ystride, zp);
96			}
97			PixelAccess(COLRV bp, int ystride, short dp) {
98			refDepth = 1.;
99	greg	2.9	swap2d = !nativebigendian();
100	greg	2.1	Init(bp, ystride, dp);
101			}
102	greg	2.4	PixelAccess(COLORV rp, int ystride, short dp) {
103			refDepth = 1.;
104	greg	2.9	swap2d = !nativebigendian();
105	greg	2.4	Init(rp, ystride, dp);
106			}
107	greg	2.1	void Init() {
108			pbase.f = NULL; dbase.f = NULL;
109			rowStride = 0;
110			primp = NULL;
111			dtyp = 0;
112			}
113			/// Initializers default to rendering color space
114			void Init(COLORV rp, int ystride, float zp=NULL) {
115			pbase.f = rp; dbase.f = zp;
116			rowStride = ystride;
117			if (NCSAMP > 3) {
118			dtyp = RDTscolor; primp = NULL;
119			} else {
120			dtyp = RDTrgb; primp = stdprims;
121			}
122			if (zp) dtyp \|= RDTdfloat;
123			}
124			void Init(COLRV bp, int ystride, float zp=NULL) {
125			pbase.b = bp; dbase.f = zp;
126			rowStride = ystride;
127			if (NCSAMP > 3) {
128			dtyp = RDTscolr; primp = NULL;
129			} else {
130			dtyp = RDTrgbe; primp = stdprims;
131			}
132			if (zp) dtyp \|= RDTdfloat;
133			}
134			void Init(COLRV bp, int ystride, short dp) {
135			pbase.b = bp; dbase.s = dp;
136			rowStride = ystride;
137			if (NCSAMP > 3) {
138			dtyp = RDTscolr; primp = NULL;
139			} else {
140			dtyp = RDTrgbe; primp = stdprims;
141			}
142			if (dp) dtyp \|= RDTdshort;
143			}
144	greg	2.4	void Init(COLORV rp, int ystride, short dp) {
145			pbase.f = rp; dbase.s = dp;
146			rowStride = ystride;
147			if (NCSAMP > 3) {
148			dtyp = RDTscolor; primp = NULL;
149			} else {
150			dtyp = RDTrgb; primp = stdprims;
151			}
152			if (dp) dtyp \|= RDTdshort;
153			}
154	greg	2.1	/// Set color space after non-empty initialization
155			bool SetColorSpace(RenderDataType cs, RGBPRIMP pr=NULL);
156			/// Get color space
157			RenderDataType ColorSpace() const {
158			return RDTcolorT(dtyp);
159			}
160			/// Get color primaries (NULL if spectral)
161			RGBPRIMP Primaries() const {
162			return primp;
163			}
164			/// Number of represented color/spectral components
165			int NC() const {
166			switch (ColorSpace()) {
167			case RDTrgb: case RDTrgbe:
168			case RDTxyz: case RDTxyze:
169			return 3;
170			case RDTscolor: case RDTscolr:
171			return NCSAMP;
172			default:;
173			}
174			return 0;
175			}
176			/// Get depth type
177			RenderDataType DepthType() const {
178			return RDTdepthT(dtyp);
179			}
180			/// Get row stride
181			long GetRowStride() const {
182			return rowStride;
183			}
184			/// Assign a pixel value (& depth) from rendered ray value
185			bool SetPixel(int x, int y, const RAY *rp);
186			/// Assign pixel color (& depth) -- may re-represent either/both
187			bool SetPixel(int x, int y, const COLORV *pv, float z=0) {
188			if (NC() == 3) {
189			if (RDTcommonE(dtyp))
190			setcolr(CB3(x,y), pv[RED], pv[GRN], pv[BLU]);
191			else
192			copycolor(CF3(x,y), pv);
193			} else if (RDTcommonE(dtyp))
194			scolor_scolr(SCB(x,y), pv);
195			else
196			copyscolor(SCF(x,y), pv);
197	greg	2.9	if (DepthType() == RDTdfloat)
198	greg	2.1	dbase.f[rowStride*y + x] = z;
199	greg	2.9	else if (DepthType() == RDTdshort)
200			EncodeDepth16(x, y, z);
201	greg	2.1	return true;
202			}
203			/// Retrieve pixel color (& depth) -- may convert either/both
204			bool GetPixel(int x, int y, COLORV pv, float zp=NULL) const {
205			if (NC() == 3) {
206			if (RDTcommonE(dtyp))
207	greg	2.2	colr_color(pv, CB3(x,y));
208	greg	2.1	else
209	greg	2.2	copycolor(pv, CF3(x,y));
210	greg	2.1	} else if (RDTcommonE(dtyp))
211	greg	2.2	scolr_scolor(pv, SCB(x,y));
212	greg	2.1	else
213	greg	2.2	copyscolor(pv, SCF(x,y));
214	greg	2.1	if (!zp) return true;
215	greg	2.9	if (DepthType() == RDTdfloat)
216	greg	2.1	zp = dbase.f[rowStridey + x];
217	greg	2.9	else if (DepthType() == RDTdshort)
218			*zp = DecodeDepth16(x, y);
219	greg	2.1	else
220			*zp = .0f;
221			return true;
222			}
223			/// Copy pixel from one location to another (no conversion)
224			bool CopyPixel(int dx, int dy, int sx, int sy) {
225			if ((dx==sx) & (dy==sy)) return true;
226			const int nc = NC();
227			if (nc == 3) {
228			if (RDTcommonE(dtyp))
229	greg	2.2	copycolr(CB3(dx,dy), CB3(sx,sy));
230	greg	2.1	else
231	greg	2.2	copycolor(CF3(dx,dy), CF3(sx,sy));
232	greg	2.1	} else if (RDTcommonE(dtyp))
233	greg	2.2	copyscolr(SCB(dx,dy), SCB(sx,sy));
234	greg	2.1	else
235	greg	2.2	copyscolor(SCF(dx,dy), SCF(sx,sy));
236	greg	2.9	switch (DepthType()) {
237	greg	2.1	case RDTdfloat:
238			dbase.f[rowStride*dy + dx] =
239			dbase.f[rowStride*sy + sx];
240			break;
241			case RDTdshort:
242			dbase.s[rowStride*dy + dx] =
243			dbase.s[rowStride*sy + sx];
244			break;
245			default:;
246			}
247			return true;
248			}
249			};
250
251			/// Call-back function for progress reporting
252			typedef void ProgReportCB(double pct);
253
254			/// rpict-like simulation manager (at most one such object)
255			class RpictSimulManager : protected RtraceSimulManager {
256			static RayReportCall RtCall; // our callback for cooked rays
257			VIEW vw; // frame view
258			VIEW pvw; // previous view
259			int hvres[2]; // overall picture dimensions
260			int tgsize[2]; // tile grid size
261			int thvres[2]; // tile dimensions
262			VIEW tvw, ptvw; // this tile's view (& previous)
263			PixelAccess pacc; // pixel accessor
264			char dunit[32]; // depth with units (if any)
265			ABitMap2 doneMap; // which tile pixels are done
266			COLORV * barPix; // current render bar pixels
267			float * barDepth; // current render bar depths
268			bool SetTile(const int ti[2]);
269	greg	2.7	bool RenderRect(const int x0 = 0, const int y0 = 0);
270	greg	2.1	bool ComputePixel(int x, int y);
271	greg	2.7	bool BelowSampThresh(const int x, const int y,
272			const int noff[4][2]) const;
273	greg	2.2	void FillSquare(const int x, const int y, const int noff[4][2]);
274	greg	2.1	void NewBar(int ht = 0);
275	greg	2.3	bool LowerBar(int v, int ytop);
276	greg	2.1	bool RenderBelow(int ytop, const int vstep, FILE *pfp,
277			const int dt, FILE *dfp=NULL);
278			public:
279			ProgReportCB * prCB; // progress report call-back
280			RGBPRIMP prims; // output primaries (NULL if spectral)
281			int frameNo; // frame number (0 if not sequence)
282			RpictSimulManager(const char *octn = NULL) :
283			RtraceSimulManager(RtCall, this, octn) {
284			tvw.type = vw.type = 0;
285			hvres[0] = hvres[1] = 0;
286			thvres[0] = thvres[1] = 0;
287			pacc.refDepth = 1.; dunit[0] = '1'; dunit[1] = '\0';
288			barPix = NULL; barDepth = NULL;
289			prCB = NULL;
290			prims = NULL;
291			frameNo = 0;
292			}
293			~RpictSimulManager() {
294	greg	2.5	delete [] barPix; delete [] barDepth;
295	greg	2.1	}
296			/// Load octree and prepare renderer
297			bool LoadOctree(const char *octn) {
298			return RtraceSimulManager::LoadOctree(octn);
299			}
300			/// Prepare header from previous input (or clear)
301			bool NewHeader(const char *inspec=NULL) {
302			return RtraceSimulManager::NewHeader(inspec);
303			}
304			/// Add a string to header (adds newline if none)
305			bool AddHeader(const char *str) {
306			return RtraceSimulManager::AddHeader(str);
307			}
308			/// Append program line to header
309			bool AddHeader(int ac, char *av[]) {
310			return RtraceSimulManager::AddHeader(ac, av);
311			}
312	greg	2.11	/// Get current header length in bytes
313			int GetHeadLen() const {
314			return RtraceSimulManager::GetHeadLen();
315			}
316	greg	2.1	/// Get header lines if any
317	greg	2.8	const char * GetHeadStr() const {
318			return RtraceSimulManager::GetHeadStr();
319			}
320			/// Look for specific header keyword, return value
321			const char * GetHeadStr(const char *key, bool inOK = false) const {
322			return RtraceSimulManager::GetHeadStr(key, inOK);
323	greg	2.1	}
324			/// Set number of computation threads (0 => #cores)
325			int SetThreadCount(int nt = 0) {
326			return RtraceSimulManager::SetThreadCount(nt);
327			}
328			/// Check thread count (1 means no multi-threading)
329			int NThreads() const {
330			return RtraceSimulManager::NThreads();
331			}
332			/// How many threads are currently unoccupied?
333			int ThreadsAvailable() const {
334			return RtraceSimulManager::ThreadsAvailable();
335			}
336			/// Are we ready?
337			bool Ready() const {
338			return RtraceSimulManager::Ready();
339			}
340			/// Assign reference depth string (e.g., "2.5/meter")
341			bool SetReferenceDepth(const char *dstr) {
342			double dref = atof(dstr);
343			if (dref <= .0) return false;
344			strlcpy(dunit, dstr, sizeof(dunit));
345			pacc.refDepth = dref;
346			return true;
347			}
348			bool SetReferenceDepth(double dref, const char *unit=NULL) {
349			if (dref <= .0) return false;
350			if (unit) sprintf(dunit, "%g/%s", dref, unit);
351			else sprintf(dunit, "%g", dref);
352			pacc.refDepth = dref;
353			return true;
354			}
355			/// Return reference depth
356			double GetReferenceDepth(char *du=NULL) const {
357			if (du) strcpy(du, dunit);
358			return pacc.refDepth;
359			}
360			/// Set up rendering frame (call after octree loaded)
361			/// Overall dimensions may be adjusted for view,
362			/// optional pixel aspect ratio and tile grid
363			/// Increments frameNo if >0
364			bool NewFrame(const VIEW &v, int xydim[2], double *ap=NULL,
365			const int *tgrid=NULL);
366	greg	2.4	/// Get current view if set
367			const VIEW * GetView() const {
368			if (!vw.type) return NULL;
369			return &vw;
370			}
371			/// Writeable previous view (for motion blur)
372			VIEW & PreView() {
373			return pvw;
374			}
375	greg	2.1	/// Get current picture width
376			int GetWidth() const {
377			return hvres[0];
378			}
379			/// Get current picture height
380			int GetHeight() const {
381			return hvres[1];
382			}
383			/// Tile width
384			int TWidth() const {
385			return thvres[0];
386			}
387			/// Tile height
388			int THeight() const {
389			return thvres[1];
390			}
391			/// Render the specified tile in frame
392			/// Tile pixels are contiguous unless ystride != 0
393			/// Tiles numbered from lower-left at (0,0)
394			/// Pixel type influenced by this->prims assignment
395			bool RenderTile(COLORV rp, int ystride=0, float zp=NULL,
396			const int *tile=NULL);
397			/// Same but store as common-exponent COLR or SCOLR
398			bool RenderTile(COLRV bp, int ystride=0, float zp=NULL,
399			const int *tile=NULL);
400			/// Same but also use 16-bit encoded depth buffer
401			bool RenderTile(COLRV bp, int ystride, short dp,
402			const int *tile=NULL);
403	greg	2.4	/// Back to float color with 16-bit depth
404			bool RenderTile(COLORV rp, int ystride, short dp,
405			const int *tile=NULL);
406	greg	2.1	/// Render and write a frame to the named file
407			/// Include any header lines set prior to call
408	greg	2.5	/// Picture file must not exist
409	greg	2.2	/// Write pixels to stdout if !pfname
410			/// Write depth to a command if dfname[0]=='!'
411	greg	2.1	RenderDataType RenderFrame(const char *pfname,
412			RenderDataType dt=RDTrgbe,
413			const char *dfname=NULL);
414			/// Resume partially finished rendering
415			/// Picture file must exist with valid header
416			RenderDataType ResumeFrame(const char *pfname,
417			const char *dfname=NULL);
418	greg	2.5	/// Prepare new picture (and depth) output
419	greg	2.9	/// Called by RenderFrame() after NewFrame()
420	greg	2.5	RenderDataType NewOutput(FILE pdfp[2], const char pfname,
421			RenderDataType dt=RDTrgbe,
422			const char *dfname=NULL);
423			/// Reopen existing picture (and depth) file
424	greg	2.6	/// Called by ResumeFrame()
425	greg	2.5	/// File pointers @ end of header (before res.)
426			RenderDataType ReopenOutput(FILE pdfp[2], const char pfname,
427			const char *dfname=NULL);
428	greg	2.1	/// Close octree, free data, return status
429			int Cleanup(bool everything = false) {
430			NewBar();
431			tvw.type = vw.type = 0;
432			hvres[0] = hvres[1] = 0;
433			thvres[0] = thvres[1] = 0;
434			prims = NULL;
435			frameNo = 0;
436			return RtraceSimulManager::Cleanup(everything);
437			}
438			};
439
440			#endif /* RpictSimulManager_h */