src/rt/RcontribSimulManager.h

/* RCSid $Id: RcontribSimulManager.h,v 2.7 2024/11/08 15:49:34 greg Exp $ */
/*
 *  RcontribSimulManager.h
 *
 *      Rcontrib simulation manager class declaration
 *
 *  Created by Greg Ward on 10/11/2024.
 */

#ifndef RcontribSimulManager_h
#define RcontribSimulManager_h

#include "RtraceSimulManager.h"
#include "RdataShare.h"
#include "lookup.h"
#include "rtprocess.h"

/*
 * As with other single-object classes, many global variable affect
 * behavior.  Besides rendering parameters, there are spectral parameters
 * and output dimensions taken from the environment.
 *
 * NOTE:  "record" and "row" are used interchangeably throughout.
 */

extern char             RCCONTEXT[];            // global rcontrib context

class RcontribSimulManager;                     // need forward decl

/// Shared data object for record output (includes header; may be write-only)
class RcontribOutput {
        RcontribOutput *        next;           // next in sorted list
        char *                  ofname;         // output file name
        uint32                  rowCountPos;    // row count position in header
        void *                  rowp;           // current row memory
        bool                    NewHeader(const RcontribSimulManager *rcp);
        int                     CheckHeader(const RcontribSimulManager *rcp);
public:
        RdataShare *            rData;          // data sharing object
        size_t                  rowBytes;       // byte count per row
        const char *            omod;           // single modifier (or NULL)
        int32                   obin;           // single output bin (or -1)
        uint32                  begData;        // start of data (type-aligned)
        int32                   curRow;         // current output row
        uint32                  nRows;          // total number of rows
                                RcontribOutput(const char *fnm = NULL) {
                                        next = NULL;
                                        omod = NULL;
                                        obin = -1;
                                        rData = NULL;
                                        ofname = savqstr(fnm);
                                        rowBytes = 0;
                                        nRows = 0;
                                        rowp = NULL; curRow = -1;
                                }
                                ~RcontribOutput() {
                                        DoneRow();
                                        delete rData;
                                        delete next;
                                        freeqstr(ofname);
                                }
                                /// Return output channel name
        const char *            GetName() const {
                                        if (rData) return rData->GetName();
                                        return ofname;
                                }
                                /// Update output row count
        bool                    SetRowsDone(int r) {
                                        if (!rData | (0 >= r) | (r > nRows)) return false;
                                        char *  rbuf = (char *)rData->GetMemory(rowCountPos, 17, 0);
                                        sprintf(rbuf, "%-16d", r);
                                        rbuf[16] = '\n';        // replaces nul byte
                                        return rData->ReleaseMemory(rbuf, RDSwrite);
                                }
                                /// Get buffer for indicated row (contents may be random)
        void *                  GetRow(int r) {
                                        if (!rData | (r < 0)) return NULL;
                                        if (r != curRow) {
                                                DoneRow();
                                                if (r < nRows)
                                                        rowp = rData->GetMemory(begData + r*rowBytes,
                                                                                 rowBytes, 0);
                                                if (rowp) curRow = r;
                                        }
                                        return rowp;
                                }
                                /// Current row with byte offset
        void *                  InsertionP(int coffset) const {
                                        if (!rowp | (coffset < 0) | (coffset >= rowBytes))
                                                return NULL;
                                        return (char *)rowp + coffset;
                                }
                                /// Release current row, writing contents
        void                    DoneRow() {
                                        if (rowp) rData->ReleaseMemory(rowp, RDSwrite);
                                        rowp = NULL; curRow = -1;
                                }
                                /// Get next in list
        const RcontribOutput *  Next() const {
                                        return next;
                                }
        RcontribOutput *        Next() {
                                        return next;
                                }
                                /// RcontribSimulManager gets full access
        friend class            RcontribSimulManager;
};

typedef double          DCOLORV;        // color accumulator type

/// Modifier channel for recording contributions (no constructor/destructor)
struct RcontribMod;

/// Allocate rcontrib accumulator
extern RcontribMod *    NewRcMod(const char *prms = NULL, const char *binexpr = NULL, int ncbins = 1);
/// Free an RcontribMod
extern lut_free_t       FreeRcMod;

/*
 * General RcontribSimulManager class operation:
 *
 *  1)  Call LoadOctree(), then alter the header as desired
 *  2)  Set number of spectral samples (NCSAMP) and call SetDataFormat()
 *  3)  Set xres and yres to desired dimensions (xres>0 for picture output)
 *  4)  Call AddModifier() and AddModFile() to indicate tracked modifiers
 *  5)  Set outOp and cdsF according to desired output/recovery
 *  6)  Set desired computation flags via SetFlag()
 *  7)  Call PrepOutput() to open output channels
 *  8)  Call SetThreadCount() to fork children if desired
 *  9)  Set accum to the number of ray samples per record
 * 10)  Call ComputeRecord() with accum ray samples
 * 11)  Continue until GetRowMax() records have been sent
 * 12)  Call Cleanup()
 *
 * The order of some of these calls may be changed.  Technically, the octree
 * may be loaded anytime before PrepOutput() is called.  Also, SetThreadCount()
 * may be called anytime *after* PrepOutput(), and may be interleaved with
 * calls to ComputeRecord().  The accum setting may be changed at any time.
 * Finally, it is possible to restart the output using ResetRow(), and
 * a zero argument will rewind to the beginning, whence all records
 * may be recalculated.  The previous output rows are not zeroed or deleted,
 * but are overwritten as the calculation proceeds from the new starting point.
 * However, the output file(s) will indicate in the NROWS= line in the header
 * that only the newly calculated rows are present.  If you wish to start over
 * with a different set of modifiers or outputs, call ClearModifiers() instead,
 * which keeps the current octree in memory.  This call also returns to single
 * process mode if any children were running.
 *
 * It is not possible to write to standard output, but the output
 * model is quite flexible thanks to the RdataShare polymorphic class.
 * The current default output class creates a shared, memory-mapped file,
 * which is the most efficient object on most systems.
 *
 * ASCII output is not supported, so full data recovery is.
 */

/// Output channel opening options: new/exclusive, overwrite if exists, or recover data
enum RCOutputOp {RCOnew=0, RCOforce, RCOrecover};

/// Converts above to RdataShare open flags (may be adjusted by calling program)
extern int      RSDOflags[];

/// Call-back function type to create named data channel (freed using "delete" operator)
typedef RdataShare *    RcreateDataShareF(const char *name, RCOutputOp op, size_t siz);

/// Our default data share function
extern RcreateDataShareF        defDataShare;

/// Modifiable ray-tracing flags for rcontrib
#define RCcontrib               (RTmask+1)      // compute contributions? (r.t. coefficients)
#define RCmask                  (RTlimDist|RTimmIrrad|RCcontrib)

/// rcontrib-like simulation manager (at most one such object)
class RcontribSimulManager : protected RtraceSimulManager {
protected:
        static RayReportCall    RctCall;        // our callback for traced rays
        ABitMap                 rowsDone;       // bit mask of completed rows
        uint32                  rInPos;         // which row (record) is next on input?
        uby8                    nChan;          // NCSAMP setting for this calculation
        char                    dtyp;           // data type ('f', 'd', or 'c')
        uint16                  dsiz;           // N-component element size in bytes
        RcontribOutput *        outList;        // ordered list of output channels
        LUTAB                   modLUT;         // modifier lookup table
        SUBPROC *               kid;            // array of child processes
        int32 *                 kidRow;         // row assigned to each child
        int                     nkids;          // child process count (-1 in child)
        bool                    UpdateRowsDone(int r);
        int                     GetChild(bool forceWait = false);
        bool                    StartKids(int n2go);
        int                     StopKids(int n2end = 0);
        void                    RunChild();
public:
        RCOutputOp              outOp;          // output operation
        RcreateDataShareF *     cdsF;           // data share creator
        int                     xres, yres;     // output (picture) size
        uint32                  accum;          // # rays to accumulate per record
                                RcontribSimulManager(const char *octn = NULL)
                                                : RtraceSimulManager(NULL, NULL, octn) {
                                        rInPos = 0;
                                        nChan = 0;
                                        dtyp = 'f';
                                        dsiz = 0;
                                        outList = NULL;
                                        memset(&modLUT, 0, sizeof(modLUT));
                                        modLUT.hashf = lu_shash;
                                        modLUT.keycmp = strcmp;
                                        modLUT.freek = efree;
                                        modLUT.freed = FreeRcMod;
                                        kid = NULL; kidRow = NULL; nkids = 0;
                                        rtFlags = RTtraceSources;
                                        SetTraceCall(&RctCall, this);
                                        outOp = RCOnew;
                                        cdsF = &defDataShare;
                                        xres = yres = 0;
                                        accum = 1;
                                }
                                ~RcontribSimulManager() {
                                        if (nkids >= 0) ClearModifiers();
                                }
                                /// Check modifiable ray-tracing computation flag(s)
        bool                    HasFlag(int fl) const {
                                        return ((rtFlags & RCmask & fl) != 0);
                                }
                                /// Set/reset modifiable ray-tracing computation flag(s)
        bool                    SetFlag(int fl, bool val = true) {
                                        if (!(fl &= RCmask)) return false;
                                        if (val) rtFlags |= fl;
                                        else rtFlags &= ~fl;
                                        return true;
                                }
                                /// 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 output format ('f', 'd', or 'c'), call before mods
        bool                    SetDataFormat(int ty);
                                /// Get current format (and element size in bytes)
        int                     GetFormat(int *siz = NULL) const {
                                        if (siz) *siz = dsiz;
                                        return dtyp;
                                }
                                /// Add a modifier and arguments, create output(s)
        bool                    AddModifier(const char *modn, const char *outspec,
                                                const char *prms = NULL,
                                                const char *binval = NULL, int bincnt = 1);
                                /// Add a file of modifiers with associated arguments
        bool                    AddModFile(const char *modfn, const char *outspec,
                                                const char *prms = NULL,
                                                const char *binval = NULL, int bincnt = 1);
                                /// Get named rcontrib output (or list)
        const RcontribOutput *  GetOutput(const char *nm = NULL) const {
                                        if (!nm) return outList;
                                        const RcontribOutput *  op = outList;
                                        while (op && strcmp(op->GetName(), nm))
                                                op = op->next;
                                        return op;
                                }
                                /// Open output channels and return # completed rows
        int                     PrepOutput();
                                /// Are we ready to compute some records?
        bool                    Ready() const {
                                        return (rowsDone.Length() > 0) & (accum > 0);
                                }
                                /// Set number of computation threads (0 => #cores)
        int                     SetThreadCount(int nt = 0);
                                /// Check thread count (1 means no multi-processing)
        int                     NThreads() const {
                                        return nkids + !nkids;
                                }
                                /// What is maximum row?
        int                     GetRowMax() const {
                                        if (!outList) return yres * (xres + !xres);
                                        return outList->nRows;
                                }
                                /// Get current row count (# rows sent for computation)
        int                     GetRowCount() const {
                                        return rInPos;
                                }
                                /// Get # rows completed
        int                     GetRowFinished() const {
                                        if (!nkids) return rInPos;
                                        uint32  nDone = rowsDone.Find(0, false);
                                        if (nDone == ABMend)
                                                return rowsDone.Length();
                                        return nDone;
                                }
                                /// Add a ray/bundle to compute next record (n=accum)
        int                     ComputeRecord(const FVECT orig_direc[]);
                                /// Finish pending rays if multi-processing
        bool                    FlushQueue() {
                                        if (nkids <= 0) return true;
                                        while (GetChild(true) >= 0)
                                                ;
                                        return true;
                                }
                                /// Rewind calculation (previous results unchanged)
        bool                    ResetRow(int r);
                                /// Clear the modifiers and close all outputs
        void                    ClearModifiers() {
                                        if (rowsDone.Length()) {
                                                SetThreadCount(1);
                                                cow_doneshare();
                                                rowsDone.NewBitMap(0);
                                        }
                                        lu_done(&modLUT);
                                        delete outList; outList = NULL;
                                        nChan = 0;
                                }
                                /// Close octree, free data, return status
        int                     Cleanup(bool everything = false) {
                                        ClearModifiers();
                                        return RtraceSimulManager::Cleanup(everything);
                                }
};

extern const char *     formstr(int f);         // string from format

#endif /* RcontribSimulManager_h */
Revision:	2.8
Committed:	Tue Dec 3 17:39:42 2024 UTC (4 months, 4 weeks ago) by greg
Content type:	text/plain
Branch:	MAIN
Changes since 2.7:	+3 -1 lines
Log Message:	refactor(rxcontrib): Moved definition of formstr() to make it more accessible
#	Content
1	/* RCSid $Id: RcontribSimulManager.h,v 2.7 2024/11/08 15:49:34 greg Exp $ */
2	/*
3	* RcontribSimulManager.h
4	*
5	* Rcontrib simulation manager class declaration
6	*
7	* Created by Greg Ward on 10/11/2024.
8	*/
9
10	#ifndef RcontribSimulManager_h
11	#define RcontribSimulManager_h
12
13	#include "RtraceSimulManager.h"
14	#include "RdataShare.h"
15	#include "lookup.h"
16	#include "rtprocess.h"
17
18	/*
19	* As with other single-object classes, many global variable affect
20	* behavior. Besides rendering parameters, there are spectral parameters
21	* and output dimensions taken from the environment.
22	*
23	* NOTE: "record" and "row" are used interchangeably throughout.
24	*/
25
26	extern char RCCONTEXT[]; // global rcontrib context
27
28	class RcontribSimulManager; // need forward decl
29
30	/// Shared data object for record output (includes header; may be write-only)
31	class RcontribOutput {
32	RcontribOutput * next; // next in sorted list
33	char * ofname; // output file name
34	uint32 rowCountPos; // row count position in header
35	void * rowp; // current row memory
36	bool NewHeader(const RcontribSimulManager *rcp);
37	int CheckHeader(const RcontribSimulManager *rcp);
38	public:
39	RdataShare * rData; // data sharing object
40	size_t rowBytes; // byte count per row
41	const char * omod; // single modifier (or NULL)
42	int32 obin; // single output bin (or -1)
43	uint32 begData; // start of data (type-aligned)
44	int32 curRow; // current output row
45	uint32 nRows; // total number of rows
46	RcontribOutput(const char *fnm = NULL) {
47	next = NULL;
48	omod = NULL;
49	obin = -1;
50	rData = NULL;
51	ofname = savqstr(fnm);
52	rowBytes = 0;
53	nRows = 0;
54	rowp = NULL; curRow = -1;
55	}
56	~RcontribOutput() {
57	DoneRow();
58	delete rData;
59	delete next;
60	freeqstr(ofname);
61	}
62	/// Return output channel name
63	const char * GetName() const {
64	if (rData) return rData->GetName();
65	return ofname;
66	}
67	/// Update output row count
68	bool SetRowsDone(int r) {
69	if (!rData \| (0 >= r) \| (r > nRows)) return false;
70	char * rbuf = (char *)rData->GetMemory(rowCountPos, 17, 0);
71	sprintf(rbuf, "%-16d", r);
72	rbuf[16] = '\n'; // replaces nul byte
73	return rData->ReleaseMemory(rbuf, RDSwrite);
74	}
75	/// Get buffer for indicated row (contents may be random)
76	void * GetRow(int r) {
77	if (!rData \| (r < 0)) return NULL;
78	if (r != curRow) {
79	DoneRow();
80	if (r < nRows)
81	rowp = rData->GetMemory(begData + r*rowBytes,
82	rowBytes, 0);
83	if (rowp) curRow = r;
84	}
85	return rowp;
86	}
87	/// Current row with byte offset
88	void * InsertionP(int coffset) const {
89	if (!rowp \| (coffset < 0) \| (coffset >= rowBytes))
90	return NULL;
91	return (char *)rowp + coffset;
92	}
93	/// Release current row, writing contents
94	void DoneRow() {
95	if (rowp) rData->ReleaseMemory(rowp, RDSwrite);
96	rowp = NULL; curRow = -1;
97	}
98	/// Get next in list
99	const RcontribOutput * Next() const {
100	return next;
101	}
102	RcontribOutput * Next() {
103	return next;
104	}
105	/// RcontribSimulManager gets full access
106	friend class RcontribSimulManager;
107	};
108
109	typedef double DCOLORV; // color accumulator type
110
111	/// Modifier channel for recording contributions (no constructor/destructor)
112	struct RcontribMod;
113
114	/// Allocate rcontrib accumulator
115	extern RcontribMod * NewRcMod(const char prms = NULL, const char binexpr = NULL, int ncbins = 1);
116	/// Free an RcontribMod
117	extern lut_free_t FreeRcMod;
118
119	/*
120	* General RcontribSimulManager class operation:
121	*
122	* 1) Call LoadOctree(), then alter the header as desired
123	* 2) Set number of spectral samples (NCSAMP) and call SetDataFormat()
124	* 3) Set xres and yres to desired dimensions (xres>0 for picture output)
125	* 4) Call AddModifier() and AddModFile() to indicate tracked modifiers
126	* 5) Set outOp and cdsF according to desired output/recovery
127	* 6) Set desired computation flags via SetFlag()
128	* 7) Call PrepOutput() to open output channels
129	* 8) Call SetThreadCount() to fork children if desired
130	* 9) Set accum to the number of ray samples per record
131	* 10) Call ComputeRecord() with accum ray samples
132	* 11) Continue until GetRowMax() records have been sent
133	* 12) Call Cleanup()
134	*
135	* The order of some of these calls may be changed. Technically, the octree
136	* may be loaded anytime before PrepOutput() is called. Also, SetThreadCount()
137	* may be called anytime after PrepOutput(), and may be interleaved with
138	* calls to ComputeRecord(). The accum setting may be changed at any time.
139	* Finally, it is possible to restart the output using ResetRow(), and
140	* a zero argument will rewind to the beginning, whence all records
141	* may be recalculated. The previous output rows are not zeroed or deleted,
142	* but are overwritten as the calculation proceeds from the new starting point.
143	* However, the output file(s) will indicate in the NROWS= line in the header
144	* that only the newly calculated rows are present. If you wish to start over
145	* with a different set of modifiers or outputs, call ClearModifiers() instead,
146	* which keeps the current octree in memory. This call also returns to single
147	* process mode if any children were running.
148	*
149	* It is not possible to write to standard output, but the output
150	* model is quite flexible thanks to the RdataShare polymorphic class.
151	* The current default output class creates a shared, memory-mapped file,
152	* which is the most efficient object on most systems.
153	*
154	* ASCII output is not supported, so full data recovery is.
155	*/
156
157	/// Output channel opening options: new/exclusive, overwrite if exists, or recover data
158	enum RCOutputOp {RCOnew=0, RCOforce, RCOrecover};
159
160	/// Converts above to RdataShare open flags (may be adjusted by calling program)
161	extern int RSDOflags[];
162
163	/// Call-back function type to create named data channel (freed using "delete" operator)
164	typedef RdataShare * RcreateDataShareF(const char *name, RCOutputOp op, size_t siz);
165
166	/// Our default data share function
167	extern RcreateDataShareF defDataShare;
168
169	/// Modifiable ray-tracing flags for rcontrib
170	#define RCcontrib (RTmask+1) // compute contributions? (r.t. coefficients)
171	#define RCmask (RTlimDist\|RTimmIrrad\|RCcontrib)
172
173	/// rcontrib-like simulation manager (at most one such object)
174	class RcontribSimulManager : protected RtraceSimulManager {
175	protected:
176	static RayReportCall RctCall; // our callback for traced rays
177	ABitMap rowsDone; // bit mask of completed rows
178	uint32 rInPos; // which row (record) is next on input?
179	uby8 nChan; // NCSAMP setting for this calculation
180	char dtyp; // data type ('f', 'd', or 'c')
181	uint16 dsiz; // N-component element size in bytes
182	RcontribOutput * outList; // ordered list of output channels
183	LUTAB modLUT; // modifier lookup table
184	SUBPROC * kid; // array of child processes
185	int32 * kidRow; // row assigned to each child
186	int nkids; // child process count (-1 in child)
187	bool UpdateRowsDone(int r);
188	int GetChild(bool forceWait = false);
189	bool StartKids(int n2go);
190	int StopKids(int n2end = 0);
191	void RunChild();
192	public:
193	RCOutputOp outOp; // output operation
194	RcreateDataShareF * cdsF; // data share creator
195	int xres, yres; // output (picture) size
196	uint32 accum; // # rays to accumulate per record
197	RcontribSimulManager(const char *octn = NULL)
198	: RtraceSimulManager(NULL, NULL, octn) {
199	rInPos = 0;
200	nChan = 0;
201	dtyp = 'f';
202	dsiz = 0;
203	outList = NULL;
204	memset(&modLUT, 0, sizeof(modLUT));
205	modLUT.hashf = lu_shash;
206	modLUT.keycmp = strcmp;
207	modLUT.freek = efree;
208	modLUT.freed = FreeRcMod;
209	kid = NULL; kidRow = NULL; nkids = 0;
210	rtFlags = RTtraceSources;
211	SetTraceCall(&RctCall, this);
212	outOp = RCOnew;
213	cdsF = &defDataShare;
214	xres = yres = 0;
215	accum = 1;
216	}
217	~RcontribSimulManager() {
218	if (nkids >= 0) ClearModifiers();
219	}
220	/// Check modifiable ray-tracing computation flag(s)
221	bool HasFlag(int fl) const {
222	return ((rtFlags & RCmask & fl) != 0);
223	}
224	/// Set/reset modifiable ray-tracing computation flag(s)
225	bool SetFlag(int fl, bool val = true) {
226	if (!(fl &= RCmask)) return false;
227	if (val) rtFlags \|= fl;
228	else rtFlags &= ~fl;
229	return true;
230	}
231	/// Load octree and prepare renderer
232	bool LoadOctree(const char *octn) {
233	return RtraceSimulManager::LoadOctree(octn);
234	}
235	/// Prepare header from previous input (or clear)
236	bool NewHeader(const char *inspec=NULL) {
237	return RtraceSimulManager::NewHeader(inspec);
238	}
239	/// Add a string to header (adds newline if none)
240	bool AddHeader(const char *str) {
241	return RtraceSimulManager::AddHeader(str);
242	}
243	/// Append program line to header
244	bool AddHeader(int ac, char *av[]) {
245	return RtraceSimulManager::AddHeader(ac, av);
246	}
247	/// Get current header length in bytes
248	int GetHeadLen() const {
249	return RtraceSimulManager::GetHeadLen();
250	}
251	/// Get header lines if any
252	const char * GetHeadStr() const {
253	return RtraceSimulManager::GetHeadStr();
254	}
255	/// Look for specific header keyword, return value
256	const char * GetHeadStr(const char *key, bool inOK = false) const {
257	return RtraceSimulManager::GetHeadStr(key, inOK);
258	}
259	/// Set output format ('f', 'd', or 'c'), call before mods
260	bool SetDataFormat(int ty);
261	/// Get current format (and element size in bytes)
262	int GetFormat(int *siz = NULL) const {
263	if (siz) *siz = dsiz;
264	return dtyp;
265	}
266	/// Add a modifier and arguments, create output(s)
267	bool AddModifier(const char modn, const char outspec,
268	const char *prms = NULL,
269	const char *binval = NULL, int bincnt = 1);
270	/// Add a file of modifiers with associated arguments
271	bool AddModFile(const char modfn, const char outspec,
272	const char *prms = NULL,
273	const char *binval = NULL, int bincnt = 1);
274	/// Get named rcontrib output (or list)
275	const RcontribOutput * GetOutput(const char *nm = NULL) const {
276	if (!nm) return outList;
277	const RcontribOutput * op = outList;
278	while (op && strcmp(op->GetName(), nm))
279	op = op->next;
280	return op;
281	}
282	/// Open output channels and return # completed rows
283	int PrepOutput();
284	/// Are we ready to compute some records?
285	bool Ready() const {
286	return (rowsDone.Length() > 0) & (accum > 0);
287	}
288	/// Set number of computation threads (0 => #cores)
289	int SetThreadCount(int nt = 0);
290	/// Check thread count (1 means no multi-processing)
291	int NThreads() const {
292	return nkids + !nkids;
293	}
294	/// What is maximum row?
295	int GetRowMax() const {
296	if (!outList) return yres * (xres + !xres);
297	return outList->nRows;
298	}
299	/// Get current row count (# rows sent for computation)
300	int GetRowCount() const {
301	return rInPos;
302	}
303	/// Get # rows completed
304	int GetRowFinished() const {
305	if (!nkids) return rInPos;
306	uint32 nDone = rowsDone.Find(0, false);
307	if (nDone == ABMend)
308	return rowsDone.Length();
309	return nDone;
310	}
311	/// Add a ray/bundle to compute next record (n=accum)
312	int ComputeRecord(const FVECT orig_direc[]);
313	/// Finish pending rays if multi-processing
314	bool FlushQueue() {
315	if (nkids <= 0) return true;
316	while (GetChild(true) >= 0)
317	;
318	return true;
319	}
320	/// Rewind calculation (previous results unchanged)
321	bool ResetRow(int r);
322	/// Clear the modifiers and close all outputs
323	void ClearModifiers() {
324	if (rowsDone.Length()) {
325	SetThreadCount(1);
326	cow_doneshare();
327	rowsDone.NewBitMap(0);
328	}
329	lu_done(&modLUT);
330	delete outList; outList = NULL;
331	nChan = 0;
332	}
333	/// Close octree, free data, return status
334	int Cleanup(bool everything = false) {
335	ClearModifiers();
336	return RtraceSimulManager::Cleanup(everything);
337	}
338	};
339
340	extern const char * formstr(int f); // string from format
341
342	#endif /* RcontribSimulManager_h */