MultiSource/Benchmarks/nbench/nbench1.h - third_party/llvm-test-suite - Git at Google

 /*
 ** nbench1.h
 ** Header for nbench1.c
 ** BYTEmark (tm)
 ** BYTE's Native Mode Benchmarks
 ** Rick Grehan, BYTE Magazine
 **
 ** Creation:
 ** Revision: 3/95;10/95
 **
 ** DISCLAIMER
 ** The source, executable, and documentation files that comprise
 ** the BYTEmark benchmarks are made available on an "as is" basis.
 ** This means that we at BYTE Magazine have made every reasonable
 ** effort to verify that the there are no errors in the source and
 ** executable code.  We cannot, however, guarantee that the programs
 ** are error-free.  Consequently, McGraw-HIll and BYTE Magazine make
 ** no claims in regard to the fitness of the source code, executable
 ** code, and documentation of the BYTEmark.
 **  Furthermore, BYTE Magazine, McGraw-Hill, and all employees
 ** of McGraw-Hill cannot be held responsible for any damages resulting
 ** from the use of this code or the results obtained from using
 ** this code.
 */

 /*
 ** DEFINES
 */
 /* #define DEBUG */

 /*
 ** EXTERNALS
 */
 extern ulong global_min_ticks;

 extern SortStruct global_numsortstruct;
 extern SortStruct global_strsortstruct;
 extern BitOpStruct global_bitopstruct;
 extern EmFloatStruct global_emfloatstruct;
 extern FourierStruct global_fourierstruct;
 extern AssignStruct global_assignstruct;
 extern IDEAStruct global_ideastruct;
 extern HuffStruct global_huffstruct;
 extern NNetStruct global_nnetstruct;
 extern LUStruct global_lustruct;

 /* External PROTOTYPES */
 /*extern unsigned long abs_randwc(unsigned long num);*/     /* From MISC */
 /*extern long randnum(long lngval);*/
 extern int32 randwc(int32 num);
 extern u32 abs_randwc(u32 num);
 extern int32 randnum(int32 lngval);

 extern farvoid *AllocateMemory(unsigned long nbytes,    /* From SYSSPEC */
 	int *errorcode);
 extern void FreeMemory(farvoid *mempointer,
 	int *errorcode);
 extern void MoveMemory(farvoid *destination,
 		farvoid *source, unsigned long nbytes);
 extern void ReportError(char *context, int errorcode);
 extern void ErrorExit();
 extern unsigned long StartStopwatch();
 extern unsigned long StopStopwatch(unsigned long startticks);
 extern unsigned long TicksToSecs(unsigned long tickamount);
 extern double TicksToFracSecs(unsigned long tickamount);

 /*****************
 ** NUMERIC SORT **
 *****************/

 /*
 ** PROTOTYPES
 */
 void DoNumSort(void);
 static ulong DoNumSortIteration(farlong *arraybase,
 		ulong arraysize,
 		uint numarrays);
 static void LoadNumArrayWithRand(farlong *array,
 		ulong arraysize,
 		uint numarrays);
 static void NumHeapSort(farlong *array,
 		ulong bottom,
 		ulong top);
 static void NumSift(farlong *array,
 		ulong i,
 		ulong j);


 /****************
 ** STRING SORT **
 *****************
 */


 /*
 ** PROTOTYPES
 */
 void DoStringSort(void);
 static ulong DoStringSortIteration(faruchar *arraybase,
 		uint numarrays,
 		ulong arraysize);
 static farulong *LoadStringArray(faruchar *strarray,
 		uint numarrays,
 		ulong *strings,
 		ulong arraysize);
 static void stradjust(farulong *optrarray,
 		faruchar *strarray,
 		ulong nstrings,
 		ulong i,
 		uchar l);
 static void StrHeapSort(farulong *optrarray,
 		faruchar *strarray,
 		ulong numstrings,
 		ulong bottom,
 		ulong top);
 static int str_is_less(farulong *optrarray,
 		faruchar *strarray,
 		ulong numstrings,
 		ulong a,
 		ulong b);
 static void strsift(farulong *optrarray,
 		faruchar *strarray,
 		ulong numstrings,
 		ulong i,
 		ulong j);

 /************************
 ** BITFIELD OPERATIONS **
 *************************
 */

 /*
 ** PROTOTYPES
 */
 void DoBitops(void);
 static ulong DoBitfieldIteration(farulong *bitarraybase,
 		farulong *bitoparraybase,
 		long bitoparraysize,
 		ulong *nbitops);
 static void ToggleBitRun(farulong *bitmap,
 		ulong bit_addr,
 		ulong nbits,
 		uint val);
 static void FlipBitRun(farulong *bitmap,
 		ulong bit_addr,
 		ulong nbits);

 /****************************
 ** EMULATED FLOATING POINT **
 ****************************/
 typedef struct
 {
 	u8 type;        /* Indicates, NORMAL, SUBNORMAL, etc. */
 	u8 sign;        /* Mantissa sign */
 	short exp;      /* Signed exponent...no bias */
 	u16 mantissa[INTERNAL_FPF_PRECISION];
 } InternalFPF;

 /*
 ** PROTOTYPES
 */
 void DoEmFloat(void);

 /*
 ** EXTERNALS
 */
 extern void SetupCPUEmFloatArrays(InternalFPF *abase,
 	InternalFPF *bbase, InternalFPF *cbase,
 	ulong arraysize);
 extern ulong DoEmFloatIteration(InternalFPF *abase,
 	InternalFPF *bbase, InternalFPF *cbase,
 	ulong arraysize, ulong loops);

 /*************************
 ** FOURIER COEFFICIENTS **
 *************************/

 /*
 ** PROTOTYPES
 */
 void DoFourier(void);
 static ulong DoFPUTransIteration(fardouble *abase,
 		fardouble *bbase,
 		ulong arraysize);
 static double TrapezoidIntegrate(double x0,
 		double x1,
 		int nsteps,
 		double omegan,
 		int select);
 static double thefunction(double x,
 		double omegan,
 		int select);

 /*************************
 ** ASSIGNMENT ALGORITHM **
 *************************/

 /*
 ** DEFINES
 */

 #define ASSIGNROWS 101L
 #define ASSIGNCOLS 101L

 /*
 ** TYPEDEFS
 */
 typedef struct {
 	union {
 		long *p;
 		long (*ap)[ASSIGNROWS][ASSIGNCOLS];
 	} ptrs;
 } longptr;

 /*
 ** PROTOTYPES
 */
 void DoAssign(void);
 static ulong DoAssignIteration(farlong *arraybase,
 		ulong numarrays);
 static void LoadAssignArrayWithRand(farlong *arraybase,
 		ulong numarrays);
 static void LoadAssign(farlong arraybase[][ASSIGNCOLS]);
 static void CopyToAssign(farlong arrayfrom[][ASSIGNCOLS],
 		long arrayto[][ASSIGNCOLS]);
 static void Assignment(farlong arraybase[][ASSIGNCOLS]);
 static void calc_minimum_costs(long tableau[][ASSIGNCOLS]);
 static int first_assignments(long tableau[][ASSIGNCOLS],
 		short assignedtableau[][ASSIGNCOLS]);
 static void second_assignments(long tableau[][ASSIGNCOLS],
 		short assignedtableau[][ASSIGNCOLS]);

 /********************
 ** IDEA ENCRYPTION **
 ********************/

 /*
 ** DEFINES
 */
 #define IDEAKEYSIZE 16
 #define IDEABLOCKSIZE 8
 #define ROUNDS 8
 #define KEYLEN (6*ROUNDS+4)

 /*
 ** MACROS
 */
 #define low16(x) ((x) & 0x0FFFF)
 #define MUL(x,y) (x=mul(low16(x),y))


 typedef u16 IDEAkey[KEYLEN];

 /*
 ** PROTOTYPES
 */
 void DoIDEA(void);
 static ulong DoIDEAIteration(faruchar *plain1,
 	faruchar *crypt1, faruchar *plain2,
 	ulong arraysize, ulong nloops,
 	IDEAkey Z, IDEAkey DK);
 static u16 mul(register u16 a, register u16 b);
 static u16 inv(u16 x);
 static void en_key_idea(u16 userkey[8], IDEAkey Z);
 static void de_key_idea(IDEAkey Z, IDEAkey DK);
 static void cipher_idea(u16 in[4], u16 out[4], IDEAkey Z);

 /************************
 ** HUFFMAN COMPRESSION **
 ************************/

 /*
 ** DEFINES
 */
 #define EXCLUDED 32000L          /* Big positive value */

 /*
 ** TYPEDEFS
 */
 typedef struct {
 	uchar c;                /* Byte value */
 	float freq;             /* Frequency */
 	int parent;             /* Parent node */
 	int left;               /* Left pointer = 0 */
 	int right;              /* Right pointer = 1 */
 } huff_node;

 /*
 ** GLOBALS
 */
 static huff_node *hufftree;             /* The huffman tree */
 static long plaintextlen;               /* Length of plaintext */

 /*
 ** PROTOTYPES
 */
 void DoHuffman();
 static void create_text_line(farchar *dt,long nchars);
 static void create_text_block(farchar *tb, ulong tblen,
 		ushort maxlinlen);
 static ulong DoHuffIteration(farchar *plaintext,
 	farchar *comparray, farchar *decomparray,
 	ulong arraysize, ulong nloops, huff_node *hufftree);
 static void SetCompBit(u8 *comparray, u32 bitoffset, char bitchar);
 static int GetCompBit(u8 *comparray, u32 bitoffset);

 /********************************
 ** BACK PROPAGATION NEURAL NET **
 ********************************/

 /*
 ** DEFINES
 */
 #define T 1                     /* TRUE */
 #define F 0                     /* FALSE */
 #define ERR -1
 #define MAXPATS 10              /* max number of patterns in data file */
 #define IN_X_SIZE 5             /* number of neurodes/row of input layer */
 #define IN_Y_SIZE 7             /* number of neurodes/col of input layer */
 #define IN_SIZE 35              /* equals IN_X_SIZE*IN_Y_SIZE */
 #define MID_SIZE 8              /* number of neurodes in middle layer */
 #define OUT_SIZE 8              /* number of neurodes in output layer */
 #define MARGIN 0.1              /* how near to 1,0 do we have to come to stop? */
 #define BETA 0.09               /* beta learning constant */
 #define ALPHA 0.09              /* momentum term constant */
 #define STOP 0.1                /* when worst_error less than STOP, training is done */

 /*
 ** GLOBALS
 */
 double  mid_wts[MID_SIZE][IN_SIZE];     /* middle layer weights */
 double  out_wts[OUT_SIZE][MID_SIZE];    /* output layer weights */
 double  mid_out[MID_SIZE];              /* middle layer output */
 double  out_out[OUT_SIZE];              /* output layer output */
 double  mid_error[MID_SIZE];            /* middle layer errors */
 double  out_error[OUT_SIZE];            /* output layer errors */
 double  mid_wt_change[MID_SIZE][IN_SIZE]; /* storage for last wt change */
 double  out_wt_change[OUT_SIZE][MID_SIZE]; /* storage for last wt change */
 double  in_pats[MAXPATS][IN_SIZE];      /* input patterns */
 double  out_pats[MAXPATS][OUT_SIZE];    /* desired output patterns */
 double  tot_out_error[MAXPATS];         /* measure of whether net is done */
 double  out_wt_cum_change[OUT_SIZE][MID_SIZE]; /* accumulated wt changes */
 double  mid_wt_cum_change[MID_SIZE][IN_SIZE];  /* accumulated wt changes */

 double  worst_error; /* worst error each pass through the data */
 double  average_error; /* average error each pass through the data */
 double  avg_out_error[MAXPATS]; /* average error each pattern */

 int iteration_count;    /* number of passes thru network so far */
 int numpats;            /* number of patterns in data file */
 int numpasses;          /* number of training passes through data file */
 int learned;            /* flag--if TRUE, network has learned all patterns */

 /*
 ** The Neural Net test requires an input data file.
 ** The name is specified here.
 */
 char *inpath="NNET.DAT";

 /*
 ** PROTOTYPES
 */
 void DoNNET(void);
 static ulong DoNNetIteration(ulong nloops);
 static void do_mid_forward(int patt);
 static void do_out_forward();
 void display_output(int patt);
 static void do_forward_pass(int patt);
 static void do_out_error(int patt);
 static void worst_pass_error();
 static void do_mid_error();
 static void adjust_out_wts();
 static void adjust_mid_wts();
 static void do_back_pass(int patt);
 static void move_wt_changes();
 static int check_out_error();
 static void zero_changes();
 static void randomize_wts();
 static int read_data_file();
 /* static int initialize_net(); */

 /***********************
 **  LU DECOMPOSITION  **
 ** (Linear Equations) **
 ***********************/

 /*
 ** DEFINES
 */

 #define LUARRAYROWS 101L
 #define LUARRAYCOLS 101L

 /*
 ** TYPEDEFS
 */
 typedef struct
 {       union
 	{       fardouble *p;
 		fardouble (*ap)[][LUARRAYCOLS];
 	} ptrs;
 } LUdblptr;

 /*
 ** GLOBALS
 */
 fardouble *LUtempvv;

 /*
 ** PROTOTYPES
 */
 void DoLU(void);
 static void LUFreeMem(fardouble *a, fardouble *b,
 	fardouble *abase, fardouble *bbase);
 static ulong DoLUIteration(fardouble *a, fardouble *b,
 	fardouble *abase, fardouble *bbase,
 	ulong numarrays);
 static void build_problem( double a[][LUARRAYCOLS],
 	int n, double b[LUARRAYROWS]);
 static int ludcmp(double a[][LUARRAYCOLS],
 	int n, int indx[], int *d);
 static void lubksb(double a[][LUARRAYCOLS],
 	int n, int indx[LUARRAYROWS],
 	double b[LUARRAYROWS]);
 static int lusolve(double a[][LUARRAYCOLS],
 	int n, double b[LUARRAYROWS]);
	/*
	** nbench1.h
	** Header for nbench1.c
	** BYTEmark (tm)
	** BYTE's Native Mode Benchmarks
	** Rick Grehan, BYTE Magazine
	**
	** Creation:
	** Revision: 3/95;10/95
	**
	** DISCLAIMER
	** The source, executable, and documentation files that comprise
	** the BYTEmark benchmarks are made available on an "as is" basis.
	** This means that we at BYTE Magazine have made every reasonable
	** effort to verify that the there are no errors in the source and
	** executable code. We cannot, however, guarantee that the programs
	** are error-free. Consequently, McGraw-HIll and BYTE Magazine make
	** no claims in regard to the fitness of the source code, executable
	** code, and documentation of the BYTEmark.
	** Furthermore, BYTE Magazine, McGraw-Hill, and all employees
	** of McGraw-Hill cannot be held responsible for any damages resulting
	** from the use of this code or the results obtained from using
	** this code.
	*/

	/*
	** DEFINES
	*/
	/* #define DEBUG */

	/*
	** EXTERNALS
	*/
	extern ulong global_min_ticks;

	extern SortStruct global_numsortstruct;
	extern SortStruct global_strsortstruct;
	extern BitOpStruct global_bitopstruct;
	extern EmFloatStruct global_emfloatstruct;
	extern FourierStruct global_fourierstruct;
	extern AssignStruct global_assignstruct;
	extern IDEAStruct global_ideastruct;
	extern HuffStruct global_huffstruct;
	extern NNetStruct global_nnetstruct;
	extern LUStruct global_lustruct;

	/* External PROTOTYPES */
	/extern unsigned long abs_randwc(unsigned long num);/ /* From MISC */
	/extern long randnum(long lngval);/
	extern int32 randwc(int32 num);
	extern u32 abs_randwc(u32 num);
	extern int32 randnum(int32 lngval);

	extern farvoid AllocateMemory(unsigned long nbytes, / From SYSSPEC */
	int *errorcode);
	extern void FreeMemory(farvoid *mempointer,
	int *errorcode);
	extern void MoveMemory(farvoid *destination,
	farvoid *source, unsigned long nbytes);
	extern void ReportError(char *context, int errorcode);
	extern void ErrorExit();
	extern unsigned long StartStopwatch();
	extern unsigned long StopStopwatch(unsigned long startticks);
	extern unsigned long TicksToSecs(unsigned long tickamount);
	extern double TicksToFracSecs(unsigned long tickamount);

	/*****************
	NUMERIC SORT
	*****************/

	/*
	** PROTOTYPES
	*/
	void DoNumSort(void);
	static ulong DoNumSortIteration(farlong *arraybase,
	ulong arraysize,
	uint numarrays);
	static void LoadNumArrayWithRand(farlong *array,
	ulong arraysize,
	uint numarrays);
	static void NumHeapSort(farlong *array,
	ulong bottom,
	ulong top);
	static void NumSift(farlong *array,
	ulong i,
	ulong j);


	/****************
	STRING SORT
	*****************
	*/


	/*
	** PROTOTYPES
	*/
	void DoStringSort(void);
	static ulong DoStringSortIteration(faruchar *arraybase,
	uint numarrays,
	ulong arraysize);
	static farulong LoadStringArray(faruchar strarray,
	uint numarrays,
	ulong *strings,
	ulong arraysize);
	static void stradjust(farulong *optrarray,
	faruchar *strarray,
	ulong nstrings,
	ulong i,
	uchar l);
	static void StrHeapSort(farulong *optrarray,
	faruchar *strarray,
	ulong numstrings,
	ulong bottom,
	ulong top);
	static int str_is_less(farulong *optrarray,
	faruchar *strarray,
	ulong numstrings,
	ulong a,
	ulong b);
	static void strsift(farulong *optrarray,
	faruchar *strarray,
	ulong numstrings,
	ulong i,
	ulong j);

	/************************
	BITFIELD OPERATIONS
	*************************
	*/

	/*
	** PROTOTYPES
	*/
	void DoBitops(void);
	static ulong DoBitfieldIteration(farulong *bitarraybase,
	farulong *bitoparraybase,
	long bitoparraysize,
	ulong *nbitops);
	static void ToggleBitRun(farulong *bitmap,
	ulong bit_addr,
	ulong nbits,
	uint val);
	static void FlipBitRun(farulong *bitmap,
	ulong bit_addr,
	ulong nbits);

	/****************************
	EMULATED FLOATING POINT
	****************************/
	typedef struct
	{
	u8 type; /* Indicates, NORMAL, SUBNORMAL, etc. */
	u8 sign; /* Mantissa sign */
	short exp; /* Signed exponent...no bias */
	u16 mantissa[INTERNAL_FPF_PRECISION];
	} InternalFPF;

	/*
	** PROTOTYPES
	*/
	void DoEmFloat(void);

	/*
	** EXTERNALS
	*/
	extern void SetupCPUEmFloatArrays(InternalFPF *abase,
	InternalFPF bbase, InternalFPF cbase,
	ulong arraysize);
	extern ulong DoEmFloatIteration(InternalFPF *abase,
	InternalFPF bbase, InternalFPF cbase,
	ulong arraysize, ulong loops);

	/*************************
	FOURIER COEFFICIENTS
	*************************/

	/*
	** PROTOTYPES
	*/
	void DoFourier(void);
	static ulong DoFPUTransIteration(fardouble *abase,
	fardouble *bbase,
	ulong arraysize);
	static double TrapezoidIntegrate(double x0,
	double x1,
	int nsteps,
	double omegan,
	int select);
	static double thefunction(double x,
	double omegan,
	int select);

	/*************************
	ASSIGNMENT ALGORITHM
	*************************/

	/*
	** DEFINES
	*/

	#define ASSIGNROWS 101L
	#define ASSIGNCOLS 101L

	/*
	** TYPEDEFS
	*/
	typedef struct {
	union {
	long *p;
	long (*ap)[ASSIGNROWS][ASSIGNCOLS];
	} ptrs;
	} longptr;

	/*
	** PROTOTYPES
	*/
	void DoAssign(void);
	static ulong DoAssignIteration(farlong *arraybase,
	ulong numarrays);
	static void LoadAssignArrayWithRand(farlong *arraybase,
	ulong numarrays);
	static void LoadAssign(farlong arraybase[][ASSIGNCOLS]);
	static void CopyToAssign(farlong arrayfrom[][ASSIGNCOLS],
	long arrayto[][ASSIGNCOLS]);
	static void Assignment(farlong arraybase[][ASSIGNCOLS]);
	static void calc_minimum_costs(long tableau[][ASSIGNCOLS]);
	static int first_assignments(long tableau[][ASSIGNCOLS],
	short assignedtableau[][ASSIGNCOLS]);
	static void second_assignments(long tableau[][ASSIGNCOLS],
	short assignedtableau[][ASSIGNCOLS]);

	/********************
	IDEA ENCRYPTION
	********************/

	/*
	** DEFINES
	*/
	#define IDEAKEYSIZE 16
	#define IDEABLOCKSIZE 8
	#define ROUNDS 8
	#define KEYLEN (6*ROUNDS+4)

	/*
	** MACROS
	*/
	#define low16(x) ((x) & 0x0FFFF)
	#define MUL(x,y) (x=mul(low16(x),y))


	typedef u16 IDEAkey[KEYLEN];

	/*
	** PROTOTYPES
	*/
	void DoIDEA(void);
	static ulong DoIDEAIteration(faruchar *plain1,
	faruchar crypt1, faruchar plain2,
	ulong arraysize, ulong nloops,
	IDEAkey Z, IDEAkey DK);
	static u16 mul(register u16 a, register u16 b);
	static u16 inv(u16 x);
	static void en_key_idea(u16 userkey[8], IDEAkey Z);
	static void de_key_idea(IDEAkey Z, IDEAkey DK);
	static void cipher_idea(u16 in[4], u16 out[4], IDEAkey Z);

	/************************
	HUFFMAN COMPRESSION
	************************/

	/*
	** DEFINES
	*/
	#define EXCLUDED 32000L /* Big positive value */

	/*
	** TYPEDEFS
	*/
	typedef struct {
	uchar c; /* Byte value */
	float freq; /* Frequency */
	int parent; /* Parent node */
	int left; /* Left pointer = 0 */
	int right; /* Right pointer = 1 */
	} huff_node;

	/*
	** GLOBALS
	*/
	static huff_node hufftree; / The huffman tree */
	static long plaintextlen; /* Length of plaintext */

	/*
	** PROTOTYPES
	*/
	void DoHuffman();
	static void create_text_line(farchar *dt,long nchars);
	static void create_text_block(farchar *tb, ulong tblen,
	ushort maxlinlen);
	static ulong DoHuffIteration(farchar *plaintext,
	farchar comparray, farchar decomparray,
	ulong arraysize, ulong nloops, huff_node *hufftree);
	static void SetCompBit(u8 *comparray, u32 bitoffset, char bitchar);
	static int GetCompBit(u8 *comparray, u32 bitoffset);

	/********************************
	BACK PROPAGATION NEURAL NET
	********************************/

	/*
	** DEFINES
	*/
	#define T 1 /* TRUE */
	#define F 0 /* FALSE */
	#define ERR -1
	#define MAXPATS 10 /* max number of patterns in data file */
	#define IN_X_SIZE 5 /* number of neurodes/row of input layer */
	#define IN_Y_SIZE 7 /* number of neurodes/col of input layer */
	#define IN_SIZE 35 /* equals IN_X_SIZEIN_Y_SIZE /
	#define MID_SIZE 8 /* number of neurodes in middle layer */
	#define OUT_SIZE 8 /* number of neurodes in output layer */
	#define MARGIN 0.1 /* how near to 1,0 do we have to come to stop? */
	#define BETA 0.09 /* beta learning constant */
	#define ALPHA 0.09 /* momentum term constant */
	#define STOP 0.1 /* when worst_error less than STOP, training is done */

	/*
	** GLOBALS
	*/
	double mid_wts[MID_SIZE][IN_SIZE]; /* middle layer weights */
	double out_wts[OUT_SIZE][MID_SIZE]; /* output layer weights */
	double mid_out[MID_SIZE]; /* middle layer output */
	double out_out[OUT_SIZE]; /* output layer output */
	double mid_error[MID_SIZE]; /* middle layer errors */
	double out_error[OUT_SIZE]; /* output layer errors */
	double mid_wt_change[MID_SIZE][IN_SIZE]; /* storage for last wt change */
	double out_wt_change[OUT_SIZE][MID_SIZE]; /* storage for last wt change */
	double in_pats[MAXPATS][IN_SIZE]; /* input patterns */
	double out_pats[MAXPATS][OUT_SIZE]; /* desired output patterns */
	double tot_out_error[MAXPATS]; /* measure of whether net is done */
	double out_wt_cum_change[OUT_SIZE][MID_SIZE]; /* accumulated wt changes */
	double mid_wt_cum_change[MID_SIZE][IN_SIZE]; /* accumulated wt changes */

	double worst_error; /* worst error each pass through the data */
	double average_error; /* average error each pass through the data */
	double avg_out_error[MAXPATS]; /* average error each pattern */

	int iteration_count; /* number of passes thru network so far */
	int numpats; /* number of patterns in data file */
	int numpasses; /* number of training passes through data file */
	int learned; /* flag--if TRUE, network has learned all patterns */

	/*
	** The Neural Net test requires an input data file.
	** The name is specified here.
	*/
	char *inpath="NNET.DAT";

	/*
	** PROTOTYPES
	*/
	void DoNNET(void);
	static ulong DoNNetIteration(ulong nloops);
	static void do_mid_forward(int patt);
	static void do_out_forward();
	void display_output(int patt);
	static void do_forward_pass(int patt);
	static void do_out_error(int patt);
	static void worst_pass_error();
	static void do_mid_error();
	static void adjust_out_wts();
	static void adjust_mid_wts();
	static void do_back_pass(int patt);
	static void move_wt_changes();
	static int check_out_error();
	static void zero_changes();
	static void randomize_wts();
	static int read_data_file();
	/* static int initialize_net(); */

	/***********************
	LU DECOMPOSITION
	(Linear Equations)
	***********************/

	/*
	** DEFINES
	*/

	#define LUARRAYROWS 101L
	#define LUARRAYCOLS 101L

	/*
	** TYPEDEFS
	*/
	typedef struct
	{ union
	{ fardouble *p;
	fardouble (*ap)[][LUARRAYCOLS];
	} ptrs;
	} LUdblptr;

	/*
	** GLOBALS
	*/
	fardouble *LUtempvv;

	/*
	** PROTOTYPES
	*/
	void DoLU(void);
	static void LUFreeMem(fardouble a, fardouble b,
	fardouble abase, fardouble bbase);
	static ulong DoLUIteration(fardouble a, fardouble b,
	fardouble abase, fardouble bbase,
	ulong numarrays);
	static void build_problem( double a[][LUARRAYCOLS],
	int n, double b[LUARRAYROWS]);
	static int ludcmp(double a[][LUARRAYCOLS],
	int n, int indx[], int *d);
	static void lubksb(double a[][LUARRAYCOLS],
	int n, int indx[LUARRAYROWS],
	double b[LUARRAYROWS]);
	static int lusolve(double a[][LUARRAYCOLS],
	int n, double b[LUARRAYROWS]);