WebSVN – MLAB – Rev 2988 – /Modules/Sensors/MAG01A/SW/PIC16F887/main.lst

CCS PCM C Compiler, Version 4.106, 47914               15-V-13 20:34

               Filename: Z:\home\kaklik\svnMLAB\Modules\Sensors\MAG01A\SW\PIC16F887\main.lst

               ROM used: 775 words (9%)
                         Largest free fragment is 2048
               RAM used: 28 (8%) at main() level
                         38 (10%) worst case
               Stack:    2 locations

*
0000:  MOVLW  02
0001:  MOVWF  0A
0002:  GOTO   24F
0003:  NOP
.................... #include "main.h" 
.................... #include <16F887.h> 
.................... //////// Standard Header file for the PIC16F887 device //////////////// 
.................... #device PIC16F887 
.................... #list 
....................  
.................... #device adc=8 
....................  
.................... #FUSES NOWDT                    //No Watch Dog Timer 
.................... #FUSES INTRC                    //Internal RC Osc 
.................... #FUSES NOPUT                    //No Power Up Timer 
.................... #FUSES MCLR                     //Master Clear pin enabled 
.................... #FUSES NOPROTECT                //Code not protected from reading 
.................... #FUSES NOCPD                    //No EE protection 
.................... #FUSES NOBROWNOUT               //No brownout reset 
.................... #FUSES IESO                     //Internal External Switch Over mode enabled 
.................... #FUSES FCMEN                    //Fail-safe clock monitor enabled 
.................... #FUSES NOLVP                    //No low voltage prgming, B3(PIC16) or B5(PIC18) used for I/O 
.................... #FUSES NODEBUG                  //No Debug mode for ICD 
.................... #FUSES NOWRT                    //Program memory not write protected 
.................... #FUSES BORV40                   //Brownout reset at 4.0V 
....................  
.................... #use delay(clock=8000000) 
.................... #use i2c(master, sda=PIN_C4, scl=PIN_C3) 
*
001F:  MOVLW  08
0020:  MOVWF  78
0021:  NOP
0022:  BCF    07.3
0023:  BCF    20.3
0024:  MOVF   20,W
0025:  BSF    03.5
0026:  MOVWF  07
0027:  NOP
0028:  BCF    03.5
0029:  RLF    3D,F
002A:  BCF    07.4
002B:  BTFSS  03.0
002C:  GOTO   033
002D:  BSF    20.4
002E:  MOVF   20,W
002F:  BSF    03.5
0030:  MOVWF  07
0031:  GOTO   037
0032:  BCF    03.5
0033:  BCF    20.4
0034:  MOVF   20,W
0035:  BSF    03.5
0036:  MOVWF  07
0037:  NOP
0038:  BCF    03.5
0039:  BSF    20.3
003A:  MOVF   20,W
003B:  BSF    03.5
003C:  MOVWF  07
003D:  BCF    03.5
003E:  BTFSS  07.3
003F:  GOTO   03E
0040:  DECFSZ 78,F
0041:  GOTO   021
0042:  NOP
0043:  BCF    07.3
0044:  BCF    20.3
0045:  MOVF   20,W
0046:  BSF    03.5
0047:  MOVWF  07
0048:  NOP
0049:  BCF    03.5
004A:  BSF    20.4
004B:  MOVF   20,W
004C:  BSF    03.5
004D:  MOVWF  07
004E:  NOP
004F:  NOP
0050:  BCF    03.5
0051:  BSF    20.3
0052:  MOVF   20,W
0053:  BSF    03.5
0054:  MOVWF  07
0055:  BCF    03.5
0056:  BTFSS  07.3
0057:  GOTO   056
0058:  CLRF   78
0059:  NOP
005A:  BTFSC  07.4
005B:  BSF    78.0
005C:  BCF    07.3
005D:  BCF    20.3
005E:  MOVF   20,W
005F:  BSF    03.5
0060:  MOVWF  07
0061:  BCF    03.5
0062:  BCF    07.4
0063:  BCF    20.4
0064:  MOVF   20,W
0065:  BSF    03.5
0066:  MOVWF  07
0067:  BCF    03.5
0068:  RETURN
*
010B:  MOVLW  08
010C:  MOVWF  3E
010D:  MOVF   77,W
010E:  MOVWF  3F
010F:  BSF    20.4
0110:  MOVF   20,W
0111:  BSF    03.5
0112:  MOVWF  07
0113:  NOP
0114:  BCF    03.5
0115:  BSF    20.3
0116:  MOVF   20,W
0117:  BSF    03.5
0118:  MOVWF  07
0119:  BCF    03.5
011A:  BTFSS  07.3
011B:  GOTO   11A
011C:  BTFSC  07.4
011D:  BSF    03.0
011E:  BTFSS  07.4
011F:  BCF    03.0
0120:  RLF    78,F
0121:  NOP
0122:  BCF    20.3
0123:  MOVF   20,W
0124:  BSF    03.5
0125:  MOVWF  07
0126:  BCF    03.5
0127:  BCF    07.3
0128:  DECFSZ 3E,F
0129:  GOTO   10F
012A:  BSF    20.4
012B:  MOVF   20,W
012C:  BSF    03.5
012D:  MOVWF  07
012E:  NOP
012F:  BCF    03.5
0130:  BCF    07.4
0131:  MOVF   3F,W
0132:  BTFSC  03.2
0133:  GOTO   139
0134:  BCF    20.4
0135:  MOVF   20,W
0136:  BSF    03.5
0137:  MOVWF  07
0138:  BCF    03.5
0139:  NOP
013A:  BSF    20.3
013B:  MOVF   20,W
013C:  BSF    03.5
013D:  MOVWF  07
013E:  BCF    03.5
013F:  BTFSS  07.3
0140:  GOTO   13F
0141:  NOP
0142:  BCF    07.3
0143:  BCF    20.3
0144:  MOVF   20,W
0145:  BSF    03.5
0146:  MOVWF  07
0147:  NOP
0148:  BCF    03.5
0149:  BCF    07.4
014A:  BCF    20.4
014B:  MOVF   20,W
014C:  BSF    03.5
014D:  MOVWF  07
014E:  BCF    03.5
014F:  RETURN
.................... #use rs232(baud=115200,parity=N,xmit=PIN_C7,rcv=PIN_C6,bits=8) //rcv TXD xmit RXD 
*
00A2:  BCF    20.7
00A3:  MOVF   20,W
00A4:  BSF    03.5
00A5:  MOVWF  07
00A6:  BCF    03.5
00A7:  BCF    07.7
00A8:  MOVLW  08
00A9:  MOVWF  78
00AA:  GOTO   0AB
00AB:  NOP
00AC:  BSF    78.7
00AD:  GOTO   0C0
00AE:  BCF    78.7
00AF:  MOVF   40,W
00B0:  MOVWF  79
00B1:  RRF    79,F
00B2:  BTFSC  03.0
00B3:  BSF    07.7
00B4:  BTFSS  03.0
00B5:  BCF    07.7
00B6:  BSF    78.6
00B7:  GOTO   0C0
00B8:  BCF    78.6
00B9:  DECFSZ 78,F
00BA:  GOTO   0B1
00BB:  MOVF   79,W
00BC:  MOVWF  40
00BD:  GOTO   0BE
00BE:  NOP
00BF:  BSF    07.7
00C0:  BTFSC  78.7
00C1:  GOTO   0AE
00C2:  BTFSC  78.6
00C3:  GOTO   0B8
00C4:  RETURN
....................  
....................  
.................... #include "HMC5883L.h" 
.................... #define MAG_ADDR_R  0x3D //addresa pro cteni 
.................... #define MAG_ADDR_W  0x3C 
....................  
....................  
.................... //Konstanty nastavujici rozsah 
.................... //pro void set_mag_roz (unsigned int8 h) 
.................... #define MAG_ROZ088  0x00 
.................... #define MAG_ROZ130  0x20 
.................... #define MAG_ROZ190  0x40 
.................... #define MAG_ROZ250  0x60 
.................... #define MAG_ROZ400  0x80 
.................... #define MAG_ROZ470  0xA0 
.................... #define MAG_ROZ560  0xC0 
.................... #define MAG_ROZ810  0xE0 
....................  
....................  
.................... #include "HMC5883L.c" 
.................... // i2c slave addresses 
.................... #define HMC5883L_WRT_ADDR  0x3C 
.................... #define HMC5883L_READ_ADDR 0x3D 
....................  
.................... // Register addresses 
.................... #define HMC5883L_CFG_A_REG 0x00 
.................... #define HMC5883L_CFG_B_REG 0x01 
.................... #define HMC5883L_MODE_REG  0x02 
.................... #define HMC5883L_X_MSB_REG 0x03 
....................  
.................... //------------------------------ 
.................... // Low level routines 
.................... //------------------------------ 
.................... void hmc5883l_write_reg(int8 reg, int8 data) 
.................... { 
.................... i2c_start(); 
*
0069:  BSF    20.4
006A:  MOVF   20,W
006B:  BSF    03.5
006C:  MOVWF  07
006D:  NOP
006E:  BCF    03.5
006F:  BSF    20.3
0070:  MOVF   20,W
0071:  BSF    03.5
0072:  MOVWF  07
0073:  NOP
0074:  BCF    03.5
0075:  BCF    07.4
0076:  BCF    20.4
0077:  MOVF   20,W
0078:  BSF    03.5
0079:  MOVWF  07
007A:  NOP
007B:  BCF    03.5
007C:  BCF    07.3
007D:  BCF    20.3
007E:  MOVF   20,W
007F:  BSF    03.5
0080:  MOVWF  07
.................... i2c_write(HMC5883L_WRT_ADDR); 
0081:  MOVLW  3C
0082:  BCF    03.5
0083:  MOVWF  3D
0084:  CALL   01F
.................... i2c_write(reg); 
0085:  MOVF   37,W
0086:  MOVWF  3D
0087:  CALL   01F
.................... i2c_write(data); 
0088:  MOVF   38,W
0089:  MOVWF  3D
008A:  CALL   01F
.................... i2c_stop(); 
008B:  BCF    20.4
008C:  MOVF   20,W
008D:  BSF    03.5
008E:  MOVWF  07
008F:  NOP
0090:  BCF    03.5
0091:  BSF    20.3
0092:  MOVF   20,W
0093:  BSF    03.5
0094:  MOVWF  07
0095:  BCF    03.5
0096:  BTFSS  07.3
0097:  GOTO   096
0098:  NOP
0099:  GOTO   09A
009A:  NOP
009B:  BSF    20.4
009C:  MOVF   20,W
009D:  BSF    03.5
009E:  MOVWF  07
009F:  NOP
.................... } 
00A0:  BCF    03.5
00A1:  RETURN
....................  
.................... //------------------------------ 
.................... int8 hmc5883l_read_reg(int8 reg) 
.................... { 
.................... int8 retval; 
....................  
.................... i2c_start(); 
.................... i2c_write(HMC5883L_WRT_ADDR); 
.................... i2c_write(reg); 
.................... i2c_start(); 
.................... i2c_write(HMC5883L_READ_ADDR); 
.................... retval = i2c_read(0); 
.................... i2c_stop(); 
....................  
.................... return(retval); 
.................... } 
....................  
.................... //------------------------------ 
.................... typedef struct 
.................... { 
.................... signed int16 x; 
.................... signed int16 y; 
.................... signed int16 z; 
.................... }hmc5883l_result; 
....................  
.................... // This global structure holds the values read 
.................... // from the HMC5883L x,y,z registers. 
.................... hmc5883l_result compass = {0,0,0}; 
*
0270:  CLRF   21
0271:  CLRF   22
0272:  CLRF   23
0273:  CLRF   24
0274:  CLRF   25
0275:  CLRF   26
....................  
.................... //------------------------------ 
.................... void hmc5883l_read_data(void) 
.................... { 
.................... unsigned int8 x_lsb; 
.................... unsigned int8 x_msb; 
....................  
.................... unsigned int8 y_lsb; 
.................... unsigned int8 y_msb; 
....................  
.................... unsigned int8 z_lsb; 
.................... unsigned int8 z_msb; 
....................  
.................... i2c_start(); 
*
0150:  BSF    20.4
0151:  MOVF   20,W
0152:  BSF    03.5
0153:  MOVWF  07
0154:  NOP
0155:  BCF    03.5
0156:  BSF    20.3
0157:  MOVF   20,W
0158:  BSF    03.5
0159:  MOVWF  07
015A:  NOP
015B:  BCF    03.5
015C:  BCF    07.4
015D:  BCF    20.4
015E:  MOVF   20,W
015F:  BSF    03.5
0160:  MOVWF  07
0161:  NOP
0162:  BCF    03.5
0163:  BCF    07.3
0164:  BCF    20.3
0165:  MOVF   20,W
0166:  BSF    03.5
0167:  MOVWF  07
.................... i2c_write(HMC5883L_WRT_ADDR); 
0168:  MOVLW  3C
0169:  BCF    03.5
016A:  MOVWF  3D
016B:  CALL   01F
.................... i2c_write(HMC5883L_X_MSB_REG);  // Point to X-msb register 
016C:  MOVLW  03
016D:  MOVWF  3D
016E:  CALL   01F
.................... i2c_start(); 
016F:  BSF    20.4
0170:  MOVF   20,W
0171:  BSF    03.5
0172:  MOVWF  07
0173:  NOP
0174:  BCF    03.5
0175:  BSF    20.3
0176:  MOVF   20,W
0177:  BSF    03.5
0178:  MOVWF  07
0179:  NOP
017A:  BCF    03.5
017B:  BTFSS  07.3
017C:  GOTO   17B
017D:  BCF    07.4
017E:  BCF    20.4
017F:  MOVF   20,W
0180:  BSF    03.5
0181:  MOVWF  07
0182:  NOP
0183:  BCF    03.5
0184:  BCF    07.3
0185:  BCF    20.3
0186:  MOVF   20,W
0187:  BSF    03.5
0188:  MOVWF  07
.................... i2c_write(HMC5883L_READ_ADDR); 
0189:  MOVLW  3D
018A:  BCF    03.5
018B:  MOVWF  3D
018C:  CALL   01F
....................  
.................... x_msb = i2c_read(); 
018D:  MOVLW  01
018E:  MOVWF  77
018F:  CALL   10B
0190:  MOVF   78,W
0191:  MOVWF  38
.................... x_lsb = i2c_read(); 
0192:  MOVLW  01
0193:  MOVWF  77
0194:  CALL   10B
0195:  MOVF   78,W
0196:  MOVWF  37
....................  
.................... z_msb = i2c_read(); 
0197:  MOVLW  01
0198:  MOVWF  77
0199:  CALL   10B
019A:  MOVF   78,W
019B:  MOVWF  3C
.................... z_lsb = i2c_read();    
019C:  MOVLW  01
019D:  MOVWF  77
019E:  CALL   10B
019F:  MOVF   78,W
01A0:  MOVWF  3B
....................  
.................... y_msb = i2c_read(); 
01A1:  MOVLW  01
01A2:  MOVWF  77
01A3:  CALL   10B
01A4:  MOVF   78,W
01A5:  MOVWF  3A
.................... y_lsb = i2c_read(0); // do a NACK on last read 
01A6:  CLRF   77
01A7:  CALL   10B
01A8:  MOVF   78,W
01A9:  MOVWF  39
....................  
.................... i2c_stop(); 
01AA:  BCF    20.4
01AB:  MOVF   20,W
01AC:  BSF    03.5
01AD:  MOVWF  07
01AE:  NOP
01AF:  BCF    03.5
01B0:  BSF    20.3
01B1:  MOVF   20,W
01B2:  BSF    03.5
01B3:  MOVWF  07
01B4:  BCF    03.5
01B5:  BTFSS  07.3
01B6:  GOTO   1B5
01B7:  NOP
01B8:  GOTO   1B9
01B9:  NOP
01BA:  BSF    20.4
01BB:  MOVF   20,W
01BC:  BSF    03.5
01BD:  MOVWF  07
01BE:  NOP
....................   
.................... // Combine high and low bytes into 16-bit values. 
.................... compass.x = make16(x_msb, x_lsb); 
01BF:  BCF    03.5
01C0:  MOVF   38,W
01C1:  MOVWF  22
01C2:  MOVF   37,W
01C3:  MOVWF  21
.................... compass.y = make16(y_msb, y_lsb); 
01C4:  MOVF   3A,W
01C5:  MOVWF  24
01C6:  MOVF   39,W
01C7:  MOVWF  23
.................... compass.z = make16(z_msb, z_lsb); 
01C8:  MOVF   3C,W
01C9:  MOVWF  26
01CA:  MOVF   3B,W
01CB:  MOVWF  25
.................... } 
01CC:  BCF    0A.3
01CD:  BCF    0A.4
01CE:  GOTO   2E1 (RETURN)
....................  
....................  
....................  
....................  
.................... #include <math.h> 
.................... //////////////////////////////////////////////////////////////////////////// 
.................... ////        (C) Copyright 1996,2008 Custom Computer Services            //// 
.................... //// This source code may only be used by licensed users of the CCS C   //// 
.................... //// compiler.  This source code may only be distributed to other       //// 
.................... //// licensed users of the CCS C compiler.  No other use, reproduction  //// 
.................... //// or distribution is permitted without written permission.           //// 
.................... //// Derivative programs created using this software in object code     //// 
.................... //// form are not restricted in any way.                                //// 
.................... //////////////////////////////////////////////////////////////////////////// 
.................... ////                                                                    //// 
.................... //// History:                                                           //// 
.................... ////  * 9/20/2001 :  Improvments are made to sin/cos code.              //// 
.................... ////                 The code now is small, much faster,                //// 
.................... ////                 and more accurate.                                 //// 
.................... ////  * 2/21/2007 :  Compiler handles & operator differently and does 
.................... ////                 not return generic (int8 *) so type cast is done   //// 
.................... ////                                                                    //// 
.................... //////////////////////////////////////////////////////////////////////////// 
....................  
.................... #ifndef MATH_H 
.................... #define MATH_H 
....................  
.................... #ifdef PI 
.................... #undef  PI 
.................... #endif 
.................... #define PI     3.1415926535897932 
....................  
....................  
.................... #define SQRT2  1.4142135623730950 
....................  
.................... //float const ps[4] = {5.9304945, 21.125224, 8.9403076, 0.29730279}; 
.................... //float const qs[4] = {1.0000000, 15.035723, 17.764134, 2.4934718}; 
....................  
.................... ///////////////////////////// Round Functions ////////////////////////////// 
....................  
.................... float32 CEIL_FLOOR(float32 x, unsigned int8 n) 
.................... { 
....................    float32 y, res; 
....................    unsigned int16 l; 
....................    int1 s; 
....................  
....................    s = 0; 
....................    y = x; 
....................  
....................    if (x < 0) 
....................    { 
....................       s = 1; 
....................       y = -y; 
....................    } 
....................  
....................    if (y <= 32768.0) 
....................   res = (float32)(unsigned int16)y; 
....................  
....................  else if (y < 10000000.0) 
....................    { 
....................   l = (unsigned int16)(y/32768.0); 
....................       y = 32768.0*(y/32768.0 - (float32)l); 
....................   res = 32768.0*(float32)l; 
....................   res += (float32)(unsigned int16)y; 
....................  } 
....................  
....................  else 
....................   res = y; 
....................  
....................  y = y - (float32)(unsigned int16)y; 
....................  
....................  if (s) 
....................   res = -res; 
....................  
....................  if (y != 0) 
....................  { 
....................   if (s == 1 && n == 0) 
....................    res -= 1.0; 
....................  
....................   if (s == 0 && n == 1) 
....................    res += 1.0; 
....................  } 
....................  if (x == 0) 
....................     res = 0; 
....................  
....................  return (res); 
.................... } 
....................  
.................... // Overloaded Functions to take care for new Data types in PCD 
.................... // Overloaded function CEIL_FLOOR() for data type - Float48 
.................... #if defined(__PCD__) 
.................... float48 CEIL_FLOOR(float48 x, unsigned int8 n) 
.................... { 
....................    float48 y, res; 
....................    unsigned int16 l; 
....................    int1 s; 
....................  
....................    s = 0; 
....................    y = x; 
....................  
....................    if (x < 0) 
....................    { 
....................       s = 1; 
....................       y = -y; 
....................    } 
....................  
....................    if (y <= 32768.0) 
....................   res = (float48)(unsigned int16)y; 
....................  
....................  else if (y < 10000000.0) 
....................    { 
....................   l = (unsigned int16)(y/32768.0); 
....................       y = 32768.0*(y/32768.0 - (float48)l); 
....................   res = 32768.0*(float32)l; 
....................   res += (float48)(unsigned int16)y; 
....................  } 
....................  
....................  else 
....................   res = y; 
....................  
....................  y = y - (float48)(unsigned int16)y; 
....................  
....................  if (s) 
....................   res = -res; 
....................  
....................  if (y != 0) 
....................  { 
....................   if (s == 1 && n == 0) 
....................    res -= 1.0; 
....................  
....................   if (s == 0 && n == 1) 
....................    res += 1.0; 
....................  } 
....................  if (x == 0) 
....................     res = 0; 
....................  
....................  return (res); 
.................... } 
....................  
....................  
.................... // Overloaded function CEIL_FLOOR() for data type - Float64 
.................... float64 CEIL_FLOOR(float64 x, unsigned int8 n) 
.................... { 
....................    float64 y, res; 
....................    unsigned int16 l; 
....................    int1 s; 
....................  
....................    s = 0; 
....................    y = x; 
....................  
....................    if (x < 0) 
....................    { 
....................       s = 1; 
....................       y = -y; 
....................    } 
....................  
....................    if (y <= 32768.0) 
....................   res = (float64)(unsigned int16)y; 
....................  
....................  else if (y < 10000000.0) 
....................    { 
....................   l = (unsigned int16)(y/32768.0); 
....................       y = 32768.0*(y/32768.0 - (float64)l); 
....................   res = 32768.0*(float64)l; 
....................   res += (float64)(unsigned int16)y; 
....................  } 
....................  
....................  else 
....................   res = y; 
....................  
....................  y = y - (float64)(unsigned int16)y; 
....................  
....................  if (s) 
....................   res = -res; 
....................  
....................  if (y != 0) 
....................  { 
....................   if (s == 1 && n == 0) 
....................    res -= 1.0; 
....................  
....................   if (s == 0 && n == 1) 
....................    res += 1.0; 
....................  } 
....................  if (x == 0) 
....................     res = 0; 
....................  
....................  return (res); 
.................... } 
.................... #endif 
....................  
.................... //////////////////////////////////////////////////////////////////////////// 
.................... //   float floor(float x) 
.................... //////////////////////////////////////////////////////////////////////////// 
.................... // Description : rounds down the number x. 
.................... // Date : N/A 
.................... // 
.................... float32 floor(float32 x) 
.................... { 
....................    return CEIL_FLOOR(x, 0); 
.................... } 
.................... // Following 2 functions are overloaded functions of floor() for PCD 
.................... // Overloaded function floor() for data type - Float48 
.................... #if defined(__PCD__) 
.................... float48 floor(float48 x) 
.................... { 
....................    return CEIL_FLOOR(x, 0); 
.................... } 
....................  
.................... // Overloaded function floor() for data type - Float64 
.................... float64 floor(float64 x) 
.................... { 
....................    return CEIL_FLOOR(x, 0); 
.................... } 
.................... #endif 
....................  
....................  
.................... //////////////////////////////////////////////////////////////////////////// 
.................... //   float ceil(float x) 
.................... //////////////////////////////////////////////////////////////////////////// 
.................... // Description : rounds up the number x. 
.................... // Date : N/A 
.................... // 
.................... float32 ceil(float32 x) 
.................... { 
....................    return CEIL_FLOOR(x, 1); 
.................... } 
.................... // Following 2 functions are overloaded functions of ceil() for PCD 
.................... // Overloaded function ceil() for data type - Float48 
.................... #if defined(__PCD__) 
.................... float48 ceil(float48 x) 
.................... { 
....................    return CEIL_FLOOR(x, 1); 
.................... } 
....................  
.................... // Overloaded function ceil() for data type - Float64 
.................... float64 ceil(float64 x) 
.................... { 
....................    return CEIL_FLOOR(x, 1); 
.................... } 
.................... #endif 
....................  
....................  //////////////////////////////////////////////////////////////////////////// 
.................... //   float fabs(float x) 
.................... //////////////////////////////////////////////////////////////////////////// 
.................... // Description : Computes the absolute value of floating point number x 
.................... // Returns : returns the absolute value of x 
.................... // Date : N/A 
.................... // 
.................... #define fabs abs 
....................  
.................... //////////////////////////////////////////////////////////////////////////// 
.................... //   float fmod(float x) 
.................... //////////////////////////////////////////////////////////////////////////// 
.................... // Description : Computes the floating point remainder of x/y 
.................... // Returns : returns the value of x= i*y, for some integer i such that, if y 
.................... // is non zero, the result has the same isgn of x na dmagnitude less than the 
.................... // magnitude of y. If y is zero then a domain error occurs. 
.................... // Date : N/A 
.................... // 
....................  
.................... float fmod(float32 x,float32 y) 
.................... { 
....................    float32 i; 
....................    if (y!=0.0) 
....................    { 
....................       i=(x/y < 0.0)? ceil(x/y): floor(x/y); 
....................       return(x-(i*y)); 
....................    } 
....................    else 
....................    { 
....................    #ifdef _ERRNO 
....................    { 
....................       errno=EDOM; 
....................    } 
....................    #endif 
....................    } 
.................... } 
.................... //Overloaded function for fmod() for PCD 
.................... // Overloaded function fmod() for data type - Float48 
.................... #if defined(__PCD__) 
.................... float48 fmod(float48 x,float48 y) 
.................... { 
....................    float48 i; 
....................    if (y!=0.0) 
....................    { 
....................       i=(x/y < 0.0)? ceil(x/y): floor(x/y); 
....................       return(x-(i*y)); 
....................    } 
....................    else 
....................    { 
....................    #ifdef _ERRNO 
....................    { 
....................       errno=EDOM; 
....................    } 
....................    #endif 
....................    } 
.................... } 
.................... // Overloaded function fmod() for data type - Float64 
.................... float64 fmod(float64 x,float64 y) 
.................... { 
....................    float64 i; 
....................    if (y!=0.0) 
....................    { 
....................       i=(x/y < 0.0)? ceil(x/y): floor(x/y); 
....................       return(x-(i*y)); 
....................    } 
....................    else 
....................    { 
....................    #ifdef _ERRNO 
....................    { 
....................       errno=EDOM; 
....................    } 
....................    #endif 
....................    } 
.................... } 
.................... #endif 
.................... //////////////////// Exponential and logarithmic functions //////////////////// 
.................... //////////////////////////////////////////////////////////////////////////// 
.................... //   float exp(float x) 
.................... //////////////////////////////////////////////////////////////////////////// 
.................... // Description : returns the value (e^x) 
.................... // Date : N/A 
.................... // 
.................... #define LN2 0.6931471805599453 
....................  
.................... float const pe[6] = {0.000207455774, 0.00127100575, 0.00965065093, 
....................                      0.0554965651,  0.240227138,  0.693147172}; 
....................  
....................  
.................... float32 exp(float32 x) 
.................... { 
....................    float32 y, res, r; 
....................    #if defined(__PCD__) 
....................    int8 data1; 
....................    #endif 
....................    signed int8 n; 
....................    int1 s; 
....................    #ifdef _ERRNO 
....................    if(x > 88.722838) 
....................    { 
....................       errno=ERANGE; 
....................       return(0); 
....................    } 
....................    #endif 
....................    n = (signed int16)(x/LN2); 
....................    s = 0; 
....................    y = x; 
....................  
....................    if (x < 0) 
....................    { 
....................       s = 1; 
....................       n = -n; 
....................       y = -y; 
....................    } 
....................  
....................    res = 0.0; 
.................... #if !defined(__PCD__) 
....................    *((unsigned int8 *)(&res)) = n + 0x7F; 
.................... #endif 
....................  
.................... #if defined(__PCD__)  // Takes care of IEEE format for PCD 
....................    data1 = n+0x7F; 
....................    if(bit_test(data1,0)) 
....................    bit_set(*(((unsigned int8 *)(&res)+2)),7); 
....................    rotate_right(&data1,1); 
....................    bit_clear(data1,7); 
....................    *(((unsigned int8 *)(&res)+3)) = data1; 
.................... #endif 
....................  
....................    y = y/LN2 - (float32)n; 
....................  
....................    r = pe[0]*y + pe[1]; 
....................    r = r*y + pe[2]; 
....................    r = r*y + pe[3]; 
....................    r = r*y + pe[4]; 
....................    r = r*y + pe[5]; 
....................  
....................    res = res*(1.0 + y*r); 
....................  
....................    if (s) 
....................       res = 1.0/res; 
....................    return(res); 
.................... } 
....................  
....................  
.................... //Overloaded function for exp() for PCD 
.................... // Overloaded function exp() for data type - Float48 
.................... #if defined(__PCD__) 
.................... float48 exp(float48 x) 
.................... { 
....................    float48 y, res, r; 
....................    int8 data1; 
....................    signed int8 n; 
....................    int1 s; 
....................    #ifdef _ERRNO 
....................    if(x > 88.722838) 
....................    { 
....................       errno=ERANGE; 
....................       return(0); 
....................    } 
....................    #endif 
....................    n = (signed int16)(x/LN2); 
....................    s = 0; 
....................    y = x; 
....................  
....................    if (x < 0) 
....................    { 
....................       s = 1; 
....................       n = -n; 
....................       y = -y; 
....................    } 
....................  
....................    res = 0.0; 
....................  
....................    data1 = n+0x7F; 
....................    if(bit_test(data1,0)) 
....................    bit_set(*(((unsigned int8 *)(&res)+4)),7); 
....................    rotate_right(&data1,1); 
....................    bit_clear(data1,7); 
....................    *(((unsigned int8 *)(&res)+5)) = data1; 
....................  
....................    y = y/LN2 - (float48)n; 
....................  
....................    r = pe[0]*y + pe[1]; 
....................    r = r*y + pe[2]; 
....................    r = r*y + pe[3]; 
....................    r = r*y + pe[4]; 
....................    r = r*y + pe[5]; 
....................  
....................    res = res*(1.0 + y*r); 
....................  
....................    if (s) 
....................       res = 1.0/res; 
....................    return(res); 
.................... } 
....................  
.................... // Overloaded function exp() for data type - Float64 
.................... float64 exp(float64 x) 
.................... { 
....................    float64 y, res, r; 
....................    unsigned int16 data1, data2; 
....................    unsigned int16 *p; 
....................    signed int16 n; 
....................    int1 s; 
....................    #ifdef _ERRNO 
....................    if(x > 709.7827128) 
....................    { 
....................       errno=ERANGE; 
....................       return(0); 
....................    } 
....................    #endif 
....................    n = (signed int16)(x/LN2); 
....................    s = 0; 
....................    y = x; 
....................  
....................    if (x < 0) 
....................    { 
....................       s = 1; 
....................       n = -n; 
....................       y = -y; 
....................    } 
....................  
....................    res = 0.0; 
....................  
.................... #if !defined(__PCD__) 
....................    *((unsigned int16 *)(&res)) = n + 0x7F; 
.................... #endif 
....................    p= (((unsigned int16 *)(&res))+3); 
....................    data1 = *p; 
....................    data2 = *p;    
....................    data1 = n + 0x3FF; 
....................    data1 = data1 <<4; 
....................    if(bit_test(data2,15)) 
....................    bit_set(data1,15); 
....................    data2 = data2 & 0x000F; 
....................    data1 ^= data2; 
....................  
....................    *(((unsigned int16 *)(&res)+3)) = data1; 
....................  
....................  
....................    y = y/LN2 - (float64)n; 
....................  
....................    r = pe[0]*y + pe[1]; 
....................    r = r*y + pe[2]; 
....................    r = r*y + pe[3]; 
....................    r = r*y + pe[4]; 
....................    r = r*y + pe[5]; 
....................  
....................    res = res*(1.0 + y*r); 
....................  
....................    if (s) 
....................       res = 1.0/res; 
....................    return(res); 
.................... } 
....................  
.................... #ENDIF 
....................  
....................  
.................... /************************************************************/ 
....................  
.................... float32 const pl[4] = {0.45145214, -9.0558803, 26.940971, -19.860189}; 
.................... float32 const ql[4] = {1.0000000,  -8.1354259, 16.780517, -9.9300943}; 
....................  
.................... //////////////////////////////////////////////////////////////////////////// 
.................... //   float log(float x) 
.................... //////////////////////////////////////////////////////////////////////////// 
.................... // Description : returns the the natural log of x 
.................... // Date : N/A 
.................... // 
.................... float32 log(float32 x) 
.................... { 
....................    float32 y, res, r, y2; 
....................    #if defined(__PCD__) 
....................    unsigned int8  data1,data2; 
....................    #endif 
....................    signed int8 n; 
....................    #ifdef _ERRNO 
....................    if(x <0) 
....................    { 
....................       errno=EDOM; 
....................    } 
....................    if(x ==0) 
....................    { 
....................       errno=ERANGE; 
....................       return(0); 
....................    } 
....................    #endif 
....................    y = x; 
....................  
....................    if (y != 1.0) 
....................    { 
.................... #if !defined(__PCD__) 
....................     *((unsigned int8 *)(&y)) = 0x7E;  
.................... #endif 
....................  
.................... #if defined(__PCD__) // Takes care of IEEE format 
....................    data2 = *(((unsigned int8 *)(&y))+3); 
....................    *(((unsigned int8 *)(&y))+3) = 0x3F; 
....................    data1 = *(((unsigned int8 *)(&y))+2); 
....................    bit_clear(data1,7); 
....................    *(((unsigned int8 *)(&y))+2) = data1; 
....................    if(bit_test(data2,7)) 
....................    bit_set(*(((unsigned int8 *)(&y))+3),7); 
.................... #endif 
....................  
....................       y = (y - 1.0)/(y + 1.0); 
....................  
....................       y2=y*y; 
....................  
....................       res = pl[0]*y2 + pl[1]; 
....................       res = res*y2 + pl[2]; 
....................       res = res*y2 + pl[3]; 
....................  
....................       r = ql[0]*y2 + ql[1]; 
....................       r = r*y2 + ql[2]; 
....................       r = r*y2 + ql[3]; 
....................  
....................       res = y*res/r; 
.................... #if !defined(__PCD__) 
....................       n = *((unsigned int8 *)(&x)) - 0x7E; 
.................... #endif 
.................... #if defined(__PCD__)  
....................     data1 = *(((unsigned int8 *)(&x)+3)); 
....................     rotate_left(&data1,1); 
....................     data2 = *(((unsigned int8 *)(&x)+2)); 
....................     if(bit_test (data2,7)) 
....................       bit_set(data1,0); 
....................     n = data1 - 0x7E; 
.................... #endif 
....................  
....................       if (n<0)  
....................          r = -(float32)-n; 
....................       else 
....................          r = (float32)n; 
....................  
....................       res += r*LN2; 
....................    } 
....................  
....................    else 
....................       res = 0.0; 
....................  
....................    return(res); 
.................... } 
....................  
.................... //Overloaded function for log() for PCD 
.................... // Overloaded function log() for data type - Float48 
.................... #if defined(__PCD__) 
.................... float48 log(float48 x) 
.................... { 
....................    float48 y, res, r, y2; 
....................    unsigned int8  data1,data2; 
....................    signed int8 n; 
....................    #ifdef _ERRNO 
....................    if(x <0) 
....................    { 
....................       errno=EDOM; 
....................    } 
....................    if(x ==0) 
....................    { 
....................       errno=ERANGE; 
....................       return(0); 
....................    } 
....................    #endif 
....................    y = x; 
....................  
....................    if (y != 1.0) 
....................    { 
....................     
....................    #if !defined(__PCD__) 
....................        *((unsigned int8 *)(&y)) = 0x7E;  
....................    #endif 
....................       data2 = *(((unsigned int8 *)(&y))+5); 
....................       *(((unsigned int8 *)(&y))+5) = 0x3F; 
....................       data1 = *(((unsigned int8 *)(&y))+4); 
....................       bit_clear(data1,7); 
....................       *(((unsigned int8 *)(&y))+4) = data1; 
....................    
....................       if(bit_test(data2,7)) 
....................          bit_set(*(((unsigned int8 *)(&y))+4),7); 
....................       y = (y - 1.0)/(y + 1.0); 
....................  
....................       y2=y*y; 
....................  
....................       res = pl[0]*y2 + pl[1]; 
....................       res = res*y2 + pl[2]; 
....................       res = res*y2 + pl[3]; 
....................  
....................       r = ql[0]*y2 + ql[1]; 
....................       r = r*y2 + ql[2]; 
....................       r = r*y2 + ql[3]; 
....................  
....................       res = y*res/r; 
....................  
....................     data1 = *(((unsigned int8 *)(&x)+5)); 
....................     rotate_left(&data1,1); 
....................     data2 = *(((unsigned int8 *)(&x)+4)); 
....................     if(bit_test (data2,7)) 
....................        bit_set(data1,0); 
....................       
....................     n = data1 - 0x7E; 
....................  
....................       if (n<0) 
....................          r = -(float48)-n; 
....................       else 
....................          r = (float48)n; 
....................  
....................       res += r*LN2; 
....................    } 
....................  
....................    else 
....................       res = 0.0; 
....................  
....................    return(res); 
.................... } 
....................  
.................... // Overloaded function log() for data type - Float48 
.................... #if defined(__PCD__) 
.................... float32 const pl_64[4] = {0.45145214, -9.0558803, 26.940971, -19.860189}; 
.................... float32 const ql_64[4] = {1.0000000,  -8.1354259, 16.780517, -9.9300943}; 
.................... #endif 
.................... float64 log(float64 x) 
.................... { 
....................    float64 y, res, r, y2; 
....................    unsigned int16  data1,data2; 
....................    unsigned int16 *p; 
....................    signed int16 n; 
....................    #ifdef _ERRNO 
....................    if(x <0) 
....................    { 
....................       errno=EDOM; 
....................    } 
....................    if(x ==0) 
....................    { 
....................       errno=ERANGE; 
....................       return(0); 
....................    } 
....................    #endif 
....................    y = x; 
....................  
....................    if (y != 1.0) 
....................    { 
....................    #if !defined(__PCD__) 
....................        *((unsigned int8 *)(&y)) = 0x7E;  
....................    #endif 
....................       p= (((unsigned int16 *)(&y))+3); 
....................       data1 = *p; 
....................       data2 = *p; 
....................       data1 = 0x3FE; 
....................       data1 = data1 <<4; 
....................       if(bit_test (data2,15)) 
....................       bit_set(data1,15); 
....................       data2 = data2 & 0x000F; 
....................       data1 ^=data2; 
....................  
....................       *p = data1; 
....................  
....................       y = (y - 1.0)/(y + 1.0); 
....................  
....................       y2=y*y; 
....................  
....................       res = pl_64[0]*y2 + pl_64[1]; 
....................       res = res*y2 + pl_64[2]; 
....................       res = res*y2 + pl_64[3]; 
....................  
....................       r = ql_64[0]*y2 + ql_64[1]; 
....................       r = r*y2 + ql_64[2]; 
....................       r = r*y2 + ql_64[3]; 
....................  
....................       res = y*res/r; 
....................   
....................       p= (((unsigned int16 *)(&x))+3); 
....................       data1 = *p; 
....................       bit_clear(data1,15); 
....................       data1 = data1 >>4;     
....................       n = data1 - 0x3FE; 
....................  
....................  
....................       if (n<0) 
....................          r = -(float64)-n; 
....................       else 
....................          r = (float64)n; 
....................  
....................       res += r*LN2; 
....................    } 
....................  
....................    else 
....................       res = 0.0; 
....................  
....................    return(res); 
.................... } 
.................... #endif 
....................  
....................  
.................... #define LN10 2.3025850929940456 
....................  
.................... //////////////////////////////////////////////////////////////////////////// 
.................... //   float log10(float x) 
.................... //////////////////////////////////////////////////////////////////////////// 
.................... // Description : returns the the log base 10 of x 
.................... // Date : N/A 
.................... // 
.................... float32 log10(float32 x) 
.................... { 
....................    float32 r; 
....................  
....................    r = log(x); 
....................    r = r/LN10; 
....................    return(r); 
.................... } 
....................  
.................... //Overloaded functions for log10() for PCD 
.................... // Overloaded function log10() for data type - Float48 
.................... #if defined(__PCD__) 
.................... float48 log10(float48 x) 
.................... { 
....................    float48 r; 
....................  
....................    r = log(x); 
....................    r = r/LN10; 
....................    return(r); 
.................... } 
....................  
.................... // Overloaded function log10() for data type - Float64 
.................... float64 log10(float64 x) 
.................... { 
....................    float64 r; 
....................  
....................    r = log(x); 
....................    r = r/LN10; 
....................    return(r); 
.................... } 
.................... #endif 
.................... //////////////////////////////////////////////////////////////////////////// 
.................... //   float modf(float x) 
.................... //////////////////////////////////////////////////////////////////////////// 
.................... // Description :breaks the argument value int integral and fractional parts, 
.................... // ach of which have the same sign as the argument.  It stores the integral part 
.................... // as a float in the object pointed to by the iptr 
.................... // Returns : returns the signed fractional part of value. 
.................... // Date : N/A 
.................... // 
....................  
.................... float32 modf(float32 value,float32 *iptr) 
.................... { 
....................    *iptr=(value < 0.0)? ceil(value): floor(value); 
....................    return(value - *iptr); 
.................... } 
.................... //Overloaded functions for modf() for PCD 
.................... // Overloaded function modf() for data type - Float48 
.................... #if defined(__PCD__) 
.................... float48 modf(float48 value,float48 *iptr) 
.................... { 
....................    *iptr=(value < 0.0)? ceil(value): floor(value); 
....................    return(value - *iptr); 
.................... } 
.................... // Overloaded function modf() for data type - Float64 
.................... float64 modf(float64 value,float64 *iptr) 
.................... { 
....................    *iptr=(value < 0.0)? ceil(value): floor(value); 
....................    return(value - *iptr); 
.................... } 
.................... #endif 
....................  
.................... //////////////////////////////////////////////////////////////////////////// 
.................... //   float pwr(float x,float y) 
.................... //////////////////////////////////////////////////////////////////////////// 
.................... // Description : returns the value (x^y) 
.................... // Date : N/A 
.................... // Note : 0 is returned when the function will generate an imaginary number 
.................... // 
.................... float32 pwr(float32 x,float32 y) 
.................... { 
....................    if(0 > x && fmod(y, 1) == 0) { 
....................       if(fmod(y, 2) == 0) { 
....................          return (exp(log(-x) * y)); 
....................       } else { 
....................          return (-exp(log(-x) * y)); 
....................       } 
....................    } else if(0 > x && fmod(y, 1) != 0) { 
....................       return 0; 
....................    } else { 
....................       if(x != 0 || 0 >= y) { 
....................          return (exp(log(x) * y)); 
....................       } 
....................    } 
.................... } 
.................... //Overloaded functions for pwr() for PCD 
.................... // Overloaded function pwr() for data type - Float48 
.................... #if defined(__PCD__) 
.................... float48 pwr(float48 x,float48 y) 
.................... { 
....................    if(0 > x && fmod(y, 1) == 0) { 
....................       if(fmod(y, 2) == 0) { 
....................          return (exp(log(-x) * y)); 
....................       } else { 
....................          return (-exp(log(-x) * y)); 
....................       } 
....................    } else if(0 > x && fmod(y, 1) != 0) { 
....................       return 0; 
....................    } else { 
....................       if(x != 0 || 0 >= y) { 
....................          return (exp(log(x) * y)); 
....................       } 
....................    } 
.................... } 
.................... // Overloaded function pwr() for data type - Float64 
.................... float64 pwr(float64 x,float64 y) 
.................... { 
....................    if(0 > x && fmod(y, 1) == 0) { 
....................       if(fmod(y, 2) == 0) { 
....................          return (exp(log(-x) * y)); 
....................       } else { 
....................          return (-exp(log(-x) * y)); 
....................       } 
....................    } else if(0 > x && fmod(y, 1) != 0) { 
....................       return 0; 
....................    } else { 
....................       if(x != 0 || 0 >= y) { 
....................          return (exp(log(x) * y)); 
....................       } 
....................    } 
.................... } 
.................... #endif 
....................  
.................... //////////////////// Power functions //////////////////// 
....................  
.................... //////////////////////////////////////////////////////////////////////////// 
.................... //   float pow(float x,float y) 
.................... //////////////////////////////////////////////////////////////////////////// 
.................... // Description : returns the value (x^y) 
.................... // Date : N/A 
.................... // Note : 0 is returned when the function will generate an imaginary number 
.................... // 
.................... float32 pow(float32 x,float32 y) 
.................... { 
....................    if(0 > x && fmod(y, 1) == 0) { 
....................       if(fmod(y, 2) == 0) { 
....................          return (exp(log(-x) * y)); 
....................       } else { 
....................          return (-exp(log(-x) * y)); 
....................       } 
....................    } else if(0 > x && fmod(y, 1) != 0) { 
....................       return 0; 
....................    } else { 
....................       if(x != 0 || 0 >= y) { 
....................          return (exp(log(x) * y)); 
....................       } 
....................    } 
.................... } 
.................... //Overloaded functions for pow() for PCD 
.................... // Overloaded function for pow() data type - Float48 
.................... #if defined(__PCD__) 
.................... float48 pow(float48 x,float48 y) 
.................... { 
....................    if(0 > x && fmod(y, 1) == 0) { 
....................       if(fmod(y, 2) == 0) { 
....................          return (exp(log(-x) * y)); 
....................       } else { 
....................          return (-exp(log(-x) * y)); 
....................       } 
....................    } else if(0 > x && fmod(y, 1) != 0) { 
....................       return 0; 
....................    } else { 
....................       if(x != 0 || 0 >= y) { 
....................          return (exp(log(x) * y)); 
....................       } 
....................    } 
.................... } 
....................  
.................... // Overloaded function pow() for data type - Float64 
.................... float64 pow(float64 x,float64 y) 
.................... { 
....................    if(0 > x && fmod(y, 1) == 0) { 
....................       if(fmod(y, 2) == 0) { 
....................          return (exp(log(-x) * y)); 
....................       } else { 
....................          return (-exp(log(-x) * y)); 
....................       } 
....................    } else if(0 > x && fmod(y, 1) != 0) { 
....................       return 0; 
....................    } else { 
....................       if(x != 0 || 0 >= y) { 
....................          return (exp(log(x) * y)); 
....................       } 
....................    } 
.................... } 
.................... #endif 
....................  
.................... //////////////////////////////////////////////////////////////////////////// 
.................... //   float sqrt(float x) 
.................... //////////////////////////////////////////////////////////////////////////// 
.................... // Description : returns the square root of x 
.................... // Date : N/A 
.................... // 
.................... float32 sqrt(float32 x) 
.................... { 
....................    float32 y, res; 
....................    #if defined(__PCD__) 
....................    unsigned int16 data1,data2; 
....................    #endif 
....................    BYTE *p; 
....................  
....................    #ifdef _ERRNO 
....................    if(x < 0) 
....................    { 
....................       errno=EDOM; 
....................    } 
....................    #endif 
....................  
....................    if( x<=0.0) 
....................       return(0.0); 
....................  
....................    y=x; 
....................     
....................    #if !defined(__PCD__) 
....................     p=&y; 
....................    (*p)=(BYTE)((((unsigned int16)(*p)) + 127) >> 1); 
....................    #endif 
....................     
....................    #if defined(__PCD__) 
....................     p = (((unsigned int8 *)(&y))+3); 
....................     data1 = *(((unsigned int8 *)(&y))+3); 
....................     data2 = *(((unsigned int8 *)(&y))+2); 
....................     rotate_left(&data1,1);     
....................     if(bit_test(data2,7))     
....................     bit_set(data1,0);     
....................     data1 = ((data1+127) >>1); 
....................     bit_clear(data2,7); 
....................     if(bit_test(data1,0)) 
....................     bit_set(data2,7); 
....................     data1 = data1 >>1; 
....................     *(((unsigned int8 *)(&y))+3) = data1; 
....................     *(((unsigned int8 *)(&y))+2) = data2; 
....................      
....................   #endif 
....................  
....................    do { 
....................       res=y; 
....................       y+=(x/y); 
....................  
....................       #if !defined(__PCD__) 
....................      (*p)--; 
....................    #endif 
....................     
....................    #if defined(__PCD__) 
....................     data1 = *(((unsigned int8 *)(&y))+3); 
....................     data2 = *(((unsigned int8 *)(&y))+2); 
....................     rotate_left(&data1,1); 
....................     if(bit_test(data2,7)) 
....................     bit_set(data1,0);     
....................     data1--; 
....................     bit_clear(data2,7); 
....................     if(bit_test(data1,0)) 
....................     bit_set(data2,7); 
....................     data1 = data1 >>1; 
....................     *(((unsigned int8 *)(&y))+3) = data1; 
....................     *(((unsigned int8 *)(&y))+2) = data2; 
....................      
....................   #endif 
....................    } while(res != y); 
....................  
....................    return(res); 
.................... } 
.................... //Overloaded functions for sqrt() for PCD 
.................... // Overloaded function sqrt() for data type - Float48 
.................... #if defined(__PCD__) 
.................... float48 sqrt(float48 x) 
.................... { 
....................    float48 y, res; 
....................    unsigned int16 data1,data2; 
....................    BYTE *p; 
....................  
....................    #ifdef _ERRNO 
....................    if(x < 0) 
....................    { 
....................       errno=EDOM; 
....................    } 
....................    #endif 
....................  
....................    if( x<=0.0) 
....................       return(0.0); 
....................  
....................    y=x; 
....................     
....................    #if !defined(__PCD__) 
....................     p=&y; 
....................    (*p)=(BYTE)((((unsigned int16)(*p)) + 127) >> 1); 
....................    #endif 
....................     
....................    #if defined(__PCD__) 
....................     p = (((unsigned int8 *)(&y))+5); 
....................     data1 = *(((unsigned int8 *)(&y))+5); 
....................     data2 = *(((unsigned int8 *)(&y))+4); 
....................     rotate_left(&data1,1); 
....................     if(bit_test(data2,7)) 
....................     bit_set(data1,0);     
....................     data1 = ((data1+127) >>1); 
....................     bit_clear(data2,7); 
....................     if(bit_test(data1,0)) 
....................     bit_set(data2,7); 
....................     data1 = data1 >>1; 
....................     *(((unsigned int8 *)(&y))+5) = data1; 
....................     *(((unsigned int8 *)(&y))+4) = data2; 
....................      
....................   #endif 
....................  
....................    do { 
....................       res=y; 
....................       y+=(x/y); 
....................  
....................       #if !defined(__PCD__) 
....................      (*p)--; 
....................    #endif 
....................     
....................     data1 = *(((unsigned int8 *)(&y))+5); 
....................     data2 = *(((unsigned int8 *)(&y))+4); 
....................     rotate_left(&data1,1); 
....................     if(bit_test(data2,7)) 
....................     bit_set(data1,0);     
....................     data1--; 
....................     bit_clear(data2,7); 
....................     if(bit_test(data1,0)) 
....................     bit_set(data2,7); 
....................     data1 = data1 >>1; 
....................     *(((unsigned int8 *)(&y))+5) = data1; 
....................     *(((unsigned int8 *)(&y))+4) = data2; 
....................      
....................    } while(res != y); 
....................  
....................    return(res); 
.................... } 
....................  
.................... // Overloaded function sqrt() for data type - Float64 
.................... float64 sqrt(float64 x) 
.................... { 
....................    float64 y, res; 
....................    unsigned int16 *p; 
....................    unsigned int16 temp1,temp2; 
....................  
....................    #ifdef _ERRNO 
....................    if(x < 0) 
....................    { 
....................       errno=EDOM; 
....................    } 
....................    #endif 
....................  
....................    if( x<=0.0) 
....................       return(0.0); 
....................  
....................    y=x; 
....................    p= (((unsigned int16 *)(&y))+3); 
....................    temp1 = *p; 
....................    temp2 = *p; 
....................    bit_clear(temp1,15); 
....................    temp1 = (temp1>>4)+1023; 
....................    temp1 = temp1 >> 1; 
....................    temp1 = (temp1<<4) & 0xFFF0; 
....................    if(bit_test(temp2,15)) 
....................    bit_set(temp1,15); 
....................    temp2 = temp2 & 0x000F; 
....................    temp1 ^= temp2; 
....................     
....................    (*p) = temp1; 
....................     
....................    do { 
....................       res=y; 
....................       y+=(x/y); 
....................      temp1 = *p; 
....................      temp2 = *p; 
....................      bit_clear(temp1,15); 
....................      temp1 = (temp1>>4); 
....................      temp1--; 
....................      temp1 = (temp1<<4) & 0xFFF0; 
....................      if(bit_test(temp2,15)) 
....................      bit_set(temp1,15); 
....................      temp2 = temp2 & 0x000F; 
....................      temp1 ^= temp2; 
....................      (*p) = temp1; 
....................  
....................    } while(res != y); 
....................  
....................    return(res); 
.................... } 
.................... #endif 
....................  
.................... ////////////////////////////// Trig Functions ////////////////////////////// 
.................... #ifdef PI_DIV_BY_TWO 
.................... #undef PI_DIV_BY_TWO 
.................... #endif 
.................... #define PI_DIV_BY_TWO   1.5707963267948966 
.................... #ifdef TWOBYPI 
.................... #undef TWOBYPI 
.................... #define TWOBYPI          0.6366197723675813 
.................... #endif 
.................... //////////////////////////////////////////////////////////////////////////// 
.................... //   float cos(float x) 
.................... //////////////////////////////////////////////////////////////////////////// 
.................... // Description : returns the cosine value of the angle x, which is in radian 
.................... // Date : 9/20/2001 
.................... // 
.................... float32 cos(float32 x) 
.................... { 
....................    float32 y, t, t2 = 1.0; 
....................    unsigned int8 quad, i; 
....................    float32 frac; 
....................    float32 p[6] = {                    //by the series definition for cosine 
....................       -0.5,                            // sum ( ( (-1)^n * x^2n )/(2n)! ) 
....................        0.04166666666667, 
....................       -0.00138888888889, 
....................        0.00002480158730, 
....................       -0.00000027557319, 
....................        0.00000000208767, 
....................       //-0.00000000001147, 
....................       // 0.00000000000005 
....................    }; 
....................  
....................    if (x < 0) x = -x;                  // absolute value of input 
....................  
....................    quad = (unsigned int8)(x / PI_DIV_BY_TWO);    // quadrant 
....................    frac = (x / PI_DIV_BY_TWO) - quad;  // fractional part of input 
....................    quad = quad % 4;                    // quadrant (0 to 3) 
....................  
....................    if (quad == 0 || quad == 2) 
....................       t = frac * PI_DIV_BY_TWO; 
....................    else if (quad == 1) 
....................       t = (1-frac) * PI_DIV_BY_TWO; 
....................    else // should be 3 
....................       t = (frac-1) * PI_DIV_BY_TWO; 
....................  
....................    y = 1.0; 
....................    t = t * t; 
....................    for (i = 0; i <= 5; i++) 
....................    { 
....................       t2 = t2 * t; 
....................       y = y + p[i] * t2; 
....................    } 
....................  
....................    if (quad == 2 || quad == 1) 
....................       y = -y;  // correct sign 
....................  
....................    return (y); 
.................... } 
....................  
....................  
.................... //Overloaded functions for cos() for PCD 
.................... // Overloaded function cos() for data type - Float48 
.................... #if defined(__PCD__) 
.................... float48 cos(float48 x) 
.................... { 
....................    float48 y, t, t2 = 1.0; 
....................    unsigned int8 quad, i; 
....................    float48 frac; 
....................    float48 p[6] = {                    //by the series definition for cosine 
....................       -0.5,                            // sum ( ( (-1)^n * x^2n )/(2n)! ) 
....................        0.04166666666667, 
....................       -0.00138888888889, 
....................        0.00002480158730, 
....................       -0.00000027557319, 
....................        0.00000000208767, 
....................       //-0.00000000001147, 
....................       // 0.00000000000005 
....................    }; 
....................  
....................    if (x < 0) x = -x;                  // absolute value of input 
....................  
....................    quad = (unsigned int8)(x / PI_DIV_BY_TWO);    // quadrant 
....................    frac = (x / PI_DIV_BY_TWO) - quad;  // fractional part of input 
....................    quad = quad % 4;                    // quadrant (0 to 3) 
....................  
....................    if (quad == 0 || quad == 2) 
....................       t = frac * PI_DIV_BY_TWO; 
....................    else if (quad == 1) 
....................       t = (1-frac) * PI_DIV_BY_TWO; 
....................    else // should be 3 
....................       t = (frac-1) * PI_DIV_BY_TWO; 
....................  
....................    y = 0.999999999781; 
....................    t = t * t; 
....................    for (i = 0; i <= 5; i++) 
....................    { 
....................       t2 = t2 * t; 
....................       y = y + p[i] * t2; 
....................    } 
....................  
....................    if (quad == 2 || quad == 1) 
....................       y = -y;  // correct sign 
....................  
....................    return (y); 
.................... } 
....................  
.................... // Overloaded function cos() for data type - Float48 
.................... float64 cos(float64 x) 
.................... { 
....................    float64 y, t, t2 = 1.0; 
....................    unsigned int8 quad, i; 
....................    float64 frac; 
....................    float64 p[6] = {                    //by the series definition for cosine 
....................       -0.5,                            // sum ( ( (-1)^n * x^2n )/(2n)! ) 
....................        0.04166666666667, 
....................       -0.00138888888889, 
....................        0.00002480158730, 
....................       -0.00000027557319, 
....................        0.00000000208767, 
....................       //-0.00000000001147, 
....................       // 0.00000000000005 
....................    }; 
....................  
....................    if (x < 0) x = -x;                  // absolute value of input 
....................  
....................    quad = (unsigned int8)(x / PI_DIV_BY_TWO);    // quadrant 
....................    frac = (x / PI_DIV_BY_TWO) - quad;  // fractional part of input 
....................    quad = quad % 4;                    // quadrant (0 to 3) 
....................  
....................    if (quad == 0 || quad == 2) 
....................       t = frac * PI_DIV_BY_TWO; 
....................    else if (quad == 1) 
....................       t = (1-frac) * PI_DIV_BY_TWO; 
....................    else // should be 3 
....................       t = (frac-1) * PI_DIV_BY_TWO; 
....................  
....................    y = 0.999999999781; 
....................    t = t * t; 
....................    for (i = 0; i <= 5; i++) 
....................    { 
....................       t2 = t2 * t; 
....................       y = y + p[i] * t2; 
....................    } 
....................  
....................    if (quad == 2 || quad == 1) 
....................       y = -y;  // correct sign 
....................  
....................    return (y); 
.................... } 
....................  
.................... #endif 
....................  
.................... //////////////////////////////////////////////////////////////////////////// 
.................... //   float sin(float x) 
.................... //////////////////////////////////////////////////////////////////////////// 
.................... // Description : returns the sine value of the angle x, which is in radian 
.................... // Date : 9/20/2001 
.................... // 
.................... float32 sin(float32 x) 
.................... { 
....................    return cos(x - PI_DIV_BY_TWO); 
.................... } 
....................  
.................... //Overloaded functions for sin() for PCD 
.................... // Overloaded function sin() for data type - Float48 
.................... #if defined(__PCD__) 
.................... float48 sin(float48 x) 
.................... { 
....................    return cos(x - PI_DIV_BY_TWO); 
.................... } 
....................  
.................... // Overloaded function sin() for data type - Float48 
.................... float64 sin(float64 x) 
.................... { 
....................    return cos(x - PI_DIV_BY_TWO); 
.................... } 
.................... #endif 
....................  
.................... //////////////////////////////////////////////////////////////////////////// 
.................... //   float tan(float x) 
.................... //////////////////////////////////////////////////////////////////////////// 
.................... // Description : returns the tangent value of the angle x, which is in radian 
.................... // Date : 9/20/2001 
.................... // 
.................... float32 tan(float32 x) 
.................... { 
....................    float32 c, s; 
....................  
....................    c = cos(x); 
....................    if (c == 0.0) 
....................       return (1.0e+36); 
....................  
....................    s = sin(x); 
....................    return(s/c); 
.................... } 
.................... //Overloaded functions for tan() for PCD 
.................... // Overloaded function tan() for data type - Float48 
.................... #if defined(__PCD__) 
.................... float48 tan(float48 x) 
.................... { 
....................    float48 c, s; 
....................  
....................    c = cos(x); 
....................    if (c == 0.0) 
....................       return (1.0e+36); 
....................  
....................    s = sin(x); 
....................    return(s/c); 
.................... } 
....................  
.................... // Overloaded function tan() for data type - Float48 
.................... float64 tan(float64 x) 
.................... { 
....................    float64 c, s; 
....................  
....................    c = cos(x); 
....................    if (c == 0.0) 
....................       return (1.0e+36); 
....................  
....................    s = sin(x); 
....................    return(s/c); 
.................... } 
.................... #endif 
....................  
.................... float32 const pas[3] = {0.49559947, -4.6145309, 5.6036290}; 
.................... float32 const qas[3] = {1.0000000,  -5.5484666, 5.6036290}; 
....................  
.................... float32 ASIN_COS(float32 x, unsigned int8 n) 
.................... { 
....................    float32 y, res, r, y2; 
....................    int1 s; 
....................    #ifdef _ERRNO 
....................    if(x <-1 || x > 1) 
....................    { 
....................       errno=EDOM; 
....................    } 
....................    #endif 
....................    s = 0; 
....................    y = x; 
....................  
....................    if (x < 0) 
....................    { 
....................       s = 1; 
....................       y = -y; 
....................    } 
....................  
....................    if (y > 0.5) 
....................    { 
....................       y = sqrt((1.0 - y)/2.0); 
....................       n += 2; 
....................    } 
....................  
....................    y2=y*y; 
....................  
....................    res = pas[0]*y2 + pas[1]; 
....................    res = res*y2 + pas[2]; 
....................  
....................    r = qas[0]*y2 + qas[1]; 
....................    r = r*y2 + qas[2]; 
....................  
....................    res = y*res/r; 
....................  
....................    if (n & 2)     // |x| > 0.5 
....................       res = PI_DIV_BY_TWO - 2.0*res; 
....................    if (s) 
....................       res = -res; 
....................    if (n & 1)           // take arccos 
....................       res = PI_DIV_BY_TWO - res; 
....................  
....................    return(res); 
.................... } 
....................  
.................... //Overloaded functions for ASIN_COS() for PCD 
.................... // Overloaded function ASIN_COS() for data type - Float48 
.................... #if defined(__PCD__) 
.................... float48 ASIN_COS(float48 x, unsigned int8 n) 
.................... { 
....................    float48 y, res, r, y2; 
....................    int1 s; 
....................    #ifdef _ERRNO 
....................    if(x <-1 || x > 1) 
....................    { 
....................       errno=EDOM; 
....................    } 
....................    #endif 
....................    s = 0; 
....................    y = x; 
....................  
....................    if (x < 0) 
....................    { 
....................       s = 1; 
....................       y = -y; 
....................    } 
....................  
....................    if (y > 0.5) 
....................    { 
....................       y = sqrt((1.0 - y)/2.0); 
....................       n += 2; 
....................    } 
....................  
....................    y2=y*y; 
....................  
....................    res = pas[0]*y2 + pas[1]; 
....................    res = res*y2 + pas[2]; 
....................  
....................    r = qas[0]*y2 + qas[1]; 
....................    r = r*y2 + qas[2]; 
....................  
....................    res = y*res/r; 
....................  
....................    if (n & 2)     // |x| > 0.5 
....................       res = PI_DIV_BY_TWO - 2.0*res; 
....................    if (s) 
....................       res = -res; 
....................    if (n & 1)           // take arccos 
....................       res = PI_DIV_BY_TWO - res; 
....................  
....................    return(res); 
.................... } 
....................  
.................... // Overloaded function ASIN_COS() for data type - Float64 
.................... float64 ASIN_COS(float64 x, unsigned int8 n) 
.................... { 
....................    float64 y, res, r, y2; 
....................    int1 s; 
....................    #ifdef _ERRNO 
....................    if(x <-1 || x > 1) 
....................    { 
....................       errno=EDOM; 
....................    } 
....................    #endif 
....................    s = 0; 
....................    y = x; 
....................  
....................    if (x < 0) 
....................    { 
....................       s = 1; 
....................       y = -y; 
....................    } 
....................  
....................    if (y > 0.5) 
....................    { 
....................       y = sqrt((1.0 - y)/2.0); 
....................       n += 2; 
....................    } 
....................  
....................    y2=y*y; 
....................  
....................    res = pas[0]*y2 + pas[1]; 
....................    res = res*y2 + pas[2]; 
....................  
....................    r = qas[0]*y2 + qas[1]; 
....................    r = r*y2 + qas[2]; 
....................  
....................    res = y*res/r; 
....................  
....................    if (n & 2)     // |x| > 0.5 
....................       res = PI_DIV_BY_TWO - 2.0*res; 
....................    if (s) 
....................       res = -res; 
....................    if (n & 1)           // take arccos 
....................       res = PI_DIV_BY_TWO - res; 
....................  
....................    return(res); 
.................... } 
.................... #endif 
....................  
.................... //////////////////////////////////////////////////////////////////////////// 
.................... //   float asin(float x) 
.................... //////////////////////////////////////////////////////////////////////////// 
.................... // Description : returns the arcsine value of the value x. 
.................... // Date : N/A 
.................... // 
.................... float32 asin(float32 x) 
.................... { 
....................    float32 r; 
....................  
....................    r = ASIN_COS(x, 0); 
....................    return(r); 
.................... } 
.................... //Overloaded functions for asin() for PCD 
.................... // Overloaded function asin() for data type - Float48 
.................... #if defined(__PCD__) 
.................... float48 asin(float48 x) 
.................... { 
....................    float48 r; 
....................  
....................    r = ASIN_COS(x, 0); 
....................    return(r); 
.................... } 
....................  
.................... // Overloaded function asin() for data type - Float64 
.................... float64 asin(float64 x) 
.................... { 
....................    float64 r; 
....................  
....................    r = ASIN_COS(x, 0); 
....................    return(r); 
.................... } 
.................... #endif 
....................  
.................... //////////////////////////////////////////////////////////////////////////// 
.................... //   float acos(float x) 
.................... //////////////////////////////////////////////////////////////////////////// 
.................... // Description : returns the arccosine value of the value x. 
.................... // Date : N/A 
.................... // 
.................... float32 acos(float32 x) 
.................... { 
....................    float32 r; 
....................  
....................    r = ASIN_COS(x, 1); 
....................    return(r); 
.................... } 
.................... //Overloaded functions for acos() for PCD 
.................... // Overloaded function acos() for data type - Float48 
.................... #if defined(__PCD__) 
.................... float48 acos(float48 x) 
.................... { 
....................    float48 r; 
....................  
....................    r = ASIN_COS(x, 1); 
....................    return(r); 
.................... } 
....................  
.................... // Overloaded function acos() for data type - Float64 
.................... float64 acos(float64 x) 
.................... { 
....................    float64 r; 
....................  
....................    r = ASIN_COS(x, 1); 
....................    return(r); 
.................... } 
.................... #endif 
....................  
.................... float32 const pat[4] = {0.17630401, 5.6710795, 22.376096, 19.818457}; 
.................... float32 const qat[4] = {1.0000000,  11.368190, 28.982246, 19.818457}; 
....................  
.................... //////////////////////////////////////////////////////////////////////////// 
.................... //   float atan(float x) 
.................... //////////////////////////////////////////////////////////////////////////// 
.................... // Description : returns the arctangent value of the value x. 
.................... // Date : N/A 
.................... // 
.................... float32 atan(float32 x) 
.................... { 
....................    float32 y, res, r; 
....................    int1 s, flag; 
....................  
....................    s = 0; 
....................    flag = 0; 
....................    y = x; 
....................  
....................    if (x < 0) 
....................    { 
....................       s = 1; 
....................       y = -y; 
....................    } 
....................  
....................    if (y > 1.0) 
....................    { 
....................       y = 1.0/y; 
....................       flag = 1; 
....................    } 
....................  
....................    res = pat[0]*y*y + pat[1]; 
....................    res = res*y*y + pat[2]; 
....................    res = res*y*y + pat[3]; 
....................  
....................    r = qat[0]*y*y + qat[1]; 
....................    r = r*y*y + qat[2]; 
....................    r = r*y*y + qat[3]; 
....................  
....................    res = y*res/r; 
....................  
....................  
....................    if (flag)                              // for |x| > 1 
....................       res = PI_DIV_BY_TWO - res; 
....................    if (s) 
....................       res = -res; 
....................  
....................    return(res); 
.................... } 
.................... //Overloaded functions for atan() for PCD 
.................... // Overloaded function atan() for data type - Float48 
.................... #if defined(__PCD__) 
.................... float48 atan(float48 x) 
.................... { 
....................    float48 y, res, r; 
....................    int1 s, flag; 
....................  
....................    s = 0; 
....................    flag = 0; 
....................    y = x; 
....................  
....................    if (x < 0) 
....................    { 
....................       s = 1; 
....................       y = -y; 
....................    } 
....................  
....................    if (y > 1.0) 
....................    { 
....................       y = 1.0/y; 
....................       flag = 1; 
....................    } 
....................  
....................    res = pat[0]*y*y + pat[1]; 
....................    res = res*y*y + pat[2]; 
....................    res = res*y*y + pat[3]; 
....................  
....................    r = qat[0]*y*y + qat[1]; 
....................    r = r*y*y + qat[2]; 
....................    r = r*y*y + qat[3]; 
....................  
....................    res = y*res/r; 
....................  
....................  
....................    if (flag)                              // for |x| > 1 
....................       res = PI_DIV_BY_TWO - res; 
....................    if (s) 
....................       res = -res; 
....................  
....................    return(res); 
.................... } 
....................  
.................... // Overloaded function atan() for data type - Float64 
.................... float64 atan(float64 x) 
.................... { 
....................    float64 y, res, r; 
....................    int1 s, flag; 
....................  
....................    s = 0; 
....................    flag = 0; 
....................    y = x; 
....................  
....................    if (x < 0) 
....................    { 
....................       s = 1; 
....................       y = -y; 
....................    } 
....................  
....................    if (y > 1.0) 
....................    { 
....................       y = 1.0/y; 
....................       flag = 1; 
....................    } 
....................  
....................    res = pat[0]*y*y + pat[1]; 
....................    res = res*y*y + pat[2]; 
....................    res = res*y*y + pat[3]; 
....................  
....................    r = qat[0]*y*y + qat[1]; 
....................    r = r*y*y + qat[2]; 
....................    r = r*y*y + qat[3]; 
....................  
....................    res = y*res/r; 
....................  
....................  
....................    if (flag)                              // for |x| > 1 
....................       res = PI_DIV_BY_TWO - res; 
....................    if (s) 
....................       res = -res; 
....................  
....................    return(res); 
.................... } 
.................... #endif 
....................  
.................... ///////////////////////////////////////////////////////////////////////////// 
.................... //   float atan2(float y, float x) 
.................... ///////////////////////////////////////////////////////////////////////////// 
.................... // Description :computes the principal value of arc tangent of y/x, using the 
.................... // signs of both the arguments to determine the quadrant of the return value 
.................... // Returns : returns the arc tangent of y/x. 
.................... // Date : N/A 
.................... // 
....................  
.................... float32 atan2(float32 y,float32 x) 
.................... { 
....................    float32 z; 
....................    int1 sign; 
....................    unsigned int8 quad; 
....................    sign=0; 
....................    quad=0; //quadrant 
....................    quad=((y<=0.0)?((x<=0.0)?3:4):((x<0.0)?2:1)); 
....................    if(y<0.0) 
....................    { 
....................       sign=1; 
....................       y=-y; 
....................    } 
....................    if(x<0.0) 
....................    { 
....................       x=-x; 
....................    } 
....................    if (x==0.0) 
....................    { 
....................       if(y==0.0) 
....................       { 
....................       #ifdef _ERRNO 
....................       { 
....................          errno=EDOM; 
....................       } 
....................       #endif 
....................       } 
....................       else 
....................       { 
....................          if(sign) 
....................          { 
....................          return (-(PI_DIV_BY_TWO)); 
....................          } 
....................          else 
....................          { 
....................          return (PI_DIV_BY_TWO); 
....................          } 
....................       } 
....................    } 
....................    else 
....................    { 
....................       z=y/x; 
....................       switch(quad) 
....................       { 
....................          case 1: 
....................          { 
....................             return atan(z); 
....................             break; 
....................          } 
....................          case 2: 
....................          { 
.................... //            return (atan(z)+PI_DIV_BY_TWO);  //2L3122 
....................             return (PI-atan(z)); 
....................             break; 
....................          } 
....................          case 3: 
....................          { 
....................             return (atan(z)-PI); 
....................             break; 
....................          } 
....................          case 4: 
....................          { 
....................             return (-atan(z)); 
....................             break; 
....................          } 
....................       } 
....................    } 
.................... } 
....................  
.................... //Overloaded functions for atan2() for PCD 
.................... // Overloaded function atan2() for data type - Float48 
.................... #if defined(__PCD__) 
.................... float48 atan2(float48 y,float48 x) 
.................... { 
....................    float48 z; 
....................    int1 sign; 
....................    unsigned int8 quad; 
....................    sign=0; 
....................    quad=0; //quadrant 
....................    quad=((y<=0.0)?((x<=0.0)?3:4):((x<0.0)?2:1)); 
....................    if(y<0.0) 
....................    { 
....................       sign=1; 
....................       y=-y; 
....................    } 
....................    if(x<0.0) 
....................    { 
....................       x=-x; 
....................    } 
....................    if (x==0.0) 
....................    { 
....................       if(y==0.0) 
....................       { 
....................       #ifdef _ERRNO 
....................       { 
....................          errno=EDOM; 
....................       } 
....................       #endif 
....................       } 
....................       else 
....................       { 
....................          if(sign) 
....................          { 
....................          return (-(PI_DIV_BY_TWO)); 
....................          } 
....................          else 
....................          { 
....................          return (PI_DIV_BY_TWO); 
....................          } 
....................       } 
....................    } 
....................    else 
....................    { 
....................       z=y/x; 
....................       switch(quad) 
....................       { 
....................          case 1: 
....................          { 
....................             return atan(z); 
....................             break; 
....................          } 
....................          case 2: 
....................          { 
.................... //            return (atan(z)+PI_DIV_BY_TWO);  //2L3122 
....................             return (PI-atan(z)); 
....................             break; 
....................          } 
....................          case 3: 
....................          { 
....................             return (atan(z)-PI); 
....................             break; 
....................          } 
....................          case 4: 
....................          { 
....................             return (-atan(z)); 
....................             break; 
....................          } 
....................       } 
....................    } 
.................... } 
....................  
.................... // Overloaded function atan2() for data type - Float64 
.................... float64 atan2(float64 y,float64 x) 
.................... { 
....................    float64 z; 
....................    int1 sign; 
....................    unsigned int8 quad; 
....................    sign=0; 
....................    quad=0; //quadrant 
....................    quad=((y<=0.0)?((x<=0.0)?3:4):((x<0.0)?2:1)); 
....................    if(y<0.0) 
....................    { 
....................       sign=1; 
....................       y=-y; 
....................    } 
....................    if(x<0.0) 
....................    { 
....................       x=-x; 
....................    } 
....................    if (x==0.0) 
....................    { 
....................       if(y==0.0) 
....................       { 
....................       #ifdef _ERRNO 
....................       { 
....................          errno=EDOM; 
....................       } 
....................       #endif 
....................       } 
....................       else 
....................       { 
....................          if(sign) 
....................          { 
....................          return (-(PI_DIV_BY_TWO)); 
....................          } 
....................          else 
....................          { 
....................          return (PI_DIV_BY_TWO); 
....................          } 
....................       } 
....................    } 
....................    else 
....................    { 
....................       z=y/x; 
....................       switch(quad) 
....................       { 
....................          case 1: 
....................          { 
....................             return atan(z); 
....................             break; 
....................          } 
....................          case 2: 
....................          { 
.................... //            return (atan(z)+PI_DIV_BY_TWO);  //2L3122 
....................             return (PI-atan(z)); 
....................             break; 
....................          } 
....................          case 3: 
....................          { 
....................             return (atan(z)-PI); 
....................             break; 
....................          } 
....................          case 4: 
....................          { 
....................             return (-atan(z)); 
....................             break; 
....................          } 
....................       } 
....................    } 
.................... } 
.................... #endif 
....................  
.................... //////////////////// Hyperbolic functions //////////////////// 
....................  
.................... //////////////////////////////////////////////////////////////////////////// 
.................... //   float cosh(float x) 
.................... //////////////////////////////////////////////////////////////////////////// 
.................... // Description : Computes the hyperbolic cosine value of x 
.................... // Returns : returns the hyperbolic cosine value of x 
.................... // Date : N/A 
.................... // 
....................  
.................... float32 cosh(float32 x) 
.................... { 
....................    return ((exp(x)+exp(-x))/2); 
.................... } 
.................... //Overloaded functions for cosh() for PCD 
.................... // Overloaded function cosh() for data type - Float48 
.................... #if defined(__PCD__) 
.................... float48 cosh(float48 x) 
.................... { 
....................    return ((exp(x)+exp(-x))/2); 
.................... } 
....................  
.................... // Overloaded function cosh() for data type - Float64 
.................... float64 cosh(float64 x) 
.................... { 
....................    return ((exp(x)+exp(-x))/2); 
.................... } 
.................... #endif 
....................  
.................... //////////////////////////////////////////////////////////////////////////// 
.................... //   float sinh(float x) 
.................... //////////////////////////////////////////////////////////////////////////// 
.................... // Description : Computes the hyperbolic sine value of x 
.................... // Returns : returns the hyperbolic sine value of x 
.................... // Date : N/A 
.................... // 
....................  
.................... float32 sinh(float32 x) 
.................... { 
....................  
....................    return ((exp(x) - exp(-x))/2); 
.................... } 
.................... //Overloaded functions for sinh() for PCD 
.................... // Overloaded function sinh() for data type - Float48 
.................... #if defined(__PCD__) 
.................... float48 sinh(float48 x) 
.................... { 
....................  
....................    return ((exp(x) - exp(-x))/2); 
.................... } 
....................  
.................... // Overloaded function sinh() for data type - Float48 
.................... float64 sinh(float64 x) 
.................... { 
....................  
....................    return ((exp(x) - exp(-x))/2); 
.................... } 
.................... #endif 
....................  
.................... //////////////////////////////////////////////////////////////////////////// 
.................... //   float tanh(float x) 
.................... //////////////////////////////////////////////////////////////////////////// 
.................... // Description : Computes the hyperbolic tangent value of x 
.................... // Returns : returns the hyperbolic tangent value of x 
.................... // Date : N/A 
.................... // 
....................  
.................... float32 tanh(float32 x) 
.................... { 
....................    return(sinh(x)/cosh(x)); 
.................... } 
.................... //Overloaded functions for tanh() for PCD 
.................... // Overloaded function tanh() for data type - Float48 
.................... #if defined(__PCD__) 
.................... float48 tanh(float48 x) 
.................... { 
....................    return(sinh(x)/cosh(x)); 
.................... } 
....................  
.................... // Overloaded function tanh() for data type - Float64 
.................... float64 tanh(float64 x) 
.................... { 
....................    return(sinh(x)/cosh(x)); 
.................... } 
.................... #endif 
....................  
.................... //////////////////////////////////////////////////////////////////////////// 
.................... //   float frexp(float x, signed int *exp) 
.................... //////////////////////////////////////////////////////////////////////////// 
.................... // Description : breaks a floating point number into a normalized fraction and an integral 
.................... // power of 2. It stores the integer in the signed int object pointed to by exp. 
.................... // Returns : returns the value x, such that x is a double with magnitude in the interval 
.................... // [1/2,1) or zero, and value equals x times 2 raised to the power *exp.If value is zero, 
.................... // both parts of the result are zero. 
.................... // Date : N/A 
.................... // 
....................  
.................... #define LOG2 .30102999566398119521 
.................... float32 frexp(float32 x, signed int8 *exp) 
.................... { 
....................    float32 res; 
....................    int1 sign = 0; 
....................    if(x == 0.0) 
....................    { 
....................       *exp=0; 
....................       return (0.0); 
....................    } 
....................    if(x < 0.0) 
....................    { 
....................      x=-x; 
....................      sign=1; 
....................    } 
....................    if (x > 1.0) 
....................    { 
....................       *exp=(ceil(log10(x)/LOG2)); 
....................       res=x/(pow(2, *exp)); 
....................       if (res == 1) 
....................       { 
....................          *exp=*exp+1; 
....................           res=.5; 
....................       } 
....................    } 
....................    else 
....................    { 
....................       if(x < 0.5) 
....................       { 
....................          *exp=-1; 
....................          res=x*2; 
....................       } 
....................       else 
....................       { 
....................          *exp=0; 
....................           res=x; 
....................       } 
....................    } 
....................    if(sign) 
....................    { 
....................       res=-res; 
....................    } 
....................    return res; 
.................... } 
....................  
.................... //Overloaded functions for frexp() for PCD 
.................... // Overloaded function frexp() for data type - Float48 
.................... #if defined(__PCD__) 
.................... float48 frexp(float48 x, signed int8 *exp) 
.................... { 
....................    float48 res; 
....................    int1 sign = 0; 
....................    if(x == 0.0) 
....................    { 
....................       *exp=0; 
....................       return (0.0); 
....................    } 
....................    if(x < 0.0) 
....................    { 
....................      x=-x; 
....................      sign=1; 
....................    } 
....................    if (x > 1.0) 
....................    { 
....................       *exp=(ceil(log10(x)/LOG2)); 
....................       res=x/(pow(2, *exp)); 
....................       if (res == 1) 
....................       { 
....................          *exp=*exp+1; 
....................           res=.5; 
....................       } 
....................    } 
....................    else 
....................    { 
....................       if(x < 0.5) 
....................       { 
....................          *exp=-1; 
....................          res=x*2; 
....................       } 
....................       else 
....................       { 
....................          *exp=0; 
....................           res=x; 
....................       } 
....................    } 
....................    if(sign) 
....................    { 
....................       res=-res; 
....................    } 
....................    return res; 
.................... } 
....................  
.................... // Overloaded function frexp() for data type - Float64 
.................... float64 frexp(float64 x, signed int8 *exp) 
.................... { 
....................    float64 res; 
....................    int1 sign = 0; 
....................    if(x == 0.0) 
....................    { 
....................       *exp=0; 
....................       return (0.0); 
....................    } 
....................    if(x < 0.0) 
....................    { 
....................      x=-x; 
....................      sign=1; 
....................    } 
....................    if (x > 1.0) 
....................    { 
....................       *exp=(ceil(log10(x)/LOG2)); 
....................       res=x/(pow(2, *exp)); 
....................       if (res == 1) 
....................       { 
....................          *exp=*exp+1; 
....................           res=.5; 
....................       } 
....................    } 
....................    else 
....................    { 
....................       if(x < 0.5) 
....................       { 
....................          *exp=-1; 
....................          res=x*2; 
....................       } 
....................       else 
....................       { 
....................          *exp=0; 
....................           res=x; 
....................       } 
....................    } 
....................    if(sign) 
....................    { 
....................       res=-res; 
....................    } 
....................    return res; 
.................... } 
.................... #endif 
....................  
.................... ////////////////////////////////////////////////////////////////////////////// 
.................... //   float ldexp(float x, signed int *exp) 
.................... ////////////////////////////////////////////////////////////////////////////// 
.................... // Description : multiplies a floating point number by an integral power of 2. 
.................... // Returns : returns the value of x times 2 raised to the power exp. 
.................... // Date : N/A 
.................... // 
....................  
.................... float32 ldexp(float32 value, signed int8 exp) 
.................... { 
....................    return (value * pow(2,exp)); 
.................... } 
.................... //Overloaded functions for ldexp() for PCD 
.................... // Overloaded function ldexp() for data type - Float48 
....................  
.................... #if defined(__PCD__) 
.................... float48 ldexp(float48 value, signed int8 exp) 
.................... { 
....................    return (value * pow(2,exp)); 
.................... } 
.................... // Overloaded function ldexp() for data type - Float64 
.................... float64 ldexp(float64 value, signed int8 exp) 
.................... { 
....................    return (value * pow(2,exp)); 
.................... } 
.................... #endif 
....................  
.................... #endif 
....................  
....................  
.................... void main() 
.................... { 
*
024F:  CLRF   04
0250:  BCF    03.7
0251:  MOVLW  1F
0252:  ANDWF  03,F
0253:  MOVLW  71
0254:  BSF    03.5
0255:  MOVWF  0F
0256:  MOVF   0F,W
0257:  BCF    03.5
0258:  BCF    20.7
0259:  MOVF   20,W
025A:  BSF    03.5
025B:  MOVWF  07
025C:  BCF    03.5
025D:  BSF    07.7
025E:  BSF    03.5
025F:  BSF    03.6
0260:  MOVF   09,W
0261:  ANDLW  C0
0262:  MOVWF  09
0263:  BCF    03.6
0264:  BCF    1F.4
0265:  BCF    1F.5
0266:  MOVLW  00
0267:  BSF    03.6
0268:  MOVWF  08
0269:  BCF    03.5
026A:  CLRF   07
026B:  CLRF   08
026C:  CLRF   09
*
0276:  CLRF   34
0277:  CLRF   33
.................... float last,b,anemo_speed; 
.................... unsigned int16 anemo_round=0; 
.................... unsigned int16 i; 
....................  
....................  
.................... //signed int16 X,Y,Z; 
....................   setup_adc_ports(NO_ANALOGS|VSS_VDD); 
0278:  BSF    03.5
0279:  BSF    03.6
027A:  MOVF   09,W
027B:  ANDLW  C0
027C:  MOVWF  09
027D:  BCF    03.6
027E:  BCF    1F.4
027F:  BCF    1F.5
0280:  MOVLW  00
0281:  BSF    03.6
0282:  MOVWF  08
....................   setup_adc(ADC_CLOCK_DIV_2); 
0283:  BCF    03.5
0284:  BCF    03.6
0285:  BCF    1F.6
0286:  BCF    1F.7
0287:  BSF    03.5
0288:  BCF    1F.7
0289:  BCF    03.5
028A:  BSF    1F.0
....................   setup_spi(SPI_SS_DISABLED); 
028B:  BCF    14.5
028C:  BCF    20.5
028D:  MOVF   20,W
028E:  BSF    03.5
028F:  MOVWF  07
0290:  BCF    03.5
0291:  BSF    20.4
0292:  MOVF   20,W
0293:  BSF    03.5
0294:  MOVWF  07
0295:  BCF    03.5
0296:  BCF    20.3
0297:  MOVF   20,W
0298:  BSF    03.5
0299:  MOVWF  07
029A:  MOVLW  01
029B:  BCF    03.5
029C:  MOVWF  14
029D:  MOVLW  00
029E:  BSF    03.5
029F:  MOVWF  14
....................   setup_timer_0(RTCC_INTERNAL|RTCC_DIV_1); 
02A0:  MOVF   01,W
02A1:  ANDLW  C7
02A2:  IORLW  08
02A3:  MOVWF  01
....................   setup_timer_1(T1_DISABLED); 
02A4:  BCF    03.5
02A5:  CLRF   10
....................   setup_timer_2(T2_DISABLED,0,1); 
02A6:  MOVLW  00
02A7:  MOVWF  78
02A8:  MOVWF  12
02A9:  MOVLW  00
02AA:  BSF    03.5
02AB:  MOVWF  12
....................   setup_ccp1(CCP_OFF); 
02AC:  BCF    03.5
02AD:  BSF    20.2
02AE:  MOVF   20,W
02AF:  BSF    03.5
02B0:  MOVWF  07
02B1:  BCF    03.5
02B2:  CLRF   17
02B3:  BSF    03.5
02B4:  CLRF   1B
02B5:  CLRF   1C
02B6:  MOVLW  01
02B7:  MOVWF  1D
....................   setup_comparator(NC_NC_NC_NC);// This device COMP currently not supported by the PICWizard 
02B8:  BCF    03.5
02B9:  BSF    03.6
02BA:  CLRF   07
02BB:  CLRF   08
02BC:  CLRF   09
....................  
.................... // Init the HMC5883L.  Set Mode register for 
.................... // continuous measurements. 
.................... hmc5883l_write_reg(HMC5883L_CFG_A_REG, 0x18);      // no average, maximal update range 
02BD:  BCF    03.6
02BE:  CLRF   37
02BF:  MOVLW  18
02C0:  MOVWF  38
02C1:  CALL   069
.................... hmc5883l_write_reg(HMC5883L_CFG_B_REG, 0xE0);      // maximal range 
02C2:  MOVLW  01
02C3:  MOVWF  37
02C4:  MOVLW  E0
02C5:  MOVWF  38
02C6:  CALL   069
.................... hmc5883l_write_reg(HMC5883L_MODE_REG, 0x00); 
02C7:  MOVLW  02
02C8:  MOVWF  37
02C9:  CLRF   38
02CA:  CALL   069
....................  
.................... // Continuously read and display the x,y,z results. 
.................... // Wait at least 67 ms between reads, re the HMC5883L data sheet. 
....................  
....................  
....................   printf("Magnetometr:  \r\n",); 
02CB:  MOVLW  04
02CC:  BSF    03.6
02CD:  MOVWF  0D
02CE:  MOVLW  00
02CF:  MOVWF  0F
02D0:  BCF    03.6
02D1:  CALL   0C5
....................   printf("(c)mlab JACHO 2013:  \r\n",); 
02D2:  MOVLW  0D
02D3:  BSF    03.6
02D4:  MOVWF  0D
02D5:  MOVLW  00
02D6:  MOVWF  0F
02D7:  BCF    03.6
02D8:  CALL   0C5
....................   printf("X, Y, Z \r\n",); 
02D9:  MOVLW  19
02DA:  BSF    03.6
02DB:  MOVWF  0D
02DC:  MOVLW  00
02DD:  MOVWF  0F
02DE:  BCF    03.6
02DF:  CALL   0C5
....................  
.................... /*  while(true) 
....................   {   
....................     X = mag_readX(); 
....................     Y = mag_readY(); 
....................     Z = mag_readZ(); 
....................     printf("%4Ld %4Ld %4Ld \r\n", X, Y, Z); 
....................     Delay_ms(50);   
....................     
....................   } 
.................... */ 
....................  
.................... while(TRUE) 
....................   { 
....................  
.................... //   for(i=0;i<=10;i++) 
.................... //   { 
....................      hmc5883l_read_data();    
02E0:  GOTO   150
....................     
.................... //     b = atan2((float)compass.y,(float)compass.x); // vypocet azimutu z kartezskych souradnic 
.................... //     b = (b/3.141596)*180;  // prevod na stupne 
.................... //     b += 180; 
....................  
.................... //     anemo_speed += (b-last); 
.................... //     last=b; 
.................... //     delay_ms(10); 
.................... //   } 
.................... //   anemo_speed=anemo_speed/10; 
....................  
....................    printf("%6Ld %6Ld %6Ld \n\r", compass.x, compass.y, compass.z); 
02E1:  MOVLW  00
02E2:  MOVWF  04
02E3:  MOVF   22,W
02E4:  MOVWF  38
02E5:  MOVF   21,W
02E6:  MOVWF  37
02E7:  CALL   1CF
02E8:  MOVLW  20
02E9:  MOVWF  40
02EA:  CALL   0A2
02EB:  MOVLW  00
02EC:  MOVWF  04
02ED:  MOVF   24,W
02EE:  MOVWF  38
02EF:  MOVF   23,W
02F0:  MOVWF  37
02F1:  CALL   1CF
02F2:  MOVLW  20
02F3:  MOVWF  40
02F4:  CALL   0A2
02F5:  MOVLW  00
02F6:  MOVWF  04
02F7:  MOVF   26,W
02F8:  MOVWF  38
02F9:  MOVF   25,W
02FA:  MOVWF  37
02FB:  CALL   1CF
02FC:  MOVLW  20
02FD:  MOVWF  40
02FE:  CALL   0A2
02FF:  MOVLW  0A
0300:  MOVWF  40
0301:  CALL   0A2
0302:  MOVLW  0D
0303:  MOVWF  40
0304:  CALL   0A2
.................... //   delay_ms(100); 
....................   }     
0305:  GOTO   2E0
....................  
.................... } 
....................  
....................  
....................  
0306:  SLEEP

Configuration Fuses:
   Word  1: 2CF5   INTRC NOWDT NOPUT MCLR NOPROTECT NOCPD NOBROWNOUT IESO FCMEN NOLVP NODEBUG
   Word  2: 3FFF   NOWRT BORV40
Subversion Repositories – MLAB

(root)/Modules/Sensors/MAG01A/SW/PIC16F887/main.lst

Rev 2988
