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WiringPi/wiringPi/softServo.c

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  1. /*

  2.  * softServo.c:

  3.  *	Provide N channels of software driven PWM suitable for RC

  4.  *	servo motors.

  5.  *	Copyright (c) 2012 Gordon Henderson

  6.  ***********************************************************************

  7.  * This file is part of wiringPi:

  8.  *	https://github.com/WiringPi/WiringPi/

  9.  *

  10.  *    wiringPi is free software: you can redistribute it and/or modify

  11.  *    it under the terms of the GNU Lesser General Public License as

  12.  *    published by the Free Software Foundation, either version 3 of the

  13.  *    License, or (at your option) any later version.

  14.  *

  15.  *    wiringPi is distributed in the hope that it will be useful,

  16.  *    but WITHOUT ANY WARRANTY; without even the implied warranty of

  17.  *    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the

  18.  *    GNU Lesser General Public License for more details.

  19.  *

  20.  *    You should have received a copy of the GNU Lesser General Public

  21.  *    License along with wiringPi.

  22.  *    If not, see <http://www.gnu.org/licenses/>.

  23.  ***********************************************************************

  24.  */

  25. 

  26. //#include <stdio.h>

  27. #include <string.h>

  28. #include <time.h>

  29. #include <sys/time.h>

  30. #include <pthread.h>

  31. 

  32. #include "wiringPi.h"

  33. #include "softServo.h"

  34. 

  35. // RC Servo motors are a bit of an oddity - designed in the days when 

  36. //	radio control was experimental and people were tryin to make

  37. //	things as simple as possible as it was all very expensive...

  38. //

  39. // So... To drive an RC Servo motor, you need to send it a modified PWM

  40. //	signal - it needs anything from 1ms to 2ms - with 1ms meaning

  41. //	to move the server fully left, and 2ms meaning to move it fully

  42. //	right. Then you need a long gap before sending the next pulse.

  43. //	The reason for this is that you send a multiplexed stream of these

  44. //	pulses up the radio signal into the reciever which de-multiplexes

  45. //	them into the signals for each individual servo. Typically there

  46. //	might be 8 channels, so you need at least 8 "slots" of 2mS pulses

  47. //	meaning the entire frame must fit into a 16mS slot - which would

  48. //	then be repeated...

  49. //

  50. // In practice we have a total slot width of about 20mS - so we're sending 50

  51. //	updates per second to each servo.

  52. //

  53. // In this code, we don't need to be too fussy about the gap as we're not doing

  54. //	the multipexing, but it does need to be at least 10mS, and preferably 16

  55. //	from what I've been able to determine.

  56. 

  57. // WARNING:

  58. //	This code is really experimental. It was written in response to some people

  59. //	asking for a servo driver, however while it works, there is too much

  60. //	jitter to successfully drive a small servo - I have tried it with a micro

  61. //	servo and it worked, but the servo ran hot due to the jitter in the signal

  62. //	being sent to it.

  63. //

  64. //	If you want servo control for the Pi, then use the servoblaster kernel

  65. //	module.

  66. 

  67. #define	MAX_SERVOS	8

  68. 

  69. static int pinMap     [MAX_SERVOS] ;	// Keep track of our pins

  70. static int pulseWidth [MAX_SERVOS] ;	// microseconds

  71. 

  72. 

  73. /*

  74.  * softServoThread:

  75.  *	Thread to do the actual Servo PWM output

  76.  *********************************************************************************

  77.  */

  78. 

  79. static PI_THREAD (softServoThread)

  80. {

  81.   register int i, j, k, m, tmp ;

  82.   int lastDelay, pin, servo ;

  83. 

  84.   int myDelays [MAX_SERVOS] ;

  85.   int myPins   [MAX_SERVOS] ;

  86. 

  87.   struct timeval  tNow, tStart, tPeriod, tGap, tTotal ;

  88.   struct timespec tNs ;

  89. 

  90.   tTotal.tv_sec  =    0 ;

  91.   tTotal.tv_usec = 8000 ;

  92. 

  93.   piHiPri (50) ;

  94. 

  95.   for (;;)

  96.   {

  97.     gettimeofday (&tStart, NULL) ;

  98. 

  99.     memcpy (myDelays, pulseWidth, sizeof (myDelays)) ;

  100.     memcpy (myPins,   pinMap,     sizeof (myPins)) ;

  101. 

  102. // Sort the delays (& pins), shortest first

  103. 

  104.     for (m = MAX_SERVOS / 2 ; m > 0 ; m /= 2 )

  105.       for (j = m ; j < MAX_SERVOS ; ++j)

  106. 	for (i = j - m ; i >= 0 ; i -= m)

  107. 	{

  108. 	  k = i + m ;

  109. 	  if (myDelays [k] >= myDelays [i])

  110. 	    break ;

  111. 	  else // Swap

  112. 	  {

  113. 	    tmp = myDelays [i] ; myDelays [i] = myDelays [k] ; myDelays [k] = tmp ;

  114. 	    tmp = myPins   [i] ; myPins   [i] = myPins   [k] ; myPins   [k] = tmp ;

  115. 	  }

  116. 	}

  117. 

  118. // All on

  119. 

  120.     lastDelay = 0 ;

  121.     for (servo = 0 ; servo < MAX_SERVOS ; ++servo)

  122.     {

  123.       if ((pin = myPins [servo]) == -1)

  124. 	continue ;

  125. 

  126.       digitalWrite (pin, HIGH) ;

  127.       myDelays [servo] = myDelays [servo] - lastDelay ;

  128.       lastDelay += myDelays [servo] ;

  129.     }

  130. 

  131. // Now loop, turning them all off as required

  132. 

  133.     for (servo = 0 ; servo < MAX_SERVOS ; ++servo)

  134.     {

  135.       if ((pin = myPins [servo]) == -1)

  136. 	continue ;

  137. 

  138.       delayMicroseconds (myDelays [servo]) ;

  139.       digitalWrite (pin, LOW) ;

  140.     }

  141. 

  142. // Wait until the end of an 8mS time-slot

  143. 

  144.     gettimeofday (&tNow, NULL) ;

  145.     timersub (&tNow, &tStart, &tPeriod) ;

  146.     timersub (&tTotal, &tPeriod, &tGap) ;

  147.     tNs.tv_sec  = tGap.tv_sec ;

  148.     tNs.tv_nsec = tGap.tv_usec * 1000 ;

  149.     nanosleep (&tNs, NULL) ;

  150.   }

  151. 

  152.   return NULL ;

  153. }

  154. 

  155. 

  156. /*

  157.  * softServoWrite:

  158.  *	Write a Servo value to the given pin

  159.  *********************************************************************************

  160.  */

  161. 

  162. void softServoWrite (int servoPin, int value)

  163. {

  164.   int servo ;

  165. 

  166.   servoPin &= 63 ;

  167. 

  168.   /**/ if (value < -250)

  169.     value = -250 ;

  170.   else if (value > 1250)

  171.     value = 1250 ;

  172. 

  173.   for (servo = 0 ; servo < MAX_SERVOS ; ++servo)

  174.     if (pinMap [servo] == servoPin)

  175.       pulseWidth [servo] = value + 1000 ; // uS

  176. }

  177. 

  178. 

  179. /*

  180.  * softServoSetup:

  181.  *	Setup the software servo system

  182.  *********************************************************************************

  183.  */

  184. 

  185. int softServoSetup (int p0, int p1, int p2, int p3, int p4, int p5, int p6, int p7)

  186. {

  187.   int servo ;

  188. 

  189.   if (p0 != -1) { pinMode (p0, OUTPUT) ; digitalWrite (p0, LOW) ; }

  190.   if (p1 != -1) { pinMode (p1, OUTPUT) ; digitalWrite (p1, LOW) ; }

  191.   if (p2 != -1) { pinMode (p2, OUTPUT) ; digitalWrite (p2, LOW) ; }

  192.   if (p3 != -1) { pinMode (p3, OUTPUT) ; digitalWrite (p3, LOW) ; }

  193.   if (p4 != -1) { pinMode (p4, OUTPUT) ; digitalWrite (p4, LOW) ; }

  194.   if (p5 != -1) { pinMode (p5, OUTPUT) ; digitalWrite (p5, LOW) ; }

  195.   if (p6 != -1) { pinMode (p6, OUTPUT) ; digitalWrite (p6, LOW) ; }

  196.   if (p7 != -1) { pinMode (p7, OUTPUT) ; digitalWrite (p7, LOW) ; }

  197. 

  198.   pinMap [0] = p0 ;

  199.   pinMap [1] = p1 ;

  200.   pinMap [2] = p2 ;

  201.   pinMap [3] = p3 ;

  202.   pinMap [4] = p4 ;

  203.   pinMap [5] = p5 ;

  204.   pinMap [6] = p6 ;

  205.   pinMap [7] = p7 ;

  206. 

  207.   for (servo = 0 ; servo < MAX_SERVOS ; ++servo)

  208.     pulseWidth [servo] = 1500 ;		// Mid point

  209.   

  210.   return piThreadCreate (softServoThread) ;

  211. }