RTOS enabled i2c-driver based on the official i2c-C-api.

Dependencies:   mbed-rtos

Fork of mbed-RtosI2cDriver by Helmut Schmücker

I2cRtosDriver

Overview

  • Based on RTOS
    • Less busy wait waste of CPU cycles
    • ... but some waste of CPU cycles by context switches
    • Frees up to 80% of CPU resources
  • Fixes the bug described in https://mbed.org/forum/bugs-suggestions/topic/4128/
  • Spends minimal time in interrupt context
  • Supports I2C Master and Slave mode
  • Interface compatible to official I2C lib
  • Supports LPC1768 and LPC11U24.
  • Reuses parts of the official I2C implementation
  • The test and example programs work quite well and the results look promising. But this is by no means a thoroughly regression tested library. There might be some surprises left.
  • If you want to avoid the RTOS overhead MODI2C might be a better choice.

Usage

  • In existing projects simply replace in the I2C interface class declaration the official type by one of the adapters I2CMasterRtos or I2CSlaveRtos described below. The behavior should be the same.
  • You can also use the I2CDriver interface directly.
  • You can create several instances of I2CMasterRtos, I2CSlaveRtos and I2CDriver. The interface classes are lightweight and work in parallel.
  • See also the tests/examples in I2CDriverTest01.h - I2CDriverTest05.h
  • The I2CDriver class is the central interface
    • I2CDriver provides a "fat" API for I2C master and slave access
    • It supports on the fly changes between master and slave mode.
    • All requests are blocking. Other threads might do their work while the calling thread waits for the i2c requests to be completed.
    • It ensures mutual exclusive access to the I2C HW.
      • This is realized by a static RTOS mutex for each I2C channel. The mutex is taken by the calling thread on any call of an I2CDriver-function.
      • Thus accesses are prioritized automatically by the priority of the calling user threads.
      • Once having access to the interface the requests are performed with high priority and cannot be interrupted by other threads.
      • Optionally the interface can be locked manually. Useful if one wants to perform a sequence of commands without interruption.
  • I2CMasterRtos and I2CSlaveRtos provide an interface compatible to the official mbed I2C interface. Additionally
    • the constructors provide parameters for defining the frequency and the slave address
    • I2CMasterRtos provides a function to read data from a given slave register
    • In contrast to the original interface the I2CSlaveRtos::receive() function is blocking, i.e it returns, when the master sends a request to the listening slave. There is no need to poll the receive status in a loop. Optionally a timeout value can be passed to the function.
    • The stop function provides a timeout mechanism and returns the status. Thus if someone on the bus inhibits the creation of a stop condition by keeping the scl or the sda line low the mbed master won't get freezed.
    • The interface adapters are implemented as object adapters, i.e they hold an I2CDriver-instance, to which they forward the user requests by simple inline functions. The overhead is negligible.

Design

The i2c read and write sequences have been realized in an interrupt service routine. The communicaton between the calling thread and the ISR is realized by a simple static transfer struct and a semaphore ... see i2cRtos_api.c
The start and stop functions still use the busy wait approach. They are not entered that frequently and usually they take less than 12µs at 100kHz bus speed. At 400kHz even less time is consumed. Thus there wouldn't be much benefit if one triggers the whole interrupt/task wait/switch sequence for that short period of time.

Performance

The following performance data have been measured with the small test applications in I2CDriverTest01.h and I2CDriverTest04.h . In these applications a high priority thread, triggered at a rate of 1kHz, reads on each trigger a data packet of given size with given I2C bus speed from a SRF08 ultra sonic ranger or a MPU6050 accelerometer/gyro. At the same time the main thread - running at a lower priority - counts in an endless loop adjacent increments of the mbed's µs-ticker API and calculates a duty cycle from this. These duty cycle measurements are shown in the table below together with the time measured for one read sequence (write address+register; write address and read x byte of data). The measurements have been performed with the ISR/RTOS approach used by this driver and with the busy wait approach used by the official mbed I2C implementation. The i2c implementation can be selected via #define PREFIX in I2CDriver.cpp.

  • The time for one read cycle is almost the same for both approaches
  • At full load the duty cycle of the low priority thread drops almost to zero for the busy wait approach, whereas with the RTOS/ISR enabled driver it stays at 80%-90% on the LPC1768 and above 65% on the LPC11U24.
  • => Especially at low bus speeds and/or high data transfer loads the driver is able to free a significant amount of CPU time.
LPC17681byte/ms4byte/ms6byte/ms1byte/ms6byte/ms12byte/ms25byte/ms
SRF08@ 100kHz@ 100kHz@ 100kHz@ 400kHz@ 400kHz@ 400kHz@ 400kHz
rtos/ISRDC[%]91.791.090.593.391.990.386.8
t[µs]421714910141314518961
busy waitDC[%]57.127.78.185.868.748.23.8
t[µs]415710907128299503949
LPC17681byte/ms4byte/ms7byte/ms1byte/ms6byte/ms12byte/ms36byte/ms
MPU6050@ 100kHz@ 100kHz@ 100kHz@ 400kHz@ 400kHz@ 400kHz@ 400kHz
rtos/ISRDC[%]91.590.789.393.091.690.084.2
t[µs]415687959133254398977
busy waitDC[%]57.730.53.386.574.359.71.2
t[µs]408681953121243392974
LPC11U241byte/ms6byte/ms1byte/ms6byte/ms23byte/ms
SRF08@ 100kHz@ 100kHz@ 400kHz@ 400kHz@ 400kHz
rtos/ISRDC[%]79.277.581.178.771.4
t[µs]474975199374978
busy waitDC[%]51.82.480.5633.3
t[µs]442937156332928
LPC11U241byte/ms6byte/ms1byte/ms6byte/ms32byte/ms
MPU6050@ 100kHz@ 100kHz@ 400kHz@ 400kHz@ 400kHz
rtos/ISRDC[%]79.176.881.078.667.1
t[µs]466922188316985
busy waitDC[%]52.87.281.769.87.4
t[µs]433893143268895
Committer:
humlet
Date:
Fri Apr 19 21:33:29 2013 +0000
Revision:
3:967dde37e712
Child:
4:eafa7efcd771
refactored, compiles and crashes

Who changed what in which revision?

UserRevisionLine numberNew contents of line
humlet 3:967dde37e712 1 #include "mbed.h"
humlet 3:967dde37e712 2 #include "rtos.h"
humlet 3:967dde37e712 3 #include "I2CMasterRtos.h"
humlet 3:967dde37e712 4 #include "I2CSlaveRtos.h"
humlet 3:967dde37e712 5
humlet 3:967dde37e712 6 const int freq = 100000;
humlet 3:967dde37e712 7 const int adr = 42;
humlet 3:967dde37e712 8 const int len=42;
humlet 3:967dde37e712 9 const char* cMsg="We are mbed, resistance is futile";
humlet 3:967dde37e712 10
humlet 3:967dde37e712 11 static void rxMsg(I2CSlaveRtos& slv)
humlet 3:967dde37e712 12 {
humlet 3:967dde37e712 13 char rMsg[len];
humlet 3:967dde37e712 14 memset(rMsg,0,len);
humlet 3:967dde37e712 15 if ( slv.receive() == I2CSlave::WriteAddressed) {
humlet 3:967dde37e712 16 slv.read(rMsg, len); // have to add 1 byte for the address (bug report!)
humlet 3:967dde37e712 17 printf("thread %d received message '%s'\n",Thread::gettid(),rxMsg);
humlet 3:967dde37e712 18 } else
humlet 3:967dde37e712 19 printf("god damned nation");
humlet 3:967dde37e712 20 }
humlet 3:967dde37e712 21
humlet 3:967dde37e712 22 static void txMsg(I2CMasterRtos& mst)
humlet 3:967dde37e712 23 {
humlet 3:967dde37e712 24 mst.write(adr,cMsg,len);
humlet 3:967dde37e712 25 printf("thread %d has sent the message\n",Thread::gettid());
humlet 3:967dde37e712 26 }
humlet 3:967dde37e712 27
humlet 3:967dde37e712 28 static void channel1(void const *args)
humlet 3:967dde37e712 29 {
humlet 3:967dde37e712 30 I2CMasterRtos mst(p9,p10,freq);
humlet 3:967dde37e712 31 I2CSlaveRtos slv(p9,p10,freq,adr);
humlet 3:967dde37e712 32 while(1) {
humlet 3:967dde37e712 33 rxMsg(slv);
humlet 3:967dde37e712 34 Thread::wait(100);
humlet 3:967dde37e712 35 txMsg(mst);
humlet 3:967dde37e712 36 Thread::wait(100);
humlet 3:967dde37e712 37 }
humlet 3:967dde37e712 38 }
humlet 3:967dde37e712 39
humlet 3:967dde37e712 40 void channel2(void const *args)
humlet 3:967dde37e712 41 {
humlet 3:967dde37e712 42 I2CMasterRtos mst(p28,p27,freq);
humlet 3:967dde37e712 43 I2CSlaveRtos slv(p28,p27,freq,adr);
humlet 3:967dde37e712 44 while(1) {
humlet 3:967dde37e712 45 txMsg(mst);
humlet 3:967dde37e712 46 Thread::wait(100);
humlet 3:967dde37e712 47 rxMsg(slv);
humlet 3:967dde37e712 48 Thread::wait(100);
humlet 3:967dde37e712 49 }
humlet 3:967dde37e712 50 }
humlet 3:967dde37e712 51
humlet 3:967dde37e712 52 int doit()
humlet 3:967dde37e712 53 {
humlet 3:967dde37e712 54 Thread selftalk01(channel1,0,osPriorityAboveNormal);
humlet 3:967dde37e712 55 Thread selftalk02(channel2,0,osPriorityAboveNormal);
humlet 3:967dde37e712 56
humlet 3:967dde37e712 57 uint32_t cnt=0;
humlet 3:967dde37e712 58 while (++cnt<5) {
humlet 3:967dde37e712 59 const uint32_t dt=1e6;
humlet 3:967dde37e712 60 uint32_t tStart = us_ticker_read();
humlet 3:967dde37e712 61 uint32_t tLast = tStart;
humlet 3:967dde37e712 62 uint32_t tAct = tStart;
humlet 3:967dde37e712 63 uint32_t tMe=0;
humlet 3:967dde37e712 64 do {
humlet 3:967dde37e712 65 tAct=us_ticker_read();
humlet 3:967dde37e712 66 if(tAct>tLast) {
humlet 3:967dde37e712 67 if(tAct==tLast+1)++tMe;
humlet 3:967dde37e712 68 }
humlet 3:967dde37e712 69 tLast=tAct;
humlet 3:967dde37e712 70 } while(tAct-tStart<dt);
humlet 3:967dde37e712 71 printf("dc=%5.2f \n", 100.0*(float)tMe/dt);
humlet 3:967dde37e712 72 }
humlet 3:967dde37e712 73 return 0;
humlet 3:967dde37e712 74 }
humlet 3:967dde37e712 75