Avnet / easy-connect-wnc

Added support for the WNC M14A2A Cellular LTE Data Module.

Dependencies:   WNC14A2AInterface

Easy Connect

Easily add all supported connectivity methods to your mbed OS project

This project is derived from https://developer.mbed.org/teams/sandbox/code/simple-mbed-client-example/file/dd6231df71bb/easy-connect.lib. It give user the ability to switch between connectivity methods and includes support for the WNC14A2A Data Module. The `NetworkInterface` API makes this easy, but you still need a mechanism for the user to select the connection method, The selection is made by modifying the `mbed_app.json` file and using `easy_connect()` from your application.

Specifying connectivity method

To add support for the WNC14A2A, add the following to your ``mbed_app.json`` file:

mbed_app.json

{
    "config": {
        "network-interface":{
            "help": "options are ETHERNET,WIFI_ESP8266,WIFI_ODIN,MESH_LOWPAN_ND,MESH_THREAD,WNC14A2A",
            "value": "WNC14A2A"
        }
    },
}

After you choose `WNC14A2A` you'll also need to indicate if you want debug output or not by Enabling (true) or Disabling (false) WNC_DEBUG.

If WNC_DEBUG is enabled, there are 3 different levels of debug output (selected via bit settings). These debug levels are set using the following values:

ValueDescription
1Basic WNC driver debug output
2Comprehensive WNC driver debug output
4Network Layer debug output

You can have any combination of these three bit values for a total value of 0 – 7.

WNC Debug Settings

    "config": {
        "WNC_DEBUG": {
            "value": false
        },
        "WNC_DEBUG_SETTING": {
            "value": 4
        },
    }

Using Easy Connect from your application

Easy Connect has just one function which will either return a `NetworkInterface`-pointer or `NULL`:

Sample Code

#include "easy-connect.h"

int main(int, char**) {
    NetworkInterface* network = easy_connect(true); /* has 1 argument, enable_logging (pass in true to log to serial port) */
    if (!network) {
        printf("Connecting to the network failed... See serial output.\r\n");
        return 1;
    }
 
    // Rest of your program
}

Tested on

  • K64F with Ethernet.
  • AT&T Cellular IoT Starter Kit with WNC M14A2A Cellular Data Module

The WNCInterface class currently supports the following version(s):

  • MPSS: M14A2A_v11.50.164451 APSS: M14A2A_v11.53.164451

License

This library is released under the Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License and may obtain a copy of the License at

http://www.apache.org/licenses/LICENSE-2.0

Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License.

stm-spirit1-rf-driver/source/libs/spirit1/SPIRIT1_Library/Src/SPIRIT_Csma.c

Committer:
group-Avnet
Date:
2017-04-19
Revision:
0:478cfd88041f

File content as of revision 0:478cfd88041f:

/**
  ******************************************************************************
  * @file    SPIRIT_Csma.c
  * @author  VMA division - AMS
  * @version 3.2.2
  * @date    08-July-2015
  * @brief   Configuration and management of SPIRIT CSMA.
  * @details
  * @attention
  *
  * <h2><center>&copy; COPYRIGHT(c) 2015 STMicroelectronics</center></h2>
  *
  * Redistribution and use in source and binary forms, with or without modification,
  * are permitted provided that the following conditions are met:
  *   1. Redistributions of source code must retain the above copyright notice,
  *      this list of conditions and the following disclaimer.
  *   2. Redistributions in binary form must reproduce the above copyright notice,
  *      this list of conditions and the following disclaimer in the documentation
  *      and/or other materials provided with the distribution.
  *   3. Neither the name of STMicroelectronics nor the names of its contributors
  *      may be used to endorse or promote products derived from this software
  *      without specific prior written permission.
  *
  * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
  * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
  * DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE
  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
  * SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
  * CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
  * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
  * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
  *
  ******************************************************************************
  */

/* Includes ------------------------------------------------------------------*/
#include "SPIRIT_Csma.h"
#include "MCU_Interface.h"


/**
 * @addtogroup SPIRIT_Libraries
 * @{
 */


/**
 * @addtogroup SPIRIT_Csma
 * @{
 */


/**
 * @defgroup Csma_Private_TypesDefinitions      CSMA Private TypesDefinitions
 * @{
 */


/**
 *@}
 */


/**
 * @defgroup Csma_Private_Defines               CSMA Private Defines
 * @{
 */

/**
 *@}
 */


/**
 * @defgroup Csma_Private_Macros               CSMA Private Macros
 * @{
 */

/**
 *@}
 */


/**
 * @defgroup Csma_Private_Variables             CSMA Private Variables
 * @{
 */

/**
 *@}
 */



/**
 * @defgroup Csma_Private_FunctionPrototypes    CSMA Private FunctionPrototypes
 * @{
 */

/**
 *@}
 */


/**
 * @defgroup Csma_Private_Functions             CSMA Private Functions
 * @{
 */


/**
 * @brief  Initializes the SPIRIT CSMA according to the specified parameters in the CsmaInit.
 * @param  pxCsmaInit Csma init structure.
 *         This parameter is a pointer to @ref CsmaInit.
 * @retval None.
 */
void SpiritCsmaInit(CsmaInit* pxCsmaInit)
{
  uint8_t tempRegValue[5];

  /* Check the parameters */
  s_assert_param(IS_SPIRIT_FUNCTIONAL_STATE(pxCsmaInit->xCsmaPersistentMode));
  s_assert_param(IS_CCA_PERIOD(pxCsmaInit->xMultiplierTbit));
  s_assert_param(IS_CSMA_LENGTH(pxCsmaInit->xCcaLength));
  s_assert_param(IS_BU_COUNTER_SEED(pxCsmaInit->nBuCounterSeed));
  s_assert_param(IS_BU_PRESCALER(pxCsmaInit->cBuPrescaler));
  s_assert_param(IS_CMAX_NB(pxCsmaInit->cMaxNb));

  /* CSMA BU counter seed (MSB) config */
  tempRegValue[0] = (uint8_t)(pxCsmaInit->nBuCounterSeed >> 8);

  /* CSMA BU counter seed (LSB) config */
  tempRegValue[1] = (uint8_t) pxCsmaInit->nBuCounterSeed;

  /* CSMA BU prescaler config and CCA period config */
  tempRegValue[2] = (pxCsmaInit->cBuPrescaler << 2) | pxCsmaInit->xMultiplierTbit;

  /* CSMA CCA length config and max number of back-off */
  tempRegValue[3] = (pxCsmaInit->xCcaLength | pxCsmaInit->cMaxNb);

  /* Reads the PROTOCOL1_BASE register value, to write the SEED_RELOAD and CSMA_PERS_ON fields */
  g_xStatus = SpiritSpiReadRegisters(PROTOCOL1_BASE, 1, &tempRegValue[4]);

  /* Writes the new value for persistent mode */
  if(pxCsmaInit->xCsmaPersistentMode==S_ENABLE)
  {
    tempRegValue[4] |= PROTOCOL1_CSMA_PERS_ON_MASK;
  }
  else
  {
    tempRegValue[4] &= ~PROTOCOL1_CSMA_PERS_ON_MASK;
  }

  /* Writes PROTOCOL1_BASE register */
  g_xStatus = SpiritSpiWriteRegisters(PROTOCOL1_BASE, 1, &tempRegValue[4]);

  /* Writes CSMA_CONFIGx_BASE registers */
  g_xStatus = SpiritSpiWriteRegisters(CSMA_CONFIG3_BASE, 4, tempRegValue);

}


 /**
  * @brief  Returns the fitted structure CsmaInit starting from the registers values.
  * @param  pxCsmaInit Csma structure to be fitted.
  *         This parameter is a pointer to @ref CsmaInit.
  * @retval None.
  */
void SpiritCsmaGetInfo(CsmaInit* pxCsmaInit)
{
   uint8_t tempRegValue[5];

   /* Reads PROTOCOL1_BASE register */
   g_xStatus = SpiritSpiReadRegisters(PROTOCOL1_BASE, 1, &tempRegValue[4]);

   /* Reads CSMA_CONFIGx_BASE registers */
   g_xStatus = SpiritSpiReadRegisters(CSMA_CONFIG3_BASE, 4, tempRegValue);

   /* Reads the bu counter seed */
   pxCsmaInit->nBuCounterSeed = (uint16_t)tempRegValue[1] | ((uint16_t)(tempRegValue[0] << 8));

   /* Reads the bu prescaler */
   pxCsmaInit->cBuPrescaler = tempRegValue[2]>>2;

   /* Reads the Cca period */
   pxCsmaInit->xMultiplierTbit = (CcaPeriod)(tempRegValue[2] & 0x03);

   /* Reads the Cca length */
   pxCsmaInit->xCcaLength = (CsmaLength)(tempRegValue[3]&0xF0);

   /* Reads the max number of back off */
   pxCsmaInit->cMaxNb = tempRegValue[3] & 0x07;

   /* Reads the persistent mode enable bit */
   pxCsmaInit->xCsmaPersistentMode = (SpiritFunctionalState)((tempRegValue[4]>>1) & 0x01);

}


/**
 * @brief  Enables or Disables the CSMA.
 * @param  xNewState the state of the CSMA mode.
 *         This parameter can be: S_ENABLE or S_DISABLE.
 * @retval None.
 */
void SpiritCsma(SpiritFunctionalState xNewState)
{
  uint8_t tempRegValue;

  /* Check the parameters */
  s_assert_param(IS_SPIRIT_FUNCTIONAL_STATE(xNewState));

  /* Reads the PROTOCOL1 register value */
  g_xStatus = SpiritSpiReadRegisters(PROTOCOL1_BASE, 1, &tempRegValue);

  /* Sets or resets the CSMA enable bit */
  if(xNewState==S_ENABLE)
  {
    tempRegValue |= PROTOCOL1_CSMA_ON_MASK;
  }
  else
  {
    tempRegValue &= ~PROTOCOL1_CSMA_ON_MASK;
  }

  /* Writes the new value on the PROTOCOL1 register */
  g_xStatus = SpiritSpiWriteRegisters(PROTOCOL1_BASE, 1, &tempRegValue);

}

/**
 * @brief  Gets the CSMA mode. Says if it is enabled or disabled.
 * @param  None.
 * @retval SpiritFunctionalState: CSMA mode.
 */
SpiritFunctionalState SpiritCsmaGetCsma(void)
{
  uint8_t tempRegValue;

  /* Reads the PROTOCOL1 register value */
  g_xStatus = SpiritSpiReadRegisters(PROTOCOL1_BASE, 1, &tempRegValue);

  /* Return if set or reset */
  if(tempRegValue & PROTOCOL1_CSMA_ON_MASK)
  {
    return S_ENABLE;
  }
  else
  {
    return S_DISABLE;
  }

}

/**
 * @brief  Enables or Disables the persistent CSMA mode.
 * @param  xNewState the state of the persistent CSMA mode.
 *         This parameter can be: S_ENABLE or S_DISABLE.
 * @retval None.
 */
void SpiritCsmaPersistentMode(SpiritFunctionalState xNewState)
{
  uint8_t tempRegValue;

  /* Check the parameters */
  s_assert_param(IS_SPIRIT_FUNCTIONAL_STATE(xNewState));

  /* Reads the PROTOCOL1 register value */
  g_xStatus = SpiritSpiReadRegisters(PROTOCOL1_BASE, 1, &tempRegValue);

  /* Enables/disables the CSMA persistent mode */
  if(xNewState==S_ENABLE)
  {
    tempRegValue |= PROTOCOL1_CSMA_PERS_ON_MASK;
  }
  else
  {
    tempRegValue &= ~PROTOCOL1_CSMA_PERS_ON_MASK;
  }

  /* Writes the new vaue on the PROTOCOL1 register */
  g_xStatus = SpiritSpiWriteRegisters(PROTOCOL1_BASE, 1, &tempRegValue);

}


/**
 * @brief  Gets the persistent CSMA mode.
 * @param  None.
 * @retval SpiritFunctionalState: CSMA persistent mode.
 */
SpiritFunctionalState SpiritCsmaGetPersistentMode(void)
{
  uint8_t tempRegValue;

  /* Reads the PROTOCOL1 register value */
  g_xStatus = SpiritSpiReadRegisters(PROTOCOL1_BASE, 1, &tempRegValue);

  /* Return if set or reset */
  if(tempRegValue & PROTOCOL1_CSMA_PERS_ON_MASK)
  {
    return S_ENABLE;
  }
  else
  {
    return S_DISABLE;
  }

}


/**
 * @brief  Enables or Disables the seed reload mode (if enabled it reloads the back-off generator seed using the value written in the BU_COUNTER_SEED register).
 * @param  xNewState the state of the seed reload mode.
 *	   This parameter can be: S_ENABLE or S_DISABLE.
 * @retval None.
 */
void SpiritCsmaSeedReloadMode(SpiritFunctionalState xNewState)
{
  uint8_t tempRegValue;

  /* Check the parameters */
  s_assert_param(IS_SPIRIT_FUNCTIONAL_STATE(xNewState));

  /* Reads the PROTOCOL1 register value */
  g_xStatus = SpiritSpiReadRegisters(PROTOCOL1_BASE, 1, &tempRegValue);

  /* Enables/disables the seed reload mode */
  if(xNewState==S_ENABLE)
  {
    tempRegValue |= PROTOCOL1_SEED_RELOAD_MASK;
  }
  else
  {
    tempRegValue &= ~PROTOCOL1_SEED_RELOAD_MASK;
  }

  /* Writes the new value on the PROTOCOL1 register */
  g_xStatus = SpiritSpiWriteRegisters(PROTOCOL1_BASE, 1, &tempRegValue);

}


/**
 * @brief  Gets the seed reload mode.
 * @param  None.
 * @retval SpiritFunctionalState: CSMA seed reload mode.
 */
SpiritFunctionalState SpiritCsmaGetSeedReloadMode(void)
{
  uint8_t tempRegValue;

  /* Reads the PROTOCOL1 register value */
  g_xStatus = SpiritSpiReadRegisters(PROTOCOL1_BASE, 1, &tempRegValue);

  /* Return if set or reset */
  if(tempRegValue & PROTOCOL1_SEED_RELOAD_MASK)
  {
    return S_ENABLE;
  }
  else
  {
    return S_DISABLE;
  }
}


/**
 * @brief  Sets the BU counter seed (BU_COUNTER_SEED register). The CSMA back off time is given by the formula: BO = rand(2^NB)*BU.
 * @param  nBuCounterSeed seed of the random number generator used to apply the BBE algorithm.
 *	   This parameter is an uint16_t.
 * @retval None.
 */
void SpiritCsmaSetBuCounterSeed(uint16_t nBuCounterSeed)
{
  uint8_t tempRegValue[2];

  /* Check parameters */
  s_assert_param(IS_BU_COUNTER_SEED(nBuCounterSeed));

  /* Build value (MSB)*/
  tempRegValue[0]=(uint8_t)(nBuCounterSeed>>8);
  /* Build value (LSB) */
  tempRegValue[1]=(uint8_t)nBuCounterSeed;

  /* Writes the CSMA_CONFIG3 registers */
  g_xStatus = SpiritSpiWriteRegisters(CSMA_CONFIG3_BASE, 2, tempRegValue);

}

/**
 * @brief  Returns the BU counter seed (BU_COUNTER_SEED register).
 * @param  None.
 * @retval uint16_t Seed of the random number generator used to apply the BBE algorithm.
 */
uint16_t SpiritCsmaGetBuCounterSeed(void)
{
  uint8_t tempRegValue[2];

  /* Reads the CSMA_CONFIGx registers value */
  g_xStatus = SpiritSpiReadRegisters(CSMA_CONFIG3_BASE, 2, tempRegValue);

  /* Build the counter seed and return it */
  return ((uint16_t)tempRegValue[1] + (((uint16_t)tempRegValue[0])<<8));

}


/**
 * @brief  Sets the BU prescaler. The CSMA back off time is given by the formula: BO = rand(2^NB)*BU.
 * @param  cBuPrescaler used to program the back-off unit BU.
 * 	   This parameter is an uint8_t.
 * @retval None.
 */
void SpiritCsmaSetBuPrescaler(uint8_t cBuPrescaler)
{
  uint8_t tempRegValue;

  /* Check parameters */
  s_assert_param(IS_BU_PRESCALER(cBuPrescaler));

  /* Reads the CSMA_CONFIG1 register value */
  g_xStatus = SpiritSpiReadRegisters(CSMA_CONFIG1_BASE, 1, &tempRegValue);

  /* Build the new value for the BU prescaler */
  tempRegValue &= 0x03;
  tempRegValue |= (cBuPrescaler<<2);

  /* Writes the new value on the CSMA_CONFIG1_BASE register */
  g_xStatus = SpiritSpiWriteRegisters(CSMA_CONFIG1_BASE, 1, &tempRegValue);

}


/**
 * @brief  Returns the BU prescaler.
 * @param  None.
 * @retval uint8_t Value back-off unit (BU).
 */
uint8_t SpiritCsmaGetBuPrescaler(void)
{
  uint8_t tempRegValue;

  /* Reads the CSMA_CONFIG1 register value */
  g_xStatus = SpiritSpiReadRegisters(CSMA_CONFIG1_BASE, 1, &tempRegValue);

  /* Build and return the BU prescaler value */
  return (tempRegValue >> 2);

}


/**
 * @brief  Sets the CCA period.
 * @param  xMultiplierTbit value of CCA period to store.
 * 	   This parameter can be a value of @ref CcaPeriod.
 * @retval None.
 */
void SpiritCsmaSetCcaPeriod(CcaPeriod xMultiplierTbit)
{
  uint8_t tempRegValue;

  /* Check the parameters */
  s_assert_param(IS_CCA_PERIOD(xMultiplierTbit));

  /* Reads the CSMA_CONFIG1 register value */
  g_xStatus = SpiritSpiReadRegisters(CSMA_CONFIG1_BASE, 1, &tempRegValue);

  /* Build the new value setting the the CCA period */
  tempRegValue &= 0xFC;
  tempRegValue |= xMultiplierTbit;

  /* Writes the new value on the CSMA_CONFIG1 register */
  g_xStatus = SpiritSpiWriteRegisters(CSMA_CONFIG1_BASE, 1, &tempRegValue);

}


/**
 * @brief  Returns the CCA period.
 * @param  None.
 * @retval CcaPeriod CCA period.
 */
CcaPeriod SpiritCsmaGetCcaPeriod(void)
{
  uint8_t tempRegValue;

  /* Reads the CSMA_CONFIG1 register value */
  g_xStatus = SpiritSpiReadRegisters(CSMA_CONFIG1_BASE, 1, &tempRegValue);

  /* Build and return the CCA period value */
  return (CcaPeriod)(tempRegValue & 0x03);

}


/**
 * @brief  Sets the CCA length.
 * @param  xCcaLength the CCA length (a value between 1 and 15 that multiplies the CCA period).
 *	   This parameter can be any value of @ref CsmaLength.
 * @retval None.
 */
void SpiritCsmaSetCcaLength(CsmaLength xCcaLength)
{
  uint8_t tempRegValue;

  /* Check the parameters */
  s_assert_param(IS_CSMA_LENGTH(xCcaLength));

  /* Reads the CSMA_CONFIG0 register value */
  g_xStatus = SpiritSpiReadRegisters(CSMA_CONFIG0_BASE, 1, &tempRegValue);

  /* Build the value of CCA length to be set */
  tempRegValue &= 0x0F;
  tempRegValue |= xCcaLength;

  /* Writes the new value on the CSMA_CONFIG0 register */
  g_xStatus = SpiritSpiWriteRegisters(CSMA_CONFIG0_BASE, 1, &tempRegValue);

}


/**
 * @brief  Returns the CCA length.
 * @param  None.
 * @retval uint8_t CCA length.
 */
uint8_t SpiritCsmaGetCcaLength(void)
{
  uint8_t tempRegValue;

  /* Reads the CSMA_CONFIG0 register value */
  g_xStatus = SpiritSpiReadRegisters(CSMA_CONFIG0_BASE, 1, &tempRegValue);

  /* Build and return the CCA length */
  return tempRegValue >> 4;

}


/**
 * @brief  Sets the max number of back-off. If reached Spirit stops the transmission.
 * @param  cMaxNb the max number of back-off.
 *         This parameter is an uint8_t.
 * @retval None.
 */
void SpiritCsmaSetMaxNumberBackoff(uint8_t cMaxNb)
{
  uint8_t tempRegValue;

  /* Check the parameters */
  s_assert_param(IS_CMAX_NB(cMaxNb));

  /* Reads the CSMA_CONFIG0 register value */
  g_xStatus = SpiritSpiReadRegisters(CSMA_CONFIG0_BASE, 1, &tempRegValue);

  /* Build the value of max back off to be set */
  tempRegValue &= 0xF8;
  tempRegValue |= cMaxNb;

  /* Writes the new value on the CSMA_CONFIG0 register */
  g_xStatus = SpiritSpiWriteRegisters(CSMA_CONFIG0_BASE, 1, &tempRegValue);
}

/**
 * @brief  Returns the max number of back-off.
 * @param  None.
 * @retval uint8_t Max number of back-off.
 */
uint8_t SpiritCsmaGetMaxNumberBackoff(void)
{
  uint8_t tempRegValue;

  /* Reads the CSMA_CONFIG0 register value */
  g_xStatus = SpiritSpiReadRegisters(CSMA_CONFIG0_BASE, 1, &tempRegValue);

  /* Build and return the max number of back-off */
  return (tempRegValue & 0x07);

}


/**
 *@}
 */

/**
 *@}
 */


/**
 *@}
 */



/******************* (C) COPYRIGHT 2015 STMicroelectronics *****END OF FILE****/