This commit is contained in:
Jakob Meier 2021-04-27 17:36:05 +02:00
commit 0053879f51
84 changed files with 3360 additions and 1249 deletions

6
.gitmodules vendored
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@ -13,3 +13,9 @@
[submodule "thirdparty/lwgps"]
path = thirdparty/lwgps
url = https://github.com/rmspacefish/lwgps.git
[submodule "fsfw_hal"]
path = fsfw_hal
url = https://egit.irs.uni-stuttgart.de/fsfw/fsfw_hal.git
[submodule "generators/modgen"]
path = generators/modgen
url = https://git.ksat-stuttgart.de/source/modgen.git

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@ -40,6 +40,7 @@ set(TARGET_NAME ${CMAKE_PROJECT_NAME})
set(LIB_FSFW_NAME fsfw)
set(LIB_ETL_NAME etl)
set(LIB_CSP_NAME libcsp)
set(LIB_FSFW_HAL_NAME fsfw_hal)
set(LIB_LWGPS_NAME lwgps)
set(THIRD_PARTY_FOLDER thirdparty)
@ -50,12 +51,13 @@ set(TEST_PATH test/testtasks)
set(LINUX_PATH linux)
set(COMMON_PATH common)
set(FSFW_HAL_LIB_PATH fsfw_hal)
set(CSP_LIB_PATH ${THIRD_PARTY_FOLDER}/libcsp)
set(ETL_LIB_PATH ${THIRD_PARTY_FOLDER}/etl)
set(LWGPS_LIB_PATH ${THIRD_PARTY_FOLDER}/lwgps)
set(FSFW_WARNING_SHADOW_LOCAL_GCC OFF)
set(ADD_LINUX_FILES FALSE)
set(ADD_LINUX_FILES TRUE)
# Analyse different OS and architecture/target options, determine BSP_PATH,
# display information about compiler etc.
@ -68,10 +70,12 @@ if(TGT_BSP)
set(FSFW_CONFIG_PATH "fsfwconfig")
set(ADD_LINUX_FILES TRUE)
set(ADD_CSP_LIB TRUE)
set(FSFW_HAL_ADD_LINUX ON)
endif()
if(${TGT_BSP} MATCHES "arm/raspberrypi")
add_definitions(-DRASPBERRY_PI)
set(FSFW_HAL_ADD_RASPBERRY_PI ON)
endif()
if(${TGT_BSP} MATCHES "arm/q7s")
@ -113,6 +117,7 @@ add_subdirectory(${BSP_PATH})
add_subdirectory(${FSFW_PATH})
add_subdirectory(${MISSION_PATH})
add_subdirectory(${TEST_PATH})
add_subdirectory(${FSFW_HAL_LIB_PATH})
add_subdirectory(${COMMON_PATH})
################################################################################
@ -126,6 +131,7 @@ target_link_libraries(${TARGET_NAME} PRIVATE
${LIB_FSFW_NAME}
${LIB_OS_NAME}
${LIB_LWGPS_NAME}
${LIB_FSFW_HAL_NAME}
)
if(ADD_ETL_LIB)

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@ -198,6 +198,12 @@ IP address and path settings differ from machine to machine.
Open SSH connection to flatsat PC:
```sh
ssh eive@flatsat.eive.absatvirt.lw
```
or
```sh
ssh eive@2001:7c0:2018:1099:babe:0:e1fe:f1a5
```
@ -266,6 +272,16 @@ Then you can copy an `example` file like this
scp -P 1535 example root@localhost:/tmp
```
Copying a file from Q7S to flatsat PC
````
scp -P 22 root@192.168.133.10:/tmp/kernel-config /tmp
````
From a windows machine files can be copied with putty tools
````
pscp -scp -P 22 eive@192.168.199.227:</directory-to-example-file/>/example-file </windows-machine-path/>
````
## Launching an application at start-up
Load the root partiton from the flash memory (there are to nor-flash memories and each flash holds two xdi images).

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@ -11,13 +11,8 @@
#include <mission/core/GenericFactory.h>
#include <mission/utility/TmFunnel.h>
#ifdef LINUX
#include <fsfw/osal/linux/TcUnixUdpPollingTask.h>
#include <fsfw/osal/linux/TmTcUnixUdpBridge.h>
#elif WIN32
#include <fsfw/osal/windows/TcWinUdpPollingTask.h>
#include <fsfw/osal/windows/TmTcWinUdpBridge.h>
#endif
#include <fsfw/osal/common/UdpTcPollingTask.h>
#include <fsfw/osal/common/UdpTmTcBridge.h>
#include <fsfw/tmtcpacket/pus/TmPacketStored.h>
@ -45,17 +40,9 @@ void ObjectFactory::produce(){
Factory::setStaticFrameworkObjectIds();
ObjectFactory::produceGenericObjects();
#ifdef LINUX
new TmTcUnixUdpBridge(objects::UDP_BRIDGE,
new UdpTmTcBridge(objects::UDP_BRIDGE,
objects::CCSDS_PACKET_DISTRIBUTOR,
objects::TM_STORE, objects::TC_STORE);
new TcUnixUdpPollingTask(objects::UDP_POLLING_TASK, objects::UDP_BRIDGE);
#elif WIN32
new TmTcWinUdpBridge(objects::UDP_BRIDGE,
objects::CCSDS_PACKET_DISTRIBUTOR, objects::TM_STORE,
objects::TC_STORE);
new TcWinUdpPollingTask(objects::UDP_POLLING_TASK,
objects::UDP_BRIDGE);
#endif
new UdpTcPollingTask(objects::UDP_POLLING_TASK, objects::UDP_BRIDGE);
}

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@ -25,7 +25,31 @@ namespace gpioIds {
MGM_3_RM3100_CS,
TEST_ID_0,
TEST_ID_1
TEST_ID_1,
RTD_IC3,
RTD_IC4,
RTD_IC5,
RTD_IC6,
RTD_IC7,
RTD_IC8,
RTD_IC9,
RTD_IC10,
RTD_IC11,
RTD_IC12,
RTD_IC13,
RTD_IC14,
RTD_IC15,
RTD_IC16,
RTD_IC17,
RTD_IC18,
SPI_MUX_BIT_1,
SPI_MUX_BIT_2,
SPI_MUX_BIT_3,
SPI_MUX_BIT_4,
SPI_MUX_BIT_5,
SPI_MUX_BIT_6
};
}

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@ -8,6 +8,7 @@ add_subdirectory(boardconfig)
add_subdirectory(comIF)
add_subdirectory(devices)
add_subdirectory(boardtest)
add_subdirectory(gpio)

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@ -115,6 +115,10 @@ void initmission::initTasks() {
if(result != HasReturnvaluesIF::RETURN_OK) {
initmission::printAddObjectError("PUS_8", objects::PUS_SERVICE_8_FUNCTION_MGMT);
}
result = pusMedPrio->addComponent(objects::PUS_SERVICE_3_HOUSEKEEPING);
if(result!=HasReturnvaluesIF::RETURN_OK){
sif::error << "Object add component failed" << std::endl;
}
result = pusMedPrio->addComponent(objects::PUS_SERVICE_200_MODE_MGMT);
if(result != HasReturnvaluesIF::RETURN_OK) {
initmission::printAddObjectError("PUS_200", objects::PUS_SERVICE_200_MODE_MGMT);
@ -133,6 +137,7 @@ void initmission::initTasks() {
//TODO: Add handling of missed deadlines
/* Polling Sequence Table Default */
#if Q7S_ADD_SPI_TEST == 0
FixedTimeslotTaskIF * pollingSequenceTableTaskDefault = factory->createFixedTimeslotTask(
"PST_TASK_DEFAULT", 50, PeriodicTaskIF::MINIMUM_STACK_SIZE * 4, 3.0,
missedDeadlineFunc);
@ -140,6 +145,7 @@ void initmission::initTasks() {
if (result != HasReturnvaluesIF::RETURN_OK) {
sif::error << "InitMission::initTasks: Creating PST failed!" << std::endl;
}
#endif
#if TE0720 == 0
FixedTimeslotTaskIF* gomSpacePstTask = factory->
@ -151,13 +157,20 @@ void initmission::initTasks() {
}
#endif
PeriodicTaskIF* testTask = factory->createPeriodicTask(
"GPIOD_TEST", 60, PeriodicTaskIF::MINIMUM_STACK_SIZE, 1, missedDeadlineFunc);
#if OBSW_ADD_TEST_CODE == 1
PeriodicTaskIF* testTask = factory->createPeriodicTask(
"TEST_TASK", 60, PeriodicTaskIF::MINIMUM_STACK_SIZE, 1, missedDeadlineFunc);
result = testTask->addComponent(objects::TEST_TASK);
if(result != HasReturnvaluesIF::RETURN_OK) {
initmission::printAddObjectError("TEST_TASK", objects::TEST_TASK);
}
#if Q7S_ADD_SPI_TEST == 1
result = testTask->addComponent(objects::SPI_TEST);
if(result != HasReturnvaluesIF::RETURN_OK) {
initmission::printAddObjectError("SPI_TEST", objects::SPI_TEST);
}
#endif
#endif /* OBSW_ADD_TEST_CODE == 1 */
#if TE0720 == 1 && TEST_LIBGPIOD == 1
result = testTask->addComponent(objects::LIBGPIOD_TEST);
@ -174,7 +187,10 @@ void initmission::initTasks() {
#if TE0720 == 0
gomSpacePstTask->startTask();
#endif
#if Q7S_ADD_SPI_TEST == 0
pollingSequenceTableTaskDefault->startTask();
#endif
pusVerification->startTask();
pusEvents->startTask();
@ -182,6 +198,8 @@ void initmission::initTasks() {
pusMedPrio->startTask();
pusLowPrio->startTask();
#if OBSW_ADD_TEST_CODE == 1
testTask->startTask();
#endif
sif::info << "Tasks started.." << std::endl;
}

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@ -5,9 +5,11 @@
#include <devices/gpioIds.h>
#include <tmtc/pusIds.h>
#include <devices/powerSwitcherList.h>
#include <devices/spi.h>
#include <bsp_q7s/devices/HeaterHandler.h>
#include <bsp_q7s/devices/SolarArrayDeploymentHandler.h>
#include <bsp_q7s/gpio/gpioCallbacks.h>
#include <mission/core/GenericFactory.h>
#include <mission/devices/PDU1Handler.h>
@ -16,23 +18,40 @@
#include <mission/devices/PCDUHandler.h>
#include <mission/devices/P60DockHandler.h>
#include <mission/devices/Tmp1075Handler.h>
#include <mission/devices/devicedefinitions/GomSpacePackets.h>
#include <mission/devices/Max31865PT1000Handler.h>
#include <mission/devices/IMTQHandler.h>
#include <mission/devices/devicedefinitions/Max31865Definitions.h>
#include <mission/devices/SyrlinksHkHandler.h>
#include <mission/devices/MGMHandlerLIS3MDL.h>
#include <mission/devices/MGMHandlerRM3100.h>
#include <mission/devices/GyroL3GD20Handler.h>
#include <mission/devices/devicedefinitions/GomspaceDefinitions.h>
#include <mission/devices/devicedefinitions/SyrlinksDefinitions.h>
#include <mission/utility/TmFunnel.h>
#include <linux/csp/CspCookie.h>
#include <linux/csp/CspComIF.h>
#include <linux/i2c/I2cCookie.h>
#include <linux/i2c/I2cComIF.h>
#include <linux/gpio/LinuxLibgpioIF.h>
#include <linux/gpio/GpioCookie.h>
#include <linux/uart/UartComIF.h>
#include <linux/uart/UartCookie.h>
#include <fsfw_hal/linux/i2c/I2cCookie.h>
#include <fsfw_hal/linux/i2c/I2cComIF.h>
#include <fsfw_hal/linux/spi/SpiCookie.h>
#include <fsfw_hal/linux/spi/SpiComIF.h>
#include <fsfw_hal/linux/gpio/LinuxLibgpioIF.h>
#include <fsfw_hal/common/gpio/GpioCookie.h>
#include <fsfw/datapoollocal/LocalDataPoolManager.h>
#include <fsfw/tmtcservices/CommandingServiceBase.h>
#include <fsfw/tmtcservices/PusServiceBase.h>
#include <fsfw/osal/linux/TmTcUnixUdpBridge.h>
#include <fsfw/tmtcpacket/pus/TmPacketStored.h>
#include <fsfw/osal/linux/TcUnixUdpPollingTask.h>
/* UDP server includes */
#include <fsfw/osal/common/UdpTmTcBridge.h>
#include <fsfw/osal/common/UdpTcPollingTask.h>
#include <linux/boardtest/SpiTestClass.h>
#if TEST_LIBGPIOD == 1
#include <linux/boardtest/LibgpiodTest.h>
@ -49,10 +68,10 @@ void Factory::setStaticFrameworkObjectIds() {
// No storage object for now.
TmFunnel::storageDestination = objects::NO_OBJECT;
LocalDataPoolManager::defaultHkDestination = objects::NO_OBJECT;
LocalDataPoolManager::defaultHkDestination = objects::PUS_SERVICE_3_HOUSEKEEPING;
VerificationReporter::messageReceiver = objects::PUS_SERVICE_1_VERIFICATION;
TmPacketStored::timeStamperId = objects::TIME_STAMPER;
TmPacketBase::timeStamperId = objects::TIME_STAMPER;
}
@ -72,9 +91,27 @@ void ObjectFactory::produce(){
I2cCookie* i2cCookieTmp1075tcs2 = new I2cCookie(addresses::TMP1075_TCS_2,
TMP1075::MAX_REPLY_LENGTH, std::string("/dev/i2c-1"));
#endif
LinuxLibgpioIF* gpioComIF = new LinuxLibgpioIF(objects::GPIO_IF);
/* Communication interfaces */
new CspComIF(objects::CSP_COM_IF);
new I2cComIF(objects::I2C_COM_IF);
new UartComIF(objects::UART_COM_IF);
#if Q7S_ADD_SPI_TEST == 0
new SpiComIF(objects::SPI_COM_IF, gpioComIF);
#endif
/* Temperature sensors */
Tmp1075Handler* tmp1075Handler_1 = new Tmp1075Handler(
objects::TMP1075_HANDLER_1, objects::I2C_COM_IF,
i2cCookieTmp1075tcs1);
tmp1075Handler_1->setStartUpImmediately();
Tmp1075Handler* tmp1075Handler_2 = new Tmp1075Handler(
objects::TMP1075_HANDLER_2, objects::I2C_COM_IF,
i2cCookieTmp1075tcs2);
tmp1075Handler_2->setStartUpImmediately();
GpioCookie* heaterGpiosCookie = new GpioCookie;
#if TE0720 == 0
CspCookie* p60DockCspCookie = new CspCookie(P60Dock::MAX_REPLY_LENGTH,
@ -100,94 +137,303 @@ void ObjectFactory::produce(){
* Setting PCDU devices to mode normal immediately after start up because PCDU is always
* running.
*/
//p60dockhandler->setModeNormal();
//pdu1handler->setModeNormal();
//pdu2handler->setModeNormal();
//acuhandler->setModeNormal();
#endif
/* Temperature sensors */
Tmp1075Handler* tmp1075Handler_1 = new Tmp1075Handler(
objects::TMP1075_HANDLER_1, objects::I2C_COM_IF,
i2cCookieTmp1075tcs1);
tmp1075Handler_1->setStartUpImmediately();
Tmp1075Handler* tmp1075Handler_2 = new Tmp1075Handler(
objects::TMP1075_HANDLER_2, objects::I2C_COM_IF,
i2cCookieTmp1075tcs2);
tmp1075Handler_2->setStartUpImmediately();
/** For now this needs to be commented out because there is no PCDU connected to the OBC */
// p60dockhandler->setModeNormal();
// pdu1handler->setModeNormal();
// pdu2handler->setModeNormal();
// acuhandler->setModeNormal();
(void) p60dockhandler;
(void) pdu1handler;
(void) pdu2handler;
(void) acuhandler;
#if OBSW_ADD_ACS_BOARD == 1
GpioCookie* gpioCookieAcsBoard = new GpioCookie();
GpiodRegular* gpio = nullptr;
gpio = new GpiodRegular(std::string("gpiochip5"), 1, std::string("CS_GYRO_1_ADIS"),
gpio::OUT, gpio::HIGH);
gpioCookieAcsBoard->addGpio(gpioIds::GYRO_0_ADIS_CS, gpio);
gpio = new GpiodRegular(std::string("gpiochip5"), 7, std::string("CS_GYRO_2_L3G"),
gpio::OUT, gpio::HIGH);
gpioCookieAcsBoard->addGpio(gpioIds::GYRO_1_L3G_CS, gpio);
gpio = new GpiodRegular(std::string("gpiochip5"), 3, std::string("CS_GYRO_3_L3G"),
gpio::OUT, gpio::HIGH);
gpioCookieAcsBoard->addGpio(gpioIds::GYRO_2_L3G_CS, gpio);
gpio = new GpiodRegular(std::string("gpiochip5"), 5, std::string("CS_MGM_0_LIS3_A"),
gpio::OUT, gpio::HIGH);
gpioCookieAcsBoard->addGpio(gpioIds::MGM_0_LIS3_CS, gpio);
gpio = new GpiodRegular(std::string("gpiochip5"), 17, std::string("CS_MGM_1_RM3100_A"),
gpio::OUT, gpio::HIGH);
gpioCookieAcsBoard->addGpio(gpioIds::MGM_1_RM3100_CS, gpio);
gpio = new GpiodRegular(std::string("gpiochip6"), 0, std::string("CS_MGM_2_LIS3_B"),
gpio::OUT, gpio::HIGH);
gpioCookieAcsBoard->addGpio(gpioIds::MGM_2_LIS3_CS, gpio);
gpio = new GpiodRegular(std::string("gpiochip5"), 10, std::string("CS_MGM_3_RM3100_B"),
gpio::OUT, gpio::HIGH);
gpioCookieAcsBoard->addGpio(gpioIds::MGM_3_RM3100_CS, gpio);
gpioComIF->addGpios(gpioCookieAcsBoard);
std::string spiDev = "/dev/spidev2.0";
SpiCookie* spiCookie = new SpiCookie(addresses::MGM_0_LIS3, gpioIds::MGM_0_LIS3_CS, spiDev,
MGMLIS3MDL::MAX_BUFFER_SIZE, spi::DEFAULT_LIS3_MODE, spi::DEFAULT_LIS3_SPEED);
auto mgmLis3Handler = new MGMHandlerLIS3MDL(objects::MGM_0_LIS3_HANDLER,
objects::SPI_COM_IF, spiCookie);
mgmLis3Handler->setStartUpImmediately();
spiCookie = new SpiCookie(addresses::MGM_2_LIS3, gpioIds::MGM_2_LIS3_CS, spiDev,
MGMLIS3MDL::MAX_BUFFER_SIZE, spi::DEFAULT_LIS3_MODE, spi::DEFAULT_LIS3_SPEED);
auto mgmLis3Handler2 = new MGMHandlerLIS3MDL(objects::MGM_2_LIS3_HANDLER,
objects::SPI_COM_IF, spiCookie);
mgmLis3Handler2->setStartUpImmediately();
spiCookie = new SpiCookie(addresses::MGM_1_RM3100, gpioIds::MGM_1_RM3100_CS, spiDev,
RM3100::MAX_BUFFER_SIZE, spi::DEFAULT_RM3100_MODE, spi::DEFAULT_RM3100_SPEED);
auto mgmRm3100Handler = new MGMHandlerRM3100(objects::MGM_1_RM3100_HANDLER,
objects::SPI_COM_IF, spiCookie);
mgmRm3100Handler->setStartUpImmediately();
spiCookie = new SpiCookie(addresses::GYRO_1_L3G, gpioIds::GYRO_1_L3G_CS, spiDev,
L3GD20H::MAX_BUFFER_SIZE, spi::DEFAULT_L3G_MODE, spi::DEFAULT_L3G_SPEED);
auto gyroL3gHandler = new GyroHandlerL3GD20H(objects::GYRO_1_L3G_HANDLER, objects::SPI_COM_IF,
spiCookie);
gyroL3gHandler->setStartUpImmediately();
#endif
GpioCookie* heaterGpiosCookie = new GpioCookie;
new LinuxLibgpioIF(objects::GPIO_IF);
#if TE0720 == 0
/* Pin H2-11 on stack connector */
GpiodRegular gpioConfigHeater0(std::string("gpiochip7"), 18,
GpiodRegular* gpioConfigHeater0 = new GpiodRegular(std::string("gpiochip7"), 6,
std::string("Heater0"), gpio::OUT, 0);
heaterGpiosCookie->addGpio(gpioIds::HEATER_0, gpioConfigHeater0);
/* Pin H2-12 on stack connector */
GpiodRegular gpioConfigHeater1(std::string("gpiochip7"), 14,
GpiodRegular* gpioConfigHeater1 = new GpiodRegular(std::string("gpiochip7"), 12,
std::string("Heater1"), gpio::OUT, 0);
heaterGpiosCookie->addGpio(gpioIds::HEATER_1, gpioConfigHeater1);
/* Pin H2-13 on stack connector */
GpiodRegular gpioConfigHeater2(std::string("gpiochip7"), 20,
GpiodRegular* gpioConfigHeater2 = new GpiodRegular(std::string("gpiochip7"), 7,
std::string("Heater2"), gpio::OUT, 0);
heaterGpiosCookie->addGpio(gpioIds::HEATER_2, gpioConfigHeater2);
GpiodRegular gpioConfigHeater3(std::string("gpiochip7"), 16,
GpiodRegular* gpioConfigHeater3 = new GpiodRegular(std::string("gpiochip7"), 5,
std::string("Heater3"), gpio::OUT, 0);
heaterGpiosCookie->addGpio(gpioIds::HEATER_3, gpioConfigHeater3);
GpiodRegular gpioConfigHeater4(std::string("gpiochip7"), 24,
GpiodRegular* gpioConfigHeater4 = new GpiodRegular(std::string("gpiochip7"), 3,
std::string("Heater4"), gpio::OUT, 0);
heaterGpiosCookie->addGpio(gpioIds::HEATER_4, gpioConfigHeater4);
GpiodRegular gpioConfigHeater5(std::string("gpiochip7"), 26,
GpiodRegular* gpioConfigHeater5 = new GpiodRegular(std::string("gpiochip7"), 0,
std::string("Heater5"), gpio::OUT, 0);
heaterGpiosCookie->addGpio(gpioIds::HEATER_5, gpioConfigHeater5);
GpiodRegular gpioConfigHeater6(std::string("gpiochip7"), 22,
GpiodRegular* gpioConfigHeater6 = new GpiodRegular(std::string("gpiochip7"), 1,
std::string("Heater6"), gpio::OUT, 0);
heaterGpiosCookie->addGpio(gpioIds::HEATER_6, gpioConfigHeater6);
GpiodRegular gpioConfigHeater7(std::string("gpiochip7"), 28,
GpiodRegular* gpioConfigHeater7 = new GpiodRegular(std::string("gpiochip7"), 11,
std::string("Heater7"), gpio::OUT, 0);
heaterGpiosCookie->addGpio(gpioIds::HEATER_7, gpioConfigHeater7);
new HeaterHandler(objects::HEATER_HANDLER, objects::GPIO_IF, heaterGpiosCookie, objects::PCDU_HANDLER,
pcduSwitches::TCS_BOARD_8V_HEATER_IN);
new HeaterHandler(objects::HEATER_HANDLER, objects::GPIO_IF, heaterGpiosCookie,
objects::PCDU_HANDLER, pcduSwitches::TCS_BOARD_8V_HEATER_IN);
GpioCookie* solarArrayDeplCookie = new GpioCookie;
GpiodRegular gpioConfigDeplSA1(std::string("gpiochip7"), 25,
GpiodRegular* gpioConfigDeplSA0 = new GpiodRegular(std::string("gpiochip7"), 4,
std::string("DeplSA1"), gpio::OUT, 0);
solarArrayDeplCookie->addGpio(gpioIds::DEPLSA1, gpioConfigDeplSA1);
GpiodRegular gpioConfigDeplSA2(std::string("gpiochip7"), 23,
solarArrayDeplCookie->addGpio(gpioIds::DEPLSA1, gpioConfigDeplSA0);
GpiodRegular* gpioConfigDeplSA1 = new GpiodRegular(std::string("gpiochip7"), 2,
std::string("DeplSA2"), gpio::OUT, 0);
solarArrayDeplCookie->addGpio(gpioIds::DEPLSA2, gpioConfigDeplSA2);
solarArrayDeplCookie->addGpio(gpioIds::DEPLSA2, gpioConfigDeplSA1);
//TODO: Find out burn time. For now set to 1000 ms.
new SolarArrayDeploymentHandler(objects::SOLAR_ARRAY_DEPL_HANDLER, objects::GPIO_IF,
solarArrayDeplCookie, objects::PCDU_HANDLER, pcduSwitches::DEPLOYMENT_MECHANISM,
gpioIds::DEPLSA1, gpioIds::DEPLSA2, 1000);
#endif
new TmTcUnixUdpBridge(objects::UDP_BRIDGE,
objects::CCSDS_PACKET_DISTRIBUTOR,
objects::TM_STORE, objects::TC_STORE);
new TcUnixUdpPollingTask(objects::UDP_POLLING_TASK, objects::UDP_BRIDGE);
UartCookie* syrlinksUartCookie = new UartCookie(
std::string("/dev/ttyUL0"), 38400, SYRLINKS::MAX_REPLY_SIZE);
syrlinksUartCookie->setParityEven();
SyrlinksHkHandler* syrlinksHkHandler = new SyrlinksHkHandler(objects::SYRLINKS_HK_HANDLER,
objects::UART_COM_IF, syrlinksUartCookie);
syrlinksHkHandler->setModeNormal();
#if Q7S_ADD_RTD_DEVICES == 1
GpioCookie* rtdGpioCookie = new GpioCookie;
gpioCallbacks::initTcsBoardDecoder(gpioComIF);
GpioCallback* gpioRtdIc3 = new GpioCallback(std::string("Chip select RTD IC3"), gpio::OUT, 1,
&gpioCallbacks::tcsBoardDecoderCallback, gpioComIF);
rtdGpioCookie->addGpio(gpioIds::RTD_IC3, gpioRtdIc3);
GpioCallback* gpioRtdIc4 = new GpioCallback(std::string("Chip select RTD IC4"), gpio::OUT, 1,
&gpioCallbacks::tcsBoardDecoderCallback, gpioComIF);
rtdGpioCookie->addGpio(gpioIds::RTD_IC4, gpioRtdIc4);
GpioCallback* gpioRtdIc5 = new GpioCallback(std::string("Chip select RTD IC5"), gpio::OUT, 1,
&gpioCallbacks::tcsBoardDecoderCallback, gpioComIF);
rtdGpioCookie->addGpio(gpioIds::RTD_IC5, gpioRtdIc5);
GpioCallback* gpioRtdIc6 = new GpioCallback(std::string("Chip select RTD IC6"), gpio::OUT, 1,
&gpioCallbacks::tcsBoardDecoderCallback, gpioComIF);
rtdGpioCookie->addGpio(gpioIds::RTD_IC6, gpioRtdIc6);
GpioCallback* gpioRtdIc7 = new GpioCallback(std::string("Chip select RTD IC7"), gpio::OUT, 1,
&gpioCallbacks::tcsBoardDecoderCallback, gpioComIF);
rtdGpioCookie->addGpio(gpioIds::RTD_IC7, gpioRtdIc7);
GpioCallback* gpioRtdIc8 = new GpioCallback(std::string("Chip select RTD IC8"), gpio::OUT, 1,
&gpioCallbacks::tcsBoardDecoderCallback, gpioComIF);
rtdGpioCookie->addGpio(gpioIds::RTD_IC8, gpioRtdIc8);
GpioCallback* gpioRtdIc9 = new GpioCallback(std::string("Chip select RTD IC9"), gpio::OUT, 1,
&gpioCallbacks::tcsBoardDecoderCallback, gpioComIF);
rtdGpioCookie->addGpio(gpioIds::RTD_IC9, gpioRtdIc9);
GpioCallback* gpioRtdIc10 = new GpioCallback(std::string("Chip select RTD IC10"), gpio::OUT, 1,
&gpioCallbacks::tcsBoardDecoderCallback, gpioComIF);
rtdGpioCookie->addGpio(gpioIds::RTD_IC10, gpioRtdIc10);
GpioCallback* gpioRtdIc11 = new GpioCallback(std::string("Chip select RTD IC11"), gpio::OUT, 1,
&gpioCallbacks::tcsBoardDecoderCallback, gpioComIF);
rtdGpioCookie->addGpio(gpioIds::RTD_IC11, gpioRtdIc11);
GpioCallback* gpioRtdIc12 = new GpioCallback(std::string("Chip select RTD IC12"), gpio::OUT, 1,
&gpioCallbacks::tcsBoardDecoderCallback, gpioComIF);
rtdGpioCookie->addGpio(gpioIds::RTD_IC12, gpioRtdIc12);
GpioCallback* gpioRtdIc13 = new GpioCallback(std::string("Chip select RTD IC13"), gpio::OUT, 1,
&gpioCallbacks::tcsBoardDecoderCallback, gpioComIF);
rtdGpioCookie->addGpio(gpioIds::RTD_IC13, gpioRtdIc13);
GpioCallback* gpioRtdIc14 = new GpioCallback(std::string("Chip select RTD IC14"), gpio::OUT, 1,
&gpioCallbacks::tcsBoardDecoderCallback, gpioComIF);
rtdGpioCookie->addGpio(gpioIds::RTD_IC14, gpioRtdIc14);
GpioCallback* gpioRtdIc15 = new GpioCallback(std::string("Chip select RTD IC15"), gpio::OUT, 1,
&gpioCallbacks::tcsBoardDecoderCallback, gpioComIF);
rtdGpioCookie->addGpio(gpioIds::RTD_IC15, gpioRtdIc15);
GpioCallback* gpioRtdIc16 = new GpioCallback(std::string("Chip select RTD IC16"), gpio::OUT, 1,
&gpioCallbacks::tcsBoardDecoderCallback, gpioComIF);
rtdGpioCookie->addGpio(gpioIds::RTD_IC16, gpioRtdIc16);
GpioCallback* gpioRtdIc17 = new GpioCallback(std::string("Chip select RTD IC17"), gpio::OUT, 1,
&gpioCallbacks::tcsBoardDecoderCallback, gpioComIF);
rtdGpioCookie->addGpio(gpioIds::RTD_IC17, gpioRtdIc17);
GpioCallback* gpioRtdIc18 = new GpioCallback(std::string("Chip select RTD IC18"), gpio::OUT, 1,
&gpioCallbacks::tcsBoardDecoderCallback, gpioComIF);
rtdGpioCookie->addGpio(gpioIds::RTD_IC18, gpioRtdIc18);
gpioComIF->addGpios(rtdGpioCookie);
SpiCookie* spiRtdIc3 = new SpiCookie(addresses::RTD_IC3, gpioIds::RTD_IC3,
std::string("/dev/spidev2.0"), Max31865Definitions::MAX_REPLY_SIZE,
spi::SpiModes::MODE_1, 2000000);
SpiCookie* spiRtdIc4 = new SpiCookie(addresses::RTD_IC4, gpioIds::RTD_IC4,
std::string("/dev/spidev2.0"), Max31865Definitions::MAX_REPLY_SIZE,
spi::SpiModes::MODE_1, 2000000);
SpiCookie* spiRtdIc5 = new SpiCookie(addresses::RTD_IC5, gpioIds::RTD_IC5,
std::string("/dev/spidev2.0"), Max31865Definitions::MAX_REPLY_SIZE,
spi::SpiModes::MODE_1, 2000000);
SpiCookie* spiRtdIc6 = new SpiCookie(addresses::RTD_IC6, gpioIds::RTD_IC6,
std::string("/dev/spidev2.0"), Max31865Definitions::MAX_REPLY_SIZE,
spi::SpiModes::MODE_1, 2000000);
SpiCookie* spiRtdIc7 = new SpiCookie(addresses::RTD_IC7, gpioIds::RTD_IC7,
std::string("/dev/spidev2.0"), Max31865Definitions::MAX_REPLY_SIZE,
spi::SpiModes::MODE_1, 2000000);
SpiCookie* spiRtdIc8 = new SpiCookie(addresses::RTD_IC8, gpioIds::RTD_IC8,
std::string("/dev/spidev2.0"), Max31865Definitions::MAX_REPLY_SIZE,
spi::SpiModes::MODE_1, 2000000);
SpiCookie* spiRtdIc9 = new SpiCookie(addresses::RTD_IC9, gpioIds::RTD_IC9,
std::string("/dev/spidev2.0"), Max31865Definitions::MAX_REPLY_SIZE,
spi::SpiModes::MODE_1, 2000000);
SpiCookie* spiRtdIc10 = new SpiCookie(addresses::RTD_IC10, gpioIds::RTD_IC10,
std::string("/dev/spidev2.0"), Max31865Definitions::MAX_REPLY_SIZE,
spi::SpiModes::MODE_1, 2000000);
SpiCookie* spiRtdIc11 = new SpiCookie(addresses::RTD_IC11, gpioIds::RTD_IC11,
std::string("/dev/spidev2.0"), Max31865Definitions::MAX_REPLY_SIZE,
spi::SpiModes::MODE_1, 2000000);
SpiCookie* spiRtdIc12 = new SpiCookie(addresses::RTD_IC12, gpioIds::RTD_IC12,
std::string("/dev/spidev2.0"), Max31865Definitions::MAX_REPLY_SIZE,
spi::SpiModes::MODE_1, 2000000);
SpiCookie* spiRtdIc13 = new SpiCookie(addresses::RTD_IC13, gpioIds::RTD_IC13,
std::string("/dev/spidev2.0"), Max31865Definitions::MAX_REPLY_SIZE,
spi::SpiModes::MODE_1, 2000000);
SpiCookie* spiRtdIc14 = new SpiCookie(addresses::RTD_IC14, gpioIds::RTD_IC14,
std::string("/dev/spidev2.0"), Max31865Definitions::MAX_REPLY_SIZE,
spi::SpiModes::MODE_1, 2000000);
SpiCookie* spiRtdIc15 = new SpiCookie(addresses::RTD_IC15, gpioIds::RTD_IC15,
std::string("/dev/spidev2.0"), Max31865Definitions::MAX_REPLY_SIZE,
spi::SpiModes::MODE_1, 2000000);
SpiCookie* spiRtdIc16 = new SpiCookie(addresses::RTD_IC16, gpioIds::RTD_IC16,
std::string("/dev/spidev2.0"), Max31865Definitions::MAX_REPLY_SIZE,
spi::SpiModes::MODE_1, 2000000);
SpiCookie* spiRtdIc17 = new SpiCookie(addresses::RTD_IC17, gpioIds::RTD_IC17,
std::string("/dev/spidev2.0"), Max31865Definitions::MAX_REPLY_SIZE,
spi::SpiModes::MODE_1, 2000000);
SpiCookie* spiRtdIc18 = new SpiCookie(addresses::RTD_IC18, gpioIds::RTD_IC18,
std::string("/dev/spidev2.0"), Max31865Definitions::MAX_REPLY_SIZE,
spi::SpiModes::MODE_1, 2000000);
Max31865PT1000Handler* rtdIc3 = new Max31865PT1000Handler(objects::RTD_IC3, objects::SPI_COM_IF, spiRtdIc3, 0); // 0 is switchId
Max31865PT1000Handler* rtdIc4 = new Max31865PT1000Handler(objects::RTD_IC4, objects::SPI_COM_IF, spiRtdIc4, 0);
Max31865PT1000Handler* rtdIc5 = new Max31865PT1000Handler(objects::RTD_IC5, objects::SPI_COM_IF, spiRtdIc5, 0);
Max31865PT1000Handler* rtdIc6 = new Max31865PT1000Handler(objects::RTD_IC6, objects::SPI_COM_IF, spiRtdIc6, 0);
Max31865PT1000Handler* rtdIc7 = new Max31865PT1000Handler(objects::RTD_IC7, objects::SPI_COM_IF, spiRtdIc7, 0);
Max31865PT1000Handler* rtdIc8 = new Max31865PT1000Handler(objects::RTD_IC8, objects::SPI_COM_IF, spiRtdIc8, 0);
Max31865PT1000Handler* rtdIc9 = new Max31865PT1000Handler(objects::RTD_IC9, objects::SPI_COM_IF, spiRtdIc9, 0);
Max31865PT1000Handler* rtdIc10 = new Max31865PT1000Handler(objects::RTD_IC10, objects::SPI_COM_IF, spiRtdIc10, 0);
Max31865PT1000Handler* rtdIc11 = new Max31865PT1000Handler(objects::RTD_IC11, objects::SPI_COM_IF, spiRtdIc11, 0);
Max31865PT1000Handler* rtdIc12 = new Max31865PT1000Handler(objects::RTD_IC12, objects::SPI_COM_IF, spiRtdIc12, 0);
Max31865PT1000Handler* rtdIc13 = new Max31865PT1000Handler(objects::RTD_IC13, objects::SPI_COM_IF, spiRtdIc13, 0);
Max31865PT1000Handler* rtdIc14 = new Max31865PT1000Handler(objects::RTD_IC14, objects::SPI_COM_IF, spiRtdIc14, 0);
Max31865PT1000Handler* rtdIc15 = new Max31865PT1000Handler(objects::RTD_IC15, objects::SPI_COM_IF, spiRtdIc15, 0);
Max31865PT1000Handler* rtdIc16 = new Max31865PT1000Handler(objects::RTD_IC16, objects::SPI_COM_IF, spiRtdIc16, 0);
Max31865PT1000Handler* rtdIc17 = new Max31865PT1000Handler(objects::RTD_IC17, objects::SPI_COM_IF, spiRtdIc17, 0);
Max31865PT1000Handler* rtdIc18 = new Max31865PT1000Handler(objects::RTD_IC18, objects::SPI_COM_IF, spiRtdIc18, 0);
// rtdIc10->setStartUpImmediately();
// rtdIc4->setStartUpImmediately();
(void) rtdIc3;
(void) rtdIc4;
(void) rtdIc5;
(void) rtdIc6;
(void) rtdIc7;
(void) rtdIc8;
(void) rtdIc9;
(void) rtdIc10;
(void) rtdIc11;
(void) rtdIc12;
(void) rtdIc13;
(void) rtdIc14;
(void) rtdIc15;
(void) rtdIc16;
(void) rtdIc17;
(void) rtdIc18;
#endif /* Q7S_ADD_RTD_DEVICES == 1 */
#endif /* TE0720 == 0 */
new UdpTmTcBridge(objects::UDP_BRIDGE, objects::CCSDS_PACKET_DISTRIBUTOR, objects::TM_STORE,
objects::TC_STORE);
new UdpTcPollingTask(objects::UDP_POLLING_TASK, objects::UDP_BRIDGE);
I2cCookie* imtqI2cCookie = new I2cCookie(addresses::IMTQ, IMTQ::MAX_REPLY_SIZE,
std::string("/dev/i2c-0"));
IMTQHandler* imtqHandler = new IMTQHandler(objects::IMTQ_HANDLER, objects::I2C_COM_IF, imtqI2cCookie);
imtqHandler->setStartUpImmediately();
#if TE0720 == 1 && TEST_LIBGPIOD == 1
/* Configure MIO0 as input */
GpioConfig_t gpioConfigMio0(std::string("gpiochip0"), 0,
GpiodRegular gpioConfigMio0(std::string("gpiochip0"), 0,
std::string("MIO0"), gpio::IN, 0);
GpioCookie* gpioCookie = new GpioCookie;
gpioCookie->addGpio(gpioIds::TEST_ID_0, gpioConfigMio0);
new LibgpiodTest(objects::LIBGPIOD_TEST, objects::GPIO_IF, gpioCookie);
#elif TE0720 == 1
/* Configuration for MIO0 on TE0720-03-1CFA */
GpioConfig_t gpioConfigForDummyHeater(std::string("gpiochip0"), 0,
GpiodRegular gpioConfigForDummyHeater(std::string("gpiochip0"), 0,
std::string("Heater0"), gpio::OUT, 0);
heaterGpiosCookie->addGpio(gpioIds::HEATER_0, gpioConfigForDummyHeater);
new HeaterHandler(objects::HEATER_HANDLER, objects::GPIO_IF, heaterGpiosCookie,
objects::PCDU_HANDLER, pcduSwitches::TCS_BOARD_8V_HEATER_IN);
#endif
#if Q7S_ADD_SPI_TEST == 1
new SpiTestClass(objects::SPI_TEST, gpioComIF);
#endif
}

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@ -0,0 +1,13 @@
#ifndef BSP_Q7S_BOARDCONFIG_Q7S_CONFIG_H_
#define BSP_Q7S_BOARDCONFIG_Q7S_CONFIG_H_
#define Q7S_ADD_RTD_DEVICES 0
/* Only one of those 2 should be enabled! */
/* Add code for ACS board */
#define OBSW_ADD_ACS_BOARD 0
#define Q7S_ADD_SPI_TEST 0
#endif /* BSP_Q7S_BOARDCONFIG_Q7S_CONFIG_H_ */

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@ -2,7 +2,7 @@
#include <fsfwconfig/devices/powerSwitcherList.h>
#include <fsfw/ipc/QueueFactory.h>
#include <devices/gpioIds.h>
#include <linux/gpio/GpioCookie.h>
#include <fsfw_hal/common/gpio/GpioCookie.h>
HeaterHandler::HeaterHandler(object_id_t setObjectId_, object_id_t gpioDriverId_,
CookieIF * gpioCookie_, object_id_t mainLineSwitcherObjectId_, uint8_t mainLineSwitch_) :

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@ -10,7 +10,7 @@
#include <fsfw/devicehandlers/DeviceHandlerIF.h>
#include <fsfw/devicehandlers/CookieIF.h>
#include <fsfw/timemanager/Countdown.h>
#include <linux/gpio/GpioIF.h>
#include <fsfw_hal/common/gpio/GpioIF.h>
#include <unordered_map>
/**

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@ -3,7 +3,7 @@
#include <devices/powerSwitcherList.h>
#include <devices/gpioIds.h>
#include <linux/gpio/GpioCookie.h>
#include <fsfw_hal/common/gpio/GpioCookie.h>
#include <fsfw/ipc/QueueFactory.h>

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@ -1,8 +1,6 @@
#ifndef MISSION_DEVICES_SOLARARRAYDEPLOYMENT_H_
#define MISSION_DEVICES_SOLARARRAYDEPLOYMENT_H_
#include <linux/gpio/GpioIF.h>
#include <fsfw/objectmanager/SystemObject.h>
#include <fsfw/tasks/ExecutableObjectIF.h>
#include <fsfw/returnvalues/HasReturnvaluesIF.h>
@ -11,7 +9,7 @@
#include <fsfw/devicehandlers/CookieIF.h>
#include <fsfw/devicehandlers/DeviceHandlerIF.h>
#include <fsfw/timemanager/Countdown.h>
#include <fsfw_hal/common/gpio/GpioIF.h>
#include <unordered_map>
/**

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@ -0,0 +1,3 @@
target_sources(${TARGET_NAME} PRIVATE
gpioCallbacks.cpp
)

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@ -0,0 +1,221 @@
#include "gpioCallbacks.h"
#include <devices/gpioIds.h>
#include <fsfw_hal/linux/gpio/LinuxLibgpioIF.h>
#include <fsfw_hal/common/gpio/GpioCookie.h>
#include <fsfw/serviceinterface/ServiceInterface.h>
namespace gpioCallbacks {
GpioIF* gpioComInterface;
void initTcsBoardDecoder(GpioIF* gpioComIF) {
ReturnValue_t result;
if (gpioComIF == nullptr) {
sif::debug << "initTcsBoardDecoder: Invalid gpioComIF" << std::endl;
return;
}
gpioComInterface = gpioComIF;
GpioCookie* spiMuxGpios = new GpioCookie;
/**
* Initial values of the spi mux gpios can all be set to an arbitrary value expect for spi mux
* bit 1. Setting spi mux bit 1 to high will pull all decoder outputs to high voltage level.
*/
GpiodRegular* spiMuxBit1 = new GpiodRegular(std::string("gpiochip7"), 13,
std::string("SPI Mux Bit 1"), gpio::OUT, 1);
spiMuxGpios->addGpio(gpioIds::SPI_MUX_BIT_1, spiMuxBit1);
GpiodRegular* spiMuxBit2 = new GpiodRegular(std::string("gpiochip7"), 14,
std::string("SPI Mux Bit 2"), gpio::OUT, 0);
spiMuxGpios->addGpio(gpioIds::SPI_MUX_BIT_2, spiMuxBit2);
GpiodRegular* spiMuxBit3 = new GpiodRegular(std::string("gpiochip7"), 15,
std::string("SPI Mux Bit 3"), gpio::OUT, 0);
spiMuxGpios->addGpio(gpioIds::SPI_MUX_BIT_3, spiMuxBit3);
GpiodRegular* spiMuxBit4 = new GpiodRegular(std::string("gpiochip7"), 16,
std::string("SPI Mux Bit 4"), gpio::OUT, 0);
spiMuxGpios->addGpio(gpioIds::SPI_MUX_BIT_4, spiMuxBit4);
GpiodRegular* spiMuxBit5 = new GpiodRegular(std::string("gpiochip7"), 17,
std::string("SPI Mux Bit 5"), gpio::OUT, 0);
spiMuxGpios->addGpio(gpioIds::SPI_MUX_BIT_5, spiMuxBit5);
GpiodRegular* spiMuxBit6 = new GpiodRegular(std::string("gpiochip7"), 18,
std::string("SPI Mux Bit 6"), gpio::OUT, 0);
spiMuxGpios->addGpio(gpioIds::SPI_MUX_BIT_6, spiMuxBit6);
result = gpioComInterface->addGpios(spiMuxGpios);
if (result != HasReturnvaluesIF::RETURN_OK) {
sif::error << "initTcsBoardDecoder: Failed to add mux bit gpios to gpioComIF"
<< std::endl;
return;
}
}
void tcsBoardDecoderCallback(gpioId_t gpioId, gpio::GpioOperation gpioOp, int value,
void* args) {
if (gpioComInterface == nullptr) {
sif::debug << "tcsBoardDecoderCallback: No gpioComIF specified. Call initTcsBoardDecoder "
<< "to specify gpioComIF" << std::endl;
return;
}
/* Read is not supported by the callback function */
if (gpioOp == gpio::GpioOperation::READ) {
return;
}
if (value == 1) {
/* This will pull all 16 decoder outputs to high */
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_1);
}
else if (value == 0) {
switch (gpioId) {
case(gpioIds::RTD_IC3): {
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_1);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_2);
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_3);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_4);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_5);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_6);
break;
}
case(gpioIds::RTD_IC4): {
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_1);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_2);
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_3);
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_4);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_5);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_6);
break;
}
case(gpioIds::RTD_IC5): {
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_1);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_2);
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_3);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_4);
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_5);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_6);
break;
}
case(gpioIds::RTD_IC6): {
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_1);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_2);
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_3);
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_4);
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_5);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_6);
break;
}
case(gpioIds::RTD_IC7): {
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_1);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_2);
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_3);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_4);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_5);
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_6);
break;
}
case(gpioIds::RTD_IC8): {
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_1);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_2);
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_3);
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_4);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_5);
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_6);
break;
}
case(gpioIds::RTD_IC9): {
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_1);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_2);
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_3);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_4);
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_5);
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_6);
break;
}
case(gpioIds::RTD_IC10): {
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_1);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_2);
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_3);
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_4);
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_5);
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_6);
break;
}
case(gpioIds::RTD_IC11): {
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_1);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_3);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_4);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_5);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_6);
break;
}
case(gpioIds::RTD_IC12): {
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_1);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_3);
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_4);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_5);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_6);
break;
}
case(gpioIds::RTD_IC13): {
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_1);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_3);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_4);
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_5);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_6);
break;
}
case(gpioIds::RTD_IC14): {
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_1);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_3);
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_4);
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_5);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_6);
break;
}
case(gpioIds::RTD_IC15): {
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_1);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_3);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_4);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_5);
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_6);
break;
}
case(gpioIds::RTD_IC16): {
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_1);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_3);
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_4);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_5);
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_6);
break;
}
case(gpioIds::RTD_IC17): {
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_1);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_3);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_4);
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_5);
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_6);
break;
}
case(gpioIds::RTD_IC18): {
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_1);
gpioComInterface->pullHigh(gpioIds::SPI_MUX_BIT_3);
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_4);
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_5);
gpioComInterface->pullLow(gpioIds::SPI_MUX_BIT_6);
break;
}
default:
sif::debug << "tcsBoardDecoderCallback: Invalid gpioid " << gpioId << std::endl;
}
}
else {
sif::debug << "tcsBoardDecoderCallback: Invalid value. Must be 0 or 1" << std::endl;
}
}
}

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@ -0,0 +1,23 @@
#ifndef LINUX_GPIO_GPIOCALLBACKS_H_
#define LINUX_GPIO_GPIOCALLBACKS_H_
#include <fsfw_hal/common/gpio/gpioDefinitions.h>
#include <fsfw_hal/common/gpio/GpioIF.h>
namespace gpioCallbacks {
/**
* @brief This function initializes the GPIOs used to control the SN74LVC138APWR decoders on
* the TCS Board.
*/
void initTcsBoardDecoder(GpioIF* gpioComIF);
/**
* @brief This function implements the decoding to multiply gpios by using the two decoder
* chips SN74LVC138APWR on the TCS board.
*/
void tcsBoardDecoderCallback(gpioId_t gpioId, gpio::GpioOperation gpioOp, int value, void* args);
}
#endif /* LINUX_GPIO_GPIOCALLBACKS_H_ */

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@ -3,8 +3,9 @@
#include <fsfwconfig/objects/systemObjectList.h>
#include <fsfwconfig/OBSWConfig.h>
#include <mission/utility/InitMission.h>
#include <fsfwconfig/pollingsequence/pollingSequenceFactory.h>
#include <mission/utility/InitMission.h>
#include <fsfw/objectmanager/ObjectManagerIF.h>
#include <fsfw/returnvalues/HasReturnvaluesIF.h>
#include <fsfw/serviceinterface/ServiceInterface.h>
@ -12,7 +13,6 @@
#include <fsfw/tasks/FixedTimeslotTaskIF.h>
#include <fsfw/tasks/PeriodicTaskIF.h>
#include <fsfw/tasks/TaskFactory.h>
#include <fsfwconfig/pollingsequence/pollingSequenceFactory.h>
#include <iostream>
@ -127,7 +127,7 @@ void initmission::initTasks() {
#if RPI_TEST_ACS_BOARD == 1
FixedTimeslotTaskIF* acsTask = factory->createFixedTimeslotTask(
"ACS_PST", 50, PeriodicTaskIF::MINIMUM_STACK_SIZE * 2, 1.0, missedDeadlineFunc);
"ACS_PST", 50, PeriodicTaskIF::MINIMUM_STACK_SIZE * 2, 2.0, missedDeadlineFunc);
result = pst::pollingSequenceAcsTest(acsTask);
if(result != HasReturnvaluesIF::RETURN_OK) {
sif::warning << "initmission::initTasks: ACS PST initialization failed!" << std::endl;

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@ -1,5 +1,4 @@
#include "ObjectFactory.h"
#include <bsp_rpi/gpio/GPIORPi.h>
#include <fsfwconfig/objects/systemObjectList.h>
#include <fsfwconfig/devices/addresses.h>
@ -11,11 +10,8 @@
#include <linux/boardtest/LibgpiodTest.h>
#include <linux/boardtest/SpiTestClass.h>
#include <linux/gpio/GpioCookie.h>
#include <linux/gpio/LinuxLibgpioIF.h>
#include <linux/spi/SpiCookie.h>
#include <linux/spi/SpiComIF.h>
#include <mission/devices/GyroL3GD20Handler.h>
#include <mission/core/GenericFactory.h>
#include <mission/utility/TmFunnel.h>
#include <mission/devices/MGMHandlerLIS3MDL.h>
@ -24,12 +20,18 @@
#include <fsfw/datapoollocal/LocalDataPoolManager.h>
#include <fsfw/tmtcservices/CommandingServiceBase.h>
#include <fsfw/tmtcservices/PusServiceBase.h>
#include <fsfw/osal/linux/TmTcUnixUdpBridge.h>
#include <fsfw/tmtcpacket/pus/TmPacketStored.h>
#include <fsfw/osal/linux/TcUnixUdpPollingTask.h>
#include <fsfw/tasks/TaskFactory.h>
#include <mission/devices/GyroL3GD20Handler.h>
/* UDP server includes */
#include <fsfw/osal/common/UdpTmTcBridge.h>
#include <fsfw/osal/common/UdpTcPollingTask.h>
#include <fsfw_hal/linux/gpio/LinuxLibgpioIF.h>
#include <fsfw_hal/linux/rpi/GpioRPi.h>
#include <fsfw_hal/common/gpio/GpioCookie.h>
#include <fsfw_hal/linux/spi/SpiCookie.h>
#include <fsfw_hal/linux/spi/SpiComIF.h>
void Factory::setStaticFrameworkObjectIds() {
PusServiceBase::packetSource = objects::PUS_PACKET_DISTRIBUTOR;
@ -54,10 +56,10 @@ void ObjectFactory::produce(){
Factory::setStaticFrameworkObjectIds();
ObjectFactory::produceGenericObjects();
new TmTcUnixUdpBridge(objects::UDP_BRIDGE,
new UdpTmTcBridge(objects::UDP_BRIDGE,
objects::CCSDS_PACKET_DISTRIBUTOR,
objects::TM_STORE, objects::TC_STORE);
new TcUnixUdpPollingTask(objects::UDP_POLLING_TASK, objects::UDP_BRIDGE);
new UdpTcPollingTask(objects::UDP_POLLING_TASK, objects::UDP_BRIDGE);
GpioIF* gpioIF = new LinuxLibgpioIF(objects::GPIO_IF);

View File

@ -1,5 +1,4 @@
target_sources(${TARGET_NAME} PUBLIC
GPIORPi.cpp
)

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@ -0,0 +1,6 @@
#!/bin/sh
export PATH=$PATH:"/opt/Xilinx/SDK/2018.2/gnu/aarch32/lin/gcc-arm-linux-gnueabi/bin"
export CROSS_COMPILE="arm-linux-gnueabihf"
export Q7S_SYSROOT="$HOME/Xilinx/cortexa9hf-neon-xiphos-linux-gnueabi"

View File

@ -2,4 +2,4 @@
export PATH=$PATH:"/c/Xilinx/SDK/2018.2/gnu/aarch32/nt/gcc-arm-linux-gnueabi/bin"
export CROSS_COMPILE="arm-linux-gnueabihf"
export Q7S_SYSROOT="/c/Xilinx/SDK/2018.2/gnu/aarch32/nt/gcc-arm-linux-gnueabi/arm-linux-gnueabihf/libc"
export Q7S_SYSROOT="/c/Users/${USER}/Documents/EIVE/cortexa9hf-neon-xiphos-linux-gnueabi"

View File

@ -26,6 +26,9 @@ def main():
"Information)", default="debug")
parser.add_argument("-l", "--builddir", type=str, help="Specify build directory.")
parser.add_argument("-g", "--generator", type=str, help="CMake Generator")
parser.add_argument("-d", "--defines",
help="Additional custom defines passed to CMake (supply without -D prefix!)",
nargs="*", type=str)
parser.add_argument("-t", "--target-bsp", type=str, help="Target BSP, combination of architecture and machine")
args = parser.parse_args()

View File

@ -0,0 +1,10 @@
#ifndef COMMON_CONFIG_OBSWVERSION_H_
#define COMMON_CONFIG_OBSWVERSION_H_
const char* const SW_NAME = "eive";
#define SW_VERSION 1
#define SW_SUBVERSION 1
#define SW_SUBSUBVERSION 0
#endif /* COMMON_CONFIG_OBSWVERSION_H_ */

2
fsfw

@ -1 +1 @@
Subproject commit 83d0db824289b28dbad81cce0c80276c4fc839c8
Subproject commit 5273ffa721dd83634ebbcc37c4646752f0bea20f

1
fsfw_hal Submodule

@ -0,0 +1 @@
Subproject commit 14fe32572d62db9d19707dc1f9bb6fecb1993b73

View File

@ -17,8 +17,7 @@
#define FSFW_DISABLE_PRINTOUT 0
#endif
//! Can be used to disable the ANSI color sequences for C stdio.
#define FSFW_COLORED_OUTPUT 1
#define FSFW_USE_PUS_C_TELEMETRY 1
//! Can be used to disable the ANSI color sequences for C stdio.
#define FSFW_COLORED_OUTPUT 1
@ -43,10 +42,17 @@
//! Specify whether a special mode store is used for Subsystem components.
#define FSFW_USE_MODESTORE 0
//! Defines if the real time scheduler for linux should be used.
//! If set to 0, this will also disable priority settings for linux
//! as most systems will not allow to set nice values without privileges
//! For embedded linux system set this to 1.
//! If set to 1 the binary needs "cap_sys_nice=eip" privileges to run
#define FSFW_USE_REALTIME_FOR_LINUX 1
namespace fsfwconfig {
//! Default timestamp size. The default timestamp will be an eight byte CDC
//! short timestamp.
static constexpr uint8_t FSFW_MISSION_TIMESTAMP_SIZE = 8;
static constexpr uint8_t FSFW_MISSION_TIMESTAMP_SIZE = 7;
//! Configure the allocated pool sizes for the event manager.
static constexpr size_t FSFW_EVENTMGMR_MATCHTREE_NODES = 240;

View File

@ -8,6 +8,8 @@
#ifdef RASPBERRY_PI
#include <rpi_config.h>
#elif defined(XIPHOS_Q7S)
#include <q7s_config.h>
#endif
#include "commonConfig.h"
#include "OBSWVersion.h"
@ -24,12 +26,14 @@ debugging. */
#define P60DOCK_DEBUG 0
#define PDU1_DEBUG 0
#define PDU2_DEBUG 0
#define ACU_DEBUG 1
#define ACU_DEBUG 0
#define SYRLINKS_DEBUG 0
#define IMQT_DEBUG 1
#include "OBSWVersion.h"
/* Can be used to switch device to NORMAL mode immediately */
#define OBSW_SWITCH_TO_NORMAL_MODE_AFTER_STARTUP 1
/* Can be used for low-level debugging of the SPI bus */
#define FSFW_LINUX_SPI_WIRETAPPING 0
#ifdef __cplusplus

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@ -1,13 +0,0 @@
#ifndef FSFWCONFIG_OBSWVERSION_H_
#define FSFWCONFIG_OBSWVERSION_H_
//! TODO: Think of a cool name for the software releases.
const char* const SW_NAME = "eive";
#define SW_VERSION 1
#define SW_SUBVERSION 0
#define SW_SUBSUBVERSION 0
#endif /* FSFWCONFIG_OBSWVERSION_H_ */

View File

@ -26,10 +26,30 @@ namespace addresses {
};
enum i2cAddresses: address_t {
IMTQ = 16,
TMP1075_TCS_1 = 72,
TMP1075_TCS_2 = 73,
};
enum spiAddresses: address_t {
RTD_IC3,
RTD_IC4,
RTD_IC5,
RTD_IC6,
RTD_IC7,
RTD_IC8,
RTD_IC9,
RTD_IC10,
RTD_IC11,
RTD_IC12,
RTD_IC13,
RTD_IC14,
RTD_IC15,
RTD_IC16,
RTD_IC17,
RTD_IC18
};
/* Addresses of devices supporting the CSP protocol */
enum cspAddresses: uint8_t {
P60DOCK = 4,

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@ -1,7 +1,7 @@
#ifndef FSFWCONFIG_DEVICES_GPIOIDS_H_
#define FSFWCONFIG_DEVICES_GPIOIDS_H_
#include <linux/gpio/GpioIF.h>
#include <fsfw_hal/common/gpio/GpioIF.h>
namespace gpioIds {
enum gpioId_t {
@ -25,7 +25,31 @@ namespace gpioIds {
MGM_3_RM3100_CS,
TEST_ID_0,
TEST_ID_1
TEST_ID_1,
RTD_IC3,
RTD_IC4,
RTD_IC5,
RTD_IC6,
RTD_IC7,
RTD_IC8,
RTD_IC9,
RTD_IC10,
RTD_IC11,
RTD_IC12,
RTD_IC13,
RTD_IC14,
RTD_IC15,
RTD_IC16,
RTD_IC17,
RTD_IC18,
SPI_MUX_BIT_1,
SPI_MUX_BIT_2,
SPI_MUX_BIT_3,
SPI_MUX_BIT_4,
SPI_MUX_BIT_5,
SPI_MUX_BIT_6
};
}

View File

@ -2,7 +2,7 @@
#define FSFWCONFIG_DEVICES_SPI_H_
#include <cstdint>
#include <linux/spi/spiDefinitions.h>
#include <fsfw_hal/linux/spi/spiDefinitions.h>
/**
* SPI configuration will be contained here to let the device handlers remain independent

View File

@ -30,7 +30,8 @@ namespace objects {
ARDUINO_COM_IF = 0x49000001,
CSP_COM_IF = 0x49000002,
I2C_COM_IF = 0x49000003,
SPI_COM_IF = 0x49000004,
UART_COM_IF = 0x49000004,
SPI_COM_IF = 0x49000005,
/* 0x47 ('G') for Gpio Interfaces */
GPIO_IF = 0x47000001,
@ -42,7 +43,7 @@ namespace objects {
ACU_HANDLER = 0x44000004,
TMP1075_HANDLER_1 = 0x44000005,
TMP1075_HANDLER_2 = 0x44000006,
MGM_0_LIS3_HANDLER = 0x4400007,
MGM_0_LIS3_HANDLER = 0x44000007,
MGM_1_RM3100_HANDLER = 0x44000008,
MGM_2_LIS3_HANDLER = 0x44000009,
MGM_3_RM3100_HANDLER = 0x44000010,
@ -50,12 +51,35 @@ namespace objects {
GYRO_1_L3G_HANDLER = 0x44000012,
GYRO_2_L3G_HANDLER = 0x44000013,
IMTQ_HANDLER = 0x44000014,
/* Custom device handler */
PCDU_HANDLER = 0x44001000,
SOLAR_ARRAY_DEPL_HANDLER = 0x44001001,
SYRLINKS_HK_HANDLER = 0x44001002,
/* 0x54 ('T') for thermal objects */
HEATER_HANDLER = 0x54000003,
/**
* Not yet specified which pt1000 will measure which device/location in the satellite.
* Therefore object ids are named according to the IC naming of the RTDs in the schematic.
*/
RTD_IC3 = 0x54000004,
RTD_IC4 = 0x54000005,
RTD_IC5 = 0x54000006,
RTD_IC6 = 0x54000007,
RTD_IC7 = 0x54000008,
RTD_IC8 = 0x54000009,
RTD_IC9 = 0x5400000A,
RTD_IC10 = 0x5400000B,
RTD_IC11 = 0x5400000C,
RTD_IC12 = 0x5400000D,
RTD_IC13 = 0x5400000E,
RTD_IC14 = 0x5400000F,
RTD_IC15 = 0x5400001F,
RTD_IC16 = 0x5400002F,
RTD_IC17 = 0x5400003F,
RTD_IC18 = 0x5400004F,
/* 0x54 ('T') for test handlers */
TEST_TASK = 0x54694269,

View File

@ -1,5 +1,5 @@
#include "pollingSequenceFactory.h"
#include <OBSWConfig.h>
#include <fsfw/objectmanager/ObjectManagerIF.h>
#include <fsfw/serviceinterface/ServiceInterfaceStream.h>
#include <fsfw/devicehandlers/DeviceHandlerIF.h>
@ -20,18 +20,122 @@ ReturnValue_t pst::pollingSequenceInitDefault(FixedTimeslotTaskIF *thisSequence)
thisSequence->addSlot(objects::SOLAR_ARRAY_DEPL_HANDLER, length * 0,
DeviceHandlerIF::PERFORM_OPERATION);
#if Q7S_ADD_RTD_DEVICES == 1
thisSequence->addSlot(objects::RTD_IC3, length * 0, DeviceHandlerIF::PERFORM_OPERATION);
thisSequence->addSlot(objects::RTD_IC4, length * 0, DeviceHandlerIF::PERFORM_OPERATION);
thisSequence->addSlot(objects::RTD_IC5, length * 0, DeviceHandlerIF::PERFORM_OPERATION);
thisSequence->addSlot(objects::RTD_IC6, length * 0, DeviceHandlerIF::PERFORM_OPERATION);
thisSequence->addSlot(objects::RTD_IC7, length * 0, DeviceHandlerIF::PERFORM_OPERATION);
thisSequence->addSlot(objects::RTD_IC8, length * 0, DeviceHandlerIF::PERFORM_OPERATION);
thisSequence->addSlot(objects::RTD_IC9, length * 0, DeviceHandlerIF::PERFORM_OPERATION);
thisSequence->addSlot(objects::RTD_IC10, length * 0, DeviceHandlerIF::PERFORM_OPERATION);
thisSequence->addSlot(objects::RTD_IC11, length * 0, DeviceHandlerIF::PERFORM_OPERATION);
thisSequence->addSlot(objects::RTD_IC12, length * 0, DeviceHandlerIF::PERFORM_OPERATION);
thisSequence->addSlot(objects::RTD_IC13, length * 0, DeviceHandlerIF::PERFORM_OPERATION);
thisSequence->addSlot(objects::RTD_IC14, length * 0, DeviceHandlerIF::PERFORM_OPERATION);
thisSequence->addSlot(objects::RTD_IC15, length * 0, DeviceHandlerIF::PERFORM_OPERATION);
thisSequence->addSlot(objects::RTD_IC16, length * 0, DeviceHandlerIF::PERFORM_OPERATION);
thisSequence->addSlot(objects::RTD_IC17, length * 0, DeviceHandlerIF::PERFORM_OPERATION);
thisSequence->addSlot(objects::RTD_IC18, length * 0, DeviceHandlerIF::PERFORM_OPERATION);
#endif /* Q7S_ADD_RTD_DEVICES */
thisSequence->addSlot(objects::IMTQ_HANDLER, length * 0, DeviceHandlerIF::PERFORM_OPERATION);
thisSequence->addSlot(objects::TMP1075_HANDLER_1, length * 0.2, DeviceHandlerIF::SEND_WRITE);
thisSequence->addSlot(objects::TMP1075_HANDLER_2, length * 0.2, DeviceHandlerIF::SEND_WRITE);
#if Q7S_ADD_RTD_DEVICES == 1
thisSequence->addSlot(objects::RTD_IC3, length * 0.2, DeviceHandlerIF::SEND_WRITE);
thisSequence->addSlot(objects::RTD_IC4, length * 0.2, DeviceHandlerIF::SEND_WRITE);
thisSequence->addSlot(objects::RTD_IC5, length * 0.2, DeviceHandlerIF::SEND_WRITE);
thisSequence->addSlot(objects::RTD_IC6, length * 0.2, DeviceHandlerIF::SEND_WRITE);
thisSequence->addSlot(objects::RTD_IC7, length * 0.2, DeviceHandlerIF::SEND_WRITE);
thisSequence->addSlot(objects::RTD_IC8, length * 0.2, DeviceHandlerIF::SEND_WRITE);
thisSequence->addSlot(objects::RTD_IC9, length * 0.2, DeviceHandlerIF::SEND_WRITE);
thisSequence->addSlot(objects::RTD_IC10, length * 0.2, DeviceHandlerIF::SEND_WRITE);
thisSequence->addSlot(objects::RTD_IC11, length * 0.2, DeviceHandlerIF::SEND_WRITE);
thisSequence->addSlot(objects::RTD_IC12, length * 0.2, DeviceHandlerIF::SEND_WRITE);
thisSequence->addSlot(objects::RTD_IC13, length * 0.2, DeviceHandlerIF::SEND_WRITE);
thisSequence->addSlot(objects::RTD_IC14, length * 0.2, DeviceHandlerIF::SEND_WRITE);
thisSequence->addSlot(objects::RTD_IC15, length * 0.2, DeviceHandlerIF::SEND_WRITE);
thisSequence->addSlot(objects::RTD_IC16, length * 0.2, DeviceHandlerIF::SEND_WRITE);
thisSequence->addSlot(objects::RTD_IC17, length * 0.2, DeviceHandlerIF::SEND_WRITE);
thisSequence->addSlot(objects::RTD_IC18, length * 0.2, DeviceHandlerIF::SEND_WRITE);
#endif /* Q7S_ADD_RTD_DEVICES */
thisSequence->addSlot(objects::IMTQ_HANDLER, length * 0.2, DeviceHandlerIF::SEND_WRITE);
thisSequence->addSlot(objects::TMP1075_HANDLER_1, length * 0.4, DeviceHandlerIF::GET_WRITE);
thisSequence->addSlot(objects::TMP1075_HANDLER_2, length * 0.4, DeviceHandlerIF::GET_WRITE);
#if Q7S_ADD_RTD_DEVICES == 1
thisSequence->addSlot(objects::RTD_IC3, length * 0.4, DeviceHandlerIF::GET_WRITE);
thisSequence->addSlot(objects::RTD_IC4, length * 0.4, DeviceHandlerIF::GET_WRITE);
thisSequence->addSlot(objects::RTD_IC5, length * 0.4, DeviceHandlerIF::GET_WRITE);
thisSequence->addSlot(objects::RTD_IC6, length * 0.4, DeviceHandlerIF::GET_WRITE);
thisSequence->addSlot(objects::RTD_IC7, length * 0.4, DeviceHandlerIF::GET_WRITE);
thisSequence->addSlot(objects::RTD_IC8, length * 0.4, DeviceHandlerIF::GET_WRITE);
thisSequence->addSlot(objects::RTD_IC9, length * 0.4, DeviceHandlerIF::GET_WRITE);
thisSequence->addSlot(objects::RTD_IC10, length * 0.4, DeviceHandlerIF::GET_WRITE);
thisSequence->addSlot(objects::RTD_IC11, length * 0.4, DeviceHandlerIF::GET_WRITE);
thisSequence->addSlot(objects::RTD_IC12, length * 0.4, DeviceHandlerIF::GET_WRITE);
thisSequence->addSlot(objects::RTD_IC13, length * 0.4, DeviceHandlerIF::GET_WRITE);
thisSequence->addSlot(objects::RTD_IC14, length * 0.4, DeviceHandlerIF::GET_WRITE);
thisSequence->addSlot(objects::RTD_IC15, length * 0.4, DeviceHandlerIF::GET_WRITE);
thisSequence->addSlot(objects::RTD_IC16, length * 0.4, DeviceHandlerIF::GET_WRITE);
thisSequence->addSlot(objects::RTD_IC17, length * 0.4, DeviceHandlerIF::GET_WRITE);
thisSequence->addSlot(objects::RTD_IC18, length * 0.4, DeviceHandlerIF::GET_WRITE);
thisSequence->addSlot(objects::IMTQ_HANDLER, length * 0.4, DeviceHandlerIF::GET_WRITE);
#endif /* Q7S_ADD_RTD_DEVICES */
thisSequence->addSlot(objects::TMP1075_HANDLER_1, length * 0.6, DeviceHandlerIF::SEND_READ);
thisSequence->addSlot(objects::TMP1075_HANDLER_2, length * 0.6, DeviceHandlerIF::SEND_READ);
#if Q7S_ADD_RTD_DEVICES == 1
thisSequence->addSlot(objects::RTD_IC3, length * 0.6, DeviceHandlerIF::SEND_READ);
thisSequence->addSlot(objects::RTD_IC4, length * 0.6, DeviceHandlerIF::SEND_READ);
thisSequence->addSlot(objects::RTD_IC5, length * 0.6, DeviceHandlerIF::SEND_READ);
thisSequence->addSlot(objects::RTD_IC6, length * 0.6, DeviceHandlerIF::SEND_READ);
thisSequence->addSlot(objects::RTD_IC7, length * 0.6, DeviceHandlerIF::SEND_READ);
thisSequence->addSlot(objects::RTD_IC8, length * 0.6, DeviceHandlerIF::SEND_READ);
thisSequence->addSlot(objects::RTD_IC9, length * 0.6, DeviceHandlerIF::SEND_READ);
thisSequence->addSlot(objects::RTD_IC10, length * 0.6, DeviceHandlerIF::SEND_READ);
thisSequence->addSlot(objects::RTD_IC11, length * 0.6, DeviceHandlerIF::SEND_READ);
thisSequence->addSlot(objects::RTD_IC12, length * 0.6, DeviceHandlerIF::SEND_READ);
thisSequence->addSlot(objects::RTD_IC13, length * 0.6, DeviceHandlerIF::SEND_READ);
thisSequence->addSlot(objects::RTD_IC14, length * 0.6, DeviceHandlerIF::SEND_READ);
thisSequence->addSlot(objects::RTD_IC15, length * 0.6, DeviceHandlerIF::SEND_READ);
thisSequence->addSlot(objects::RTD_IC16, length * 0.6, DeviceHandlerIF::SEND_READ);
thisSequence->addSlot(objects::RTD_IC17, length * 0.6, DeviceHandlerIF::SEND_READ);
thisSequence->addSlot(objects::RTD_IC18, length * 0.6, DeviceHandlerIF::SEND_READ);
#endif /* Q7S_ADD_RTD_DEVICES */
thisSequence->addSlot(objects::IMTQ_HANDLER, length * 0.6, DeviceHandlerIF::SEND_READ);
thisSequence->addSlot(objects::TMP1075_HANDLER_1, length * 0.8, DeviceHandlerIF::GET_READ);
thisSequence->addSlot(objects::TMP1075_HANDLER_2, length * 0.8, DeviceHandlerIF::GET_READ);
#if Q7S_ADD_RTD_DEVICES == 1
thisSequence->addSlot(objects::RTD_IC3, length * 0.8, DeviceHandlerIF::GET_READ);
thisSequence->addSlot(objects::RTD_IC4, length * 0.8, DeviceHandlerIF::GET_READ);
thisSequence->addSlot(objects::RTD_IC5, length * 0.8, DeviceHandlerIF::GET_READ);
thisSequence->addSlot(objects::RTD_IC6, length * 0.8, DeviceHandlerIF::GET_READ);
thisSequence->addSlot(objects::RTD_IC7, length * 0.8, DeviceHandlerIF::GET_READ);
thisSequence->addSlot(objects::RTD_IC8, length * 0.8, DeviceHandlerIF::GET_READ);
thisSequence->addSlot(objects::RTD_IC9, length * 0.8, DeviceHandlerIF::GET_READ);
thisSequence->addSlot(objects::RTD_IC10, length * 0.8, DeviceHandlerIF::GET_READ);
thisSequence->addSlot(objects::RTD_IC11, length * 0.8, DeviceHandlerIF::GET_READ);
thisSequence->addSlot(objects::RTD_IC12, length * 0.8, DeviceHandlerIF::GET_READ);
thisSequence->addSlot(objects::RTD_IC13, length * 0.8, DeviceHandlerIF::GET_READ);
thisSequence->addSlot(objects::RTD_IC14, length * 0.8, DeviceHandlerIF::GET_READ);
thisSequence->addSlot(objects::RTD_IC15, length * 0.8, DeviceHandlerIF::GET_READ);
thisSequence->addSlot(objects::RTD_IC16, length * 0.8, DeviceHandlerIF::GET_READ);
thisSequence->addSlot(objects::RTD_IC17, length * 0.8, DeviceHandlerIF::GET_READ);
thisSequence->addSlot(objects::RTD_IC18, length * 0.8, DeviceHandlerIF::GET_READ);
#endif /* Q7S_ADD_RTD_DEVICES */
thisSequence->addSlot(objects::IMTQ_HANDLER, length * 0.8, DeviceHandlerIF::GET_READ);
if (thisSequence->checkSequence() == HasReturnvaluesIF::RETURN_OK) {
return HasReturnvaluesIF::RETURN_OK;
}
@ -91,6 +195,52 @@ ReturnValue_t pst::gomspacePstInit(FixedTimeslotTaskIF *thisSequence){
thisSequence->addSlot(objects::ACU_HANDLER,
length * 0.8, DeviceHandlerIF::GET_READ);
#if OBSW_ADD_ACS_BOARD == 1
// thisSequence->addSlot(objects::MGM_0_LIS3_HANDLER, length * 0,
// DeviceHandlerIF::PERFORM_OPERATION);
// thisSequence->addSlot(objects::MGM_0_LIS3_HANDLER, length * 0.2,
// DeviceHandlerIF::SEND_WRITE);
// thisSequence->addSlot(objects::MGM_0_LIS3_HANDLER, length * 0.4,
// DeviceHandlerIF::GET_WRITE);
// thisSequence->addSlot(objects::MGM_0_LIS3_HANDLER, length * 0.6,
// DeviceHandlerIF::SEND_READ);
// thisSequence->addSlot(objects::MGM_0_LIS3_HANDLER, length * 0.8,
// DeviceHandlerIF::GET_READ);
//
// thisSequence->addSlot(objects::MGM_1_RM3100_HANDLER, length * 0,
// DeviceHandlerIF::PERFORM_OPERATION);
// thisSequence->addSlot(objects::MGM_1_RM3100_HANDLER, length * 0.2,
// DeviceHandlerIF::SEND_WRITE);
// thisSequence->addSlot(objects::MGM_1_RM3100_HANDLER, length * 0.4,
// DeviceHandlerIF::GET_WRITE);
// thisSequence->addSlot(objects::MGM_1_RM3100_HANDLER, length * 0.6,
// DeviceHandlerIF::SEND_READ);
// thisSequence->addSlot(objects::MGM_1_RM3100_HANDLER, length * 0.8,
// DeviceHandlerIF::GET_READ);
thisSequence->addSlot(objects::MGM_2_LIS3_HANDLER, length * 0,
DeviceHandlerIF::PERFORM_OPERATION);
thisSequence->addSlot(objects::MGM_2_LIS3_HANDLER, length * 0.2,
DeviceHandlerIF::SEND_WRITE);
thisSequence->addSlot(objects::MGM_2_LIS3_HANDLER, length * 0.4,
DeviceHandlerIF::GET_WRITE);
thisSequence->addSlot(objects::MGM_2_LIS3_HANDLER, length * 0.6,
DeviceHandlerIF::SEND_READ);
thisSequence->addSlot(objects::MGM_2_LIS3_HANDLER, length * 0.8,
DeviceHandlerIF::GET_READ);
// thisSequence->addSlot(objects::GYRO_1_L3G_HANDLER, length * 0,
// DeviceHandlerIF::PERFORM_OPERATION);
// thisSequence->addSlot(objects::GYRO_1_L3G_HANDLER, length * 0.2,
// DeviceHandlerIF::SEND_WRITE);
// thisSequence->addSlot(objects::GYRO_1_L3G_HANDLER, length * 0.4,
// DeviceHandlerIF::GET_WRITE);
// thisSequence->addSlot(objects::GYRO_1_L3G_HANDLER, length * 0.6,
// DeviceHandlerIF::SEND_READ);
// thisSequence->addSlot(objects::GYRO_1_L3G_HANDLER, length * 0.8,
// DeviceHandlerIF::GET_READ);
#endif
if (thisSequence->checkSequence() != HasReturnvaluesIF::RETURN_OK) {
sif::error << "Initialization of GomSpace PST failed" << std::endl;
return HasReturnvaluesIF::RETURN_FAILED;

View File

@ -17,7 +17,9 @@ enum {
LINUX_SPI_COM_IF,
PCDU_HANDLER,
HEATER_HANDLER,
SA_DEPL_HANDLER
SA_DEPL_HANDLER,
SYRLINKS_HANDLER,
IMTQ_HANDLER,
};
}

1
generators/modgen Submodule

@ -0,0 +1 @@
Subproject commit 5ed4a2ae59e90c3763616bdaf41eb3317e849100

View File

@ -1,7 +1,4 @@
add_subdirectory(gpio)
add_subdirectory(i2c)
add_subdirectory(csp)
add_subdirectory(spi)
add_subdirectory(uart)
add_subdirectory(utility)
add_subdirectory(boardtest)

View File

@ -4,14 +4,18 @@
GpioCookie::GpioCookie() {
}
ReturnValue_t GpioCookie::addGpio(gpioId_t gpioId, GpiodRegular& gpioConfig){
ReturnValue_t GpioCookie::addGpio(gpioId_t gpioId, GpioBase* gpioConfig){
if (gpioConfig == nullptr) {
sif::debug << "GpioCookie::addGpio: gpioConfig is nullpointer" << std::endl;
return HasReturnvaluesIF::RETURN_FAILED;
}
auto gpioMapIter = gpioMap.find(gpioId);
if(gpioMapIter == gpioMap.end()) {
auto statusPair = gpioMap.emplace(gpioId, new GpiodRegular(gpioConfig));
auto statusPair = gpioMap.emplace(gpioId, gpioConfig);
if (statusPair.second == false) {
#if FSFW_VERBOSE_LEVEL >= 1
sif::error << "GpioCookie::addGpio: Failed to add GPIO " << gpioId <<
"to GPIO map" << std::endl;
" to GPIO map" << std::endl;
#endif
return HasReturnvaluesIF::RETURN_FAILED;
}

View File

@ -23,7 +23,7 @@ public:
virtual ~GpioCookie();
ReturnValue_t addGpio(gpioId_t gpioId, GpiodRegular& gpioConfig);
ReturnValue_t addGpio(gpioId_t gpioId, GpioBase* gpioConfig);
/**
* @brief Get map with registered GPIOs.
*/

View File

@ -56,11 +56,11 @@ ReturnValue_t LinuxLibgpioIF::configureGpios(GpioMap& mapToAdd) {
break;
}
case(gpio::GpioTypes::CALLBACK): {
auto gpioCallback = dynamic_cast<GpioCallback*>(gpioMapIter->second);
auto gpioCallback = dynamic_cast<GpioCallback*>(gpioConfig.second);
if(gpioCallback->callback == nullptr) {
return GPIO_INVALID_INSTANCE;
}
gpioCallback->callback(gpioMapIter->first, gpio::GpioOperation::READ,
gpioCallback->callback(gpioConfig.first, gpio::GpioOperation::WRITE,
gpioCallback->initValue, gpioCallback->callbackArgs);
}
}
@ -88,7 +88,8 @@ ReturnValue_t LinuxLibgpioIF::configureRegularGpio(gpioId_t gpioId, GpiodRegular
lineNum = regularGpio->lineNum;
lineHandle = gpiod_chip_get_line(chip, lineNum);
if (!lineHandle) {
sif::error << "LinuxLibgpioIF::configureGpios: Failed to open line" << std::endl;
sif::error << "LinuxLibgpioIF::configureGpios: Failed to open line for GPIO with id "
<< gpioId << std::endl;
gpiod_chip_close(chip);
return RETURN_FAILED;
}

View File

@ -7,6 +7,12 @@
using gpioId_t = uint16_t;
namespace gpio {
enum Levels {
LOW = 0,
HIGH = 1
};
enum Direction {
IN = 0,
OUT = 1

View File

@ -2,8 +2,8 @@
#define TEST_TESTTASKS_LIBGPIODTEST_H_
#include "TestTask.h"
#include <linux/gpio/GpioIF.h>
#include <linux/gpio/GpioCookie.h>
#include <fsfw_hal/common/gpio/GpioIF.h>
#include <fsfw_hal/common/gpio/GpioCookie.h>
#include <fsfw/objectmanager/SystemObject.h>
/**

View File

@ -7,19 +7,21 @@
#include <fsfw/tasks/TaskFactory.h>
#include <fsfw/timemanager/Stopwatch.h>
#include <linux/gpio/gpioDefinitions.h>
#include <linux/gpio/GpioCookie.h>
#include <linux/utility/Utility.h>
#include <fsfw_hal/linux/utility.h>
#include <fsfw_hal/linux/UnixFileGuard.h>
#include <fsfw_hal/common/gpio/gpioDefinitions.h>
#include <fsfw_hal/common/gpio/GpioCookie.h>
#include <linux/spi/spidev.h>
#include <fcntl.h>
#include <unistd.h>
#include <sys/ioctl.h>
#include <bitset>
SpiTestClass::SpiTestClass(object_id_t objectId, GpioIF* gpioIF): TestTask(objectId),
gpioIF(gpioIF) {
gpioIF(gpioIF) {
if(gpioIF == nullptr) {
sif::error << "SpiTestClass::SpiTestClass: Invalid GPIO ComIF!" << std::endl;
}
@ -34,11 +36,11 @@ ReturnValue_t SpiTestClass::performOneShotAction() {
break;
}
case(TestModes::MGM_LIS3MDL): {
performLis3MdlTest(mgm0Lis3ChipSelect);
performLis3MdlTest(mgm2Lis3mdlChipSelect);
break;
}
case(TestModes::MGM_RM3100): {
performRm3100Test(mgm1Rm3100ChipSelect);
performRm3100Test(mgm3Rm3100ChipSelect);
break;
}
case(TestModes::GYRO_L3GD20H): {
@ -76,12 +78,12 @@ void SpiTestClass::performRm3100Test(uint8_t mgmId) {
#ifdef RASPBERRY_PI
std::string deviceName = "/dev/spidev0.0";
#else
std::string deviceName = "placeholder";
std::string deviceName = "/dev/spidev2.0";
#endif
int fileDescriptor = 0;
utility::UnixFileHelper fileHelper(deviceName, &fileDescriptor, O_RDWR,
UnixFileGuard fileHelper(deviceName, &fileDescriptor, O_RDWR,
"SpiComIF::initializeInterface: ");
if(fileHelper.getOpenResult()) {
sif::error << "SpiTestClass::performRm3100Test: File descriptor could not be opened!"
@ -158,13 +160,14 @@ void SpiTestClass::performLis3MdlTest(uint8_t lis3Id) {
acsInit();
/* Adapt accordingly */
if(lis3Id != mgm0Lis3ChipSelect and lis3Id != mgm2Lis3mdlChipSelect) {
if(lis3Id != mgm0Lis3mdlChipSelect and lis3Id != mgm2Lis3mdlChipSelect) {
sif::warning << "SpiTestClass::performLis3MdlTest: Invalid MGM ID!" << std::endl;
}
gpioId_t currentGpioId = 0;
uint8_t chipSelectPin = lis3Id;
uint8_t whoAmIReg = 0b0000'1111;
if(chipSelectPin == mgm0Lis3ChipSelect) {
uint8_t whoAmIRegExpectedVal = 0b0011'1101;
if(chipSelectPin == mgm0Lis3mdlChipSelect) {
currentGpioId = gpioIds::MGM_0_LIS3_CS;
}
else {
@ -175,11 +178,11 @@ void SpiTestClass::performLis3MdlTest(uint8_t lis3Id) {
#ifdef RASPBERRY_PI
std::string deviceName = "/dev/spidev0.0";
#else
std::string deviceName = "placeholder";
std::string deviceName = "/dev/spidev2.0";
#endif
int fileDescriptor = 0;
utility::UnixFileHelper fileHelper(deviceName, &fileDescriptor, O_RDWR,
UnixFileGuard fileHelper(deviceName, &fileDescriptor, O_RDWR,
"SpiComIF::initializeInterface: ");
if(fileHelper.getOpenResult()) {
sif::error << "SpiTestClass::performLis3Mdl3100Test: File descriptor could not be opened!"
@ -187,10 +190,15 @@ void SpiTestClass::performLis3MdlTest(uint8_t lis3Id) {
return;
}
setSpiSpeedAndMode(fileDescriptor, spiMode, spiSpeed);
spiTransferStruct.delay_usecs = 0;
uint8_t whoAmIRegVal = readStmRegister(fileDescriptor, currentGpioId, whoAmIReg, false);
sif::info << "SpiTestClass::performLis3MdlTest: WHO AM I register 0b" <<
std::bitset<8>(whoAmIRegVal) << std::endl;
if(whoAmIRegVal != whoAmIRegExpectedVal) {
sif::warning << "SpiTestClass::performLis3MdlTest: WHO AM I register invalid!"
<< std::endl;
}
}
@ -221,11 +229,11 @@ void SpiTestClass::performL3gTest(uint8_t l3gId) {
#ifdef RASPBERRY_PI
std::string deviceName = "/dev/spidev0.0";
#else
std::string deviceName = "placeholder";
std::string deviceName = "/dev/spidev2.0";
#endif
int fileDescriptor = 0;
utility::UnixFileHelper fileHelper(deviceName, &fileDescriptor, O_RDWR,
UnixFileGuard fileHelper(deviceName, &fileDescriptor, O_RDWR,
"SpiComIF::initializeInterface: ");
if(fileHelper.getOpenResult()) {
sif::error << "SpiTestClass::performLis3Mdl3100Test: File descriptor could not be opened!"
@ -257,8 +265,8 @@ void SpiTestClass::performL3gTest(uint8_t l3gId) {
sizeof(readRegs));
for(uint8_t idx = 0; idx < sizeof(readRegs); idx++) {
if(readRegs[idx] != commandRegs[0]) {
sif::warning << "SpiTestClass::performL3gTest: Read control register" <<
static_cast<int>(idx + 1) << "not equal to configured value" << std::endl;
sif::warning << "SpiTestClass::performL3gTest: Read control register " <<
static_cast<int>(idx + 1) << " not equal to configured value" << std::endl;
}
}
}
@ -289,46 +297,70 @@ void SpiTestClass::performL3gTest(uint8_t l3gId) {
}
void SpiTestClass::acsInit() {
GpioCookie* gpioCookie = new GpioCookie();
GpiodRegular* gpio = nullptr;
#ifdef RASPBERRY_PI
std::string rpiGpioName = "gpiochip0";
{
GpiodRegular gpio(rpiGpioName, mgm0Lis3ChipSelect, "MGM_0_LIS3",
gpio = new GpiodRegular(rpiGpioName, mgm0Lis3mdlChipSelect, "MGM_0_LIS3",
gpio::Direction::OUT, 1);
gpioCookie->addGpio(gpioIds::MGM_0_LIS3_CS, gpio);
}
{
GpiodRegular gpio(rpiGpioName, mgm1Rm3100ChipSelect, "MGM_1_RM3100",
gpio = new GpiodRegular(rpiGpioName, mgm1Rm3100ChipSelect, "MGM_1_RM3100",
gpio::Direction::OUT, 1);
gpioCookie->addGpio(gpioIds::MGM_1_RM3100_CS, gpio);
}
{
GpiodRegular gpio(rpiGpioName, gyro0AdisChipSelect, "GYRO_0_ADIS",
gpio = new GpiodRegular(rpiGpioName, gyro0AdisChipSelect, "GYRO_0_ADIS",
gpio::Direction::OUT, 1);
gpioCookie->addGpio(gpioIds::GYRO_0_ADIS_CS, gpio);
}
{
GpiodRegular gpio(rpiGpioName, gyro1L3gd20ChipSelect, "GYRO_1_L3G",
gpio = new GpiodRegular(rpiGpioName, gyro1L3gd20ChipSelect, "GYRO_1_L3G",
gpio::Direction::OUT, 1);
gpioCookie->addGpio(gpioIds::GYRO_1_L3G_CS, gpio);
}
{
GpiodRegular gpio(rpiGpioName, gyro2L3gd20ChipSelect, "GYRO_2_L3G",
gpio = new GpiodRegular(rpiGpioName, gyro2L3gd20ChipSelect, "GYRO_2_L3G",
gpio::Direction::OUT, 1);
gpioCookie->addGpio(gpioIds::GYRO_2_L3G_CS, gpio);
}
{
GpiodRegular gpio(rpiGpioName, mgm2Lis3mdlChipSelect, "MGM_2_LIS3",
gpio = new GpiodRegular(rpiGpioName, mgm2Lis3mdlChipSelect, "MGM_2_LIS3",
gpio::Direction::OUT, 1);
gpioCookie->addGpio(gpioIds::MGM_2_LIS3_CS, gpio);
}
{
GpiodRegular gpio(rpiGpioName, mgm3Rm3100ChipSelect, "MGM_3_RM3100",
gpio = new GpiodRegular(rpiGpioName, mgm3Rm3100ChipSelect, "MGM_3_RM3100",
gpio::Direction::OUT, 1);
gpioCookie->addGpio(gpioIds::MGM_3_RM3100_CS, gpio);
}
#elif defined(XIPHOS_Q7S)
std::string q7sGpioName5 = "gpiochip5";
std::string q7sGpioName6 = "gpiochip6";
gpio = new GpiodRegular(q7sGpioName5, mgm0Lis3mdlChipSelect, "MGM_0_LIS3",
gpio::Direction::OUT, gpio::HIGH);
gpioCookie->addGpio(gpioIds::MGM_0_LIS3_CS, gpio);
gpio = new GpiodRegular(q7sGpioName5, mgm1Rm3100ChipSelect, "MGM_1_RM3100",
gpio::Direction::OUT, gpio::HIGH);
gpioCookie->addGpio(gpioIds::MGM_1_RM3100_CS, gpio);
gpio = new GpiodRegular(q7sGpioName5, gyro0AdisChipSelect, "GYRO_0_ADIS",
gpio::Direction::OUT, gpio::HIGH);
gpioCookie->addGpio(gpioIds::GYRO_0_ADIS_CS, gpio);
gpio = new GpiodRegular(q7sGpioName5, gyro1L3gd20ChipSelect, "GYRO_1_L3G",
gpio::Direction::OUT, gpio::HIGH);
gpioCookie->addGpio(gpioIds::GYRO_1_L3G_CS, gpio);
gpio = new GpiodRegular(q7sGpioName5, gyro2L3gd20ChipSelect, "GYRO_2_L3G",
gpio::Direction::OUT, gpio::HIGH);
gpioCookie->addGpio(gpioIds::GYRO_2_L3G_CS, gpio);
gpio = new GpiodRegular(q7sGpioName6, mgm2Lis3mdlChipSelect, "MGM_2_LIS3",
gpio::Direction::OUT, gpio::HIGH);
gpioCookie->addGpio(gpioIds::MGM_2_LIS3_CS, gpio);
gpio = new GpiodRegular(q7sGpioName5, mgm3Rm3100ChipSelect, "MGM_3_RM3100",
gpio::Direction::OUT, gpio::HIGH);
gpioCookie->addGpio(gpioIds::MGM_3_RM3100_CS, gpio);
#endif
if(gpioIF != nullptr) {
gpioIF->addGpios(gpioCookie);
}
@ -471,4 +503,3 @@ uint8_t SpiTestClass::readRegister(int fd, gpioId_t chipSelect, uint8_t reg) {
}
return recvBuffer[1];
}

View File

@ -1,8 +1,8 @@
#ifndef LINUX_BOARDTEST_SPITESTCLASS_H_
#define LINUX_BOARDTEST_SPITESTCLASS_H_
#include <linux/gpio/GpioIF.h>
#include <linux/spi/SpiCookie.h>
#include <fsfw_hal/common/gpio/GpioIF.h>
#include <fsfw_hal/linux/spi/SpiCookie.h>
#include <test/testtasks/TestTask.h>
#include <vector>
@ -38,13 +38,24 @@ private:
void acsInit();
/* ACS board specific variables */
uint8_t mgm0Lis3ChipSelect = 0;
#ifdef RASPBERRY_PI
uint8_t mgm0Lis3mdlChipSelect = 0;
uint8_t mgm1Rm3100ChipSelect = 1;
uint8_t gyro0AdisChipSelect = 5;
uint8_t gyro1L3gd20ChipSelect = 6;
uint8_t gyro2L3gd20ChipSelect = 4;
uint8_t mgm2Lis3mdlChipSelect = 17;
uint8_t mgm3Rm3100ChipSelect = 27;
#elif defined(XIPHOS_Q7S)
uint8_t mgm0Lis3mdlChipSelect = 5;
uint8_t mgm1Rm3100ChipSelect = 17;
uint8_t gyro0AdisResetLine = 20;
uint8_t gyro0AdisChipSelect = 21;
uint8_t gyro1L3gd20ChipSelect = 10;
uint8_t gyro2L3gd20ChipSelect = 3;
uint8_t mgm2Lis3mdlChipSelect = 0;
uint8_t mgm3Rm3100ChipSelect = 23;
#endif
static constexpr uint8_t STM_READ_MASK = 0b1000'0000;
static constexpr uint8_t RM3100_READ_MASK = STM_READ_MASK;

View File

@ -28,7 +28,7 @@ ReturnValue_t CspComIF::initializeInterface(CookieIF *cookie) {
int buf_count = 10;
int buf_size = 300;
/* Init CSP and CSP buffer system */
if (csp_init(cspClientAddress) != CSP_ERR_NONE
if (csp_init(cspOwnAddress) != CSP_ERR_NONE
|| csp_buffer_init(buf_count, buf_size) != CSP_ERR_NONE) {
sif::error << "Failed to init CSP\r\n" << std::endl;
return HasReturnvaluesIF::RETURN_FAILED;

View File

@ -65,7 +65,7 @@ private:
uint16_t replySize = 0;
/* This is the CSP address of the OBC. */
node_t cspClientAddress = 1;
node_t cspOwnAddress = 1;
/* Interface struct for csp protocol stack */
csp_iface_t csp_if;

View File

@ -1,196 +0,0 @@
#include "I2cComIF.h"
#include <fsfw/serviceinterface/ServiceInterface.h>
#include <unistd.h>
#include <fcntl.h>
#include <sys/ioctl.h>
#include <linux/i2c-dev.h>
#include <errno.h>
#include <linux/utility/Utility.h>
#include <cstring>
I2cComIF::I2cComIF(object_id_t objectId): SystemObject(objectId){
}
I2cComIF::~I2cComIF() {}
ReturnValue_t I2cComIF::initializeInterface(CookieIF* cookie) {
address_t i2cAddress;
std::string deviceFile;
if(cookie == nullptr) {
sif::error << "I2cComIF::initializeInterface: Invalid cookie!" << std::endl;
return NULLPOINTER;
}
I2cCookie* i2cCookie = dynamic_cast<I2cCookie*>(cookie);
if(i2cCookie == nullptr) {
sif::error << "I2cComIF::initializeInterface: Invalid I2C cookie!" << std::endl;
return NULLPOINTER;
}
i2cAddress = i2cCookie->getAddress();
i2cDeviceMapIter = i2cDeviceMap.find(i2cAddress);
if(i2cDeviceMapIter == i2cDeviceMap.end()) {
size_t maxReplyLen = i2cCookie->getMaxReplyLen();
I2cInstance_t i2cInstance = {std::vector<uint8_t>(maxReplyLen), 0};
auto statusPair = i2cDeviceMap.emplace(i2cAddress, i2cInstance);
if (not statusPair.second) {
sif::error << "I2cComIF::initializeInterface: Failed to insert device with address " <<
i2cAddress << "to I2C device " << "map" << std::endl;
return HasReturnvaluesIF::RETURN_FAILED;
}
return HasReturnvaluesIF::RETURN_OK;
}
sif::error << "I2cComIF::initializeInterface: Device with address " << i2cAddress <<
"already in use" << std::endl;
return HasReturnvaluesIF::RETURN_FAILED;
}
ReturnValue_t I2cComIF::sendMessage(CookieIF *cookie,
const uint8_t *sendData, size_t sendLen) {
ReturnValue_t result;
int fd;
std::string deviceFile;
if(sendData == nullptr) {
sif::error << "I2cComIF::sendMessage: Send Data is nullptr"
<< std::endl;
return HasReturnvaluesIF::RETURN_FAILED;
}
if(sendLen == 0) {
return HasReturnvaluesIF::RETURN_OK;
}
I2cCookie* i2cCookie = dynamic_cast<I2cCookie*>(cookie);
if(i2cCookie == nullptr) {
sif::error << "I2cComIF::sendMessage: Invalid I2C Cookie!" << std::endl;
return NULLPOINTER;
}
address_t i2cAddress = i2cCookie->getAddress();
i2cDeviceMapIter = i2cDeviceMap.find(i2cAddress);
if (i2cDeviceMapIter == i2cDeviceMap.end()) {
sif::error << "I2cComIF::sendMessage: i2cAddress of Cookie not "
<< "registered in i2cDeviceMap" << std::endl;
return HasReturnvaluesIF::RETURN_FAILED;
}
deviceFile = i2cCookie->getDeviceFile();
utility::UnixFileHelper fileHelper(deviceFile, &fd, O_RDWR, "I2cComIF::sendMessage");
if(fileHelper.getOpenResult() != HasReturnvaluesIF::RETURN_OK) {
return fileHelper.getOpenResult();
}
result = openDevice(deviceFile, i2cAddress, &fd);
if (result != HasReturnvaluesIF::RETURN_OK){
return result;
}
if (write(fd, sendData, sendLen) != (int)sendLen) {
sif::error << "I2cComIF::sendMessage: Failed to send data to I2C "
"device with error code " << errno << ". Error description: "
<< strerror(errno) << std::endl;
return HasReturnvaluesIF::RETURN_FAILED;
}
return HasReturnvaluesIF::RETURN_OK;
}
ReturnValue_t I2cComIF::getSendSuccess(CookieIF *cookie) {
return HasReturnvaluesIF::RETURN_OK;
}
ReturnValue_t I2cComIF::requestReceiveMessage(CookieIF *cookie,
size_t requestLen) {
ReturnValue_t result;
int fd;
std::string deviceFile;
if (requestLen == 0) {
return HasReturnvaluesIF::RETURN_OK;
}
I2cCookie* i2cCookie = dynamic_cast<I2cCookie*>(cookie);
if(i2cCookie == nullptr) {
sif::error << "I2cComIF::requestReceiveMessage: Invalid I2C Cookie!" << std::endl;
i2cDeviceMapIter->second.replyLen = 0;
return NULLPOINTER;
}
address_t i2cAddress = i2cCookie->getAddress();
i2cDeviceMapIter = i2cDeviceMap.find(i2cAddress);
if (i2cDeviceMapIter == i2cDeviceMap.end()) {
sif::error << "I2cComIF::requestReceiveMessage: i2cAddress of Cookie not "
<< "registered in i2cDeviceMap" << std::endl;
i2cDeviceMapIter->second.replyLen = 0;
return HasReturnvaluesIF::RETURN_FAILED;
}
deviceFile = i2cCookie->getDeviceFile();
utility::UnixFileHelper fileHelper(deviceFile, &fd, O_RDWR, "I2cComIF::requestReceiveMessage");
if(fileHelper.getOpenResult() != HasReturnvaluesIF::RETURN_OK) {
return fileHelper.getOpenResult();
}
result = openDevice(deviceFile, i2cAddress, &fd);
if (result != HasReturnvaluesIF::RETURN_OK){
i2cDeviceMapIter->second.replyLen = 0;
return result;
}
uint8_t* replyBuffer = i2cDeviceMapIter->second.replyBuffer.data();
if (read(fd, replyBuffer, requestLen) != static_cast<int>(requestLen)) {
sif::error << "I2cComIF::requestReceiveMessage: Reading from I2C "
<< "device failed with error code " << errno <<". Description"
<< " of error: " << strerror(errno) << std::endl;
i2cDeviceMapIter->second.replyLen = 0;
return HasReturnvaluesIF::RETURN_FAILED;
}
i2cDeviceMapIter->second.replyLen = requestLen;
return HasReturnvaluesIF::RETURN_OK;
}
ReturnValue_t I2cComIF::readReceivedMessage(CookieIF *cookie,
uint8_t **buffer, size_t* size) {
I2cCookie* i2cCookie = dynamic_cast<I2cCookie*>(cookie);
if(i2cCookie == nullptr) {
sif::error << "I2cComIF::readReceivedMessage: Invalid I2C Cookie!" << std::endl;
return NULLPOINTER;
}
address_t i2cAddress = i2cCookie->getAddress();
i2cDeviceMapIter = i2cDeviceMap.find(i2cAddress);
if (i2cDeviceMapIter == i2cDeviceMap.end()) {
sif::error << "I2cComIF::readReceivedMessage: i2cAddress of Cookie not "
<< "found in i2cDeviceMap" << std::endl;
return HasReturnvaluesIF::RETURN_FAILED;
}
*buffer = i2cDeviceMapIter->second.replyBuffer.data();
*size = i2cDeviceMapIter->second.replyLen;
return HasReturnvaluesIF::RETURN_OK;
}
ReturnValue_t I2cComIF::openDevice(std::string deviceFile,
address_t i2cAddress, int* fileDescriptor) {
if (ioctl(*fileDescriptor, I2C_SLAVE, i2cAddress) < 0) {
#if FSFW_VERBOSE_LEVEL >= 1
#if FSFW_CPP_OSTREAM_ENABLED == 1
sif::warning << "I2cComIF: Specifying target device failed with error code " << errno << "."
<< std::endl;
sif::warning << "Error description " << strerror(errno) << std::endl;
#else
sif::printWarning("I2cComIF: Specifying target device failed with error code %d.\n");
sif::printWarning("Error description: %s\n", strerror(errno));
#endif /* FSFW_CPP_OSTREAM_ENABLED == 1 */
#endif /* FSFW_VERBOSE_LEVEL >= 1 */
return HasReturnvaluesIF::RETURN_FAILED;
}
return HasReturnvaluesIF::RETURN_OK;
}

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@ -1,59 +0,0 @@
#ifndef LINUX_I2C_I2COMIF_H_
#define LINUX_I2C_I2COMIF_H_
#include "I2cCookie.h"
#include <fsfw/objectmanager/SystemObject.h>
#include <fsfw/devicehandlers/DeviceCommunicationIF.h>
#include <unordered_map>
#include <vector>
/**
* @brief This is the communication interface for i2c devices connected
* to a system running a linux OS.
*
* @author J. Meier
*/
class I2cComIF: public DeviceCommunicationIF, public SystemObject {
public:
I2cComIF(object_id_t objectId);
virtual ~I2cComIF();
ReturnValue_t initializeInterface(CookieIF * cookie) override;
ReturnValue_t sendMessage(CookieIF *cookie,const uint8_t *sendData,
size_t sendLen) override;
ReturnValue_t getSendSuccess(CookieIF *cookie) override;
ReturnValue_t requestReceiveMessage(CookieIF *cookie,
size_t requestLen) override;
ReturnValue_t readReceivedMessage(CookieIF *cookie, uint8_t **buffer,
size_t *size) override;
private:
typedef struct I2cInstance {
std::vector<uint8_t> replyBuffer;
size_t replyLen;
} I2cInstance_t;
using I2cDeviceMap = std::unordered_map<address_t, I2cInstance_t>;
using I2cDeviceMapIter = I2cDeviceMap::iterator;
/* In this map all i2c devices will be registered with their address and
* the appropriate file descriptor will be stored */
I2cDeviceMap i2cDeviceMap;
I2cDeviceMapIter i2cDeviceMapIter;
/**
* @brief This function opens an I2C device and binds the opened file
* to a specific I2C address.
* @param deviceFile The name of the device file. E.g. i2c-0
* @param i2cAddress The address of the i2c slave device.
* @param fileDescriptor Pointer to device descriptor.
* @return RETURN_OK if successful, otherwise RETURN_FAILED.
*/
ReturnValue_t openDevice(std::string deviceFile,
address_t i2cAddress, int* fileDescriptor);
};
#endif /* LINUX_I2C_I2COMIF_H_ */

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#include "I2cCookie.h"
I2cCookie::I2cCookie(address_t i2cAddress_, size_t maxReplyLen_,
std::string deviceFile_) :
i2cAddress(i2cAddress_), maxReplyLen(maxReplyLen_), deviceFile(deviceFile_) {
}
address_t I2cCookie::getAddress() const {
return i2cAddress;
}
size_t I2cCookie::getMaxReplyLen() const {
return maxReplyLen;
}
std::string I2cCookie::getDeviceFile() const {
return deviceFile;
}
I2cCookie::~I2cCookie() {}

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#ifndef LINUX_I2C_I2CCOOKIE_H_
#define LINUX_I2C_I2CCOOKIE_H_
#include <fsfw/devicehandlers/CookieIF.h>
#include <string>
/**
* @brief Cookie for the i2cDeviceComIF.
*
* @author J. Meier
*/
class I2cCookie: public CookieIF {
public:
/**
* @brief Constructor for the I2C cookie.
* @param i2cAddress_ The i2c address of the target device.
* @param maxReplyLen The maximum expected length of a reply from the
* target device.
*/
I2cCookie(address_t i2cAddress_, size_t maxReplyLen_,
std::string deviceFile_);
virtual ~I2cCookie();
address_t getAddress() const;
size_t getMaxReplyLen() const;
std::string getDeviceFile() const;
private:
address_t i2cAddress = 0;
size_t maxReplyLen = 0;
std::string deviceFile;
};
#endif /* LINUX_I2C_I2CCOOKIE_H_ */

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target_sources(${TARGET_NAME} PUBLIC
SpiComIF.cpp
SpiCookie.cpp
)

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#include "SpiComIF.h"
#include <OBSWConfig.h>
#include <linux/utility/Utility.h>
#include <linux/spi/SpiCookie.h>
#include <fsfw/ipc/MutexFactory.h>
#include <fsfw/ipc/MutexGuard.h>
#include <fsfw/globalfunctions/arrayprinter.h>
#include <linux/spi/spidev.h>
#include <fcntl.h>
#include <unistd.h>
#include <sys/ioctl.h>
#include <cerrno>
#include <cstring>
SpiComIF::SpiComIF(object_id_t objectId, GpioIF* gpioComIF): SystemObject(objectId),
gpioComIF(gpioComIF) {
if(gpioComIF == nullptr) {
#if FSFW_VERBOSE_LEVEL >= 1
#if FSFW_CPP_OSTREAM_ENABLED == 1
sif::error << "SpiComIF::SpiComIF: GPIO communication interface invalid!" << std::endl;
#else
sif::printError("SpiComIF::SpiComIF: GPIO communication interface invalid!\n");
#endif /* FSFW_CPP_OSTREAM_ENABLED == 1 */
#endif /* FSFW_VERBOSE_LEVEL >= 1 */
}
spiMutex = MutexFactory::instance()->createMutex();
}
ReturnValue_t SpiComIF::initializeInterface(CookieIF *cookie) {
int retval = 0;
SpiCookie* spiCookie = dynamic_cast<SpiCookie*>(cookie);
if(spiCookie == nullptr) {
return NULLPOINTER;
}
address_t spiAddress = spiCookie->getSpiAddress();
auto iter = spiDeviceMap.find(spiAddress);
if(iter == spiDeviceMap.end()) {
size_t bufferSize = spiCookie->getMaxBufferSize();
SpiInstance spiInstance = {std::vector<uint8_t>(bufferSize)};
auto statusPair = spiDeviceMap.emplace(spiAddress, spiInstance);
if (not statusPair.second) {
#if FSFW_VERBOSE_LEVEL >= 1
#if FSFW_CPP_OSTREAM_ENABLED == 1
sif::error << "SpiComIF::initializeInterface: Failed to insert device with address " <<
spiAddress << "to SPI device map" << std::endl;
#else
sif::printError("SpiComIF::initializeInterface: Failed to insert device with address "
"%lu to SPI device map\n", static_cast<unsigned long>(spiAddress));
#endif /* FSFW_CPP_OSTREAM_ENABLED == 1 */
#endif /* FSFW_VERBOSE_LEVEL >= 1 */
return HasReturnvaluesIF::RETURN_FAILED;
}
/* Now we emplaced the read buffer in the map, we still need to assign that location
to the SPI driver transfer struct */
spiCookie->assignReadBuffer(statusPair.first->second.replyBuffer.data());
}
else {
#if FSFW_VERBOSE_LEVEL >= 1
#if FSFW_CPP_OSTREAM_ENABLED == 1
sif::error << "SpiComIF::initializeInterface: SPI address already exists!" << std::endl;
#else
sif::printError("SpiComIF::initializeInterface: SPI address already exists!\n");
#endif /* FSFW_CPP_OSTREAM_ENABLED == 1 */
#endif /* FSFW_VERBOSE_LEVEL >= 1 */
return HasReturnvaluesIF::RETURN_FAILED;
}
/* Pull CS high in any case to be sure that device is inactive */
gpioId_t gpioId = spiCookie->getChipSelectPin();
if(gpioId != gpio::NO_GPIO) {
gpioComIF->pullHigh(gpioId);
}
size_t spiSpeed = 0;
spi::SpiModes spiMode = spi::SpiModes::MODE_0;
SpiCookie::UncommonParameters params;
spiCookie->getSpiParameters(spiMode, spiSpeed, &params);
int fileDescriptor = 0;
utility::UnixFileHelper fileHelper(spiCookie->getSpiDevice(), &fileDescriptor, O_RDWR,
"SpiComIF::initializeInterface: ");
if(fileHelper.getOpenResult() != HasReturnvaluesIF::RETURN_OK) {
return fileHelper.getOpenResult();
}
/* These flags are rather uncommon */
if(params.threeWireSpi or params.noCs or params.csHigh) {
uint32_t currentMode = 0;
retval = ioctl(fileDescriptor, SPI_IOC_RD_MODE32, &currentMode);
if(retval != 0) {
utility::handleIoctlError("SpiComIF::initialiezInterface: Could not read full mode!");
}
if(params.threeWireSpi) {
currentMode |= SPI_3WIRE;
}
if(params.noCs) {
/* Some drivers like the Raspberry Pi ignore this flag in any case */
currentMode |= SPI_NO_CS;
}
if(params.csHigh) {
currentMode |= SPI_CS_HIGH;
}
/* Write adapted mode */
retval = ioctl(fileDescriptor, SPI_IOC_WR_MODE32, &currentMode);
if(retval != 0) {
utility::handleIoctlError("SpiComIF::initialiezInterface: Could not write full mode!");
}
}
if(params.lsbFirst) {
retval = ioctl(fileDescriptor, SPI_IOC_WR_LSB_FIRST, &params.lsbFirst);
if(retval != 0) {
utility::handleIoctlError("SpiComIF::initializeInterface: Setting LSB first failed");
}
}
if(params.bitsPerWord != 8) {
retval = ioctl(fileDescriptor, SPI_IOC_WR_BITS_PER_WORD, &params.bitsPerWord);
if(retval != 0) {
utility::handleIoctlError("SpiComIF::initializeInterface: "
"Could not write bits per word!");
}
}
return HasReturnvaluesIF::RETURN_OK;
}
ReturnValue_t SpiComIF::sendMessage(CookieIF *cookie, const uint8_t *sendData, size_t sendLen) {
SpiCookie* spiCookie = dynamic_cast<SpiCookie*>(cookie);
ReturnValue_t result = HasReturnvaluesIF::RETURN_OK;
int retval = 0;
if(spiCookie == nullptr) {
return NULLPOINTER;
}
if(sendLen > spiCookie->getMaxBufferSize()) {
#if FSFW_VERBOSE_LEVEL >= 1
#if FSFW_CPP_OSTREAM_ENABLED == 1
sif::warning << "SpiComIF::sendMessage: Too much data sent, send length" << sendLen <<
"larger than maximum buffer length" << spiCookie->getMaxBufferSize() << std::endl;
#else
sif::printWarning("SpiComIF::sendMessage: Too much data sent, send length %lu larger "
"than maximum buffer length %lu!\n", static_cast<unsigned long>(sendLen),
static_cast<unsigned long>(spiCookie->getMaxBufferSize()));
#endif /* FSFW_CPP_OSTREAM_ENABLED == 1 */
#endif /* FSFW_VERBOSE_LEVEL >= 1 */
return DeviceCommunicationIF::TOO_MUCH_DATA;
}
/* Prepare transfer */
int fileDescriptor = 0;
std::string device = spiCookie->getSpiDevice();
utility::UnixFileHelper fileHelper(device, &fileDescriptor, O_RDWR,
"SpiComIF::sendMessage: ");
if(fileHelper.getOpenResult() != HasReturnvaluesIF::RETURN_OK) {
return OPENING_FILE_FAILED;
}
spi::SpiModes spiMode = spi::SpiModes::MODE_0;
uint32_t spiSpeed = 0;
spiCookie->getSpiParameters(spiMode, spiSpeed, nullptr);
setSpiSpeedAndMode(fileDescriptor, spiMode, spiSpeed);
spiCookie->assignWriteBuffer(sendData);
spiCookie->assignTransferSize(sendLen);
bool fullDuplex = spiCookie->isFullDuplex();
gpioId_t gpioId = spiCookie->getChipSelectPin();
/* GPIO access is mutex protected */
MutexGuard(spiMutex, timeoutType, timeoutMs);
/* Pull SPI CS low. For now, no support for active high given */
if(gpioId != gpio::NO_GPIO) {
gpioComIF->pullLow(gpioId);
}
/* Execute transfer */
if(fullDuplex) {
/* Initiate a full duplex SPI transfer. */
retval = ioctl(fileDescriptor, SPI_IOC_MESSAGE(1), spiCookie->getTransferStructHandle());
if(retval < 0) {
utility::handleIoctlError("SpiComIF::sendMessage: ioctl error.");
result = FULL_DUPLEX_TRANSFER_FAILED;
}
#if FSFW_LINUX_SPI_WIRETAPPING == 1
#if FSFW_CPP_OSTREAM_ENABLED == 1
sif::info << "Sent SPI data: " << std::endl;
size_t dataLen = spiCookie->getTransferStructHandle()->len;
uint8_t* dataPtr = reinterpret_cast<uint8_t*>(spiCookie->getTransferStructHandle()->tx_buf);
arrayprinter::print(dataPtr, dataLen, OutputType::HEX, false);
sif::info << "Received SPI data: " << std::endl;
dataPtr = reinterpret_cast<uint8_t*>(spiCookie->getTransferStructHandle()->rx_buf);
arrayprinter::print(dataPtr, dataLen, OutputType::HEX, false);
#else
#endif /* FSFW_CPP_OSTREAM_ENABLED == 1 */
#endif /* FSFW_LINUX_SPI_WIRETAPPING == 1 */
}
else {
/* We write with a blocking half-duplex transfer here */
if (write(fileDescriptor, sendData, sendLen) != static_cast<ssize_t>(sendLen)) {
#if FSFW_VERBOSE_LEVEL >= 1
#if FSFW_CPP_OSTREAM_ENABLED == 1
sif::warning << "SpiComIF::sendMessage: Half-Duplex write operation failed!" <<
std::endl;
#else
sif::printWarning("SpiComIF::sendMessage: Half-Duplex write operation failed!\n");
#endif /* FSFW_CPP_OSTREAM_ENABLED == 1 */
#endif /* FSFW_VERBOSE_LEVEL >= 1 */
result = HALF_DUPLEX_TRANSFER_FAILED;
}
}
if(gpioId != gpio::NO_GPIO) {
gpioComIF->pullHigh(gpioId);
}
return result;
}
ReturnValue_t SpiComIF::getSendSuccess(CookieIF *cookie) {
return HasReturnvaluesIF::RETURN_OK;
}
ReturnValue_t SpiComIF::requestReceiveMessage(CookieIF *cookie, size_t requestLen) {
ReturnValue_t result = HasReturnvaluesIF::RETURN_OK;
SpiCookie* spiCookie = dynamic_cast<SpiCookie*>(cookie);
if(spiCookie == nullptr) {
return NULLPOINTER;
}
bool fullDuplex = spiCookie->isFullDuplex();
if(fullDuplex) {
return HasReturnvaluesIF::RETURN_OK;
}
std::string device = spiCookie->getSpiDevice();
int fileDescriptor = 0;
utility::UnixFileHelper fileHelper(device, &fileDescriptor, O_RDWR,
"SpiComIF::requestReceiveMessage: ");
if(fileHelper.getOpenResult() != HasReturnvaluesIF::RETURN_OK) {
return OPENING_FILE_FAILED;
}
uint8_t* rxBuf = nullptr;
size_t readSize = spiCookie->getCurrentTransferSize();
result = getReadBuffer(spiCookie->getSpiAddress(), &rxBuf);
if(result != HasReturnvaluesIF::RETURN_OK) {
return result;
}
gpioId_t gpioId = spiCookie->getChipSelectPin();
MutexGuard(spiMutex, timeoutType, timeoutMs);
if(gpioId != gpio::NO_GPIO) {
gpioComIF->pullLow(gpioId);
}
if(read(fileDescriptor, rxBuf, readSize) != static_cast<ssize_t>(readSize)) {
#if FSFW_VERBOSE_LEVEL >= 1
#if FSFW_CPP_OSTREAM_ENABLED == 1
sif::warning << "SpiComIF::sendMessage: Half-Duplex read operation failed!" << std::endl;
#else
sif::printWarning("SpiComIF::sendMessage: Half-Duplex read operation failed!\n");
#endif /* FSFW_CPP_OSTREAM_ENABLED == 1 */
#endif /* FSFW_VERBOSE_LEVEL >= 1 */
result = HALF_DUPLEX_TRANSFER_FAILED;
}
if(gpioId != gpio::NO_GPIO) {
gpioComIF->pullHigh(gpioId);
}
return HasReturnvaluesIF::RETURN_OK;
}
ReturnValue_t SpiComIF::readReceivedMessage(CookieIF *cookie, uint8_t **buffer, size_t *size) {
SpiCookie* spiCookie = dynamic_cast<SpiCookie*>(cookie);
if(spiCookie == nullptr) {
return HasReturnvaluesIF::RETURN_FAILED;
}
uint8_t* rxBuf = nullptr;
ReturnValue_t result = getReadBuffer(spiCookie->getSpiAddress(), &rxBuf);
if(result != HasReturnvaluesIF::RETURN_OK) {
return result;
}
*buffer = rxBuf;
*size = spiCookie->getCurrentTransferSize();
return HasReturnvaluesIF::RETURN_OK;
}
ReturnValue_t SpiComIF::getReadBuffer(address_t spiAddress, uint8_t** buffer) {
if(buffer == nullptr) {
return HasReturnvaluesIF::RETURN_FAILED;
}
auto iter = spiDeviceMap.find(spiAddress);
if(iter == spiDeviceMap.end()) {
return HasReturnvaluesIF::RETURN_FAILED;
}
*buffer = iter->second.replyBuffer.data();
return HasReturnvaluesIF::RETURN_OK;
}
void SpiComIF::setSpiSpeedAndMode(int spiFd, spi::SpiModes mode, uint32_t speed) {
int retval = ioctl(spiFd, SPI_IOC_WR_MODE, reinterpret_cast<uint8_t*>(&mode));
if(retval != 0) {
utility::handleIoctlError("SpiTestClass::performRm3100Test: Setting SPI mode failed!");
}
retval = ioctl(spiFd, SPI_IOC_WR_MAX_SPEED_HZ, &speed);
if(retval != 0) {
utility::handleIoctlError("SpiTestClass::performRm3100Test: Setting SPI speed failed!");
}
}

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#ifndef LINUX_SPI_SPICOMIF_H_
#define LINUX_SPI_SPICOMIF_H_
#include <fsfw/devicehandlers/DeviceCommunicationIF.h>
#include <fsfw/objectmanager/SystemObject.h>
#include <linux/gpio/GpioIF.h>
#include <linux/spi/spiDefinitions.h>
#include <returnvalues/classIds.h>
#include <vector>
#include <unordered_map>
/**
* @brief Encapsulates access to linux SPI driver for FSFW objects
* @details
* Right now, only full-duplex SPI is supported.
* @author R. Mueller
*/
class SpiComIF: public DeviceCommunicationIF, public SystemObject {
public:
static constexpr uint8_t spiRetvalId = CLASS_ID::LINUX_SPI_COM_IF;
static constexpr ReturnValue_t OPENING_FILE_FAILED =
HasReturnvaluesIF::makeReturnCode(spiRetvalId, 0);
/* Full duplex (ioctl) transfer failure */
static constexpr ReturnValue_t FULL_DUPLEX_TRANSFER_FAILED =
HasReturnvaluesIF::makeReturnCode(spiRetvalId, 1);
/* Half duplex (read/write) transfer failure */
static constexpr ReturnValue_t HALF_DUPLEX_TRANSFER_FAILED =
HasReturnvaluesIF::makeReturnCode(spiRetvalId, 2);
SpiComIF(object_id_t objectId, GpioIF* gpioComIF);
ReturnValue_t initializeInterface(CookieIF * cookie) override;
ReturnValue_t sendMessage(CookieIF *cookie,const uint8_t *sendData,
size_t sendLen) override;
ReturnValue_t getSendSuccess(CookieIF *cookie) override;
ReturnValue_t requestReceiveMessage(CookieIF *cookie,
size_t requestLen) override;
ReturnValue_t readReceivedMessage(CookieIF *cookie, uint8_t **buffer,
size_t *size) override;
private:
struct SpiInstance {
std::vector<uint8_t> replyBuffer;
};
GpioIF* gpioComIF = nullptr;
MutexIF* spiMutex = nullptr;
MutexIF::TimeoutType timeoutType = MutexIF::TimeoutType::WAITING;
uint32_t timeoutMs = 20;
using SpiDeviceMap = std::unordered_map<address_t, SpiInstance>;
using SpiDeviceMapIter = SpiDeviceMap::iterator;
SpiDeviceMap spiDeviceMap;
ReturnValue_t getReadBuffer(address_t spiAddress, uint8_t** buffer);
void setSpiSpeedAndMode(int spiFd, spi::SpiModes mode, uint32_t speed);
};
#endif /* LINUX_SPI_SPICOMIF_H_ */

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#include "SpiCookie.h"
SpiCookie::SpiCookie(address_t spiAddress, gpioId_t chipSelect, std::string spiDev,
const size_t maxSize, spi::SpiModes spiMode, uint32_t spiSpeed): spiAddress(spiAddress),
chipSelectPin(chipSelect), spiDevice(spiDev), maxSize(maxSize), spiMode(spiMode),
spiSpeed(spiSpeed) {
}
SpiCookie::SpiCookie(address_t spiAddress, std::string spiDev, const size_t maxSize,
spi::SpiModes spiMode, uint32_t spiSpeed):
SpiCookie(spiAddress, gpio::NO_GPIO, spiDev, maxSize, spiMode, spiSpeed) {
}
void SpiCookie::getSpiParameters(spi::SpiModes& spiMode, uint32_t& spiSpeed,
UncommonParameters* parameters) const {
spiMode = this->spiMode;
spiSpeed = this->spiSpeed;
if(parameters != nullptr) {
parameters->threeWireSpi = uncommonParameters.threeWireSpi;
parameters->lsbFirst = uncommonParameters.lsbFirst;
parameters->noCs = uncommonParameters.noCs;
parameters->bitsPerWord = uncommonParameters.bitsPerWord;
parameters->csHigh = uncommonParameters.csHigh;
}
}
gpioId_t SpiCookie::getChipSelectPin() const {
return chipSelectPin;
}
size_t SpiCookie::getMaxBufferSize() const {
return maxSize;
}
address_t SpiCookie::getSpiAddress() const {
return spiAddress;
}
std::string SpiCookie::getSpiDevice() const {
return spiDevice;
}
void SpiCookie::setThreeWireSpi(bool enable) {
uncommonParameters.threeWireSpi = enable;
}
void SpiCookie::setLsbFirst(bool enable) {
uncommonParameters.lsbFirst = enable;
}
void SpiCookie::setNoCs(bool enable) {
uncommonParameters.noCs = enable;
}
void SpiCookie::setBitsPerWord(uint8_t bitsPerWord) {
uncommonParameters.bitsPerWord = bitsPerWord;
}
void SpiCookie::setCsHigh(bool enable) {
uncommonParameters.csHigh = enable;
}
void SpiCookie::activateCsDeselect(bool deselectCs, uint16_t delayUsecs) {
spiTransferStruct.cs_change = deselectCs;
spiTransferStruct.delay_usecs = delayUsecs;
}
void SpiCookie::assignReadBuffer(uint8_t* rx) {
if(rx != nullptr) {
spiTransferStruct.rx_buf = reinterpret_cast<__u64>(rx);
}
}
void SpiCookie::assignWriteBuffer(const uint8_t* tx) {
if(tx != nullptr) {
spiTransferStruct.tx_buf = reinterpret_cast<__u64>(tx);
}
}
spi_ioc_transfer* SpiCookie::getTransferStructHandle() {
return &spiTransferStruct;
}
void SpiCookie::setFullOrHalfDuplex(bool halfDuplex) {
this->halfDuplex = halfDuplex;
}
bool SpiCookie::isFullDuplex() const {
return not this->halfDuplex;
}
void SpiCookie::assignTransferSize(size_t transferSize) {
spiTransferStruct.len = transferSize;
}
size_t SpiCookie::getCurrentTransferSize() const {
return spiTransferStruct.len;
}
void SpiCookie::setSpiSpeed(uint32_t newSpeed) {
this->spiSpeed = newSpeed;
}
void SpiCookie::setSpiMode(spi::SpiModes newMode) {
this->spiMode = newMode;
}

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#ifndef LINUX_SPI_SPICOOKIE_H_
#define LINUX_SPI_SPICOOKIE_H_
#include "spiDefinitions.h"
#include <fsfw/devicehandlers/CookieIF.h>
#include <linux/gpio/gpioDefinitions.h>
#include <linux/spi/spidev.h>
class SpiCookie: public CookieIF {
public:
/**
* Each SPI device will have a corresponding cookie. The cookie is used by the communication
* interface and contains device specific information like the largest expected size to be
* sent and received and the GPIO pin used to toggle the SPI slave select pin.
* @param spiAddress
* @param chipSelect Chip select. gpio::NO_GPIO can be used for hardware slave selects.
* @param spiDev
* @param maxSize
*/
SpiCookie(address_t spiAddress, gpioId_t chipSelect, std::string spiDev,
const size_t maxReplySize, spi::SpiModes spiMode, uint32_t spiSpeed);
/**
* Like constructor above, but without a dedicated GPIO CS. Can be used for hardware
* slave select or if CS logic is performed with decoders.
*/
SpiCookie(address_t spiAddress, std::string spiDev, const size_t maxReplySize,
spi::SpiModes spiMode, uint32_t spiSpeed);
address_t getSpiAddress() const;
std::string getSpiDevice() const;
gpioId_t getChipSelectPin() const;
size_t getMaxBufferSize() const;
/** Enables changing SPI speed at run-time */
void setSpiSpeed(uint32_t newSpeed);
/** Enables changing the SPI mode at run-time */
void setSpiMode(spi::SpiModes newMode);
/**
* True if SPI transfers should be performed in full duplex mode
* @return
*/
bool isFullDuplex() const;
/**
* Set transfer type to full duplex or half duplex. Full duplex is the default setting,
* ressembling common SPI hardware implementation with shift registers, where read and writes
* happen simultaneosly.
* @param fullDuplex
*/
void setFullOrHalfDuplex(bool halfDuplex);
/**
* This needs to be called to specify where the SPI driver writes to or reads from.
* @param readLocation
* @param writeLocation
*/
void assignReadBuffer(uint8_t* rx);
void assignWriteBuffer(const uint8_t* tx);
/**
* Assign size for the next transfer.
* @param transferSize
*/
void assignTransferSize(size_t transferSize);
size_t getCurrentTransferSize() const;
struct UncommonParameters {
uint8_t bitsPerWord = 8;
bool noCs = false;
bool csHigh = false;
bool threeWireSpi = false;
/* MSB first is more common */
bool lsbFirst = false;
};
/**
* Can be used to explicitely disable hardware chip select.
* Some drivers like the Raspberry Pi Linux driver will not use hardware chip select by default
* (see https://www.raspberrypi.org/documentation/hardware/raspberrypi/spi/README.md)
* @param enable
*/
void setNoCs(bool enable);
void setThreeWireSpi(bool enable);
void setLsbFirst(bool enable);
void setCsHigh(bool enable);
void setBitsPerWord(uint8_t bitsPerWord);
void getSpiParameters(spi::SpiModes& spiMode, uint32_t& spiSpeed,
UncommonParameters* parameters = nullptr) const;
/**
* See spidev.h cs_change and delay_usecs
* @param deselectCs
* @param delayUsecs
*/
void activateCsDeselect(bool deselectCs, uint16_t delayUsecs);
spi_ioc_transfer* getTransferStructHandle();
private:
size_t currentTransferSize = 0;
address_t spiAddress;
gpioId_t chipSelectPin;
std::string spiDevice;
const size_t maxSize;
spi::SpiModes spiMode;
uint32_t spiSpeed;
bool halfDuplex = false;
struct spi_ioc_transfer spiTransferStruct = {};
UncommonParameters uncommonParameters;
};
#endif /* LINUX_SPI_SPICOOKIE_H_ */

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#ifndef LINUX_SPI_SPIDEFINITONS_H_
#define LINUX_SPI_SPIDEFINITONS_H_
#include <cstdint>
namespace spi {
enum SpiModes: uint8_t {
MODE_0,
MODE_1,
MODE_2,
MODE_3
};
}
#endif /* LINUX_SPI_SPIDEFINITONS_H_ */

View File

@ -1,6 +1,6 @@
target_sources(${TARGET_NAME} PUBLIC
I2cComIF.cpp
I2cCookie.cpp
UartComIF.cpp
UartCookie.cpp
)

368
linux/uart/UartComIF.cpp Normal file
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@ -0,0 +1,368 @@
#include "UartComIF.h"
#include <fsfw/serviceinterface/ServiceInterface.h>
#include <string.h>
#include <fcntl.h>
#include <errno.h>
#include <termios.h>
#include <unistd.h>
UartComIF::UartComIF(object_id_t objectId): SystemObject(objectId){
}
UartComIF::~UartComIF() {}
ReturnValue_t UartComIF::initializeInterface(CookieIF * cookie) {
std::string deviceFile;
UartDeviceMapIter uartDeviceMapIter;
if(cookie == nullptr) {
return NULLPOINTER;
}
UartCookie* uartCookie = dynamic_cast<UartCookie*>(cookie);
if (uartCookie == nullptr) {
sif::error << "UartComIF::initializeInterface: Invalid UART Cookie!" << std::endl;
return NULLPOINTER;
}
deviceFile = uartCookie->getDeviceFile();
uartDeviceMapIter = uartDeviceMap.find(deviceFile);
if(uartDeviceMapIter == uartDeviceMap.end()) {
int fileDescriptor = configureUartPort(uartCookie);
if (fileDescriptor < 0) {
return RETURN_FAILED;
}
size_t maxReplyLen = uartCookie->getMaxReplyLen();
UartElements_t uartElements = {fileDescriptor, std::vector<uint8_t>(maxReplyLen), 0};
std::pair status = uartDeviceMap.emplace(deviceFile, uartElements);
if (status.second == false) {
sif::debug << "UartComIF::initializeInterface: Failed to insert device " << deviceFile
<< "to Uart device map" << std::endl;
return RETURN_FAILED;
}
}
else {
sif::debug << "UartComIF::initializeInterface: Uart device " << deviceFile << "already in "
<< "use" << std::endl;
return RETURN_FAILED;
}
return RETURN_OK;
}
int UartComIF::configureUartPort(UartCookie* uartCookie) {
struct termios options;
std::string deviceFile = uartCookie->getDeviceFile();
int fd = open(deviceFile.c_str(), O_RDWR);
if (fd < 0) {
sif::debug << "UartComIF::configureUartPort: Failed to open uart " << deviceFile << "with"
<< " error code " << errno << strerror(errno) << std::endl;
return fd;
}
/* Read in existing settings */
if(tcgetattr(fd, &options) != 0) {
sif::debug << "UartComIF::configureUartPort: Error " << errno << "from tcgetattr: "
<< strerror(errno) << std::endl;
return fd;
}
setParityOptions(&options, uartCookie);
setStopBitOptions(&options, uartCookie);
setDatasizeOptions(&options, uartCookie);
setFixedOptions(&options);
/* Sets uart to non-blocking mode. Read returns immediately when there are no data available */
options.c_cc[VTIME] = 0;
options.c_cc[VMIN] = 0;
configureBaudrate(&options, uartCookie);
/* Save option settings */
if (tcsetattr(fd, TCSANOW, &options) != 0) {
sif::debug << "UartComIF::configureUartPort: Failed to set options with error " << errno
<< ": " << strerror(errno);
return fd;
}
return fd;
}
void UartComIF::setParityOptions(struct termios* options, UartCookie* uartCookie) {
/* Clear parity bit */
options->c_cflag &= ~PARENB;
switch (uartCookie->getParity()) {
case Parity::EVEN:
options->c_cflag |= PARENB;
options->c_cflag &= ~PARODD;
break;
case Parity::ODD:
options->c_cflag |= PARENB;
options->c_cflag |= PARODD;
break;
default:
break;
}
}
void UartComIF::setStopBitOptions(struct termios* options, UartCookie* uartCookie) {
/* Clear stop field. Sets stop bit to one bit */
options->c_cflag &= ~CSTOPB;
switch (uartCookie->getStopBits()) {
case StopBits::TWO_STOP_BITS:
options->c_cflag |= CSTOPB;
break;
default:
break;
}
}
void UartComIF::setDatasizeOptions(struct termios* options, UartCookie* uartCookie) {
/* Clear size bits */
options->c_cflag &= ~CSIZE;
switch (uartCookie->getBitsPerWord()) {
case 5:
options->c_cflag |= CS5;
break;
case 6:
options->c_cflag |= CS6;
break;
case 7:
options->c_cflag |= CS7;
break;
case 8:
options->c_cflag |= CS8;
break;
default:
sif::debug << "UartComIF::setDatasizeOptions: Invalid size specified" << std::endl;
break;
}
}
void UartComIF::setFixedOptions(struct termios* options) {
/* Disable RTS/CTS hardware flow control */
options->c_cflag &= ~CRTSCTS;
/* Turn on READ & ignore ctrl lines (CLOCAL = 1) */
options->c_cflag |= CREAD | CLOCAL;
/* Disable canonical mode */
options->c_lflag &= ~ICANON;
/* Disable echo */
options->c_lflag &= ~ECHO;
/* Disable erasure */
options->c_lflag &= ~ECHOE;
/* Disable new-line echo */
options->c_lflag &= ~ECHONL;
/* Disable interpretation of INTR, QUIT and SUSP */
options->c_lflag &= ~ISIG;
/* Turn off s/w flow ctrl */
options->c_iflag &= ~(IXON | IXOFF | IXANY);
/* Disable any special handling of received bytes */
options->c_iflag &= ~(IGNBRK|BRKINT|PARMRK|ISTRIP|INLCR|IGNCR|ICRNL);
/* Prevent special interpretation of output bytes (e.g. newline chars) */
options->c_oflag &= ~OPOST;
/* Prevent conversion of newline to carriage return/line feed */
options->c_oflag &= ~ONLCR;
}
void UartComIF::configureBaudrate(struct termios* options, UartCookie* uartCookie) {
switch (uartCookie->getBaudrate()) {
case 50:
cfsetispeed(options, B50);
cfsetospeed(options, B50);
break;
case 75:
cfsetispeed(options, B75);
cfsetospeed(options, B75);
break;
case 110:
cfsetispeed(options, B110);
cfsetospeed(options, B110);
break;
case 134:
cfsetispeed(options, B134);
cfsetospeed(options, B134);
break;
case 150:
cfsetispeed(options, B150);
cfsetospeed(options, B150);
break;
case 200:
cfsetispeed(options, B200);
cfsetospeed(options, B200);
break;
case 300:
cfsetispeed(options, B300);
cfsetospeed(options, B300);
break;
case 600:
cfsetispeed(options, B600);
cfsetospeed(options, B600);
break;
case 1200:
cfsetispeed(options, B1200);
cfsetospeed(options, B1200);
break;
case 1800:
cfsetispeed(options, B1800);
cfsetospeed(options, B1800);
break;
case 2400:
cfsetispeed(options, B2400);
cfsetospeed(options, B2400);
break;
case 4800:
cfsetispeed(options, B4800);
cfsetospeed(options, B4800);
break;
case 9600:
cfsetispeed(options, B9600);
cfsetospeed(options, B9600);
break;
case 19200:
cfsetispeed(options, B19200);
cfsetospeed(options, B19200);
break;
case 38400:
cfsetispeed(options, B38400);
cfsetospeed(options, B38400);
break;
case 57600:
cfsetispeed(options, B57600);
cfsetospeed(options, B57600);
break;
case 115200:
cfsetispeed(options, B115200);
cfsetospeed(options, B115200);
break;
case 230400:
cfsetispeed(options, B230400);
cfsetospeed(options, B230400);
break;
case 460800:
cfsetispeed(options, B460800);
cfsetospeed(options, B460800);
break;
default:
sif::debug << "UartComIF::configureBaudrate: Baudrate not supported" << std::endl;
break;
}
}
ReturnValue_t UartComIF::sendMessage(CookieIF *cookie,
const uint8_t *sendData, size_t sendLen) {
int fd;
std::string deviceFile;
UartDeviceMapIter uartDeviceMapIter;
if(sendData == nullptr) {
sif::debug << "UartComIF::sendMessage: Send Data is nullptr" << std::endl;
return RETURN_FAILED;
}
if(sendLen == 0) {
return RETURN_OK;
}
UartCookie* uartCookie = dynamic_cast<UartCookie*>(cookie);
if(uartCookie == nullptr) {
sif::debug << "UartComIF::sendMessasge: Invalid Uart Cookie!" << std::endl;
return NULLPOINTER;
}
deviceFile = uartCookie->getDeviceFile();
uartDeviceMapIter = uartDeviceMap.find(deviceFile);
if (uartDeviceMapIter == uartDeviceMap.end()) {
sif::debug << "UartComIF::sendMessage: Device file " << deviceFile << "not in uart map"
<< std::endl;
return RETURN_FAILED;
}
fd = uartDeviceMapIter->second.fileDescriptor;
if (write(fd, sendData, sendLen) != (int)sendLen) {
sif::error << "UartComIF::sendMessage: Failed to send data with error code " << errno
<< ": Error description: " << strerror(errno) << std::endl;
return RETURN_FAILED;
}
return RETURN_OK;
}
ReturnValue_t UartComIF::getSendSuccess(CookieIF *cookie) {
return RETURN_OK;
}
ReturnValue_t UartComIF::requestReceiveMessage(CookieIF *cookie,
size_t requestLen) {
int fd;
std::string deviceFile;
UartDeviceMapIter uartDeviceMapIter;
uint8_t* bufferPtr;
if(requestLen == 0) {
return RETURN_OK;
}
UartCookie* uartCookie = dynamic_cast<UartCookie*>(cookie);
if(uartCookie == nullptr) {
sif::debug << "UartComIF::requestReceiveMessage: Invalid Uart Cookie!" << std::endl;
return NULLPOINTER;
}
deviceFile = uartCookie->getDeviceFile();
uartDeviceMapIter = uartDeviceMap.find(deviceFile);
if (uartDeviceMapIter == uartDeviceMap.end()) {
sif::debug << "UartComIF::requestReceiveMessage: Device file " << deviceFile
<< " not in uart map" << std::endl;
return RETURN_FAILED;
}
fd = uartDeviceMapIter->second.fileDescriptor;
bufferPtr = uartDeviceMapIter->second.replyBuffer.data();
int bytesRead = read(fd, bufferPtr, requestLen);
if (bytesRead != static_cast<int>(requestLen)) {
sif::debug << "UartComIF::requestReceiveMessage: Only read " << bytesRead
<< " of " << requestLen << " bytes" << std::endl;
return RETURN_FAILED;
}
else {
uartDeviceMapIter->second.replyLen = bytesRead;
}
return RETURN_OK;
}
ReturnValue_t UartComIF::readReceivedMessage(CookieIF *cookie,
uint8_t **buffer, size_t* size) {
std::string deviceFile;
UartDeviceMapIter uartDeviceMapIter;
UartCookie* uartCookie = dynamic_cast<UartCookie*>(cookie);
if(uartCookie == nullptr) {
sif::debug << "UartComIF::readReceivedMessage: Invalid uart cookie!" << std::endl;
return NULLPOINTER;
}
deviceFile = uartCookie->getDeviceFile();
uartDeviceMapIter = uartDeviceMap.find(deviceFile);
if (uartDeviceMapIter == uartDeviceMap.end()) {
sif::debug << "UartComIF::readReceivedMessage: Device file " << deviceFile
<< " not in uart map" << std::endl;
return RETURN_FAILED;
}
*buffer = uartDeviceMapIter->second.replyBuffer.data();
*size = uartDeviceMapIter->second.replyLen;
return RETURN_OK;
}

94
linux/uart/UartComIF.h Normal file
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@ -0,0 +1,94 @@
#ifndef BSP_Q7S_COMIF_UARTCOMIF_H_
#define BSP_Q7S_COMIF_UARTCOMIF_H_
#include <fsfw/objectmanager/SystemObject.h>
#include <fsfw/devicehandlers/DeviceCommunicationIF.h>
#include <unordered_map>
#include <vector>
#include "UartCookie.h"
/**
* @brief This is the communication interface to access serial ports on linux based operating
* systems.
*
* @details The implementation follows the instructions from https://blog.mbedded.ninja/programming/
* operating-systems/linux/linux-serial-ports-using-c-cpp/#disabling-canonical-mode
*
* @author J. Meier
*/
class UartComIF: public DeviceCommunicationIF, public SystemObject {
public:
UartComIF(object_id_t objectId);
virtual ~UartComIF();
ReturnValue_t initializeInterface(CookieIF * cookie) override;
ReturnValue_t sendMessage(CookieIF *cookie,const uint8_t *sendData,
size_t sendLen) override;
ReturnValue_t getSendSuccess(CookieIF *cookie) override;
ReturnValue_t requestReceiveMessage(CookieIF *cookie,
size_t requestLen) override;
ReturnValue_t readReceivedMessage(CookieIF *cookie, uint8_t **buffer,
size_t *size) override;
private:
using UartDeviceFile_t = std::string;
typedef struct UartElements {
int fileDescriptor;
std::vector<uint8_t> replyBuffer;
/** Number of bytes read will be written to this variable */
size_t replyLen;
} UartElements_t;
using UartDeviceMap = std::unordered_map<UartDeviceFile_t, UartElements_t>;
using UartDeviceMapIter = UartDeviceMap::iterator;
/**
* The uart devie map stores informations of initialized uart ports.
*/
UartDeviceMap uartDeviceMap;
/**
* @brief This function opens and configures a uart device by using the information stored
* in the uart cookie.
* @param uartCookie Pointer to uart cookie with information about the uart. Contains the
* uart device file, baudrate, parity, stopbits etc.
* @return The file descriptor of the configured uart.
*/
int configureUartPort(UartCookie* uartCookie);
/**
* @brief This function adds the parity settings to the termios options struct.
*
* @param options Pointer to termios options struct which will be modified to enable or disable
* parity checking.
* @param uartCookie Pointer to uart cookie containing the information about the desired
* parity settings.
*
*/
void setParityOptions(struct termios* options, UartCookie* uartCookie);
void setStopBitOptions(struct termios* options, UartCookie* uartCookie);
/**
* @brief This function sets options which are not configurable by the uartCookie.
*/
void setFixedOptions(struct termios* options);
/**
* @brief With this function the datasize settings are added to the termios options struct.
*/
void setDatasizeOptions(struct termios* options, UartCookie* uartCookie);
/**
* @brief This functions adds the baudrate specified in the uartCookie to the termios options
* struct.
*/
void configureBaudrate(struct termios* options, UartCookie* uartCookie);
};
#endif /* BSP_Q7S_COMIF_UARTCOMIF_H_ */

63
linux/uart/UartCookie.cpp Normal file
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@ -0,0 +1,63 @@
#include "UartCookie.h"
#include <fsfw/serviceinterface/ServiceInterface.h>
UartCookie::UartCookie(std::string deviceFile, uint32_t baudrate, size_t maxReplyLen) :
deviceFile(deviceFile), baudrate(baudrate), maxReplyLen(maxReplyLen) {
}
UartCookie::~UartCookie() {}
uint32_t UartCookie::getBaudrate() const {
return baudrate;
}
size_t UartCookie::getMaxReplyLen() const {
return maxReplyLen;
}
std::string UartCookie::getDeviceFile() const {
return deviceFile;
}
void UartCookie::setParityOdd() {
parity = Parity::ODD;
}
void UartCookie::setParityEven() {
parity = Parity::EVEN;
}
Parity UartCookie::getParity() const {
return parity;
}
void UartCookie::setBitsPerWord(uint8_t bitsPerWord_) {
switch(bitsPerWord_) {
case 5:
case 6:
case 7:
case 8:
break;
default:
sif::debug << "UartCookie::setBitsPerWord: Invalid bits per word specified" << std::endl;
return;
}
bitsPerWord = bitsPerWord_;
}
uint8_t UartCookie::getBitsPerWord() const {
return bitsPerWord;
}
StopBits UartCookie::getStopBits() const {
return stopBits;
}
void UartCookie::setTwoStopBits() {
stopBits = StopBits::TWO_STOP_BITS;
}
void UartCookie::setOneStopBit() {
stopBits = StopBits::ONE_STOP_BIT;
}

81
linux/uart/UartCookie.h Normal file
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@ -0,0 +1,81 @@
#ifndef SAM9G20_COMIF_COOKIES_UART_COOKIE_H_
#define SAM9G20_COMIF_COOKIES_UART_COOKIE_H_
#include <fsfw/devicehandlers/CookieIF.h>
#include <string>
enum class Parity {
NONE,
EVEN,
ODD
};
enum class StopBits {
ONE_STOP_BIT,
TWO_STOP_BITS
};
/**
* @brief Cookie for the UartComIF. There are many options available to configure the uart driver.
* The constructor only requests for common options like the baudrate. Other options can
* be set by member functions.
*
* @author J. Meier
*/
class UartCookie: public CookieIF {
public:
/**
* @brief Constructor for the uart cookie.
* @param deviceFile The device file specifying the uart to use. E.g. "/dev/ttyPS1".
* @param baudrate The baudrate to use for input and output. Possible Baudrates are: 50,
* 75, 110, 134, 150, 200, 300, 600, 1200, 1800, 2400, 4800, 9600, B19200,
* 38400, 57600, 115200, 230400, 460800
* @param maxReplyLen The maximum size an object using this cookie expects.
*
* @details Default configuration: No parity
* 8 databits (number of bits transfered with one uart frame)
* One stop bit
*
*
*/
UartCookie(std::string deviceFile, uint32_t baudrate, size_t maxReplyLen);
virtual ~UartCookie();
uint32_t getBaudrate() const;
size_t getMaxReplyLen() const;
std::string getDeviceFile() const;
Parity getParity() const;
uint8_t getBitsPerWord() const;
StopBits getStopBits() const;
/**
* Functions two enable parity checking.
*/
void setParityOdd();
void setParityEven();
/**
* Function two set number of bits per UART frame.
*/
void setBitsPerWord(uint8_t bitsPerWord_);
/**
* Function to specify the number of stopbits.
*/
void setTwoStopBits();
void setOneStopBit();
private:
std::string deviceFile;
uint32_t baudrate;
size_t maxReplyLen = 0;
Parity parity = Parity::NONE;
uint8_t bitsPerWord = 8;
StopBits stopBits = StopBits::ONE_STOP_BIT;
};
#endif

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@ -1,5 +1,4 @@
target_sources(${TARGET_NAME} PUBLIC
Utility.cpp
)

View File

@ -1,52 +0,0 @@
#include "Utility.h"
void utility::handleIoctlError(const char* const customPrintout) {
#if FSFW_VERBOSE_LEVEL >= 1
#if FSFW_CPP_OSTREAM_ENABLED == 1
if(customPrintout != nullptr) {
sif::warning << customPrintout << std::endl;
}
sif::warning << "handleIoctlError: Error code " << errno << ", "<< strerror(errno) <<
std::endl;
#else
if(customPrintout != nullptr) {
sif::printWarning("%s\n", customPrintout);
}
sif::printWarning("handleIoctlError: Error code %d, %s\n", errno, strerror(errno));
#endif /* FSFW_CPP_OSTREAM_ENABLED == 1 */
#endif /* FSFW_VERBOSE_LEVEL >= 1 */
}
utility::UnixFileHelper::UnixFileHelper(std::string device, int* fileDescriptor, int flags,
std::string diagnosticPrefix):
fileDescriptor(fileDescriptor) {
if(fileDescriptor == nullptr) {
return;
}
*fileDescriptor = open(device.c_str(), flags);
if (*fileDescriptor < 0) {
#if FSFW_VERBOSE_LEVEL >= 1
#if FSFW_CPP_OSTREAM_ENABLED == 1
sif::warning << diagnosticPrefix <<"Opening device failed with error code " << errno <<
"." << std::endl;
sif::warning << "Error description: " << strerror(errno) << std::endl;
#else
sif::printError("%sOpening device failed with error code %d.\n", diagnosticPrefix);
sif::printWarning("Error description: %s\n", strerror(errno));
#endif /* FSFW_CPP_OSTREAM_ENABLED == 1 */
#endif /* FSFW_VERBOSE_LEVEL >= 1 */
openStatus = OPEN_FILE_FAILED;
}
}
utility::UnixFileHelper::~UnixFileHelper() {
if(fileDescriptor != nullptr) {
close(*fileDescriptor);
}
}
ReturnValue_t utility::UnixFileHelper::getOpenResult() const {
return openStatus;
}

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@ -1,36 +0,0 @@
#ifndef LINUX_UTILITY_UTILITY_H_
#define LINUX_UTILITY_UTILITY_H_
#include <cerrno>
#include <cstring>
#include <fsfw/serviceinterface/ServiceInterface.h>
#include <fcntl.h>
#include <unistd.h>
namespace utility {
void handleIoctlError(const char* const customPrintout);
class UnixFileHelper {
public:
static constexpr int READ_WRITE_FLAG = O_RDWR;
static constexpr int READ_ONLY_FLAG = O_RDONLY;
static constexpr int NON_BLOCKING_IO_FLAG = O_NONBLOCK;
static constexpr ReturnValue_t OPEN_FILE_FAILED = 1;
UnixFileHelper(std::string device, int* fileDescriptor, int flags,
std::string diagnosticPrefix = "");
virtual~ UnixFileHelper();
ReturnValue_t getOpenResult() const;
private:
int* fileDescriptor = nullptr;
ReturnValue_t openStatus = HasReturnvaluesIF::RETURN_OK;
};
}
#endif /* LINUX_UTILITY_UTILITY_H_ */

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@ -7,7 +7,7 @@
<buildSpec>
<buildCommand>
<name>org.eclipse.cdt.managedbuilder.core.genmakebuilder</name>
<triggers>clean,full,incremental,</triggers>
<triggers>full,incremental,</triggers>
<arguments>
</arguments>
</buildCommand>

View File

@ -10,6 +10,9 @@ target_sources(${TARGET_NAME} PUBLIC
PDU1Handler.cpp
PDU2Handler.cpp
ACUHandler.cpp
SyrlinksHkHandler.cpp
Max31865PT1000Handler.cpp
IMTQHandler.cpp
)

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@ -0,0 +1,216 @@
#include "IMTQHandler.h"
#include <fsfwconfig/OBSWConfig.h>
#include <fsfw/globalfunctions/CRC.h>
#include <fsfw/datapool/PoolReadGuard.h>
#include <fsfwconfig/OBSWConfig.h>
IMTQHandler::IMTQHandler(object_id_t objectId, object_id_t comIF, CookieIF * comCookie) :
DeviceHandlerBase(objectId, comIF, comCookie), engHkDataset(this) {
if (comCookie == NULL) {
sif::error << "IMTQHandler: Invalid com cookie" << std::endl;
}
}
IMTQHandler::~IMTQHandler() {
}
void IMTQHandler::doStartUp(){
if(mode == _MODE_START_UP){
//TODO: Set to MODE_ON again
setMode(MODE_NORMAL);
}
}
void IMTQHandler::doShutDown(){
}
ReturnValue_t IMTQHandler::buildNormalDeviceCommand(
DeviceCommandId_t * id) {
*id = IMTQ::GET_ENG_HK_DATA;
return buildCommandFromCommand(*id, NULL, 0);
}
ReturnValue_t IMTQHandler::buildTransitionDeviceCommand(
DeviceCommandId_t * id){
return HasReturnvaluesIF::RETURN_OK;
}
ReturnValue_t IMTQHandler::buildCommandFromCommand(
DeviceCommandId_t deviceCommand, const uint8_t * commandData,
size_t commandDataLen) {
switch(deviceCommand) {
case(IMTQ::GET_ENG_HK_DATA): {
commandBuffer[0] = IMTQ::CC::GET_ENG_HK_DATA;
rawPacket = commandBuffer;
rawPacketLen = 1;
return RETURN_OK;
}
case(IMTQ::START_ACTUATION_DIPOLE): {
/* IMTQ expects low byte first */
commandBuffer[0] = IMTQ::CC::START_ACTUATION_DIPOLE;
commandBuffer[1] = *(commandData + 1);
commandBuffer[2] = *(commandData);
commandBuffer[3] = *(commandData + 3);
commandBuffer[4] = *(commandData + 2);
commandBuffer[5] = *(commandData + 5);
commandBuffer[6] = *(commandData + 4);
commandBuffer[7] = *(commandData + 7);
commandBuffer[8] = *(commandData + 6);
rawPacket = commandBuffer;
rawPacketLen = 9;
return RETURN_OK;
}
default:
return DeviceHandlerIF::COMMAND_NOT_IMPLEMENTED;
}
return HasReturnvaluesIF::RETURN_FAILED;
}
void IMTQHandler::fillCommandAndReplyMap() {
this->insertInCommandAndReplyMap(IMTQ::GET_ENG_HK_DATA, 1, &engHkDataset,
IMTQ::SIZE_ENG_HK_DATA_REPLY, false, true, IMTQ::SIZE_ENG_HK_DATA_REPLY);
}
ReturnValue_t IMTQHandler::scanForReply(const uint8_t *start,
size_t remainingSize, DeviceCommandId_t *foundId, size_t *foundLen) {
ReturnValue_t result = RETURN_OK;
switch(*start) {
case(IMTQ::CC::GET_ENG_HK_DATA):
*foundLen = IMTQ::SIZE_ENG_HK_DATA_REPLY;
*foundId = IMTQ::GET_ENG_HK_DATA;
break;
default:
sif::debug << "IMTQHandler::scanForReply: Reply contains invalid command code" << std::endl;
result = IGNORE_REPLY_DATA;
break;
}
return result;
}
ReturnValue_t IMTQHandler::interpretDeviceReply(DeviceCommandId_t id,
const uint8_t *packet) {
ReturnValue_t result = RETURN_OK;
result = parseStatusByte(packet);
if (result != RETURN_OK) {
return result;
}
switch (id) {
case (IMTQ::GET_ENG_HK_DATA):
fillEngHkDataset(packet);
break;
default: {
sif::debug << "IMTQHandler::interpretDeviceReply: Unknown device reply id" << std::endl;
return DeviceHandlerIF::UNKNOWN_DEVICE_REPLY;
}
}
return RETURN_OK;
}
ReturnValue_t IMTQHandler::parseStatusByte(const uint8_t* packet) {
uint8_t cmdErrorField = *(packet + 1) & 0xF;
switch (cmdErrorField) {
case 0:
return RETURN_OK;
case 1:
return REJECTED_WITHOUT_REASON;
case 2:
return INVALID_COMMAND_CODE;
case 3:
return PARAMETER_MISSING;
case 4:
return PARAMETER_INVALID;
case 5:
return CC_UNAVAILABLE;
case 7:
return INTERNAL_PROCESSING_ERROR;
default:
sif::error << "IMTQHandler::parseStatusByte: CMD Error field contains unknown error code "
<< cmdErrorField << std::endl;
return CMD_ERR_UNKNOWN;
}
}
void IMTQHandler::fillEngHkDataset(const uint8_t* packet) {
uint8_t offset = 2;
engHkDataset.digitalVoltageMv = *(packet + offset + 1) | *(packet + offset);
offset += 2;
engHkDataset.analogVoltageMv = *(packet + offset + 1) | *(packet + offset);
offset += 2;
engHkDataset.digitalCurrentA = (*(packet + offset + 1) | *(packet + offset)) * 0.0001;
offset += 2;
engHkDataset.analogCurrentA = (*(packet + offset + 1) | *(packet + offset)) * 0.0001;
offset += 2;
engHkDataset.coilXcurrentA = (*(packet + offset + 1) | *(packet + offset)) * 0.0001;
offset += 2;
engHkDataset.coilYcurrentA = (*(packet + offset + 1) | *(packet + offset)) * 0.0001;
offset += 2;
engHkDataset.coilZcurrentA = (*(packet + offset + 1) | *(packet + offset)) * 0.0001;
offset += 2;
engHkDataset.coilXTemperature = (*(packet + offset + 1) | *(packet + offset));
offset += 2;
engHkDataset.coilYTemperature = (*(packet + offset + 1) | *(packet + offset));
offset += 2;
engHkDataset.coilZTemperature = (*(packet + offset + 1) | *(packet + offset));
offset += 2;
engHkDataset.mcuTemperature = (*(packet + offset + 1) | *(packet + offset));
#if OBSW_VERBOSE_LEVEL >= 1 && IMQT_DEBUG == 1
sif::info << "IMTQ digital voltage: " << engHkDataset.digitalVoltageMv << " mV" << std::endl;
sif::info << "IMTQ analog voltage: " << engHkDataset.analogVoltageMv << " mV" << std::endl;
sif::info << "IMTQ digital current: " << engHkDataset.digitalCurrentA << " A" << std::endl;
sif::info << "IMTQ analog current: " << engHkDataset.analogCurrentA << " A" << std::endl;
sif::info << "IMTQ coil X current: " << engHkDataset.coilXcurrentA << " A" << std::endl;
sif::info << "IMTQ coil Y current: " << engHkDataset.coilYcurrentA << " A" << std::endl;
sif::info << "IMTQ coil Z current: " << engHkDataset.coilZcurrentA << " A" << std::endl;
sif::info << "IMTQ coil X temperature: " << engHkDataset.coilXTemperature << " °C"
<< std::endl;
sif::info << "IMTQ coil Y temperature: " << engHkDataset.coilYTemperature << " °C"
<< std::endl;
sif::info << "IMTQ coil Z temperature: " << engHkDataset.coilZTemperature << " °C"
<< std::endl;
sif::info << "IMTQ coil MCU temperature: " << engHkDataset.mcuTemperature << " °C"
<< std::endl;
#endif
}
void IMTQHandler::setNormalDatapoolEntriesInvalid(){
}
uint32_t IMTQHandler::getTransitionDelayMs(Mode_t modeFrom, Mode_t modeTo){
return 500;
}
ReturnValue_t IMTQHandler::initializeLocalDataPool(localpool::DataPool& localDataPoolMap,
LocalDataPoolManager& poolManager) {
localDataPoolMap.emplace(IMTQ::DIGITAL_VOLTAGE_MV, new PoolEntry<uint16_t>( { 0 }));
localDataPoolMap.emplace(IMTQ::ANALOG_VOLTAGE_MV, new PoolEntry<uint16_t>( { 0 }));
localDataPoolMap.emplace(IMTQ::DIGITAL_CURRENT_A, new PoolEntry<float>( { 0 }));
localDataPoolMap.emplace(IMTQ::ANALOG_CURRENT_A, new PoolEntry<float>( { 0 }));
localDataPoolMap.emplace(IMTQ::COIL_X_CURRENT_A, new PoolEntry<float>( { 0 }));
localDataPoolMap.emplace(IMTQ::COIL_Y_CURRENT_A, new PoolEntry<float>( { 0 }));
localDataPoolMap.emplace(IMTQ::COIL_Z_CURRENT_A, new PoolEntry<float>( { 0 }));
localDataPoolMap.emplace(IMTQ::COIL_X_TEMPERATURE, new PoolEntry<uint16_t>( { 0 }));
localDataPoolMap.emplace(IMTQ::COIL_Y_TEMPERATURE, new PoolEntry<uint16_t>( { 0 }));
localDataPoolMap.emplace(IMTQ::COIL_Z_TEMPERATURE, new PoolEntry<uint16_t>( { 0 }));
localDataPoolMap.emplace(IMTQ::MCU_TEMPERATURE, new PoolEntry<uint16_t>( { 0 }));
return HasReturnvaluesIF::RETURN_OK;
}
void IMTQHandler::setModeNormal() {
mode = MODE_NORMAL;
}

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@ -0,0 +1,77 @@
#ifndef MISSION_DEVICES_IMTQHANDLER_H_
#define MISSION_DEVICES_IMTQHANDLER_H_
#include <fsfw/devicehandlers/DeviceHandlerBase.h>
#include <mission/devices/devicedefinitions/IMTQHandlerDefinitions.h>
#include <string.h>
/**
* @brief This is the device handler for the ISIS Magnetorquer iMTQ.
*
* @author J. Meier
*/
class IMTQHandler: public DeviceHandlerBase {
public:
IMTQHandler(object_id_t objectId, object_id_t comIF, CookieIF * comCookie);
virtual ~IMTQHandler();
/**
* @brief Sets mode to MODE_NORMAL. Can be used for debugging.
*/
void setModeNormal();
protected:
void doStartUp() override;
void doShutDown() override;
ReturnValue_t buildNormalDeviceCommand(DeviceCommandId_t * id) override;
ReturnValue_t buildTransitionDeviceCommand(DeviceCommandId_t * id) override;
void fillCommandAndReplyMap() override;
ReturnValue_t buildCommandFromCommand(DeviceCommandId_t deviceCommand,
const uint8_t * commandData,size_t commandDataLen) override;
ReturnValue_t scanForReply(const uint8_t *start, size_t remainingSize,
DeviceCommandId_t *foundId, size_t *foundLen) override;
ReturnValue_t interpretDeviceReply(DeviceCommandId_t id,
const uint8_t *packet) override;
void setNormalDatapoolEntriesInvalid() override;
uint32_t getTransitionDelayMs(Mode_t modeFrom, Mode_t modeTo) override;
ReturnValue_t initializeLocalDataPool(localpool::DataPool& localDataPoolMap,
LocalDataPoolManager& poolManager) override;
private:
static const uint8_t INTERFACE_ID = CLASS_ID::IMTQ_HANDLER;
static const ReturnValue_t INVALID_COMMAND_CODE = MAKE_RETURN_CODE(0xA0);
static const ReturnValue_t PARAMETER_MISSING = MAKE_RETURN_CODE(0xA1);
static const ReturnValue_t PARAMETER_INVALID = MAKE_RETURN_CODE(0xA2);
static const ReturnValue_t CC_UNAVAILABLE = MAKE_RETURN_CODE(0xA3);
static const ReturnValue_t INTERNAL_PROCESSING_ERROR = MAKE_RETURN_CODE(0xA4);
static const ReturnValue_t REJECTED_WITHOUT_REASON = MAKE_RETURN_CODE(0xA5);
static const ReturnValue_t CMD_ERR_UNKNOWN = MAKE_RETURN_CODE(0xA6);
IMTQ::EngHkDataset engHkDataset;
uint8_t commandBuffer[IMTQ::MAX_COMMAND_SIZE];
/**
* @brief Each reply contains a status byte giving information about a request. This function
* parses this byte and returns the associated failure message.
*
* @param packet Pointer to the received message containing the status byte.
*
* @return The return code derived from the received status byte.
*/
ReturnValue_t parseStatusByte(const uint8_t* packet);
/**
* @brief This function fills the engineering housekeeping dataset with the received data.
* @param packet Pointer to the received data.
*
*/
void fillEngHkDataset(const uint8_t* packet);
};
#endif /* MISSION_DEVICES_IMTQHANDLER_H_ */

View File

@ -1,3 +1,4 @@
#include <fsfw/datapool/PoolReadGuard.h>
#include "MGMHandlerLIS3MDL.h"
#include <fsfw/datapool/PoolReadGuard.h>
@ -32,8 +33,8 @@ void MGMHandlerLIS3MDL::doStartUp() {
/* Will be set by checking device ID (WHO AM I register) */
if(commandExecuted) {
commandExecuted = false;
}
internalState = InternalState::STATE_SETUP;
}
break;
}
case(InternalState::STATE_SETUP): {
@ -462,7 +463,7 @@ void MGMHandlerLIS3MDL::doTransition(Mode_t modeFrom, Submode_t subModeFrom) {
}
uint32_t MGMHandlerLIS3MDL::getTransitionDelayMs(Mode_t from, Mode_t to) {
return 10000;
return 20000;
}
void MGMHandlerLIS3MDL::modeChanged(void) {

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@ -0,0 +1,358 @@
#include "Max31865PT1000Handler.h"
#include <bitset>
#include <cmath>
Max31865PT1000Handler::Max31865PT1000Handler(object_id_t objectId,
object_id_t comIF, CookieIF *comCookie, uint8_t switchId):
DeviceHandlerBase(objectId, comIF, comCookie), switchId(switchId),
sensorDataset(this), sensorDatasetSid(sensorDataset.getSid()) {
#if OBSW_VERBOSE_LEVEL >= 1
debugDivider = new PeriodicOperationDivider(10);
#endif
}
Max31865PT1000Handler::~Max31865PT1000Handler() {
}
void Max31865PT1000Handler::doStartUp() {
if(internalState == InternalState::NONE) {
internalState = InternalState::WARMUP;
Clock::getUptime(&startTime);
}
if(internalState == InternalState::WARMUP) {
dur_millis_t timeNow = 0;
Clock::getUptime(&timeNow);
if(timeNow - startTime >= 100) {
internalState = InternalState::CONFIGURE;
}
}
if(internalState == InternalState::CONFIGURE) {
if(commandExecuted) {
internalState = InternalState::REQUEST_CONFIG;
commandExecuted = false;
}
}
if(internalState == InternalState::REQUEST_CONFIG) {
if (commandExecuted) {
setMode(MODE_ON);
setMode(MODE_NORMAL);
commandExecuted = false;
internalState = InternalState::RUNNING;
}
}
}
void Max31865PT1000Handler::doShutDown() {
commandExecuted = false;
setMode(MODE_OFF);
}
ReturnValue_t Max31865PT1000Handler::buildNormalDeviceCommand(
DeviceCommandId_t *id) {
if(internalState == InternalState::RUNNING) {
*id = Max31865Definitions::REQUEST_RTD;
return buildCommandFromCommand(*id, nullptr, 0);
}
else if(internalState == InternalState::REQUEST_FAULT_BYTE) {
*id = Max31865Definitions::REQUEST_FAULT_BYTE;
return buildCommandFromCommand(*id, nullptr, 0);
}
else {
return DeviceHandlerBase::NOTHING_TO_SEND;
}
}
ReturnValue_t Max31865PT1000Handler::buildTransitionDeviceCommand(
DeviceCommandId_t *id) {
switch(internalState) {
case(InternalState::NONE):
case(InternalState::WARMUP):
case(InternalState::RUNNING):
return DeviceHandlerBase::NOTHING_TO_SEND;
case(InternalState::CONFIGURE): {
*id = Max31865Definitions::CONFIG_CMD;
uint8_t config[1] = {DEFAULT_CONFIG};
return buildCommandFromCommand(*id, config, 1);
}
case(InternalState::REQUEST_CONFIG): {
*id = Max31865Definitions::REQUEST_CONFIG;
return buildCommandFromCommand(*id, nullptr, 0);
}
default:
#if FSFW_CPP_OSTREAM_ENABLED == 1
sif::error << "Max31865PT1000Handler: Invalid internal state" << std::endl;
#else
sif::printError("Max31865PT1000Handler: Invalid internal state\n");
#endif
return HasReturnvaluesIF::RETURN_FAILED;
}
}
ReturnValue_t Max31865PT1000Handler::buildCommandFromCommand(
DeviceCommandId_t deviceCommand, const uint8_t *commandData,
size_t commandDataLen) {
switch(deviceCommand) {
case(Max31865Definitions::CONFIG_CMD) : {
commandBuffer[0] = static_cast<uint8_t>(Max31865Definitions::CONFIG_CMD);
if(commandDataLen == 1) {
commandBuffer[1] = commandData[0];
DeviceHandlerBase::rawPacketLen = 2;
DeviceHandlerBase::rawPacket = commandBuffer.data();
return HasReturnvaluesIF::RETURN_OK;
}
else {
return DeviceHandlerIF::NO_COMMAND_DATA;
}
}
case(Max31865Definitions::REQUEST_CONFIG): {
commandBuffer[0] = 0x00; // dummy byte
commandBuffer[1] = static_cast<uint8_t>(
Max31865Definitions::REQUEST_CONFIG);
DeviceHandlerBase::rawPacketLen = 2;
DeviceHandlerBase::rawPacket = commandBuffer.data();
return HasReturnvaluesIF::RETURN_OK;
}
case(Max31865Definitions::REQUEST_RTD): {
commandBuffer[0] = static_cast<uint8_t>(
Max31865Definitions::REQUEST_RTD);
// two dummy bytes
commandBuffer[1] = 0x00;
commandBuffer[2] = 0x00;
DeviceHandlerBase::rawPacketLen = 3;
DeviceHandlerBase::rawPacket = commandBuffer.data();
return HasReturnvaluesIF::RETURN_OK;
}
case(Max31865Definitions::REQUEST_FAULT_BYTE): {
commandBuffer[0] = static_cast<uint8_t>(
Max31865Definitions::REQUEST_FAULT_BYTE);
commandBuffer[1] = 0x00;
DeviceHandlerBase::rawPacketLen = 2;
DeviceHandlerBase::rawPacket = commandBuffer.data();
return HasReturnvaluesIF::RETURN_OK;
}
default:
//Unknown DeviceCommand
return DeviceHandlerIF::COMMAND_NOT_IMPLEMENTED;
}
}
void Max31865PT1000Handler::fillCommandAndReplyMap() {
insertInCommandAndReplyMap(Max31865Definitions::CONFIG_CMD, 3);
insertInCommandAndReplyMap(Max31865Definitions::REQUEST_CONFIG, 3);
insertInCommandAndReplyMap(Max31865Definitions::REQUEST_RTD, 3,
&sensorDataset);
insertInCommandAndReplyMap(Max31865Definitions::REQUEST_FAULT_BYTE, 3);
}
ReturnValue_t Max31865PT1000Handler::scanForReply(const uint8_t *start,
size_t remainingSize, DeviceCommandId_t *foundId, size_t *foundLen) {
size_t rtdReplySize = 3;
size_t configReplySize = 2;
if(remainingSize == rtdReplySize and
internalState == InternalState::RUNNING) {
*foundId = Max31865Definitions::REQUEST_RTD;
*foundLen = rtdReplySize;
}
if(remainingSize == configReplySize) {
if(internalState == InternalState::CONFIGURE) {
commandExecuted = true;
*foundLen = configReplySize;
*foundId = Max31865Definitions::CONFIG_CMD;
}
else if(internalState == InternalState::REQUEST_FAULT_BYTE) {
*foundId = Max31865Definitions::REQUEST_FAULT_BYTE;
*foundLen = 2;
internalState = InternalState::RUNNING;
}
else {
*foundId = Max31865Definitions::REQUEST_CONFIG;
*foundLen = configReplySize;
}
}
return RETURN_OK;
}
ReturnValue_t Max31865PT1000Handler::interpretDeviceReply(
DeviceCommandId_t id, const uint8_t *packet) {
switch(id) {
case(Max31865Definitions::REQUEST_CONFIG): {
if(packet[1] != DEFAULT_CONFIG) {
#if FSFW_CPP_OSTREAM_ENABLED == 1
// it propably would be better if we at least try one restart..
sif::error << "Max31865PT1000Handler: Invalid configuration reply!" << std::endl;
#else
sif::printError("Max31865PT1000Handler: Invalid configuration reply!\n");
#endif
return HasReturnvaluesIF::RETURN_OK;
}
// set to true for invalid configs too for now.
if(internalState == InternalState::REQUEST_CONFIG) {
commandExecuted = true;
}
else if(internalState == InternalState::RUNNING) {
// we should propably generate a telemetry with the config byte
// as payload here.
}
break;
}
case(Max31865Definitions::REQUEST_RTD): {
// first bit of LSB reply byte is the fault bit
uint8_t faultBit = packet[2] & 0b0000'0001;
if(faultBit == 1) {
// Maybe we should attempt to restart it?
if(faultByte == 0) {
internalState = InternalState::REQUEST_FAULT_BYTE;
}
}
// RTD value consists of last seven bits of the LSB reply byte and
// the MSB reply byte
uint16_t adcCode = ((packet[1] << 8) | packet[2]) >> 1;
// do something with rtd value, will propably be stored in
// dataset.
float rtdValue = adcCode * RTD_RREF_PT1000 / INT16_MAX;
// calculate approximation
float approxTemp = adcCode / 32.0 - 256.0;
#if OBSW_VERBOSE_LEVEL >= 1
if(debugDivider->checkAndIncrement()) {
#if FSFW_CPP_OSTREAM_ENABLED == 1
sif::info << "Max31865PT1000Handler::interpretDeviceReply: Measured "
<< "resistance is " << rtdValue << " Ohms." << std::endl;
sif::info << "Approximated temperature is " << approxTemp << " °C"
<< std::endl;
#else
sif::printInfo("Max31865PT1000Handler::interpretDeviceReply: Measured resistance is %f"
" Ohms.\n", rtdValue);
sif::printInfo("Approximated temperature is %f C\n", approxTemp);
#endif
sensorDataset.setChanged(true);
}
#endif
ReturnValue_t result = sensorDataset.read();
if(result != HasReturnvaluesIF::RETURN_OK) {
// Configuration error
#if FSFW_CPP_OSTREAM_ENABLED == 1
sif::debug << "Max31865PT1000Handler::interpretDeviceReply: Error reading dataset!"
<< std::endl;
#else
sif::printDebug("Max31865PT1000Handler::interpretDeviceReply: Error reading dataset!\n");
#endif
return result;
}
if(not sensorDataset.isValid()) {
sensorDataset.temperatureCelcius.setValid(true);
}
sensorDataset.temperatureCelcius = approxTemp;
result = sensorDataset.commit();
if(result != HasReturnvaluesIF::RETURN_OK) {
// Configuration error
#if FSFW_CPP_OSTREAM_ENABLED == 1
sif::debug << "Max31865PT1000Handler::interpretDeviceReply: "
"Error commiting dataset!" << std::endl;
#else
sif::printDebug("Max31865PT1000Handler::interpretDeviceReply: "
"Error commiting dataset!\n");
#endif
return result;
}
break;
}
case(Max31865Definitions::REQUEST_FAULT_BYTE): {
faultByte = packet[1];
#if OBSW_VERBOSE_LEVEL >= 1
#if FSFW_CPP_OSTREAM_ENABLED == 1
sif::info << "Max31865PT1000Handler::interpretDeviceReply: Fault byte"
" is: 0b" << std::bitset<8>(faultByte) << std::endl;
#else
sif::printInfo("Max31865PT1000Handler::interpretDeviceReply: Fault byte"
" is: 0b" BYTE_TO_BINARY_PATTERN "\n", BYTE_TO_BINARY(faultByte));
#endif
#endif
ReturnValue_t result = sensorDataset.read();
if(result != HasReturnvaluesIF::RETURN_OK) {
// Configuration error
#if FSFW_CPP_OSTREAM_ENABLED == 1
sif::debug << "Max31865PT1000Handler::interpretDeviceReply: "
"Error reading dataset!" << std::endl;
#else
sif::printDebug("Max31865PT1000Handler::interpretDeviceReply: "
"Error reading dataset!\n");
#endif
return result;
}
sensorDataset.errorByte.setValid(true);
sensorDataset.errorByte = faultByte;
if(faultByte != 0) {
sensorDataset.temperatureCelcius.setValid(false);
}
result = sensorDataset.commit();
if(result != HasReturnvaluesIF::RETURN_OK) {
// Configuration error
#if FSFW_CPP_OSTREAM_ENABLED == 1
sif::debug << "Max31865PT1000Handler::interpretDeviceReply: "
"Error commiting dataset!" << std::endl;
#else
sif::printDebug("Max31865PT1000Handler::interpretDeviceReply: "
"Error commiting dataset!\n");
#endif
return result;
}
break;
}
default:
break;
}
return HasReturnvaluesIF::RETURN_OK;
}
void Max31865PT1000Handler::debugInterface(uint8_t positionTracker,
object_id_t objectId, uint32_t parameter) {
}
uint32_t Max31865PT1000Handler::getTransitionDelayMs(
Mode_t modeFrom, Mode_t modeTo) {
return 5000;
}
ReturnValue_t Max31865PT1000Handler::getSwitches(
const uint8_t **switches, uint8_t *numberOfSwitches) {
return DeviceHandlerBase::NO_SWITCH;
}
void Max31865PT1000Handler::doTransition(Mode_t modeFrom,
Submode_t subModeFrom) {
DeviceHandlerBase::doTransition(modeFrom, subModeFrom);
}
ReturnValue_t Max31865PT1000Handler::initializeLocalDataPool(localpool::DataPool& localDataPoolMap,
LocalDataPoolManager& poolManager) {
localDataPoolMap.emplace(Max31865Definitions::PoolIds::TEMPERATURE_C,
new PoolEntry<float>({0}, 1, true));
localDataPoolMap.emplace(Max31865Definitions::PoolIds::FAULT_BYTE,
new PoolEntry<uint8_t>({0}));
poolManager.subscribeForPeriodicPacket(sensorDatasetSid,
false, 4.0, false);
return HasReturnvaluesIF::RETURN_OK;
}
void Max31865PT1000Handler::modeChanged() {
internalState = InternalState::NONE;
}

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@ -0,0 +1,104 @@
#ifndef MISSION_DEVICES_MAX31865PT1000HANDLER_H_
#define MISSION_DEVICES_MAX31865PT1000HANDLER_H_
#include <OBSWConfig.h>
#include <fsfw/devicehandlers/DeviceHandlerBase.h>
#include <fsfw/globalfunctions/PeriodicOperationDivider.h>
#include <array>
#include <cstdint>
#include "devicedefinitions/Max31865Definitions.h"
/**
* @brief Device Handler for the thermal sensors
* @details
* Documentation of devices:
* MAX31865 RTD converter:
* https://datasheets.maximintegrated.com/en/ds/MAX31865.pdf
* Pt1000 platinum resistance thermometers OMEGA F2020-1000-1/3B:
* https://br.omega.com/omegaFiles/temperature/pdf/F1500_F2000_F4000.pdf
*
* The thermal sensor values are measured using the MAX31865 RTD converter IC
* which creates digital values from the measured resistance of the Pt1000
* devices which can be read with the SPI interface.
* Refer to the SOURCE system schematic for the exact setup and number
* of devices.
*
* @author R. Mueller
* @ingroup devices
*/
class Max31865PT1000Handler: public DeviceHandlerBase {
public:
Max31865PT1000Handler(object_id_t objectId, object_id_t comIF,
CookieIF * comCookie, uint8_t switchId);
virtual~ Max31865PT1000Handler();
// Configuration in 8 digit code:
// 1. 1 for V_BIAS enabled, 0 for disabled
// 2. 1 for Auto-conversion, 0 for off
// 3. 1 for 1-shot enabled, 0 for disabled
// 4. 1 for 3-wire disabled, 0 for disabled
// 5./6. Fault detection: 00 for no action, 01 for automatic delay, 1
// 0 for run fault detection with manual delay,
// 11 for finish fault detection with manual delay
// 7. Fault status: 1 for auto-clear, 0 for auto-clear off
// 8. 1 for 50 Hz filter, 0 for 60 Hz filter (noise rejection filter)
static constexpr uint8_t DEFAULT_CONFIG = 0b11000001;
static constexpr float RTD_RREF_PT1000 = 4000.0; //!< Ohm
static constexpr float RTD_RESISTANCE0_PT1000 = 1000.0; //!< Ohm
protected:
/* DeviceHandlerBase abstract function implementation */
void doStartUp() override;
void doShutDown() override;
ReturnValue_t buildNormalDeviceCommand(DeviceCommandId_t * id) override;
ReturnValue_t buildTransitionDeviceCommand(DeviceCommandId_t * id) override;
ReturnValue_t buildCommandFromCommand(DeviceCommandId_t deviceCommand,
const uint8_t * commandData, size_t commandDataLen) override;
void fillCommandAndReplyMap() override;
ReturnValue_t scanForReply(const uint8_t *start, size_t remainingSize,
DeviceCommandId_t *foundId, size_t *foundLen) override;
ReturnValue_t interpretDeviceReply(DeviceCommandId_t id,
const uint8_t *packet) override;
uint32_t getTransitionDelayMs(Mode_t modeFrom, Mode_t modeTo) override;
ReturnValue_t getSwitches(const uint8_t **switches,
uint8_t *numberOfSwitches) override;
void doTransition(Mode_t modeFrom, Submode_t subModeFrom) override;
void debugInterface(uint8_t positionTracker = 0,
object_id_t objectId = 0, uint32_t parameter = 0) override;
ReturnValue_t initializeLocalDataPool(localpool::DataPool& localDataPoolMap,
LocalDataPoolManager& poolManager) override;
void modeChanged() override;
private:
const uint8_t switchId;
enum class InternalState {
NONE,
WARMUP,
CONFIGURE,
REQUEST_CONFIG,
RUNNING,
REQUEST_FAULT_BYTE
};
InternalState internalState = InternalState::NONE;
bool commandExecuted = false;
dur_millis_t startTime = 0;
uint8_t faultByte = 0;
std::array<uint8_t, 3> commandBuffer { 0 };
Max31865Definitions::Max31865Set sensorDataset;
sid_t sensorDatasetSid;
#if OBSW_VERBOSE_LEVEL >= 1
PeriodicOperationDivider* debugDivider;
#endif
};
#endif /* MISSION_DEVICES_MAX31865PT1000HANDLER_H_ */

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@ -20,7 +20,7 @@ ReturnValue_t PDU1Handler::buildNormalDeviceCommand(
void PDU1Handler::letChildHandleHkReply(DeviceCommandId_t id, const uint8_t *packet) {
parseHkTableReply(packet);
// handleDeviceTM(&pdu1HkTableDataset, id, true);
handleDeviceTM(&pdu1HkTableDataset, id, true);
#if OBSW_VERBOSE_LEVEL >= 1 && PDU1_DEBUG == 1
pdu1HkTableDataset.read();

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@ -0,0 +1,463 @@
#include <mission/devices/SyrlinksHkHandler.h>
#include <fsfwconfig/OBSWConfig.h>
#include <fsfw/globalfunctions/CRC.h>
#include <fsfw/datapool/PoolReadGuard.h>
#include <fsfwconfig/OBSWConfig.h>
SyrlinksHkHandler::SyrlinksHkHandler(object_id_t objectId, object_id_t comIF, CookieIF * comCookie) :
DeviceHandlerBase(objectId, comIF, comCookie), rxDataset(this), txDataset(this) {
if (comCookie == NULL) {
sif::error << "SyrlinksHkHandler: Invalid com cookie" << std::endl;
}
}
SyrlinksHkHandler::~SyrlinksHkHandler() {
}
void SyrlinksHkHandler::doStartUp(){
if(mode == _MODE_START_UP){
setMode(MODE_ON);
}
}
void SyrlinksHkHandler::doShutDown(){
}
ReturnValue_t SyrlinksHkHandler::buildNormalDeviceCommand(
DeviceCommandId_t * id) {
switch (nextCommand) {
case(SYRLINKS::READ_RX_STATUS_REGISTERS):
*id = SYRLINKS::READ_RX_STATUS_REGISTERS;
nextCommand = SYRLINKS::READ_TX_STATUS;
break;
case(SYRLINKS::READ_TX_STATUS):
*id = SYRLINKS::READ_TX_STATUS;
nextCommand = SYRLINKS::READ_TX_WAVEFORM;
break;
case(SYRLINKS::READ_TX_WAVEFORM):
*id = SYRLINKS::READ_TX_WAVEFORM;
nextCommand = SYRLINKS::READ_TX_AGC_VALUE_HIGH_BYTE;
break;
case(SYRLINKS::READ_TX_AGC_VALUE_HIGH_BYTE):
*id = SYRLINKS::READ_TX_AGC_VALUE_HIGH_BYTE;
nextCommand = SYRLINKS::READ_TX_AGC_VALUE_LOW_BYTE;
break;
case(SYRLINKS::READ_TX_AGC_VALUE_LOW_BYTE):
*id = SYRLINKS::READ_TX_AGC_VALUE_LOW_BYTE;
nextCommand = SYRLINKS::READ_RX_STATUS_REGISTERS;
break;
default:
sif::debug << "SyrlinksHkHandler::buildNormalDeviceCommand: rememberCommandId has invalid"
<< "command id" << std::endl;
break;
}
return buildCommandFromCommand(*id, NULL, 0);
}
ReturnValue_t SyrlinksHkHandler::buildTransitionDeviceCommand(
DeviceCommandId_t * id){
return HasReturnvaluesIF::RETURN_OK;
}
ReturnValue_t SyrlinksHkHandler::buildCommandFromCommand(
DeviceCommandId_t deviceCommand, const uint8_t * commandData,
size_t commandDataLen) {
switch(deviceCommand) {
case(SYRLINKS::RESET_UNIT): {
resetCommand.copy(reinterpret_cast<char*>(commandBuffer), resetCommand.size(), 0);
rawPacketLen = resetCommand.size();
rawPacket = commandBuffer;
return RETURN_OK;
}
case(SYRLINKS::SET_TX_MODE_STANDBY): {
setTxModeStandby.copy(reinterpret_cast<char*>(commandBuffer), setTxModeStandby.size(), 0);
rawPacketLen = setTxModeStandby.size();
rawPacket = commandBuffer;
return RETURN_OK;
}
case(SYRLINKS::SET_TX_MODE_MODULATION): {
setTxModeModulation.copy(reinterpret_cast<char*>(commandBuffer), setTxModeModulation.size(), 0);
rawPacketLen = setTxModeModulation.size();
rawPacket = commandBuffer;
return RETURN_OK;
}
case(SYRLINKS::SET_TX_MODE_CW): {
setTxModeCw.copy(reinterpret_cast<char*>(commandBuffer), setTxModeCw.size(), 0);
rawPacketLen = setTxModeCw.size();
rawPacket = commandBuffer;
return RETURN_OK;
}
case(SYRLINKS::READ_RX_STATUS_REGISTERS): {
readRxStatusRegCommand.copy(reinterpret_cast<char*>(commandBuffer), readRxStatusRegCommand.size(), 0);
rawPacketLen = readRxStatusRegCommand.size();
rawPacket = commandBuffer;
return RETURN_OK;
}
case(SYRLINKS::READ_TX_STATUS): {
readTxStatus.copy(reinterpret_cast<char*>(commandBuffer), readTxStatus.size(), 0);
rawPacketLen = readTxStatus.size();
rememberCommandId = SYRLINKS::READ_TX_STATUS;
rawPacket = commandBuffer;
return RETURN_OK;
}
case(SYRLINKS::READ_TX_WAVEFORM): {
readTxWaveform.copy(reinterpret_cast<char*>(commandBuffer), readTxStatus.size(), 0);
rawPacketLen = readTxWaveform.size();
rememberCommandId = SYRLINKS::READ_TX_WAVEFORM;
rawPacket = commandBuffer;
return RETURN_OK;
}
case(SYRLINKS::READ_TX_AGC_VALUE_HIGH_BYTE): {
readTxAgcValueHighByte.copy(reinterpret_cast<char*>(commandBuffer), readTxStatus.size(), 0);
rawPacketLen = readTxAgcValueHighByte.size();
rememberCommandId = SYRLINKS::READ_TX_AGC_VALUE_HIGH_BYTE;
rawPacket = commandBuffer;
return RETURN_OK;
}
case(SYRLINKS::READ_TX_AGC_VALUE_LOW_BYTE): {
readTxAgcValueLowByte.copy(reinterpret_cast<char*>(commandBuffer), readTxStatus.size(), 0);
rawPacketLen = readTxAgcValueLowByte.size();
rememberCommandId = SYRLINKS::READ_TX_AGC_VALUE_LOW_BYTE;
rawPacket = commandBuffer;
return RETURN_OK;
}
default:
return DeviceHandlerIF::COMMAND_NOT_IMPLEMENTED;
}
return HasReturnvaluesIF::RETURN_FAILED;
}
void SyrlinksHkHandler::fillCommandAndReplyMap() {
this->insertInCommandAndReplyMap(SYRLINKS::RESET_UNIT, 1, nullptr, SYRLINKS::ACK_SIZE, false,
true, SYRLINKS::ACK_REPLY);
this->insertInCommandAndReplyMap(SYRLINKS::SET_TX_MODE_STANDBY, 1, nullptr, SYRLINKS::ACK_SIZE,
false, true, SYRLINKS::ACK_REPLY);
this->insertInCommandAndReplyMap(SYRLINKS::SET_TX_MODE_MODULATION, 1, nullptr,
SYRLINKS::ACK_SIZE, false, true, SYRLINKS::ACK_REPLY);
this->insertInCommandAndReplyMap(SYRLINKS::SET_TX_MODE_CW, 1, nullptr, SYRLINKS::ACK_SIZE,
false, true, SYRLINKS::ACK_REPLY);
this->insertInCommandAndReplyMap(SYRLINKS::READ_TX_STATUS, 1, &txDataset,
SYRLINKS::READ_ONE_REGISTER_REPLY_SIE);
this->insertInCommandAndReplyMap(SYRLINKS::READ_TX_WAVEFORM, 1, &txDataset,
SYRLINKS::READ_ONE_REGISTER_REPLY_SIE);
this->insertInCommandAndReplyMap(SYRLINKS::READ_TX_AGC_VALUE_HIGH_BYTE, 1, &txDataset,
SYRLINKS::READ_ONE_REGISTER_REPLY_SIE);
this->insertInCommandAndReplyMap(SYRLINKS::READ_TX_AGC_VALUE_LOW_BYTE, 1, &txDataset,
SYRLINKS::READ_ONE_REGISTER_REPLY_SIE);
this->insertInCommandAndReplyMap(SYRLINKS::READ_RX_STATUS_REGISTERS, 1, &rxDataset,
SYRLINKS::RX_STATUS_REGISTERS_REPLY_SIZE);
}
ReturnValue_t SyrlinksHkHandler::scanForReply(const uint8_t *start,
size_t remainingSize, DeviceCommandId_t *foundId, size_t *foundLen) {
ReturnValue_t result = RETURN_OK;
if(*start != '<') {
sif::error << "SyrlinksHkHandler::scanForReply: Missing start frame character" << std::endl;
return MISSING_START_FRAME_CHARACTER;
}
switch(*(start + 1)) {
case('A'):
*foundLen = SYRLINKS::ACK_SIZE;
*foundId = SYRLINKS::ACK_REPLY;
break;
case('E'):
*foundLen = SYRLINKS::RX_STATUS_REGISTERS_REPLY_SIZE;
*foundId = SYRLINKS::READ_RX_STATUS_REGISTERS;
break;
case('R'):
*foundId = rememberCommandId;
*foundLen = SYRLINKS::READ_ONE_REGISTER_REPLY_SIE;
break;
default:
sif::error << "SyrlinksHkHandler::scanForReply: Unknown reply identifier" << std::endl;
result = IGNORE_REPLY_DATA;
break;
}
return result;
}
ReturnValue_t SyrlinksHkHandler::interpretDeviceReply(DeviceCommandId_t id,
const uint8_t *packet) {
ReturnValue_t result;
switch (id) {
case (SYRLINKS::ACK_REPLY):
result = verifyReply(packet, SYRLINKS::ACK_SIZE);
if (result != RETURN_OK) {
sif::error << "SyrlinksHkHandler::interpretDeviceReply: Acknowledgement reply has "
"invalid crc" << std::endl;
return CRC_FAILURE;
}
result = parseReplyStatus(reinterpret_cast<const char*>(packet + SYRLINKS::MESSAGE_HEADER_SIZE));
if (result != RETURN_OK) {
return result;
}
break;
case(SYRLINKS::READ_RX_STATUS_REGISTERS):
result = verifyReply(packet, SYRLINKS::RX_STATUS_REGISTERS_REPLY_SIZE);
if (result != RETURN_OK) {
sif::error << "SyrlinksHkHandler::interpretDeviceReply: Read rx status registers reply "
<< "has invalid crc" << std::endl;
return CRC_FAILURE;
}
parseRxStatusRegistersReply(packet);
break;
case(SYRLINKS::READ_TX_STATUS):
result = verifyReply(packet, SYRLINKS::READ_ONE_REGISTER_REPLY_SIE);
if (result != RETURN_OK) {
sif::error << "SyrlinksHkHandler::interpretDeviceReply: Read tx status reply "
<< "has invalid crc" << std::endl;
return CRC_FAILURE;
}
parseTxStatusReply(packet);
break;
case(SYRLINKS::READ_TX_WAVEFORM):
result = verifyReply(packet, SYRLINKS::READ_ONE_REGISTER_REPLY_SIE);
if (result != RETURN_OK) {
sif::error << "SyrlinksHkHandler::interpretDeviceReply: Read tx waveform reply "
<< "has invalid crc" << std::endl;
return CRC_FAILURE;
}
parseTxWaveformReply(packet);
break;
case(SYRLINKS::READ_TX_AGC_VALUE_HIGH_BYTE):
result = verifyReply(packet, SYRLINKS::READ_ONE_REGISTER_REPLY_SIE);
if (result != RETURN_OK) {
sif::error << "SyrlinksHkHandler::interpretDeviceReply: Read tx AGC high byte reply "
<< "has invalid crc" << std::endl;
return CRC_FAILURE;
}
parseAgcHighByte(packet);
break;
case(SYRLINKS::READ_TX_AGC_VALUE_LOW_BYTE):
result = verifyReply(packet, SYRLINKS::READ_ONE_REGISTER_REPLY_SIE);
if (result != RETURN_OK) {
sif::error << "SyrlinksHkHandler::interpretDeviceReply: Read tx AGC low byte reply "
<< "has invalid crc" << std::endl;
return CRC_FAILURE;
}
parseAgcLowByte(packet);
break;
default: {
sif::debug << "SyrlinksHkHandler::interpretDeviceReply: Unknown device reply id"
<< std::endl;
return DeviceHandlerIF::UNKNOWN_DEVICE_REPLY;
}
}
return RETURN_OK;
}
LocalPoolDataSetBase* SyrlinksHkHandler::getDataSetHandle(sid_t sid) {
if (sid == rxDataset.getSid()) {
return &rxDataset;
}
else if (sid== txDataset.getSid()) {
return &txDataset;
}
else {
sif::error << "SyrlinksHkHandler::getDataSetHandle: Invalid sid" << std::endl;
return nullptr;
}
}
std::string SyrlinksHkHandler::convertUint16ToHexString(uint16_t intValue) {
std::stringstream stream;
stream << std::setfill('0') << std::setw(4) << std::hex << std::uppercase << intValue;
return stream.str();
}
uint8_t SyrlinksHkHandler::convertHexStringToUint8(const char* twoChars) {
uint32_t value;
std::string hexString(twoChars, 2);
std::stringstream stream;
stream << std::hex << hexString;
stream >> value;
return static_cast<uint8_t>(value);
}
uint16_t SyrlinksHkHandler::convertHexStringToUint16(const char* fourChars) {
uint16_t value = 0;
value = convertHexStringToUint8(fourChars) << 8 | convertHexStringToUint8(fourChars+2);
return value;
}
uint32_t SyrlinksHkHandler::convertHexStringToUint32(const char* characters, uint8_t numberOfChars) {
uint32_t value = 0;
switch (numberOfChars) {
case 6:
value = convertHexStringToUint8(characters) << 16
| convertHexStringToUint8(characters + 2) << 8
| convertHexStringToUint8(characters + 4);
return value;
case 8:
value = convertHexStringToUint8(characters) << 24
| convertHexStringToUint8(characters + 2) << 16
| convertHexStringToUint8(characters + 4) << 8
| convertHexStringToUint8(characters + 4);
return value;
default:
sif::debug << "SyrlinksHkHandler::convertHexStringToUint32: Invalid number of characters. "
<< "Must be either 6 or 8" << std::endl;
return 0;
}
}
ReturnValue_t SyrlinksHkHandler::parseReplyStatus(const char* status) {
switch (*status) {
case '0':
return RETURN_OK;
case '1':
sif::debug << "SyrlinksHkHandler::parseReplyStatus: Uart faming or parity error"
<< std::endl;
return UART_FRAMIN_OR_PARITY_ERROR_ACK;
case '2':
sif::debug << "SyrlinksHkHandler::parseReplyStatus: Bad character detected" << std::endl;
return BAD_CHARACTER_ACK;
case '3':
sif::debug << "SyrlinksHkHandler::parseReplyStatus: Bad parameter value (unexpected value "
<< "detected" << std::endl;
return BAD_PARAMETER_VALUE_ACK;
case '4':
sif::debug << "SyrlinksHkHandler::parseReplyStatus: Bad end of frame" << std::endl;
return BAD_END_OF_FRAME_ACK;
case '5':
sif::debug << "SyrlinksHkHandler::parseReplyStatus: Unknown command id or attempt to access"
<< " a protected register" << std::endl;
return UNKNOWN_COMMAND_ID_ACK;
case '6':
sif::debug << "SyrlinksHkHandler::parseReplyStatus: Bad CRC" << std::endl;
return BAD_CRC_ACK;
default:
sif::debug << "SyrlinksHkHandler::parseReplyStatus: Status reply contains an invalid "
<< "status id" << std::endl;
return RETURN_FAILED;
}
}
ReturnValue_t SyrlinksHkHandler::verifyReply(const uint8_t* packet, uint8_t size) {
int result = 0;
/* Calculate crc from received packet */
uint16_t crc = CRC::crc16ccitt(packet, size - SYRLINKS::SIZE_CRC_AND_TERMINATION,
CRC_INITIAL_VALUE);
std::string recalculatedCrc = convertUint16ToHexString(crc);
const char* startOfCrc = reinterpret_cast<const char*>(packet + size - SYRLINKS::SIZE_CRC_AND_TERMINATION);
const char* endOfCrc = reinterpret_cast<const char*>(packet + size - 1);
std::string replyCrc(startOfCrc, endOfCrc);
result = recalculatedCrc.compare(replyCrc);
if (result != 0) {
return RETURN_FAILED;
}
return RETURN_OK;
}
void SyrlinksHkHandler::parseRxStatusRegistersReply(const uint8_t* packet) {
PoolReadGuard readHelper(&rxDataset);
uint16_t offset = SYRLINKS::MESSAGE_HEADER_SIZE;
rxDataset.rxStatus = convertHexStringToUint8(reinterpret_cast<const char*>(packet + offset));
offset += 2;
rxDataset.rxSensitivity = convertHexStringToUint32(reinterpret_cast<const char*>(packet + offset), 6);
offset += 6;
rxDataset.rxFrequencyShift = convertHexStringToUint32(reinterpret_cast<const char*>(packet + offset), 6);
offset += 6;
rxDataset.rxIqPower = convertHexStringToUint16(reinterpret_cast<const char*>(packet + offset));
offset += 4;
rxDataset.rxAgcValue = convertHexStringToUint16(reinterpret_cast<const char*>(packet + offset));
offset += 4;
offset += 2; // reserved register
rxDataset.rxDemodEb= convertHexStringToUint32(reinterpret_cast<const char*>(packet + offset), 6);
offset += 6;
rxDataset.rxDemodN0= convertHexStringToUint32(reinterpret_cast<const char*>(packet + offset), 6);
offset += 6;
rxDataset.rxDataRate = convertHexStringToUint8(reinterpret_cast<const char*>(packet + offset));
#if OBSW_VERBOSE_LEVEL >= 1 && SYRLINKS_DEBUG == 1
sif::info << "Syrlinks RX Status: 0x" << std::hex << (unsigned int)rxDataset.rxStatus.value << std::endl;
sif::info << "Syrlinks RX Sensitivity: " << std::dec << rxDataset.rxSensitivity << std::endl;
sif::info << "Syrlinks RX Frequency Shift: " << rxDataset.rxFrequencyShift << std::endl;
sif::info << "Syrlinks RX IQ Power: " << rxDataset.rxIqPower << std::endl;
sif::info << "Syrlinks RX AGC Value: " << rxDataset.rxAgcValue << std::endl;
sif::info << "Syrlinks RX Demod Eb: " << rxDataset.rxDemodEb << std::endl;
sif::info << "Syrlinks RX Demod N0: " << rxDataset.rxDemodN0 << std::endl;
sif::info << "Syrlinks RX Datarate: " << (unsigned int)rxDataset.rxDataRate.value << std::endl;
#endif
}
void SyrlinksHkHandler::parseTxStatusReply(const uint8_t* packet) {
PoolReadGuard readHelper(&txDataset);
uint16_t offset = SYRLINKS::MESSAGE_HEADER_SIZE;
txDataset.txStatus = convertHexStringToUint8(reinterpret_cast<const char*>(packet + offset));
#if OBSW_VERBOSE_LEVEL >= 1 && SYRLINKS_DEBUG == 1
sif::info << "Syrlinks TX Status: 0x" << std::hex << (unsigned int) txDataset.txStatus.value
<< std::endl;
#endif
}
void SyrlinksHkHandler::parseTxWaveformReply(const uint8_t* packet) {
PoolReadGuard readHelper(&txDataset);
uint16_t offset = SYRLINKS::MESSAGE_HEADER_SIZE;
txDataset.txWaveform = convertHexStringToUint8(reinterpret_cast<const char*>(packet + offset));
#if OBSW_VERBOSE_LEVEL >= 1 && SYRLINKS_DEBUG == 1
sif::info << "Syrlinks TX Waveform: 0x" << std::hex << (unsigned int) txDataset.txWaveform.value
<< std::endl;
#endif
}
void SyrlinksHkHandler::parseAgcLowByte(const uint8_t* packet) {
PoolReadGuard readHelper(&txDataset);
uint16_t offset = SYRLINKS::MESSAGE_HEADER_SIZE;
txDataset.txAgcValue = agcValueHighByte << 8 | convertHexStringToUint8(reinterpret_cast<const char*>(packet + offset));
#if OBSW_VERBOSE_LEVEL >= 1 && SYRLINKS_DEBUG == 1
sif::info << "Syrlinks TX AGC Value: " << txDataset.txAgcValue << std::endl;
#endif
}
void SyrlinksHkHandler::parseAgcHighByte(const uint8_t* packet) {
PoolReadGuard readHelper(&txDataset);
uint16_t offset = SYRLINKS::MESSAGE_HEADER_SIZE;
agcValueHighByte = convertHexStringToUint8(reinterpret_cast<const char*>(packet + offset));
}
void SyrlinksHkHandler::setNormalDatapoolEntriesInvalid(){
}
uint32_t SyrlinksHkHandler::getTransitionDelayMs(Mode_t modeFrom, Mode_t modeTo){
return 500;
}
ReturnValue_t SyrlinksHkHandler::initializeLocalDataPool(localpool::DataPool& localDataPoolMap,
LocalDataPoolManager& poolManager) {
localDataPoolMap.emplace(SYRLINKS::RX_STATUS, new PoolEntry<uint8_t>( { 0 }));
localDataPoolMap.emplace(SYRLINKS::RX_SENSITIVITY, new PoolEntry<uint32_t>( { 0 }));
localDataPoolMap.emplace(SYRLINKS::RX_FREQUENCY_SHIFT, new PoolEntry<uint32_t>( { 0 }));
localDataPoolMap.emplace(SYRLINKS::RX_IQ_POWER, new PoolEntry<uint16_t>( { 0 }));
localDataPoolMap.emplace(SYRLINKS::RX_AGC_VALUE, new PoolEntry<uint16_t>( { 0 }));
localDataPoolMap.emplace(SYRLINKS::RX_DEMOD_EB, new PoolEntry<uint32_t>( { 0 }));
localDataPoolMap.emplace(SYRLINKS::RX_DEMOD_N0, new PoolEntry<uint32_t>( { 0 }));
localDataPoolMap.emplace(SYRLINKS::RX_DATA_RATE, new PoolEntry<uint8_t>( { 0 }));
localDataPoolMap.emplace(SYRLINKS::TX_STATUS, new PoolEntry<uint8_t>( { 0 }));
localDataPoolMap.emplace(SYRLINKS::TX_WAVEFORM, new PoolEntry<uint8_t>( { 0 }));
localDataPoolMap.emplace(SYRLINKS::TX_AGC_VALUE, new PoolEntry<uint16_t>( { 0 }));
return HasReturnvaluesIF::RETURN_OK;
}
void SyrlinksHkHandler::setModeNormal() {
mode = MODE_NORMAL;
}

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@ -0,0 +1,178 @@
#ifndef MISSION_DEVICES_SYRLINKSHKHANDLER_H_
#define MISSION_DEVICES_SYRLINKSHKHANDLER_H_
#include <fsfw/devicehandlers/DeviceHandlerBase.h>
#include <mission/devices/devicedefinitions/SyrlinksDefinitions.h>
#include <string.h>
/**
* @brief This is the device handler for the syrlinks transceiver. It handles the command
* transmission and reading of housekeeping data via the housekeeping interface. The
* transmission of telemetry and the reception of telecommands is handled by an additional
* class.
*
* @author J. Meier
*/
class SyrlinksHkHandler: public DeviceHandlerBase {
public:
SyrlinksHkHandler(object_id_t objectId, object_id_t comIF,
CookieIF * comCookie);
virtual ~SyrlinksHkHandler();
/**
* @brief Sets mode to MODE_NORMAL. Can be used for debugging.
*/
void setModeNormal();
protected:
void doStartUp() override;
void doShutDown() override;
ReturnValue_t buildNormalDeviceCommand(DeviceCommandId_t * id) override;
ReturnValue_t buildTransitionDeviceCommand(DeviceCommandId_t * id) override;
void fillCommandAndReplyMap() override;
ReturnValue_t buildCommandFromCommand(DeviceCommandId_t deviceCommand,
const uint8_t * commandData,size_t commandDataLen) override;
ReturnValue_t scanForReply(const uint8_t *start, size_t remainingSize,
DeviceCommandId_t *foundId, size_t *foundLen) override;
ReturnValue_t interpretDeviceReply(DeviceCommandId_t id,
const uint8_t *packet) override;
void setNormalDatapoolEntriesInvalid() override;
uint32_t getTransitionDelayMs(Mode_t modeFrom, Mode_t modeTo) override;
ReturnValue_t initializeLocalDataPool(localpool::DataPool& localDataPoolMap,
LocalDataPoolManager& poolManager) override;
LocalPoolDataSetBase* getDataSetHandle(sid_t sid) override;
private:
static const uint8_t INTERFACE_ID = CLASS_ID::SYRLINKS_HANDLER;
static const ReturnValue_t CRC_FAILURE = MAKE_RETURN_CODE(0xA0);
static const ReturnValue_t UART_FRAMIN_OR_PARITY_ERROR_ACK = MAKE_RETURN_CODE(0xA1);
static const ReturnValue_t BAD_CHARACTER_ACK = MAKE_RETURN_CODE(0xA2);
static const ReturnValue_t BAD_PARAMETER_VALUE_ACK = MAKE_RETURN_CODE(0xA3);
static const ReturnValue_t BAD_END_OF_FRAME_ACK = MAKE_RETURN_CODE(0xA4);
static const ReturnValue_t UNKNOWN_COMMAND_ID_ACK = MAKE_RETURN_CODE(0xA5);
static const ReturnValue_t BAD_CRC_ACK = MAKE_RETURN_CODE(0xA6);
static const ReturnValue_t REPLY_WRONG_SIZE = MAKE_RETURN_CODE(0xA7);
static const ReturnValue_t MISSING_START_FRAME_CHARACTER = MAKE_RETURN_CODE(0xA8);
static const uint8_t CRC_INITIAL_VALUE = 0x0;
std::string resetCommand = "<C04:5A5A:FF41>";
std::string readRxStatusRegCommand = "<E00::825B>";
std::string setTxModeStandby = "<W04:0040:2B9E>";
/** W - write, 04 - 4 bytes in data field, 01 - value, 40 register to write value */
std::string setTxModeModulation = "<W04:0140:5D2A>";
std::string setTxModeCw = "<W04:1040:81CF>";
std::string readTxStatus = "<R02:40:7555>";
std::string readTxWaveform = "<R02:44:B991>";
std::string readTxAgcValueHighByte = "<R02:46:DFF3>";
std::string readTxAgcValueLowByte = "<R02:47:ECC2>";
/**
* In some cases it is not possible to extract from the received reply the information about
* the associated command. This variable is thus used to remember the command id.
*/
DeviceCommandId_t rememberCommandId = SYRLINKS::NONE;
SYRLINKS::RxDataset rxDataset;
SYRLINKS::TxDataset txDataset;
uint8_t agcValueHighByte;
uint8_t commandBuffer[SYRLINKS::MAX_COMMAND_SIZE];
/**
* This object is used to store the id of the next command to execute. This controls the
* read out of multiple registers which can not be fetched with one single command.
*/
DeviceCommandId_t nextCommand = SYRLINKS::READ_RX_STATUS_REGISTERS;
/**
* @brief This function converts an uint16_t into its hexadecimal string representation.
*
* @param intValue The value to convert.
*
* @return An std::string object containing the hex representation of intValue.
*/
std::string convertUint16ToHexString(uint16_t intValue);
/**
* @brief This function converts a hex number represented by to chars to an 8-bit integer.
*
* @param twoChars Pointer to the two characters representing the hex value.
*
* @details E.g. when twoChars points to an array with the two characters "A5" then the function
* will return 0xA5.
* @return The converted integer.
*/
uint8_t convertHexStringToUint8(const char* twoChars);
/**
* @brief This function converts a hex number represented by 4 chars to an uint16_t.
*
* @param Pointer to the fourCharacters representing the 16-bit integer.
*
* @return The uint16_t result.
*/
uint16_t convertHexStringToUint16(const char* fourChars);
/**
* @brief Function converts a hex number represented by 6 or 8 characters to an uint32_t.
*
* @param characters Pointer to the hex characters array.
* @param numberOfChars Number of characters representing the hex value. Must be 6 or 8.
*
* @return The uint32_t value.
*/
uint32_t convertHexStringToUint32(const char* characters, uint8_t numberOfChars);
/**
* @brief This function parses the status reply
* @param status Pointer to the status information.
*
* @details Some commands reply with a status message giving information about the preceding
* command transmission and/or execution was successful.
*/
ReturnValue_t parseReplyStatus(const char* status);
/**
* @brief Function verifies the received reply from the syrlinks by recalculating and
* comparing the crc.
*
* @param packet Pointer to the received reply.
* @param size Size of the whole packet including the crc and the packet termination
* character '>'.
*
* @return RETURN_OK if successful, otherwise RETURN_FAILED.
*/
ReturnValue_t verifyReply(const uint8_t* packet, uint8_t size);
/**
* @brief This function extracts the data from a rx status registers reply and writes the
* information to the status registers dataset.
* @param packet Pointer to the reply packet.
*/
void parseRxStatusRegistersReply(const uint8_t* packet);
/**
* @brief This function writes the read tx status register to the txStatusDataset.
* @param packet Pointer to the received packet.
*/
void parseTxStatusReply(const uint8_t* packet);
/**
* @brief This function writes the received waveform configuration to the txDataset.
*/
void parseTxWaveformReply(const uint8_t* packet);
/**
* @brief The agc value is split over two registers. The parse agc functions are used to get
* the values from the received reply and write them into the txDataset.
*/
void parseAgcLowByte(const uint8_t* packet);
void parseAgcHighByte(const uint8_t* packet);
};
#endif /* MISSION_DEVICES_SYRLINKSHKHANDLER_H_ */

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@ -0,0 +1,127 @@
#ifndef MISSION_DEVICES_DEVICEDEFINITIONS_IMTQDEFINITIONS_H_
#define MISSION_DEVICES_DEVICEDEFINITIONS_IMTQDEFINITIONS_H_
namespace IMTQ {
static const DeviceCommandId_t NONE = 0x0;
static const DeviceCommandId_t GET_ENG_HK_DATA = 0x1;
static const DeviceCommandId_t START_ACTUATION_DIPOLE = 0x2;
static const uint8_t GET_TEMP_REPLY_SIZE = 2;
static const uint8_t CFGR_CMD_SIZE = 3;
static const uint8_t POINTER_REG_SIZE = 1;
static const uint32_t ENG_HK_DATA_SET_ID = GET_ENG_HK_DATA;
static const uint8_t SIZE_ENG_HK_COMMAND = 1;
static const uint8_t SIZE_ENG_HK_DATA_REPLY = 24;
static const uint8_t MAX_REPLY_SIZE = SIZE_ENG_HK_DATA_REPLY;
static const uint8_t MAX_COMMAND_SIZE = 9;
static const uint8_t POOL_ENTRIES = 11;
/**
* Command code definitions. Each command or reply of an IMTQ request will begin with one of
* the following command codes.
*/
namespace CC {
static const uint8_t START_ACTUATION_DIPOLE = 0x6;
static const uint8_t SOFTWARE_RESET = 0xAA;
static const uint8_t GET_ENG_HK_DATA = 0x4A;
};
enum IMTQPoolIds: lp_id_t {
DIGITAL_VOLTAGE_MV,
ANALOG_VOLTAGE_MV,
DIGITAL_CURRENT_A,
ANALOG_CURRENT_A,
COIL_X_CURRENT_A,
COIL_Y_CURRENT_A,
COIL_Z_CURRENT_A,
COIL_X_TEMPERATURE,
COIL_Y_TEMPERATURE,
COIL_Z_TEMPERATURE,
MCU_TEMPERATURE
};
class EngHkDataset:
public StaticLocalDataSet<POOL_ENTRIES> {
public:
EngHkDataset(HasLocalDataPoolIF* owner):
StaticLocalDataSet(owner, ENG_HK_DATA_SET_ID) {
}
EngHkDataset(object_id_t objectId):
StaticLocalDataSet(sid_t(objectId, ENG_HK_DATA_SET_ID)) {
}
lp_var_t<uint16_t> digitalVoltageMv = lp_var_t<uint16_t>(sid.objectId,
DIGITAL_VOLTAGE_MV, this);
lp_var_t<uint16_t> analogVoltageMv = lp_var_t<uint16_t>(sid.objectId,
ANALOG_VOLTAGE_MV, this);
lp_var_t<float> digitalCurrentA = lp_var_t<float>(sid.objectId,
DIGITAL_CURRENT_A, this);
lp_var_t<float> analogCurrentA = lp_var_t<float>(sid.objectId,
ANALOG_CURRENT_A, this);
lp_var_t<float> coilXcurrentA = lp_var_t<float>(sid.objectId,
COIL_X_CURRENT_A, this);
lp_var_t<float> coilYcurrentA = lp_var_t<float>(sid.objectId,
COIL_Y_CURRENT_A, this);
lp_var_t<float> coilZcurrentA = lp_var_t<float>(sid.objectId,
COIL_Z_CURRENT_A, this);
/** All temperatures in [°C] */
lp_var_t<uint16_t> coilXTemperature = lp_var_t<uint16_t>(sid.objectId,
COIL_X_TEMPERATURE, this);
lp_var_t<uint16_t> coilYTemperature = lp_var_t<uint16_t>(sid.objectId,
COIL_Y_TEMPERATURE, this);
lp_var_t<uint16_t> coilZTemperature = lp_var_t<uint16_t>(sid.objectId,
COIL_Z_TEMPERATURE, this);
lp_var_t<uint16_t> mcuTemperature = lp_var_t<uint16_t>(sid.objectId,
MCU_TEMPERATURE, this);
};
/**
* @brief This class can be used to ease the generation of an action message commanding the
* IMTQHandler to configure the magnettorquer with the desired dipoles.
*
* @details Deserialize the packet, write the deserialized data to the ipc store and store the
* the ipc store address in the action message.
*/
class CommandDipolePacket : public SerialLinkedListAdapter<SerializeIF> {
public:
CommandDipolePacket() {
setLinks();
}
private:
/**
* @brief Constructor
*
* @param xDipole The dipole of the x coil in 10^-4*Am^2
* @param yDipole The dipole of the y coil in 10^-4*Am^2
* @param zDipole The dipole of the z coil in 10^-4*Am^2
* @param duration The duration in milliseconds the dipole will be generated by the coils.
* When set to 0, the dipole will be generated until a new dipole actuation
* command is sent.
*/
CommandDipolePacket(uint16_t xDipole, uint16_t yDipole, uint16_t zDipole, uint16_t duration) :
xDipole(xDipole), yDipole(yDipole), zDipole(zDipole), duration(duration) {
}
void setLinks() {
setStart(&xDipole);
xDipole.setNext(&yDipole);
yDipole.setNext(&zDipole);
zDipole.setNext(&duration);
}
SerializeElement<uint16_t> xDipole;
SerializeElement<uint16_t> yDipole;
SerializeElement<uint16_t> zDipole;
SerializeElement<uint16_t> duration;
};
}
#endif /* MISSION_DEVICES_DEVICEDEFINITIONS_IMTQDEFINITIONS_H_ */

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@ -0,0 +1,54 @@
#ifndef MISSION_DEVICES_DEVICEPACKETS_THERMALSENSORPACKET_H_
#define MISSION_DEVICES_DEVICEPACKETS_THERMALSENSORPACKET_H_
#include <fsfw/datapoollocal/StaticLocalDataSet.h>
#include <fsfw/datapoollocal/LocalPoolVariable.h>
#include <fsfw/devicehandlers/DeviceHandlerIF.h>
#include <fsfwconfig/objects/systemObjectList.h>
namespace Max31865Definitions {
enum PoolIds: lp_id_t {
TEMPERATURE_C,
FAULT_BYTE
};
static constexpr DeviceCommandId_t CONFIG_CMD = 0x80;
static constexpr DeviceCommandId_t REQUEST_CONFIG = 0x00;
static constexpr DeviceCommandId_t REQUEST_RTD = 0x01;
static constexpr DeviceCommandId_t REQUEST_FAULT_BYTE = 0x07;
static constexpr uint32_t MAX31865_SET_ID = REQUEST_RTD;
static constexpr size_t MAX_REPLY_SIZE = 5;
class Max31865Set:
public StaticLocalDataSet<sizeof(float) + sizeof(uint8_t)> {
public:
/**
* Constructor used by owner and data creators like device handlers.
* @param owner
* @param setId
*/
Max31865Set(HasLocalDataPoolIF* owner):
StaticLocalDataSet(owner, MAX31865_SET_ID) {
}
/**
* Constructor used by data users like controllers.
* @param sid
*/
Max31865Set(object_id_t objectId):
StaticLocalDataSet(sid_t(objectId, MAX31865_SET_ID)) {
}
lp_var_t<float> temperatureCelcius = lp_var_t<float>(sid.objectId,
PoolIds::TEMPERATURE_C, this);
lp_var_t<uint8_t> errorByte = lp_var_t<uint8_t>(sid.objectId,
PoolIds::FAULT_BYTE, this);
};
}
#endif /* MISSION_DEVICES_DEVICEPACKETS_THERMALSENSORPACKET_H_ */

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@ -0,0 +1,101 @@
#ifndef MISSION_DEVICES_DEVICEDEFINITIONS_SYRLINKSDEFINITIONS_H_
#define MISSION_DEVICES_DEVICEDEFINITIONS_SYRLINKSDEFINITIONS_H_
namespace SYRLINKS {
static const DeviceCommandId_t NONE = 0x0;
static const DeviceCommandId_t RESET_UNIT = 0x01;
/** Reads out all status registers */
static const DeviceCommandId_t READ_RX_STATUS_REGISTERS = 0x02;
/** Sets Tx mode to standby */
static const DeviceCommandId_t SET_TX_MODE_STANDBY = 0x03;
/** Starts transmission mode. Only reached when clock signal is applying to the data tx input */
static const DeviceCommandId_t SET_TX_MODE_MODULATION = 0x04;
/** Sends out a single carrier wave for testing purpose */
static const DeviceCommandId_t SET_TX_MODE_CW = 0x05;
static const DeviceCommandId_t ACK_REPLY = 0x06;
static const DeviceCommandId_t READ_TX_STATUS = 0x07;
static const DeviceCommandId_t READ_TX_WAVEFORM = 0x08;
static const DeviceCommandId_t READ_TX_AGC_VALUE_HIGH_BYTE = 0x09;
static const DeviceCommandId_t READ_TX_AGC_VALUE_LOW_BYTE = 0x0A;
/** Size of a simple transmission success response */
static const uint8_t ACK_SIZE = 11;
static const uint8_t SIZE_CRC_AND_TERMINATION = 5;
/** The size of the header with the message identifier and the payload size field */
static const uint8_t MESSAGE_HEADER_SIZE = 5;
/** Size of reply to an rx status registers request */
static const uint8_t RX_STATUS_REGISTERS_REPLY_SIZE = 49;
static const uint8_t READ_ONE_REGISTER_REPLY_SIE = 13;
static const uint8_t RX_DATASET_ID = 0x1;
static const uint8_t TX_DATASET_ID = 0x2;
static const size_t MAX_REPLY_SIZE = RX_STATUS_REGISTERS_REPLY_SIZE;
static const size_t MAX_COMMAND_SIZE = 15;
static const size_t CRC_FIELD_SIZE = 4;
static const uint8_t RX_DATASET_SIZE = 8;
static const uint8_t TX_DATASET_SIZE = 3;
enum SyrlinksPoolIds: lp_id_t {
RX_STATUS,
RX_SENSITIVITY,
RX_FREQUENCY_SHIFT,
RX_IQ_POWER,
RX_AGC_VALUE,
RX_DEMOD_EB,
RX_DEMOD_N0,
RX_DATA_RATE,
TX_STATUS,
TX_CONV_DIFF,
TX_CONV_FILTER,
TX_WAVEFORM,
TX_PCM_INDEX,
TX_AGC_VALUE,
};
class RxDataset: public StaticLocalDataSet<RX_DATASET_SIZE> {
public:
RxDataset(HasLocalDataPoolIF* owner) :
StaticLocalDataSet(owner, RX_DATASET_ID) {
}
RxDataset(object_id_t objectId) :
StaticLocalDataSet(sid_t(objectId, RX_DATASET_ID)) {
}
lp_var_t<uint8_t> rxStatus = lp_var_t<uint8_t>(sid.objectId, RX_STATUS, this);
lp_var_t<uint32_t> rxSensitivity = lp_var_t<uint32_t>(sid.objectId, RX_SENSITIVITY, this);
lp_var_t<uint32_t> rxFrequencyShift = lp_var_t<uint32_t>(sid.objectId, RX_FREQUENCY_SHIFT, this);
lp_var_t<uint16_t> rxIqPower = lp_var_t<uint16_t>(sid.objectId, RX_IQ_POWER, this);
lp_var_t<uint16_t> rxAgcValue = lp_var_t<uint16_t>(sid.objectId, RX_AGC_VALUE, this);
lp_var_t<uint32_t> rxDemodEb = lp_var_t<uint32_t>(sid.objectId, RX_DEMOD_EB, this);
lp_var_t<uint32_t> rxDemodN0 = lp_var_t<uint32_t>(sid.objectId, RX_DEMOD_N0, this);
lp_var_t<uint8_t> rxDataRate = lp_var_t<uint8_t>(sid.objectId, RX_DATA_RATE, this);
};
class TxDataset: public StaticLocalDataSet<TX_DATASET_SIZE> {
public:
TxDataset(HasLocalDataPoolIF* owner) :
StaticLocalDataSet(owner, TX_DATASET_ID) {
}
TxDataset(object_id_t objectId) :
StaticLocalDataSet(sid_t(objectId, TX_DATASET_ID)) {
}
lp_var_t<uint8_t> txStatus = lp_var_t<uint8_t>(sid.objectId, TX_STATUS, this);
lp_var_t<uint8_t> txWaveform = lp_var_t<uint8_t>(sid.objectId, TX_WAVEFORM, this);
lp_var_t<uint16_t> txAgcValue = lp_var_t<uint16_t>(sid.objectId, TX_AGC_VALUE, this);
};
}
#endif /* MISSION_DEVICES_DEVICEDEFINITIONS_SYRLINKSDEFINITIONS_H_ */

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@ -1,7 +1,7 @@
#include <fsfw/ipc/QueueFactory.h>
#include <fsfw/tmtcpacket/pus/TmPacketBase.h>
#include <fsfw/tmtcpacket/pus/TmPacketStored.h>
#include <fsfw/serviceinterface/ServiceInterfaceStream.h>
#include <fsfw/tmtcpacket/pus/TmPacketPusC.h>
#include <mission/utility/TmFunnel.h>
object_id_t TmFunnel::downlinkDestination = objects::NO_OBJECT;
@ -50,7 +50,7 @@ ReturnValue_t TmFunnel::handlePacket(TmTcMessage* message) {
if(result != HasReturnvaluesIF::RETURN_OK){
return result;
}
TmPacketBase packet(packetData);
TmPacketPusC packet(packetData);
packet.setPacketSequenceCount(this->sourceSequenceCount);
sourceSequenceCount++;
sourceSequenceCount = sourceSequenceCount %

View File

@ -66,6 +66,14 @@ gps_rx_data[] = ""
"$GPRMC,183731,A,3907.482,N,12102.436,W,000.0,360.0,080301,015.5,E*67\r\n"
"$GPRMB,A,,,,,,,,,,,,V*71\r\n";
const char hyperion_gps_data[] = ""
"$GNGGA,173225.998892,4908.5596,N,00906.2765,E,1,05,2.1,215.0,M,48.2,M,,0000*74\r\n"
"$GNGLL,4908.5596,N,00906.2765,E,173225.998892,A,A*7F\r\n"
"$GPGSA,A,3,18,16,26,31,20,,,,,,,,3.2,2.1,2.4*3C\r\n"
"$GNRMC,173225.998892,A,4908.5596,N,00906.2765,E,000.0,040.7,270221,,,A*4F\r\n"
"$GNVTG,040.7,T,,M,000.0,N,000.0,K,A*10\r\n"
"$GNZDA,173225.998892,27,02,2021,00,00*75\r\n";
ReturnValue_t TestTask::performOneShotAction() {
#if OBSW_ADD_TEST_CODE == 1
//performLwgpsTest();
@ -93,18 +101,18 @@ ReturnValue_t TestTask::performActionB() {
void TestTask::performLwgpsTest() {
/* Everything here will only be performed once. */
etl::vector<uint8_t, 30> testVec;
sif::info << "Processing sample GPS output.." << std::endl;
lwgps_t gpsStruct;
sif::info << "Size of GPS struct: " << sizeof(gpsStruct) << std::endl;
lwgps_init(&gpsStruct);
/* Process all input data */
lwgps_process(&gpsStruct, gps_rx_data, strlen(gps_rx_data));
lwgps_process(&gpsStruct, hyperion_gps_data, strlen(hyperion_gps_data));
/* Print messages */
printf("Valid status: %d\r\n", gpsStruct.is_valid);
printf("Latitude: %f degrees\r\n", gpsStruct.latitude);
printf("Longitude: %f degrees\r\n", gpsStruct.longitude);
printf("Altitude: %f meters\r\n", gpsStruct.altitude);
printf("Valid status: %d\n", gpsStruct.is_valid);
printf("Latitude: %f degrees\n", gpsStruct.latitude);
printf("Longitude: %f degrees\n", gpsStruct.longitude);
printf("Altitude: %f meters\n", gpsStruct.altitude);
}

2
tmtc

@ -1 +1 @@
Subproject commit 5f1803b66393210ded8c5d88fbc28cd8130cef91
Subproject commit 7cc06ef0e0882d286bab8156ca756e0211e5ebae