Two-Wire Automotive Interface (TWAI)
Overview
The Two-Wire Automotive Interface (TWAI) is a real-time serial communication protocol suited for automotive and industrial applications. It is compatible with ISO11898-1 Classical frames, thus can support Standard Frame Format (11-bit ID) and Extended Frame Format (29-bit ID). The ESP32’s peripherals contains a TWAI controller that can be configured to communicate on a TWAI bus via an external transceiver.
Warning
The TWAI controller is not compatible with ISO11898-1 FD Format frames, and will interpret such frames as errors.
This programming guide is split into the following sections:
TWAI Protocol Summary
The TWAI is a multi-master, multi-cast, asynchronous, serial communication protocol. TWAI also supports error detection and signalling, and inbuilt message prioritization.
Multi-master: Any node on the bus can initiate the transfer of a message.
Multi-cast: When a node transmits a message, all nodes on the bus will receive the message (i.e., broadcast) thus ensuring data consistency across all nodes. However, some nodes can selectively choose which messages to accept via the use of acceptance filtering (multi-cast).
Asynchronous: The bus does not contain a clock signal. All nodes on the bus operate at the same bit rate and synchronize using the edges of the bits transmitted on the bus.
Error Detection and Signalling: Every node will constantly monitor the bus. When any node detects an error, it will signal the detection by transmitting an error frame. Other nodes will receive the error frame and transmit their own error frames in response. This will result in an error detection being propagated to all nodes on the bus.
Message Priorities: Messages contain an ID field. If two or more nodes attempt to transmit simultaneously, the node transmitting the message with the lower ID value will win arbitration of the bus. All other nodes will become receivers ensuring that there is at most one transmitter at any time.
TWAI Messages
TWAI Messages are split into Data Frames and Remote Frames. Data Frames are used to deliver a data payload to other nodes, whereas a Remote Frame is used to request a Data Frame from other nodes (other nodes can optionally respond with a Data Frame). Data and Remote Frames have two frame formats known as Extended Frame and Standard Frame which contain a 29-bit ID and an 11-bit ID respectively. A TWAI message consists of the following fields:
29-bit or 11-bit ID: Determines the priority of the message (lower value has higher priority).
Data Length Code (DLC) between 0 to 8: Indicates the size (in bytes) of the data payload for a Data Frame, or the amount of data to request for a Remote Frame.
Up to 8 bytes of data for a Data Frame (should match DLC).
Error States and Counters
The TWAI protocol implements a feature known as “fault confinement” where a persistently erroneous node will eventually eliminate itself form the bus. This is implemented by requiring every node to maintain two internal error counters known as the Transmit Error Counter (TEC) and the Receive Error Counter (REC). The two error counters are incremented and decremented according to a set of rules (where the counters increase on an error, and decrease on a successful message transmission/reception). The values of the counters are used to determine a node’s error state, namely Error Active, Error Passive, and Bus-Off.
Error Active: A node is Error Active when both TEC and REC are less than 128 and indicates that the node is operating normally. Error Active nodes are allowed to participate in bus communications, and will actively signal the detection of any errors by automatically transmitting an Active Error Flag over the bus.
Error Passive: A node is Error Passive when either the TEC or REC becomes greater than or equal to 128. Error Passive nodes are still able to take part in bus communications, but will instead transmit a Passive Error Flag upon detection of an error.
Bus-Off: A node becomes Bus-Off when the TEC becomes greater than or equal to 256. A Bus-Off node is unable influence the bus in any manner (essentially disconnected from the bus) thus eliminating itself from the bus. A node will remain in the Bus-Off state until it undergoes bus-off recovery.
Signals Lines and Transceiver
The TWAI controller does not contain a integrated transceiver. Therefore, to connect the TWAI controller to a TWAI bus, an external transceiver is required. The type of external transceiver used should depend on the application’s physical layer specification (e.g. using SN65HVD23x transceivers for ISO 11898-2 compatibility).
The TWAI controller’s interface consists of 4 signal lines known as TX, RX, BUS-OFF, and CLKOUT. These four signal lines can be routed through the GPIO Matrix to the ESP32’s GPIO pads.
TX and RX: The TX and RX signal lines are required to interface with an external transceiver. Both signal lines represent/interpret a dominant bit as a low logic level (0V), and a recessive bit as a high logic level (3.3V).
BUS-OFF: The BUS-OFF signal line is optional and is set to a low logic level (0V) whenever the TWAI controller reaches a bus-off state. The BUS-OFF signal line is set to a high logic level (3.3V) otherwise.
CLKOUT: The CLKOUT signal line is optional and outputs a prescaled version of the controller’s source clock (APB Clock).
Note
An external transceiver must internally loopback the TX to RX such that a change in logic level to the TX signal line can be observed on the RX line. Failing to do so will cause the TWAI controller to interpret differences in logic levels between the two signal lines as a loss in arbitration or a bit error.
Driver Configuration
This section covers how to configure the TWAI driver.
Operating Modes
The TWAI driver supports the following modes of operations:
Normal Mode: The normal operating mode allows the TWAI controller to take part in bus activities such as transmitting and receiving messages/error frames. Acknowledgement from another node is required when transmitting a message.
No Ack Mode: The No Acknowledgement mode is similar to normal mode, however acknowledgements are not required for a message transmission to be considered successful. This mode is useful when self testing the TWAI controller (loopback of transmissions).
Listen Only Mode: This mode will prevent the TWAI controller from influencing the bus. Therefore, transmission of messages/acknowledgement/error frames will be disabled. However the TWAI controller will still be able to receive messages but will not acknowledge the message. This mode is suited for bus monitor applications.
Alerts
The TWAI driver contains an alert feature that is used to notify the application layer of certain TWAI controller or TWAI bus events. Alerts are selectively enabled when the TWAI driver is installed, but can be reconfigured during runtime by calling twai_reconfigure_alerts()
. The application can then wait for any enabled alerts to occur by calling twai_read_alerts()
. The TWAI driver supports the following alerts:
Alert Flag |
Description |
---|---|
|
No more messages queued for transmission |
|
The previous transmission was successful |
|
A frame has been received and added to the RX queue |
|
Both error counters have dropped below error warning limit |
|
TWAI controller has become error active |
|
TWAI controller is undergoing bus recovery |
|
TWAI controller has successfully completed bus recovery |
|
The previous transmission lost arbitration |
|
One of the error counters have exceeded the error warning limit |
|
A (Bit, Stuff, CRC, Form, ACK) error has occurred on the bus |
|
The previous transmission has failed |
|
The RX queue is full causing a received frame to be lost |
|
TWAI controller has become error passive |
|
Bus-off condition occurred. TWAI controller can no longer influence bus |
Note
The TWAI controller’s error warning limit is used to preemptively warn the application of bus errors before the error passive state is reached. By default, the TWAI driver sets the error warning limit to 96. The TWAI_ALERT_ABOVE_ERR_WARN
is raised when the TEC or REC becomes larger then or equal to the error warning limit. The TWAI_ALERT_BELOW_ERR_WARN
is raised when both TEC and REC return back to values below 96.
Note
When enabling alerts, the TWAI_ALERT_AND_LOG
flag can be used to cause the TWAI driver to log any raised alerts to UART. However, alert logging is disabled and TWAI_ALERT_AND_LOG
if the CONFIG_TWAI_ISR_IN_IRAM option is enabled (see Placing ISR into IRAM).
Note
The TWAI_ALERT_ALL
and TWAI_ALERT_NONE
macros can also be used to enable/disable all alerts during configuration/reconfiguration.
Bit Timing
The operating bit rate of the TWAI driver is configured using the twai_timing_config_t
structure. The period of each bit is made up of multiple time quanta, and the period of a time quantum is determined by a prescaled version of the TWAI controller’s source clock. A single bit contains the following segments in the following order:
The Synchronization Segment consists of a single time quantum
Timing Segment 1 consists of 1 to 16 time quanta before sample point
Timing Segment 2 consists of 1 to 8 time quanta after sample point
The Baudrate Prescaler is used to determine the period of each time quantum by dividing the TWAI controller’s source clock (80 MHz APB clock). On the ESP32, the brp
can be any even number from 2 to 128.
If the ESP32 is a revision 2 or later chip, the brp
will also support any multiple of 4 from 132 to 256, and can be enabled by setting the CONFIG_ESP32_REV_MIN to revision 2 or higher.
The sample point of a bit is located on the intersection of Timing Segment 1 and 2. Enabling Triple Sampling will cause 3 time quanta to be sampled per bit instead of 1 (extra samples are located at the tail end of Timing Segment 1).
The Synchronization Jump Width is used to determine the maximum number of time quanta a single bit time can be lengthened/shortened for synchronization purposes. sjw
can range from 1 to 4.
Note
Multiple combinations of brp
, tseg_1
, tseg_2
, and sjw
can achieve the same bit rate. Users should tune these values to the physical characteristics of their bus by taking into account factors such as propagation delay, node information processing time, and phase errors.
Bit timing macro initializers are also available for commonly used bit rates. The following macro initializers are provided by the TWAI driver.
TWAI_TIMING_CONFIG_1MBITS()
TWAI_TIMING_CONFIG_800KBITS()
TWAI_TIMING_CONFIG_500KBITS()
TWAI_TIMING_CONFIG_250KBITS()
TWAI_TIMING_CONFIG_125KBITS()
TWAI_TIMING_CONFIG_100KBITS()
TWAI_TIMING_CONFIG_50KBITS()
TWAI_TIMING_CONFIG_25KBITS()
Revision 2 or later of the ESP32 also supports the following bit rates:
TWAI_TIMING_CONFIG_20KBITS()
TWAI_TIMING_CONFIG_16KBITS()
TWAI_TIMING_CONFIG_12_5KBITS()
Acceptance Filter
The TWAI controller contains a hardware acceptance filter which can be used to filter messages of a particular ID. A node that filters out a message will not receive the message, but will still acknowledge it. Acceptance filters can make a node more efficient by filtering out messages sent over the bus that are irrelevant to the node. The acceptance filter is configured using two 32-bit values within twai_filter_config_t
known as the acceptance code and the acceptance mask.
The acceptance code specifies the bit sequence which a message’s ID, RTR, and data bytes must match in order for the message to be received by the TWAI controller. The acceptance mask is a bit sequence specifying which bits of the acceptance code can be ignored. This allows for a messages of different IDs to be accepted by a single acceptance code.
The acceptance filter can be used under Single or Dual Filter Mode. Single Filter Mode will use the acceptance code and mask to define a single filter. This allows for the first two data bytes of a standard frame to be filtered, or the entirety of an extended frame’s 29-bit ID. The following diagram illustrates how the 32-bit acceptance code and mask will be interpreted under Single Filter Mode (Note: The yellow and blue fields represent standard and extended frame formats respectively).
Dual Filter Mode will use the acceptance code and mask to define two separate filters allowing for increased flexibility of ID’s to accept, but does not allow for all 29-bits of an extended ID to be filtered. The following diagram illustrates how the 32-bit acceptance code and mask will be interpreted under Dual Filter Mode (Note: The yellow and blue fields represent standard and extended frame formats respectively).
Disabling TX Queue
The TX queue can be disabled during configuration by setting the tx_queue_len
member of twai_general_config_t
to 0
. This will allow applications that do not require message transmission to save a small amount of memory when using the TWAI driver.
Placing ISR into IRAM
The TWAI driver’s ISR (Interrupt Service Routine) can be placed into IRAM so that the ISR can still run whilst the cache is disabled. Placing the ISR into IRAM may be necessary to maintain the TWAI driver’s functionality during lengthy cache disabling operations (such as SPI Flash writes, OTA updates etc). Whilst the cache is disabled, the ISR will continue to:
Read received messages from the RX buffer and place them into the driver’s RX queue.
Load messages pending transmission from the driver’s TX queue and write them into the TX buffer.
To place the TWAI driver’s ISR, users must do the following:
Enable the CONFIG_TWAI_ISR_IN_IRAM option using
idf.py menuconfig
.When calling
twai_driver_install()
, the intr_flags member oftwai_general_config_t
should set theESP_INTR_FLAG_IRAM
set.
Note
When the CONFIG_TWAI_ISR_IN_IRAM option is enabled, the TWAI driver will no longer log any alerts (i.e., the TWAI_ALERT_AND_LOG
flag will not have any effect).
ESP32 Errata Workarounds
The ESP32’s TWAI controller contains multiple hardware errata (more details about the errata can be found in the ESP32’s ECO document). Some of these errata are critical, and under specific circumstances, can place the TWAI controller into an unrecoverable state (i.e., the controller gets stuck until it is reset by the CPU).
The TWAI driver contains software workarounds for these critical errata. With these workarounds, the ESP32 TWAI driver can operate normally, albeit with degraded performance. The degraded performance will affect users in the following ways depending on what particular errata conditions are encountered:
The TWAI driver can occasionally drop some received messages.
The TWAI driver can be unresponsive for a short period of time (i.e., will not transmit or ACK for 11 bit times or longer).
If CONFIG_TWAI_ISR_IN_IRAM is enabled, the workarounds will increase IRAM usage by approximately 1KB.
The software workarounds are enabled by default and it is recommended that users keep this workarounds enabled.
Driver Operation
The TWAI driver is designed with distinct states and strict rules regarding the functions or conditions that trigger a state transition. The following diagram illustrates the various states and their transitions.
Label |
Transition |
Action/Condition |
---|---|---|
A |
Uninstalled -> Stopped |
|
B |
Stopped -> Uninstalled |
|
C |
Stopped -> Running |
|
D |
Running -> Stopped |
|
E |
Running -> Bus-Off |
Transmit Error Counter >= 256 |
F |
Bus-Off -> Uninstalled |
|
G |
Bus-Off -> Recovering |
|
H |
Recovering -> Stopped |
128 occurrences of 11 consecutive recessive bits. |
Driver States
Uninstalled: In the uninstalled state, no memory is allocated for the driver and the TWAI controller is powered OFF.
Stopped: In this state, the TWAI controller is powered ON and the TWAI driver has been installed. However the TWAI controller will be unable to take part in any bus activities such as transmitting, receiving, or acknowledging messages.
Running: In the running state, the TWAI controller is able to take part in bus activities. Therefore messages can be transmitted/received/acknowledged. Furthermore the TWAI controller will be able to transmit error frames upon detection of errors on the bus.
Bus-Off: The bus-off state is automatically entered when the TWAI controller’s Transmit Error Counter becomes greater than or equal to 256. The bus-off state indicates the occurrence of severe errors on the bus or in the TWAI controller. Whilst in the bus-off state, the TWAI controller will be unable to take part in any bus activities. To exit the bus-off state, the TWAI controller must undergo the bus recovery process.
Recovering: The recovering state is entered when the TWAI controller undergoes bus recovery. The TWAI controller/TWAI driver will remain in the recovering state until the 128 occurrences of 11 consecutive recessive bits is observed on the bus.
Message Fields and Flags
The TWAI driver distinguishes different types of messages by using the various bit field members of the twai_message_t
structure. These bit field members determine whether a message is in standard or extended format, a remote frame, and the type of transmission to use when transmitting such a message.
These bit field members can also be toggled using the the flags member of twai_message_t
and the following message flags:
Message Flag |
Description |
---|---|
|
Message is in Extended Frame Format (29bit ID) |
|
Message is a Remote Frame (Remote Transmission Request) |
|
Transmit message using Single Shot Transmission (Message will not be retransmitted upon error or loss of arbitration). Unused for received message. |
|
Transmit message using Self Reception Request (Transmitted message will also received by the same node). Unused for received message. |
|
Message’s Data length code is larger than 8. This will break compliance with TWAI |
|
Clears all bit fields. Equivalent to a Standard Frame Format (11bit ID) Data Frame. |
Examples
Configuration & Installation
The following code snippet demonstrates how to configure, install, and start the TWAI driver via the use of the various configuration structures, macro initializers, the twai_driver_install()
function, and the twai_start()
function.
#include "driver/gpio.h"
#include "driver/twai.h"
void app_main()
{
//Initialize configuration structures using macro initializers
twai_general_config_t g_config = TWAI_GENERAL_CONFIG_DEFAULT(GPIO_NUM_21, GPIO_NUM_22, TWAI_MODE_NORMAL);
twai_timing_config_t t_config = TWAI_TIMING_CONFIG_500KBITS();
twai_filter_config_t f_config = TWAI_FILTER_CONFIG_ACCEPT_ALL();
//Install TWAI driver
if (twai_driver_install(&g_config, &t_config, &f_config) == ESP_OK) {
printf("Driver installed\n");
} else {
printf("Failed to install driver\n");
return;
}
//Start TWAI driver
if (twai_start() == ESP_OK) {
printf("Driver started\n");
} else {
printf("Failed to start driver\n");
return;
}
...
}
The usage of macro initializers is not mandatory and each of the configuration structures can be manually.
Message Transmission
The following code snippet demonstrates how to transmit a message via the usage of the twai_message_t
type and twai_transmit()
function.
#include "driver/twai.h"
...
//Configure message to transmit
twai_message_t message;
message.identifier = 0xAAAA;
message.extd = 1;
message.data_length_code = 4;
for (int i = 0; i < 4; i++) {
message.data[i] = 0;
}
//Queue message for transmission
if (twai_transmit(&message, pdMS_TO_TICKS(1000)) == ESP_OK) {
printf("Message queued for transmission\n");
} else {
printf("Failed to queue message for transmission\n");
}
Message Reception
The following code snippet demonstrates how to receive a message via the usage of the twai_message_t
type and twai_receive()
function.
#include "driver/twai.h"
...
//Wait for message to be received
twai_message_t message;
if (twai_receive(&message, pdMS_TO_TICKS(10000)) == ESP_OK) {
printf("Message received\n");
} else {
printf("Failed to receive message\n");
return;
}
//Process received message
if (message.extd) {
printf("Message is in Extended Format\n");
} else {
printf("Message is in Standard Format\n");
}
printf("ID is %d\n", message.identifier);
if (!(message.rtr)) {
for (int i = 0; i < message.data_length_code; i++) {
printf("Data byte %d = %d\n", i, message.data[i]);
}
}
Reconfiguring and Reading Alerts
The following code snippet demonstrates how to reconfigure and read TWAI driver alerts via the use of the twai_reconfigure_alerts()
and twai_read_alerts()
functions.
#include "driver/twai.h"
...
//Reconfigure alerts to detect Error Passive and Bus-Off error states
uint32_t alerts_to_enable = TWAI_ALERT_ERR_PASS | TWAI_ALERT_BUS_OFF;
if (twai_reconfigure_alerts(alerts_to_enable, NULL) == ESP_OK) {
printf("Alerts reconfigured\n");
} else {
printf("Failed to reconfigure alerts");
}
//Block indefinitely until an alert occurs
uint32_t alerts_triggered;
twai_read_alerts(&alerts_triggered, portMAX_DELAY);
Stop and Uninstall
The following code demonstrates how to stop and uninstall the TWAI driver via the use of the twai_stop()
and twai_driver_uninstall()
functions.
#include "driver/twai.h"
...
//Stop the TWAI driver
if (twai_stop() == ESP_OK) {
printf("Driver stopped\n");
} else {
printf("Failed to stop driver\n");
return;
}
//Uninstall the TWAI driver
if (twai_driver_uninstall() == ESP_OK) {
printf("Driver uninstalled\n");
} else {
printf("Failed to uninstall driver\n");
return;
}
Multiple ID Filter Configuration
The acceptance mask in twai_filter_config_t
can be configured such that two or more IDs will be accepted for a single filter. For a particular filter to accept multiple IDs, the conflicting bit positions amongst the IDs must be set in the acceptance mask. The acceptance code can be set to any one of the IDs.
The following example shows how the calculate the acceptance mask given multiple IDs:
ID1 = 11'b101 1010 0000
ID2 = 11'b101 1010 0001
ID3 = 11'b101 1010 0100
ID4 = 11'b101 1010 1000
//Acceptance Mask
MASK = 11'b000 0000 1101
Application Examples
Network Example: The TWAI Network example demonstrates communication between two ESP32s using the TWAI driver API. One TWAI node acts as a network master that initiates and ceases the transfer of a data from another node acting as a network slave. The example can be found via peripherals/twai/twai_network.
Alert and Recovery Example: This example demonstrates how to use the TWAI driver’s alert and bus-off recovery API. The example purposely introduces errors on the bus to put the TWAI controller into the Bus-Off state. An alert is used to detect the Bus-Off state and trigger the bus recovery process. The example can be found via peripherals/twai/twai_alert_and_recovery.
Self Test Example: This example uses the No Acknowledge Mode and Self Reception Request to cause the TWAI controller to send and simultaneously receive a series of messages. This example can be used to verify if the connections between the TWAI controller and the external transceiver are working correctly. The example can be found via peripherals/twai/twai_self_test.
API Reference
Header File
Structures
-
struct twai_message_t
Structure to store a TWAI message.
Note
The flags member is deprecated
Public Members
-
uint32_t extd
Extended Frame Format (29bit ID)
-
uint32_t rtr
Message is a Remote Frame
-
uint32_t ss
Transmit as a Single Shot Transmission. Unused for received.
-
uint32_t self
Transmit as a Self Reception Request. Unused for received.
-
uint32_t dlc_non_comp
Message’s Data length code is larger than 8. This will break compliance with ISO 11898-1
-
uint32_t reserved
Reserved bits
-
uint32_t flags
Deprecated: Alternate way to set bits using message flags
-
uint32_t identifier
11 or 29 bit identifier
-
uint8_t data_length_code
Data length code
-
uint8_t data[TWAI_FRAME_MAX_DLC]
Data bytes (not relevant in RTR frame)
-
uint32_t extd
-
struct twai_timing_config_t
Structure for bit timing configuration of the TWAI driver.
Note
Macro initializers are available for this structure
Public Members
-
uint32_t brp
Baudrate prescaler (i.e., APB clock divider). Any even number from 2 to 128 for ESP32, 2 to 32768 for ESP32S2. For ESP32 Rev 2 or later, multiples of 4 from 132 to 256 are also supported
-
uint8_t tseg_1
Timing segment 1 (Number of time quanta, between 1 to 16)
-
uint8_t tseg_2
Timing segment 2 (Number of time quanta, 1 to 8)
-
uint8_t sjw
Synchronization Jump Width (Max time quanta jump for synchronize from 1 to 4)
-
bool triple_sampling
Enables triple sampling when the TWAI controller samples a bit
-
uint32_t brp
-
struct twai_filter_config_t
Structure for acceptance filter configuration of the TWAI driver (see documentation)
Note
Macro initializers are available for this structure
Macros
-
TWAI_EXTD_ID_MASK
TWAI Constants.
Bit mask for 29 bit Extended Frame Format ID
-
TWAI_STD_ID_MASK
Bit mask for 11 bit Standard Frame Format ID
-
TWAI_FRAME_MAX_DLC
Max data bytes allowed in TWAI
-
TWAI_FRAME_EXTD_ID_LEN_BYTES
EFF ID requires 4 bytes (29bit)
-
TWAI_FRAME_STD_ID_LEN_BYTES
SFF ID requires 2 bytes (11bit)
-
TWAI_ERR_PASS_THRESH
Error counter threshold for error passive
Enumerations
-
enum twai_mode_t
TWAI Controller operating modes.
Values:
-
enumerator TWAI_MODE_NORMAL
Normal operating mode where TWAI controller can send/receive/acknowledge messages
-
enumerator TWAI_MODE_NO_ACK
Transmission does not require acknowledgment. Use this mode for self testing
-
enumerator TWAI_MODE_LISTEN_ONLY
The TWAI controller will not influence the bus (No transmissions or acknowledgments) but can receive messages
-
enumerator TWAI_MODE_NORMAL
Header File
Functions
-
esp_err_t twai_driver_install(const twai_general_config_t *g_config, const twai_timing_config_t *t_config, const twai_filter_config_t *f_config)
Install TWAI driver.
This function installs the TWAI driver using three configuration structures. The required memory is allocated and the TWAI driver is placed in the stopped state after running this function.
Note
Macro initializers are available for the configuration structures (see documentation)
Note
To reinstall the TWAI driver, call twai_driver_uninstall() first
- Parameters
g_config – [in] General configuration structure
t_config – [in] Timing configuration structure
f_config – [in] Filter configuration structure
- Returns
ESP_OK: Successfully installed TWAI driver
ESP_ERR_INVALID_ARG: Arguments are invalid
ESP_ERR_NO_MEM: Insufficient memory
ESP_ERR_INVALID_STATE: Driver is already installed
-
esp_err_t twai_driver_uninstall(void)
Uninstall the TWAI driver.
This function uninstalls the TWAI driver, freeing the memory utilized by the driver. This function can only be called when the driver is in the stopped state or the bus-off state.
Warning
The application must ensure that no tasks are blocked on TX/RX queues or alerts when this function is called.
- Returns
ESP_OK: Successfully uninstalled TWAI driver
ESP_ERR_INVALID_STATE: Driver is not in stopped/bus-off state, or is not installed
-
esp_err_t twai_start(void)
Start the TWAI driver.
This function starts the TWAI driver, putting the TWAI driver into the running state. This allows the TWAI driver to participate in TWAI bus activities such as transmitting/receiving messages. The TX and RX queue are reset in this function, clearing any messages that are unread or pending transmission. This function can only be called when the TWAI driver is in the stopped state.
- Returns
ESP_OK: TWAI driver is now running
ESP_ERR_INVALID_STATE: Driver is not in stopped state, or is not installed
-
esp_err_t twai_stop(void)
Stop the TWAI driver.
This function stops the TWAI driver, preventing any further message from being transmitted or received until twai_start() is called. Any messages in the TX queue are cleared. Any messages in the RX queue should be read by the application after this function is called. This function can only be called when the TWAI driver is in the running state.
Warning
A message currently being transmitted/received on the TWAI bus will be ceased immediately. This may lead to other TWAI nodes interpreting the unfinished message as an error.
- Returns
ESP_OK: TWAI driver is now Stopped
ESP_ERR_INVALID_STATE: Driver is not in running state, or is not installed
-
esp_err_t twai_transmit(const twai_message_t *message, TickType_t ticks_to_wait)
Transmit a TWAI message.
This function queues a TWAI message for transmission. Transmission will start immediately if no other messages are queued for transmission. If the TX queue is full, this function will block until more space becomes available or until it times out. If the TX queue is disabled (TX queue length = 0 in configuration), this function will return immediately if another message is undergoing transmission. This function can only be called when the TWAI driver is in the running state and cannot be called under Listen Only Mode.
Note
This function does not guarantee that the transmission is successful. The TX_SUCCESS/TX_FAILED alert can be enabled to alert the application upon the success/failure of a transmission.
Note
The TX_IDLE alert can be used to alert the application when no other messages are awaiting transmission.
- Parameters
message – [in] Message to transmit
ticks_to_wait – [in] Number of FreeRTOS ticks to block on the TX queue
- Returns
ESP_OK: Transmission successfully queued/initiated
ESP_ERR_INVALID_ARG: Arguments are invalid
ESP_ERR_TIMEOUT: Timed out waiting for space on TX queue
ESP_FAIL: TX queue is disabled and another message is currently transmitting
ESP_ERR_INVALID_STATE: TWAI driver is not in running state, or is not installed
ESP_ERR_NOT_SUPPORTED: Listen Only Mode does not support transmissions
-
esp_err_t twai_receive(twai_message_t *message, TickType_t ticks_to_wait)
Receive a TWAI message.
This function receives a message from the RX queue. The flags field of the message structure will indicate the type of message received. This function will block if there are no messages in the RX queue
Warning
The flags field of the received message should be checked to determine if the received message contains any data bytes.
- Parameters
message – [out] Received message
ticks_to_wait – [in] Number of FreeRTOS ticks to block on RX queue
- Returns
ESP_OK: Message successfully received from RX queue
ESP_ERR_TIMEOUT: Timed out waiting for message
ESP_ERR_INVALID_ARG: Arguments are invalid
ESP_ERR_INVALID_STATE: TWAI driver is not installed
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esp_err_t twai_read_alerts(uint32_t *alerts, TickType_t ticks_to_wait)
Read TWAI driver alerts.
This function will read the alerts raised by the TWAI driver. If no alert has been issued when this function is called, this function will block until an alert occurs or until it timeouts.
Note
Multiple alerts can be raised simultaneously. The application should check for all alerts that have been enabled.
- Parameters
alerts – [out] Bit field of raised alerts (see documentation for alert flags)
ticks_to_wait – [in] Number of FreeRTOS ticks to block for alert
- Returns
ESP_OK: Alerts read
ESP_ERR_TIMEOUT: Timed out waiting for alerts
ESP_ERR_INVALID_ARG: Arguments are invalid
ESP_ERR_INVALID_STATE: TWAI driver is not installed
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esp_err_t twai_reconfigure_alerts(uint32_t alerts_enabled, uint32_t *current_alerts)
Reconfigure which alerts are enabled.
This function reconfigures which alerts are enabled. If there are alerts which have not been read whilst reconfiguring, this function can read those alerts.
- Parameters
alerts_enabled – [in] Bit field of alerts to enable (see documentation for alert flags)
current_alerts – [out] Bit field of currently raised alerts. Set to NULL if unused
- Returns
ESP_OK: Alerts reconfigured
ESP_ERR_INVALID_STATE: TWAI driver is not installed
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esp_err_t twai_initiate_recovery(void)
Start the bus recovery process.
This function initiates the bus recovery process when the TWAI driver is in the bus-off state. Once initiated, the TWAI driver will enter the recovering state and wait for 128 occurrences of the bus-free signal on the TWAI bus before returning to the stopped state. This function will reset the TX queue, clearing any messages pending transmission.
Note
The BUS_RECOVERED alert can be enabled to alert the application when the bus recovery process completes.
- Returns
ESP_OK: Bus recovery started
ESP_ERR_INVALID_STATE: TWAI driver is not in the bus-off state, or is not installed
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esp_err_t twai_get_status_info(twai_status_info_t *status_info)
Get current status information of the TWAI driver.
- Parameters
status_info – [out] Status information
- Returns
ESP_OK: Status information retrieved
ESP_ERR_INVALID_ARG: Arguments are invalid
ESP_ERR_INVALID_STATE: TWAI driver is not installed
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esp_err_t twai_clear_transmit_queue(void)
Clear the transmit queue.
This function will clear the transmit queue of all messages.
Note
The transmit queue is automatically cleared when twai_stop() or twai_initiate_recovery() is called.
- Returns
ESP_OK: Transmit queue cleared
ESP_ERR_INVALID_STATE: TWAI driver is not installed or TX queue is disabled
Structures
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struct twai_general_config_t
Structure for general configuration of the TWAI driver.
Note
Macro initializers are available for this structure
Public Members
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twai_mode_t mode
Mode of TWAI controller
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gpio_num_t tx_io
Transmit GPIO number
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gpio_num_t rx_io
Receive GPIO number
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gpio_num_t clkout_io
CLKOUT GPIO number (optional, set to -1 if unused)
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gpio_num_t bus_off_io
Bus off indicator GPIO number (optional, set to -1 if unused)
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uint32_t tx_queue_len
Number of messages TX queue can hold (set to 0 to disable TX Queue)
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uint32_t rx_queue_len
Number of messages RX queue can hold
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uint32_t alerts_enabled
Bit field of alerts to enable (see documentation)
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uint32_t clkout_divider
CLKOUT divider. Can be 1 or any even number from 2 to 14 (optional, set to 0 if unused)
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int intr_flags
Interrupt flags to set the priority of the driver’s ISR. Note that to use the ESP_INTR_FLAG_IRAM, the CONFIG_TWAI_ISR_IN_IRAM option should be enabled first.
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twai_mode_t mode
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struct twai_status_info_t
Structure to store status information of TWAI driver.
Public Members
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twai_state_t state
Current state of TWAI controller (Stopped/Running/Bus-Off/Recovery)
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uint32_t msgs_to_tx
Number of messages queued for transmission or awaiting transmission completion
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uint32_t msgs_to_rx
Number of messages in RX queue waiting to be read
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uint32_t tx_error_counter
Current value of Transmit Error Counter
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uint32_t rx_error_counter
Current value of Receive Error Counter
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uint32_t tx_failed_count
Number of messages that failed transmissions
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uint32_t rx_missed_count
Number of messages that were lost due to a full RX queue (or errata workaround if enabled)
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uint32_t rx_overrun_count
Number of messages that were lost due to a RX FIFO overrun
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uint32_t arb_lost_count
Number of instances arbitration was lost
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uint32_t bus_error_count
Number of instances a bus error has occurred
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twai_state_t state
Enumerations
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enum twai_state_t
TWAI driver states.
Values:
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enumerator TWAI_STATE_STOPPED
Stopped state. The TWAI controller will not participate in any TWAI bus activities
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enumerator TWAI_STATE_RUNNING
Running state. The TWAI controller can transmit and receive messages
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enumerator TWAI_STATE_BUS_OFF
Bus-off state. The TWAI controller cannot participate in bus activities until it has recovered
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enumerator TWAI_STATE_RECOVERING
Recovering state. The TWAI controller is undergoing bus recovery
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enumerator TWAI_STATE_STOPPED