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/** @addtogroup fdcan_file FDCAN peripheral API
*
* @ingroup peripheral_apis
*
* @brief <b>libopencm3 STM32 FDCAN</b>
*
* @version 1.0.0
*
* @author @htmlonly &copy; @endhtmlonly 2021 Eduard Drusa <ventyl86 at netkosice dot sk>
*
* Device is equipped with two FDCAN peripherals residing in one FDCAN block. The peripherals
* support both CAN 2.0 A and B standard and Bosch FDCAN standard. FDCAN frame format and
* bitrate switching is supported. The peripheral has several filters for incoming messages that
* can be distributed between two FIFOs and transmit buffer all of configurable amount of
* entries. For transmitted messages it is possible to opt for event notification once message
* is transmitted.
*
* The FDCAN peripheral present in STM32 H7 is a superset of FDCAN peripheral found in other MCUs
* such as STM32 G4. It allows more fine-grade control over buffer and filter allocation and
* supports TTCAN on CAN1, etc. This driver provides source-level backwards compatible
* implementation of driver, which allows build of unmodified software originally written for
* STM32 G4 on STM32 H7.
*
* LGPL License Terms @ref lgpl_license
*/
/*
* This file is part of the libopencm3 project.
*
* Copyright (C) 2021 Eduard Drusa <ventyl86 at netkosice dot sk>
*
* This library is free software: you can redistribute it and/or modify
* it under the terms of the GNU Lesser General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public License
* along with this library. If not, see <http://www.gnu.org/licenses/>.
*/
#include <libopencm3/stm32/fdcan.h>
#include <libopencm3/stm32/rcc.h>
#include <stddef.h>
#define FDCAN_LSS_COUNT(can_base) \
((FDCAN_SIDFC(can_base) >> FDCAN_SIDFC_LSS_SHIFT) & FDCAN_SIDFC_LSS_MASK)
#define FDCAN_LSE_COUNT(can_base) \
((FDCAN_XIDFC(can_base) >> FDCAN_XIDFC_LSE_SHIFT) & FDCAN_XIDFC_LSE_MASK)
/* --- FD-CAN functions ----------------------------------------------------- */
/** @ingroup fdcan_file */
/**@{
* */
/** Returns actual size of FIFO entry in FIFO for given CAN port and FIFO.
*
* Obtains value of FIFO entry length. This value covers both fixed-size frame
* header block and payload buffer. User can configure payload buffer size individually
* for each FIFO and designated RX buffer.
*
* @param [in] canport FDCAN block base address. See @ref fdcan_block.
* @param [in] fifo_id ID of FIFO whole length is queried.
* @returns Length of FIFO entry length covering frame header and frame payload.
*/
unsigned fdcan_get_fifo_element_size(uint32_t canport, unsigned fifo_id)
{
unsigned element_size;
if (fifo_id == 0) {
element_size = FDCAN_RXESC(canport) >> FDCAN_RXESC_F0DS_SHIFT;
} else {
element_size = FDCAN_RXESC(canport) >> FDCAN_RXESC_F1DS_SHIFT;
}
/* Mask is unshifted and at this point, element_size is unshifted too */
return 8 + fdcan_dlc_to_length((element_size & FDCAN_RXESC_F0DS_MASK) | 0x8);
}
/** Returns actual size of transmit entry in transmit queue/FIFO for given CAN port.
*
* Obtains value of entry length in transmit queue/FIFO. This value covers both
* fixed-sized frame header block and payload buffer. User can configure payload buffer
* size.
*
* @param [in] canport FDCAN block base address. See @ref fdcan_block.
* @returns Length of FIFO entry length covering frame header and frame payload.
*/
unsigned fdcan_get_txbuf_element_size(uint32_t canport)
{
unsigned element_size;
element_size = (FDCAN_TXESC(canport) >> FDCAN_TXESC_TBDS_SHIFT) & FDCAN_TXESC_TBDS_MASK;
return 8 + fdcan_dlc_to_length((element_size & FDCAN_TXESC_TBDS_MASK) | 0x8);
}
/** Initialize allocation of standard filter block in CAN message RAM.
*
* Allows specifying size of standard filtering block (in term of available filtering
* rules and filter base address within CAN message RAM. Note, that there are no limitations
* nor checking on address provided. It is possible to share whole filtering block or
* portion of it between multiple CAN interfaces.
* @param [in] canport FDCAN block base address. See @ref fdcan_block.
* @param [in] flssa standard filtering block start address offset in message RAM
* @param [in] lss amount of standard filters
*/
void fdcan_init_std_filter_ram(uint32_t canport, uint32_t flssa, uint8_t lss)
{
FDCAN_SIDFC(canport) = flssa << FDCAN_SIDFC_FLSSA_SHIFT
| lss << FDCAN_SIDFC_LSS_SHIFT;
}
/** Initialize allocation of extended filter block in CAN message RAM.
*
* Allows specifying size of extended filtering block (in term of available filtering
* rules and filter base address within CAN message RAM. Note, that there are no limitations
* nor checking on address provided. It is possible to share whole filtering block or
* portion of it between multiple CAN interfaces.
* @param [in] canport FDCAN block base address. See @ref fdcan_block.
* @param [in] flesa extended filtering block start address offset in message RAM
* @param [in] lse amount of extended filters
*/
void fdcan_init_ext_filter_ram(uint32_t canport, uint32_t flesa, uint8_t lse)
{
FDCAN_XIDFC(canport) = flesa << FDCAN_XIDFC_FLESA_SHIFT
| lse << FDCAN_XIDFC_LSE_SHIFT;
}
/** Initialize allocation of FIFO block in CAN message RAM.
*
* Allows specifying size of FIFO block (in term of available messages in FIFO
* and FIFO base address within CAN message RAM. Note, that there are no limitations
* nor checking on address provided.
* @param [in] canport FDCAN block base address. See @ref fdcan_block.
* @param [in] fifo_id ID of fifo being configured
* @param [in] fxsa FIFO block start address offset in message RAM
* @param [in] fxs number of elements to assign
*/
void fdcan_init_fifo_ram(uint32_t canport, unsigned fifo_id, uint32_t fxsa, uint8_t fxs)
{
FDCAN_RXFIC(canport, fifo_id) = (FDCAN_RXFIC(canport, fifo_id)
& ~(
(FDCAN_RXFIC_FIS_MASK << FDCAN_RXFIC_FIS_SHIFT)
| (FDCAN_RXFIC_FISA_MASK << FDCAN_RXFIC_FISA_SHIFT)
))
| (fxs << FDCAN_RXFIC_FIS_SHIFT)
| (fxsa & (FDCAN_RXFIC_FISA_MASK << FDCAN_RXFIC_FISA_SHIFT));
}
/** Initialize allocation of transmit event block in CAN message RAM.
*
* Allows specifying size of transmit event block (in term of allocated events and block
* base address within CAN message RAM. Note, that there are no limitations
* nor checking on address provided.
* @param [in] canport FDCAN block base address. See @ref fdcan_block.
* @param [in] tesa block start address offset in message RAM
* @param [in] tes number of elements to assign
*/
void fdcan_init_tx_event_ram(uint32_t canport, uint32_t tesa, uint8_t tes)
{
FDCAN_TXEFC(canport) = (FDCAN_TXEFC(canport)
& ~(
(FDCAN_TXEFC_EFS_MASK << FDCAN_TXEFC_EFS_SHIFT)
| (FDCAN_TXEFC_EFSA_MASK << FDCAN_TXEFC_EFSA_SHIFT)
))
| (tes << FDCAN_TXEFC_EFS_SHIFT)
| (tesa & (FDCAN_TXEFC_EFSA_MASK << FDCAN_TXEFC_EFSA_SHIFT));
}
/** Initialize allocation of transmit queue block in CAN message RAM.
*
* Allows specifying size of transmit queue block (in term of allocated buffers and block
* base address within CAN message RAM. Note, that there are no limitations
* nor checking on address provided.
* @param [in] canport FDCAN block base address. See @ref fdcan_block.
* @param [in] tbsa block start address offset in message RAM
* @param [in] tbs number of elements to assign
*/
void fdcan_init_tx_buffer_ram(uint32_t canport, uint32_t tbsa, uint8_t tbs)
{
FDCAN_TXBC(canport) = (FDCAN_TXBC(canport)
& ~(
(FDCAN_TXBC_TFQS_MASK << FDCAN_TXBC_TFQS_SHIFT)
| (FDCAN_TXBC_TBSA_MASK << FDCAN_TXBC_TBSA_SHIFT)
))
| (tbs << FDCAN_TXBC_TFQS_SHIFT)
| (tbsa & (FDCAN_TXBC_TBSA_MASK << FDCAN_TXBC_TBSA_SHIFT));
}
/** Initialize size of data fields in reception buffers.
*
* Configures maximum size of message payload, which can be stored in different
* reception buffers. Each buffer can have maximum payload size configured independently.
* Buffers can only be configured to sizes which are valid sizes of FDCAN payload. Sizes smaller
* than 8 are automatically padded to 8.
* @note If you change these values, then content of reception buffers is invalidated. You may
* also want to recalculate base addresses of objects in message RAM as their size might have
* changed.
* @param [in] canport FDCAN block base address. See @ref fdcan_block.
* @param [in] rxbuf maximum storable payload size of dedicated RX buffer
* @param [in] rxfifo0 maximum storable payload size of RX FIFO 0
* @param [in] rxfifo1 maximum storable payload size of RX FIFO 1
* @returns operation return status. See @ref fdcan_error.
*/
int fdcan_set_rx_element_size(uint32_t canport, uint8_t rxbuf, uint8_t rxfifo0, uint8_t rxfifo1)
{
unsigned rxbufdlc = fdcan_length_to_dlc(rxbuf);
unsigned rxfifo0dlc = fdcan_length_to_dlc(rxfifo0);
unsigned rxfifo1dlc = fdcan_length_to_dlc(rxfifo1);
if (rxbufdlc == 0xFF || rxfifo0dlc == 0xFF || rxfifo1dlc == 0xFF) {
return FDCAN_E_INVALID;
}
/* RXESC fields use format of FDCAN DLC, albeit using only
* three LSBs. DLC < 8 is always allocated as 8 bytes and is always
* encoded as 0.
*/
if (rxbufdlc <= 8) {
rxbufdlc = 0;
} else {
rxbufdlc &= ~(1 << 4);
}
if (rxfifo0dlc <= 8) {
rxfifo0dlc = 0;
} else {
rxfifo0dlc &= ~(1 << 4);
}
if (rxfifo1dlc <= 8) {
rxfifo1dlc = 0;
} else {
rxfifo1dlc &= ~(1 << 4);
}
FDCAN_RXESC(canport) = rxbufdlc << FDCAN_RXESC_RBDS_SHIFT
| rxfifo1dlc << FDCAN_RXESC_F1DS_SHIFT
| rxfifo0dlc << FDCAN_RXESC_F0DS_SHIFT;
return FDCAN_E_OK;
}
/** Initialize size of data fields in transmit buffers.
*
* Configures maximum size of message payload, which can be stored either in dedicated
* transmit buffer or into transmit queue/FIFO. One size is applied both to transmit buffer
* and transmit queue / FIFO. Buffers can only be configured to sizes which are valid sizes
* of FDCAN payload. Sizes smaller than 8 are automatically padded to 8 bytes.
* @note If you change these values, then content of transmission buffers is invalidated. You may
* also want to recalculate base addresses of objects in message RAM as their size might have
* changed.
* @param [in] canport FDCAN block base address. See @ref fdcan_block.
* @param [in] txbuf maximum storable payload size of TX buffer / FIFO / queue
* @returns operation return status. See @ref fdcan_error.
*/
int fdcan_set_tx_element_size(uint32_t canport, uint8_t txbuf)
{
unsigned txbufdlc = fdcan_length_to_dlc(txbuf);
if (txbufdlc == 0xFF) {
return FDCAN_E_INVALID;
}
if (txbufdlc <= 8) {
txbufdlc = 0;
} else {
txbufdlc &= ~(1 << 4);
}
FDCAN_TXESC(canport) = txbufdlc << FDCAN_TXESC_TBDS_SHIFT;
return FDCAN_E_OK;
}
/** Configure amount of filters and initialize filtering block.
*
* This function allows to configure global amount of filters present.
* FDCAN block will only ever check as many filters as this function configures.
* Function will also clear all filter blocks to zero values. This function
* can be only called after @ref fdcan_init has already been called and
* @ref fdcan_start has not been called yet as registers holding filter
* count are write-protected unless FDCAN block is in INIT mode. It is possible
* to reconfigure filters (@ref fdcan_set_std_filter and @ref fdcan_set_ext_filter)
* after FDCAN block has already been started.
*
* This function is provided for source level compatibility with code written for
* STM32G4. As an alternative, you can use @ref fdcan_init_std_filter_ram() and
* @ref fdcan_init_ext_filter_ram() to have more control over filtering configuration.
* Note that if you do so, your code won't be compatible with STM32G4 controllers.
*
* @param [in] canport FDCAN block base address. See @ref fdcan_block.
* @param [in] std_filt requested amount of standard ID filter rules (0-28)
* @param [in] ext_filt requested amount of extended ID filter rules (0-8)
*/
void fdcan_init_filter(uint32_t canport, uint8_t std_filt, uint8_t ext_filt)
{
struct fdcan_standard_filter *lfssa;
struct fdcan_extended_filter *lfesa;
int can_id = FDCAN_BLOCK_ID(canport);
int lfsofs = 0;
int lfeofs = 0;
int lfssize = std_filt * sizeof(struct fdcan_standard_filter);
int lfesize = ext_filt * sizeof(struct fdcan_extended_filter);
if (can_id == 0) {
lfsofs = 0;
lfeofs = lfssize;
} else {
lfsofs = CAN_MSG_BASE + CAN_MSG_SIZE - lfssize;
lfeofs = lfsofs - lfesize;
}
fdcan_init_std_filter_ram(canport, lfsofs, 28);
fdcan_init_ext_filter_ram(canport, lfeofs, 8);
lfssa = fdcan_get_flssa_addr(canport);
lfesa = fdcan_get_flesa_addr(canport);
/* Only perform initialization of message RAM if there are
* any filters required
*/
if (std_filt > 0) {
for (int q = 0; q < 28; ++q) {
lfssa[q].type_id1_conf_id2 = 0;
}
}
if (ext_filt > 0) {
for (int q = 0; q < 8; ++q) {
lfesa[q].conf_id1 = 0;
lfesa[q].type_id2 = 0;
}
}
}
/** Enable FDCAN operation after FDCAN block has been set up.
*
* This function will disable FDCAN configuration effectively
* allowing FDCAN to sync up with the bus. After calling this function
* it is not possible to reconfigure amount of filter rules, yet
* it is possible to configure rules themselves. FDCAN block operation
* state can be checked using @ref fdcan_get_init_state.
*
* @param [in] canport FDCAN block base address. See @ref fdcan_block.
* @param [in] timeout Amount of empty busy loops, which routine should wait for FDCAN
* confirming that it left INIT mode. If set to 0, function will return
* immediately.
* @returns Operation error status. See @ref fdcan_error.
* @note If this function returns with timeout, it usually means that
* FDCAN_clk is not set up properly.
*/
int fdcan_start(uint32_t canport, uint32_t timeout)
{
/* This block detects obviously invalid configuration of
* RX FIFOs and TX buffers. Such situation may happen
* if code originally targeted for STM32G4 is compiled for
* STM32H7. This code is not aware of H7 abilities and
* leaves this stuff unconfigured. We pick up here and
* assume, that the code wants the FDCAN to behave as if
* it was STM32G4. Therefore we will configure two three entry
* long RX FIFOs, three entry long TX event buffer and three
* entry long TX FIFO/queue here.
*/
if (FDCAN_RXFIFO_OFFSET(canport, 0) == 0
&& FDCAN_RXFIFO_OFFSET(canport, 1) == 0
&& FDCAN_TXBUF_OFFSET(canport) == 0
&& FDCAN_TXEVT_OFFSET(canport) == 0
&& FDCAN_RXESC(canport) == 0
&& FDCAN_TXESC(canport) == 0
) {
/* These sizes are fixed based on what G4 contains. */
int fifo0_size = 3 * sizeof(struct fdcan_rx_fifo_element);
int fifo1_size = fifo0_size;
int txevt_size = 3 * sizeof(struct fdcan_tx_event_element);
int txbuf_size = 3 * sizeof(struct fdcan_tx_buffer_element);
fdcan_set_rx_element_size(canport, 0, 64, 64);
fdcan_set_tx_element_size(canport, 64);
/* At this point we simply assume that FLSSA and FLESA were
* set up by calling fdcan_init_filter(). It they weren't,
* there just won't be allocated any space for them.
* That's not a problem as after fdcan_start returns, it is
* not possible to configure filter amount anymore.
*
* Default approach is to configure CAN1 to occupy bottom
* of message RAM and CAN1 to occupy top of message RAM keeping
* large unused space in between. This ensures that even if someone
* starts playing with CAN1, "implicit" configuration of CAN2 done
* here won't break things magically.
*/
if (FDCAN_BLOCK_ID(canport) == 0) {
/* CAN1 will use bottom-up layout with
* FLSSA < FLESA < F0SA < F1SA < TXESA < TXBSA
* Rx buffer is not used.
*/
fdcan_init_fifo_ram(canport, 0,
FDCAN_LFESA_OFFSET(canport)
+ FDCAN_LSE_COUNT(canport) * sizeof(struct fdcan_extended_filter),
3);
fdcan_init_fifo_ram(canport, 1,
FDCAN_RXFIFO_OFFSET(canport, 0) + fifo0_size, 3);
fdcan_init_tx_event_ram(canport,
FDCAN_RXFIFO_OFFSET(canport, 1) + fifo1_size, 3);
fdcan_init_tx_buffer_ram(canport,
FDCAN_TXEVT_OFFSET(canport) + txevt_size, 3);
} else {
/* LFESA might be uninitialized. In such case
* we forge it's address at the end of MSG RAM
*/
int lfesa_offs = FDCAN_LFESA_OFFSET(canport);
if (lfesa_offs == 0) {
lfesa_offs = CAN_MSG_SIZE;
}
/* CAN2 will use top-down layout with
* TXBSA < TXESA < F1SA < F0SA < FLESA < FLSSA
* Rx buffer is not used.
* This arrangement should ensure that even if
* CAN1 was configured manually, CAN2 default
* configuration should not break CAN1.
*/
fdcan_init_fifo_ram(canport, 0, lfesa_offs - fifo0_size, 3);
fdcan_init_fifo_ram(canport, 1,
FDCAN_RXFIFO_OFFSET(canport, 0) - fifo1_size, 3);
fdcan_init_tx_event_ram(canport,
FDCAN_RXFIFO_OFFSET(canport, 1) - txevt_size, 3);
fdcan_init_tx_buffer_ram(canport,
FDCAN_TXEVT_OFFSET(canport) - txbuf_size, 3);
}
}
/* Error here usually means, that FDCAN_clk is not set up
* correctly, or at all. This usually can't be seen above
* when INIT is set to 1, because default value for INIT is
* 1 as long as one has FDCAN_pclk configured properly.
**/
if (fdcan_cccr_init_cfg(canport, false, timeout) != 0) {
return FDCAN_E_TIMEOUT;
}
return FDCAN_E_OK;
}
/** Configure FDCAN FIFO lock mode
*
* This function allows to choose between locked and overewrite mode of FIFOs. In locked mode,
* whenever FIFO is full and new frame arrives, which would normally been stored into given
* FIFO, then frame is dropped. If overwrite mode is active, then most recent message in FIFO
* is rewritten by frame just received.
* @param [in] canport FDCAN block base address. See @ref fdcan_block.
* @param [in] locked true activates locked mode, false activates overwrite mode
*/
void fdcan_set_fifo_locked_mode(uint32_t canport, bool locked)
{
if (locked) {
FDCAN_RXF0C(canport) &= ~(FDCAN_RXF0C_F0OM);
FDCAN_RXF1C(canport) &= ~(FDCAN_RXF1C_F1OM);
} else {
FDCAN_RXF0C(canport) |= FDCAN_RXF0C_F0OM;
FDCAN_RXF1C(canport) |= FDCAN_RXF1C_F1OM;
}
}
/**@}*/