/* CAN transactions to and from the host come in the form of a certain number of CANPacket_t. The transaction is split into multiple transfers or chunks. * comms_can_read outputs this buffer in chunks of a specified length. chunks are always the given length, except the last one. * comms_can_write reads in this buffer in chunks. * both functions maintain an overflow buffer for a partial CANPacket_t that spans multiple transfers/chunks. * the overflow buffers are reset by a dedicated control transfer handler, which is sent by the host on each start of a connection. */ typedef struct { uint32_t ptr; uint32_t tail_size; uint8_t data[72]; } asm_buffer; static asm_buffer can_read_buffer = {.ptr = 0U, .tail_size = 0U}; int comms_can_read(uint8_t *data, uint32_t max_len) { uint32_t pos = 0U; // Send tail of previous message if it is in buffer if (can_read_buffer.ptr > 0U) { uint32_t overflow_len = MIN(max_len - pos, can_read_buffer.ptr); (void)memcpy(&data[pos], can_read_buffer.data, overflow_len); pos += overflow_len; (void)memcpy(can_read_buffer.data, &can_read_buffer.data[overflow_len], can_read_buffer.ptr - overflow_len); can_read_buffer.ptr -= overflow_len; } if (can_read_buffer.ptr == 0U) { // Fill rest of buffer with new data CANPacket_t can_packet; while ((pos < max_len) && can_pop(&can_rx_q, &can_packet)) { uint32_t pckt_len = CANPACKET_HEAD_SIZE + dlc_to_len[can_packet.data_len_code]; if ((pos + pckt_len) <= max_len) { (void)memcpy(&data[pos], (uint8_t*)&can_packet, pckt_len); pos += pckt_len; } else { (void)memcpy(&data[pos], (uint8_t*)&can_packet, max_len - pos); can_read_buffer.ptr += pckt_len - (max_len - pos); // cppcheck-suppress objectIndex (void)memcpy(can_read_buffer.data, &((uint8_t*)&can_packet)[(max_len - pos)], can_read_buffer.ptr); pos = max_len; } } } return pos; } static asm_buffer can_write_buffer = {.ptr = 0U, .tail_size = 0U}; // send on CAN void comms_can_write(const uint8_t *data, uint32_t len) { uint32_t pos = 0U; // Assembling can message with data from buffer if (can_write_buffer.ptr != 0U) { if (can_write_buffer.tail_size <= (len - pos)) { // we have enough data to complete the buffer CANPacket_t to_push = {0}; (void)memcpy(&can_write_buffer.data[can_write_buffer.ptr], &data[pos], can_write_buffer.tail_size); can_write_buffer.ptr += can_write_buffer.tail_size; pos += can_write_buffer.tail_size; // send out (void)memcpy((uint8_t*)&to_push, can_write_buffer.data, can_write_buffer.ptr); can_send(&to_push, to_push.bus, false); // reset overflow buffer can_write_buffer.ptr = 0U; can_write_buffer.tail_size = 0U; } else { // maybe next time uint32_t data_size = len - pos; (void) memcpy(&can_write_buffer.data[can_write_buffer.ptr], &data[pos], data_size); can_write_buffer.tail_size -= data_size; can_write_buffer.ptr += data_size; pos += data_size; } } // rest of the message while (pos < len) { uint32_t pckt_len = CANPACKET_HEAD_SIZE + dlc_to_len[(data[pos] >> 4U)]; if ((pos + pckt_len) <= len) { CANPacket_t to_push = {0}; (void)memcpy((uint8_t*)&to_push, &data[pos], pckt_len); can_send(&to_push, to_push.bus, false); pos += pckt_len; } else { (void)memcpy(can_write_buffer.data, &data[pos], len - pos); can_write_buffer.ptr = len - pos; can_write_buffer.tail_size = pckt_len - can_write_buffer.ptr; pos += can_write_buffer.ptr; } } refresh_can_tx_slots_available(); } void comms_can_reset(void) { can_write_buffer.ptr = 0U; can_write_buffer.tail_size = 0U; can_read_buffer.ptr = 0U; can_read_buffer.tail_size = 0U; } // TODO: make this more general! void refresh_can_tx_slots_available(void) { if (can_tx_check_min_slots_free(MAX_CAN_MSGS_PER_USB_BULK_TRANSFER)) { can_tx_comms_resume_usb(); } if (can_tx_check_min_slots_free(MAX_CAN_MSGS_PER_SPI_BULK_TRANSFER)) { can_tx_comms_resume_spi(); } }