/* * Copyright (c) 2017 Erwin Rol * Copyright (c) 2020 Alexander Kozhinov * SPDX-License-Identifier: Apache-2.0 */ #define DT_DRV_COMPAT st_stm32_ethernet #define LOG_MODULE_NAME eth_stm32_hal #define LOG_LEVEL CONFIG_ETHERNET_LOG_LEVEL #include LOG_MODULE_REGISTER(LOG_MODULE_NAME); #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "eth.h" #include "eth_stm32_hal_priv.h" #if defined(CONFIG_ETH_STM32_HAL_USE_DTCM_FOR_DMA_BUFFER) && \ !DT_NODE_HAS_STATUS(DT_CHOSEN(zephyr_dtcm), okay) #error DTCM for DMA buffer is activated but zephyr,dtcm is not present in dts #endif #define PHY_ADDR CONFIG_ETH_STM32_HAL_PHY_ADDRESS #if defined(CONFIG_SOC_SERIES_STM32H7X) #define PHY_BSR ((uint16_t)0x0001U) /*!< Transceiver Basic Status Register */ #define PHY_LINKED_STATUS ((uint16_t)0x0004U) /*!< Valid link established */ #define GET_FIRST_DMA_TX_DESC(heth) (heth->Init.TxDesc) #define IS_ETH_DMATXDESC_OWN(dma_tx_desc) (dma_tx_desc->DESC3 & \ ETH_DMATXNDESCRF_OWN) #define ETH_RXBUFNB ETH_RX_DESC_CNT #define ETH_TXBUFNB ETH_TX_DESC_CNT #define ETH_MEDIA_INTERFACE_MII HAL_ETH_MII_MODE #define ETH_MEDIA_INTERFACE_RMII HAL_ETH_RMII_MODE #define ETH_DMA_TRANSMIT_TIMEOUT 20U /* transmit timeout in sys tiks */ #else #define GET_FIRST_DMA_TX_DESC(heth) (heth->TxDesc) #define IS_ETH_DMATXDESC_OWN(dma_tx_desc) (dma_tx_desc->Status & \ ETH_DMATXDESC_OWN) #endif /* CONFIG_SOC_SERIES_STM32H7X */ #if defined(CONFIG_ETH_STM32_HAL_USE_DTCM_FOR_DMA_BUFFER) && \ DT_NODE_HAS_STATUS(DT_CHOSEN(zephyr_dtcm), okay) #define ETH_DMA_MEM __dtcm_noinit_section #else #define ETH_DMA_MEM __aligned(4) #endif /* CONFIG_ETH_STM32_HAL_USE_DTCM_FOR_DMA_BUFFER */ #if defined(CONFIG_NOCACHE_MEMORY) #define CACHE __nocache #else #define CACHE #endif static ETH_DMADescTypeDef dma_rx_desc_tab[ETH_RXBUFNB] CACHE ETH_DMA_MEM; static ETH_DMADescTypeDef dma_tx_desc_tab[ETH_TXBUFNB] CACHE ETH_DMA_MEM; static uint8_t dma_rx_buffer[ETH_RXBUFNB][ETH_RX_BUF_SIZE] CACHE ETH_DMA_MEM; static uint8_t dma_tx_buffer[ETH_TXBUFNB][ETH_TX_BUF_SIZE] CACHE ETH_DMA_MEM; #if defined(CONFIG_SOC_SERIES_STM32H7X) static ETH_TxPacketConfig tx_config CACHE; #endif #if defined(CONFIG_NET_L2_CANBUS_ETH_TRANSLATOR) #include static void set_mac_to_translator_addr(uint8_t *mac_addr) { /* Set the last 14 bit to the translator link layer address to avoid * address collissions with the 6LoCAN address range */ mac_addr[4] = (mac_addr[4] & 0xC0) | (NET_CAN_ETH_TRANSLATOR_ADDR >> 8); mac_addr[5] = NET_CAN_ETH_TRANSLATOR_ADDR & 0xFF; } static void enable_canbus_eth_translator_filter(ETH_HandleTypeDef *heth, uint8_t *mac_addr) { heth->Instance->MACA1LR = (mac_addr[3] << 24U) | (mac_addr[2] << 16U) | (mac_addr[1] << 8U) | mac_addr[0]; #if defined(CONFIG_SOC_SERIES_STM32H7X) heth->Instance->MACA1HR = ETH_MACAHR_AE | ETH_MACAHR_MBC_HBITS15_8 | ETH_MACAHR_MBC_HBITS7_0; #else /*enable filter 1 and ignore byte 5 and 6 for filtering*/ heth->Instance->MACA1HR = ETH_MACA1HR_AE | ETH_MACA1HR_MBC_HBits15_8 | ETH_MACA1HR_MBC_HBits7_0; #endif /* CONFIG_SOC_SERIES_STM32H7X */ } #endif /*CONFIG_NET_L2_CANBUS_ETH_TRANSLATOR*/ static HAL_StatusTypeDef read_eth_phy_register(ETH_HandleTypeDef *heth, uint32_t PHYAddr, uint32_t PHYReg, uint32_t *RegVal) { #if defined(CONFIG_SOC_SERIES_STM32H7X) return HAL_ETH_ReadPHYRegister(heth, PHYAddr, PHYReg, RegVal); #else ARG_UNUSED(PHYAddr); return HAL_ETH_ReadPHYRegister(heth, PHYReg, RegVal); #endif /* CONFIG_SOC_SERIES_STM32H7X */ } static inline void disable_mcast_filter(ETH_HandleTypeDef *heth) { __ASSERT_NO_MSG(heth != NULL); #if defined(CONFIG_SOC_SERIES_STM32H7X) ETH_MACFilterConfigTypeDef MACFilterConf; HAL_ETH_GetMACFilterConfig(heth, &MACFilterConf); MACFilterConf.HashMulticast = DISABLE; MACFilterConf.PassAllMulticast = ENABLE; MACFilterConf.HachOrPerfectFilter = DISABLE; HAL_ETH_SetMACFilterConfig(heth, &MACFilterConf); k_sleep(K_MSEC(1)); #else uint32_t tmp = heth->Instance->MACFFR; /* disable multicast filtering */ tmp &= ~(ETH_MULTICASTFRAMESFILTER_PERFECTHASHTABLE | ETH_MULTICASTFRAMESFILTER_HASHTABLE | ETH_MULTICASTFRAMESFILTER_PERFECT); /* enable receiving all multicast frames */ tmp |= ETH_MULTICASTFRAMESFILTER_NONE; heth->Instance->MACFFR = tmp; /* Wait until the write operation will be taken into account: * at least four TX_CLK/RX_CLK clock cycles */ tmp = heth->Instance->MACFFR; k_sleep(K_MSEC(1)); heth->Instance->MACFFR = tmp; #endif /* CONFIG_SOC_SERIES_STM32H7X) */ } static int eth_tx(struct device *dev, struct net_pkt *pkt) { struct eth_stm32_hal_dev_data *dev_data = DEV_DATA(dev); ETH_HandleTypeDef *heth; uint8_t *dma_buffer; int res; size_t total_len; __IO ETH_DMADescTypeDef *dma_tx_desc; HAL_StatusTypeDef hal_ret = HAL_OK; __ASSERT_NO_MSG(pkt != NULL); __ASSERT_NO_MSG(pkt->frags != NULL); __ASSERT_NO_MSG(dev != NULL); __ASSERT_NO_MSG(dev_data != NULL); heth = &dev_data->heth; k_mutex_lock(&dev_data->tx_mutex, K_FOREVER); total_len = net_pkt_get_len(pkt); if (total_len > ETH_TX_BUF_SIZE) { LOG_ERR("PKT to big"); res = -EIO; goto error; } #if defined(CONFIG_SOC_SERIES_STM32H7X) const uint32_t cur_tx_desc_idx = 0; /* heth->TxDescList.CurTxDesc; */ #endif dma_tx_desc = GET_FIRST_DMA_TX_DESC(heth); while (IS_ETH_DMATXDESC_OWN(dma_tx_desc) != (uint32_t)RESET) { k_yield(); } #if defined(CONFIG_SOC_SERIES_STM32H7X) dma_buffer = dma_tx_buffer[cur_tx_desc_idx]; #else dma_buffer = (uint8_t *)(dma_tx_desc->Buffer1Addr); #endif /* CONFIG_SOC_SERIES_STM32H7X */ if (net_pkt_read(pkt, dma_buffer, total_len)) { res = -EIO; goto error; } #if defined(CONFIG_SOC_SERIES_STM32H7X) ETH_BufferTypeDef tx_buffer_def[ETH_TXBUFNB]; memset(tx_buffer_def, 0, ETH_TXBUFNB*sizeof(ETH_BufferTypeDef)); tx_buffer_def[cur_tx_desc_idx].buffer = dma_buffer; tx_buffer_def[cur_tx_desc_idx].len = total_len; tx_buffer_def[cur_tx_desc_idx].next = NULL; tx_config.Length = total_len; tx_config.TxBuffer = tx_buffer_def; hal_ret = HAL_ETH_Transmit(heth, &tx_config, ETH_DMA_TRANSMIT_TIMEOUT); #else hal_ret = HAL_ETH_TransmitFrame(heth, total_len); #endif /* CONFIG_SOC_SERIES_STM32H7X */ if (hal_ret != HAL_OK) { LOG_ERR("HAL_ETH_Transmit{Frame}: failed!"); res = -EIO; goto error; } #if !defined(CONFIG_SOC_SERIES_STM32H7X) /* When Transmit Underflow flag is set, clear it and issue a * Transmit Poll Demand to resume transmission. */ if ((heth->Instance->DMASR & ETH_DMASR_TUS) != (uint32_t)RESET) { /* Clear TUS ETHERNET DMA flag */ heth->Instance->DMASR = ETH_DMASR_TUS; /* Resume DMA transmission*/ heth->Instance->DMATPDR = 0; res = -EIO; goto error; } #endif /* CONFIG_SOC_SERIES_STM32H7X */ res = 0; error: k_mutex_unlock(&dev_data->tx_mutex); return res; } static struct net_if *get_iface(struct eth_stm32_hal_dev_data *ctx, uint16_t vlan_tag) { #if defined(CONFIG_NET_VLAN) struct net_if *iface; iface = net_eth_get_vlan_iface(ctx->iface, vlan_tag); if (!iface) { return ctx->iface; } return iface; #else ARG_UNUSED(vlan_tag); return ctx->iface; #endif } static struct net_pkt *eth_rx(struct device *dev, uint16_t *vlan_tag) { struct eth_stm32_hal_dev_data *dev_data; ETH_HandleTypeDef *heth; #if !defined(CONFIG_SOC_SERIES_STM32H7X) __IO ETH_DMADescTypeDef *dma_rx_desc; #endif /* !CONFIG_SOC_SERIES_STM32H7X */ struct net_pkt *pkt; size_t total_len; uint8_t *dma_buffer; HAL_StatusTypeDef hal_ret = HAL_OK; __ASSERT_NO_MSG(dev != NULL); dev_data = DEV_DATA(dev); __ASSERT_NO_MSG(dev_data != NULL); heth = &dev_data->heth; #if defined(CONFIG_SOC_SERIES_STM32H7X) if (HAL_ETH_IsRxDataAvailable(heth) != true) { /* no frame available */ return NULL; } ETH_BufferTypeDef rx_buffer_def; uint32_t frame_length = 0; hal_ret = HAL_ETH_GetRxDataBuffer(heth, &rx_buffer_def); if (hal_ret != HAL_OK) { LOG_ERR("HAL_ETH_GetRxDataBuffer: failed with state: %d", hal_ret); return NULL; } hal_ret = HAL_ETH_GetRxDataLength(heth, &frame_length); if (hal_ret != HAL_OK) { LOG_ERR("HAL_ETH_GetRxDataLength: failed with state: %d", hal_ret); return NULL; } total_len = frame_length; dma_buffer = rx_buffer_def.buffer; #else hal_ret = HAL_ETH_GetReceivedFrame_IT(heth); if (hal_ret != HAL_OK) { /* no frame available */ return NULL; } total_len = heth->RxFrameInfos.length; dma_buffer = (uint8_t *)heth->RxFrameInfos.buffer; #endif /* CONFIG_SOC_SERIES_STM32H7X */ pkt = net_pkt_rx_alloc_with_buffer(get_iface(dev_data, *vlan_tag), total_len, AF_UNSPEC, 0, K_NO_WAIT); if (!pkt) { LOG_ERR("Failed to obtain RX buffer"); goto release_desc; } if (net_pkt_write(pkt, dma_buffer, total_len)) { LOG_ERR("Failed to append RX buffer to context buffer"); net_pkt_unref(pkt); pkt = NULL; goto release_desc; } release_desc: #if defined(CONFIG_SOC_SERIES_STM32H7X) hal_ret = HAL_ETH_BuildRxDescriptors(heth); if (hal_ret != HAL_OK) { LOG_ERR("HAL_ETH_BuildRxDescriptors: failed: %d", hal_ret); } #else /* Release descriptors to DMA */ /* Point to first descriptor */ dma_rx_desc = heth->RxFrameInfos.FSRxDesc; /* Set Own bit in Rx descriptors: gives the buffers back to DMA */ for (int i = 0; i < heth->RxFrameInfos.SegCount; i++) { dma_rx_desc->Status |= ETH_DMARXDESC_OWN; dma_rx_desc = (ETH_DMADescTypeDef *) (dma_rx_desc->Buffer2NextDescAddr); } /* Clear Segment_Count */ heth->RxFrameInfos.SegCount = 0; /* When Rx Buffer unavailable flag is set: clear it * and resume reception. */ if ((heth->Instance->DMASR & ETH_DMASR_RBUS) != (uint32_t)RESET) { /* Clear RBUS ETHERNET DMA flag */ heth->Instance->DMASR = ETH_DMASR_RBUS; /* Resume DMA reception */ heth->Instance->DMARPDR = 0; } #endif /* CONFIG_SOC_SERIES_STM32H7X */ #if defined(CONFIG_NET_VLAN) struct net_eth_hdr *hdr = NET_ETH_HDR(pkt); if (ntohs(hdr->type) == NET_ETH_PTYPE_VLAN) { struct net_eth_vlan_hdr *hdr_vlan = (struct net_eth_vlan_hdr *)NET_ETH_HDR(pkt); net_pkt_set_vlan_tci(pkt, ntohs(hdr_vlan->vlan.tci)); *vlan_tag = net_pkt_vlan_tag(pkt); #if CONFIG_NET_TC_RX_COUNT > 1 enum net_priority prio; prio = net_vlan2priority(net_pkt_vlan_priority(pkt)); net_pkt_set_priority(pkt, prio); #endif } else { net_pkt_set_iface(pkt, dev_data->iface); } #endif /* CONFIG_NET_VLAN */ if (!pkt) { eth_stats_update_errors_rx(get_iface(dev_data, *vlan_tag)); } return pkt; } static void rx_thread(void *arg1, void *unused1, void *unused2) { uint16_t vlan_tag = NET_VLAN_TAG_UNSPEC; struct device *dev; struct eth_stm32_hal_dev_data *dev_data; struct net_pkt *pkt; int res; uint32_t status; HAL_StatusTypeDef hal_ret = HAL_OK; __ASSERT_NO_MSG(arg1 != NULL); ARG_UNUSED(unused1); ARG_UNUSED(unused2); dev = (struct device *)arg1; dev_data = DEV_DATA(dev); __ASSERT_NO_MSG(dev_data != NULL); while (1) { res = k_sem_take(&dev_data->rx_int_sem, K_MSEC(CONFIG_ETH_STM32_CARRIER_CHECK_RX_IDLE_TIMEOUT_MS)); if (res == 0) { /* semaphore taken, update link status and receive packets */ if (dev_data->link_up != true) { dev_data->link_up = true; net_eth_carrier_on(get_iface(dev_data, vlan_tag)); } while ((pkt = eth_rx(dev, &vlan_tag)) != NULL) { res = net_recv_data(net_pkt_iface(pkt), pkt); if (res < 0) { eth_stats_update_errors_rx( net_pkt_iface(pkt)); LOG_ERR("Failed to enqueue frame " "into RX queue: %d", res); net_pkt_unref(pkt); } } } else if (res == -EAGAIN) { /* semaphore timeout period expired, check link status */ hal_ret = read_eth_phy_register(&dev_data->heth, PHY_ADDR, PHY_BSR, (uint32_t *) &status); if (hal_ret == HAL_OK) { if ((status & PHY_LINKED_STATUS) == PHY_LINKED_STATUS) { if (dev_data->link_up != true) { dev_data->link_up = true; net_eth_carrier_on( get_iface(dev_data, vlan_tag)); } } else { if (dev_data->link_up != false) { dev_data->link_up = false; net_eth_carrier_off( get_iface(dev_data, vlan_tag)); } } } } } } static void eth_isr(void *arg) { struct device *dev; struct eth_stm32_hal_dev_data *dev_data; ETH_HandleTypeDef *heth; __ASSERT_NO_MSG(arg != NULL); dev = (struct device *)arg; dev_data = DEV_DATA(dev); __ASSERT_NO_MSG(dev_data != NULL); heth = &dev_data->heth; __ASSERT_NO_MSG(heth != NULL); HAL_ETH_IRQHandler(heth); } void HAL_ETH_RxCpltCallback(ETH_HandleTypeDef *heth_handle) { __ASSERT_NO_MSG(heth_handle != NULL); struct eth_stm32_hal_dev_data *dev_data = CONTAINER_OF(heth_handle, struct eth_stm32_hal_dev_data, heth); __ASSERT_NO_MSG(dev_data != NULL); k_sem_give(&dev_data->rx_int_sem); } #if defined(CONFIG_ETH_STM32_HAL_RANDOM_MAC) static void generate_mac(uint8_t *mac_addr) { gen_random_mac(mac_addr, ST_OUI_B0, ST_OUI_B1, ST_OUI_B2); } #endif static int eth_initialize(struct device *dev) { struct eth_stm32_hal_dev_data *dev_data; const struct eth_stm32_hal_dev_cfg *cfg; ETH_HandleTypeDef *heth; HAL_StatusTypeDef hal_ret = HAL_OK; int ret = 0; __ASSERT_NO_MSG(dev != NULL); dev_data = DEV_DATA(dev); cfg = DEV_CFG(dev); __ASSERT_NO_MSG(dev_data != NULL); __ASSERT_NO_MSG(cfg != NULL); dev_data->clock = device_get_binding(STM32_CLOCK_CONTROL_NAME); __ASSERT_NO_MSG(dev_data->clock != NULL); /* enable clock */ ret = clock_control_on(dev_data->clock, (clock_control_subsys_t *)&cfg->pclken); ret |= clock_control_on(dev_data->clock, (clock_control_subsys_t *)&cfg->pclken_tx); ret |= clock_control_on(dev_data->clock, (clock_control_subsys_t *)&cfg->pclken_rx); #if !defined(CONFIG_SOC_SERIES_STM32H7X) ret |= clock_control_on(dev_data->clock, (clock_control_subsys_t *)&cfg->pclken_ptp); #endif /* !defined(CONFIG_SOC_SERIES_STM32H7X) */ if (ret) { LOG_ERR("Failed to enable ethernet clock"); return -EIO; } heth = &dev_data->heth; #if defined(CONFIG_ETH_STM32_HAL_RANDOM_MAC) generate_mac(dev_data->mac_addr); #endif #if defined(CONFIG_NET_L2_CANBUS_ETH_TRANSLATOR) set_mac_to_translator_addr(dev_data->mac_addr); #endif heth->Init.MACAddr = dev_data->mac_addr; #if defined(CONFIG_SOC_SERIES_STM32H7X) heth->Init.TxDesc = dma_tx_desc_tab; heth->Init.RxDesc = dma_rx_desc_tab; heth->Init.RxBuffLen = ETH_RX_BUF_SIZE; #endif /* CONFIG_SOC_SERIES_STM32H7X */ hal_ret = HAL_ETH_Init(heth); if (hal_ret == HAL_TIMEOUT) { /* HAL Init time out. This could be linked to */ /* a recoverable error. Log the issue and continue */ /* driver initialisation */ LOG_ERR("HAL_ETH_Init Timed out"); } else if (hal_ret != HAL_OK) { LOG_ERR("HAL_ETH_Init failed: %d", hal_ret); return -EINVAL; } #if defined(CONFIG_SOC_SERIES_STM32H7X) /* Tx config init: */ memset(&tx_config, 0, sizeof(ETH_TxPacketConfig)); tx_config.Attributes = ETH_TX_PACKETS_FEATURES_CSUM | ETH_TX_PACKETS_FEATURES_CRCPAD; tx_config.ChecksumCtrl = ETH_CHECKSUM_IPHDR_PAYLOAD_INSERT_PHDR_CALC; tx_config.CRCPadCtrl = ETH_CRC_PAD_INSERT; #endif /* CONFIG_SOC_SERIES_STM32H7X */ dev_data->link_up = false; /* Initialize semaphores */ k_mutex_init(&dev_data->tx_mutex); k_sem_init(&dev_data->rx_int_sem, 0, UINT_MAX); /* Start interruption-poll thread */ k_thread_create(&dev_data->rx_thread, dev_data->rx_thread_stack, K_THREAD_STACK_SIZEOF(dev_data->rx_thread_stack), rx_thread, (void *) dev, NULL, NULL, K_PRIO_COOP(CONFIG_ETH_STM32_HAL_RX_THREAD_PRIO), 0, K_NO_WAIT); #if defined(CONFIG_SOC_SERIES_STM32H7X) for (uint32_t i = 0; i < ETH_RX_DESC_CNT; i++) { hal_ret = HAL_ETH_DescAssignMemory(heth, i, dma_rx_buffer[i], NULL); if (hal_ret != HAL_OK) { LOG_ERR("HAL_ETH_DescAssignMemory: failed: %d, i: %d", hal_ret, i); return -EINVAL; } } hal_ret = HAL_ETH_Start_IT(heth); #else HAL_ETH_DMATxDescListInit(heth, dma_tx_desc_tab, &dma_tx_buffer[0][0], ETH_TXBUFNB); HAL_ETH_DMARxDescListInit(heth, dma_rx_desc_tab, &dma_rx_buffer[0][0], ETH_RXBUFNB); hal_ret = HAL_ETH_Start(heth); #endif /* CONFIG_SOC_SERIES_STM32H7X */ if (hal_ret != HAL_OK) { LOG_ERR("HAL_ETH_Start{_IT} failed"); } disable_mcast_filter(heth); #if defined(CONFIG_NET_L2_CANBUS_ETH_TRANSLATOR) enable_canbus_eth_translator_filter(heth, dev_data->mac_addr); #endif #if defined(CONFIG_SOC_SERIES_STM32H7X) /* Adjust MDC clock range depending on HCLK frequency: */ HAL_ETH_SetMDIOClockRange(heth); /* @TODO: read duplex mode and speed from PHY and set it to ETH */ ETH_MACConfigTypeDef mac_config; HAL_ETH_GetMACConfig(heth, &mac_config); mac_config.DuplexMode = ETH_FULLDUPLEX_MODE; mac_config.Speed = ETH_SPEED_100M; HAL_ETH_SetMACConfig(heth, &mac_config); #endif /* CONFIG_SOC_SERIES_STM32H7X */ LOG_DBG("MAC %02x:%02x:%02x:%02x:%02x:%02x", dev_data->mac_addr[0], dev_data->mac_addr[1], dev_data->mac_addr[2], dev_data->mac_addr[3], dev_data->mac_addr[4], dev_data->mac_addr[5]); return 0; } static void eth_iface_init(struct net_if *iface) { struct device *dev; struct eth_stm32_hal_dev_data *dev_data; __ASSERT_NO_MSG(iface != NULL); dev = net_if_get_device(iface); __ASSERT_NO_MSG(dev != NULL); dev_data = DEV_DATA(dev); __ASSERT_NO_MSG(dev_data != NULL); /* For VLAN, this value is only used to get the correct L2 driver. * The iface pointer in context should contain the main interface * if the VLANs are enabled. */ if (dev_data->iface == NULL) { dev_data->iface = iface; /* Now that the iface is setup, we are safe to enable IRQs. */ __ASSERT_NO_MSG(DEV_CFG(dev)->config_func != NULL); DEV_CFG(dev)->config_func(); } /* Register Ethernet MAC Address with the upper layer */ net_if_set_link_addr(iface, dev_data->mac_addr, sizeof(dev_data->mac_addr), NET_LINK_ETHERNET); ethernet_init(iface); net_if_flag_set(iface, NET_IF_NO_AUTO_START); } static enum ethernet_hw_caps eth_stm32_hal_get_capabilities(struct device *dev) { ARG_UNUSED(dev); return ETHERNET_LINK_10BASE_T | ETHERNET_LINK_100BASE_T #if defined(CONFIG_NET_VLAN) | ETHERNET_HW_VLAN #endif ; } static int eth_stm32_hal_set_config(struct device *dev, enum ethernet_config_type type, const struct ethernet_config *config) { struct eth_stm32_hal_dev_data *dev_data; ETH_HandleTypeDef *heth; switch (type) { case ETHERNET_CONFIG_TYPE_MAC_ADDRESS: dev_data = DEV_DATA(dev); heth = &dev_data->heth; memcpy(dev_data->mac_addr, config->mac_address.addr, 6); heth->Instance->MACA0HR = (dev_data->mac_addr[5] << 8) | dev_data->mac_addr[4]; heth->Instance->MACA0LR = (dev_data->mac_addr[3] << 24) | (dev_data->mac_addr[2] << 16) | (dev_data->mac_addr[1] << 8) | dev_data->mac_addr[0]; return 0; default: break; } return -ENOTSUP; } static const struct ethernet_api eth_api = { .iface_api.init = eth_iface_init, .get_capabilities = eth_stm32_hal_get_capabilities, .set_config = eth_stm32_hal_set_config, .send = eth_tx, }; DEVICE_DECLARE(eth0_stm32_hal); static void eth0_irq_config(void) { IRQ_CONNECT(DT_INST_IRQN(0), DT_INST_IRQ(0, priority), eth_isr, DEVICE_GET(eth0_stm32_hal), 0); irq_enable(DT_INST_IRQN(0)); } static const struct eth_stm32_hal_dev_cfg eth0_config = { .config_func = eth0_irq_config, .pclken = {.bus = DT_INST_CLOCKS_CELL_BY_NAME(0, stmmaceth, bus), .enr = DT_INST_CLOCKS_CELL_BY_NAME(0, stmmaceth, bits)}, .pclken_tx = {.bus = DT_INST_CLOCKS_CELL_BY_NAME(0, mac_clk_tx, bus), .enr = DT_INST_CLOCKS_CELL_BY_NAME(0, mac_clk_tx, bits)}, .pclken_rx = {.bus = DT_INST_CLOCKS_CELL_BY_NAME(0, mac_clk_rx, bus), .enr = DT_INST_CLOCKS_CELL_BY_NAME(0, mac_clk_rx, bits)}, #if !defined(CONFIG_SOC_SERIES_STM32H7X) .pclken_ptp = {.bus = DT_INST_CLOCKS_CELL_BY_NAME(0, mac_clk_ptp, bus), .enr = DT_INST_CLOCKS_CELL_BY_NAME(0, mac_clk_ptp, bits)}, #endif /* !CONFIG_SOC_SERIES_STM32H7X */ }; static struct eth_stm32_hal_dev_data eth0_data = { .heth = { .Instance = (ETH_TypeDef *)DT_INST_REG_ADDR(0), .Init = { #if !defined(CONFIG_SOC_SERIES_STM32H7X) .AutoNegotiation = ETH_AUTONEGOTIATION_ENABLE, .PhyAddress = PHY_ADDR, .RxMode = ETH_RXINTERRUPT_MODE, .ChecksumMode = ETH_CHECKSUM_BY_SOFTWARE, #endif /* !CONFIG_SOC_SERIES_STM32H7X */ #if defined(CONFIG_ETH_STM32_HAL_MII) .MediaInterface = ETH_MEDIA_INTERFACE_MII, #else .MediaInterface = ETH_MEDIA_INTERFACE_RMII, #endif }, }, .mac_addr = { ST_OUI_B0, ST_OUI_B1, ST_OUI_B2, #if !defined(CONFIG_ETH_STM32_HAL_RANDOM_MAC) CONFIG_ETH_STM32_HAL_MAC3, CONFIG_ETH_STM32_HAL_MAC4, CONFIG_ETH_STM32_HAL_MAC5 #endif }, }; ETH_NET_DEVICE_INIT(eth0_stm32_hal, DT_INST_LABEL(0), eth_initialize, device_pm_control_nop, ð0_data, ð0_config, CONFIG_ETH_INIT_PRIORITY, ð_api, ETH_STM32_HAL_MTU);