/* * Copyright (c) 2017 Intel Corporation. * * SPDX-License-Identifier: Apache-2.0 */ #define SYS_LOG_DOMAIN "ETH DW" #define SYS_LOG_LEVEL CONFIG_SYS_LOG_ETHERNET_LEVEL #include #include #include #include #include #include #include #include #include #include #include #include #include #include "eth_dw_priv.h" #ifdef CONFIG_SHARED_IRQ #include #endif #define TX_BUSY_LOOP_SPINS 20 static inline u32_t eth_read(u32_t base_addr, u32_t offset) { return sys_read32(base_addr + offset); } static inline void eth_write(u32_t base_addr, u32_t offset, u32_t val) { sys_write32(val, base_addr + offset); } static void eth_rx(struct device *port) { struct eth_runtime *context = port->driver_data; struct net_pkt *pkt; u32_t frm_len; int r; /* Check whether the RX descriptor is still owned by the device. If not, * process the received frame or an error that may have occurred. */ if (context->rx_desc.own) { SYS_LOG_ERR("Spurious receive interrupt from Ethernet MAC"); return; } if (context->rx_desc.err_summary) { SYS_LOG_ERR("Error receiving frame: RDES0 = %08x, RDES1 = %08x", context->rx_desc.rdes0, context->rx_desc.rdes1); goto release_desc; } frm_len = context->rx_desc.frm_len; if (frm_len > sizeof(context->rx_buf)) { SYS_LOG_ERR("Frame too large: %u", frm_len); goto release_desc; } /* Throw away the last 4 bytes (CRC). See IntelĀ® Quark TM SoC X1000 * datasheet, Table 95 (Receive Descriptor Fields (RDES0)), "frame * length": * These bits indicate the byte length of the received frame that * was transferred to host memory (including CRC). * If the CRC is not removed here, packet processing in upper layers * will fail since the packet length will be different from the * received frame length by exactly 4 bytes. */ if (frm_len < sizeof(u32_t)) { SYS_LOG_ERR("Frame too small: %u", frm_len); goto release_desc; } else { frm_len -= sizeof(u32_t); } pkt = net_pkt_get_reserve_rx(0, K_NO_WAIT); if (!pkt) { SYS_LOG_ERR("Failed to obtain RX buffer"); goto release_desc; } if (!net_pkt_append_all(pkt, frm_len, (u8_t *)context->rx_buf, K_NO_WAIT)) { SYS_LOG_ERR("Failed to append RX buffer to context buffer"); net_pkt_unref(pkt); goto release_desc; } r = net_recv_data(context->iface, pkt); if (r < 0) { SYS_LOG_ERR("Failed to enqueue frame into RX queue: %d", r); net_pkt_unref(pkt); } release_desc: /* Return ownership of the RX descriptor to the device. */ context->rx_desc.own = 1; /* Request that the device check for an available RX descriptor, since * ownership of the descriptor was just transferred to the device. */ eth_write(context->base_addr, REG_ADDR_RX_POLL_DEMAND, 1); } static void eth_tx_spin_wait(struct eth_runtime *context) { int spins; for (spins = 0; spins < TX_BUSY_LOOP_SPINS; spins++) { if (!context->tx_desc.own) { return; } } while (context->tx_desc.own) { k_yield(); } } static void eth_tx_data(struct eth_runtime *context, u8_t *data, u16_t len) { #ifdef CONFIG_NET_DEBUG_L2_ETHERNET /* Check whether an error occurred transmitting the previous frame. */ if (context->tx_desc.err_summary) { SYS_LOG_ERR("Error transmitting frame: TDES0 = %08x," "TDES1 = %08x", context->tx_desc.tdes0, context->tx_desc.tdes1); } #endif /* Update transmit descriptor. */ context->tx_desc.buf1_ptr = data; context->tx_desc.tx_buf1_sz = len; eth_write(context->base_addr, REG_ADDR_TX_DESC_LIST, (u32_t)&context->tx_desc); context->tx_desc.own = 1; /* Request that the device check for an available TX descriptor, since * ownership of the descriptor was just transferred to the device. */ eth_write(context->base_addr, REG_ADDR_TX_POLL_DEMAND, 1); /* Ensure DMA transfer has been completed. */ eth_tx_spin_wait(context); } /* @brief Transmit the current Ethernet frame. * * This procedure will block indefinitely until all fragments from a * net_buf have been transmitted. Data is copied using DMA directly * from each fragment's data pointer. This procedure might yield to * other threads while waiting for the DMA transfer to finish. */ static int eth_tx(struct net_if *iface, struct net_pkt *pkt) { struct device *port = net_if_get_device(iface); struct eth_runtime *context = port->driver_data; /* Ensure we're clear to transmit. */ eth_tx_spin_wait(context); if (!pkt->frags) { eth_tx_data(context, net_pkt_ll(pkt), net_pkt_ll_reserve(pkt)); } else { struct net_buf *frag; eth_tx_data(context, net_pkt_ll(pkt), net_pkt_ll_reserve(pkt) + pkt->frags->len); for (frag = pkt->frags->frags; frag; frag = frag->frags) { eth_tx_data(context, frag->data, frag->len); } } net_pkt_unref(pkt); return 0; } static void eth_dw_isr(struct device *port) { struct eth_runtime *context = port->driver_data; #ifdef CONFIG_SHARED_IRQ u32_t int_status; int_status = eth_read(context->base_addr, REG_ADDR_STATUS); /* If using with shared IRQ, this function will be called * by the shared IRQ driver. So check here if the interrupt * is coming from the GPIO controller (or somewhere else). */ if ((int_status & STATUS_RX_INT) == 0) { return; } #endif eth_rx(port); /* Acknowledge the interrupt. */ eth_write(context->base_addr, REG_ADDR_STATUS, STATUS_NORMAL_INT | STATUS_RX_INT); } #ifdef CONFIG_PCI static inline int eth_setup(struct device *dev) { struct eth_runtime *context = dev->driver_data; pci_bus_scan_init(); if (!pci_bus_scan(&context->pci_dev)) return 0; #ifdef CONFIG_PCI_ENUMERATION context->base_addr = context->pci_dev.addr; #endif pci_enable_regs(&context->pci_dev); pci_enable_bus_master(&context->pci_dev); pci_show(&context->pci_dev); return 1; } #else #define eth_setup(_unused_) (1) #endif /* CONFIG_PCI */ static int eth_initialize_internal(struct net_if *iface) { struct device *port = net_if_get_device(iface); struct eth_runtime *context = port->driver_data; const struct eth_config *config = port->config->config_info; u32_t base_addr; context->iface = iface; base_addr = context->base_addr; /* Read the MAC address from the device. */ context->mac_addr.words[1] = eth_read(base_addr, REG_ADDR_MACADDR_HI); context->mac_addr.words[0] = eth_read(base_addr, REG_ADDR_MACADDR_LO); net_if_set_link_addr(context->iface, context->mac_addr.bytes, sizeof(context->mac_addr.bytes), NET_LINK_ETHERNET); /* Initialize the frame filter enabling unicast messages */ eth_write(base_addr, REG_ADDR_MAC_FRAME_FILTER, MAC_FILTER_4_PM); /* Initialize receive descriptor. */ context->rx_desc.rdes0 = 0; context->rx_desc.rdes1 = 0; context->rx_desc.buf1_ptr = (u8_t *)context->rx_buf; context->rx_desc.first_desc = 1; context->rx_desc.last_desc = 1; context->rx_desc.own = 1; context->rx_desc.rx_buf1_sz = sizeof(context->rx_buf); context->rx_desc.rx_end_of_ring = 1; /* Install receive descriptor. */ eth_write(base_addr, REG_ADDR_RX_DESC_LIST, (u32_t)&context->rx_desc); /* Initialize transmit descriptor. */ context->tx_desc.tdes0 = 0; context->tx_desc.tdes1 = 0; context->tx_desc.buf1_ptr = NULL; context->tx_desc.tx_buf1_sz = 0; context->tx_desc.first_seg_in_frm = 1; context->tx_desc.last_seg_in_frm = 1; context->tx_desc.tx_end_of_ring = 1; /* Install transmit descriptor. */ eth_write(context->base_addr, REG_ADDR_TX_DESC_LIST, (u32_t)&context->tx_desc); eth_write(base_addr, REG_ADDR_MAC_CONF, /* Set the RMII speed to 100Mbps */ MAC_CONF_14_RMII_100M | /* Enable full-duplex mode */ MAC_CONF_11_DUPLEX | /* Enable transmitter */ MAC_CONF_3_TX_EN | /* Enable receiver */ MAC_CONF_2_RX_EN); eth_write(base_addr, REG_ADDR_INT_ENABLE, INT_ENABLE_NORMAL | /* Enable receive interrupts */ INT_ENABLE_RX); /* Mask all the MMC interrupts */ eth_write(base_addr, REG_MMC_RX_INTR_MASK, MMC_DEFAULT_MASK); eth_write(base_addr, REG_MMC_TX_INTR_MASK, MMC_DEFAULT_MASK); eth_write(base_addr, REG_MMC_RX_IPC_INTR_MASK, MMC_DEFAULT_MASK); eth_write(base_addr, REG_ADDR_DMA_OPERATION, /* Enable receive store-and-forward mode for simplicity. */ OP_MODE_25_RX_STORE_N_FORWARD | /* Enable transmit store-and-forward mode for simplicity. */ OP_MODE_21_TX_STORE_N_FORWARD | /* Place the transmitter state machine in the Running state. */ OP_MODE_13_START_TX | /* Place the receiver state machine in the Running state. */ OP_MODE_1_START_RX); SYS_LOG_INF("Enabled 100M full-duplex mode"); config->config_func(port); return 0; } static void eth_initialize(struct net_if *iface) { int r = eth_initialize_internal(iface); if (r < 0) { SYS_LOG_ERR("Could not initialize ethernet device: %d", r); } } /* Bindings to the plaform */ #if CONFIG_ETH_DW_0 static void eth_config_0_irq(struct device *port) { const struct eth_config *config = port->config->config_info; struct device *shared_irq_dev; #ifdef CONFIG_ETH_DW_0_IRQ_DIRECT ARG_UNUSED(shared_irq_dev); IRQ_CONNECT(ETH_DW_0_IRQ, CONFIG_ETH_DW_0_IRQ_PRI, eth_dw_isr, DEVICE_GET(eth_dw_0), 0); irq_enable(ETH_DW_0_IRQ); #elif defined(CONFIG_ETH_DW_0_IRQ_SHARED) shared_irq_dev = device_get_binding(config->shared_irq_dev_name); __ASSERT(shared_irq_dev != NULL, "Failed to get eth_dw device binding"); shared_irq_isr_register(shared_irq_dev, (isr_t)eth_dw_isr, port); shared_irq_enable(shared_irq_dev, port); #endif } static const struct eth_config eth_config_0 = { #ifdef CONFIG_ETH_DW_0_IRQ_DIRECT .irq_num = ETH_DW_0_IRQ, #endif .config_func = eth_config_0_irq, #ifdef CONFIG_ETH_DW_0_IRQ_SHARED .shared_irq_dev_name = CONFIG_ETH_DW_0_IRQ_SHARED_NAME, #endif }; static struct eth_runtime eth_0_runtime = { .base_addr = ETH_DW_0_BASE_ADDR, #if CONFIG_PCI .pci_dev.class_type = ETH_DW_PCI_CLASS, .pci_dev.bus = ETH_DW_0_PCI_BUS, .pci_dev.dev = ETH_DW_0_PCI_DEV, .pci_dev.vendor_id = ETH_DW_PCI_VENDOR_ID, .pci_dev.device_id = ETH_DW_PCI_DEVICE_ID, .pci_dev.function = ETH_DW_0_PCI_FUNCTION, .pci_dev.bar = ETH_DW_0_PCI_BAR, #endif }; static struct net_if_api api_funcs = { .init = eth_initialize, .send = eth_tx, }; NET_DEVICE_INIT(eth_dw_0, CONFIG_ETH_DW_0_NAME, eth_setup, ð_0_runtime, ð_config_0, CONFIG_ETH_INIT_PRIORITY, &api_funcs, ETHERNET_L2, NET_L2_GET_CTX_TYPE(ETHERNET_L2), ETH_DW_MTU); #endif /* CONFIG_ETH_DW_0 */