lab 3
arch/TARGET_Freescale/k64f_emac.c
- Committer:
- mbed_official
- Date:
- 2015-06-15
- Revision:
- 27:fde88aaaea28
- Parent:
- 21:10cdd9fe0509
- Child:
- 31:da93f0f73711
File content as of revision 27:fde88aaaea28:
#include "lwip/opt.h" #include "lwip/sys.h" #include "lwip/def.h" #include "lwip/mem.h" #include "lwip/pbuf.h" #include "lwip/stats.h" #include "lwip/snmp.h" #include "lwip/tcpip.h" #include "netif/etharp.h" #include "netif/ppp_oe.h" #include "eth_arch.h" #include "sys_arch.h" #include "fsl_enet_driver.h" #include "fsl_enet_hal.h" #include "fsl_device_registers.h" #include "fsl_phy_driver.h" #include "fsl_interrupt_manager.h" #include "k64f_emac_config.h" #include <ctype.h> #include <stdio.h> #include <string.h> #include <stdlib.h> #include "mbed_interface.h" extern IRQn_Type enet_irq_ids[HW_ENET_INSTANCE_COUNT][FSL_FEATURE_ENET_INTERRUPT_COUNT]; extern uint8_t enetIntMap[kEnetIntNum]; extern void *enetIfHandle; /******************************************************************************** * Internal data ********************************************************************************/ extern void k64f_init_eth_hardware(void); /* K64F EMAC driver data structure */ struct k64f_enetdata { struct netif *netif; /**< Reference back to LWIP parent netif */ sys_sem_t RxReadySem; /**< RX packet ready semaphore */ sys_sem_t TxCleanSem; /**< TX cleanup thread wakeup semaphore */ sys_mutex_t TXLockMutex; /**< TX critical section mutex */ sys_sem_t xTXDCountSem; /**< TX free buffer counting semaphore */ volatile u32_t rx_free_descs; /**< Count of free RX descriptors */ struct pbuf *rxb[ENET_RX_RING_LEN]; /**< RX pbuf pointer list, zero-copy mode */ uint8_t *rx_desc_start_addr; /**< RX descriptor start address */ uint8_t *tx_desc_start_addr; /**< TX descriptor start address */ uint8_t tx_consume_index, tx_produce_index; /**< TX buffers ring */ uint8_t rx_fill_index; /**< RX ring fill index */ struct pbuf *txb[ENET_TX_RING_LEN]; /**< TX pbuf pointer list, zero-copy mode */ void *txb_aligned[ENET_TX_RING_LEN]; /**< TX aligned buffers (if needed) */ }; static struct k64f_enetdata k64f_enetdata; static enet_dev_if_t enetDevIf[HW_ENET_INSTANCE_COUNT]; static enet_mac_config_t g_enetMacCfg[HW_ENET_INSTANCE_COUNT] = { { ENET_ETH_MAX_FLEN , /*!< enet receive buffer size*/ ENET_RX_LARGE_BUFFER_NUM, /*!< enet large receive buffer number*/ ENET_RX_RING_LEN, /*!< enet receive bd number*/ ENET_TX_RING_LEN, /*!< enet transmit bd number*/ {0}, /*!< enet mac address*/ kEnetCfgRmii, /*!< enet rmii interface*/ kEnetCfgSpeed100M, /*!< enet rmii 100M*/ kEnetCfgFullDuplex, /*!< enet rmii Full- duplex*/ /*!< enet mac control flag recommended to use enet_mac_control_flag_t we send frame with crc so receive crc forward for data length check test*/ kEnetRxCrcFwdEnable | kEnetRxFlowControlEnable, true, /*!< enet txaccelerator enabled*/ true, /*!< enet rxaccelerator enabled*/ false, /*!< enet store and forward*/ {false, false, true, false, true}, /*!< enet rxaccelerator config*/ {false, false, true}, /*!< enet txaccelerator config*/ true, /*!< vlan frame support*/ true, /*!< phy auto discover*/ ENET_MII_CLOCK, /*!< enet MDC clock*/ }, }; static enet_phy_config_t g_enetPhyCfg[HW_ENET_INSTANCE_COUNT] = { {0, false} }; /** \brief Driver transmit and receive thread priorities * * Thread priorities for receive thread and TX cleanup thread. Alter * to prioritize receive or transmit bandwidth. In a heavily loaded * system or with LEIP_DEBUG enabled, the priorities might be better * the same. */ #define RX_PRIORITY (osPriorityNormal) #define TX_PRIORITY (osPriorityNormal) #define PHY_PRIORITY (osPriorityNormal) /** \brief Debug output formatter lock define * * When using FreeRTOS and with LWIP_DEBUG enabled, enabling this * define will allow RX debug messages to not interleave with the * TX messages (so they are actually readable). Not enabling this * define when the system is under load will cause the output to * be unreadable. There is a small tradeoff in performance for this * so use it only for debug. */ //#define LOCK_RX_THREAD /** \brief Signal used for ethernet ISR to signal packet_rx() thread. */ #define RX_SIGNAL 1 // K64F-specific macros #define RX_PBUF_AUTO_INDEX (-1) /******************************************************************************** * Buffer management ********************************************************************************/ /** \brief Queues a pbuf into the RX descriptor list * * \param[in] k64f_enet Pointer to the drvier data structure * \param[in] p Pointer to pbuf to queue * \param[in] bidx Index to queue into */ static void k64f_rxqueue_pbuf(struct k64f_enetdata *k64f_enet, struct pbuf *p, int bidx) { enet_bd_struct_t *start = (enet_bd_struct_t *)k64f_enet->rx_desc_start_addr; int idx; /* Get next free descriptor index */ if (bidx == RX_PBUF_AUTO_INDEX) idx = k64f_enet->rx_fill_index; else idx = bidx; /* Setup descriptor and clear statuses */ enet_hal_init_rxbds(start + idx, (uint8_t*)p->payload, idx == ENET_RX_RING_LEN - 1); /* Save pbuf pointer for push to network layer later */ k64f_enet->rxb[idx] = p; /* Wrap at end of descriptor list */ idx = (idx + 1) % ENET_RX_RING_LEN; /* Queue descriptor(s) */ k64f_enet->rx_free_descs -= 1; if (bidx == RX_PBUF_AUTO_INDEX) k64f_enet->rx_fill_index = idx; enet_hal_active_rxbd(BOARD_DEBUG_ENET_INSTANCE_ADDR); LWIP_DEBUGF(UDP_LPC_EMAC | LWIP_DBG_TRACE, ("k64f_rxqueue_pbuf: pbuf packet queued: %p (free desc=%d)\n", p, k64f_enet->rx_free_descs)); } /** \brief Attempt to allocate and requeue a new pbuf for RX * * \param[in] netif Pointer to the netif structure * \returns number of queued packets */ s32_t k64f_rx_queue(struct netif *netif, int idx) { struct k64f_enetdata *k64f_enet = netif->state; enet_dev_if_t *enetIfPtr = (enet_dev_if_t *)&enetDevIf[BOARD_DEBUG_ENET_INSTANCE]; struct pbuf *p; int queued = 0; /* Attempt to requeue as many packets as possible */ while (k64f_enet->rx_free_descs > 0) { /* Allocate a pbuf from the pool. We need to allocate at the maximum size as we don't know the size of the yet to be received packet. */ p = pbuf_alloc(PBUF_RAW, enetIfPtr->macCfgPtr->rxBufferSize + RX_BUF_ALIGNMENT, PBUF_RAM); if (p == NULL) { LWIP_DEBUGF(UDP_LPC_EMAC | LWIP_DBG_TRACE, ("k64_rx_queue: could not allocate RX pbuf (free desc=%d)\n", k64f_enet->rx_free_descs)); return queued; } /* K64F note: the next line ensures that the RX buffer is properly aligned for the K64F RX descriptors (16 bytes alignment). However, by doing so, we're effectively changing a data structure which is internal to lwIP. This might not prove to be a good idea in the long run, but a better fix would probably involve modifying lwIP itself */ p->payload = (void*)ENET_ALIGN((uint32_t)p->payload, RX_BUF_ALIGNMENT); /* pbufs allocated from the RAM pool should be non-chained. */ LWIP_ASSERT("k64f_rx_queue: pbuf is not contiguous (chained)", pbuf_clen(p) <= 1); /* Queue packet */ k64f_rxqueue_pbuf(k64f_enet, p, idx); queued++; } return queued; } /** \brief Sets up the RX descriptor ring buffers. * * This function sets up the descriptor list used for receive packets. * * \param[in] netif Pointer to driver data structure * \returns ERR_MEM if out of memory, ERR_OK otherwise */ static err_t k64f_rx_setup(struct netif *netif, enet_rxbd_config_t *rxbdCfg) { struct k64f_enetdata *k64f_enet = netif->state; enet_dev_if_t *enetIfPtr = (enet_dev_if_t *)&enetDevIf[BOARD_DEBUG_ENET_INSTANCE]; uint8_t *rxBdPtr; uint32_t rxBufferSizeAligned; // Allocate RX descriptors rxBdPtr = (uint8_t *)calloc(1, enet_hal_get_bd_size() * enetIfPtr->macCfgPtr->rxBdNumber + ENET_BD_ALIGNMENT); if(!rxBdPtr) return ERR_MEM; k64f_enet->rx_desc_start_addr = (uint8_t *)ENET_ALIGN((uint32_t)rxBdPtr, ENET_BD_ALIGNMENT); k64f_enet->rx_free_descs = enetIfPtr->macCfgPtr->rxBdNumber; k64f_enet->rx_fill_index = 0; rxBufferSizeAligned = ENET_ALIGN(enetIfPtr->macCfgPtr->rxBufferSize, ENET_RX_BUFFER_ALIGNMENT); enetIfPtr->macContextPtr->rxBufferSizeAligned = rxBufferSizeAligned; rxbdCfg->rxBdPtrAlign = k64f_enet->rx_desc_start_addr; rxbdCfg->rxBdNum = enetIfPtr->macCfgPtr->rxBdNumber; rxbdCfg->rxBufferNum = enetIfPtr->macCfgPtr->rxBdNumber; k64f_rx_queue(netif, RX_PBUF_AUTO_INDEX); return ERR_OK; } /** \brief Sets up the TX descriptor ring buffers. * * This function sets up the descriptor list used for transmit packets. * * \param[in] netif Pointer to driver data structure * \returns ERR_MEM if out of memory, ERR_OK otherwise */ static err_t k64f_tx_setup(struct netif *netif, enet_txbd_config_t *txbdCfg) { struct k64f_enetdata *k64f_enet = netif->state; enet_dev_if_t *enetIfPtr = (enet_dev_if_t *)&enetDevIf[BOARD_DEBUG_ENET_INSTANCE]; uint8_t *txBdPtr; // Allocate TX descriptors txBdPtr = (uint8_t *)calloc(1, enet_hal_get_bd_size() * enetIfPtr->macCfgPtr->txBdNumber + ENET_BD_ALIGNMENT); if(!txBdPtr) return ERR_MEM; k64f_enet->tx_desc_start_addr = (uint8_t *)ENET_ALIGN((uint32_t)txBdPtr, ENET_BD_ALIGNMENT); k64f_enet->tx_consume_index = k64f_enet->tx_produce_index = 0; txbdCfg->txBdPtrAlign = k64f_enet->tx_desc_start_addr; txbdCfg->txBufferNum = enetIfPtr->macCfgPtr->txBdNumber; txbdCfg->txBufferSizeAlign = ENET_ALIGN(enetIfPtr->maxFrameSize, ENET_TX_BUFFER_ALIGNMENT); // Make the TX descriptor ring circular enet_hal_init_txbds(k64f_enet->tx_desc_start_addr + enet_hal_get_bd_size() * (ENET_TX_RING_LEN - 1), 1); return ERR_OK; } /** \brief Free TX buffers that are complete * * \param[in] k64f_enet Pointer to driver data structure */ static void k64f_tx_reclaim(struct k64f_enetdata *k64f_enet) { uint8_t i; volatile enet_bd_struct_t * bdPtr = (enet_bd_struct_t *)k64f_enet->tx_desc_start_addr; /* Get exclusive access */ sys_mutex_lock(&k64f_enet->TXLockMutex); // Traverse all descriptors, looking for the ones modified by the uDMA i = k64f_enet->tx_consume_index; while(i != k64f_enet->tx_produce_index && !(bdPtr[i].control & kEnetTxBdReady)) { if (k64f_enet->txb_aligned[i]) { free(k64f_enet->txb_aligned[i]); k64f_enet->txb_aligned[i] = NULL; } else if (k64f_enet->txb[i]) { pbuf_free(k64f_enet->txb[i]); k64f_enet->txb[i] = NULL; } osSemaphoreRelease(k64f_enet->xTXDCountSem.id); bdPtr[i].controlExtend2 &= ~TX_DESC_UPDATED_MASK; i = (i + 1) % ENET_TX_RING_LEN; } k64f_enet->tx_consume_index = i; /* Restore access */ sys_mutex_unlock(&k64f_enet->TXLockMutex); } /** \brief Low level init of the MAC and PHY. * * \param[in] netif Pointer to LWIP netif structure */ static err_t low_level_init(struct netif *netif) { enet_dev_if_t * enetIfPtr; uint32_t device = BOARD_DEBUG_ENET_INSTANCE_ADDR; enet_rxbd_config_t rxbdCfg; enet_txbd_config_t txbdCfg; enet_phy_speed_t phy_speed; enet_phy_duplex_t phy_duplex; k64f_init_eth_hardware(); /* Initialize device*/ enetIfPtr = (enet_dev_if_t *)&enetDevIf[BOARD_DEBUG_ENET_INSTANCE]; enetIfPtr->deviceNumber = device; enetIfPtr->macCfgPtr = &g_enetMacCfg[BOARD_DEBUG_ENET_INSTANCE]; enetIfPtr->phyCfgPtr = &g_enetPhyCfg[BOARD_DEBUG_ENET_INSTANCE]; enetIfPtr->macApiPtr = &g_enetMacApi; enetIfPtr->phyApiPtr = (void *)&g_enetPhyApi; memcpy(enetIfPtr->macCfgPtr->macAddr, (char*)netif->hwaddr, kEnetMacAddrLen); /* Allocate buffer for ENET mac context*/ enetIfPtr->macContextPtr = (enet_mac_context_t *)calloc(1, sizeof(enet_mac_context_t)); if (!enetIfPtr->macContextPtr) { return ERR_BUF; } /* Initialize enet buffers*/ if(k64f_rx_setup(netif, &rxbdCfg) != ERR_OK) { return ERR_BUF; } /* Initialize enet buffers*/ if(k64f_tx_setup(netif, &txbdCfg) != ERR_OK) { return ERR_BUF; } /* Initialize enet module*/ if (enet_mac_init(enetIfPtr, &rxbdCfg, &txbdCfg) == kStatus_ENET_Success) { /* Initialize PHY*/ if (enetIfPtr->macCfgPtr->isPhyAutoDiscover) { if (((enet_phy_api_t *)(enetIfPtr->phyApiPtr))->phy_auto_discover(enetIfPtr) != kStatus_PHY_Success) return ERR_IF; } if (((enet_phy_api_t *)(enetIfPtr->phyApiPtr))->phy_init(enetIfPtr) != kStatus_PHY_Success) return ERR_IF; enetIfPtr->isInitialized = true; } else { // TODOETH: cleanup memory return ERR_IF; } /* Get link information from PHY */ phy_get_link_speed(enetIfPtr, &phy_speed); phy_get_link_duplex(enetIfPtr, &phy_duplex); BW_ENET_RCR_RMII_10T(enetIfPtr->deviceNumber, phy_speed == kEnetSpeed10M ? kEnetCfgSpeed10M : kEnetCfgSpeed100M); BW_ENET_TCR_FDEN(enetIfPtr->deviceNumber, phy_duplex == kEnetFullDuplex ? kEnetCfgFullDuplex : kEnetCfgHalfDuplex); /* Enable Ethernet module*/ enet_hal_config_ethernet(BOARD_DEBUG_ENET_INSTANCE_ADDR, true, true); /* Active Receive buffer descriptor must be done after module enable*/ enet_hal_active_rxbd(enetIfPtr->deviceNumber); return ERR_OK; } /******************************************************************************** * LWIP port ********************************************************************************/ /** \brief Ethernet receive interrupt handler * * This function handles the receive interrupt of K64F. */ void enet_mac_rx_isr(void *enetIfPtr) { /* Clear interrupt */ enet_hal_clear_interrupt(((enet_dev_if_t *)enetIfPtr)->deviceNumber, kEnetRxFrameInterrupt); sys_sem_signal(&k64f_enetdata.RxReadySem); } void enet_mac_tx_isr(void *enetIfPtr) { /*Clear interrupt*/ enet_hal_clear_interrupt(((enet_dev_if_t *)enetIfPtr)->deviceNumber, kEnetTxFrameInterrupt); sys_sem_signal(&k64f_enetdata.TxCleanSem); } /** * This function is the ethernet packet send function. It calls * etharp_output after checking link status. * * \param[in] netif the lwip network interface structure for this enetif * \param[in] q Pointer to pbug to send * \param[in] ipaddr IP address * \return ERR_OK or error code */ err_t k64f_etharp_output(struct netif *netif, struct pbuf *q, ip_addr_t *ipaddr) { /* Only send packet is link is up */ if (netif->flags & NETIF_FLAG_LINK_UP) return etharp_output(netif, q, ipaddr); return ERR_CONN; } /** \brief Allocates a pbuf and returns the data from the incoming packet. * * \param[in] netif the lwip network interface structure * \param[in] idx index of packet to be read * \return a pbuf filled with the received packet (including MAC header) */ static struct pbuf *k64f_low_level_input(struct netif *netif, int idx) { struct k64f_enetdata *k64f_enet = netif->state; enet_bd_struct_t * bdPtr = (enet_bd_struct_t*)k64f_enet->rx_desc_start_addr; struct pbuf *p = NULL; u32_t length = 0, orig_length; const u16_t err_mask = kEnetRxBdTrunc | kEnetRxBdCrc | kEnetRxBdNoOctet | kEnetRxBdLengthViolation; #ifdef LOCK_RX_THREAD /* Get exclusive access */ sys_mutex_lock(&k64f_enet->TXLockMutex); #endif /* Determine if a frame has been received */ if ((bdPtr[idx].control & err_mask) != 0) { #if LINK_STATS if ((bdPtr[idx].control & kEnetRxBdLengthViolation) != 0) LINK_STATS_INC(link.lenerr); else LINK_STATS_INC(link.chkerr); #endif LINK_STATS_INC(link.drop); /* Re-queue the same buffer */ k64f_enet->rx_free_descs++; p = k64f_enet->rxb[idx]; k64f_enet->rxb[idx] = NULL; k64f_rxqueue_pbuf(k64f_enet, p, idx); p = NULL; } else { /* A packet is waiting, get length */ length = enet_hal_get_bd_length(bdPtr + idx); /* Zero-copy */ p = k64f_enet->rxb[idx]; orig_length = p->len; p->len = (u16_t) length; /* Free pbuf from descriptor */ k64f_enet->rxb[idx] = NULL; k64f_enet->rx_free_descs++; /* Attempt to queue new buffer */ if (k64f_rx_queue(netif, idx) == 0) { /* Drop frame (out of memory) */ LINK_STATS_INC(link.drop); /* Re-queue the same buffer */ p->len = orig_length; k64f_rxqueue_pbuf(k64f_enet, p, idx); LWIP_DEBUGF(UDP_LPC_EMAC | LWIP_DBG_TRACE, ("k64f_low_level_input: Packet index %d dropped for OOM\n", idx)); #ifdef LOCK_RX_THREAD sys_mutex_unlock(&k64f_enet->TXLockMutex); #endif return NULL; } LWIP_DEBUGF(UDP_LPC_EMAC | LWIP_DBG_TRACE, ("k64f_low_level_input: Packet received: %p, size %d (index=%d)\n", p, length, idx)); /* Save size */ p->tot_len = (u16_t) length; LINK_STATS_INC(link.recv); } #ifdef LOCK_RX_THREAD sys_mutex_unlock(&k64f_enet->TXLockMutex); #endif return p; } /** \brief Attempt to read a packet from the EMAC interface. * * \param[in] netif the lwip network interface structure * \param[in] idx index of packet to be read */ void k64f_enetif_input(struct netif *netif, int idx) { struct eth_hdr *ethhdr; struct pbuf *p; /* move received packet into a new pbuf */ p = k64f_low_level_input(netif, idx); if (p == NULL) return; /* points to packet payload, which starts with an Ethernet header */ ethhdr = (struct eth_hdr*)p->payload; switch (htons(ethhdr->type)) { case ETHTYPE_IP: case ETHTYPE_ARP: #if PPPOE_SUPPORT case ETHTYPE_PPPOEDISC: case ETHTYPE_PPPOE: #endif /* PPPOE_SUPPORT */ /* full packet send to tcpip_thread to process */ if (netif->input(p, netif) != ERR_OK) { LWIP_DEBUGF(NETIF_DEBUG, ("k64f_enetif_input: IP input error\n")); /* Free buffer */ pbuf_free(p); } break; default: /* Return buffer */ pbuf_free(p); break; } } /** \brief Packet reception task * * This task is called when a packet is received. It will * pass the packet to the LWIP core. * * \param[in] pvParameters pointer to the interface data */ static void packet_rx(void* pvParameters) { struct k64f_enetdata *k64f_enet = pvParameters; volatile enet_bd_struct_t * bdPtr = (enet_bd_struct_t*)k64f_enet->rx_desc_start_addr; int idx = 0; while (1) { /* Wait for receive task to wakeup */ sys_arch_sem_wait(&k64f_enet->RxReadySem, 0); while ((bdPtr[idx].control & kEnetRxBdEmpty) == 0) { k64f_enetif_input(k64f_enet->netif, idx); idx = (idx + 1) % ENET_RX_RING_LEN; } } } /** \brief Transmit cleanup task * * This task is called when a transmit interrupt occurs and * reclaims the pbuf and descriptor used for the packet once * the packet has been transferred. * * \param[in] pvParameters pointer to the interface data */ static void packet_tx(void* pvParameters) { struct k64f_enetdata *k64f_enet = pvParameters; while (1) { /* Wait for transmit cleanup task to wakeup */ sys_arch_sem_wait(&k64f_enet->TxCleanSem, 0); // TODOETH: handle TX underrun? k64f_tx_reclaim(k64f_enet); } } /** \brief Polls if an available TX descriptor is ready. Can be used to * determine if the low level transmit function will block. * * \param[in] netif the lwip network interface structure * \return 0 if no descriptors are read, or >0 */ s32_t k64f_tx_ready(struct netif *netif) { struct k64f_enetdata *k64f_enet = netif->state; s32_t fb; u32_t idx, cidx; cidx = k64f_enet->tx_consume_index; idx = k64f_enet->tx_produce_index; /* Determine number of free buffers */ if (idx == cidx) fb = ENET_TX_RING_LEN; else if (cidx > idx) fb = (ENET_TX_RING_LEN - 1) - ((idx + ENET_TX_RING_LEN) - cidx); else fb = (ENET_TX_RING_LEN - 1) - (cidx - idx); return fb; } /*FUNCTION**************************************************************** * * Function Name: enet_hal_update_txbds * Description: Update ENET transmit buffer descriptors. *END*********************************************************************/ void k64f_update_txbds(struct k64f_enetdata *k64f_enet, int idx, uint8_t *buffer, uint16_t length, bool isLast) { volatile enet_bd_struct_t * bdPtr = (enet_bd_struct_t *)(k64f_enet->tx_desc_start_addr + idx * enet_hal_get_bd_size()); bdPtr->length = HTONS(length); /* Set data length*/ bdPtr->buffer = (uint8_t *)HTONL((uint32_t)buffer); /* Set data buffer*/ if (isLast) bdPtr->control |= kEnetTxBdLast; else bdPtr->control &= ~kEnetTxBdLast; bdPtr->controlExtend1 |= kEnetTxBdTxInterrupt; bdPtr->controlExtend2 &= ~TX_DESC_UPDATED_MASK; // descriptor not updated by DMA bdPtr->control |= kEnetTxBdTransmitCrc | kEnetTxBdReady; } /** \brief Low level output of a packet. Never call this from an * interrupt context, as it may block until TX descriptors * become available. * * \param[in] netif the lwip network interface structure for this netif * \param[in] p the MAC packet to send (e.g. IP packet including MAC addresses and type) * \return ERR_OK if the packet could be sent or an err_t value if the packet couldn't be sent */ static err_t k64f_low_level_output(struct netif *netif, struct pbuf *p) { struct k64f_enetdata *k64f_enet = netif->state; struct pbuf *q; u32_t idx; s32_t dn; uint8_t *psend = NULL, *dst; /* Get free TX buffer index */ idx = k64f_enet->tx_produce_index; /* Check the pbuf chain for payloads that are not 8-byte aligned. If found, a new properly aligned buffer needs to be allocated and the data copied there */ for (q = p; q != NULL; q = q->next) if (((u32_t)q->payload & (TX_BUF_ALIGNMENT - 1)) != 0) break; if (q != NULL) { // Allocate properly aligned buffer psend = (uint8_t*)malloc(p->tot_len); if (NULL == psend) return ERR_MEM; LWIP_ASSERT("k64f_low_level_output: buffer not properly aligned", ((u32_t)psend & (TX_BUF_ALIGNMENT - 1)) == 0); for (q = p, dst = psend; q != NULL; q = q->next) { MEMCPY(dst, q->payload, q->len); dst += q->len; } k64f_enet->txb_aligned[idx] = psend; dn = 1; } else { k64f_enet->txb_aligned[idx] = NULL; dn = (s32_t) pbuf_clen(p); pbuf_ref(p); } /* Wait until enough descriptors are available for the transfer. */ /* THIS WILL BLOCK UNTIL THERE ARE ENOUGH DESCRIPTORS AVAILABLE */ while (dn > k64f_tx_ready(netif)) osSemaphoreWait(k64f_enet->xTXDCountSem.id, osWaitForever); /* Get exclusive access */ sys_mutex_lock(&k64f_enet->TXLockMutex); /* Setup transfers */ q = p; while (dn > 0) { dn--; if (psend != NULL) { k64f_update_txbds(k64f_enet, idx, psend, p->tot_len, 1); k64f_enet->txb[idx] = NULL; LWIP_DEBUGF(UDP_LPC_EMAC | LWIP_DBG_TRACE, ("k64f_low_level_output: aligned packet(%p) sent" " size = %d (index=%d)\n", psend, p->tot_len, idx)); } else { LWIP_ASSERT("k64f_low_level_output: buffer not properly aligned", ((u32_t)q->payload & 0x07) == 0); /* Only save pointer to free on last descriptor */ if (dn == 0) { /* Save size of packet and signal it's ready */ k64f_update_txbds(k64f_enet, idx, q->payload, q->len, 1); k64f_enet->txb[idx] = p; } else { /* Save size of packet, descriptor is not last */ k64f_update_txbds(k64f_enet, idx, q->payload, q->len, 0); k64f_enet->txb[idx] = NULL; } LWIP_DEBUGF(UDP_LPC_EMAC | LWIP_DBG_TRACE, ("k64f_low_level_output: pbuf packet(%p) sent, chain#=%d," " size = %d (index=%d)\n", q->payload, dn, q->len, idx)); } q = q->next; idx = (idx + 1) % ENET_TX_RING_LEN; } k64f_enet->tx_produce_index = idx; enet_hal_active_txbd(BOARD_DEBUG_ENET_INSTANCE_ADDR); LINK_STATS_INC(link.xmit); /* Restore access */ sys_mutex_unlock(&k64f_enet->TXLockMutex); return ERR_OK; } /******************************************************************************* * PHY task: monitor link *******************************************************************************/ #define PHY_TASK_PERIOD_MS 200 #define STATE_UNKNOWN (-1) typedef struct { int connected; enet_phy_speed_t speed; enet_phy_duplex_t duplex; } PHY_STATE; int phy_link_status() { bool connection_status; enet_dev_if_t * enetIfPtr = (enet_dev_if_t*)&enetDevIf[BOARD_DEBUG_ENET_INSTANCE]; phy_get_link_status(enetIfPtr, &connection_status); return (int)connection_status; } static void k64f_phy_task(void *data) { struct netif *netif = (struct netif*)data; bool connection_status; enet_dev_if_t * enetIfPtr = (enet_dev_if_t*)&enetDevIf[BOARD_DEBUG_ENET_INSTANCE]; PHY_STATE crt_state = {STATE_UNKNOWN, (enet_phy_speed_t)STATE_UNKNOWN, (enet_phy_duplex_t)STATE_UNKNOWN}; PHY_STATE prev_state; prev_state = crt_state; while (true) { // Get current status phy_get_link_status(enetIfPtr, &connection_status); crt_state.connected = connection_status ? 1 : 0; phy_get_link_speed(enetIfPtr, &crt_state.speed); phy_get_link_duplex(enetIfPtr, &crt_state.duplex); // Compare with previous state if (crt_state.connected != prev_state.connected) { if (crt_state.connected) tcpip_callback_with_block((tcpip_callback_fn)netif_set_link_up, (void*) netif, 1); else tcpip_callback_with_block((tcpip_callback_fn)netif_set_link_down, (void*) netif, 1); } if (crt_state.speed != prev_state.speed) BW_ENET_RCR_RMII_10T(enetIfPtr->deviceNumber, crt_state.speed == kEnetSpeed10M ? kEnetCfgSpeed10M : kEnetCfgSpeed100M); // TODO: duplex change requires disable/enable of Ethernet interface, to be implemented prev_state = crt_state; osDelay(PHY_TASK_PERIOD_MS); } } /** * Should be called at the beginning of the program to set up the * network interface. * * This function should be passed as a parameter to netif_add(). * * @param[in] netif the lwip network interface structure for this netif * @return ERR_OK if the loopif is initialized * ERR_MEM if private data couldn't be allocated * any other err_t on error */ err_t eth_arch_enetif_init(struct netif *netif) { err_t err; LWIP_ASSERT("netif != NULL", (netif != NULL)); k64f_enetdata.netif = netif; /* set MAC hardware address */ #if (MBED_MAC_ADDRESS_SUM != MBED_MAC_ADDR_INTERFACE) netif->hwaddr[0] = MBED_MAC_ADDR_0; netif->hwaddr[1] = MBED_MAC_ADDR_1; netif->hwaddr[2] = MBED_MAC_ADDR_2; netif->hwaddr[3] = MBED_MAC_ADDR_3; netif->hwaddr[4] = MBED_MAC_ADDR_4; netif->hwaddr[5] = MBED_MAC_ADDR_5; #else mbed_mac_address((char *)netif->hwaddr); #endif netif->hwaddr_len = ETHARP_HWADDR_LEN; /* maximum transfer unit */ netif->mtu = 1500; /* device capabilities */ // TODOETH: check if the flags are correct below netif->flags = NETIF_FLAG_BROADCAST | NETIF_FLAG_ETHARP | NETIF_FLAG_ETHERNET | NETIF_FLAG_IGMP; /* Initialize the hardware */ netif->state = &k64f_enetdata; err = low_level_init(netif); if (err != ERR_OK) return err; #if LWIP_NETIF_HOSTNAME /* Initialize interface hostname */ netif->hostname = "lwipk64f"; #endif /* LWIP_NETIF_HOSTNAME */ netif->name[0] = 'e'; netif->name[1] = 'n'; netif->output = k64f_etharp_output; netif->linkoutput = k64f_low_level_output; /* CMSIS-RTOS, start tasks */ #ifdef CMSIS_OS_RTX memset(k64f_enetdata.xTXDCountSem.data, 0, sizeof(k64f_enetdata.xTXDCountSem.data)); k64f_enetdata.xTXDCountSem.def.semaphore = k64f_enetdata.xTXDCountSem.data; #endif k64f_enetdata.xTXDCountSem.id = osSemaphoreCreate(&k64f_enetdata.xTXDCountSem.def, ENET_TX_RING_LEN); LWIP_ASSERT("xTXDCountSem creation error", (k64f_enetdata.xTXDCountSem.id != NULL)); err = sys_mutex_new(&k64f_enetdata.TXLockMutex); LWIP_ASSERT("TXLockMutex creation error", (err == ERR_OK)); /* Packet receive task */ err = sys_sem_new(&k64f_enetdata.RxReadySem, 0); LWIP_ASSERT("RxReadySem creation error", (err == ERR_OK)); sys_thread_new("receive_thread", packet_rx, netif->state, DEFAULT_THREAD_STACKSIZE, RX_PRIORITY); /* Transmit cleanup task */ err = sys_sem_new(&k64f_enetdata.TxCleanSem, 0); LWIP_ASSERT("TxCleanSem creation error", (err == ERR_OK)); sys_thread_new("txclean_thread", packet_tx, netif->state, DEFAULT_THREAD_STACKSIZE, TX_PRIORITY); /* PHY monitoring task */ sys_thread_new("phy_thread", k64f_phy_task, netif, DEFAULT_THREAD_STACKSIZE, PHY_PRIORITY); /* Allow the PHY task to detect the initial link state and set up the proper flags */ osDelay(10); return ERR_OK; } void eth_arch_enable_interrupts(void) { enet_hal_config_interrupt(BOARD_DEBUG_ENET_INSTANCE_ADDR, (kEnetTxFrameInterrupt | kEnetRxFrameInterrupt), true); INT_SYS_EnableIRQ(enet_irq_ids[BOARD_DEBUG_ENET_INSTANCE][enetIntMap[kEnetRxfInt]]); INT_SYS_EnableIRQ(enet_irq_ids[BOARD_DEBUG_ENET_INSTANCE][enetIntMap[kEnetTxfInt]]); } void eth_arch_disable_interrupts(void) { INT_SYS_DisableIRQ(enet_irq_ids[BOARD_DEBUG_ENET_INSTANCE][enetIntMap[kEnetRxfInt]]); INT_SYS_DisableIRQ(enet_irq_ids[BOARD_DEBUG_ENET_INSTANCE][enetIntMap[kEnetTxfInt]]); } void ENET_Transmit_IRQHandler(void) { enet_mac_tx_isr(enetIfHandle); } void ENET_Receive_IRQHandler(void) { enet_mac_rx_isr(enetIfHandle); } #if FSL_FEATURE_ENET_SUPPORT_PTP void ENET_1588_Timer_IRQHandler(void) { enet_mac_ts_isr(enetIfHandle); } #endif /** * @} */ /* --------------------------------- End Of File ------------------------------ */