/**************************************************************************** * drivers/net/enc28j60.c * * Copyright (C) 2010-2012, 2014-2017 Gregory Nutt. All rights reserved. * Author: Gregory Nutt * * References: * - ENC28J60 Data Sheet, Stand-Alone Ethernet Controller with SPI Interface, * DS39662C, 2008 Microchip Technology Inc. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in * the documentation and/or other materials provided with the * distribution. * 3. Neither the name NuttX nor the names of its contributors may be * used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE * COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS * OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN * ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. * ****************************************************************************/ /**************************************************************************** * Included Files ****************************************************************************/ #include #if defined(CONFIG_NET) && defined(CONFIG_ENC28J60) #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef CONFIG_NET_PKT # include #endif #include "enc28j60.h" /**************************************************************************** * Pre-processor Definitions ****************************************************************************/ /* Configuration ************************************************************/ /* ENC28J60 Configuration Settings: * * CONFIG_ENC28J60 - Enabled ENC28J60 support * CONFIG_ENC28J60_SPIMODE - Controls the SPI mode * CONFIG_ENC28J60_FREQUENCY - Define to use a different bus frequency * CONFIG_ENC28J60_NINTERFACES - Specifies the number of physical ENC28J60 * devices that will be supported. * CONFIG_ENC28J60_HALFDUPPLEX - Default is full duplex */ /* The ENC28J60 spec says that it supports SPI mode 0,0 only: "The * implementation used on this device supports SPI mode 0,0 only. In * addition, the SPI port requires that SCK be at Idle in a low state; * selectable clock polarity is not supported." However, sometimes you * need to tinker with these things. */ #ifndef CONFIG_ENC28J60_SPIMODE # define CONFIG_ENC28J60_SPIMODE SPIDEV_MODE0 #endif /* CONFIG_ENC28J60_NINTERFACES determines the number of physical interfaces * that will be supported. */ #ifndef CONFIG_ENC28J60_NINTERFACES # define CONFIG_ENC28J60_NINTERFACES 1 #endif /* CONFIG_NET_ETH_MTU must always be defined */ #if !defined(CONFIG_NET_ETH_MTU) && (CONFIG_NET_ETH_MTU <= MAX_FRAMELEN) # error "CONFIG_NET_ETH_MTU is not valid for the ENC28J60" #endif /* We need to have the work queue to handle SPI interrupts */ #if !defined(CONFIG_SCHED_WORKQUEUE) # error "Worker thread support is required (CONFIG_SCHED_WORKQUEUE)" #else # if defined(CONFIG_ENC28J60_HPWORK) # define ENCWORK HPWORK # elif defined(CONFIG_ENC28J60_LPWORK) # define ENCWORK LPWORK # else # error "Neither CONFIG_ENC28J60_HPWORK nor CONFIG_ENC28J60_LPWORK defined" # endif #endif /* CONFIG_ENC28J60_DUMPPACKET will dump the contents of each packet to the console. */ #ifdef CONFIG_ENC28J60_DUMPPACKET # define enc_dumppacket(m,a,n) lib_dumpbuffer(m,a,n) #else # define enc_dumppacket(m,a,n) #endif /* Low-level register debug */ #if !defined(CONFIG_DEBUG_FEATURES) || !defined(CONFIG_DEBUG_NET) # undef CONFIG_ENC28J60_REGDEBUG #endif /* Timing *******************************************************************/ /* TX poll deley = 1 seconds. CLK_TCK is the number of clock ticks per second */ #define ENC_WDDELAY (1*CLK_TCK) /* TX timeout = 1 minute */ #define ENC_TXTIMEOUT (60*CLK_TCK) /* Poll timeout */ #define ENC_POLLTIMEOUT MSEC2TICK(50) /* Packet Memory ************************************************************/ /* Packet memory layout */ #define ALIGNED_BUFSIZE ((CONFIG_NET_ETH_MTU + 255) & ~255) /* Work around Errata #5 (spurious reset of ERXWRPT to 0) by placing the RX * FIFO at the beginning of packet memory. */ #define ERRATA5 1 #if ERRATA5 # define PKTMEM_RX_START 0x0000 /* RX buffer must be at addr 0 for errata 5 */ # define PKTMEM_RX_END (PKTMEM_END-ALIGNED_BUFSIZE) /* RX buffer length is total SRAM minus TX buffer */ # define PKTMEM_TX_START (PKTMEM_RX_END+1) /* Start TX buffer after */ # define PKTMEM_TX_ENDP1 (PKTMEM_TX_START+ALIGNED_BUFSIZE) /* Allow TX buffer for one frame */ #else # define PKTMEM_TX_START 0x0000 /* Start TX buffer at 0 */ # define PKTMEM_TX_ENDP1 ALIGNED_BUFSIZE /* Allow TX buffer for one frame */ # define PKTMEM_RX_START PKTMEM_TX_ENDP1 /* Followed by RX buffer */ # define PKTMEM_RX_END PKTMEM_END /* RX buffer goes to the end of SRAM */ #endif /* Misc. Helper Macros ******************************************************/ #define enc_rdgreg(priv,ctrlreg) \ enc_rdgreg2(priv, ENC_RCR | GETADDR(ctrlreg)) #define enc_wrgreg(priv,ctrlreg,wrdata) \ enc_wrgreg2(priv, ENC_WCR | GETADDR(ctrlreg), wrdata) #define enc_bfcgreg(priv,ctrlreg,clrbits) \ enc_wrgreg2(priv, ENC_BFC | GETADDR(ctrlreg), clrbits) #define enc_bfsgreg(priv,ctrlreg,setbits) \ enc_wrgreg2(priv, ENC_BFS | GETADDR(ctrlreg), setbits) /* This is a helper pointer for accessing the contents of the Ethernet header */ #define BUF ((struct eth_hdr_s *)priv->dev.d_buf) /* Debug ********************************************************************/ #ifdef CONFIG_ENC28J60_REGDEBUG # define enc_wrdump(a,v) \ syslog(LOG_DEBUG, "ENC28J60: %02x<-%02x\n", a, v); # define enc_rddump(a,v) \ syslog(LOG_DEBUG, "ENC28J60: %02x->%02x\n", a, v); # define enc_cmddump(c) \ syslog(LOG_DEBUG, "ENC28J60: CMD: %02x\n", c); # define enc_bmdump(c,b,s) \ syslog(LOG_DEBUG, "ENC28J60: CMD: %02x buffer: %p length: %d\n", c, b, s); #else # define enc_wrdump(a,v) # define enc_rddump(a,v) # define enc_cmddump(c) # define enc_bmdump(c,b,s) #endif /**************************************************************************** * Private Types ****************************************************************************/ /* The state of the interface */ enum enc_state_e { ENCSTATE_UNINIT = 0, /* The interface is in an uninitialized state */ ENCSTATE_DOWN, /* The interface is down */ ENCSTATE_UP /* The interface is up */ }; /* The enc_driver_s encapsulates all state information for a single hardware * interface */ struct enc_driver_s { /* Device control */ uint8_t ifstate; /* Interface state: See ENCSTATE_* */ uint8_t bank; /* Currently selected bank */ uint16_t nextpkt; /* Next packet address */ FAR const struct enc_lower_s *lower; /* Low-level MCU-specific support */ /* Timing */ WDOG_ID txpoll; /* TX poll timer */ WDOG_ID txtimeout; /* TX timeout timer */ /* If we don't own the SPI bus, then we cannot do SPI accesses from the * interrupt handler. */ struct work_s irqwork; /* Interrupt continuation work queue support */ struct work_s towork; /* Tx timeout work queue support */ struct work_s pollwork; /* Poll timeout work queue support */ /* This is the contained SPI driver intstance */ FAR struct spi_dev_s *spi; /* This holds the information visible to the NuttX network */ struct net_driver_s dev; /* Interface understood by the network */ }; /**************************************************************************** * Private Data ****************************************************************************/ /* A single packet buffer is used */ static uint8_t g_pktbuf[MAX_NET_DEV_MTU + CONFIG_NET_GUARDSIZE]; /* Driver status structure */ static struct enc_driver_s g_enc28j60[CONFIG_ENC28J60_NINTERFACES]; /**************************************************************************** * Private Function Prototypes ****************************************************************************/ /* Low-level SPI helpers */ static inline void enc_configspi(FAR struct spi_dev_s *spi); static void enc_lock(FAR struct enc_driver_s *priv); static inline void enc_unlock(FAR struct enc_driver_s *priv); /* SPI control register access */ static uint8_t enc_rdgreg2(FAR struct enc_driver_s *priv, uint8_t cmd); static void enc_wrgreg2(FAR struct enc_driver_s *priv, uint8_t cmd, uint8_t wrdata); static inline void enc_src(FAR struct enc_driver_s *priv); static void enc_setbank(FAR struct enc_driver_s *priv, uint8_t bank); static uint8_t enc_rdbreg(FAR struct enc_driver_s *priv, uint8_t ctrlreg); static void enc_wrbreg(FAR struct enc_driver_s *priv, uint8_t ctrlreg, uint8_t wrdata); static int enc_waitbreg(FAR struct enc_driver_s *priv, uint8_t ctrlreg, uint8_t bits, uint8_t value); #if 0 /* Sometimes useful */ static void enc_rxdump(FAR struct enc_driver_s *priv); static void enc_txdump(FAR struct enc_driver_s *priv); #endif /* SPI buffer transfers */ static void enc_rdbuffer(FAR struct enc_driver_s *priv, FAR uint8_t *buffer, size_t buflen); static inline void enc_wrbuffer(FAR struct enc_driver_s *priv, FAR const uint8_t *buffer, size_t buflen); /* PHY register access */ static uint16_t enc_rdphy(FAR struct enc_driver_s *priv, uint8_t phyaddr); static void enc_wrphy(FAR struct enc_driver_s *priv, uint8_t phyaddr, uint16_t phydata); /* Common TX logic */ static int enc_transmit(FAR struct enc_driver_s *priv); static int enc_txpoll(struct net_driver_s *dev); /* Interrupt handling */ static void enc_linkstatus(FAR struct enc_driver_s *priv); static void enc_txif(FAR struct enc_driver_s *priv); static void enc_txerif(FAR struct enc_driver_s *priv); static void enc_txerif(FAR struct enc_driver_s *priv); static void enc_rxerif(FAR struct enc_driver_s *priv); static void enc_rxdispatch(FAR struct enc_driver_s *priv); static void enc_pktif(FAR struct enc_driver_s *priv); static void enc_irqworker(FAR void *arg); static int enc_interrupt(int irq, FAR void *context, FAR void *arg); /* Watchdog timer expirations */ static void enc_toworker(FAR void *arg); static void enc_txtimeout(int argc, uint32_t arg, ...); static void enc_pollworker(FAR void *arg); static void enc_polltimer(int argc, uint32_t arg, ...); /* NuttX callback functions */ static int enc_ifup(struct net_driver_s *dev); static int enc_ifdown(struct net_driver_s *dev); static int enc_txavail(struct net_driver_s *dev); #ifdef CONFIG_NET_IGMP static int enc_addmac(struct net_driver_s *dev, FAR const uint8_t *mac); static int enc_rmmac(struct net_driver_s *dev, FAR const uint8_t *mac); #endif /* Initialization */ static void enc_pwrsave(FAR struct enc_driver_s *priv); static void enc_pwrfull(FAR struct enc_driver_s *priv); static void enc_setmacaddr(FAR struct enc_driver_s *priv); static int enc_reset(FAR struct enc_driver_s *priv); /**************************************************************************** * Private Functions ****************************************************************************/ /**************************************************************************** * Name: enc_configspi * * Description: * Configure the SPI for use with the ENC28J60 * * Input Parameters: * spi - Reference to the SPI driver structure * * Returned Value: * None * * Assumptions: * ****************************************************************************/ static inline void enc_configspi(FAR struct spi_dev_s *spi) { /* Configure SPI for the ENC28J60. */ SPI_SETMODE(spi, CONFIG_ENC28J60_SPIMODE); SPI_SETBITS(spi, 8); (void)SPI_HWFEATURES(spi, 0); (void)SPI_SETFREQUENCY(spi, CONFIG_ENC28J60_FREQUENCY); } /**************************************************************************** * Name: enc_lock * * Description: * Select the SPI, locking and re-configuring if necessary * * Input Parameters: * spi - Reference to the SPI driver structure * * Returned Value: * None * * Assumptions: * ****************************************************************************/ static void enc_lock(FAR struct enc_driver_s *priv) { /* Lock the SPI bus in case there are multiple devices competing for the SPI * bus. */ SPI_LOCK(priv->spi, true); /* Now make sure that the SPI bus is configured for the ENC28J60 (it * might have gotten configured for a different device while unlocked) */ SPI_SETMODE(priv->spi, CONFIG_ENC28J60_SPIMODE); SPI_SETBITS(priv->spi, 8); (void)SPI_HWFEATURES(priv->spi, 0); (void)SPI_SETFREQUENCY(priv->spi, CONFIG_ENC28J60_FREQUENCY); } /**************************************************************************** * Name: enc_unlock * * Description: * De-select the SPI * * Input Parameters: * spi - Reference to the SPI driver structure * * Returned Value: * None * * Assumptions: * ****************************************************************************/ static inline void enc_unlock(FAR struct enc_driver_s *priv) { /* Relinquish the lock on the bus. */ SPI_LOCK(priv->spi, false); } /**************************************************************************** * Name: enc_rdgreg2 * * Description: * Read a global register (EIE, EIR, ESTAT, ECON2, or ECON1). The cmd * include the CMD 'OR'd with the global address register. * * Input Parameters: * priv - Reference to the driver state structure * cmd - The full command to received (cmd | address) * * Returned Value: * The value read from the register * * Assumptions: * ****************************************************************************/ static uint8_t enc_rdgreg2(FAR struct enc_driver_s *priv, uint8_t cmd) { uint8_t rddata; DEBUGASSERT(priv && priv->spi); /* Select ENC28J60 chip */ SPI_SELECT(priv->spi, SPIDEV_ETHERNET(0), true); /* Send the read command and collect the data. The sequence requires * 16-clocks: 8 to clock out the cmd + 8 to clock in the data. */ (void)SPI_SEND(priv->spi, cmd); /* Clock out the command */ rddata = SPI_SEND(priv->spi, 0); /* Clock in the data */ /* De-select ENC28J60 chip */ SPI_SELECT(priv->spi, SPIDEV_ETHERNET(0), false); enc_rddump(cmd, rddata); return rddata; } /**************************************************************************** * Name: enc_wrgreg2 * * Description: * Write to a global register (EIE, EIR, ESTAT, ECON2, or ECON1). The cmd * include the CMD 'OR'd with the global address register. * * Input Parameters: * priv - Reference to the driver state structure * cmd - The full command to received (cmd | address) * wrdata - The data to send * * Returned Value: * None * * Assumptions: * ****************************************************************************/ static void enc_wrgreg2(FAR struct enc_driver_s *priv, uint8_t cmd, uint8_t wrdata) { DEBUGASSERT(priv && priv->spi); /* Select ENC28J60 chip */ SPI_SELECT(priv->spi, SPIDEV_ETHERNET(0), true); /* Send the write command and data. The sequence requires 16-clocks: * 8 to clock out the cmd + 8 to clock out the data. */ (void)SPI_SEND(priv->spi, cmd); /* Clock out the command */ (void)SPI_SEND(priv->spi, wrdata); /* Clock out the data */ /* De-select ENC28J60 chip. */ SPI_SELECT(priv->spi, SPIDEV_ETHERNET(0), false); enc_wrdump(cmd, wrdata); } /**************************************************************************** * Name: enc_src * * Description: * Send the single byte system reset command (SRC). * * "The System Reset Command (SRC) allows the host controller to issue a * System Soft Reset command. Unlike other SPI commands, the SRC is * only a single byte command and does not operate on any register. The * command is started by pulling the CS pin low. The SRC opcode is the * sent, followed by a 5-bit Soft Reset command constant of 1Fh. The * SRC operation is terminated by raising the CS pin." * * Input Parameters: * priv - Reference to the driver state structure * * Returned Value: * None * * Assumptions: * ****************************************************************************/ static inline void enc_src(FAR struct enc_driver_s *priv) { DEBUGASSERT(priv && priv->spi); /* Select ENC28J60 chip */ SPI_SELECT(priv->spi, SPIDEV_ETHERNET(0), true); /* Send the system reset command. */ (void)SPI_SEND(priv->spi, ENC_SRC); /* Check CLKRDY bit to see when the reset is complete. There is an errata * that says the CLKRDY may be invalid. We'll wait a couple of msec to * workaround this condition. * * Also, "After a System Reset, all PHY registers should not be read or * written to until at least 50 µs have passed since the Reset has ended. * All registers will revert to their Reset default values. The dual * port buffer memory will maintain state throughout the System Reset." */ up_mdelay(2); /* while ((enc_rdgreg(priv, ENC_ESTAT) & ESTAT_CLKRDY) != 0); */ /* De-select ENC28J60 chip. */ SPI_SELECT(priv->spi, SPIDEV_ETHERNET(0), false); enc_cmddump(ENC_SRC); } /**************************************************************************** * Name: enc_setbank * * Description: * Set the bank for these next control register access. * * Assumption: * The caller has exclusive access to the SPI bus * * Input Parameters: * priv - Reference to the driver state structure * bank - The bank to select (0-3) * * Returned Value: * None * * Assumptions: * ****************************************************************************/ static void enc_setbank(FAR struct enc_driver_s *priv, uint8_t bank) { /* Check if the bank setting has changed */ if (bank != priv->bank) { /* Select bank 0 (just so that all of the bits are cleared) */ enc_bfcgreg(priv, ENC_ECON1, ECON1_BSEL_MASK); /* Then OR in bits to get the correct bank */ if (bank != 0) { enc_bfsgreg(priv, ENC_ECON1, (bank << ECON1_BSEL_SHIFT)); } /* Then remember the bank setting */ priv->bank = bank; } } /**************************************************************************** * Name: enc_rdbreg * * Description: * Read from a banked control register using the RCR command. * * Input Parameters: * priv - Reference to the driver state structure * ctrlreg - Bit encoded address of banked register to read * * Returned Value: * The byte read from the banked register * * Assumptions: * ****************************************************************************/ static uint8_t enc_rdbreg(FAR struct enc_driver_s *priv, uint8_t ctrlreg) { uint8_t rddata; DEBUGASSERT(priv && priv->spi); /* Set the bank */ enc_setbank(priv, GETBANK(ctrlreg)); /* Re-select ENC28J60 chip */ SPI_SELECT(priv->spi, SPIDEV_ETHERNET(0), true); /* Send the RCR command and collect the data. How we collect the data * depends on if this is a PHY/CAN or not. The normal sequence requires * 16-clocks: 8 to clock out the cmd and 8 to clock in the data. */ (void)SPI_SEND(priv->spi, ENC_RCR | GETADDR(ctrlreg)); /* Clock out the command */ if (ISPHYMAC(ctrlreg)) { /* The PHY/MAC sequence requires 24-clocks: 8 to clock out the cmd, * 8 dummy bits, and 8 to clock in the PHY/MAC data. */ (void)SPI_SEND(priv->spi, 0); /* Clock in the dummy byte */ } rddata = SPI_SEND(priv->spi, 0); /* Clock in the data */ /* De-select ENC28J60 chip */ SPI_SELECT(priv->spi, SPIDEV_ETHERNET(0), false); enc_rddump(ENC_RCR | GETADDR(ctrlreg), rddata); return rddata; } /**************************************************************************** * Name: enc_wrbreg * * Description: * Write to a banked control register using the WCR command. Unlike * reading, this same SPI sequence works for normal, MAC, and PHY * registers. * * Input Parameters: * priv - Reference to the driver state structure * ctrlreg - Bit encoded address of banked register to write * wrdata - The data to send * * Returned Value: * None * * Assumptions: * ****************************************************************************/ static void enc_wrbreg(FAR struct enc_driver_s *priv, uint8_t ctrlreg, uint8_t wrdata) { DEBUGASSERT(priv && priv->spi); /* Set the bank */ enc_setbank(priv, GETBANK(ctrlreg)); /* Re-select ENC28J60 chip */ SPI_SELECT(priv->spi, SPIDEV_ETHERNET(0), true); /* Send the WCR command and data. The sequence requires 16-clocks: * 8 to clock out the cmd + 8 to clock out the data. */ (void)SPI_SEND(priv->spi, ENC_WCR | GETADDR(ctrlreg)); /* Clock out the command */ (void)SPI_SEND(priv->spi, wrdata); /* Clock out the data */ /* De-select ENC28J60 chip. */ SPI_SELECT(priv->spi, SPIDEV_ETHERNET(0), false); enc_wrdump(ENC_WCR | GETADDR(ctrlreg), wrdata); } /**************************************************************************** * Name: enc_waitbreg * * Description: * Wait until banked register bit(s) take a specific value (or a timeout * occurs). * * Input Parameters: * priv - Reference to the driver state structure * ctrlreg - Bit encoded address of banked register to check * bits - The bits to check (a mask) * value - The value of the bits to return (value under mask) * * Returned Value: * OK on success, negated errno on failure * * Assumptions: * ****************************************************************************/ static int enc_waitbreg(FAR struct enc_driver_s *priv, uint8_t ctrlreg, uint8_t bits, uint8_t value) { systime_t start = clock_systimer(); systime_t elapsed; uint8_t rddata; /* Loop until the exit condition is met */ do { /* Read the byte from the requested banked register */ rddata = enc_rdbreg(priv, ctrlreg); elapsed = clock_systimer() - start; } while ((rddata & bits) != value && elapsed < ENC_POLLTIMEOUT); return (rddata & bits) == value ? OK : -ETIMEDOUT; } /**************************************************************************** * Name: enc_txdump enc_rxdump * * Description: * Dump registers associated with receiving or sending packets. * * Input Parameters: * priv - Reference to the driver state structure * * Returned Value: * None * * Assumptions: * ****************************************************************************/ #if 0 /* Sometimes useful */ static void enc_rxdump(FAR struct enc_driver_s *priv) { syslog(LOG_DEBUG, "Rx Registers:\n"); syslog(LOG_DEBUG, " EIE: %02x EIR: %02x\n", enc_rdgreg(priv, ENC_EIE), enc_rdgreg(priv, ENC_EIR)); syslog(LOG_DEBUG, " ESTAT: %02x ECON1: %02x ECON2: %02x\n", enc_rdgreg(priv, ENC_ESTAT), enc_rdgreg(priv, ENC_ECON1), enc_rdgreg(priv, ENC_ECON2)); syslog(LOG_DEBUG, " ERXST: %02x %02x\n", enc_rdbreg(priv, ENC_ERXSTH), enc_rdbreg(priv, ENC_ERXSTL)); syslog(LOG_DEBUG, " ERXND: %02x %02x\n", enc_rdbreg(priv, ENC_ERXNDH), enc_rdbreg(priv, ENC_ERXNDL)); syslog(LOG_DEBUG, " ERXRDPT: %02x %02x\n", enc_rdbreg(priv, ENC_ERXRDPTH), enc_rdbreg(priv, ENC_ERXRDPTL)); syslog(LOG_DEBUG, " ERXFCON: %02x EPKTCNT: %02x\n", enc_rdbreg(priv, ENC_ERXFCON), enc_rdbreg(priv, ENC_EPKTCNT)); syslog(LOG_DEBUG, " MACON1: %02x MACON3: %02x\n", enc_rdbreg(priv, ENC_MACON1), enc_rdbreg(priv, ENC_MACON3)); syslog(LOG_DEBUG, " MAMXFL: %02x %02x\n", enc_rdbreg(priv, ENC_MAMXFLH), enc_rdbreg(priv, ENC_MAMXFLL)); syslog(LOG_DEBUG, " MAADR: %02x:%02x:%02x:%02x:%02x:%02x\n", enc_rdbreg(priv, ENC_MAADR1), enc_rdbreg(priv, ENC_MAADR2), enc_rdbreg(priv, ENC_MAADR3), enc_rdbreg(priv, ENC_MAADR4), enc_rdbreg(priv, ENC_MAADR5), enc_rdbreg(priv, ENC_MAADR6)); } #endif #if 0 /* Sometimes useful */ static void enc_txdump(FAR struct enc_driver_s *priv) { syslog(LOG_DEBUG, "Tx Registers:\n"); syslog(LOG_DEBUG, " EIE: %02x EIR: %02x\n", enc_rdgreg(priv, ENC_EIE), enc_rdgreg(priv, ENC_EIR)); syslog(LOG_DEBUG, " ESTAT: %02x ECON1: %02x\n", enc_rdgreg(priv, ENC_ESTAT), enc_rdgreg(priv, ENC_ECON1)); syslog(LOG_DEBUG, " ETXST: %02x %02x\n", enc_rdbreg(priv, ENC_ETXSTH), enc_rdbreg(priv, ENC_ETXSTL)); syslog(LOG_DEBUG, " ETXND: %02x %02x\n", enc_rdbreg(priv, ENC_ETXNDH), enc_rdbreg(priv, ENC_ETXNDL)); syslog(LOG_DEBUG, " MACON1: %02x MACON3: %02x MACON4: %02x\n", enc_rdbreg(priv, ENC_MACON1), enc_rdbreg(priv, ENC_MACON3), enc_rdbreg(priv, ENC_MACON4)); syslog(LOG_DEBUG, " MACON1: %02x MACON3: %02x MACON4: %02x\n", enc_rdbreg(priv, ENC_MACON1), enc_rdbreg(priv, ENC_MACON3), enc_rdbreg(priv, ENC_MACON4)); syslog(LOG_DEBUG, " MABBIPG: %02x MAIPG %02x %02x\n", enc_rdbreg(priv, ENC_MABBIPG), enc_rdbreg(priv, ENC_MAIPGH), enc_rdbreg(priv, ENC_MAIPGL)); syslog(LOG_DEBUG, " MACLCON1: %02x MACLCON2: %02x\n", enc_rdbreg(priv, ENC_MACLCON1), enc_rdbreg(priv, ENC_MACLCON2)); syslog(LOG_DEBUG, " MAMXFL: %02x %02x\n", enc_rdbreg(priv, ENC_MAMXFLH), enc_rdbreg(priv, ENC_MAMXFLL)); } #endif /**************************************************************************** * Name: enc_rdbuffer * * Description: * Read a buffer of data. * * Input Parameters: * priv - Reference to the driver state structure * buffer - A pointer to the buffer to read into * buflen - The number of bytes to read * * Returned Value: * None * * Assumptions: * Read pointer is set to the correct address * ****************************************************************************/ static void enc_rdbuffer(FAR struct enc_driver_s *priv, FAR uint8_t *buffer, size_t buflen) { DEBUGASSERT(priv && priv->spi); /* Select ENC28J60 chip */ SPI_SELECT(priv->spi, SPIDEV_ETHERNET(0), true); /* Send the read buffer memory command (ignoring the response) */ (void)SPI_SEND(priv->spi, ENC_RBM); /* Then read the buffer data */ SPI_RECVBLOCK(priv->spi, buffer, buflen); /* De-select ENC28J60 chip. */ SPI_SELECT(priv->spi, SPIDEV_ETHERNET(0), false); enc_bmdump(ENC_WBM, buffer, buflen); } /**************************************************************************** * Name: enc_wrbuffer * * Description: * Write a buffer of data. * * Input Parameters: * priv - Reference to the driver state structure * buffer - A pointer to the buffer to write from * buflen - The number of bytes to write * * Returned Value: * None * * Assumptions: * Read pointer is set to the correct address * ****************************************************************************/ static inline void enc_wrbuffer(FAR struct enc_driver_s *priv, FAR const uint8_t *buffer, size_t buflen) { DEBUGASSERT(priv && priv->spi); /* Select ENC28J60 chip * * "The WBM command is started by lowering the CS pin. ..." */ SPI_SELECT(priv->spi, SPIDEV_ETHERNET(0), true); /* Send the write buffer memory command (ignoring the response) * * "...The [3-bit]WBM opcode should then be sent to the ENC28J60, * followed by the 5-bit constant, 1Ah." */ (void)SPI_SEND(priv->spi, ENC_WBM); /* "...the ENC28J60 requires a single per packet control byte to * precede the packet for transmission." * * POVERRIDE: Per Packet Override bit (Not set): * 1 = The values of PCRCEN, PPADEN and PHUGEEN will override the * configuration defined by MACON3. * 0 = The values in MACON3 will be used to determine how the packet * will be transmitted * PCRCEN: Per Packet CRC Enable bit (Set, but won't be used because * POVERRIDE is zero). * PPADEN: Per Packet Padding Enable bit (Set, but won't be used because * POVERRIDE is zero). * PHUGEEN: Per Packet Huge Frame Enable bit (Set, but won't be used * because POVERRIDE is zero). */ (void)SPI_SEND(priv->spi, (PKTCTRL_PCRCEN | PKTCTRL_PPADEN | PKTCTRL_PHUGEEN)); /* Then send the buffer * * "... After the WBM command and constant are sent, the data to * be stored in the memory pointed to by EWRPT should be shifted * out MSb first to the ENC28J60. After 8 data bits are received, * the Write Pointer will automatically increment if AUTOINC is * set. The host controller can continue to provide clocks on the * SCK pin and send data on the SI pin, without raising CS, to * keep writing to the memory. In this manner, with AUTOINC * enabled, it is possible to continuously write sequential bytes * to the buffer memory without any extra SPI command * overhead. */ SPI_SNDBLOCK(priv->spi, buffer, buflen); /* De-select ENC28J60 chip * * "The WBM command is terminated by bringing up the CS pin. ..." */ SPI_SELECT(priv->spi, SPIDEV_ETHERNET(0), false); enc_bmdump(ENC_WBM, buffer, buflen+1); } /**************************************************************************** * Name: enc_rdphy * * Description: * Read 16-bits of PHY data. * * Input Parameters: * priv - Reference to the driver state structure * phyaddr - The PHY register address * * Returned Value: * 16-bit value read from the PHY * * Assumptions: * ****************************************************************************/ static uint16_t enc_rdphy(FAR struct enc_driver_s *priv, uint8_t phyaddr) { uint16_t data = 0; /* "To read from a PHY register: * * 1. Write the address of the PHY register to read from into the MIREGADR * register. */ enc_wrbreg(priv, ENC_MIREGADR, phyaddr); /* 2. Set the MICMD.MIIRD bit. The read operation begins and the * MISTAT.BUSY bit is set. */ enc_wrbreg(priv, ENC_MICMD, MICMD_MIIRD); /* 3. Wait 10.24 µs. Poll the MISTAT.BUSY bit to be certain that the * operation is complete. While busy, the host controller should not * start any MIISCAN operations or write to the MIWRH register. * * When the MAC has obtained the register contents, the BUSY bit will * clear itself. */ up_udelay(12); if (enc_waitbreg(priv, ENC_MISTAT, MISTAT_BUSY, 0x00) == OK) { /* 4. Clear the MICMD.MIIRD bit. */ enc_wrbreg(priv, ENC_MICMD, 0x00); /* 5. Read the desired data from the MIRDL and MIRDH registers. The * order that these bytes are accessed is unimportant." */ data = (uint16_t)enc_rdbreg(priv, ENC_MIRDL); data |= (uint16_t)enc_rdbreg(priv, ENC_MIRDH) << 8; } return data; } /**************************************************************************** * Name: enc_wrphy * * Description: * write 16-bits of PHY data. * * Input Parameters: * priv - Reference to the driver state structure * phyaddr - The PHY register address * phydata - 16-bit data to write to the PHY * * Returned Value: * None * * Assumptions: * ****************************************************************************/ static void enc_wrphy(FAR struct enc_driver_s *priv, uint8_t phyaddr, uint16_t phydata) { /* "To write to a PHY register: * * 1. Write the address of the PHY register to write to into the * MIREGADR register. */ enc_wrbreg(priv, ENC_MIREGADR, phyaddr); /* 2. Write the lower 8 bits of data to write into the MIWRL register. */ enc_wrbreg(priv, ENC_MIWRL, phydata); /* 3. Write the upper 8 bits of data to write into the MIWRH register. * Writing to this register automatically begins the MIIM transaction, * so it must be written to after MIWRL. The MISTAT.BUSY bit becomes * set. */ enc_wrbreg(priv, ENC_MIWRH, phydata >> 8); /* The PHY register will be written after the MIIM operation completes, * which takes 10.24 µs. When the write operation has completed, the BUSY * bit will clear itself. * * The host controller should not start any MIISCAN or MIIRD operations * while busy." */ up_udelay(12); enc_waitbreg(priv, ENC_MISTAT, MISTAT_BUSY, 0x00); } /**************************************************************************** * Name: enc_transmit * * Description: * Start hardware transmission. Called either from: * * - pkif interrupt when an application responds to the receipt of data * by trying to send something, or * - From watchdog based polling. * * Input Parameters: * priv - Reference to the driver state structure * * Returned Value: * OK on success; a negated errno on failure * * Assumptions: * ****************************************************************************/ static int enc_transmit(FAR struct enc_driver_s *priv) { uint16_t txend; /* Increment statistics */ ninfo("Sending packet, pktlen: %d\n", priv->dev.d_len); NETDEV_TXPACKETS(&priv->dev); /* Verify that the hardware is ready to send another packet. The driver * starts a transmission process by setting ECON1.TXRTS. When the packet is * finished transmitting or is aborted due to an error/cancellation, the * ECON1.TXRTS bit will be cleared. * * NOTE: If we got here, then we have committed to sending a packet. * higher level logic must have assured that (1) there is no transmission * in progress, and that (2) TX-related interrupts are disabled. */ DEBUGASSERT((enc_rdgreg(priv, ENC_ECON1) & ECON1_TXRTS) == 0); /* Send the packet: address=priv->dev.d_buf, length=priv->dev.d_len */ enc_dumppacket("Transmit Packet", priv->dev.d_buf, priv->dev.d_len); /* Set transmit buffer start (is this necessary?). */ enc_wrbreg(priv, ENC_ETXSTL, PKTMEM_TX_START & 0xff); enc_wrbreg(priv, ENC_ETXSTH, PKTMEM_TX_START >> 8); /* Reset the write pointer to start of transmit buffer */ enc_wrbreg(priv, ENC_EWRPTL, PKTMEM_TX_START & 0xff); enc_wrbreg(priv, ENC_EWRPTH, PKTMEM_TX_START >> 8); /* Set the TX End pointer based on the size of the packet to send. Note * that the offset accounts for the control byte at the beginning the * buffer plus the size of the packet data. */ txend = PKTMEM_TX_START + priv->dev.d_len; enc_wrbreg(priv, ENC_ETXNDL, txend & 0xff); enc_wrbreg(priv, ENC_ETXNDH, txend >> 8); /* Send the WBM command and copy the packet itself into the transmit * buffer at the position of the EWRPT register. */ enc_wrbuffer(priv, priv->dev.d_buf, priv->dev.d_len); /* Set TXRTS to send the packet in the transmit buffer */ enc_bfsgreg(priv, ENC_ECON1, ECON1_TXRTS); /* Setup the TX timeout watchdog (perhaps restarting the timer). Note: * Is there a race condition. Could the TXIF interrupt occur before * the timer is started? */ (void)wd_start(priv->txtimeout, ENC_TXTIMEOUT, enc_txtimeout, 1, (wdparm_t)priv); return OK; } /**************************************************************************** * Name: enc_txpoll * * Description: * The transmitter is available, check if the network has any outgoing packets ready * to send. This is a callback from devif_poll(). devif_poll() may be called: * * 1. When the preceding TX packet send is complete, * 2. When the preceding TX packet send timesout and the interface is reset * 3. During normal TX polling * * Input Parameters: * dev - Reference to the NuttX driver state structure * * Returned Value: * OK on success; a negated errno on failure * * Assumptions: * Interrupts are enabled but the caller holds the network lock. * ****************************************************************************/ static int enc_txpoll(struct net_driver_s *dev) { FAR struct enc_driver_s *priv = (FAR struct enc_driver_s *)dev->d_private; /* If the polling resulted in data that should be sent out on the network, * the field d_len is set to a value > 0. */ ninfo("Poll result: d_len=%d\n", priv->dev.d_len); if (priv->dev.d_len > 0) { /* Look up the destination MAC address and add it to the Ethernet * header. */ #ifdef CONFIG_NET_IPv4 #ifdef CONFIG_NET_IPv6 if (IFF_IS_IPv4(priv->dev.d_flags)) #endif { arp_out(&priv->dev); } #endif /* CONFIG_NET_IPv4 */ #ifdef CONFIG_NET_IPv6 #ifdef CONFIG_NET_IPv4 else #endif { neighbor_out(&priv->dev); } #endif /* CONFIG_NET_IPv6 */ /* Send the packet */ enc_transmit(priv); /* Stop the poll now because we can queue only one packet */ return -EBUSY; } /* If zero is returned, the polling will continue until all connections have * been examined. */ return OK; } /**************************************************************************** * Name: enc_linkstatus * * Description: * The current link status can be obtained from the PHSTAT1.LLSTAT or * PHSTAT2.LSTAT. * * Input Parameters: * priv - Reference to the driver state structure * * Returned Value: * None * * Assumptions: * ****************************************************************************/ static void enc_linkstatus(FAR struct enc_driver_s *priv) { #if 0 uint16_t regval = enc_rdphy(priv, ENC_PHSTAT2); priv->duplex = ((regval & PHSTAT2_DPXSTAT) != 0); priv->carrier = ((regval & PHSTAT2_LSTAT) != 0); #endif } /**************************************************************************** * Name: enc_txif * * Description: * An TXIF interrupt was received indicating that the last TX packet(s) is * done * * Input Parameters: * priv - Reference to the driver state structure * * Returned Value: * None * * Assumptions: * Interrupts are enabled but the caller holds the network lock. * ****************************************************************************/ static void enc_txif(FAR struct enc_driver_s *priv) { /* Update statistics */ NETDEV_TXDONE(&priv->dev); /* Clear the request to send bit */ enc_bfcgreg(priv, ENC_ECON1, ECON1_TXRTS); /* If no further xmits are pending, then cancel the TX timeout */ wd_cancel(priv->txtimeout); /* Then poll the network for new XMIT data */ (void)devif_poll(&priv->dev, enc_txpoll); } /**************************************************************************** * Name: enc_txerif * * Description: * An TXERIF interrupt was received indicating that a TX abort has occurred. * * Input Parameters: * priv - Reference to the driver state structure * * Returned Value: * None * * Assumptions: * ****************************************************************************/ static void enc_txerif(FAR struct enc_driver_s *priv) { /* Update statistics */ NETDEV_TXERRORS(&priv->dev); /* Reset TX */ enc_bfsgreg(priv, ENC_ECON1, ECON1_TXRST); enc_bfcgreg(priv, ENC_ECON1, ECON1_TXRST | ECON1_TXRTS); /* Here we really should re-transmit (I fact, if we want half duplex to * work right, then it is necessary to do this!): * * 1. Read the TSV: * - Read ETXNDL to get the end pointer * - Read 7 bytes from that pointer + 1 using ENC_RMB. * 2. Determine if we need to retransmit. Check the LATE COLLISION bit, if * set, then we need to transmit. * 3. Retranmit by resetting ECON1_TXRTS. */ #ifdef CONFIG_ENC28J60_HALFDUPLEX # error "Missing logic for half duplex" #endif } /**************************************************************************** * Name: enc_rxerif * * Description: * An RXERIF interrupt was received indicating that the last TX packet(s) is * done * * Input Parameters: * priv - Reference to the driver state structure * * Returned Value: * None * * Assumptions: * ****************************************************************************/ static void enc_rxerif(FAR struct enc_driver_s *priv) { /* REVISIT: Update statistics */ } /**************************************************************************** * Name: enc_rxdispatch * * Description: * Give the newly received packet to the network. * * Input Parameters: * priv - Reference to the driver state structure * * Returned Value: * None * * Assumptions: * Interrupts are enabled but the caller holds the network lock. * ****************************************************************************/ static void enc_rxdispatch(FAR struct enc_driver_s *priv) { #ifdef CONFIG_NET_PKT /* When packet sockets are enabled, feed the frame into the packet tap */ pkt_input(&priv->dev); #endif /* We only accept IP packets of the configured type and ARP packets */ #ifdef CONFIG_NET_IPv4 if (BUF->type == HTONS(ETHTYPE_IP)) { ninfo("IPv4 frame\n"); NETDEV_RXIPV4(&priv->dev); /* Handle ARP on input then give the IPv4 packet to the network * layer */ arp_ipin(&priv->dev); ipv4_input(&priv->dev); /* If the above function invocation resulted in data that should be * sent out on the network, the field d_len will set to a value > 0. */ if (priv->dev.d_len > 0) { /* Update the Ethernet header with the correct MAC address */ #ifdef CONFIG_NET_IPv6 if (IFF_IS_IPv4(priv->dev.d_flags)) #endif { arp_out(&priv->dev); } #ifdef CONFIG_NET_IPv6 else { neighbor_out(&priv->dev); } #endif /* And send the packet */ enc_transmit(priv); } } else #endif #ifdef CONFIG_NET_IPv6 if (BUF->type == HTONS(ETHTYPE_IP6)) { ninfo("Iv6 frame\n"); NETDEV_RXIPV6(&priv->dev); /* Give the IPv6 packet to the network layer */ ipv6_input(&priv->dev); /* If the above function invocation resulted in data that should be * sent out on the network, the field d_len will set to a value > 0. */ if (priv->dev.d_len > 0) { /* Update the Ethernet header with the correct MAC address */ #ifdef CONFIG_NET_IPv4 if (IFF_IS_IPv4(priv->dev.d_flags)) { arp_out(&priv->dev); } else #endif #ifdef CONFIG_NET_IPv6 { neighbor_out(&priv->dev); } #endif /* And send the packet */ enc_transmit(priv); } } else #endif #ifdef CONFIG_NET_ARP if (BUF->type == htons(ETHTYPE_ARP)) { ninfo("ARP packet received (%02x)\n", BUF->type); NETDEV_RXARP(&priv->dev); arp_arpin(&priv->dev); /* If the above function invocation resulted in data that should be * sent out on the network, the field d_len will set to a value > 0. */ if (priv->dev.d_len > 0) { enc_transmit(priv); } } else #endif { nerr("ERROR: Unsupported packet type dropped (%02x)\n", htons(BUF->type)); NETDEV_RXDROPPED(&priv->dev); } } /**************************************************************************** * Name: enc_pktif * * Description: * An interrupt was received indicating the availability of a new RX packet * * Input Parameters: * priv - Reference to the driver state structure * * Returned Value: * None * * Assumptions: * Interrupts are enabled but the caller holds the network lock. * ****************************************************************************/ static void enc_pktif(FAR struct enc_driver_s *priv) { uint8_t rsv[6]; uint16_t pktlen; uint16_t rxstat; /* Update statistics */ NETDEV_RXPACKETS(&priv->dev); /* Set the read pointer to the start of the received packet (ERDPT) */ DEBUGASSERT(priv->nextpkt <= PKTMEM_RX_END); enc_wrbreg(priv, ENC_ERDPTL, (priv->nextpkt)); enc_wrbreg(priv, ENC_ERDPTH, (priv->nextpkt) >> 8); /* Read the next packet pointer and the 4 byte read status vector (RSV) * at the beginning of the received packet. (ERDPT should auto-increment * and wrap to the beginning of the read buffer as necessary) */ enc_rdbuffer(priv, rsv, 6); /* Decode the new next packet pointer, and the RSV. The * RSV is encoded as: * * Bits 0-15: Indicates length of the received frame. This includes the * destination address, source address, type/length, data, * padding and CRC fields. This field is stored in little- * endian format. * Bits 16-31: Bit encoded RX status. */ priv->nextpkt = (uint16_t)rsv[1] << 8 | (uint16_t)rsv[0]; pktlen = (uint16_t)rsv[3] << 8 | (uint16_t)rsv[2]; rxstat = (uint16_t)rsv[5] << 8 | (uint16_t)rsv[4]; ninfo("Receiving packet, nextpkt: %04x pktlen: %d rxstat: %04x\n", priv->nextpkt, pktlen, rxstat); /* Check if the packet was received OK */ if ((rxstat & RXSTAT_OK) == 0) { nerr("ERROR: RXSTAT: %04x\n", rxstat); NETDEV_RXERRORS(&priv->dev); } /* Check for a usable packet length (4 added for the CRC) */ else if (pktlen > (CONFIG_NET_ETH_MTU + 4) || pktlen <= (ETH_HDRLEN + 4)) { nerr("ERROR: Bad packet size dropped (%d)\n", pktlen); NETDEV_RXERRORS(&priv->dev); } /* Otherwise, read and process the packet */ else { /* Save the packet length (without the 4 byte CRC) in priv->dev.d_len */ priv->dev.d_len = pktlen - 4; /* Copy the data data from the receive buffer to priv->dev.d_buf. * ERDPT should be correctly positioned from the last call to to * end_rdbuffer (above). */ enc_rdbuffer(priv, priv->dev.d_buf, priv->dev.d_len); enc_dumppacket("Received Packet", priv->dev.d_buf, priv->dev.d_len); /* Dispatch the packet to the network */ enc_rxdispatch(priv); } /* Move the RX read pointer to the start of the next received packet. * This frees the memory we just read. */ enc_wrbreg(priv, ENC_ERXRDPTL, (priv->nextpkt)); enc_wrbreg(priv, ENC_ERXRDPTH, (priv->nextpkt) >> 8); /* Decrement the packet counter indicate we are done with this packet */ enc_bfsgreg(priv, ENC_ECON2, ECON2_PKTDEC); } /**************************************************************************** * Name: enc_irqworker * * Description: * Perform interrupt handling logic outside of the interrupt handler (on * the work queue thread). * * Input Parameters: * arg - The reference to the driver structure (case to void*) * * Returned Value: * None * * Assumptions: * ****************************************************************************/ static void enc_irqworker(FAR void *arg) { FAR struct enc_driver_s *priv = (FAR struct enc_driver_s *)arg; uint8_t eir; DEBUGASSERT(priv); /* Get exclusive access to both the network and the SPI bus. */ net_lock(); enc_lock(priv); /* Disable further interrupts by clearing the global interrupt enable bit. * "After an interrupt occurs, the host controller should clear the global * enable bit for the interrupt pin before servicing the interrupt. Clearing * the enable bit will cause the interrupt pin to return to the non-asserted * state (high). Doing so will prevent the host controller from missing a * falling edge should another interrupt occur while the immediate interrupt * is being serviced." */ enc_bfcgreg(priv, ENC_EIE, EIE_INTIE); /* Loop until all interrupts have been processed (EIR==0). Note that * there is no infinite loop check... if there are always pending interrupts, * we are just broken. */ while ((eir = enc_rdgreg(priv, ENC_EIR) & EIR_ALLINTS) != 0) { /* Handle interrupts according to interrupt register register bit * settings. */ ninfo("EIR: %02x\n", eir); /* DMAIF: The DMA interrupt indicates that the DMA module has completed * its memory copy or checksum calculation. Additionally, this interrupt * will be caused if the host controller cancels a DMA operation by * manually clearing the DMAST bit. Once set, DMAIF can only be cleared * by the host controller or by a Reset condition. */ if ((eir & EIR_DMAIF) != 0) /* DMA interrupt */ { /* Not used by this driver. Just clear the interrupt request. */ enc_bfcgreg(priv, ENC_EIR, EIR_DMAIF); } /* LINKIF: The LINKIF indicates that the link status has changed. * The actual current link status can be obtained from the * PHSTAT1.LLSTAT or PHSTAT2.LSTAT. Unlike other interrupt sources, the * link status change interrupt is created in the integrated PHY * module. * * To receive it, the host controller must set the PHIE.PLNKIE and * PGEIE bits. After setting the two PHY interrupt enable bits, the * LINKIF bit will then shadow the contents of the PHIR.PGIF bit. * * Once LINKIF is set, it can only be cleared by the host controller or * by a Reset. The LINKIF bit is read-only. Performing an MII read on * the PHIR register will clear the LINKIF, PGIF and PLNKIF bits * automatically and allow for future link status change interrupts. */ if ((eir & EIR_LINKIF) != 0) /* Link change interrupt */ { enc_linkstatus(priv); /* Get current link status */ enc_rdphy(priv, ENC_PHIR); /* Clear the LINKIF interrupt */ } /* TXIF: The Transmit Interrupt Flag (TXIF) is used to indicate that * the requested packet transmission has ended. Upon transmission * completion, abort or transmission cancellation by the host * controller, the EIR.TXIF flag will be set to 1. * * Once TXIF is set, it can only be cleared by the host controller * or by a Reset condition. Once processed, the host controller should * use the BFC command to clear the EIR.TXIF bit. */ if ((eir & EIR_TXIF) != 0) /* Transmit interrupt */ { enc_txif(priv); /* Handle TX completion */ enc_bfcgreg(priv, ENC_EIR, EIR_TXIF); /* Clear the TXIF interrupt */ } /* TXERIF: The Transmit Error Interrupt Flag (TXERIF) is used to * indicate that a transmit abort has occurred. An abort can occur * because of any of the following: * * 1. Excessive collisions occurred as defined by the Retransmission * Maximum (RETMAX) bits in the MACLCON1 register. * 2. A late collision occurred as defined by the Collision Window * (COLWIN) bits in the MACLCON2 register. * 3. A collision after transmitting 64 bytes occurred (ESTAT.LATECOL * set). * 4. The transmission was unable to gain an opportunity to transmit * the packet because the medium was constantly occupied for too long. * The deferral limit (2.4287 ms) was reached and the MACON4.DEFER bit * was clear. * 5. An attempt to transmit a packet larger than the maximum frame * length defined by the MAMXFL registers was made without setting * the MACON3.HFRMEN bit or per packet POVERRIDE and PHUGEEN bits. * * Upon any of these conditions, the EIR.TXERIF flag is set to 1. Once * set, it can only be cleared by the host controller or by a Reset * condition. * * After a transmit abort, the TXRTS bit will be cleared, the * ESTAT.TXABRT bit will be set and the transmit status vector will be * written at ETXND + 1. The MAC will not automatically attempt to * retransmit the packet. The host controller may wish to read the * transmit status vector and LATECOL bit to determine the cause of * the abort. After determining the problem and solution, the host * controller should clear the LATECOL (if set) and TXABRT bits so * that future aborts can be detected accurately. * * In Full-Duplex mode, condition 5 is the only one that should cause * this interrupt. Collisions and other problems related to sharing * the network are not possible on full-duplex networks. The conditions * which cause the transmit error interrupt meet the requirements of the * transmit interrupt. As a result, when this interrupt occurs, TXIF * will also be simultaneously set. */ if ((eir & EIR_TXERIF) != 0) /* Transmit Error Interrupts */ { enc_txerif(priv); /* Handle the TX error */ enc_bfcgreg(priv, ENC_EIR, EIR_TXERIF); /* Clear the TXERIF interrupt */ } /* PKTIF The Receive Packet Pending Interrupt Flag (PKTIF) is used to * indicate the presence of one or more data packets in the receive * buffer and to provide a notification means for the arrival of new * packets. When the receive buffer has at least one packet in it, * EIR.PKTIF will be set. In other words, this interrupt flag will be * set anytime the Ethernet Packet Count register (EPKTCNT) is non-zero. * * The PKTIF bit can only be cleared by the host controller or by a Reset * condition. In order to clear PKTIF, the EPKTCNT register must be * decremented to 0. If the last data packet in the receive buffer is * processed, EPKTCNT will become zero and the PKTIF bit will automatically * be cleared. */ /* Ignore PKTIF because is unreliable. Use EPKTCNT instead */ /* if ((eir & EIR_PKTIF) != 0) */ { uint8_t pktcnt = enc_rdbreg(priv, ENC_EPKTCNT); if (pktcnt > 0) { nerr("EPKTCNT: %02x\n", pktcnt); /* Handle packet receipt */ enc_pktif(priv); } } /* RXERIF: The Receive Error Interrupt Flag (RXERIF) is used to * indicate a receive buffer overflow condition. Alternately, this * interrupt may indicate that too many packets are in the receive * buffer and more cannot be stored without overflowing the EPKTCNT * register. When a packet is being received and the receive buffer * runs completely out of space, or EPKTCNT is 255 and cannot be * incremented, the packet being received will be aborted (permanently * lost) and the EIR.RXERIF bit will be set to 1. * * Once set, RXERIF can only be cleared by the host controller or by a * Reset condition. Normally, upon the receive error condition, the * host controller would process any packets pending from the receive * buffer and then make additional room for future packets by * advancing the ERXRDPT registers (low byte first) and decrementing * the EPKTCNT register. * * Once processed, the host controller should use the BFC command to * clear the EIR.RXERIF bit. */ if ((eir & EIR_RXERIF) != 0) /* Receive Errror Interrupts */ { enc_rxerif(priv); /* Handle the RX error */ enc_bfcgreg(priv, ENC_EIR, EIR_RXERIF); /* Clear the RXERIF interrupt */ } } /* Enable GPIO interrupts */ priv->lower->enable(priv->lower); /* Enable Ethernet interrupts */ enc_bfsgreg(priv, ENC_EIE, EIE_INTIE); /* Release lock on the SPI bus and the network */ enc_unlock(priv); net_unlock(); } /**************************************************************************** * Name: enc_interrupt * * Description: * Hardware interrupt handler * * Input Parameters: * irq - Number of the IRQ that generated the interrupt * context - Interrupt register state save info (architecture-specific) * * Returned Value: * OK on success * * Assumptions: * ****************************************************************************/ static int enc_interrupt(int irq, FAR void *context, FAR void *arg) { FAR struct enc_driver_s *priv; DEBUGASSERT(arg != NULL); priv = (FAR struct enc_driver_s *)arg; /* In complex environments, we cannot do SPI transfers from the interrupt * handler because semaphores are probably used to lock the SPI bus. In * this case, we will defer processing to the worker thread. This is also * much kinder in the use of system resources and is, therefore, probably * a good thing to do in any event. */ DEBUGASSERT(work_available(&priv->irqwork)); /* Notice that further GPIO interrupts are disabled until the work is * actually performed. This is to prevent overrun of the worker thread. * Interrupts are re-enabled in enc_irqworker() when the work is completed. */ priv->lower->disable(priv->lower); return work_queue(ENCWORK, &priv->irqwork, enc_irqworker, (FAR void *)priv, 0); } /**************************************************************************** * Name: enc_toworker * * Description: * Our TX watchdog timed out. This is the worker thread continuation of * the watchdog timer interrupt. Reset the hardware and start again. * * Input Parameters: * arg - The reference to the driver structure (case to void*) * * Returned Value: * None * * Assumptions: * ****************************************************************************/ static void enc_toworker(FAR void *arg) { FAR struct enc_driver_s *priv = (FAR struct enc_driver_s *)arg; int ret; nerr("ERROR: Tx timeout\n"); DEBUGASSERT(priv); /* Get exclusive access to the network */ net_lock(); /* Increment statistics and dump debug info */ NETDEV_TXTIMEOUTS(&priv->dev); /* Then reset the hardware: Take the interface down, then bring it * back up */ ret = enc_ifdown(&priv->dev); DEBUGASSERT(ret == OK); ret = enc_ifup(&priv->dev); DEBUGASSERT(ret == OK); UNUSED(ret); /* Then poll the network for new XMIT data */ (void)devif_poll(&priv->dev, enc_txpoll); /* Release lock on the network */ net_unlock(); } /**************************************************************************** * Name: enc_txtimeout * * Description: * Our TX watchdog timed out. Called from the timer interrupt handler. * The last TX never completed. Perform work on the worker thread. * * Input Parameters: * argc - The number of available arguments * arg - The first argument * * Returned Value: * None * * Assumptions: * ****************************************************************************/ static void enc_txtimeout(int argc, uint32_t arg, ...) { FAR struct enc_driver_s *priv = (FAR struct enc_driver_s *)arg; int ret; /* In complex environments, we cannot do SPI transfers from the timout * handler because semaphores are probably used to lock the SPI bus. In * this case, we will defer processing to the worker thread. This is also * much kinder in the use of system resources and is, therefore, probably * a good thing to do in any event. */ DEBUGASSERT(priv && work_available(&priv->towork)); /* Notice that Tx timeout watchdog is not active so further Tx timeouts * can occur until we restart the Tx timeout watchdog. */ ret = work_queue(ENCWORK, &priv->towork, enc_toworker, (FAR void *)priv, 0); DEBUGASSERT(ret == OK); UNUSED(ret); } /**************************************************************************** * Name: enc_pollworker * * Description: * Periodic timer handler continuation. * * Input Parameters: * argc - The number of available arguments * arg - The first argument * * Returned Value: * None * * Assumptions: * ****************************************************************************/ static void enc_pollworker(FAR void *arg) { FAR struct enc_driver_s *priv = (FAR struct enc_driver_s *)arg; DEBUGASSERT(priv); /* Get exclusive access to both the network and the SPI bus. */ net_lock(); enc_lock(priv); /* Verify that the hardware is ready to send another packet. The driver * start a transmission process by setting ECON1.TXRTS. When the packet is * finished transmitting or is aborted due to an error/cancellation, the * ECON1.TXRTS bit will be cleared. */ if ((enc_rdgreg(priv, ENC_ECON1) & ECON1_TXRTS) == 0) { /* Yes.. update TCP timing states and poll the network for new XMIT data. Hmmm.. * looks like a bug here to me. Does this mean if there is a transmit * in progress, we will missing TCP time state updates? */ (void)devif_timer(&priv->dev, enc_txpoll); } /* Release lock on the SPI bus and the network */ enc_unlock(priv); net_unlock(); /* Setup the watchdog poll timer again */ (void)wd_start(priv->txpoll, ENC_WDDELAY, enc_polltimer, 1, (wdparm_t)arg); } /**************************************************************************** * Name: enc_polltimer * * Description: * Periodic timer handler. Called from the timer interrupt handler. * * Input Parameters: * argc - The number of available arguments * arg - The first argument * * Returned Value: * None * * Assumptions: * ****************************************************************************/ static void enc_polltimer(int argc, uint32_t arg, ...) { FAR struct enc_driver_s *priv = (FAR struct enc_driver_s *)arg; int ret; /* In complex environments, we cannot do SPI transfers from the timout * handler because semaphores are probably used to lock the SPI bus. In * this case, we will defer processing to the worker thread. This is also * much kinder in the use of system resources and is, therefore, probably * a good thing to do in any event. */ DEBUGASSERT(priv && work_available(&priv->pollwork)); /* Notice that poll watchdog is not active so further poll timeouts can * occur until we restart the poll timeout watchdog. */ ret = work_queue(ENCWORK, &priv->pollwork, enc_pollworker, (FAR void *)priv, 0); DEBUGASSERT(ret == OK); UNUSED(ret); } /**************************************************************************** * Name: enc_ifup * * Description: * NuttX Callback: Bring up the Ethernet interface when an IP address is * provided * * Input Parameters: * dev - Reference to the NuttX driver state structure * * Returned Value: * None * * Assumptions: * ****************************************************************************/ static int enc_ifup(struct net_driver_s *dev) { FAR struct enc_driver_s *priv = (FAR struct enc_driver_s *)dev->d_private; int ret; ninfo("Bringing up: %d.%d.%d.%d\n", dev->d_ipaddr & 0xff, (dev->d_ipaddr >> 8) & 0xff, (dev->d_ipaddr >> 16) & 0xff, dev->d_ipaddr >> 24); /* Lock the SPI bus so that we have exclusive access */ enc_lock(priv); /* Initialize Ethernet interface, set the MAC address, and make sure that * the ENC28J80 is not in power save mode. */ ret = enc_reset(priv); if (ret == OK) { enc_setmacaddr(priv); enc_pwrfull(priv); /* Enable interrupts at the ENC28J60. Interrupts are still disabled * at the interrupt controller. */ enc_wrphy(priv, ENC_PHIE, PHIE_PGEIE | PHIE_PLNKIE); enc_bfcgreg(priv, ENC_EIR, EIR_ALLINTS); enc_wrgreg(priv, ENC_EIE, EIE_INTIE | EIE_PKTIE | EIE_LINKIE | EIE_TXIE | EIE_TXERIE | EIE_RXERIE); /* Enable the receiver */ enc_bfsgreg(priv, ENC_ECON1, ECON1_RXEN); /* Set and activate a timer process */ (void)wd_start(priv->txpoll, ENC_WDDELAY, enc_polltimer, 1, (wdparm_t)priv); /* Mark the interface up and enable the Ethernet interrupt at the * controller */ priv->ifstate = ENCSTATE_UP; priv->lower->enable(priv->lower); } /* Un-lock the SPI bus */ enc_unlock(priv); return ret; } /**************************************************************************** * Name: enc_ifdown * * Description: * NuttX Callback: Stop the interface. * * Input Parameters: * dev - Reference to the NuttX driver state structure * * Returned Value: * None * * Assumptions: * ****************************************************************************/ static int enc_ifdown(struct net_driver_s *dev) { FAR struct enc_driver_s *priv = (FAR struct enc_driver_s *)dev->d_private; irqstate_t flags; int ret; ninfo("Taking down: %d.%d.%d.%d\n", dev->d_ipaddr & 0xff, (dev->d_ipaddr >> 8) & 0xff, (dev->d_ipaddr >> 16) & 0xff, dev->d_ipaddr >> 24); /* Lock the SPI bus so that we have exclusive access */ enc_lock(priv); /* Disable the Ethernet interrupt */ flags = enter_critical_section(); priv->lower->disable(priv->lower); /* Cancel the TX poll timer and TX timeout timers */ wd_cancel(priv->txpoll); wd_cancel(priv->txtimeout); /* Reset the device and leave in the power save state */ ret = enc_reset(priv); enc_pwrsave(priv); priv->ifstate = ENCSTATE_DOWN; leave_critical_section(flags); /* Un-lock the SPI bus */ enc_unlock(priv); return ret; } /**************************************************************************** * Name: enc_txavail * * Description: * Driver callback invoked when new TX data is available. This is a * stimulus perform an out-of-cycle poll and, thereby, reduce the TX * latency. * * Input Parameters: * dev - Reference to the NuttX driver state structure * * Returned Value: * None * * Assumptions: * Called in normal user mode * ****************************************************************************/ static int enc_txavail(struct net_driver_s *dev) { FAR struct enc_driver_s *priv = (FAR struct enc_driver_s *)dev->d_private; irqstate_t flags; /* Lock the SPI bus so that we have exclusive access */ enc_lock(priv); /* Ignore the notification if the interface is not yet up */ flags = enter_critical_section(); if (priv->ifstate == ENCSTATE_UP) { /* Check if the hardware is ready to send another packet. The driver * starts a transmission process by setting ECON1.TXRTS. When the packet is * finished transmitting or is aborted due to an error/cancellation, the * ECON1.TXRTS bit will be cleared. */ if ((enc_rdgreg(priv, ENC_ECON1) & ECON1_TXRTS) == 0) { /* The interface is up and TX is idle; poll the network for new XMIT data */ (void)devif_poll(&priv->dev, enc_txpoll); } } /* Un-lock the SPI bus */ leave_critical_section(flags); enc_unlock(priv); return OK; } /**************************************************************************** * Name: enc_addmac * * Description: * NuttX Callback: Add the specified MAC address to the hardware multicast * address filtering * * Input Parameters: * dev - Reference to the NuttX driver state structure * mac - The MAC address to be added * * Returned Value: * None * * Assumptions: * ****************************************************************************/ #ifdef CONFIG_NET_IGMP static int enc_addmac(struct net_driver_s *dev, FAR const uint8_t *mac) { FAR struct enc_driver_s *priv = (FAR struct enc_driver_s *)dev->d_private; /* Lock the SPI bus so that we have exclusive access */ enc_lock(priv); /* Add the MAC address to the hardware multicast routing table */ #warning "Multicast MAC support not implemented" /* Un-lock the SPI bus */ enc_unlock(priv); return OK; } #endif /**************************************************************************** * Name: enc_rmmac * * Description: * NuttX Callback: Remove the specified MAC address from the hardware multicast * address filtering * * Input Parameters: * dev - Reference to the NuttX driver state structure * mac - The MAC address to be removed * * Returned Value: * None * * Assumptions: * ****************************************************************************/ #ifdef CONFIG_NET_IGMP static int enc_rmmac(struct net_driver_s *dev, FAR const uint8_t *mac) { FAR struct enc_driver_s *priv = (FAR struct enc_driver_s *)dev->d_private; /* Lock the SPI bus so that we have exclusive access */ enc_lock(priv); /* Add the MAC address to the hardware multicast routing table */ #warning "Multicast MAC support not implemented" /* Un-lock the SPI bus */ enc_unlock(priv); return OK; } #endif /**************************************************************************** * Name: enc_pwrsave * * Description: * The ENC28J60 may be commanded to power-down via the SPI interface. * When powered down, it will no longer be able to transmit and receive * any packets. To maximize power savings: * * 1. Turn off packet reception by clearing ECON1.RXEN. * 2. Wait for any in-progress packets to finish being received by * polling ESTAT.RXBUSY. This bit should be clear before proceeding. * 3. Wait for any current transmissions to end by confirming ECON1.TXRTS * is clear. * 4. Set ECON2.VRPS (if not already set). * 5. Enter Sleep by setting ECON2.PWRSV. All MAC, MII and PHY registers * become inaccessible as a result. Setting PWRSV also clears * ESTAT.CLKRDY automatically. * * In Sleep mode, all registers and buffer memory will maintain their * states. The ETH registers and buffer memory will still be accessible * by the host controller. Additionally, the clock driver will continue * to operate. The CLKOUT function will be unaffected. * * Input Parameters: * priv - Reference to the driver state structure * * Returned Value: * None * * Assumptions: * ****************************************************************************/ static void enc_pwrsave(FAR struct enc_driver_s *priv) { ninfo("Set PWRSV\n"); /* 1. Turn off packet reception by clearing ECON1.RXEN. */ enc_bfcgreg(priv, ENC_ECON1, ECON1_RXEN); /* 2. Wait for any in-progress packets to finish being received by * polling ESTAT.RXBUSY. This bit should be clear before proceeding. */ if (enc_waitbreg(priv, ENC_ESTAT, ESTAT_RXBUSY, 0) == OK) { /* 3. Wait for any current transmissions to end by confirming * ECON1.TXRTS is clear. */ enc_waitbreg(priv, ENC_ECON1, ECON1_TXRTS, 0); /* 4. Set ECON2.VRPS (if not already set). */ /* enc_bfsgreg(priv, ENC_ECON2, ECON2_VRPS); <-- Set in enc_reset() */ /* 5. Enter Sleep by setting ECON2.PWRSV. */ enc_bfsgreg(priv, ENC_ECON2, ECON2_PWRSV); } } /**************************************************************************** * Name: enc_pwrfull * * Description: * When normal operation is desired, the host controller must perform * a slightly modified procedure: * * 1. Wake-up by clearing ECON2.PWRSV. * 2. Wait at least 300 ìs for the PHY to stabilize. To accomplish the * delay, the host controller may poll ESTAT.CLKRDY and wait for it * to become set. * 3. Restore receive capability by setting ECON1.RXEN. * * After leaving Sleep mode, there is a delay of many milliseconds * before a new link is established (assuming an appropriate link * partner is present). The host controller may wish to wait until * the link is established before attempting to transmit any packets. * The link status can be determined by polling the PHSTAT2.LSTAT bit. * Alternatively, the link change interrupt may be used if it is * enabled. * * Input Parameters: * priv - Reference to the driver state structure * * Returned Value: * None * * Assumptions: * ****************************************************************************/ static void enc_pwrfull(FAR struct enc_driver_s *priv) { ninfo("Clear PWRSV\n"); /* 1. Wake-up by clearing ECON2.PWRSV. */ enc_bfcgreg(priv, ENC_ECON2, ECON2_PWRSV); /* 2. Wait at least 300 ìs for the PHY to stabilize. To accomplish the * delay, the host controller may poll ESTAT.CLKRDY and wait for it to * become set. */ enc_waitbreg(priv, ENC_ESTAT, ESTAT_CLKRDY, ESTAT_CLKRDY); /* 3. Restore receive capability by setting ECON1.RXEN. * * The caller will do this when it is read to receive packets */ } /**************************************************************************** * Name: enc_setmacaddr * * Description: * Set the MAC address to the configured value. This is done after ifup * or after a TX timeout. Note that this means that the interface must * be down before configuring the MAC addr. * * Input Parameters: * priv - Reference to the driver state structure * * Returned Value: * None * * Assumptions: * ****************************************************************************/ static void enc_setmacaddr(FAR struct enc_driver_s *priv) { /* Program the hardware with it's MAC address (for filtering). * MAADR1 MAC Address Byte 1 (MAADR<47:40>), OUI Byte 1 * MAADR2 MAC Address Byte 2 (MAADR<39:32>), OUI Byte 2 * MAADR3 MAC Address Byte 3 (MAADR<31:24>), OUI Byte 3 * MAADR4 MAC Address Byte 4 (MAADR<23:16>) * MAADR5 MAC Address Byte 5 (MAADR<15:8>) * MAADR6 MAC Address Byte 6 (MAADR<7:0>) */ enc_wrbreg(priv, ENC_MAADR1, priv->dev.d_mac.ether.ether_addr_octet[0]); enc_wrbreg(priv, ENC_MAADR2, priv->dev.d_mac.ether.ether_addr_octet[1]); enc_wrbreg(priv, ENC_MAADR3, priv->dev.d_mac.ether.ether_addr_octet[2]); enc_wrbreg(priv, ENC_MAADR4, priv->dev.d_mac.ether.ether_addr_octet[3]); enc_wrbreg(priv, ENC_MAADR5, priv->dev.d_mac.ether.ether_addr_octet[4]); enc_wrbreg(priv, ENC_MAADR6, priv->dev.d_mac.ether.ether_addr_octet[5]); } /**************************************************************************** * Name: enc_reset * * Description: * Stop, reset, re-initialize, and restart the ENC28J60. This is done * initially, on ifup, and after a TX timeout. * * Input Parameters: * priv - Reference to the driver state structure * * Returned Value: * None * * Assumptions: * ****************************************************************************/ static int enc_reset(FAR struct enc_driver_s *priv) { uint8_t regval; nwarn("WARNING: Reset\n"); /* Configure SPI for the ENC28J60 */ enc_configspi(priv->spi); /* Reset the ENC28J60 */ enc_src(priv); /* Initialize ECON1: Clear ECON1 */ enc_wrgreg(priv, ENC_ECON1, 0x00); /* Initialize ECON2: Enable address auto increment and voltage * regulator powersave. */ enc_wrgreg(priv, ENC_ECON2, ECON2_AUTOINC | ECON2_VRPS); /* Initialize receive buffer. * First, set the receive buffer start address. */ priv->nextpkt = PKTMEM_RX_START; enc_wrbreg(priv, ENC_ERXSTL, PKTMEM_RX_START & 0xff); enc_wrbreg(priv, ENC_ERXSTH, PKTMEM_RX_START >> 8); /* Set the receive data pointer */ enc_wrbreg(priv, ENC_ERXRDPTL, PKTMEM_RX_START & 0xff); enc_wrbreg(priv, ENC_ERXRDPTH, PKTMEM_RX_START >> 8); /* Set the receive buffer end. */ enc_wrbreg(priv, ENC_ERXNDL, PKTMEM_RX_END & 0xff); enc_wrbreg(priv, ENC_ERXNDH, PKTMEM_RX_END >> 8); /* Set transmit buffer start. */ enc_wrbreg(priv, ENC_ETXSTL, PKTMEM_TX_START & 0xff); enc_wrbreg(priv, ENC_ETXSTH, PKTMEM_TX_START >> 8); /* Check if we are actually communicating with the ENC28J60. If its * 0x00 or 0xff, then we are probably not communicating correctly * via SPI. */ regval = enc_rdbreg(priv, ENC_EREVID); if (regval == 0x00 || regval == 0xff) { nerr("ERROR: Bad Rev ID: %02x\n", regval); return -ENODEV; } ninfo("Rev ID: %02x\n", regval); /* Set filter mode: unicast OR broadcast AND crc valid */ enc_wrbreg(priv, ENC_ERXFCON, ERXFCON_UCEN | ERXFCON_CRCEN | ERXFCON_BCEN); /* Enable MAC receive */ enc_wrbreg(priv, ENC_MACON1, MACON1_MARXEN | MACON1_TXPAUS | MACON1_RXPAUS); /* Enable automatic padding and CRC operations */ #ifdef CONFIG_ENC28J60_HALFDUPLEX enc_wrbreg(priv, ENC_MACON3, MACON3_PADCFG0 | MACON3_TXCRCEN | MACON3_FRMLNEN); enc_wrbreg(priv, ENC_MACON4, MACON4_DEFER); /* Defer transmission enable */ /* Set Non-Back-to-Back Inter-Packet Gap */ enc_wrbreg(priv, ENC_MAIPGL, 0x12); enc_wrbreg(priv, ENC_MAIPGH, 0x0c); /* Set Back-to-Back Inter-Packet Gap */ enc_wrbreg(priv, ENC_MABBIPG, 0x12); #else /* Set filter mode: unicast OR broadcast AND crc valid AND Full Duplex */ enc_wrbreg(priv, ENC_MACON3, MACON3_PADCFG0 | MACON3_TXCRCEN | MACON3_FRMLNEN | MACON3_FULDPX); /* Set Non-Back-to-Back Inter-Packet Gap */ enc_wrbreg(priv, ENC_MAIPGL, 0x12); /* Set Back-to-Back Inter-Packet Gap */ enc_wrbreg(priv, ENC_MABBIPG, 0x15); #endif /* Set the maximum packet size which the controller will accept */ enc_wrbreg(priv, ENC_MAMXFLL, CONFIG_NET_ETH_MTU & 0xff); enc_wrbreg(priv, ENC_MAMXFLH, CONFIG_NET_ETH_MTU >> 8); /* Configure LEDs (No, just use the defaults for now) */ /* enc_wrphy(priv, ENC_PHLCON, ??); */ /* Setup up PHCON1 & 2 */ #ifdef CONFIG_ENC28J60_HALFDUPLEX enc_wrphy(priv, ENC_PHCON1, 0x00); enc_wrphy(priv, ENC_PHCON2, PHCON2_HDLDIS); #else enc_wrphy(priv, ENC_PHCON1, PHCON1_PDPXMD); enc_wrphy(priv, ENC_PHCON2, 0x00); #endif return OK; } /**************************************************************************** * Public Functions ****************************************************************************/ /**************************************************************************** * Name: enc_initialize * * Description: * Initialize the Ethernet driver. The ENC28J60 device is assumed to be * in the post-reset state upon entry to this function. * * Input Parameters: * spi - A reference to the platform's SPI driver for the ENC28J60 * lower - The MCU-specific interrupt used to control low-level MCU * functions (i.e., ENC28J60 GPIO interrupts). * devno - If more than one ENC28J60 is supported, then this is the * zero based number that identifies the ENC28J60; * * Returned Value: * OK on success; Negated errno on failure. * * Assumptions: * ****************************************************************************/ int enc_initialize(FAR struct spi_dev_s *spi, FAR const struct enc_lower_s *lower, unsigned int devno) { FAR struct enc_driver_s *priv; DEBUGASSERT(devno < CONFIG_ENC28J60_NINTERFACES); priv = &g_enc28j60[devno]; /* Initialize the driver structure */ memset(g_enc28j60, 0, CONFIG_ENC28J60_NINTERFACES*sizeof(struct enc_driver_s)); priv->dev.d_buf = g_pktbuf; /* Single packet buffer */ priv->dev.d_ifup = enc_ifup; /* I/F down callback */ priv->dev.d_ifdown = enc_ifdown; /* I/F up (new IP address) callback */ priv->dev.d_txavail = enc_txavail; /* New TX data callback */ #ifdef CONFIG_NET_IGMP priv->dev.d_addmac = enc_addmac; /* Add multicast MAC address */ priv->dev.d_rmmac = enc_rmmac; /* Remove multicast MAC address */ #endif priv->dev.d_private = priv; /* Used to recover private state from dev */ /* Create a watchdog for timing polling for and timing of transmissions */ priv->txpoll = wd_create(); /* Create periodic poll timer */ priv->txtimeout = wd_create(); /* Create TX timeout timer */ priv->spi = spi; /* Save the SPI instance */ priv->lower = lower; /* Save the low-level MCU interface */ /* The interface should be in the down state. However, this function is called * too early in initalization to perform the ENC28J60 reset in enc_ifdown. We * are depending upon the fact that the application level logic will call enc_ifdown * later to reset the ENC28J60. NOTE: The MAC address will not be set up until * enc_ifup() is called. That gives the app time to set the MAC address before * bringing the interface up. */ priv->ifstate = ENCSTATE_UNINIT; /* Attach the interrupt to the driver (but don't enable it yet) */ if (lower->attach(lower, enc_interrupt, priv) < 0) { /* We could not attach the ISR to the interrupt */ return -EAGAIN; } /* Register the device with the OS so that socket IOCTLs can be performed */ return netdev_register(&priv->dev, NET_LL_ETHERNET); } #endif /* CONFIG_NET && CONFIG_ENC28J60_NET */