From: David van Moolenbroek Date: Tue, 2 Dec 2014 14:03:14 +0000 (+0000) Subject: e1000: use new libnetdriver X-Git-Url: http://zhaoyanbai.com/repos/man.nsupdate.html?a=commitdiff_plain;h=refs%2Fchanges%2F19%2F2919%2F1;p=minix.git e1000: use new libnetdriver Change-Id: I111750d2ca27f01039d0b427b1314aea861e2074 --- diff --git a/minix/drivers/net/e1000/Makefile b/minix/drivers/net/e1000/Makefile index a21331d34..ce5945683 100644 --- a/minix/drivers/net/e1000/Makefile +++ b/minix/drivers/net/e1000/Makefile @@ -6,7 +6,7 @@ FILES=$(PROG).conf FILESNAME=$(PROG) FILESDIR= /etc/system.conf.d -DPADD+= ${LIBNETDRIVER} ${LIBSYS} ${LIBTIMERS} -LDADD+= -lnetdriver -lsys -ltimers +DPADD+= ${LIBNETDRIVER} ${LIBSYS} +LDADD+= -lnetdriver -lsys .include diff --git a/minix/drivers/net/e1000/e1000.c b/minix/drivers/net/e1000/e1000.c index 367200ff0..72b7e3baf 100644 --- a/minix/drivers/net/e1000/e1000.c +++ b/minix/drivers/net/e1000/e1000.c @@ -2,13 +2,7 @@ #include #include -#include -#include -#include #include -#include -#include -#include #include #include "assert.h" #include "e1000.h" @@ -16,37 +10,34 @@ #include "e1000_reg.h" #include "e1000_pci.h" -static int e1000_instance; -static e1000_t e1000_state; - -static void e1000_init(message *mp); -static void e1000_init_pci(void); +static int e1000_init(unsigned int instance, ether_addr_t *addr); +static void e1000_stop(void); +static int e1000_send(struct netdriver_data *data, size_t size); +static ssize_t e1000_recv(struct netdriver_data *data, size_t max); +static void e1000_stat(eth_stat_t *stat); +static void e1000_intr(unsigned int mask); static int e1000_probe(e1000_t *e, int skip); -static int e1000_init_hw(e1000_t *e); -static void e1000_init_addr(e1000_t *e); -static void e1000_init_buf(e1000_t *e); -static void e1000_reset_hw(e1000_t *e); -static void e1000_writev_s(message *mp, int from_int); -static void e1000_readv_s(message *mp, int from_int); -static void e1000_getstat_s(message *mp); -static void e1000_interrupt(message *mp); -static int e1000_link_changed(e1000_t *e); -static void e1000_stop(e1000_t *e); +static void e1000_init_hw(e1000_t *e, ether_addr_t *addr); static uint32_t e1000_reg_read(e1000_t *e, uint32_t reg); static void e1000_reg_write(e1000_t *e, uint32_t reg, uint32_t value); static void e1000_reg_set(e1000_t *e, uint32_t reg, uint32_t value); static void e1000_reg_unset(e1000_t *e, uint32_t reg, uint32_t value); -static u16_t eeprom_eerd(void *e, int reg); -static u16_t eeprom_ich(void *e, int reg); +static u16_t eeprom_eerd(e1000_t *e, int reg); +static u16_t eeprom_ich(e1000_t *e, int reg); static int eeprom_ich_init(e1000_t *e); static int eeprom_ich_cycle(e1000_t *e, u32_t timeout); -static void reply(e1000_t *e); -static void mess_reply(message *req, message *reply); -/* SEF functions and variables. */ -static void sef_local_startup(void); -static int sef_cb_init_fresh(int type, sef_init_info_t *info); -static void sef_cb_signal_handler(int signo); +static int e1000_instance; +static e1000_t e1000_state; + +static const struct netdriver e1000_table = { + .ndr_init = e1000_init, + .ndr_stop = e1000_stop, + .ndr_recv = e1000_recv, + .ndr_send = e1000_send, + .ndr_stat = e1000_stat, + .ndr_intr = e1000_intr, +}; /* * The e1000 driver. @@ -54,161 +45,86 @@ static void sef_cb_signal_handler(int signo); int main(int argc, char * argv[]) { - message m; - int ipc_status; - int r; - /* SEF local startup. */ env_setargs(argc, argv); - sef_local_startup(); - - /* - * Enter the main driver loop. - */ - while (TRUE) { - if ((r = netdriver_receive(ANY, &m, &ipc_status)) != OK) - panic("netdriver_receive failed: %d", r); - - if (is_ipc_notify(ipc_status)) { - switch (_ENDPOINT_P(m.m_source)) { - case HARDWARE: - e1000_interrupt(&m); - break; - } - continue; - } + /* Let the netdriver library take control. */ + netdriver_task(&e1000_table); - switch (m.m_type) { - case DL_WRITEV_S: e1000_writev_s(&m, FALSE); break; - case DL_READV_S: e1000_readv_s(&m, FALSE); break; - case DL_CONF: e1000_init(&m); break; - case DL_GETSTAT_S: e1000_getstat_s(&m); break; - default: panic("illegal message: %d", m.m_type); - } - } + return 0; } /* - * Perform SEF initialization. - */ -static void -sef_local_startup(void) -{ - - /* Register init callbacks. */ - sef_setcb_init_fresh(sef_cb_init_fresh); - sef_setcb_init_lu(sef_cb_init_fresh); - sef_setcb_init_restart(sef_cb_init_fresh); - - /* Register live update callbacks. */ - sef_setcb_lu_prepare(sef_cb_lu_prepare_always_ready); - sef_setcb_lu_state_isvalid(sef_cb_lu_state_isvalid_workfree); - - /* Register signal callbacks. */ - sef_setcb_signal_handler(sef_cb_signal_handler); - - /* Let SEF perform startup. */ - sef_startup(); -} - -/* - * Initialize the e1000 driver. + * Initialize the e1000 driver and device. */ static int -sef_cb_init_fresh(int __unused type, sef_init_info_t * __unused info) +e1000_init(unsigned int instance, ether_addr_t * addr) { - long v; + e1000_t *e; int r; - v = 0; - (void)env_parse("instance", "d", 0, &v, 0, 255); - e1000_instance = (int) v; + e1000_instance = instance; /* Clear state. */ memset(&e1000_state, 0, sizeof(e1000_state)); + e = &e1000_state; + strlcpy(e->name, "e1000#0", sizeof(e->name)); + e->name[6] += instance; + /* Perform calibration. */ if ((r = tsc_calibrate()) != OK) panic("tsc_calibrate failed: %d", r); - /* Announce we are up! */ - netdriver_announce(); + /* See if we can find a matching device. */ + if (!e1000_probe(e, instance)) + return ENXIO; - return OK; -} + /* Initialize the hardware, and return its ethernet address. */ + e1000_init_hw(e, addr); -/* - * Process a signal. - */ -static void -sef_cb_signal_handler(int signo) -{ - e1000_t *e; - - e = &e1000_state; - - E1000_DEBUG(3, ("%s: got signal\n", e->name)); - - /* Only check for termination signal, ignore anything else. */ - if (signo != SIGTERM) return; - - e1000_stop(e); + return OK; } /* - * Process a configuration message from Inet. + * Map flash memory. This step is optional. */ static void -e1000_init(message * mp) +e1000_map_flash(e1000_t * e, int devind, int did) { - static int first_time = 1; - message reply_mess; - e1000_t *e; + u32_t flash_addr, gfpreg, sector_base_addr; + size_t flash_size; - E1000_DEBUG(3, ("e1000: init()\n")); + /* The flash memory is pointed to by BAR2. It may not be present. */ + if ((flash_addr = pci_attr_r32(devind, PCI_BAR_2)) == 0) + return; - /* Configure PCI devices, if needed. */ - if (first_time) { - first_time = 0; - e1000_init_pci(); - } + /* The default flash size. */ + flash_size = 0x10000; - e = &e1000_state; + switch (did) { + case E1000_DEV_ID_82540EM: + case E1000_DEV_ID_82545EM: + case E1000_DEV_ID_82540EP: + return; /* don't even try */ - /* Initialize hardware, if needed. */ - if (!(e->status & E1000_ENABLED) && !(e1000_init_hw(e))) { - reply_mess.m_type = DL_CONF_REPLY; - reply_mess.m_netdrv_net_dl_conf.stat = ENXIO; - mess_reply(mp, &reply_mess); - return; + /* 82566/82567/82562V series support mapping 4kB of flash memory. */ + case E1000_DEV_ID_ICH10_D_BM_LM: + case E1000_DEV_ID_ICH10_R_BM_LF: + flash_size = 0x1000; + break; } - /* Reply back to INET. */ - reply_mess.m_type = DL_CONF_REPLY; - reply_mess.m_netdrv_net_dl_conf.stat = OK; - memcpy(reply_mess.m_netdrv_net_dl_conf.hw_addr, e->address.ea_addr, - sizeof(reply_mess.m_netdrv_net_dl_conf.hw_addr)); - mess_reply(mp, &reply_mess); -} + e->flash = vm_map_phys(SELF, (void *)flash_addr, flash_size); + if (e->flash == MAP_FAILED) + panic("e1000: couldn't map in flash"); -/* - * Find a matching PCI device. - */ -static void -e1000_init_pci(void) -{ - e1000_t *e; + /* sector_base_addr is a "sector"-aligned address (4096 bytes). */ + gfpreg = E1000_READ_FLASH_REG(e, ICH_FLASH_GFPREG); + sector_base_addr = gfpreg & FLASH_GFPREG_BASE_MASK; - /* Initialize the PCI bus. */ - pci_init(); - - /* Try to detect e1000 cards. */ - e = &e1000_state; - strlcpy(e->name, "e1000#0", sizeof(e->name)); - e->name[6] += e1000_instance; - - e1000_probe(e, e1000_instance); + /* flash_base_addr is byte-aligned. */ + e->flash_base_addr = sector_base_addr << FLASH_SECTOR_ADDR_SHIFT; } /* @@ -219,14 +135,15 @@ e1000_probe(e1000_t * e, int skip) { int r, devind, ioflag; u16_t vid, did, cr; - u32_t status[2]; + u32_t status; u32_t base, size; - size_t flash_size; - u32_t gfpreg, sector_base_addr; char *dname; E1000_DEBUG(3, ("%s: probe()\n", e->name)); + /* Initialize communication to the PCI driver. */ + pci_init(); + /* Attempt to iterate the PCI bus. Start at the beginning. */ if ((r = pci_first_dev(&devind, &vid, &did)) == 0) return FALSE; @@ -241,7 +158,6 @@ e1000_probe(e1000_t * e, int skip) } /* We found a matching card. Set card-specific properties. */ - e->status |= E1000_DETECTED; e->eeprom_read = eeprom_eerd; switch (did) { @@ -265,12 +181,11 @@ e1000_probe(e1000_t * e, int skip) /* Inform the user about the new card. */ if (!(dname = pci_dev_name(vid, did))) dname = "Intel Pro/1000 Gigabit Ethernet Card"; - E1000_DEBUG(1, ("%s: %s (%04x/%04x/%02x) at %s\n", - e->name, dname, vid, did, e->revision, pci_slot_name(devind))); + E1000_DEBUG(1, ("%s: %s (%04x/%04x) at %s\n", + e->name, dname, vid, did, pci_slot_name(devind))); /* Reserve PCI resources found. */ - if ((r = pci_reserve_ok(devind)) != OK) - panic("failed to reserve PCI device: %d", r); + pci_reserve(devind); /* Read PCI configuration. */ e->irq = pci_attr_r8(devind, PCI_ILR); @@ -289,108 +204,36 @@ e1000_probe(e1000_t * e, int skip) pci_attr_w16(devind, PCI_CR, cr | PCI_CR_MAST_EN); /* Optionally map flash memory. */ - if (did != E1000_DEV_ID_82540EM && did != E1000_DEV_ID_82545EM && - did != E1000_DEV_ID_82540EP && pci_attr_r32(devind, PCI_BAR_2)) { - /* - * 82566/82567/82562V series support mapping 4kB of flash - * memory. - */ - switch (did) { - case E1000_DEV_ID_ICH10_D_BM_LM: - case E1000_DEV_ID_ICH10_R_BM_LF: - flash_size = 0x1000; - break; - default: - flash_size = 0x10000; - } - - if ((e->flash = vm_map_phys(SELF, - (void *)pci_attr_r32(devind, PCI_BAR_2), - flash_size)) == MAP_FAILED) - panic("e1000: couldn't map in flash"); - - /* - * sector_base_addr is a "sector"-aligned address (4096 bytes) - */ - gfpreg = E1000_READ_FLASH_REG(e, ICH_FLASH_GFPREG); - sector_base_addr = gfpreg & FLASH_GFPREG_BASE_MASK; - - /* flash_base_addr is byte-aligned */ - e->flash_base_addr = - sector_base_addr << FLASH_SECTOR_ADDR_SHIFT; - } + e1000_map_flash(e, devind, did); /* Output debug information. */ - status[0] = e1000_reg_read(e, E1000_REG_STATUS); + status = e1000_reg_read(e, E1000_REG_STATUS); E1000_DEBUG(3, ("%s: MEM at %p, IRQ %d\n", e->name, e->regs, e->irq)); E1000_DEBUG(3, ("%s: link %s, %s duplex\n", e->name, - status[0] & 3 ? "up" : "down", status[0] & 1 ? "full" : "half")); + status & 3 ? "up" : "down", status & 1 ? "full" : "half")); return TRUE; } /* - * Initialize the hardware. + * Reset the card. */ -static int -e1000_init_hw(e1000_t * e) +static void +e1000_reset_hw(e1000_t * e) { - int r, i; - - e->status |= E1000_ENABLED; - e->irq_hook = e->irq; - - /* - * Set the interrupt handler and policy. Do not automatically - * reenable interrupts. Return the IRQ line number on interrupts. - */ - if ((r = sys_irqsetpolicy(e->irq, 0, &e->irq_hook)) != OK) - panic("sys_irqsetpolicy failed: %d", r); - if ((r = sys_irqenable(&e->irq_hook)) != OK) - panic("sys_irqenable failed: %d", r); - - /* Reset hardware. */ - e1000_reset_hw(e); - - /* - * Initialize appropriately, according to section 14.3 General - * Configuration of Intel's Gigabit Ethernet Controllers Software - * Developer's Manual. - */ - e1000_reg_set(e, E1000_REG_CTRL, - E1000_REG_CTRL_ASDE | E1000_REG_CTRL_SLU); - e1000_reg_unset(e, E1000_REG_CTRL, E1000_REG_CTRL_LRST); - e1000_reg_unset(e, E1000_REG_CTRL, E1000_REG_CTRL_PHY_RST); - e1000_reg_unset(e, E1000_REG_CTRL, E1000_REG_CTRL_ILOS); - e1000_reg_write(e, E1000_REG_FCAL, 0); - e1000_reg_write(e, E1000_REG_FCAH, 0); - e1000_reg_write(e, E1000_REG_FCT, 0); - e1000_reg_write(e, E1000_REG_FCTTV, 0); - e1000_reg_unset(e, E1000_REG_CTRL, E1000_REG_CTRL_VME); - - /* Clear Multicast Table Array (MTA). */ - for (i = 0; i < 128; i++) - e1000_reg_write(e, E1000_REG_MTA + i, 0); - - /* Initialize statistics registers. */ - for (i = 0; i < 64; i++) - e1000_reg_write(e, E1000_REG_CRCERRS + (i * 4), 0); - /* Acquire MAC address and set up RX/TX buffers. */ - e1000_init_addr(e); - e1000_init_buf(e); + /* Assert a Device Reset signal. */ + e1000_reg_set(e, E1000_REG_CTRL, E1000_REG_CTRL_RST); - /* Enable interrupts. */ - e1000_reg_set(e, E1000_REG_IMS, E1000_REG_IMS_LSC | E1000_REG_IMS_RXO | - E1000_REG_IMS_RXT | E1000_REG_IMS_TXQE | E1000_REG_IMS_TXDW); - return TRUE; + /* Wait one microsecond. */ + tickdelay(1); } /* - * Initialize the card's ethernet address. + * Initialize and return the card's ethernet address. */ static void -e1000_init_addr(e1000_t * e) +e1000_init_addr(e1000_t * e, ether_addr_t * addr) { static char eakey[] = E1000_ENVVAR "#_EA"; static char eafmt[] = "x:x:x:x:x:x"; @@ -405,28 +248,27 @@ e1000_init_addr(e1000_t * e) if (env_parse(eakey, eafmt, i, &v, 0x00L, 0xFFL) != EP_SET) break; else - e->address.ea_addr[i] = v; + addr->ea_addr[i] = v; } /* If that fails, read Ethernet Address from EEPROM. */ if (i != 6) { for (i = 0; i < 3; i++) { word = e->eeprom_read(e, i); - e->address.ea_addr[(i * 2)] = (word & 0x00ff); - e->address.ea_addr[(i * 2) + 1] = (word & 0xff00) >> 8; + addr->ea_addr[i * 2] = (word & 0x00ff); + addr->ea_addr[i * 2 + 1] = (word & 0xff00) >> 8; } } /* Set Receive Address. */ - e1000_reg_write(e, E1000_REG_RAL, *(u32_t *)(&e->address.ea_addr[0])); - e1000_reg_write(e, E1000_REG_RAH, *(u16_t *)(&e->address.ea_addr[4])); + e1000_reg_write(e, E1000_REG_RAL, *(u32_t *)(&addr->ea_addr[0])); + e1000_reg_write(e, E1000_REG_RAH, *(u16_t *)(&addr->ea_addr[4])); e1000_reg_set(e, E1000_REG_RAH, E1000_REG_RAH_AV); e1000_reg_set(e, E1000_REG_RCTL, E1000_REG_RCTL_MPE); E1000_DEBUG(3, ("%s: Ethernet Address %x:%x:%x:%x:%x:%x\n", e->name, - e->address.ea_addr[0], e->address.ea_addr[1], - e->address.ea_addr[2], e->address.ea_addr[3], - e->address.ea_addr[4], e->address.ea_addr[5])); + addr->ea_addr[0], addr->ea_addr[1], addr->ea_addr[2], + addr->ea_addr[3], addr->ea_addr[4], addr->ea_addr[5])); } /* @@ -435,61 +277,52 @@ e1000_init_addr(e1000_t * e) static void e1000_init_buf(e1000_t * e) { - phys_bytes rx_buff_p; - phys_bytes tx_buff_p; + phys_bytes rx_desc_p, rx_buff_p; + phys_bytes tx_desc_p, tx_buff_p; int i; /* Number of descriptors. */ e->rx_desc_count = E1000_RXDESC_NR; e->tx_desc_count = E1000_TXDESC_NR; - /* Allocate the receive descriptors. */ - if (!e->rx_desc) { - if ((e->rx_desc = alloc_contig(sizeof(e1000_rx_desc_t) * - e->rx_desc_count, AC_ALIGN4K, &e->rx_desc_p)) == NULL) - panic("failed to allocate RX descriptors"); + /* Allocate receive descriptors. */ + if ((e->rx_desc = alloc_contig(sizeof(e1000_rx_desc_t) * + e->rx_desc_count, AC_ALIGN4K, &rx_desc_p)) == NULL) + panic("failed to allocate RX descriptors"); - memset(e->rx_desc, 0, - sizeof(e1000_rx_desc_t) * e->rx_desc_count); + memset(e->rx_desc, 0, sizeof(e1000_rx_desc_t) * e->rx_desc_count); - e->rx_buffer_size = E1000_RXDESC_NR * E1000_IOBUF_SIZE; + /* Allocate receive buffers. */ + e->rx_buffer_size = E1000_RXDESC_NR * E1000_IOBUF_SIZE; - /* Allocate receive buffers. */ - if ((e->rx_buffer = alloc_contig(e->rx_buffer_size, AC_ALIGN4K, - &rx_buff_p)) == NULL) - panic("failed to allocate RX buffers"); + if ((e->rx_buffer = alloc_contig(e->rx_buffer_size, AC_ALIGN4K, + &rx_buff_p)) == NULL) + panic("failed to allocate RX buffers"); - /* Set up receive descriptors. */ - for (i = 0; i < E1000_RXDESC_NR; i++) - e->rx_desc[i].buffer = rx_buff_p + - (i * E1000_IOBUF_SIZE); - } + /* Set up receive descriptors. */ + for (i = 0; i < E1000_RXDESC_NR; i++) + e->rx_desc[i].buffer = rx_buff_p + i * E1000_IOBUF_SIZE; /* Allocate transmit descriptors. */ - if (!e->tx_desc) { - if ((e->tx_desc = alloc_contig(sizeof(e1000_tx_desc_t) * - e->tx_desc_count, AC_ALIGN4K, &e->tx_desc_p)) == NULL) - panic("failed to allocate TX descriptors"); - - memset(e->tx_desc, 0, - sizeof(e1000_tx_desc_t) * e->tx_desc_count); - - /* Allocate transmit buffers. */ - e->tx_buffer_size = E1000_TXDESC_NR * E1000_IOBUF_SIZE; - - /* Attempt to allocate. */ - if ((e->tx_buffer = alloc_contig(e->tx_buffer_size, AC_ALIGN4K, - &tx_buff_p)) == NULL) - panic("failed to allocate TX buffers"); - - /* Set up transmit descriptors. */ - for (i = 0; i < E1000_TXDESC_NR; i++) - e->tx_desc[i].buffer = tx_buff_p + - (i * E1000_IOBUF_SIZE); - } + if ((e->tx_desc = alloc_contig(sizeof(e1000_tx_desc_t) * + e->tx_desc_count, AC_ALIGN4K, &tx_desc_p)) == NULL) + panic("failed to allocate TX descriptors"); + + memset(e->tx_desc, 0, sizeof(e1000_tx_desc_t) * e->tx_desc_count); + + /* Allocate transmit buffers. */ + e->tx_buffer_size = E1000_TXDESC_NR * E1000_IOBUF_SIZE; + + if ((e->tx_buffer = alloc_contig(e->tx_buffer_size, AC_ALIGN4K, + &tx_buff_p)) == NULL) + panic("failed to allocate TX buffers"); + + /* Set up transmit descriptors. */ + for (i = 0; i < E1000_TXDESC_NR; i++) + e->tx_desc[i].buffer = tx_buff_p + i * E1000_IOBUF_SIZE; /* Set up the receive ring registers. */ - e1000_reg_write(e, E1000_REG_RDBAL, e->rx_desc_p); + e1000_reg_write(e, E1000_REG_RDBAL, rx_desc_p); e1000_reg_write(e, E1000_REG_RDBAH, 0); e1000_reg_write(e, E1000_REG_RDLEN, e->rx_desc_count * sizeof(e1000_rx_desc_t)); @@ -499,7 +332,7 @@ e1000_init_buf(e1000_t * e) e1000_reg_set(e, E1000_REG_RCTL, E1000_REG_RCTL_EN); /* Set up the transmit ring registers. */ - e1000_reg_write(e, E1000_REG_TDBAL, e->tx_desc_p); + e1000_reg_write(e, E1000_REG_TDBAL, tx_desc_p); e1000_reg_write(e, E1000_REG_TDBAH, 0); e1000_reg_write(e, E1000_REG_TDLEN, e->tx_desc_count * sizeof(e1000_tx_desc_t)); @@ -510,231 +343,208 @@ e1000_init_buf(e1000_t * e) } /* - * Reset the card. + * Initialize the hardware. Return the ethernet address. */ static void -e1000_reset_hw(e1000_t * e) +e1000_init_hw(e1000_t * e, ether_addr_t * addr) { + int r, i; - /* Assert a Device Reset signal. */ - e1000_reg_set(e, E1000_REG_CTRL, E1000_REG_CTRL_RST); + e->irq_hook = e->irq; - /* Wait one microsecond. */ - tickdelay(1); + /* + * Set the interrupt handler and policy. Do not automatically + * reenable interrupts. Return the IRQ line number on interrupts. + */ + if ((r = sys_irqsetpolicy(e->irq, 0, &e->irq_hook)) != OK) + panic("sys_irqsetpolicy failed: %d", r); + if ((r = sys_irqenable(&e->irq_hook)) != OK) + panic("sys_irqenable failed: %d", r); + + /* Reset hardware. */ + e1000_reset_hw(e); + + /* + * Initialize appropriately, according to section 14.3 General + * Configuration of Intel's Gigabit Ethernet Controllers Software + * Developer's Manual. + */ + e1000_reg_set(e, E1000_REG_CTRL, + E1000_REG_CTRL_ASDE | E1000_REG_CTRL_SLU); + e1000_reg_unset(e, E1000_REG_CTRL, E1000_REG_CTRL_LRST); + e1000_reg_unset(e, E1000_REG_CTRL, E1000_REG_CTRL_PHY_RST); + e1000_reg_unset(e, E1000_REG_CTRL, E1000_REG_CTRL_ILOS); + e1000_reg_write(e, E1000_REG_FCAL, 0); + e1000_reg_write(e, E1000_REG_FCAH, 0); + e1000_reg_write(e, E1000_REG_FCT, 0); + e1000_reg_write(e, E1000_REG_FCTTV, 0); + e1000_reg_unset(e, E1000_REG_CTRL, E1000_REG_CTRL_VME); + + /* Clear Multicast Table Array (MTA). */ + for (i = 0; i < 128; i++) + e1000_reg_write(e, E1000_REG_MTA + i * 4, 0); + + /* Initialize statistics registers. */ + for (i = 0; i < 64; i++) + e1000_reg_write(e, E1000_REG_CRCERRS + i * 4, 0); + + /* Acquire MAC address and set up RX/TX buffers. */ + e1000_init_addr(e, addr); + e1000_init_buf(e); + + /* Enable interrupts. */ + e1000_reg_set(e, E1000_REG_IMS, E1000_REG_IMS_LSC | E1000_REG_IMS_RXO | + E1000_REG_IMS_RXT | E1000_REG_IMS_TXQE | E1000_REG_IMS_TXDW); } /* * Try to send a packet. */ -static void -e1000_writev_s(message * mp, int from_int) +static int +e1000_send(struct netdriver_data * data, size_t size) { - e1000_t *e = &e1000_state; + e1000_t *e; e1000_tx_desc_t *desc; - iovec_s_t iovec[E1000_IOVEC_NR]; - int r, head, tail, i, bytes = 0, size; + unsigned int head, tail, next; + char *ptr; - E1000_DEBUG(3, ("e1000: writev_s(%p,%d)\n", mp, from_int)); + e = &e1000_state; - /* Are we called from the interrupt handler? */ - if (!from_int) { - /* We cannot write twice simultaneously. - assert(!(e->status & E1000_WRITING)); */ + if (size > E1000_IOBUF_SIZE) + panic("packet too large to send"); - /* Copy write message. */ - e->tx_message = *mp; - e->client = mp->m_source; - e->status |= E1000_WRITING; + /* + * The queue tail must not advance to the point that it is equal to the + * queue head, since this condition indicates that the queue is empty. + */ + head = e1000_reg_read(e, E1000_REG_TDH); + tail = e1000_reg_read(e, E1000_REG_TDT); + next = (tail + 1) % e->tx_desc_count; - /* Must be a sane vector count. */ - assert(e->tx_message.m_net_netdrv_dl_writev_s.count > 0); - assert(e->tx_message.m_net_netdrv_dl_writev_s.count < - E1000_IOVEC_NR); + if (next == head) + return SUSPEND; - /* - * Copy the I/O vector table. - */ - if ((r = sys_safecopyfrom(e->tx_message.m_source, - e->tx_message.m_net_netdrv_dl_writev_s.grant, 0, - (vir_bytes)iovec, - e->tx_message.m_net_netdrv_dl_writev_s.count * - sizeof(iovec_s_t))) != OK) - panic("sys_safecopyfrom() failed: %d", r); - - /* Find the head, tail and current descriptors. */ - head = e1000_reg_read(e, E1000_REG_TDH); - tail = e1000_reg_read(e, E1000_REG_TDT); - desc = &e->tx_desc[tail]; - - E1000_DEBUG(4, ("%s: head=%d, tail=%d\n", - e->name, head, tail)); - - /* Loop vector elements. */ - for (i = 0; i < e->tx_message.m_net_netdrv_dl_writev_s.count; - i++) - { - size = iovec[i].iov_size < (E1000_IOBUF_SIZE - bytes) ? - iovec[i].iov_size : (E1000_IOBUF_SIZE - bytes); - - E1000_DEBUG(4, ("iovec[%d] = %d\n", i, size)); - - /* Copy bytes to TX queue buffers. */ - if ((r = sys_safecopyfrom(e->tx_message.m_source, - iovec[i].iov_grant, 0, (vir_bytes) e->tx_buffer + - (tail * E1000_IOBUF_SIZE), size)) != OK) - panic("sys_safecopyfrom() failed: %d", r); - - /* Mark this descriptor ready. */ - desc->status = 0; - desc->command = 0; - desc->length = size; - - /* Marks End-of-Packet. */ - if (i == - e->tx_message.m_net_netdrv_dl_writev_s.count - 1) { - desc->command = E1000_TX_CMD_EOP | - E1000_TX_CMD_FCS | E1000_TX_CMD_RS; - } - /* Move to next descriptor. */ - tail = (tail + 1) % e->tx_desc_count; - bytes += size; - desc = &e->tx_desc[tail]; - } + /* The descriptor to use is the one pointed to by the current tail. */ + desc = &e->tx_desc[tail]; + + /* Copy the packet from the caller. */ + ptr = e->tx_buffer + tail * E1000_IOBUF_SIZE; + + netdriver_copyin(data, 0, ptr, size); - /* Increment tail. Start transmission. */ - e1000_reg_write(e, E1000_REG_TDT, tail); + /* Mark this descriptor ready. */ + desc->status = 0; + desc->length = size; + desc->command = E1000_TX_CMD_EOP | E1000_TX_CMD_FCS | E1000_TX_CMD_RS; - E1000_DEBUG(2, ("e1000: wrote %d byte packet\n", bytes)); - } else - e->status |= E1000_TRANSMIT; - reply(e); + /* Increment tail. Start transmission. */ + e1000_reg_write(e, E1000_REG_TDT, next); + + return OK; } /* * Try to receive a packet. */ -static void -e1000_readv_s(message * mp, int from_int) +static ssize_t +e1000_recv(struct netdriver_data * data, size_t max) { - e1000_t *e = &e1000_state; + e1000_t *e; e1000_rx_desc_t *desc; - iovec_s_t iovec[E1000_IOVEC_NR]; - int i, r, head, tail, cur, bytes = 0, size; + unsigned int head, tail, cur; + char *ptr; + size_t size; - E1000_DEBUG(3, ("e1000: readv_s(%p,%d)\n", mp, from_int)); + e = &e1000_state; - /* Are we called from the interrupt handler? */ - if (!from_int) { - e->rx_message = *mp; - e->client = mp->m_source; - e->status |= E1000_READING; - e->rx_size = 0; + /* If the queue head and tail are equal, the queue is empty. */ + head = e1000_reg_read(e, E1000_REG_RDH); + tail = e1000_reg_read(e, E1000_REG_RDT); - assert(e->rx_message.m_net_netdrv_dl_readv_s.count > 0); - assert(e->rx_message.m_net_netdrv_dl_readv_s.count < - E1000_IOVEC_NR); - } + E1000_DEBUG(4, ("%s: head=%u, tail=%u\n", e->name, head, tail)); - if (e->status & E1000_READING) { - /* - * Copy the I/O vector table first. - */ - if ((r = sys_safecopyfrom(e->rx_message.m_source, - e->rx_message.m_net_netdrv_dl_readv_s.grant, 0, - (vir_bytes)iovec, - e->rx_message.m_net_netdrv_dl_readv_s.count * - sizeof(iovec_s_t))) != OK) - panic("sys_safecopyfrom() failed: %d", r); - - /* Find the head, tail and current descriptors. */ - head = e1000_reg_read(e, E1000_REG_RDH); - tail = e1000_reg_read(e, E1000_REG_RDT); - cur = (tail + 1) % e->rx_desc_count; - desc = &e->rx_desc[cur]; + if (head == tail) + return SUSPEND; - /* - * Only handle one packet at a time. - */ - if (!(desc->status & E1000_RX_STATUS_EOP)) { - reply(e); - return; - } - E1000_DEBUG(4, ("%s: head=%x, tail=%d\n", - e->name, head, tail)); + /* Has a packet been received? */ + cur = (tail + 1) % e->rx_desc_count; + desc = &e->rx_desc[cur]; - /* - * Copy to vector elements. - */ - for (i = 0; i < e->rx_message.m_net_netdrv_dl_readv_s.count && - bytes < desc->length; i++) { - size = iovec[i].iov_size < (desc->length - bytes) ? - iovec[i].iov_size : (desc->length - bytes); - - E1000_DEBUG(4, ("iovec[%d] = %lu[%d]\n", - i, iovec[i].iov_size, size)); - - if ((r = sys_safecopyto(e->rx_message.m_source, - iovec[i].iov_grant, 0, (vir_bytes)e->rx_buffer + - bytes + (cur * E1000_IOBUF_SIZE), size)) != OK) - panic("sys_safecopyto() failed: %d", r); - bytes += size; - } - desc->status = 0; + if (!(desc->status & E1000_RX_STATUS_DONE)) + return SUSPEND; - /* - * Update state. - */ - e->rx_size = bytes; - e->status |= E1000_RECEIVED; - E1000_DEBUG(2, ("e1000: got %d byte packet\n", e->rx_size)); + /* + * HACK: we expect all packets to fit in a single receive buffer. + * Eventually, some sort of support to deal with packets spanning + * multiple receive descriptors should be added. For now, we panic, + * so that we can continue after the restart; this is already an + * improvement over freezing (the old behavior of this driver). + */ + size = desc->length; - /* Increment tail. */ - e1000_reg_write(e, E1000_REG_RDT, - (tail + 1) % e->rx_desc_count); - } - reply(e); + if (!(desc->status & E1000_RX_STATUS_EOP)) + panic("received packet too large"); + + /* Copy the packet to the caller. */ + ptr = e->rx_buffer + cur * E1000_IOBUF_SIZE; + + if (size > max) + size = max; + + netdriver_copyout(data, 0, ptr, size); + + /* Reset the descriptor. */ + desc->status = 0; + + /* Increment tail. */ + e1000_reg_write(e, E1000_REG_RDT, cur); + + /* Return the size of the received packet. */ + return size; } /* * Return statistics. */ static void -e1000_getstat_s(message * mp) +e1000_stat(eth_stat_t * stat) { - int r; - eth_stat_t stats; e1000_t *e = &e1000_state; - E1000_DEBUG(3, ("e1000: getstat_s()\n")); - - stats.ets_recvErr = e1000_reg_read(e, E1000_REG_RXERRC); - stats.ets_sendErr = 0; - stats.ets_OVW = 0; - stats.ets_CRCerr = e1000_reg_read(e, E1000_REG_CRCERRS); - stats.ets_frameAll = 0; - stats.ets_missedP = e1000_reg_read(e, E1000_REG_MPC); - stats.ets_packetR = e1000_reg_read(e, E1000_REG_TPR); - stats.ets_packetT = e1000_reg_read(e, E1000_REG_TPT); - stats.ets_collision = e1000_reg_read(e, E1000_REG_COLC); - stats.ets_transAb = 0; - stats.ets_carrSense = 0; - stats.ets_fifoUnder = 0; - stats.ets_fifoOver = 0; - stats.ets_CDheartbeat = 0; - stats.ets_OWC = 0; - - sys_safecopyto(mp->m_source, mp->m_net_netdrv_dl_getstat_s.grant, 0, - (vir_bytes)&stats, sizeof(stats)); - mp->m_type = DL_STAT_REPLY; - if ((r = ipc_send(mp->m_source, mp)) != OK) - panic("e1000_getstat: ipc_send() failed: %d", r); + E1000_DEBUG(3, ("e1000: stat()\n")); + + stat->ets_recvErr = e1000_reg_read(e, E1000_REG_RXERRC); + stat->ets_sendErr = 0; + stat->ets_OVW = 0; + stat->ets_CRCerr = e1000_reg_read(e, E1000_REG_CRCERRS); + stat->ets_frameAll = 0; + stat->ets_missedP = e1000_reg_read(e, E1000_REG_MPC); + stat->ets_packetR = e1000_reg_read(e, E1000_REG_TPR); + stat->ets_packetT = e1000_reg_read(e, E1000_REG_TPT); + stat->ets_collision = e1000_reg_read(e, E1000_REG_COLC); + stat->ets_transAb = 0; + stat->ets_carrSense = 0; + stat->ets_fifoUnder = 0; + stat->ets_fifoOver = 0; + stat->ets_CDheartbeat = 0; + stat->ets_OWC = 0; +} + +/* + * Link status has changed. Nothing to do for now. + */ +static void +e1000_link_changed(e1000_t * e) +{ + + E1000_DEBUG(4, ("%s: link_changed()\n", e->name)); } /* * Handle an interrupt. */ static void -e1000_interrupt(message * mp) +e1000_intr(unsigned int __unused mask) { e1000_t *e; u32_t cause; @@ -753,36 +563,26 @@ e1000_interrupt(message * mp) e1000_link_changed(e); if (cause & (E1000_REG_ICR_RXO | E1000_REG_ICR_RXT)) - e1000_readv_s(&e->rx_message, TRUE); + netdriver_recv(); if (cause & (E1000_REG_ICR_TXQE | E1000_REG_ICR_TXDW)) - e1000_writev_s(&e->tx_message, TRUE); + netdriver_send(); } } -/* - * Link status has changed. Nothing to do for now. - */ -static int -e1000_link_changed(e1000_t * e) -{ - - E1000_DEBUG(4, ("%s: link_changed()\n", e->name)); - return FALSE; -} - /* * Stop the card. */ static void -e1000_stop(e1000_t *e) +e1000_stop(void) { + e1000_t *e; + + e = &e1000_state; E1000_DEBUG(3, ("%s: stop()\n", e->name)); e1000_reset_hw(e); - - exit(EXIT_SUCCESS); } /* @@ -851,9 +651,8 @@ e1000_reg_unset(e1000_t * e, uint32_t reg, uint32_t value) * Read from EEPROM. */ static u16_t -eeprom_eerd(void * v, int reg) +eeprom_eerd(e1000_t * e, int reg) { - e1000_t *e = (e1000_t *)v; u32_t data; /* Request EEPROM read. */ @@ -883,7 +682,7 @@ eeprom_ich_init(e1000_t * e) if (hsfsts.hsf_status.fldesvalid == 0) { E1000_DEBUG(3, ("Flash descriptor invalid. " "SW Sequencing must be used.")); - goto out; + return ret_val; } /* Clear FCERR and DAEL in hw status by writing 1 */ @@ -935,7 +734,7 @@ eeprom_ich_init(e1000_t * e) ("Flash controller busy, cannot get access")); } } -out: + return ret_val; } @@ -975,7 +774,7 @@ eeprom_ich_cycle(e1000_t * e, u32_t timeout) * Read from ICH8 flash. */ static u16_t -eeprom_ich(void * v, int reg) +eeprom_ich(e1000_t * e, int reg) { union ich8_hws_flash_status hsfsts; union ich8_hws_flash_ctrl hsflctl; @@ -983,13 +782,12 @@ eeprom_ich(void * v, int reg) u32_t flash_data = 0; int ret_val = -1; u8_t count = 0; - e1000_t *e = (e1000_t *)v; u16_t data = 0; E1000_DEBUG(3, ("e1000_read_flash_data_ich8lan")); if (reg > ICH_FLASH_LINEAR_ADDR_MASK) - goto out; + return data; reg *= sizeof(u16_t); flash_linear_addr = (ICH_FLASH_LINEAR_ADDR_MASK & reg) + @@ -1010,7 +808,7 @@ eeprom_ich(void * v, int reg) E1000_WRITE_FLASH_REG16(e, ICH_FLASH_HSFCTL, hsflctl.regval); E1000_WRITE_FLASH_REG(e, ICH_FLASH_FADDR, flash_linear_addr); - ret_val = eeprom_ich_cycle(v, ICH_FLASH_READ_COMMAND_TIMEOUT); + ret_val = eeprom_ich_cycle(e, ICH_FLASH_READ_COMMAND_TIMEOUT); /* * Check if FCERR is set to 1, if set to 1, clear it and try @@ -1043,59 +841,5 @@ eeprom_ich(void * v, int reg) } } while (count++ < ICH_FLASH_CYCLE_REPEAT_COUNT); -out: return data; } - -/* - * Reply to a task request from Inet. - */ -static void -reply(e1000_t *e) -{ - message msg; - int r; - - /* Only reply to client for read/write request. */ - if (!(e->status & E1000_READING || e->status & E1000_WRITING)) - return; - - /* Construct reply message. */ - msg.m_type = DL_TASK_REPLY; - msg.m_netdrv_net_dl_task.flags = DL_NOFLAGS; - msg.m_netdrv_net_dl_task.count = 0; - - /* Did we successfully receive packet(s)? */ - if (e->status & E1000_READING && e->status & E1000_RECEIVED) { - msg.m_netdrv_net_dl_task.flags |= DL_PACK_RECV; - msg.m_netdrv_net_dl_task.count = - e->rx_size >= ETH_MIN_PACK_SIZE ? - e->rx_size : ETH_MIN_PACK_SIZE; - - /* Clear flags. */ - e->status &= ~(E1000_READING | E1000_RECEIVED); - } - - /* Did we successfully transmit packet(s)? */ - if (e->status & E1000_TRANSMIT && e->status & E1000_WRITING) { - msg.m_netdrv_net_dl_task.flags |= DL_PACK_SEND; - - /* Clear flags. */ - e->status &= ~(E1000_WRITING | E1000_TRANSMIT); - } - - /* Acknowledge to INET. */ - if ((r = ipc_send(e->client, &msg)) != OK) - panic("ipc_send() failed: %d", r); -} - -/* - * Send a reply to Inet. - */ -static void -mess_reply(message *req, message *reply_mess) -{ - - if (ipc_send(req->m_source, reply_mess) != OK) - panic("unable to send reply message"); -} diff --git a/minix/drivers/net/e1000/e1000.h b/minix/drivers/net/e1000/e1000.h index d1e26dd72..f97b437e7 100644 --- a/minix/drivers/net/e1000/e1000.h +++ b/minix/drivers/net/e1000/e1000.h @@ -18,13 +18,6 @@ #ifndef __E1000_H #define __E1000_H -#include -#include -#include -#include -#include -#include -#include #include "e1000_hw.h" /** @@ -38,14 +31,11 @@ /** Number of transmit descriptors per card. */ #define E1000_TXDESC_NR 256 -/** Number of I/O vectors to use. */ -#define E1000_IOVEC_NR 16 - /** Size of each I/O buffer per descriptor. */ #define E1000_IOBUF_SIZE 2048 /** Debug verbosity. */ -#define E1000_VERBOSE 1 +#define E1000_VERBOSE 0 /** MAC address override variable. */ #define E1000_ENVVAR "E1000ETH" @@ -59,24 +49,6 @@ * @{ */ -/** Card has been detected on the PCI bus. */ -#define E1000_DETECTED (1 << 0) - -/** Card is enabled. */ -#define E1000_ENABLED (1 << 1) - -/** Client has requested to receive packets. */ -#define E1000_READING (1 << 2) - -/** Client has requested to write packets. */ -#define E1000_WRITING (1 << 3) - -/** Received some packets on the card. */ -#define E1000_RECEIVED (1 << 4) - -/** Transmitted some packets on the card. */ -#define E1000_TRANSMIT (1 << 5) - /** * @} */ @@ -141,36 +113,25 @@ typedef struct e1000 { char name[8]; /**< String containing the device name. */ - int status; /**< Describes the card's current state. */ int irq; /**< Interrupt Request Vector. */ int irq_hook; /**< Interrupt Request Vector Hook. */ - int revision; /**< Hardware Revision Number. */ u8_t *regs; /**< Memory mapped hardware registers. */ u8_t *flash; /**< Optional flash memory. */ u32_t flash_base_addr; /**< Flash base address. */ - ether_addr_t address; /**< Ethernet MAC address. */ - u16_t (*eeprom_read)(void *, int reg); /**< Function to read - the EEPROM. */ + u16_t (*eeprom_read)(struct e1000 *, int reg); + /**< Function to read the EEPROM. */ int eeprom_done_bit; /**< Offset of the EERD.DONE bit. */ int eeprom_addr_off; /**< Offset of the EERD.ADDR field. */ e1000_rx_desc_t *rx_desc; /**< Receive Descriptor table. */ - phys_bytes rx_desc_p; /**< Physical Receive Descriptor Address. */ int rx_desc_count; /**< Number of Receive Descriptors. */ char *rx_buffer; /**< Receive buffer returned by malloc(). */ int rx_buffer_size; /**< Size of the receive buffer. */ e1000_tx_desc_t *tx_desc; /**< Transmit Descriptor table. */ - phys_bytes tx_desc_p; /**< Physical Transmit Descriptor Address. */ int tx_desc_count; /**< Number of Transmit Descriptors. */ char *tx_buffer; /**< Transmit buffer returned by malloc(). */ int tx_buffer_size; /**< Size of the transmit buffer. */ - - int client; /**< Process ID being served by e1000. */ - message rx_message; /**< Read message received from client. */ - message tx_message; /**< Write message received from client. */ - size_t rx_size; /**< Size of one packet received. */ -} -e1000_t; +} e1000_t; #endif /* __E1000_H */