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[/] [openrisc/] [trunk/] [rtos/] [ecos-2.0/] [packages/] [devs/] [eth/] [powerpc/] [quicc/] [v2_0/] [src/] [if_quicc.c] - Rev 365
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//========================================================================== // // dev/if_quicc.c // // Ethernet device driver for PowerPC QUICC (MPC8xx) boards // //========================================================================== //####ECOSGPLCOPYRIGHTBEGIN#### // ------------------------------------------- // This file is part of eCos, the Embedded Configurable Operating System. // Copyright (C) 1998, 1999, 2000, 2001, 2002 Red Hat, Inc. // Copyright (C) 2002 Gary Thomas // Copyright (C) 2003 Nick Garnett <nickg@calivar.com> // // eCos is free software; you can redistribute it and/or modify it under // the terms of the GNU General Public License as published by the Free // Software Foundation; either version 2 or (at your option) any later version. // // eCos is distributed in the hope that it will be useful, but WITHOUT ANY // WARRANTY; without even the implied warranty of MERCHANTABILITY or // FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License // for more details. // // You should have received a copy of the GNU General Public License along // with eCos; if not, write to the Free Software Foundation, Inc., // 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA. // // As a special exception, if other files instantiate templates or use macros // or inline functions from this file, or you compile this file and link it // with other works to produce a work based on this file, this file does not // by itself cause the resulting work to be covered by the GNU General Public // License. However the source code for this file must still be made available // in accordance with section (3) of the GNU General Public License. // // This exception does not invalidate any other reasons why a work based on // this file might be covered by the GNU General Public License. // // Alternative licenses for eCos may be arranged by contacting the copyright // holders. // ------------------------------------------- //####ECOSGPLCOPYRIGHTEND#### //####BSDCOPYRIGHTBEGIN#### // // ------------------------------------------- // // Portions of this software may have been derived from OpenBSD or other sources, // and are covered by the appropriate copyright disclaimers included herein. // // ------------------------------------------- // //####BSDCOPYRIGHTEND#### //========================================================================== //#####DESCRIPTIONBEGIN#### // // Author(s): gthomas // Contributors: gthomas, nickg // Date: 2000-01-10 // Purpose: // Description: hardware driver for MPC8xx QUICC // // //####DESCRIPTIONEND#### // //========================================================================== // Ethernet device driver for MPC8xx QUICC #include <pkgconf/system.h> #include <pkgconf/devs_eth_powerpc_quicc.h> #include <pkgconf/io_eth_drivers.h> #ifdef CYGPKG_NET #include <pkgconf/net.h> #endif #include <cyg/infra/cyg_type.h> #include <cyg/infra/diag.h> #include <cyg/hal/hal_arch.h> #include <cyg/hal/hal_cache.h> #include <cyg/hal/hal_intr.h> #include <cyg/hal/drv_api.h> #include <cyg/io/eth/netdev.h> #include <cyg/io/eth/eth_drv.h> #include "quicc_eth.h" static unsigned char quicc_eth_rxbufs[CYGNUM_DEVS_ETH_POWERPC_QUICC_RxNUM] [CYGNUM_DEVS_ETH_POWERPC_QUICC_BUFSIZE]; static unsigned char quicc_eth_txbufs[CYGNUM_DEVS_ETH_POWERPC_QUICC_TxNUM] [CYGNUM_DEVS_ETH_POWERPC_QUICC_BUFSIZE]; static struct quicc_eth_info quicc_eth0_info; static unsigned char _default_enaddr[] = { 0x08, 0x00, 0x3E, 0x28, 0x79, 0xB8}; static unsigned char enaddr[6]; #ifdef CYGPKG_REDBOOT #include <pkgconf/redboot.h> #ifdef CYGSEM_REDBOOT_FLASH_CONFIG #include <redboot.h> #include <flash_config.h> RedBoot_config_option("Network hardware address [MAC]", quicc_esa, ALWAYS_ENABLED, true, CONFIG_ESA, 0 ); #endif #endif // For fetching the ESA from RedBoot #include <cyg/hal/hal_if.h> #ifndef CONFIG_ESA #define CONFIG_ESA 6 #endif ETH_DRV_SC(quicc_eth0_sc, &quicc_eth0_info, // Driver specific data "eth0", // Name for this interface quicc_eth_start, quicc_eth_stop, quicc_eth_control, quicc_eth_can_send, quicc_eth_send, quicc_eth_recv, quicc_eth_deliver, quicc_eth_int, quicc_eth_int_vector); NETDEVTAB_ENTRY(quicc_netdev, "quicc_eth", quicc_eth_init, &quicc_eth0_sc); // LED activity [exclusive of hardware bits] #ifndef _get_led #define _get_led() #define _set_led(v) #endif #ifndef LED_TxACTIVE #define LED_TxACTIVE 7 #define LED_RxACTIVE 6 #define LED_IntACTIVE 5 #endif static void set_led(int bit) { _set_led(_get_led() | (1<<bit)); } static void clear_led(int bit) { _set_led(_get_led() & ~(1<<bit)); } #ifdef CYGINT_IO_ETH_INT_SUPPORT_REQUIRED static cyg_interrupt quicc_eth_interrupt; static cyg_handle_t quicc_eth_interrupt_handle; #endif static void quicc_eth_int(struct eth_drv_sc *data); #ifdef CYGINT_IO_ETH_INT_SUPPORT_REQUIRED // This ISR is called when the ethernet interrupt occurs static int quicc_eth_isr(cyg_vector_t vector, cyg_addrword_t data, HAL_SavedRegisters *regs) { cyg_drv_interrupt_mask(QUICC_ETH_INT); cyg_drv_interrupt_acknowledge(QUICC_ETH_INT); return (CYG_ISR_HANDLED|CYG_ISR_CALL_DSR); // Run the DSR } #endif // Deliver function (ex-DSR) handles the ethernet [logical] processing static void quicc_eth_deliver(struct eth_drv_sc * sc) { quicc_eth_int(sc); #ifdef CYGINT_IO_ETH_INT_SUPPORT_REQUIRED // Allow interrupts to happen again cyg_drv_interrupt_unmask(QUICC_ETH_INT); #endif } // // Initialize the interface - performed at system startup // This function must set up the interface, including arranging to // handle interrupts, etc, so that it may be "started" cheaply later. // static bool quicc_eth_init(struct cyg_netdevtab_entry *tab) { struct eth_drv_sc *sc = (struct eth_drv_sc *)tab->device_instance; struct quicc_eth_info *qi = (struct quicc_eth_info *)sc->driver_private; volatile EPPC *eppc = (volatile EPPC *)eppc_base(); struct cp_bufdesc *rxbd, *txbd; unsigned char *RxBUF, *TxBUF, *ep, *ap; volatile struct ethernet_pram *enet_pram; volatile struct scc_regs *scc; int TxBD, RxBD; int cache_state; int i; bool esa_ok = false; #ifdef QUICC_ETH_FETCH_ESA QUICC_ETH_FETCH_ESA(esa_ok); #endif if (!esa_ok) { #if defined(CYGPKG_REDBOOT) && \ defined(CYGSEM_REDBOOT_FLASH_CONFIG) esa_ok = flash_get_config("quicc_esa", enaddr, CONFIG_ESA); #else esa_ok = CYGACC_CALL_IF_FLASH_CFG_OP(CYGNUM_CALL_IF_FLASH_CFG_GET, "quicc_esa", enaddr, CONFIG_ESA); #endif if (!esa_ok) { // Can't figure out ESA diag_printf("QUICC_ETH - Warning! ESA unknown\n"); memcpy(&enaddr, &_default_enaddr, sizeof(enaddr)); } } // Ensure consistent state between cache and what the QUICC sees HAL_DCACHE_IS_ENABLED(cache_state); HAL_DCACHE_SYNC(); HAL_DCACHE_DISABLE(); #ifdef CYGINT_IO_ETH_INT_SUPPORT_REQUIRED // Set up to handle interrupts cyg_drv_interrupt_create(QUICC_ETH_INT, CYGARC_SIU_PRIORITY_HIGH, (cyg_addrword_t)sc, // Data item passed to interrupt handler (cyg_ISR_t *)quicc_eth_isr, (cyg_DSR_t *)eth_drv_dsr, &quicc_eth_interrupt_handle, &quicc_eth_interrupt); cyg_drv_interrupt_attach(quicc_eth_interrupt_handle); cyg_drv_interrupt_acknowledge(QUICC_ETH_INT); cyg_drv_interrupt_unmask(QUICC_ETH_INT); #endif qi->pram = enet_pram = &eppc->pram[QUICC_ETH_SCC].enet_scc; qi->ctl = scc = &eppc->scc_regs[QUICC_ETH_SCC]; // Use SCCx // Shut down ethernet, in case it is already running scc->scc_gsmr_l &= ~(QUICC_SCC_GSML_ENR | QUICC_SCC_GSML_ENT); memset((void *)enet_pram, 0, sizeof(*enet_pram)); TxBD = _mpc8xx_allocBd(CYGNUM_DEVS_ETH_POWERPC_QUICC_TxNUM * sizeof(struct cp_bufdesc)); RxBD = _mpc8xx_allocBd(CYGNUM_DEVS_ETH_POWERPC_QUICC_RxNUM * sizeof(struct cp_bufdesc)); txbd = (struct cp_bufdesc *)((char *)eppc + TxBD); rxbd = (struct cp_bufdesc *)((char *)eppc + RxBD); qi->tbase = txbd; qi->txbd = txbd; qi->tnext = txbd; qi->rbase = rxbd; qi->rxbd = rxbd; qi->rnext = rxbd; qi->txactive = 0; RxBUF = &quicc_eth_rxbufs[0][0]; TxBUF = &quicc_eth_txbufs[0][0]; // setup buffer descriptors for (i = 0; i < CYGNUM_DEVS_ETH_POWERPC_QUICC_RxNUM; i++) { rxbd->length = 0; rxbd->buffer = RxBUF; rxbd->ctrl = QUICC_BD_CTL_Ready | QUICC_BD_CTL_Int; RxBUF += CYGNUM_DEVS_ETH_POWERPC_QUICC_BUFSIZE; rxbd++; } rxbd--; rxbd->ctrl |= QUICC_BD_CTL_Wrap; // Last buffer for (i = 0; i < CYGNUM_DEVS_ETH_POWERPC_QUICC_TxNUM; i++) { txbd->length = 0; txbd->buffer = TxBUF; txbd->ctrl = 0; TxBUF += CYGNUM_DEVS_ETH_POWERPC_QUICC_BUFSIZE; txbd++; } txbd--; txbd->ctrl |= QUICC_BD_CTL_Wrap; // Last buffer // Set up parallel ports for connection to ethernet tranceiver eppc->pio_papar |= (QUICC_ETH_PA_RXD | QUICC_ETH_PA_TXD); eppc->pio_padir &= ~(QUICC_ETH_PA_RXD | QUICC_ETH_PA_TXD); eppc->pio_paodr &= ~QUICC_ETH_PA_TXD; eppc->pio_pcpar &= ~(QUICC_ETH_PC_COLLISION | QUICC_ETH_PC_Rx_ENABLE); eppc->pio_pcdir &= ~(QUICC_ETH_PC_COLLISION | QUICC_ETH_PC_Rx_ENABLE); eppc->pio_pcso |= (QUICC_ETH_PC_COLLISION | QUICC_ETH_PC_Rx_ENABLE); eppc->pio_papar |= (QUICC_ETH_PA_Tx_CLOCK | QUICC_ETH_PA_Rx_CLOCK); eppc->pio_padir &= ~(QUICC_ETH_PA_Tx_CLOCK | QUICC_ETH_PA_Rx_CLOCK); // Set up clock routing eppc->si_sicr &= ~QUICC_ETH_SICR_MASK; eppc->si_sicr |= QUICC_ETH_SICR_ENET; eppc->si_sicr &= ~QUICC_ETH_SICR_ENABLE; // Set up DMA mode eppc->dma_sdcr = 0x0001; // Initialize shared PRAM enet_pram->rbase = RxBD; enet_pram->tbase = TxBD; // Set Big Endian mode enet_pram->rfcr = QUICC_SCC_FCR_BE; enet_pram->tfcr = QUICC_SCC_FCR_BE; // Size of receive buffers enet_pram->mrblr = CYGNUM_DEVS_ETH_POWERPC_QUICC_BUFSIZE; // Initialize CRC calculations enet_pram->c_pres = 0xFFFFFFFF; enet_pram->c_mask = 0xDEBB20E3; // Actual CRC formula enet_pram->crcec = 0; enet_pram->alec = 0; enet_pram->disfc = 0; // Frame padding enet_pram->pads = 0x8888; enet_pram->pads = 0x0000; // Retries enet_pram->ret_lim = 15; enet_pram->ret_cnt = 0; // Frame sizes enet_pram->mflr = IEEE_8023_MAX_FRAME; enet_pram->minflr = IEEE_8023_MIN_FRAME; enet_pram->maxd1 = CYGNUM_DEVS_ETH_POWERPC_QUICC_BUFSIZE; enet_pram->maxd2 = CYGNUM_DEVS_ETH_POWERPC_QUICC_BUFSIZE; // Group address hash enet_pram->gaddr1 = 0; enet_pram->gaddr2 = 0; enet_pram->gaddr3 = 0; enet_pram->gaddr4 = 0; // Device physical address ep = &enaddr[sizeof(enaddr)]; ap = (unsigned char *)&enet_pram->paddr_h; for (i = 0; i < sizeof(enaddr); i++) { *ap++ = *--ep; } // Persistence counter enet_pram->p_per = 0; // Individual address filter enet_pram->iaddr1 = 0; enet_pram->iaddr2 = 0; enet_pram->iaddr3 = 0; enet_pram->iaddr4 = 0; // Temp address enet_pram->taddr_h = 0; enet_pram->taddr_m = 0; enet_pram->taddr_l = 0; // Initialize the CPM (set up buffer pointers, etc). eppc->cp_cr = QUICC_CPM_SCCx | QUICC_CPM_CR_INIT_TXRX | QUICC_CPM_CR_BUSY; while (eppc->cp_cr & QUICC_CPM_CR_BUSY) ; // Clear any pending interrupt/exceptions scc->scc_scce = 0xFFFF; // Enable interrupts scc->scc_sccm = QUICC_SCCE_INTS | QUICC_SCCE_GRC | QUICC_SCCE_BSY; // Set up SCCx to run in ethernet mode scc->scc_gsmr_h = 0; scc->scc_gsmr_l = QUICC_SCC_GSML_TCI | QUICC_SCC_GSML_TPL_48 | QUICC_SCC_GSML_TPP_01 | QUICC_SCC_GSML_MODE_ENET; // Sync delimiters scc->scc_dsr = 0xD555; // Protocol specifics (as if GSML wasn't enough) scc->scc_psmr = QUICC_PMSR_ENET_CRC | QUICC_PMSR_SEARCH_AFTER_22 | QUICC_PMSR_RCV_SHORT_FRAMES; #ifdef QUICC_ETH_ENABLE QUICC_ETH_ENABLE(); #endif #ifdef QUICC_ETH_RESET_PHY QUICC_ETH_RESET_PHY(); #endif // Enable ethernet interface #ifdef QUICC_ETH_PC_Tx_ENABLE eppc->pio_pcpar |= QUICC_ETH_PC_Tx_ENABLE; eppc->pio_pcdir &= ~QUICC_ETH_PC_Tx_ENABLE; #else eppc->pip_pbpar |= QUICC_ETH_PB_Tx_ENABLE; eppc->pip_pbdir |= QUICC_ETH_PB_Tx_ENABLE; #endif if (cache_state) HAL_DCACHE_ENABLE(); // Initialize upper level driver (sc->funs->eth_drv->init)(sc, (unsigned char *)&enaddr); // Set LED state clear_led(LED_TxACTIVE); clear_led(LED_RxACTIVE); return true; } // // This function is called to shut down the interface. // static void quicc_eth_stop(struct eth_drv_sc *sc) { struct quicc_eth_info *qi = (struct quicc_eth_info *)sc->driver_private; volatile struct scc_regs *scc = qi->ctl; // Disable the device! scc->scc_gsmr_l &= ~(QUICC_SCC_GSML_ENR | QUICC_SCC_GSML_ENT); } // // This function is called to "start up" the interface. It may be called // multiple times, even when the hardware is already running. It will be // called whenever something "hardware oriented" changes and should leave // the hardware ready to send/receive packets. // static void quicc_eth_start(struct eth_drv_sc *sc, unsigned char *enaddr, int flags) { struct quicc_eth_info *qi = (struct quicc_eth_info *)sc->driver_private; volatile struct scc_regs *scc = qi->ctl; // Enable the device! scc->scc_gsmr_l |= QUICC_SCC_GSML_ENR | QUICC_SCC_GSML_ENT; } // // This function is called for low level "control" operations // static int quicc_eth_control(struct eth_drv_sc *sc, unsigned long key, void *data, int length) { switch (key) { case ETH_DRV_SET_MAC_ADDRESS: return 0; break; #ifdef ETH_DRV_GET_IF_STATS case ETH_DRV_GET_IF_STATS: { struct ether_drv_stats *p = (struct ether_drv_stats *)data; struct quicc_eth_info *qi = (struct quicc_eth_info *)sc->driver_private; strcpy( p->description, "QUICC (MPC8xx) SCC Ethernet" ); CYG_ASSERT( 48 > strlen(p->description), "Description too long" ); // Really need to determine the following values properly, for // now just assume the link is up, full duplex, unknown speed. p->operational = 3; // LINK UP p->duplex = 1; p->speed = 0; { p->supports_dot3 = false; // Those commented out are not available on this chip. p->tx_good = qi->tx_good ; //p->tx_max_collisions = qi->tx_max_collisions ; p->tx_late_collisions = qi->tx_late_collisions ; p->tx_underrun = qi->tx_underrun ; p->tx_carrier_loss = qi->tx_carrier_loss ; p->tx_deferred = qi->tx_deferred ; //p->tx_sqetesterrors = qi->tx_sqetesterrors ; //p->tx_single_collisions = qi->tx_single_collisions; //p->tx_mult_collisions = qi->tx_mult_collisions ; //p->tx_total_collisions = qi->tx_total_collisions ; p->rx_good = qi->rx_good ; p->rx_crc_errors = qi->rx_crc_errors ; p->rx_align_errors = qi->rx_align_errors ; p->rx_resource_errors = qi->rx_resource_errors ; p->rx_overrun_errors = qi->rx_overrun_errors ; p->rx_collisions = qi->rx_collisions ; p->rx_short_frames = qi->rx_short_frames ; p->rx_too_long_frames = qi->rx_long_frames ; //p->rx_symbol_errors = qi->rx_symbol_errors ; p->interrupts = qi->interrupts ; p->rx_count = qi->rx_count ; p->rx_deliver = qi->rx_deliver ; p->rx_resource = qi->rx_resource ; p->rx_restart = qi->rx_restart ; p->tx_count = qi->tx_count ; p->tx_complete = qi->tx_complete ; p->tx_dropped = qi->tx_dropped ; } p->tx_queue_len = CYGNUM_DEVS_ETH_POWERPC_QUICC_TxNUM; return 0; // OK } #endif default: return 1; break; } } // // This function is called to see if another packet can be sent. // It should return the number of packets which can be handled. // Zero should be returned if the interface is busy and can not send any more. // static int quicc_eth_can_send(struct eth_drv_sc *sc) { struct quicc_eth_info *qi = (struct quicc_eth_info *)sc->driver_private; return (qi->txactive < CYGNUM_DEVS_ETH_POWERPC_QUICC_TxNUM); } // // This routine is called to send data to the hardware. static void quicc_eth_send(struct eth_drv_sc *sc, struct eth_drv_sg *sg_list, int sg_len, int total_len, unsigned long key) { struct quicc_eth_info *qi = (struct quicc_eth_info *)sc->driver_private; volatile struct cp_bufdesc *txbd, *txfirst; volatile char *bp; int i, txindex, cache_state; unsigned int ctrl; qi->tx_count++; // Find a free buffer txbd = txfirst = qi->txbd; if ((txbd->ctrl & (QUICC_BD_CTL_Ready | QUICC_BD_CTL_Int ))) #ifdef CYGPKG_NET panic ("No free xmit buffers"); #else diag_printf("QUICC Ethernet: No free xmit buffers\n"); #endif // Remember the next buffer to try if (txbd->ctrl & QUICC_BD_CTL_Wrap) { qi->txbd = qi->tbase; } else { qi->txbd = txbd+1; } txindex = ((unsigned long)txbd - (unsigned long)qi->tbase) / sizeof(*txbd); qi->txkey[txindex] = key; // Set up buffer txbd->length = total_len; bp = txbd->buffer; for (i = 0; i < sg_len; i++) { memcpy((void *)bp, (void *)sg_list[i].buf, sg_list[i].len); bp += sg_list[i].len; } // Note: the MPC8xx does not seem to snoop/invalidate the data cache properly! HAL_DCACHE_IS_ENABLED(cache_state); if (cache_state) { HAL_DCACHE_FLUSH(txbd->buffer, txbd->length); // Make sure no stale data } // Send it on it's way ctrl = txbd->ctrl & ~QUICC_BD_TX_PAD; if (txbd->length < IEEE_8023_MIN_FRAME) { ctrl |= QUICC_BD_TX_PAD; } txbd->ctrl = ctrl | QUICC_BD_CTL_Ready | QUICC_BD_CTL_Int | QUICC_BD_TX_LAST | QUICC_BD_TX_TC; qi->txactive++; set_led(LED_TxACTIVE); } // // This function is called when a packet has been received. It's job is // to prepare to unload the packet from the hardware. Once the length of // the packet is known, the upper layer of the driver can be told. When // the upper layer is ready to unload the packet, the internal function // 'quicc_eth_recv' will be called to actually fetch it from the hardware. // static void quicc_eth_RxEvent(struct eth_drv_sc *sc) { struct quicc_eth_info *qi = (struct quicc_eth_info *)sc->driver_private; volatile struct cp_bufdesc *rxbd; rxbd = qi->rnext; while ((rxbd->ctrl & (QUICC_BD_CTL_Ready | QUICC_BD_CTL_Int)) == QUICC_BD_CTL_Int) { qi->rx_count++; if( rxbd->ctrl & QUICC_BD_RX_MISS ) { qi->rx_miss++; } if( rxbd->ctrl & QUICC_BD_RX_LG ) { qi->rx_long_frames++; } if( rxbd->ctrl & QUICC_BD_RX_NO ) { qi->rx_align_errors++; } if( rxbd->ctrl & QUICC_BD_RX_SH ) { qi->rx_short_frames++; } if( rxbd->ctrl & QUICC_BD_RX_CR ) { qi->rx_crc_errors++; } if( rxbd->ctrl & QUICC_BD_RX_OV ) { qi->rx_overrun_errors++; } if( rxbd->ctrl & QUICC_BD_RX_CL ) { qi->rx_collisions++; } if( (rxbd->ctrl & QUICC_BD_RX_ERRORS) == 0 ) { qi->rx_good++; // OK frame - Prepare for callback qi->rxbd = rxbd; // Save for callback set_led(LED_RxACTIVE); (sc->funs->eth_drv->recv)(sc, rxbd->length); clear_led(LED_RxACTIVE); } // Clear flags and wrap if needed else step up BD pointer if (rxbd->ctrl & QUICC_BD_CTL_Wrap) { rxbd->ctrl = QUICC_BD_CTL_Ready | QUICC_BD_CTL_Int | QUICC_BD_CTL_Wrap; rxbd = qi->rbase; } else { rxbd->ctrl = QUICC_BD_CTL_Ready | QUICC_BD_CTL_Int; rxbd++; } } // Remember where we left off qi->rnext = (struct cp_bufdesc *)rxbd; } // // This function is called as a result of the "eth_drv_recv()" call above. // It's job is to actually fetch data for a packet from the hardware once // memory buffers have been allocated for the packet. Note that the buffers // may come in pieces, using a scatter-gather list. This allows for more // efficient processing in the upper layers of the stack. // static void quicc_eth_recv(struct eth_drv_sc *sc, struct eth_drv_sg *sg_list, int sg_len) { struct quicc_eth_info *qi = (struct quicc_eth_info *)sc->driver_private; unsigned char *bp; int i, cache_state; int sg_list_null_buffer = 0; bp = (unsigned char *)qi->rxbd->buffer; // Note: the MPC8xx does not seem to snoop/invalidate the data cache properly! HAL_DCACHE_IS_ENABLED(cache_state); if (cache_state) { HAL_DCACHE_INVALIDATE(qi->rxbd->buffer, qi->rxbd->length); // Make sure no stale data } for (i = 0; i < sg_len; i++) { if (sg_list[i].buf != 0) { memcpy((void *)sg_list[i].buf, bp, sg_list[i].len); bp += sg_list[i].len; } else sg_list_null_buffer = 1; } // A NULL sg_list buffer usually means no mbufs, so we don't count // it as a delivery, instead we count it as a resource error. if (!sg_list_null_buffer) qi->rx_deliver++; else qi->rx_resource++; } static void quicc_eth_command( struct eth_drv_sc *sc, unsigned long cmd) { volatile EPPC *eppc = (volatile EPPC *)eppc_base(); eppc->cp_cr = QUICC_CPM_SCCx | cmd | QUICC_CPM_CR_BUSY; while (eppc->cp_cr & QUICC_CPM_CR_BUSY ) continue; } static void quicc_eth_TxEvent(struct eth_drv_sc *sc, int stat) { struct quicc_eth_info *qi = (struct quicc_eth_info *)sc->driver_private; volatile struct cp_bufdesc *txbd; int txindex; bool restart = false; txbd = qi->tnext; while ((txbd->ctrl & (QUICC_BD_CTL_Ready | QUICC_BD_CTL_Int)) == QUICC_BD_CTL_Int) { txindex = ((unsigned long)txbd - (unsigned long)qi->tbase) / sizeof(*txbd); qi->tx_complete++; (sc->funs->eth_drv->tx_done)(sc, qi->txkey[txindex], 0); txbd->ctrl &= ~QUICC_BD_CTL_Int; // Reset int pending bit if (txbd->ctrl & QUICC_BD_TX_LC ) qi->tx_late_collisions++, restart = true; if (txbd->ctrl & QUICC_BD_TX_RL ) qi->tx_retransmit_error++, restart = true; if (txbd->ctrl & QUICC_BD_TX_UN ) qi->tx_underrun++, restart = true; if (txbd->ctrl & QUICC_BD_TX_CSL ) qi->tx_carrier_loss++; if (txbd->ctrl & QUICC_BD_TX_HB ) qi->tx_heartbeat_loss++; if (txbd->ctrl & QUICC_BD_TX_DEF ) qi->tx_deferred++; if( (txbd->ctrl & QUICC_BD_TX_ERRORS) == 0 ) qi->tx_good++; if (txbd->ctrl & QUICC_BD_CTL_Wrap) { txbd->ctrl = QUICC_BD_CTL_Wrap; txbd = qi->tbase; } else { txbd->ctrl = 0; txbd++; } qi->txactive--; } if (qi->txactive == 0) { clear_led(LED_TxACTIVE); } // Remember where we left off qi->tnext = (struct cp_bufdesc *)txbd; if (restart) { quicc_eth_command(sc,QUICC_CPM_CR_RESTART_TX); qi->tx_restart++; } } // // Interrupt processing // static void quicc_eth_int(struct eth_drv_sc *sc) { struct quicc_eth_info *qi = (struct quicc_eth_info *)sc->driver_private; volatile struct scc_regs *scc = qi->ctl; unsigned short scce; qi->interrupts++; while ( (scce = scc->scc_scce) != 0 ) { scc->scc_scce = scce; if ( (scce & (QUICC_SCCE_TXE | QUICC_SCCE_TX)) != 0) { quicc_eth_TxEvent(sc, scce); } if ( (scce & ( QUICC_SCCE_RXF | QUICC_SCCE_RX )) != 0) { quicc_eth_RxEvent(sc); } if ( (scce & QUICC_SCCE_BSY) != 0) { qi->rx_resource_errors++; } if ( (scce & QUICC_SCCE_GRC) != 0 ) { quicc_eth_command(sc, QUICC_CPM_CR_RESTART_TX); qi->tx_restart++; quicc_eth_command(sc, QUICC_CPM_CR_HUNT_MODE); qi->rx_restart++; } } } // // Interrupt vector // static int quicc_eth_int_vector(struct eth_drv_sc *sc) { return (QUICC_ETH_INT); }
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