#include #include "DM9000A.H" #include "basic_io.h" //------------------------------------------------------------------------- void iow(unsigned int reg, unsigned int data) { IOWR(DM9000A_BASE,IO_addr,reg); usleep(STD_DELAY); IOWR(DM9000A_BASE,IO_data,data); } //------------------------------------------------------------------------- unsigned int ior(unsigned int reg) { IOWR(DM9000A_BASE,IO_addr,reg); usleep(STD_DELAY); return IORD(DM9000A_BASE,IO_data); } //------------------------------------------------------------------------- void phy_write (unsigned int reg, unsigned int value) { /* set PHY register address into EPAR REG. 0CH */ iow(0x0C, reg | 0x40); /* PHY register address setting, and DM9000_PHY offset = 0x40 */ /* fill PHY WRITE data into EPDR REG. 0EH & REG. 0DH */ iow(0x0E, ((value >> 8) & 0xFF)); /* PHY data high_byte */ iow(0x0D, value & 0xFF); /* PHY data low_byte */ /* issue PHY + WRITE command = 0xa into EPCR REG. 0BH */ iow(0x0B, 0x8); /* clear PHY command first */ IOWR(DM9000A_BASE, IO_data, 0x0A); /* issue PHY + WRITE command */ usleep(STD_DELAY); IOWR(DM9000A_BASE, IO_data, 0x08); /* clear PHY command again */ usleep(50); /* wait 1~30 us (>20 us) for PHY + WRITE completion */ } //------------------------------------------------------------------------- /* DM9000_init I/O routine */ unsigned int DM9000_init (void) /* initialize DM9000 LAN chip */ { unsigned int i; /* set the internal PHY power-on (GPIOs normal settings) */ iow(0x1E, 0x01); /* GPCR REG. 1EH = 1 selected GPIO0 "output" port for internal PHY */ iow(0x1F, 0x00); /* GPR REG. 1FH GEPIO0 Bit [0] = 0 to activate internal PHY */ msleep(5); /* wait > 2 ms for PHY power-up ready */ /* software-RESET NIC */ iow(NCR, 0x03); /* NCR REG. 00 RST Bit [0] = 1 reset on, and LBK Bit [2:1] = 01b MAC loopback on */ usleep(20); /* wait > 10us for a software-RESET ok */ iow(NCR, 0x00); /* normalize */ iow(NCR, 0x03); usleep(20); iow(NCR, 0x00); /* set GPIO0=1 then GPIO0=0 to turn off and on the internal PHY */ iow(0x1F, 0x01); /* GPR PHYPD Bit [0] = 1 turn-off PHY */ iow(0x1F, 0x00); /* PHYPD Bit [0] = 0 activate phyxcer */ msleep(10); /* wait >4 ms for PHY power-up */ /* set PHY operation mode */ phy_write(0,PHY_reset); /* reset PHY: registers back to the default states */ usleep(50); /* wait >30 us for PHY software-RESET ok */ phy_write(16, 0x404); /* turn off PHY reduce-power-down mode only */ phy_write(4, PHY_txab); /* set PHY TX advertised ability: ALL + Flow_control */ phy_write(0, 0x1200); /* PHY auto-NEGO re-start enable (RESTART_AUTO_NEGOTIATION + AUTO_NEGOTIATION_ENABLE) to auto sense and recovery PHY registers */ msleep(5); /* wait >2 ms for PHY auto-sense linking to partner */ /* store MAC address into NIC */ for (i = 0; i < 6; i++) iow(16 + i, ether_addr[i]); /* clear any pending interrupt */ iow(ISR, 0x3F); /* clear the ISR status: PRS, PTS, ROS, ROOS 4 bits, by RW/C1 */ iow(NSR, 0x2C); /* clear the TX status: TX1END, TX2END, WAKEUP 3 bits, by RW/C1 */ /* program operating registers~ */ iow(NCR, NCR_set); /* NCR REG. 00 enable the chip functions (and disable this MAC loopback mode back to normal) */ iow(0x08, BPTR_set); /* BPTR REG.08 (if necessary) RX Back Pressure Threshold in Half duplex moe only: High Water 3KB, 600 us */ iow(0x09, FCTR_set); /* FCTR REG.09 (if necessary) Flow Control Threshold setting High/ Low Water Overflow 5KB/ 10KB */ iow(0x0A, RTFCR_set); /* RTFCR REG.0AH (if necessary) RX/TX Flow Control Register enable TXPEN, BKPM (TX_Half), FLCE (RX) */ iow(0x0F, 0x00); /* Clear the all Event */ iow(0x2D, 0x80); /* Switch LED to mode 1 */ /* set other registers depending on applications */ iow(ETXCSR, ETXCSR_set); /* Early Transmit 75% */ /* enable interrupts to activate DM9000 ~on */ iow(IMR, INTR_set); /* IMR REG. FFH PAR=1 only, or + PTM=1& PRM=1 enable RxTx interrupts */ /* enable RX (Broadcast/ ALL_MULTICAST) ~go */ iow(RCR , RCR_set | RX_ENABLE | PASS_MULTICAST); /* RCR REG. 05 RXEN Bit [0] = 1 to enable the RX machine/ filter */ /* RETURN "DEVICE_SUCCESS" back to upper layer */ return (ior(0x2D)==0x80) ? DMFE_SUCCESS : DMFE_FAIL; } //------------------------------------------------------------------------- /* Transmit one Packet TX I/O routine */ unsigned int TransmitPacket(unsigned char *data_ptr,unsigned int tx_len) { unsigned int i; /* mask NIC interrupts IMR: PAR only */ iow(IMR, PAR_set); /* issue TX packet's length into TXPLH REG. FDH & TXPLL REG. FCH */ iow(0xFD, (tx_len >> 8) & 0xFF); /* TXPLH High_byte length */ iow(0xFC, tx_len & 0xFF); /* TXPLL Low_byte length */ /* wirte transmit data to chip SRAM */ IOWR(DM9000A_BASE, IO_addr, MWCMD); /* set MWCMD REG. F8H TX I/O port ready */ for (i = 0; i < tx_len; i += 2) { usleep(STD_DELAY); IOWR(DM9000A_BASE, IO_data, (data_ptr[i+1]<<8)|data_ptr[i] ); } /* issue TX polling command activated */ iow(TCR , TCR_set | TX_REQUEST); /* TXCR Bit [0] TXREQ auto clear after TX completed */ /* wait TX transmit done */ while(!(ior(NSR)&0x0C)) usleep(STD_DELAY); /* clear the NSR Register */ iow(NSR,0x00); /* re-enable NIC interrupts */ iow(IMR, INTR_set); /* RETURN "TX_SUCCESS" to upper layer */ return DMFE_SUCCESS; } //------------------------------------------------------------------------- /* Receive One Packet I/O routine */ unsigned int ReceivePacket (unsigned char *data_ptr,unsigned int *rx_len) { unsigned char rx_READY,GoodPacket; unsigned int Tmp, RxStatus, i; RxStatus = rx_len[0] = 0; GoodPacket=FALSE; /* mask NIC interrupts IMR: PAR only */ iow(IMR, PAR_set); /* dummy read a byte from MRCMDX REG. F0H */ rx_READY = ior(MRCMDX); /* got most updated byte: rx_READY */ rx_READY = IORD(DM9000A_BASE,IO_data)&0x03; usleep(STD_DELAY); /* check if (rx_READY == 0x01): Received Packet READY? */ if (rx_READY == DM9000_PKT_READY) { /* got RX_Status & RX_Length from RX SRAM */ IOWR(DM9000A_BASE, IO_addr, MRCMD); /* set MRCMD REG. F2H RX I/O port ready */ usleep(STD_DELAY); RxStatus = IORD(DM9000A_BASE,IO_data); usleep(STD_DELAY); rx_len[0] = IORD(DM9000A_BASE,IO_data); /* Check this packet_status GOOD or BAD? */ if ( !(RxStatus & 0xBF00) && (rx_len[0] < MAX_PACKET_SIZE) ) { /* read 1 received packet from RX SRAM into RX buffer */ for (i = 0; i < rx_len[0]; i += 2) { usleep(STD_DELAY); Tmp = IORD(DM9000A_BASE, IO_data); data_ptr[i] = Tmp&0xFF; data_ptr[i+1] = (Tmp>>8)&0xFF; } GoodPacket=TRUE; } /* end if (GoodPacket) */ else { /* this packet is bad, dump it from RX SRAM */ for (i = 0; i < rx_len[0]; i += 2) { usleep(STD_DELAY); Tmp = IORD(DM9000A_BASE, IO_data); } printf("\nError\n"); rx_len[0] = 0; } /* end if (!GoodPacket) */ } /* end if (rx_READY == DM9000_PKT_READY) ok */ else if(rx_READY) /* status check first byte: rx_READY Bit[1:0] must be "00"b or "01"b */ { /* software-RESET NIC */ iow(NCR, 0x03); /* NCR REG. 00 RST Bit [0] = 1 reset on, and LBK Bit [2:1] = 01b MAC loopback on */ usleep(20); /* wait > 10us for a software-RESET ok */ iow(NCR, 0x00); /* normalize */ iow(NCR, 0x03); usleep(20); iow(NCR, 0x00); /* program operating registers~ */ iow(NCR, NCR_set); /* NCR REG. 00 enable the chip functions (and disable this MAC loopback mode back to normal) */ iow(0x08, BPTR_set); /* BPTR REG.08 (if necessary) RX Back Pressure Threshold in Half duplex moe only: High Water 3KB, 600 us */ iow(0x09, FCTR_set); /* FCTR REG.09 (if necessary) Flow Control Threshold setting High/ Low Water Overflow 5KB/ 10KB */ iow(0x0A, RTFCR_set); /* RTFCR REG.0AH (if necessary) RX/TX Flow Control Register enable TXPEN, BKPM (TX_Half), FLCE (RX) */ iow(0x0F, 0x00); /* Clear the all Event */ iow(0x2D, 0x80); /* Switch LED to mode 1 */ /* set other registers depending on applications */ iow(ETXCSR, ETXCSR_set); /* Early Transmit 75% */ /* enable interrupts to activate DM9000 ~on */ iow(IMR, INTR_set); /* IMR REG. FFH PAR=1 only, or + PTM=1& PRM=1 enable RxTx interrupts */ /* enable RX (Broadcast/ ALL_MULTICAST) ~go */ iow(RCR , RCR_set | RX_ENABLE | PASS_MULTICAST); /* RCR REG. 05 RXEN Bit [0] = 1 to enable the RX machine/ filter */ } /* end NIC H/W system Data-Bus error */ return GoodPacket ? DMFE_SUCCESS : DMFE_FAIL; } //-------------------------------------------------------------------------