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[/] [openrisc/] [trunk/] [orpsocv2/] [sw/] [tests/] [ethmac/] [sim/] [ethmac-rxtxcallresponse.c] - Rev 438
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////////////////////////////////////////////////////////////////////// //// //// //// Interrupt-driven Ethernet MAC transmit test code //// //// //// //// Description //// //// Send packets while receiving packets //// //// //// //// Test data comes from pre-calculated array of random values, //// //// MAC TX buffer pointers are set to addresses in this array, //// //// saving copying the data around before transfers. //// //// //// //// Author(s): //// //// - jb, jb@orsoc.se, with parts taken from Linux kernel //// //// open_eth driver. //// //// //// //// //// ////////////////////////////////////////////////////////////////////// //// //// //// Copyright (C) 2009 Authors and OPENCORES.ORG //// //// //// //// This source file may be used and distributed without //// //// restriction provided that this copyright statement is not //// //// removed from the file and that any derivative work contains //// //// the original copyright notice and the associated disclaimer. //// //// //// //// This source file is free software; you can redistribute it //// //// and/or modify it under the terms of the GNU Lesser General //// //// Public License as published by the Free Software Foundation; //// //// either version 2.1 of the License, or (at your option) any //// //// later version. //// //// //// //// This source 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 Lesser General Public License for more //// //// details. //// //// //// //// You should have received a copy of the GNU Lesser General //// //// Public License along with this source; if not, download it //// //// from http://www.opencores.org/lgpl.shtml //// //// //// ////////////////////////////////////////////////////////////////////// #include "cpu-utils.h" #include "board.h" #include "int.h" #include "ethmac.h" #include "eth-phy-mii.h" volatile unsigned tx_done; volatile unsigned rx_done; static int next_tx_buf_num; /* Functions in this file */ void ethmac_setup(void); /* Interrupt functions */ void oeth_interrupt(void); static void oeth_rx(void); static void oeth_tx(void); /* Let the ethernet packets use a space beginning here for buffering */ #define ETH_BUFF_BASE 0x01000000 #define RXBUFF_PREALLOC 1 #define TXBUFF_PREALLOC 1 //#undef RXBUFF_PREALLOC //#undef TXBUFF_PREALLOC /* The transmitter timeout */ #define TX_TIMEOUT (2*HZ) /* Buffer number (must be 2^n) */ #define OETH_RXBD_NUM 16 #define OETH_TXBD_NUM 16 #define OETH_RXBD_NUM_MASK (OETH_RXBD_NUM-1) #define OETH_TXBD_NUM_MASK (OETH_TXBD_NUM-1) /* Buffer size */ #define OETH_RX_BUFF_SIZE 0x600-4 #define OETH_TX_BUFF_SIZE 0x600-4 /* Buffer size (if not XXBUF_PREALLOC */ #define MAX_FRAME_SIZE 1518 /* The buffer descriptors track the ring buffers. */ struct oeth_private { //struct sk_buff* rx_skbuff[OETH_RXBD_NUM]; //struct sk_buff* tx_skbuff[OETH_TXBD_NUM]; unsigned short tx_next; /* Next buffer to be sent */ unsigned short tx_last; /* Next buffer to be checked if packet sent */ unsigned short tx_full; /* Buffer ring fuul indicator */ unsigned short rx_cur; /* Next buffer to be checked if packet received */ oeth_regs *regs; /* Address of controller registers. */ oeth_bd *rx_bd_base; /* Address of Rx BDs. */ oeth_bd *tx_bd_base; /* Address of Tx BDs. */ // struct net_device_stats stats; }; #define PHYNUM 7 // Data array of data to transmit, tx_data_array[] //#include "eth-rxtx-data.h" // Not used int tx_data_pointer; void eth_mii_write(char phynum, short regnum, short data) { static volatile oeth_regs *regs = (oeth_regs *)(OETH_REG_BASE); regs->miiaddress = (regnum << 8) | phynum; regs->miitx_data = data; regs->miicommand = OETH_MIICOMMAND_WCTRLDATA; regs->miicommand = 0; while(regs->miistatus & OETH_MIISTATUS_BUSY); } short eth_mii_read(char phynum, short regnum) { static volatile oeth_regs *regs = (oeth_regs *)(OETH_REG_BASE); regs->miiaddress = (regnum << 8) | phynum; regs->miicommand = OETH_MIICOMMAND_RSTAT; regs->miicommand = 0; while(regs->miistatus & OETH_MIISTATUS_BUSY); return regs->miirx_data; } // Wait here until all packets have been transmitted void wait_until_all_tx_clear(void) { int i; volatile oeth_bd *tx_bd; tx_bd = (volatile oeth_bd *)OETH_BD_BASE; /* Search from beginning*/ int some_tx_waiting = 1; while (some_tx_waiting) { some_tx_waiting = 0; /* Go through the TX buffs, search for unused one */ for(i = 0; i < OETH_TXBD_NUM; i++) { // Looking for buffer ready for transmit if((tx_bd[i].len_status & OETH_TX_BD_READY)) some_tx_waiting = 1; } } } void ethphy_set_10mbit(int phynum) { wait_until_all_tx_clear(); // Hardset PHY to just use 10Mbit mode short cr = eth_mii_read(phynum, MII_BMCR); cr &= ~BMCR_ANENABLE; // Clear auto negotiate bit cr &= ~BMCR_SPEED100; // Clear fast eth. bit eth_mii_write(phynum, MII_BMCR, cr); } void ethphy_set_100mbit(int phynum) { wait_until_all_tx_clear(); // Hardset PHY to just use 100Mbit mode short cr = eth_mii_read(phynum, MII_BMCR); cr |= BMCR_ANENABLE; // Clear auto negotiate bit cr |= BMCR_SPEED100; // Clear fast eth. bit eth_mii_write(phynum, MII_BMCR, cr); } void ethmac_setup(void) { // from arch/or32/drivers/open_eth.c volatile oeth_regs *regs; regs = (oeth_regs *)(OETH_REG_BASE); /* Reset MII mode module */ regs->miimoder = OETH_MIIMODER_RST; /* MII Reset ON */ regs->miimoder &= ~OETH_MIIMODER_RST; /* MII Reset OFF */ regs->miimoder = 0x64; /* Clock divider for MII Management interface */ /* Reset the controller. */ regs->moder = OETH_MODER_RST; /* Reset ON */ regs->moder &= ~OETH_MODER_RST; /* Reset OFF */ /* Setting TXBD base to OETH_TXBD_NUM. */ regs->tx_bd_num = OETH_TXBD_NUM; /* Set min/max packet length */ regs->packet_len = 0x00400600; /* Set IPGT register to recomended value */ regs->ipgt = 0x12; /* Set IPGR1 register to recomended value */ regs->ipgr1 = 0x0000000c; /* Set IPGR2 register to recomended value */ regs->ipgr2 = 0x00000012; /* Set COLLCONF register to recomended value */ regs->collconf = 0x000f003f; /* Set control module mode */ #if 0 regs->ctrlmoder = OETH_CTRLMODER_TXFLOW | OETH_CTRLMODER_RXFLOW; #else regs->ctrlmoder = 0; #endif /* Clear MIIM registers */ regs->miitx_data = 0; regs->miiaddress = 0; regs->miicommand = 0; regs->mac_addr1 = ETH_MACADDR0 << 8 | ETH_MACADDR1; regs->mac_addr0 = ETH_MACADDR2 << 24 | ETH_MACADDR3 << 16 | ETH_MACADDR4 << 8 | ETH_MACADDR5; /* Clear all pending interrupts */ regs->int_src = 0xffffffff; /* Promisc, IFG, CRCEn */ regs->moder |= OETH_MODER_PRO | OETH_MODER_PAD | OETH_MODER_IFG | OETH_MODER_CRCEN | OETH_MODER_FULLD; /* Enable interrupt sources. */ regs->int_mask = OETH_INT_MASK_TXB | OETH_INT_MASK_TXE | OETH_INT_MASK_RXF | OETH_INT_MASK_RXE | OETH_INT_MASK_BUSY | OETH_INT_MASK_TXC | OETH_INT_MASK_RXC; // Buffer setup stuff volatile oeth_bd *tx_bd, *rx_bd; int i,j,k; /* Initialize TXBD pointer */ tx_bd = (volatile oeth_bd *)OETH_BD_BASE; /* Initialize RXBD pointer */ rx_bd = ((volatile oeth_bd *)OETH_BD_BASE) + OETH_TXBD_NUM; /* Preallocated ethernet buffer setup */ unsigned long mem_addr = ETH_BUFF_BASE; /* Defined at top */ // Setup TX Buffers for(i = 0; i < OETH_TXBD_NUM; i++) { //tx_bd[i].len_status = OETH_TX_BD_PAD | OETH_TX_BD_CRC | OETH_RX_BD_IRQ; tx_bd[i].len_status = OETH_TX_BD_PAD | OETH_TX_BD_CRC; tx_bd[i].addr = mem_addr; mem_addr += OETH_TX_BUFF_SIZE; } tx_bd[OETH_TXBD_NUM - 1].len_status |= OETH_TX_BD_WRAP; // Setup RX buffers for(i = 0; i < OETH_RXBD_NUM; i++) { rx_bd[i].len_status = OETH_RX_BD_EMPTY | OETH_RX_BD_IRQ; // Init. with IRQ rx_bd[i].addr = mem_addr; mem_addr += OETH_RX_BUFF_SIZE; } rx_bd[OETH_RXBD_NUM - 1].len_status |= OETH_RX_BD_WRAP; // Last buffer wraps /* Enable RX and TX in MAC */ regs->moder &= ~(OETH_MODER_RXEN | OETH_MODER_TXEN); regs->moder |= OETH_MODER_RXEN | OETH_MODER_TXEN; next_tx_buf_num = 0; // init tx buffer pointer return; } // Enable RX in ethernet MAC void oeth_enable_rx(void) { volatile oeth_regs *regs; regs = (oeth_regs *)(OETH_REG_BASE); regs->moder |= OETH_MODER_RXEN; } // Disable RX in ethernet MAC void oeth_disable_rx(void) { volatile oeth_regs *regs; regs = (oeth_regs *)(OETH_REG_BASE); regs->moder &= ~(OETH_MODER_RXEN); } /* Setup buffer descriptors with data */ /* length is in BYTES */ void tx_packet(void* data, int length) { volatile oeth_regs *regs; regs = (oeth_regs *)(OETH_REG_BASE); volatile oeth_bd *tx_bd; volatile int i; tx_bd = (volatile oeth_bd *)OETH_BD_BASE; tx_bd = (struct oeth_bd*) &tx_bd[next_tx_buf_num]; // If it's in use - wait while ((tx_bd->len_status & OETH_TX_BD_IRQ)); /* Clear all of the status flags. */ tx_bd->len_status &= ~OETH_TX_BD_STATS; /* If the frame is short, tell CPM to pad it. */ #define ETH_ZLEN 60 /* Min. octets in frame sans FCS */ if (length <= ETH_ZLEN) tx_bd->len_status |= OETH_TX_BD_PAD; else tx_bd->len_status &= ~OETH_TX_BD_PAD; #ifdef _ETH_RXTX_DATA_H_ // Set the address pointer to the place // in memory where the data is and transmit from there tx_bd->addr = (char*) &tx_data_array[tx_data_pointer&~(0x3)]; tx_data_pointer += length + 1; if (tx_data_pointer > (255*1024)) tx_data_pointer = 0; #else if (data){ //Copy the data into the transmit buffer, byte at a time char* data_p = (char*) data; char* data_b = (char*) tx_bd->addr; for(i=0;i<length;i++) { data_b[i] = data_p[i]; } } #endif /* Set the length of the packet's data in the buffer descriptor */ tx_bd->len_status = (tx_bd->len_status & 0x0000ffff) | ((length&0xffff) << 16); /* Send it on its way. Tell controller its ready, interrupt when sent * and to put the CRC on the end. */ tx_bd->len_status |= (OETH_TX_BD_READY | OETH_TX_BD_CRC | OETH_TX_BD_IRQ); next_tx_buf_num = (next_tx_buf_num + 1) & OETH_TXBD_NUM_MASK; return; } /* The interrupt handler. */ void oeth_interrupt(void) { volatile oeth_regs *regs; regs = (oeth_regs *)(OETH_REG_BASE); uint int_events; int serviced; serviced = 0; /* Get the interrupt events that caused us to be here. */ int_events = regs->int_src; regs->int_src = int_events; /* Handle receive event in its own function. */ if (int_events & (OETH_INT_RXF | OETH_INT_RXE)) { serviced |= 0x1; oeth_rx(); } /* Handle transmit event in its own function. */ if (int_events & (OETH_INT_TXB | OETH_INT_TXE)) { serviced |= 0x2; oeth_tx(); serviced |= 0x2; } /* Check for receive busy, i.e. packets coming but no place to * put them. */ if (int_events & OETH_INT_BUSY) { serviced |= 0x4; if (!(int_events & (OETH_INT_RXF | OETH_INT_RXE))) oeth_rx(); } return; } static void oeth_rx(void) { volatile oeth_regs *regs; regs = (oeth_regs *)(OETH_REG_BASE); volatile oeth_bd *rx_bdp; int pkt_len, i; int bad = 0; rx_bdp = ((oeth_bd *)OETH_BD_BASE) + OETH_TXBD_NUM; /* Find RX buffers marked as having received data */ for(i = 0; i < OETH_RXBD_NUM; i++) { bad=0; if(!(rx_bdp[i].len_status & OETH_RX_BD_EMPTY)){ /* Looking for NOT empty buffers desc. */ /* Check status for errors. */ if (rx_bdp[i].len_status & (OETH_RX_BD_TOOLONG | OETH_RX_BD_SHORT)) { bad = 1; report(0xbaad0001); } if (rx_bdp[i].len_status & OETH_RX_BD_DRIBBLE) { bad = 1; report(0xbaad0002); } if (rx_bdp[i].len_status & OETH_RX_BD_CRCERR) { bad = 1; report(0xbaad0003); } if (rx_bdp[i].len_status & OETH_RX_BD_OVERRUN) { bad = 1; report(0xbaad0004); } if (rx_bdp[i].len_status & OETH_RX_BD_MISS) { report(0xbaad0005); } if (rx_bdp[i].len_status & OETH_RX_BD_LATECOL) { bad = 1; report(0xbaad0006); } if (bad) { rx_bdp[i].len_status &= ~OETH_RX_BD_STATS; rx_bdp[i].len_status |= OETH_RX_BD_EMPTY; exit(0xbaaaaaad); continue; } else { /* Process the incoming frame. */ pkt_len = rx_bdp[i].len_status >> 16; /* finish up */ rx_bdp[i].len_status &= ~OETH_RX_BD_STATS; /* Clear stats */ rx_bdp[i].len_status |= OETH_RX_BD_EMPTY; /* Mark RX BD as empty */ rx_done++; } } } } static void oeth_tx(void) { volatile oeth_bd *tx_bd; int i; tx_bd = (volatile oeth_bd *)OETH_BD_BASE; /* Search from beginning*/ /* Go through the TX buffs, search for one that was just sent */ for(i = 0; i < OETH_TXBD_NUM; i++) { /* Looking for buffer NOT ready for transmit. and IRQ enabled */ if( (!(tx_bd[i].len_status & (OETH_TX_BD_READY))) && (tx_bd[i].len_status & (OETH_TX_BD_IRQ)) ) { /* Single threaded so no chance we have detected a buffer that has had its IRQ bit set but not its BD_READ flag. Maybe this won't work in linux */ tx_bd[i].len_status &= ~OETH_TX_BD_IRQ; /* Probably good to check for TX errors here */ /* set our test variable */ tx_done++; } } return; } // A function and defines to fill and transmit a packet #define MAX_TX_BUFFER 1532 static char tx_buffer[MAX_TX_BUFFER]; void fill_and_tx_call_packet(int size, int response_time) { int i; volatile oeth_regs *regs; regs = (oeth_regs *)(OETH_REG_BASE); volatile oeth_bd *tx_bd; tx_bd = (volatile oeth_bd *)OETH_BD_BASE; tx_bd = (volatile oeth_bd*) &tx_bd[next_tx_buf_num]; // If it's in use - wait while ((tx_bd->len_status & OETH_TX_BD_IRQ)); // Use rand() function to generate data for transmission // Assumption: ethernet buffer descriptors are 4byte aligned char* data_b = (char*) tx_bd->addr; // We will fill with words until there' less than a word to go int words_to_fill = size / sizeof(unsigned int); unsigned int* data_w = (unsigned int*) data_b; // Put first word as size of packet, second as response time data_w[0] = size; data_w[1] = response_time; for(i=2;i<words_to_fill;i++) data_w[i] = rand(); // Point data_b to offset wher word fills ended data_b += (words_to_fill * sizeof(unsigned int)); int leftover_size = size - (words_to_fill * sizeof(unsigned int)); for(i=0;i<leftover_size;i++) { data_b[i] = rand() & 0xff; } tx_packet((void*)0, size); } // Send a packet, the very first byte of which will be read by the testbench // and used to indicate which test we'll use. void send_ethmac_rxtx_test_init_packet(char test) { char cmd_tx_buffer[40]; cmd_tx_buffer[0] = test; tx_packet(cmd_tx_buffer, 40); // Smallest packet that can be sent (I think) } // Loop to check if a number is prime by doing mod divide of the number // to test by every number less than it int is_prime_number(unsigned long n) { unsigned long c; if (n < 2) return 0; for(c=2;c<n;c++) if ((n % c) == 0) return 0; return 1; } int main () { tx_data_pointer = 0; /* Initialise handler vector */ int_init(); /* Install ethernet interrupt handler, it is enabled here too */ int_add(ETH0_IRQ, oeth_interrupt, 0); /* Enable interrupts in supervisor register */ cpu_enable_user_interrupts(); /* Enable CPU timer */ cpu_enable_timer(); ethmac_setup(); /* Configure MAC, TX/RX BDs and enable RX and TX in MODER */ /* clear tx_done, the tx interrupt handler will set it when it's been transmitted */ tx_done = 0; rx_done = 0; ethphy_set_100mbit(0); send_ethmac_rxtx_test_init_packet(0x0); // 0x0 - call response test #define ETH_TX_MIN_PACKET_SIZE 512 #define ETH_TX_NUM_PACKETS (ETH_TX_MIN_PACKET_SIZE + 20) //int response_time = 150000; // Response time before response packet it sent // back (should be in nanoseconds). int response_time = 0; unsigned long num_to_check; for(num_to_check=ETH_TX_MIN_PACKET_SIZE; num_to_check<ETH_TX_NUM_PACKETS; num_to_check++) fill_and_tx_call_packet(num_to_check, response_time); // Wait a moment for the RX packet check to complete before switching off RX for(num_to_check=0;num_to_check=1000;num_to_check++); oeth_disable_rx(); // Now for 10mbit mode... ethphy_set_10mbit(0); oeth_enable_rx(); for(num_to_check=ETH_TX_MIN_PACKET_SIZE; num_to_check<ETH_TX_NUM_PACKETS; num_to_check++) fill_and_tx_call_packet(num_to_check, response_time); oeth_disable_rx(); // Go back to 100-mbit mode ethphy_set_100mbit(0); oeth_enable_rx(); for(num_to_check=ETH_TX_MIN_PACKET_SIZE; num_to_check<ETH_TX_NUM_PACKETS; num_to_check++) fill_and_tx_call_packet(num_to_check, response_time); exit(0x8000000d); }
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