15d014d131
The way the hardware and firmware work is that there is one shared RX queue and IRQ for a number of different network interfaces. Due to this, we would like to process received packets for every interface in the same NAPI poll handler, so we need a pseudo-device to schedule polling on. What the driver currently does is that it always schedules polling for the first network interface in the list, and processes packets for every interface in the poll handler for that first interface -- however, this scheme breaks down if the first network interface happens to not be up, since netif_rx_schedule_prep() checks netif_running(). sky2 apparently has the same issue, and Stephen Hemminger suggested a way to work around this: create a variant of netif_rx_schedule_prep() that does not check netif_running(). I implemented this locally and called it netif_rx_schedule_prep_notup(), and it seems to work well, but it's something that probably not everyone would be happy with. The ixp2000 is an ARM CPU with a high-speed network interface in the CPU itself (full duplex 4Gb/s or 10Gb/s depending on the IXP model.) The CPU package also contains 8 or 16 (again depending on the IXP model) 'microengines', which are somewhat primitive but very fast and efficient processor cores which can be used to offload various things from the main CPU. This driver makes the high-speed network interface in the CPU visible and usable as a regular linux network device. Currently, it only supports the Radisys ENP2611 IXP board, but adding support for other board types should be fairly easy. Signed-off-by: Lennert Buytenhek <buytenh@wantstofly.org> Signed-off-by: Jeff Garzik <jgarzik@pobox.com>
137 lines
3.1 KiB
C
137 lines
3.1 KiB
C
/*
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* Helper functions for the SPI-3 bridge FPGA on the Radisys ENP2611
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* Copyright (C) 2004, 2005 Lennert Buytenhek <buytenh@wantstofly.org>
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* Dedicated to Marija Kulikova.
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*
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* This program is free software; you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation; either version 2 of the License, or
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* (at your option) any later version.
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*/
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#include <linux/config.h>
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#include <linux/module.h>
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#include <linux/delay.h>
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#include <asm/io.h>
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#define CALEB_IDLO 0x00
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#define CALEB_IDHI 0x01
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#define CALEB_RID 0x02
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#define CALEB_RESET 0x03
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#define CALEB_INTREN0 0x04
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#define CALEB_INTREN1 0x05
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#define CALEB_INTRSTAT0 0x06
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#define CALEB_INTRSTAT1 0x07
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#define CALEB_PORTEN 0x08
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#define CALEB_BURST 0x09
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#define CALEB_PORTPAUS 0x0A
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#define CALEB_PORTPAUSD 0x0B
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#define CALEB_PHY0RX 0x10
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#define CALEB_PHY1RX 0x11
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#define CALEB_PHY0TX 0x12
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#define CALEB_PHY1TX 0x13
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#define CALEB_IXPRX_HI_CNTR 0x15
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#define CALEB_PHY0RX_HI_CNTR 0x16
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#define CALEB_PHY1RX_HI_CNTR 0x17
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#define CALEB_IXPRX_CNTR 0x18
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#define CALEB_PHY0RX_CNTR 0x19
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#define CALEB_PHY1RX_CNTR 0x1A
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#define CALEB_IXPTX_CNTR 0x1B
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#define CALEB_PHY0TX_CNTR 0x1C
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#define CALEB_PHY1TX_CNTR 0x1D
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#define CALEB_DEBUG0 0x1E
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#define CALEB_DEBUG1 0x1F
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static u8 caleb_reg_read(int reg)
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{
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u8 value;
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value = *((volatile u8 *)(ENP2611_CALEB_VIRT_BASE + reg));
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// printk(KERN_INFO "caleb_reg_read(%d) = %.2x\n", reg, value);
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return value;
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}
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static void caleb_reg_write(int reg, u8 value)
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{
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u8 dummy;
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// printk(KERN_INFO "caleb_reg_write(%d, %.2x)\n", reg, value);
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*((volatile u8 *)(ENP2611_CALEB_VIRT_BASE + reg)) = value;
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dummy = *((volatile u8 *)ENP2611_CALEB_VIRT_BASE);
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__asm__ __volatile__("mov %0, %0" : "+r" (dummy));
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}
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void caleb_reset(void)
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{
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/*
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* Perform a chip reset.
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*/
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caleb_reg_write(CALEB_RESET, 0x02);
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udelay(1);
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/*
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* Enable all interrupt sources. This is needed to get
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* meaningful results out of the status bits (register 6
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* and 7.)
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*/
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caleb_reg_write(CALEB_INTREN0, 0xff);
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caleb_reg_write(CALEB_INTREN1, 0x07);
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/*
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* Set RX and TX FIFO thresholds to 1.5kb.
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*/
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caleb_reg_write(CALEB_PHY0RX, 0x11);
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caleb_reg_write(CALEB_PHY1RX, 0x11);
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caleb_reg_write(CALEB_PHY0TX, 0x11);
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caleb_reg_write(CALEB_PHY1TX, 0x11);
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/*
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* Program SPI-3 burst size.
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*/
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caleb_reg_write(CALEB_BURST, 0); // 64-byte RBUF mpackets
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// caleb_reg_write(CALEB_BURST, 1); // 128-byte RBUF mpackets
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// caleb_reg_write(CALEB_BURST, 2); // 256-byte RBUF mpackets
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}
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void caleb_enable_rx(int port)
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{
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u8 temp;
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temp = caleb_reg_read(CALEB_PORTEN);
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temp |= 1 << port;
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caleb_reg_write(CALEB_PORTEN, temp);
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}
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void caleb_disable_rx(int port)
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{
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u8 temp;
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temp = caleb_reg_read(CALEB_PORTEN);
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temp &= ~(1 << port);
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caleb_reg_write(CALEB_PORTEN, temp);
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}
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void caleb_enable_tx(int port)
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{
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u8 temp;
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temp = caleb_reg_read(CALEB_PORTEN);
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temp |= 1 << (port + 4);
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caleb_reg_write(CALEB_PORTEN, temp);
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}
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void caleb_disable_tx(int port)
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{
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u8 temp;
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temp = caleb_reg_read(CALEB_PORTEN);
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temp &= ~(1 << (port + 4));
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caleb_reg_write(CALEB_PORTEN, temp);
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}
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