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Elphel
linux-elphel
Commits
25f54b0e
Commit
25f54b0e
authored
Nov 23, 2017
by
Oleg Dzhimiev
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xilinx_emacps.c
src/drivers/net/ethernet/xilinx/xilinx_emacps.c
+3197
-0
xilinx_emacps.c.patch_noneed
src/patches/xilinx_emacps.c.patch_noneed
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src/drivers/net/ethernet/xilinx/xilinx_emacps.c
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25f54b0e
/*
* Xilinx Ethernet: Linux driver for Ethernet.
*
* Author: Xilinx, Inc.
*
* 2010 (c) Xilinx, Inc. This file is licensed uner the terms of the GNU
* General Public License version 2. This program is licensed "as is"
* without any warranty of any kind, whether express or implied.
*
* This is a driver for xilinx processor sub-system (ps) ethernet device.
* This driver is mainly used in Linux 2.6.30 and above and it does _not_
* support Linux 2.4 kernel due to certain new features (e.g. NAPI) is
* introduced in this driver.
*
* TODO:
* 1. JUMBO frame is not enabled per EPs spec. Please update it if this
* support is added in and set MAX_MTU to 9000.
* 2. PTP slave mode: Currently master and slave sync is tested for 111MHz and
* 125 MHz ptp clock. Need to test with various other clock frequencies.
*/
#include <linux/module.h>
#include <linux/kernel.h>
#include <linux/init.h>
#include <linux/mm.h>
#include <linux/netdevice.h>
#include <linux/etherdevice.h>
#include <linux/platform_device.h>
#include <linux/phy.h>
#include <linux/mii.h>
#include <linux/delay.h>
#include <linux/dma-mapping.h>
#include <linux/io.h>
#include <linux/ethtool.h>
#include <linux/vmalloc.h>
#include <linux/version.h>
#include <linux/of.h>
#include <linux/interrupt.h>
#include <linux/clocksource.h>
#include <linux/net_tstamp.h>
#include <linux/pm_runtime.h>
#include <linux/clk.h>
#include <linux/of_net.h>
#include <linux/of_address.h>
#include <linux/of_mdio.h>
#include <linux/timer.h>
#include <linux/ptp_clock_kernel.h>
#include <linux/timecounter.h>
/************************** Constant Definitions *****************************/
/* Must be shorter than length of ethtool_drvinfo.driver field to fit */
#define DRIVER_NAME "xemacps"
#define DRIVER_DESCRIPTION "Xilinx Tri-Mode Ethernet MAC driver"
#define DRIVER_VERSION "1.00a"
/* Transmission timeout is 3 seconds. */
#define TX_TIMEOUT (3*HZ)
/* for RX skb IP header word-aligned */
#define RX_IP_ALIGN_OFFSET 2
/* DMA buffer descriptors must be aligned on a 4-byte boundary. */
#define ALIGNMENT_BD 8
/* Maximum value for hash bits. 2**6 */
#define XEMACPS_MAX_HASH_BITS 64
/* MDC clock division
* currently supporting 8, 16, 32, 48, 64, 96, 128, 224.
*/
enum
{
MDC_DIV_8
=
0
,
MDC_DIV_16
,
MDC_DIV_32
,
MDC_DIV_48
,
MDC_DIV_64
,
MDC_DIV_96
,
MDC_DIV_128
,
MDC_DIV_224
};
/* Specify the receive buffer size in bytes, 64, 128, 192, 10240 */
#define XEMACPS_RX_BUF_SIZE 1536
/* Number of receive buffer bytes as a unit, this is HW setup */
#define XEMACPS_RX_BUF_UNIT 64
/* Default SEND and RECV buffer descriptors (BD) numbers.
* BD Space needed is (XEMACPS_SEND_BD_CNT+XEMACPS_RECV_BD_CNT)*8
*/
#undef DEBUG
#define DEBUG
#define XEMACPS_SEND_BD_CNT 256
#define XEMACPS_RECV_BD_CNT 256
#define XEMACPS_NAPI_WEIGHT 64
/* Register offset definitions. Unless otherwise noted, register access is
* 32 bit. Names are self explained here.
*/
#define XEMACPS_NWCTRL_OFFSET 0x00000000
/* Network Control reg */
#define XEMACPS_NWCFG_OFFSET 0x00000004
/* Network Config reg */
#define XEMACPS_NWSR_OFFSET 0x00000008
/* Network Status reg */
#define XEMACPS_USERIO_OFFSET 0x0000000C
/* User IO reg */
#define XEMACPS_DMACR_OFFSET 0x00000010
/* DMA Control reg */
#define XEMACPS_TXSR_OFFSET 0x00000014
/* TX Status reg */
#define XEMACPS_RXQBASE_OFFSET 0x00000018
/* RX Q Base address reg */
#define XEMACPS_TXQBASE_OFFSET 0x0000001C
/* TX Q Base address reg */
#define XEMACPS_RXSR_OFFSET 0x00000020
/* RX Status reg */
#define XEMACPS_ISR_OFFSET 0x00000024
/* Interrupt Status reg */
#define XEMACPS_IER_OFFSET 0x00000028
/* Interrupt Enable reg */
#define XEMACPS_IDR_OFFSET 0x0000002C
/* Interrupt Disable reg */
#define XEMACPS_IMR_OFFSET 0x00000030
/* Interrupt Mask reg */
#define XEMACPS_PHYMNTNC_OFFSET 0x00000034
/* Phy Maintaince reg */
#define XEMACPS_RXPAUSE_OFFSET 0x00000038
/* RX Pause Time reg */
#define XEMACPS_TXPAUSE_OFFSET 0x0000003C
/* TX Pause Time reg */
#define XEMACPS_HASHL_OFFSET 0x00000080
/* Hash Low address reg */
#define XEMACPS_HASHH_OFFSET 0x00000084
/* Hash High address reg */
#define XEMACPS_LADDR1L_OFFSET 0x00000088
/* Specific1 addr low */
#define XEMACPS_LADDR1H_OFFSET 0x0000008C
/* Specific1 addr high */
#define XEMACPS_LADDR2L_OFFSET 0x00000090
/* Specific2 addr low */
#define XEMACPS_LADDR2H_OFFSET 0x00000094
/* Specific2 addr high */
#define XEMACPS_LADDR3L_OFFSET 0x00000098
/* Specific3 addr low */
#define XEMACPS_LADDR3H_OFFSET 0x0000009C
/* Specific3 addr high */
#define XEMACPS_LADDR4L_OFFSET 0x000000A0
/* Specific4 addr low */
#define XEMACPS_LADDR4H_OFFSET 0x000000A4
/* Specific4 addr high */
#define XEMACPS_MATCH1_OFFSET 0x000000A8
/* Type ID1 Match reg */
#define XEMACPS_MATCH2_OFFSET 0x000000AC
/* Type ID2 Match reg */
#define XEMACPS_MATCH3_OFFSET 0x000000B0
/* Type ID3 Match reg */
#define XEMACPS_MATCH4_OFFSET 0x000000B4
/* Type ID4 Match reg */
#define XEMACPS_WOL_OFFSET 0x000000B8
/* Wake on LAN reg */
#define XEMACPS_STRETCH_OFFSET 0x000000BC
/* IPG Stretch reg */
#define XEMACPS_SVLAN_OFFSET 0x000000C0
/* Stacked VLAN reg */
#define XEMACPS_MODID_OFFSET 0x000000FC
/* Module ID reg */
#define XEMACPS_OCTTXL_OFFSET 0x00000100
/* Octects transmitted Low
reg */
#define XEMACPS_OCTTXH_OFFSET 0x00000104
/* Octects transmitted High
reg */
#define XEMACPS_TXCNT_OFFSET 0x00000108
/* Error-free Frmaes
transmitted counter */
#define XEMACPS_TXBCCNT_OFFSET 0x0000010C
/* Error-free Broadcast
Frames counter*/
#define XEMACPS_TXMCCNT_OFFSET 0x00000110
/* Error-free Multicast
Frame counter */
#define XEMACPS_TXPAUSECNT_OFFSET 0x00000114
/* Pause Frames Transmitted
Counter */
#define XEMACPS_TX64CNT_OFFSET 0x00000118
/* Error-free 64 byte Frames
Transmitted counter */
#define XEMACPS_TX65CNT_OFFSET 0x0000011C
/* Error-free 65-127 byte
Frames Transmitted counter */
#define XEMACPS_TX128CNT_OFFSET 0x00000120
/* Error-free 128-255 byte
Frames Transmitted counter */
#define XEMACPS_TX256CNT_OFFSET 0x00000124
/* Error-free 256-511 byte
Frames transmitted counter */
#define XEMACPS_TX512CNT_OFFSET 0x00000128
/* Error-free 512-1023 byte
Frames transmitted counter */
#define XEMACPS_TX1024CNT_OFFSET 0x0000012C
/* Error-free 1024-1518 byte
Frames transmitted counter */
#define XEMACPS_TX1519CNT_OFFSET 0x00000130
/* Error-free larger than
1519 byte Frames transmitted
Counter */
#define XEMACPS_TXURUNCNT_OFFSET 0x00000134
/* TX under run error
Counter */
#define XEMACPS_SNGLCOLLCNT_OFFSET 0x00000138
/* Single Collision Frame
Counter */
#define XEMACPS_MULTICOLLCNT_OFFSET 0x0000013C
/* Multiple Collision Frame
Counter */
#define XEMACPS_EXCESSCOLLCNT_OFFSET 0x00000140
/* Excessive Collision Frame
Counter */
#define XEMACPS_LATECOLLCNT_OFFSET 0x00000144
/* Late Collision Frame
Counter */
#define XEMACPS_TXDEFERCNT_OFFSET 0x00000148
/* Deferred Transmission
Frame Counter */
#define XEMACPS_CSENSECNT_OFFSET 0x0000014C
/* Carrier Sense Error
Counter */
#define XEMACPS_OCTRXL_OFFSET 0x00000150
/* Octects Received register
Low */
#define XEMACPS_OCTRXH_OFFSET 0x00000154
/* Octects Received register
High */
#define XEMACPS_RXCNT_OFFSET 0x00000158
/* Error-free Frames
Received Counter */
#define XEMACPS_RXBROADCNT_OFFSET 0x0000015C
/* Error-free Broadcast
Frames Received Counter */
#define XEMACPS_RXMULTICNT_OFFSET 0x00000160
/* Error-free Multicast
Frames Received Counter */
#define XEMACPS_RXPAUSECNT_OFFSET 0x00000164
/* Pause Frames
Received Counter */
#define XEMACPS_RX64CNT_OFFSET 0x00000168
/* Error-free 64 byte Frames
Received Counter */
#define XEMACPS_RX65CNT_OFFSET 0x0000016C
/* Error-free 65-127 byte
Frames Received Counter */
#define XEMACPS_RX128CNT_OFFSET 0x00000170
/* Error-free 128-255 byte
Frames Received Counter */
#define XEMACPS_RX256CNT_OFFSET 0x00000174
/* Error-free 256-512 byte
Frames Received Counter */
#define XEMACPS_RX512CNT_OFFSET 0x00000178
/* Error-free 512-1023 byte
Frames Received Counter */
#define XEMACPS_RX1024CNT_OFFSET 0x0000017C
/* Error-free 1024-1518 byte
Frames Received Counter */
#define XEMACPS_RX1519CNT_OFFSET 0x00000180
/* Error-free 1519-max byte
Frames Received Counter */
#define XEMACPS_RXUNDRCNT_OFFSET 0x00000184
/* Undersize Frames Received
Counter */
#define XEMACPS_RXOVRCNT_OFFSET 0x00000188
/* Oversize Frames Received
Counter */
#define XEMACPS_RXJABCNT_OFFSET 0x0000018C
/* Jabbers Received
Counter */
#define XEMACPS_RXFCSCNT_OFFSET 0x00000190
/* Frame Check Sequence
Error Counter */
#define XEMACPS_RXLENGTHCNT_OFFSET 0x00000194
/* Length Field Error
Counter */
#define XEMACPS_RXSYMBCNT_OFFSET 0x00000198
/* Symbol Error Counter */
#define XEMACPS_RXALIGNCNT_OFFSET 0x0000019C
/* Alignment Error
Counter */
#define XEMACPS_RXRESERRCNT_OFFSET 0x000001A0
/* Receive Resource Error
Counter */
#define XEMACPS_RXORCNT_OFFSET 0x000001A4
/* Receive Overrun */
#define XEMACPS_RXIPCCNT_OFFSET 0x000001A8
/* IP header Checksum Error
Counter */
#define XEMACPS_RXTCPCCNT_OFFSET 0x000001AC
/* TCP Checksum Error
Counter */
#define XEMACPS_RXUDPCCNT_OFFSET 0x000001B0
/* UDP Checksum Error
Counter */
#define XEMACPS_1588S_OFFSET 0x000001D0
/* 1588 Timer Seconds */
#define XEMACPS_1588NS_OFFSET 0x000001D4
/* 1588 Timer Nanoseconds */
#define XEMACPS_1588ADJ_OFFSET 0x000001D8
/* 1588 Timer Adjust */
#define XEMACPS_1588INC_OFFSET 0x000001DC
/* 1588 Timer Increment */
#define XEMACPS_PTPETXS_OFFSET 0x000001E0
/* PTP Event Frame
Transmitted Seconds */
#define XEMACPS_PTPETXNS_OFFSET 0x000001E4
/* PTP Event Frame
Transmitted Nanoseconds */
#define XEMACPS_PTPERXS_OFFSET 0x000001E8
/* PTP Event Frame Received
Seconds */
#define XEMACPS_PTPERXNS_OFFSET 0x000001EC
/* PTP Event Frame Received
Nanoseconds */
#define XEMACPS_PTPPTXS_OFFSET 0x000001F0
/* PTP Peer Frame
Transmitted Seconds */
#define XEMACPS_PTPPTXNS_OFFSET 0x000001F4
/* PTP Peer Frame
Transmitted Nanoseconds */
#define XEMACPS_PTPPRXS_OFFSET 0x000001F8
/* PTP Peer Frame Received
Seconds */
#define XEMACPS_PTPPRXNS_OFFSET 0x000001FC
/* PTP Peer Frame Received
Nanoseconds */
/* network control register bit definitions */
#define XEMACPS_NWCTRL_FLUSH_DPRAM_MASK 0x00040000
#define XEMACPS_NWCTRL_RXTSTAMP_MASK 0x00008000
/* RX Timestamp in CRC */
#define XEMACPS_NWCTRL_ZEROPAUSETX_MASK 0x00001000
/* Transmit zero quantum
pause frame */
#define XEMACPS_NWCTRL_PAUSETX_MASK 0x00000800
/* Transmit pause frame */
#define XEMACPS_NWCTRL_HALTTX_MASK 0x00000400
/* Halt transmission
after current frame */
#define XEMACPS_NWCTRL_STARTTX_MASK 0x00000200
/* Start tx (tx_go) */
#define XEMACPS_NWCTRL_STATWEN_MASK 0x00000080
/* Enable writing to
stat counters */
#define XEMACPS_NWCTRL_STATINC_MASK 0x00000040
/* Increment statistic
registers */
#define XEMACPS_NWCTRL_STATCLR_MASK 0x00000020
/* Clear statistic
registers */
#define XEMACPS_NWCTRL_MDEN_MASK 0x00000010
/* Enable MDIO port */
#define XEMACPS_NWCTRL_TXEN_MASK 0x00000008
/* Enable transmit */
#define XEMACPS_NWCTRL_RXEN_MASK 0x00000004
/* Enable receive */
#define XEMACPS_NWCTRL_LOOPEN_MASK 0x00000002
/* local loopback */
/* name network configuration register bit definitions */
#define XEMACPS_NWCFG_BADPREAMBEN_MASK 0x20000000
/* disable rejection of
non-standard preamble */
#define XEMACPS_NWCFG_IPDSTRETCH_MASK 0x10000000
/* enable transmit IPG */
#define XEMACPS_NWCFG_FCSIGNORE_MASK 0x04000000
/* disable rejection of
FCS error */
#define XEMACPS_NWCFG_HDRXEN_MASK 0x02000000
/* RX half duplex */
#define XEMACPS_NWCFG_RXCHKSUMEN_MASK 0x01000000
/* enable RX checksum
offload */
#define XEMACPS_NWCFG_PAUSECOPYDI_MASK 0x00800000
/* Do not copy pause
Frames to memory */
#define XEMACPS_NWCFG_MDC_SHIFT_MASK 18
/* shift bits for MDC */
#define XEMACPS_NWCFG_MDCCLKDIV_MASK 0x001C0000
/* MDC Mask PCLK divisor */
#define XEMACPS_NWCFG_FCSREM_MASK 0x00020000
/* Discard FCS from
received frames */
#define XEMACPS_NWCFG_LENGTHERRDSCRD_MASK 0x00010000
/* RX length error discard */
#define XEMACPS_NWCFG_RXOFFS_MASK 0x0000C000
/* RX buffer offset */
#define XEMACPS_NWCFG_PAUSEEN_MASK 0x00002000
/* Enable pause TX */
#define XEMACPS_NWCFG_RETRYTESTEN_MASK 0x00001000
/* Retry test */
#define XEMACPS_NWCFG_1000_MASK 0x00000400
/* Gigbit mode */
#define XEMACPS_NWCFG_EXTADDRMATCHEN_MASK 0x00000200
/* External address match enable */
#define XEMACPS_NWCFG_UCASTHASHEN_MASK 0x00000080
/* Receive unicast hash
frames */
#define XEMACPS_NWCFG_MCASTHASHEN_MASK 0x00000040
/* Receive multicast hash
frames */
#define XEMACPS_NWCFG_BCASTDI_MASK 0x00000020
/* Do not receive
broadcast frames */
#define XEMACPS_NWCFG_COPYALLEN_MASK 0x00000010
/* Copy all frames */
#define XEMACPS_NWCFG_NVLANDISC_MASK 0x00000004
/* Receive only VLAN
frames */
#define XEMACPS_NWCFG_FDEN_MASK 0x00000002
/* Full duplex */
#define XEMACPS_NWCFG_100_MASK 0x00000001
/* 10 or 100 Mbs */
/* network status register bit definitaions */
#define XEMACPS_NWSR_MDIOIDLE_MASK 0x00000004
/* PHY management idle */
#define XEMACPS_NWSR_MDIO_MASK 0x00000002
/* Status of mdio_in */
/* MAC address register word 1 mask */
#define XEMACPS_LADDR_MACH_MASK 0x0000FFFF
/* Address bits[47:32]
bit[31:0] are in BOTTOM */
/* DMA control register bit definitions */
#define XEMACPS_DMACR_RXBUF_MASK 0x00FF0000
/* Mask bit for RX buffer
size */
#define XEMACPS_DMACR_RXBUF_SHIFT 16
/* Shift bit for RX buffer
size */
#define XEMACPS_DMACR_TCPCKSUM_MASK 0x00000800
/* enable/disable TX
checksum offload */
#define XEMACPS_DMACR_TXSIZE_MASK 0x00000400
/* TX buffer memory size */
#define XEMACPS_DMACR_RXSIZE_MASK 0x00000300
/* RX buffer memory size */
#define XEMACPS_DMACR_ENDIAN_MASK 0x00000080
/* Endian configuration */
#define XEMACPS_DMACR_BLENGTH_MASK 0x0000001F
/* Buffer burst length */
#define XEMACPS_DMACR_BLENGTH_INCR16 0x00000010
/* Buffer burst length */
#define XEMACPS_DMACR_BLENGTH_INCR8 0x00000008
/* Buffer burst length */
#define XEMACPS_DMACR_BLENGTH_INCR4 0x00000004
/* Buffer burst length */
#define XEMACPS_DMACR_BLENGTH_SINGLE 0x00000002
/* Buffer burst length */
/* transmit status register bit definitions */
#define XEMACPS_TXSR_HRESPNOK_MASK 0x00000100
/* Transmit hresp not OK */
#define XEMACPS_TXSR_COL1000_MASK 0x00000080
/* Collision Gbs mode */
#define XEMACPS_TXSR_URUN_MASK 0x00000040
/* Transmit underrun */
#define XEMACPS_TXSR_TXCOMPL_MASK 0x00000020
/* Transmit completed OK */
#define XEMACPS_TXSR_BUFEXH_MASK 0x00000010
/* Transmit buffs exhausted
mid frame */
#define XEMACPS_TXSR_TXGO_MASK 0x00000008
/* Status of go flag */
#define XEMACPS_TXSR_RXOVR_MASK 0x00000004
/* Retry limit exceeded */
#define XEMACPS_TXSR_COL100_MASK 0x00000002
/* Collision 10/100 mode */
#define XEMACPS_TXSR_USEDREAD_MASK 0x00000001
/* TX buffer used bit set */
#define XEMACPS_TXSR_ERROR_MASK (XEMACPS_TXSR_HRESPNOK_MASK | \
XEMACPS_TXSR_COL1000_MASK | \
XEMACPS_TXSR_URUN_MASK | \
XEMACPS_TXSR_BUFEXH_MASK | \
XEMACPS_TXSR_RXOVR_MASK | \
XEMACPS_TXSR_COL100_MASK | \
XEMACPS_TXSR_USEDREAD_MASK)
/* receive status register bit definitions */
#define XEMACPS_RXSR_HRESPNOK_MASK 0x00000008
/* Receive hresp not OK */
#define XEMACPS_RXSR_RXOVR_MASK 0x00000004
/* Receive overrun */
#define XEMACPS_RXSR_FRAMERX_MASK 0x00000002
/* Frame received OK */
#define XEMACPS_RXSR_BUFFNA_MASK 0x00000001
/* RX buffer used bit set */
#define XEMACPS_RXSR_ERROR_MASK (XEMACPS_RXSR_HRESPNOK_MASK | \
XEMACPS_RXSR_RXOVR_MASK | \
XEMACPS_RXSR_BUFFNA_MASK)
/* interrupts bit definitions
* Bits definitions are same in XEMACPS_ISR_OFFSET,
* XEMACPS_IER_OFFSET, XEMACPS_IDR_OFFSET, and XEMACPS_IMR_OFFSET
*/
#define XEMACPS_IXR_PTPPSTX_MASK 0x02000000
/* PTP Psync transmitted */
#define XEMACPS_IXR_PTPPDRTX_MASK 0x01000000
/* PTP Pdelay_req
transmitted */
#define XEMACPS_IXR_PTPSTX_MASK 0x00800000
/* PTP Sync transmitted */
#define XEMACPS_IXR_PTPDRTX_MASK 0x00400000
/* PTP Delay_req
transmitted */
#define XEMACPS_IXR_PTPPSRX_MASK 0x00200000
/* PTP Psync received */
#define XEMACPS_IXR_PTPPDRRX_MASK 0x00100000
/* PTP Pdelay_req
received */
#define XEMACPS_IXR_PTPSRX_MASK 0x00080000
/* PTP Sync received */
#define XEMACPS_IXR_PTPDRRX_MASK 0x00040000
/* PTP Delay_req received */
#define XEMACPS_IXR_PAUSETX_MASK 0x00004000
/* Pause frame
transmitted */
#define XEMACPS_IXR_PAUSEZERO_MASK 0x00002000
/* Pause time has reached
zero */
#define XEMACPS_IXR_PAUSENZERO_MASK 0x00001000
/* Pause frame received */
#define XEMACPS_IXR_HRESPNOK_MASK 0x00000800
/* hresp not ok */
#define XEMACPS_IXR_RXOVR_MASK 0x00000400
/* Receive overrun
occurred */
#define XEMACPS_IXR_TXCOMPL_MASK 0x00000080
/* Frame transmitted ok */
#define XEMACPS_IXR_TXEXH_MASK 0x00000040
/* Transmit err occurred or
no buffers*/
#define XEMACPS_IXR_RETRY_MASK 0x00000020
/* Retry limit exceeded */
#define XEMACPS_IXR_URUN_MASK 0x00000010
/* Transmit underrun */
#define XEMACPS_IXR_TXUSED_MASK 0x00000008
/* Tx buffer used bit read */
#define XEMACPS_IXR_RXUSED_MASK 0x00000004
/* Rx buffer used bit read */
#define XEMACPS_IXR_FRAMERX_MASK 0x00000002
/* Frame received ok */
#define XEMACPS_IXR_MGMNT_MASK 0x00000001
/* PHY management complete */
#define XEMACPS_IXR_ALL_MASK 0x00000CFE
/* all interrupts in use */
#define XEMACPS_IXR_TX_ERR_MASK (XEMACPS_IXR_TXEXH_MASK | \
XEMACPS_IXR_RETRY_MASK | \
XEMACPS_IXR_URUN_MASK | \
XEMACPS_IXR_TXUSED_MASK)
#define XEMACPS_IXR_RX_ERR_MASK (XEMACPS_IXR_HRESPNOK_MASK | \
XEMACPS_IXR_RXUSED_MASK | \
XEMACPS_IXR_RXOVR_MASK)
/* PHY Maintenance bit definitions */
#define XEMACPS_PHYMNTNC_OP_MASK 0x40020000
/* operation mask bits */
#define XEMACPS_PHYMNTNC_OP_R_MASK 0x20000000
/* read operation */
#define XEMACPS_PHYMNTNC_OP_W_MASK 0x10000000
/* write operation */
#define XEMACPS_PHYMNTNC_ADDR_MASK 0x0F800000
/* Address bits */
#define XEMACPS_PHYMNTNC_REG_MASK 0x007C0000
/* register bits */
#define XEMACPS_PHYMNTNC_DATA_MASK 0x0000FFFF
/* data bits */
#define XEMACPS_PHYMNTNC_PHYAD_SHIFT_MASK 23
/* Shift bits for PHYAD */
#define XEMACPS_PHYMNTNC_PHREG_SHIFT_MASK 18
/* Shift bits for PHREG */
/* Wake on LAN bit definition */
#define XEMACPS_WOL_MCAST_MASK 0x00080000
#define XEMACPS_WOL_SPEREG1_MASK 0x00040000
#define XEMACPS_WOL_ARP_MASK 0x00020000
#define XEMACPS_WOL_MAGIC_MASK 0x00010000
#define XEMACPS_WOL_ARP_ADDR_MASK 0x0000FFFF
/* Buffer descriptor status words offset */
#define XEMACPS_BD_ADDR_OFFSET 0x00000000
/**< word 0/addr of BDs */
#define XEMACPS_BD_STAT_OFFSET 0x00000004
/**< word 1/status of BDs */
/* Transmit buffer descriptor status words bit positions.
* Transmit buffer descriptor consists of two 32-bit registers,
* the first - word0 contains a 32-bit address pointing to the location of
* the transmit data.
* The following register - word1, consists of various information to
* control transmit process. After transmit, this is updated with status
* information, whether the frame was transmitted OK or why it had failed.
*/
#define XEMACPS_TXBUF_USED_MASK 0x80000000
/* Used bit. */
#define XEMACPS_TXBUF_WRAP_MASK 0x40000000
/* Wrap bit, last
descriptor */
#define XEMACPS_TXBUF_RETRY_MASK 0x20000000
/* Retry limit exceeded */
#define XEMACPS_TXBUF_EXH_MASK 0x08000000
/* Buffers exhausted */
#define XEMACPS_TXBUF_LAC_MASK 0x04000000
/* Late collision. */
#define XEMACPS_TXBUF_NOCRC_MASK 0x00010000
/* No CRC */
#define XEMACPS_TXBUF_LAST_MASK 0x00008000
/* Last buffer */
#define XEMACPS_TXBUF_LEN_MASK 0x00003FFF
/* Mask for length field */
#define XEMACPS_TXBUF_ERR_MASK 0x3C000000
/* Mask for length field */
/* Receive buffer descriptor status words bit positions.
* Receive buffer descriptor consists of two 32-bit registers,
* the first - word0 contains a 32-bit word aligned address pointing to the
* address of the buffer. The lower two bits make up the wrap bit indicating
* the last descriptor and the ownership bit to indicate it has been used.
* The following register - word1, contains status information regarding why
* the frame was received (the filter match condition) as well as other
* useful info.
*/
#define XEMACPS_RXBUF_BCAST_MASK 0x80000000
/* Broadcast frame */
#define XEMACPS_RXBUF_MULTIHASH_MASK 0x40000000
/* Multicast hashed frame */
#define XEMACPS_RXBUF_UNIHASH_MASK 0x20000000
/* Unicast hashed frame */
#define XEMACPS_RXBUF_EXH_MASK 0x08000000
/* buffer exhausted */
#define XEMACPS_RXBUF_AMATCH_MASK 0x06000000
/* Specific address
matched */
#define XEMACPS_RXBUF_IDFOUND_MASK 0x01000000
/* Type ID matched */
#define XEMACPS_RXBUF_IDMATCH_MASK 0x00C00000
/* ID matched mask */
#define XEMACPS_RXBUF_VLAN_MASK 0x00200000
/* VLAN tagged */
#define XEMACPS_RXBUF_PRI_MASK 0x00100000
/* Priority tagged */
#define XEMACPS_RXBUF_VPRI_MASK 0x000E0000
/* Vlan priority */
#define XEMACPS_RXBUF_CFI_MASK 0x00010000
/* CFI frame */
#define XEMACPS_RXBUF_EOF_MASK 0x00008000
/* End of frame. */
#define XEMACPS_RXBUF_SOF_MASK 0x00004000
/* Start of frame. */
#define XEMACPS_RXBUF_LEN_MASK 0x00001FFF
/* Mask for length field */
#define XEMACPS_RXBUF_WRAP_MASK 0x00000002
/* Wrap bit, last BD */
#define XEMACPS_RXBUF_NEW_MASK 0x00000001
/* Used bit.. */
#define XEMACPS_RXBUF_ADD_MASK 0xFFFFFFFC
/* Mask for address */
#define XEAMCPS_GEN_PURPOSE_TIMER_LOAD 100
/* timeout value is msecs */
#define XEMACPS_GMII2RGMII_FULLDPLX BMCR_FULLDPLX
#define XEMACPS_GMII2RGMII_SPEED1000 BMCR_SPEED1000
#define XEMACPS_GMII2RGMII_SPEED100 BMCR_SPEED100
#define XEMACPS_GMII2RGMII_REG_NUM 0x10
#define XEMACPS_MDIO_BUSY_TIMEOUT (1 * HZ)
#ifdef CONFIG_XILINX_PS_EMAC_HWTSTAMP
#define NS_PER_SEC 1000000000ULL
/* Nanoseconds per
second */
/* Sum of Ethernet, IP and UDP header length */
#define XEMACPS_TX_PTPHDR_OFFSET 42
#define XEMACPS_RX_PTPHDR_OFFSET 28
/* Sum of IP and UDP header length */
#define XEMACPS_IP_PROTO_OFFSET 9
/* Protocol field offset */
#define XEMACPS_UDP_PORT_OFFSET 22
/* UDP dst port offset */
#define XEMACPS_PTP_EVENT_PORT_NUM 0x13F
/* Transport port for ptp */
#define XEMACPS_PTP_CC_MULT (1 << 31)
#endif
/* Elphel */
#define AT803X_PHY_ID 0x004dd072
/*Particular one, AR8035 but we'll use a broad mask */
#define AT803X_PHY_ID_MASK 0xffffffe0
#define xemacps_read(base, reg) \
readl_relaxed(((void __iomem *)(base)) + (reg))
#define xemacps_write(base, reg, val) \
writel_relaxed((val), ((void __iomem *)(base)) + (reg))
struct
ring_info
{
struct
sk_buff
*
skb
;
dma_addr_t
mapping
;
size_t
len
;
};
/* DMA buffer descriptor structure. Each BD is two words */
struct
xemacps_bd
{
u32
addr
;
u32
ctrl
;
};
/* Our private device data. */
struct
net_local
{
void
__iomem
*
baseaddr
;
struct
clk
*
devclk
;
struct
clk
*
aperclk
;
struct
device_node
*
phy_node
;
struct
device_node
*
gmii2rgmii_phy_node
;
struct
ring_info
*
tx_skb
;
struct
ring_info
*
rx_skb
;
struct
xemacps_bd
*
rx_bd
;
struct
xemacps_bd
*
tx_bd
;
dma_addr_t
rx_bd_dma
;
/* physical address */
dma_addr_t
tx_bd_dma
;
/* physical address */
u32
tx_bd_ci
;
u32
tx_bd_tail
;
u32
rx_bd_ci
;
u32
tx_bd_freecnt
;
spinlock_t
tx_lock
;
spinlock_t
rx_lock
;
spinlock_t
nwctrlreg_lock
;
spinlock_t
mdio_lock
;
struct
platform_device
*
pdev
;
struct
net_device
*
ndev
;
/* this device */
struct
tasklet_struct
tx_bdreclaim_tasklet
;
struct
workqueue_struct
*
txtimeout_handler_wq
;
struct
work_struct
txtimeout_reinit
;
struct
napi_struct
napi
;
/* napi information for device */
struct
net_device_stats
stats
;
/* Statistics for this device */
struct
timer_list
gen_purpose_timer
;
/* Used for stats update */
struct
mii_bus
*
mii_bus
;
struct
phy_device
*
phy_dev
;
struct
phy_device
*
gmii2rgmii_phy_dev
;
phy_interface_t
phy_interface
;
unsigned
int
link
;
unsigned
int
speed
;
unsigned
int
duplex
;
/* RX ip/tcp/udp checksum */
unsigned
ip_summed
;
unsigned
int
enetnum
;
unsigned
int
lastrxfrmscntr
;
unsigned
int
has_mdio
;
bool
timerready
;
#ifdef CONFIG_XILINX_PS_EMAC_HWTSTAMP
struct
hwtstamp_config
hwtstamp_config
;
struct
ptp_clock
*
ptp_clock
;
struct
ptp_clock_info
ptp_caps
;
spinlock_t
tmreg_lock
;
int
phc_index
;
unsigned
int
tmr_add
;
struct
cyclecounter
cc
;
struct
timecounter
tc
;
struct
timer_list
time_keep
;
#endif
};
#define to_net_local(_nb) container_of(_nb, struct net_local,\
clk_rate_change_nb)
static
struct
net_device_ops
netdev_ops
;
/**
* xemacps_mdio_wait - Wait for the MDIO to be ready to use
* @lp: Pointer to the Emacps device private data
*
* This function waits till the device is ready to accept a new MDIO
* request.
*
* Return: 0 for success or ETIMEDOUT for a timeout
*/
static
int
xemacps_mdio_wait
(
struct
net_local
*
lp
)
{
ulong
timeout
=
jiffies
+
XEMACPS_MDIO_BUSY_TIMEOUT
;
u32
regval
;
/* Wait till the bus is free */
do
{
regval
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_NWSR_OFFSET
);
if
(
regval
&
XEMACPS_NWSR_MDIOIDLE_MASK
)
break
;
else
cpu_relax
();
}
while
(
!
time_after_eq
(
jiffies
,
timeout
));
if
(
time_after_eq
(
jiffies
,
timeout
))
return
-
ETIMEDOUT
;
return
0
;
}
/**
* xemacps_mdio_read - Read current value of phy register indicated by
* phyreg.
* @bus: mdio bus
* @mii_id: mii id
* @phyreg: phy register to be read
*
* Return: value read from specified phy register.
*
* note: This is for 802.3 clause 22 phys access. For 802.3 clause 45 phys
* access, set bit 30 to be 1. e.g. change XEMACPS_PHYMNTNC_OP_MASK to
* 0x00020000.
*/
static
int
xemacps_mdio_read
(
struct
mii_bus
*
bus
,
int
mii_id
,
int
phyreg
)
{
struct
net_local
*
lp
=
bus
->
priv
;
u32
regval
;
int
value
;
pm_runtime_get_sync
(
&
lp
->
pdev
->
dev
);
spin_lock
(
&
lp
->
mdio_lock
);
if
(
xemacps_mdio_wait
(
lp
))
goto
timeout
;
regval
=
XEMACPS_PHYMNTNC_OP_MASK
;
regval
|=
XEMACPS_PHYMNTNC_OP_R_MASK
;
regval
|=
(
mii_id
<<
XEMACPS_PHYMNTNC_PHYAD_SHIFT_MASK
);
regval
|=
(
phyreg
<<
XEMACPS_PHYMNTNC_PHREG_SHIFT_MASK
);
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_PHYMNTNC_OFFSET
,
regval
);
/* wait for end of transfer */
if
(
xemacps_mdio_wait
(
lp
))
goto
timeout
;
value
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_PHYMNTNC_OFFSET
)
&
XEMACPS_PHYMNTNC_DATA_MASK
;
spin_unlock
(
&
lp
->
mdio_lock
);
pm_runtime_put
(
&
lp
->
pdev
->
dev
);
return
value
;
timeout:
spin_unlock
(
&
lp
->
mdio_lock
);
pm_runtime_put
(
&
lp
->
pdev
->
dev
);
return
-
ETIMEDOUT
;
}
/**
* xemacps_mdio_write - Write passed in value to phy register indicated
* by phyreg.
* @bus: mdio bus
* @mii_id: mii id
* @phyreg: phy register to be configured.
* @value: value to be written to phy register.
* Return: 0. This API requires to be int type or compile warning generated
*
* note: This is for 802.3 clause 22 phys access. For 802.3 clause 45 phys
* access, set bit 30 to be 1. e.g. change XEMACPS_PHYMNTNC_OP_MASK to
* 0x00020000.
*/
static
int
xemacps_mdio_write
(
struct
mii_bus
*
bus
,
int
mii_id
,
int
phyreg
,
u16
value
)
{
struct
net_local
*
lp
=
bus
->
priv
;
u32
regval
;
pm_runtime_get_sync
(
&
lp
->
pdev
->
dev
);
spin_lock
(
&
lp
->
mdio_lock
);
if
(
xemacps_mdio_wait
(
lp
))
goto
timeout
;
regval
=
XEMACPS_PHYMNTNC_OP_MASK
;
regval
|=
XEMACPS_PHYMNTNC_OP_W_MASK
;
regval
|=
(
mii_id
<<
XEMACPS_PHYMNTNC_PHYAD_SHIFT_MASK
);
regval
|=
(
phyreg
<<
XEMACPS_PHYMNTNC_PHREG_SHIFT_MASK
);
regval
|=
value
;
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_PHYMNTNC_OFFSET
,
regval
);
/* wait for end of transfer */
if
(
xemacps_mdio_wait
(
lp
))
goto
timeout
;
spin_unlock
(
&
lp
->
mdio_lock
);
pm_runtime_put
(
&
lp
->
pdev
->
dev
);
return
0
;
timeout:
spin_unlock
(
&
lp
->
mdio_lock
);
pm_runtime_put
(
&
lp
->
pdev
->
dev
);
return
-
ETIMEDOUT
;
}
/**
* xemacps_mdio_reset - mdio reset. It seems to be required per open
* source documentation phy.txt. But there is no reset in this device.
* Provide function API for now.
* @bus: mdio bus
*
* Return: Always 0
*/
static
int
xemacps_mdio_reset
(
struct
mii_bus
*
bus
)
{
return
0
;
}
/**
* xemacps_set_freq - Set a clock to a new frequency
* @clk: Pointer to the clock to change
* @rate: New frequency in Hz
* @dev: Pointer to the struct device
*/
static
void
xemacps_set_freq
(
struct
clk
*
clk
,
long
rate
,
struct
device
*
dev
)
{
rate
=
clk_round_rate
(
clk
,
rate
);
if
(
rate
<
0
)
return
;
dev_info
(
dev
,
"Set clk to %ld Hz
\n
"
,
rate
);
if
(
clk_set_rate
(
clk
,
rate
))
dev_err
(
dev
,
"Setting new clock rate failed.
\n
"
);
}
/**
* xemacps_adjust_link - handles link status changes, such as speed,
* duplex, up/down, ...
* @ndev: network device
*/
static
void
xemacps_adjust_link
(
struct
net_device
*
ndev
)
{
struct
net_local
*
lp
=
netdev_priv
(
ndev
);
struct
phy_device
*
phydev
=
lp
->
phy_dev
;
struct
phy_device
*
gmii2rgmii_phydev
=
lp
->
gmii2rgmii_phy_dev
;
int
status_change
=
0
;
u32
regval
;
u16
gmii2rgmii_reg
=
0
;
if
(
phydev
->
link
)
{
if
((
lp
->
speed
!=
phydev
->
speed
)
||
(
lp
->
duplex
!=
phydev
->
duplex
))
{
regval
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_NWCFG_OFFSET
);
regval
&=
~
(
XEMACPS_NWCFG_FDEN_MASK
|
XEMACPS_NWCFG_1000_MASK
|
XEMACPS_NWCFG_100_MASK
);
if
(
phydev
->
duplex
)
{
regval
|=
XEMACPS_NWCFG_FDEN_MASK
;
gmii2rgmii_reg
|=
XEMACPS_GMII2RGMII_FULLDPLX
;
}
if
(
phydev
->
speed
==
SPEED_1000
)
{
regval
|=
XEMACPS_NWCFG_1000_MASK
;
gmii2rgmii_reg
|=
XEMACPS_GMII2RGMII_SPEED1000
;
xemacps_set_freq
(
lp
->
devclk
,
125000000
,
&
lp
->
pdev
->
dev
);
}
else
if
(
phydev
->
speed
==
SPEED_100
)
{
regval
|=
XEMACPS_NWCFG_100_MASK
;
gmii2rgmii_reg
|=
XEMACPS_GMII2RGMII_SPEED100
;
xemacps_set_freq
(
lp
->
devclk
,
25000000
,
&
lp
->
pdev
->
dev
);
}
else
if
(
phydev
->
speed
==
SPEED_10
)
{
xemacps_set_freq
(
lp
->
devclk
,
2500000
,
&
lp
->
pdev
->
dev
);
}
else
{
dev_err
(
&
lp
->
pdev
->
dev
,
"%s: unknown PHY speed %d
\n
"
,
__func__
,
phydev
->
speed
);
return
;
}
if
(
lp
->
timerready
&&
(
phydev
->
speed
!=
SPEED_1000
))
{
del_timer_sync
(
&
(
lp
->
gen_purpose_timer
));
lp
->
timerready
=
false
;
}
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_NWCFG_OFFSET
,
regval
);
if
(
gmii2rgmii_phydev
!=
NULL
)
{
xemacps_mdio_write
(
lp
->
mii_bus
,
gmii2rgmii_phydev
->
mdio
.
addr
,
XEMACPS_GMII2RGMII_REG_NUM
,
gmii2rgmii_reg
);
}
lp
->
speed
=
phydev
->
speed
;
lp
->
duplex
=
phydev
->
duplex
;
status_change
=
1
;
}
}
if
(
phydev
->
link
!=
lp
->
link
)
{
lp
->
link
=
phydev
->
link
;
status_change
=
1
;
}
if
(
status_change
)
{
if
(
phydev
->
link
)
dev_info
(
&
lp
->
pdev
->
dev
,
"link up (%d/%s)
\n
"
,
phydev
->
speed
,
DUPLEX_FULL
==
phydev
->
duplex
?
"FULL"
:
"HALF"
);
else
dev_info
(
&
lp
->
pdev
->
dev
,
"link down
\n
"
);
}
}
/**
* xemacps_mii_probe - probe mii bus, find the right bus_id to register
* phy callback function.
* @ndev: network interface device structure
* Return: 0 on success, negative value if error
*/
static
int
xemacps_mii_probe
(
struct
net_device
*
ndev
)
{
struct
net_local
*
lp
=
netdev_priv
(
ndev
);
struct
phy_device
*
phydev
=
NULL
;
if
(
!
lp
->
phy_node
)
{
dev_info
(
&
lp
->
pdev
->
dev
,
"%s: no PHY setup
\n
"
,
ndev
->
name
);
return
0
;
}
if
(
lp
->
gmii2rgmii_phy_node
)
{
phydev
=
of_phy_attach
(
lp
->
ndev
,
lp
->
gmii2rgmii_phy_node
,
0
,
0
);
if
(
!
phydev
)
{
dev_err
(
&
lp
->
pdev
->
dev
,
"%s: no gmii to rgmii converter found
\n
"
,
ndev
->
name
);
return
-
1
;
}
lp
->
gmii2rgmii_phy_dev
=
phydev
;
}
else
lp
->
gmii2rgmii_phy_dev
=
NULL
;
phydev
=
of_phy_connect
(
lp
->
ndev
,
lp
->
phy_node
,
&
xemacps_adjust_link
,
0
,
lp
->
phy_interface
);
if
(
!
phydev
)
{
dev_err
(
&
lp
->
pdev
->
dev
,
"%s: no PHY found
\n
"
,
ndev
->
name
);
if
(
lp
->
gmii2rgmii_phy_dev
)
{
phy_disconnect
(
lp
->
gmii2rgmii_phy_dev
);
lp
->
gmii2rgmii_phy_dev
=
NULL
;
}
return
-
1
;
}
dev_dbg
(
&
lp
->
pdev
->
dev
,
"GEM: phydev %p, phydev->phy_id 0x%x, phydev->addr 0x%x
\n
"
,
phydev
,
phydev
->
phy_id
,
phydev
->
mdio
.
addr
);
phydev
->
supported
&=
(
PHY_GBIT_FEATURES
|
SUPPORTED_Pause
|
SUPPORTED_Asym_Pause
);
phydev
->
advertising
=
phydev
->
supported
;
lp
->
link
=
0
;
lp
->
speed
=
0
;
lp
->
duplex
=
-
1
;
lp
->
phy_dev
=
phydev
;
phy_start
(
lp
->
phy_dev
);
dev_dbg
(
&
lp
->
pdev
->
dev
,
"phy_addr 0x%x, phy_id 0x%08x
\n
"
,
lp
->
phy_dev
->
mdio
.
addr
,
lp
->
phy_dev
->
phy_id
);
dev_dbg
(
&
lp
->
pdev
->
dev
,
"attach [%s] phy driver
\n
"
,
lp
->
phy_dev
->
drv
->
name
);
return
0
;
}
/* http://www.spinics.net/lists/devicetree/msg06322.html */
static
int
ar8035_phy_fixup
(
struct
phy_device
*
dev
)
{
u16
val
;
// Elphel: phy_device has changed
//struct net_local *lp = dev->bus->priv;
struct
mdio_device
*
mdiodev
=
dev
->
mdio
;
struct
net_local
*
lp
=
&
mdiodev
->
bus
->
priv
;
dev_dbg
(
&
lp
->
pdev
->
dev
,
"fixup start"
);
/* Ar803x phy SmartEEE feature cause link status generates glitch,
* which cause ethernet link down/up issue, so disable SmartEEE
*/
phy_write
(
dev
,
0xd
,
0x3
);
phy_write
(
dev
,
0xe
,
0x805d
);
phy_write
(
dev
,
0xd
,
0x4003
);
val
=
phy_read
(
dev
,
0xe
);
phy_write
(
dev
,
0xe
,
val
&
~
(
1
<<
8
));
/*Enable if needed */
#if 0
/* To enable AR8031 output a 125MHz clk from CLK_25M */
phy_write(dev, 0xd, 0x7);
phy_write(dev, 0xe, 0x8016);
phy_write(dev, 0xd, 0x4007);
val = phy_read(dev, 0xe);
val &= 0xffe3;
val |= 0x18;
phy_write(dev, 0xe, val);
#endif
/* Next one what is really needed for Elphel 393 */
/* introduce tx clock delay */
phy_write
(
dev
,
0x1d
,
0x5
);
val
=
phy_read
(
dev
,
0x1e
);
val
|=
0x0100
;
phy_write
(
dev
,
0x1e
,
val
);
/*check phy power*/
val
=
phy_read
(
dev
,
0x0
);
if
(
val
&
BMCR_PDOWN
)
phy_write
(
dev
,
0x0
,
val
&
~
BMCR_PDOWN
);
dev_dbg
(
&
lp
->
pdev
->
dev
,
"fixup end"
);
return
0
;
}
/**
* xemacps_mii_init - Initialize and register mii bus to network device
* @lp: local device instance pointer
* Return: 0 on success, negative value if error
*/
static
int
xemacps_mii_init
(
struct
net_local
*
lp
)
{
int
rc
=
-
ENXIO
,
i
;
struct
resource
res
;
struct
device_node
*
np
=
of_get_parent
(
lp
->
phy_node
);
struct
device_node
*
npp
;
phy_register_fixup_for_uid
(
AT803X_PHY_ID
,
AT803X_PHY_ID_MASK
,
ar8035_phy_fixup
);
lp
->
mii_bus
=
of_mdio_find_bus
(
np
);
if
(
!
lp
->
has_mdio
&&
lp
->
mii_bus
)
return
0
;
lp
->
mii_bus
=
mdiobus_alloc
();
if
(
lp
->
mii_bus
==
NULL
)
{
rc
=
-
ENOMEM
;
goto
err_out
;
}
lp
->
mii_bus
->
name
=
"XEMACPS mii bus"
;
lp
->
mii_bus
->
read
=
&
xemacps_mdio_read
;
lp
->
mii_bus
->
write
=
&
xemacps_mdio_write
;
lp
->
mii_bus
->
reset
=
&
xemacps_mdio_reset
;
lp
->
mii_bus
->
priv
=
lp
;
lp
->
mii_bus
->
parent
=
&
lp
->
ndev
->
dev
;
for
(
i
=
0
;
i
<
PHY_MAX_ADDR
;
i
++
)
lp
->
mii_bus
->
irq
[
i
]
=
PHY_POLL
;
npp
=
of_get_parent
(
np
);
of_address_to_resource
(
npp
,
0
,
&
res
);
snprintf
(
lp
->
mii_bus
->
id
,
MII_BUS_ID_SIZE
,
"%.8llx"
,
(
unsigned
long
long
)
res
.
start
);
if
(
lp
->
phy_node
)
{
if
(
of_mdiobus_register
(
lp
->
mii_bus
,
np
))
goto
err_out_free_mdiobus
;
}
return
0
;
err_out_free_mdiobus:
mdiobus_free
(
lp
->
mii_bus
);
err_out:
return
rc
;
}
/**
* xemacps_update_hdaddr - Update device's MAC address when configured
* MAC address is not valid, reconfigure with a good one.
* @lp: local device instance pointer
*/
static
void
xemacps_update_hwaddr
(
struct
net_local
*
lp
)
{
u32
regvall
;
u16
regvalh
;
u8
addr
[
6
];
regvall
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_LADDR1L_OFFSET
);
regvalh
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_LADDR1H_OFFSET
);
addr
[
0
]
=
regvall
&
0xFF
;
addr
[
1
]
=
(
regvall
>>
8
)
&
0xFF
;
addr
[
2
]
=
(
regvall
>>
16
)
&
0xFF
;
addr
[
3
]
=
(
regvall
>>
24
)
&
0xFF
;
addr
[
4
]
=
regvalh
&
0xFF
;
addr
[
5
]
=
(
regvalh
>>
8
)
&
0xFF
;
if
(
is_valid_ether_addr
(
addr
))
{
ether_addr_copy
(
lp
->
ndev
->
dev_addr
,
addr
);
}
else
{
dev_info
(
&
lp
->
pdev
->
dev
,
"invalid address, use random
\n
"
);
eth_hw_addr_random
(
lp
->
ndev
);
dev_info
(
&
lp
->
pdev
->
dev
,
"MAC updated %02x:%02x:%02x:%02x:%02x:%02x
\n
"
,
lp
->
ndev
->
dev_addr
[
0
],
lp
->
ndev
->
dev_addr
[
1
],
lp
->
ndev
->
dev_addr
[
2
],
lp
->
ndev
->
dev_addr
[
3
],
lp
->
ndev
->
dev_addr
[
4
],
lp
->
ndev
->
dev_addr
[
5
]);
}
}
/**
* xemacps_set_hwaddr - Set device's MAC address from ndev->dev_addr
* @lp: local device instance pointer
*/
static
void
xemacps_set_hwaddr
(
struct
net_local
*
lp
)
{
u32
regvall
=
0
;
u16
regvalh
=
0
;
#ifdef __LITTLE_ENDIAN
regvall
=
cpu_to_le32
(
*
((
u32
*
)
lp
->
ndev
->
dev_addr
));
regvalh
=
cpu_to_le16
(
*
((
u16
*
)(
lp
->
ndev
->
dev_addr
+
4
)));
#endif
#ifdef __BIG_ENDIAN
regvall
=
cpu_to_be32
(
*
((
u32
*
)
lp
->
ndev
->
dev_addr
));
regvalh
=
cpu_to_be16
(
*
((
u16
*
)(
lp
->
ndev
->
dev_addr
+
4
)));
#endif
/* LADDRXH has to be wriiten latter than LADDRXL to enable
* this address even if these 16 bits are zeros. */
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_LADDR1L_OFFSET
,
regvall
);
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_LADDR1H_OFFSET
,
regvalh
);
#ifdef DEBUG
regvall
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_LADDR1L_OFFSET
);
regvalh
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_LADDR1H_OFFSET
);
dev_dbg
(
&
lp
->
pdev
->
dev
,
"MAC 0x%08x, 0x%08x, %02x:%02x:%02x:%02x:%02x:%02x
\n
"
,
regvall
,
regvalh
,
(
regvall
&
0xff
),
((
regvall
>>
8
)
&
0xff
),
((
regvall
>>
16
)
&
0xff
),
(
regvall
>>
24
),
(
regvalh
&
0xff
),
(
regvalh
>>
8
));
#endif
}
/*
* xemacps_reset_hw - Helper function to reset the underlying hardware.
* This is called when we get into such deep trouble that we don't know
* how to handle otherwise.
* @lp: local device instance pointer
*/
static
void
xemacps_reset_hw
(
struct
net_local
*
lp
)
{
u32
regisr
;
/* make sure we have the buffer for ourselves */
wmb
();
/* Clear statistic counters and keep mdio enabled as this mdio
* interface might be being reused by the other MAC.
*/
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_NWCTRL_OFFSET
,
XEMACPS_NWCTRL_STATCLR_MASK
|
XEMACPS_NWCTRL_MDEN_MASK
);
/* Clear TX and RX status */
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_TXSR_OFFSET
,
~
0UL
);
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_RXSR_OFFSET
,
~
0UL
);
/* Disable all interrupts */
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_IDR_OFFSET
,
~
0UL
);
synchronize_irq
(
lp
->
ndev
->
irq
);
regisr
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_ISR_OFFSET
);
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_ISR_OFFSET
,
regisr
);
}
#ifdef CONFIG_XILINX_PS_EMAC_HWTSTAMP
/**
* xemacps_time_keep - Call timecounter_read every second to avoid timer overrun
* @_data: Contains the device instance pointer
* Return: None
*/
void
xemacps_time_keep
(
unsigned
long
_data
)
{
struct
net_local
*
lp
=
(
struct
net_local
*
)
_data
;
u64
ns
;
unsigned
long
flags
;
spin_lock_irqsave
(
&
lp
->
tmreg_lock
,
flags
);
ns
=
timecounter_read
(
&
lp
->
tc
);
spin_unlock_irqrestore
(
&
lp
->
tmreg_lock
,
flags
);
mod_timer
(
&
lp
->
time_keep
,
jiffies
+
HZ
);
}
/**
* xemacps_ptp_read - Read timestamp information from the timer counters
* @lp: Local device instance pointer
* @ts: Timespec structure to hold the current time value
* Return: None
*/
static
inline
void
xemacps_ptp_read
(
struct
net_local
*
lp
,
struct
timespec
*
ts
)
{
ts
->
tv_sec
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_1588S_OFFSET
);
ts
->
tv_nsec
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_1588NS_OFFSET
);
if
(
ts
->
tv_sec
<
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_1588S_OFFSET
))
ts
->
tv_nsec
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_1588NS_OFFSET
);
}
/**
* xemacps_read_clock - Read raw cycle counter (to be used by time counter)
* @cc: Cyclecounter structure
* Return: Hw time stamp
*/
static
cycle_t
xemacps_read_clock
(
const
struct
cyclecounter
*
cc
)
{
struct
net_local
*
lp
=
container_of
(
cc
,
struct
net_local
,
cc
);
u64
stamp
;
struct
timespec
ts
;
xemacps_ptp_read
(
lp
,
&
ts
);
stamp
=
ts
.
tv_sec
*
NS_PER_SEC
+
ts
.
tv_nsec
;
return
stamp
;
}
/**
* xemacps_ptp_write - Update the currenrt time value to the timer counters
* @lp: Local device instance pointer
* @ts: Timespec structure to hold the time value
* Return: None
*/
static
inline
void
xemacps_ptp_write
(
struct
net_local
*
lp
,
const
struct
timespec
*
ts
)
{
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_1588S_OFFSET
,
ts
->
tv_sec
);
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_1588NS_OFFSET
,
ts
->
tv_nsec
);
}
/**
* xemacps_systim_to_hwtstamp - Convert system time value to hw timestamp
* @lp: Local device instance pointer
* @shhwtstamps: Timestamp structure to update
* @regval: Unsigned 64bit system time value.
* Return: None
*/
static
void
xemacps_systim_to_hwtstamp
(
struct
net_local
*
lp
,
struct
skb_shared_hwtstamps
*
shhwtstamps
,
u64
regval
)
{
u64
ns
;
ns
=
timecounter_cyc2time
(
&
lp
->
tc
,
regval
);
memset
(
shhwtstamps
,
0
,
sizeof
(
struct
skb_shared_hwtstamps
));
shhwtstamps
->
hwtstamp
=
ns_to_ktime
(
ns
);
}
/**
* xemacps_rx_hwtstamp - Read rx timestamp from hw and update it to the skbuff
* @lp: Local device instance pointer
* @skb: Pointer to the socket buffer
* @msg_type: PTP message type
* Return: None
*/
static
void
xemacps_rx_hwtstamp
(
struct
net_local
*
lp
,
struct
sk_buff
*
skb
,
unsigned
msg_type
)
{
u32
sec
,
nsec
;
u64
time64
;
if
(
msg_type
)
{
/* PTP Peer Event Frame packets */
sec
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_PTPPRXS_OFFSET
);
nsec
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_PTPPRXNS_OFFSET
);
}
else
{
/* PTP Event Frame packets */
sec
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_PTPERXS_OFFSET
);
nsec
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_PTPERXNS_OFFSET
);
}
time64
=
sec
*
NS_PER_SEC
+
nsec
;
xemacps_systim_to_hwtstamp
(
lp
,
skb_hwtstamps
(
skb
),
time64
);
}
/**
* xemacps_tx_hwtstamp - Read tx timestamp from hw and update it to the skbuff
* @lp: Local device instance pointer
* @skb: Pointer to the socket buffer
* @msg_type: PTP message type
* Return: None
*/
static
void
xemacps_tx_hwtstamp
(
struct
net_local
*
lp
,
struct
sk_buff
*
skb
,
unsigned
msg_type
)
{
u32
sec
,
nsec
;
u64
time64
;
if
(
msg_type
)
{
/* PTP Peer Event Frame packets */
sec
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_PTPPTXS_OFFSET
);
nsec
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_PTPPTXNS_OFFSET
);
}
else
{
/* PTP Event Frame packets */
sec
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_PTPETXS_OFFSET
);
nsec
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_PTPETXNS_OFFSET
);
}
time64
=
sec
*
NS_PER_SEC
+
nsec
;
xemacps_systim_to_hwtstamp
(
lp
,
skb_hwtstamps
(
skb
),
time64
);
skb_tstamp_tx
(
skb
,
skb_hwtstamps
(
skb
));
}
/**
* xemacps_ptp_enable - Select the mode of operation
* @ptp: PTP clock structure
* @rq: Requested feature to change
* @on: Whether to enable or disable the feature
* Return: Always returns EOPNOTSUPP
*/
static
int
xemacps_ptp_enable
(
struct
ptp_clock_info
*
ptp
,
struct
ptp_clock_request
*
rq
,
int
on
)
{
return
-
EOPNOTSUPP
;
}
/**
* xemacps_ptp_gettime - Get the current time from the timer counter
* @ptp: PTP clock structure
* @ts: Timespec structure to hold the current time value
* Return: Always returns zero
*/
static
int
xemacps_ptp_gettime
(
struct
ptp_clock_info
*
ptp
,
struct
timespec64
*
ts
)
{
unsigned
long
flags
;
struct
net_local
*
lp
=
container_of
(
ptp
,
struct
net_local
,
ptp_caps
);
u64
ns
;
u32
remainder
;
spin_lock_irqsave
(
&
lp
->
tmreg_lock
,
flags
);
ns
=
timecounter_read
(
&
lp
->
tc
);
spin_unlock_irqrestore
(
&
lp
->
tmreg_lock
,
flags
);
ts
->
tv_sec
=
div_u64_rem
(
ns
,
NS_PER_SEC
,
&
remainder
);
ts
->
tv_nsec
=
remainder
;
return
0
;
}
/**
* xemacps_ptp_settime - Reset the timercounter to use new base value
* @ptp: PTP clock structure
* @ts: Timespec structure to hold the current time value
* Return: Always returns zero
*/
static
int
xemacps_ptp_settime
(
struct
ptp_clock_info
*
ptp
,
const
struct
timespec64
*
ts
)
{
unsigned
long
flags
;
struct
net_local
*
lp
=
container_of
(
ptp
,
struct
net_local
,
ptp_caps
);
u64
ns
;
ns
=
ts
->
tv_sec
*
NS_PER_SEC
;
ns
+=
ts
->
tv_nsec
;
spin_lock_irqsave
(
&
lp
->
tmreg_lock
,
flags
);
timecounter_init
(
&
lp
->
tc
,
&
lp
->
cc
,
ns
);
spin_unlock_irqrestore
(
&
lp
->
tmreg_lock
,
flags
);
return
0
;
}
/**
* xemacps_ptp_adjfreq - Adjust the clock freequency
* @ptp: PTP clock info structure
* @ppb: Frequency in parts per billion
* Return: Always returns zero
*/
static
int
xemacps_ptp_adjfreq
(
struct
ptp_clock_info
*
ptp
,
s32
ppb
)
{
u64
diff
;
unsigned
long
flags
;
int
neg_adj
=
0
;
u32
mult
=
XEMACPS_PTP_CC_MULT
;
struct
net_local
*
lp
=
container_of
(
ptp
,
struct
net_local
,
ptp_caps
);
if
(
ppb
<
0
)
{
neg_adj
=
1
;
ppb
=
-
ppb
;
}
diff
=
mult
;
diff
*=
ppb
;
diff
=
div_u64
(
diff
,
NS_PER_SEC
);
spin_lock_irqsave
(
&
lp
->
tmreg_lock
,
flags
);
/*
* dummy read to set cycle_last in tc to now.
* So use adjusted mult to calculate when next call
* timercounter_read.
*/
timecounter_read
(
&
lp
->
tc
);
lp
->
cc
.
mult
=
neg_adj
?
mult
-
diff
:
mult
+
diff
;
spin_unlock_irqrestore
(
&
lp
->
tmreg_lock
,
flags
);
return
0
;
}
/**
* xemacps_ptp_adjtime - Adjust the timer counter value with delta
* @ptp: PTP clock info structure
* @delta: Delta value in nano seconds
* Return: Always returns zero
*/
static
int
xemacps_ptp_adjtime
(
struct
ptp_clock_info
*
ptp
,
s64
delta
)
{
unsigned
long
flags
;
struct
net_local
*
lp
=
container_of
(
ptp
,
struct
net_local
,
ptp_caps
);
u64
now
;
spin_lock_irqsave
(
&
lp
->
tmreg_lock
,
flags
);
now
=
timecounter_read
(
&
lp
->
tc
);
now
+=
delta
;
timecounter_init
(
&
lp
->
tc
,
&
lp
->
cc
,
now
);
spin_unlock_irqrestore
(
&
lp
->
tmreg_lock
,
flags
);
return
0
;
}
/**
* xemacps_ptp_init - Initialize the clock and register with ptp sub system
* @lp: Local device instance pointer
* Return: None
*/
static
void
xemacps_ptp_init
(
struct
net_local
*
lp
)
{
struct
timespec
now
;
unsigned
long
rate
;
lp
->
ptp_caps
.
owner
=
THIS_MODULE
;
snprintf
(
lp
->
ptp_caps
.
name
,
16
,
"zynq ptp"
);
lp
->
ptp_caps
.
n_alarm
=
0
;
lp
->
ptp_caps
.
n_ext_ts
=
0
;
lp
->
ptp_caps
.
n_per_out
=
0
;
lp
->
ptp_caps
.
pps
=
0
;
lp
->
ptp_caps
.
adjfreq
=
xemacps_ptp_adjfreq
;
lp
->
ptp_caps
.
adjtime
=
xemacps_ptp_adjtime
;
lp
->
ptp_caps
.
gettime64
=
xemacps_ptp_gettime
;
lp
->
ptp_caps
.
settime64
=
xemacps_ptp_settime
;
lp
->
ptp_caps
.
enable
=
xemacps_ptp_enable
;
rate
=
clk_get_rate
(
lp
->
aperclk
);
spin_lock_init
(
&
lp
->
tmreg_lock
);
init_timer
(
&
lp
->
time_keep
);
lp
->
time_keep
.
data
=
(
unsigned
long
)
lp
;
lp
->
time_keep
.
function
=
xemacps_time_keep
;
lp
->
time_keep
.
expires
=
jiffies
+
HZ
;
add_timer
(
&
lp
->
time_keep
);
lp
->
ptp_caps
.
max_adj
=
rate
;
memset
(
&
lp
->
cc
,
0
,
sizeof
(
lp
->
cc
));
lp
->
cc
.
read
=
xemacps_read_clock
;
lp
->
cc
.
mask
=
CLOCKSOURCE_MASK
(
64
);
lp
->
cc
.
mult
=
XEMACPS_PTP_CC_MULT
;
lp
->
cc
.
shift
=
31
;
lp
->
tmr_add
=
(
NS_PER_SEC
/
rate
);
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_1588INC_OFFSET
,
lp
->
tmr_add
);
getnstimeofday
(
&
now
);
xemacps_ptp_write
(
lp
,
(
const
struct
timespec
*
)
&
now
);
timecounter_init
(
&
lp
->
tc
,
&
lp
->
cc
,
ktime_to_ns
(
ktime_get_real
()));
lp
->
ptp_clock
=
ptp_clock_register
(
&
lp
->
ptp_caps
,
&
lp
->
pdev
->
dev
);
if
(
IS_ERR
(
lp
->
ptp_clock
))
pr_err
(
"ptp_clock_register failed
\n
"
);
lp
->
phc_index
=
ptp_clock_index
(
lp
->
ptp_clock
);
}
/**
* xemacps_ptp_close - Disable the ptp interface
* @lp: Local device instance pointer
* Return: None
*/
static
void
xemacps_ptp_close
(
struct
net_local
*
lp
)
{
/* Clear the time counters */
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_1588NS_OFFSET
,
0x0
);
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_1588S_OFFSET
,
0x0
);
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_1588ADJ_OFFSET
,
0x0
);
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_1588INC_OFFSET
,
0x0
);
del_timer
(
&
lp
->
time_keep
);
ptp_clock_unregister
(
lp
->
ptp_clock
);
/* Initialize hwstamp config */
lp
->
hwtstamp_config
.
rx_filter
=
HWTSTAMP_FILTER_NONE
;
lp
->
hwtstamp_config
.
tx_type
=
HWTSTAMP_TX_OFF
;
}
#endif
/* CONFIG_XILINX_PS_EMAC_HWTSTAMP */
/**
* xemacps_rx - process received packets when napi called
* @lp: local device instance pointer
* @budget: NAPI budget
* Return: number of BDs processed
*/
static
int
xemacps_rx
(
struct
net_local
*
lp
,
int
budget
)
{
struct
xemacps_bd
*
cur_p
;
u32
len
;
struct
sk_buff
*
skb
;
struct
sk_buff
*
new_skb
;
u32
new_skb_baddr
;
unsigned
int
numbdfree
=
0
;
u32
size
=
0
;
u32
packets
=
0
;
u32
regval
;
cur_p
=
&
lp
->
rx_bd
[
lp
->
rx_bd_ci
];
regval
=
cur_p
->
addr
;
rmb
();
while
(
numbdfree
<
budget
)
{
if
(
!
(
regval
&
XEMACPS_RXBUF_NEW_MASK
))
break
;
regval
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_RXSR_OFFSET
);
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_RXSR_OFFSET
,
regval
);
if
(
regval
&
XEMACPS_RXSR_HRESPNOK_MASK
)
{
dev_err
(
&
lp
->
pdev
->
dev
,
"RX error 0x%x
\n
"
,
regval
);
numbdfree
=
0xFFFFFFFF
;
break
;
}
new_skb
=
netdev_alloc_skb
(
lp
->
ndev
,
XEMACPS_RX_BUF_SIZE
);
if
(
new_skb
==
NULL
)
{
dev_err
(
&
lp
->
ndev
->
dev
,
"no memory for new sk_buff
\n
"
);
break
;
}
/* Get dma handle of skb->data */
new_skb_baddr
=
(
u32
)
dma_map_single
(
lp
->
ndev
->
dev
.
parent
,
new_skb
->
data
,
XEMACPS_RX_BUF_SIZE
,
DMA_FROM_DEVICE
);
if
(
dma_mapping_error
(
lp
->
ndev
->
dev
.
parent
,
new_skb_baddr
))
{
dev_kfree_skb
(
new_skb
);
break
;
}
/* the packet length */
len
=
cur_p
->
ctrl
&
XEMACPS_RXBUF_LEN_MASK
;
rmb
();
skb
=
lp
->
rx_skb
[
lp
->
rx_bd_ci
].
skb
;
dma_unmap_single
(
lp
->
ndev
->
dev
.
parent
,
lp
->
rx_skb
[
lp
->
rx_bd_ci
].
mapping
,
lp
->
rx_skb
[
lp
->
rx_bd_ci
].
len
,
DMA_FROM_DEVICE
);
/* setup received skb and send it upstream */
skb_put
(
skb
,
len
);
/* Tell the skb how much data we got. */
skb
->
protocol
=
eth_type_trans
(
skb
,
lp
->
ndev
);
skb
->
ip_summed
=
lp
->
ip_summed
;
#ifdef CONFIG_XILINX_PS_EMAC_HWTSTAMP
if
((
lp
->
hwtstamp_config
.
rx_filter
==
HWTSTAMP_FILTER_ALL
)
&&
(
ntohs
(
skb
->
protocol
)
==
ETH_P_IP
))
{
u8
transport_poto
,
msg_type
;
u16
dst_port
;
/* While the GEM can timestamp PTP packets, it does
* not mark the RX descriptor to identify them. This
* is entirely the wrong place to be parsing UDP
* headers, but some minimal effort must be made.
* NOTE: the below parsing of ip_proto and dest_port
* depend on the use of Ethernet_II encapsulation,
* IPv4 without any options.
*/
skb_copy_from_linear_data_offset
(
skb
,
XEMACPS_IP_PROTO_OFFSET
,
&
transport_poto
,
1
);
if
(
transport_poto
==
IPPROTO_UDP
)
{
skb_copy_from_linear_data_offset
(
skb
,
XEMACPS_UDP_PORT_OFFSET
,
&
dst_port
,
2
);
if
(
ntohs
(
dst_port
)
==
XEMACPS_PTP_EVENT_PORT_NUM
)
{
skb_copy_from_linear_data_offset
(
skb
,
XEMACPS_RX_PTPHDR_OFFSET
,
&
msg_type
,
1
);
xemacps_rx_hwtstamp
(
lp
,
skb
,
msg_type
&
0x2
);
}
}
}
#endif
/* CONFIG_XILINX_PS_EMAC_HWTSTAMP */
size
+=
len
;
packets
++
;
netif_receive_skb
(
skb
);
cur_p
->
addr
=
(
cur_p
->
addr
&
~
XEMACPS_RXBUF_ADD_MASK
)
|
(
new_skb_baddr
);
lp
->
rx_skb
[
lp
->
rx_bd_ci
].
skb
=
new_skb
;
lp
->
rx_skb
[
lp
->
rx_bd_ci
].
mapping
=
new_skb_baddr
;
lp
->
rx_skb
[
lp
->
rx_bd_ci
].
len
=
XEMACPS_RX_BUF_SIZE
;
cur_p
->
ctrl
=
0
;
cur_p
->
addr
&=
(
~
XEMACPS_RXBUF_NEW_MASK
);
wmb
();
lp
->
rx_bd_ci
++
;
lp
->
rx_bd_ci
=
lp
->
rx_bd_ci
%
XEMACPS_RECV_BD_CNT
;
cur_p
=
&
lp
->
rx_bd
[
lp
->
rx_bd_ci
];
regval
=
cur_p
->
addr
;
rmb
();
numbdfree
++
;
}
wmb
();
lp
->
stats
.
rx_packets
+=
packets
;
lp
->
stats
.
rx_bytes
+=
size
;
return
numbdfree
;
}
/**
* xemacps_rx_poll - NAPI poll routine
* @napi: pointer to napi struct
* @budget: NAPI budget
* Return: number of BDs processed
*/
static
int
xemacps_rx_poll
(
struct
napi_struct
*
napi
,
int
budget
)
{
struct
net_local
*
lp
=
container_of
(
napi
,
struct
net_local
,
napi
);
int
work_done
=
0
;
u32
count
;
spin_lock
(
&
lp
->
rx_lock
);
while
(
1
)
{
count
=
xemacps_rx
(
lp
,
budget
-
work_done
);
if
(
count
==
0xFFFFFFFF
)
{
napi_complete
(
napi
);
spin_unlock
(
&
lp
->
rx_lock
);
goto
reset_hw
;
}
work_done
+=
count
;
if
(
work_done
>=
budget
)
break
;
napi_complete
(
napi
);
/* We disabled RX interrupts in interrupt service
* routine, now it is time to enable it back.
*/
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_IER_OFFSET
,
XEMACPS_IXR_FRAMERX_MASK
);
/* If a packet has come in between the last check of the BD
* list and unmasking the interrupts, we may have missed the
* interrupt, so reschedule here.
*/
if
((
lp
->
rx_bd
[
lp
->
rx_bd_ci
].
addr
&
XEMACPS_RXBUF_NEW_MASK
)
&&
napi_reschedule
(
napi
))
{
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_IDR_OFFSET
,
XEMACPS_IXR_FRAMERX_MASK
);
continue
;
}
break
;
}
spin_unlock
(
&
lp
->
rx_lock
);
return
work_done
;
reset_hw:
queue_work
(
lp
->
txtimeout_handler_wq
,
&
lp
->
txtimeout_reinit
);
return
0
;
}
/**
* xemacps_tx_poll - tx bd reclaim tasklet handler
* @data: pointer to network interface device structure
*/
static
void
xemacps_tx_poll
(
unsigned
long
data
)
{
struct
net_device
*
ndev
=
(
struct
net_device
*
)
data
;
struct
net_local
*
lp
=
netdev_priv
(
ndev
);
u32
regval
;
struct
xemacps_bd
*
cur_p
;
u32
numbdsinhw
;
struct
ring_info
*
rp
;
struct
sk_buff
*
skb
;
unsigned
long
flags
;
u32
txbdcount
=
0
;
bool
isfrag
=
false
;
numbdsinhw
=
XEMACPS_SEND_BD_CNT
-
lp
->
tx_bd_freecnt
;
if
(
!
numbdsinhw
)
return
;
regval
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_TXSR_OFFSET
);
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_TXSR_OFFSET
,
regval
);
dev_dbg
(
&
lp
->
pdev
->
dev
,
"TX status 0x%x
\n
"
,
regval
);
if
(
regval
&
(
XEMACPS_TXSR_HRESPNOK_MASK
|
XEMACPS_TXSR_BUFEXH_MASK
))
dev_err
(
&
lp
->
pdev
->
dev
,
"TX error 0x%x
\n
"
,
regval
);
cur_p
=
&
lp
->
tx_bd
[
lp
->
tx_bd_ci
];
while
(
numbdsinhw
)
{
if
((
cur_p
->
ctrl
&
XEMACPS_TXBUF_USED_MASK
)
!=
XEMACPS_TXBUF_USED_MASK
)
{
if
(
isfrag
==
false
)
break
;
}
rp
=
&
lp
->
tx_skb
[
lp
->
tx_bd_ci
];
skb
=
rp
->
skb
;
lp
->
stats
.
tx_bytes
+=
cur_p
->
ctrl
&
XEMACPS_TXBUF_LEN_MASK
;
#ifdef CONFIG_XILINX_PS_EMAC_HWTSTAMP
if
(
skb_shinfo
(
skb
)
->
tx_flags
&
SKBTX_HW_TSTAMP
)
{
u8
msg_type
;
skb_copy_from_linear_data_offset
(
skb
,
XEMACPS_TX_PTPHDR_OFFSET
,
&
msg_type
,
1
);
xemacps_tx_hwtstamp
(
lp
,
skb
,
msg_type
&
0x2
);
}
#endif
/* CONFIG_XILINX_PS_EMAC_HWTSTAMP */
dma_unmap_single
(
&
lp
->
pdev
->
dev
,
rp
->
mapping
,
rp
->
len
,
DMA_TO_DEVICE
);
rp
->
skb
=
NULL
;
dev_kfree_skb
(
skb
);
/* log tx completed packets, errors logs
* are in other error counters.
*/
if
(
cur_p
->
ctrl
&
XEMACPS_TXBUF_LAST_MASK
)
{
lp
->
stats
.
tx_packets
++
;
isfrag
=
false
;
}
else
{
isfrag
=
true
;
}
/* Set used bit, preserve wrap bit; clear everything else. */
cur_p
->
ctrl
|=
XEMACPS_TXBUF_USED_MASK
;
cur_p
->
ctrl
&=
(
XEMACPS_TXBUF_USED_MASK
|
XEMACPS_TXBUF_WRAP_MASK
);
lp
->
tx_bd_ci
++
;
lp
->
tx_bd_ci
=
lp
->
tx_bd_ci
%
XEMACPS_SEND_BD_CNT
;
cur_p
=
&
lp
->
tx_bd
[
lp
->
tx_bd_ci
];
numbdsinhw
--
;
txbdcount
++
;
}
spin_lock
(
&
lp
->
tx_lock
);
lp
->
tx_bd_freecnt
+=
txbdcount
;
spin_unlock
(
&
lp
->
tx_lock
);
if
(
numbdsinhw
)
{
spin_lock_irqsave
(
&
lp
->
nwctrlreg_lock
,
flags
);
regval
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_NWCTRL_OFFSET
);
regval
|=
XEMACPS_NWCTRL_STARTTX_MASK
;
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_NWCTRL_OFFSET
,
regval
);
spin_unlock_irqrestore
(
&
lp
->
nwctrlreg_lock
,
flags
);
}
netif_wake_queue
(
ndev
);
}
/**
* xemacps_interrupt - interrupt main service routine
* @irq: interrupt number
* @dev_id: pointer to a network device structure
* Return: IRQ_HANDLED or IRQ_NONE
*/
static
irqreturn_t
xemacps_interrupt
(
int
irq
,
void
*
dev_id
)
{
struct
net_device
*
ndev
=
dev_id
;
struct
net_local
*
lp
=
netdev_priv
(
ndev
);
u32
regisr
;
u32
regctrl
;
regisr
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_ISR_OFFSET
);
if
(
unlikely
(
!
regisr
))
return
IRQ_NONE
;
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_ISR_OFFSET
,
regisr
);
while
(
regisr
)
{
if
(
regisr
&
(
XEMACPS_IXR_TXCOMPL_MASK
|
XEMACPS_IXR_TX_ERR_MASK
))
{
tasklet_schedule
(
&
lp
->
tx_bdreclaim_tasklet
);
}
if
(
regisr
&
XEMACPS_IXR_RXUSED_MASK
)
{
spin_lock
(
&
lp
->
nwctrlreg_lock
);
regctrl
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_NWCTRL_OFFSET
);
regctrl
|=
XEMACPS_NWCTRL_FLUSH_DPRAM_MASK
;
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_NWCTRL_OFFSET
,
regctrl
);
spin_unlock
(
&
lp
->
nwctrlreg_lock
);
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_IDR_OFFSET
,
XEMACPS_IXR_FRAMERX_MASK
);
napi_schedule
(
&
lp
->
napi
);
}
if
(
regisr
&
XEMACPS_IXR_FRAMERX_MASK
)
{
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_IDR_OFFSET
,
XEMACPS_IXR_FRAMERX_MASK
);
napi_schedule
(
&
lp
->
napi
);
}
regisr
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_ISR_OFFSET
);
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_ISR_OFFSET
,
regisr
);
}
return
IRQ_HANDLED
;
}
/*
* Free all packets presently in the descriptor rings.
*/
static
void
xemacps_clean_rings
(
struct
net_local
*
lp
)
{
int
i
;
for
(
i
=
0
;
i
<
XEMACPS_RECV_BD_CNT
;
i
++
)
{
if
(
lp
->
rx_skb
&&
lp
->
rx_skb
[
i
].
skb
)
{
dma_unmap_single
(
lp
->
ndev
->
dev
.
parent
,
lp
->
rx_skb
[
i
].
mapping
,
lp
->
rx_skb
[
i
].
len
,
DMA_FROM_DEVICE
);
dev_kfree_skb
(
lp
->
rx_skb
[
i
].
skb
);
lp
->
rx_skb
[
i
].
skb
=
NULL
;
lp
->
rx_skb
[
i
].
mapping
=
0
;
}
}
for
(
i
=
0
;
i
<
XEMACPS_SEND_BD_CNT
;
i
++
)
{
if
(
lp
->
tx_skb
&&
lp
->
tx_skb
[
i
].
skb
)
{
dma_unmap_single
(
lp
->
ndev
->
dev
.
parent
,
lp
->
tx_skb
[
i
].
mapping
,
lp
->
tx_skb
[
i
].
len
,
DMA_TO_DEVICE
);
dev_kfree_skb
(
lp
->
tx_skb
[
i
].
skb
);
lp
->
tx_skb
[
i
].
skb
=
NULL
;
lp
->
tx_skb
[
i
].
mapping
=
0
;
}
}
}
/**
* xemacps_descriptor_free - Free allocated TX and RX BDs
* @lp: local device instance pointer
*/
static
void
xemacps_descriptor_free
(
struct
net_local
*
lp
)
{
int
size
;
xemacps_clean_rings
(
lp
);
/* kfree(NULL) is safe, no need to check here */
kfree
(
lp
->
tx_skb
);
lp
->
tx_skb
=
NULL
;
kfree
(
lp
->
rx_skb
);
lp
->
rx_skb
=
NULL
;
size
=
XEMACPS_RECV_BD_CNT
*
sizeof
(
struct
xemacps_bd
);
if
(
lp
->
rx_bd
)
{
dma_free_coherent
(
&
lp
->
pdev
->
dev
,
size
,
lp
->
rx_bd
,
lp
->
rx_bd_dma
);
lp
->
rx_bd
=
NULL
;
}
size
=
XEMACPS_SEND_BD_CNT
*
sizeof
(
struct
xemacps_bd
);
if
(
lp
->
tx_bd
)
{
dma_free_coherent
(
&
lp
->
pdev
->
dev
,
size
,
lp
->
tx_bd
,
lp
->
tx_bd_dma
);
lp
->
tx_bd
=
NULL
;
}
}
/**
* xemacps_descriptor_init - Allocate both TX and RX BDs
* @lp: local device instance pointer
* Return: 0 on success, negative value if error
*/
static
int
xemacps_descriptor_init
(
struct
net_local
*
lp
)
{
int
size
;
struct
sk_buff
*
new_skb
;
u32
new_skb_baddr
;
u32
i
;
struct
xemacps_bd
*
cur_p
;
u32
regval
;
lp
->
tx_skb
=
NULL
;
lp
->
rx_skb
=
NULL
;
lp
->
rx_bd
=
NULL
;
lp
->
tx_bd
=
NULL
;
/* Reset the indexes which are used for accessing the BDs */
lp
->
tx_bd_ci
=
0
;
lp
->
tx_bd_tail
=
0
;
lp
->
rx_bd_ci
=
0
;
size
=
XEMACPS_SEND_BD_CNT
*
sizeof
(
struct
ring_info
);
lp
->
tx_skb
=
kzalloc
(
size
,
GFP_KERNEL
);
if
(
!
lp
->
tx_skb
)
goto
err_out
;
size
=
XEMACPS_RECV_BD_CNT
*
sizeof
(
struct
ring_info
);
lp
->
rx_skb
=
kzalloc
(
size
,
GFP_KERNEL
);
if
(
!
lp
->
rx_skb
)
goto
err_out
;
/*
* Set up RX buffer descriptors.
*/
size
=
XEMACPS_RECV_BD_CNT
*
sizeof
(
struct
xemacps_bd
);
lp
->
rx_bd
=
dma_alloc_coherent
(
&
lp
->
pdev
->
dev
,
size
,
&
lp
->
rx_bd_dma
,
GFP_KERNEL
);
if
(
!
lp
->
rx_bd
)
goto
err_out
;
dev_dbg
(
&
lp
->
pdev
->
dev
,
"RX ring %d bytes at 0x%x mapped %p
\n
"
,
size
,
lp
->
rx_bd_dma
,
lp
->
rx_bd
);
for
(
i
=
0
;
i
<
XEMACPS_RECV_BD_CNT
;
i
++
)
{
cur_p
=
&
lp
->
rx_bd
[
i
];
new_skb
=
netdev_alloc_skb
(
lp
->
ndev
,
XEMACPS_RX_BUF_SIZE
);
if
(
new_skb
==
NULL
)
{
dev_err
(
&
lp
->
ndev
->
dev
,
"alloc_skb error %d
\n
"
,
i
);
goto
err_out
;
}
/* Get dma handle of skb->data */
new_skb_baddr
=
(
u32
)
dma_map_single
(
lp
->
ndev
->
dev
.
parent
,
new_skb
->
data
,
XEMACPS_RX_BUF_SIZE
,
DMA_FROM_DEVICE
);
if
(
dma_mapping_error
(
lp
->
ndev
->
dev
.
parent
,
new_skb_baddr
))
goto
err_out
;
/* set wrap bit for last BD */
regval
=
(
new_skb_baddr
&
XEMACPS_RXBUF_ADD_MASK
);
if
(
i
==
XEMACPS_RECV_BD_CNT
-
1
)
regval
|=
XEMACPS_RXBUF_WRAP_MASK
;
cur_p
->
addr
=
regval
;
cur_p
->
ctrl
=
0
;
wmb
();
lp
->
rx_skb
[
i
].
skb
=
new_skb
;
lp
->
rx_skb
[
i
].
mapping
=
new_skb_baddr
;
lp
->
rx_skb
[
i
].
len
=
XEMACPS_RX_BUF_SIZE
;
}
/*
* Set up TX buffer descriptors.
*/
size
=
XEMACPS_SEND_BD_CNT
*
sizeof
(
struct
xemacps_bd
);
lp
->
tx_bd
=
dma_alloc_coherent
(
&
lp
->
pdev
->
dev
,
size
,
&
lp
->
tx_bd_dma
,
GFP_KERNEL
);
if
(
!
lp
->
tx_bd
)
goto
err_out
;
dev_dbg
(
&
lp
->
pdev
->
dev
,
"TX ring %d bytes at 0x%x mapped %p
\n
"
,
size
,
lp
->
tx_bd_dma
,
lp
->
tx_bd
);
for
(
i
=
0
;
i
<
XEMACPS_SEND_BD_CNT
;
i
++
)
{
cur_p
=
&
lp
->
tx_bd
[
i
];
/* set wrap bit for last BD */
cur_p
->
addr
=
0
;
regval
=
XEMACPS_TXBUF_USED_MASK
;
if
(
i
==
XEMACPS_SEND_BD_CNT
-
1
)
regval
|=
XEMACPS_TXBUF_WRAP_MASK
;
cur_p
->
ctrl
=
regval
;
}
wmb
();
lp
->
tx_bd_freecnt
=
XEMACPS_SEND_BD_CNT
;
dev_dbg
(
&
lp
->
pdev
->
dev
,
"lp->tx_bd %p lp->tx_bd_dma %p lp->tx_skb %p
\n
"
,
lp
->
tx_bd
,
(
void
*
)
lp
->
tx_bd_dma
,
lp
->
tx_skb
);
dev_dbg
(
&
lp
->
pdev
->
dev
,
"lp->rx_bd %p lp->rx_bd_dma %p lp->rx_skb %p
\n
"
,
lp
->
rx_bd
,
(
void
*
)
lp
->
rx_bd_dma
,
lp
->
rx_skb
);
return
0
;
err_out:
xemacps_descriptor_free
(
lp
);
return
-
ENOMEM
;
}
/**
* xemacps_init_hw - Initialize hardware to known good state
* @lp: local device instance pointer
*/
static
void
xemacps_init_hw
(
struct
net_local
*
lp
)
{
u32
regval
;
xemacps_reset_hw
(
lp
);
xemacps_set_hwaddr
(
lp
);
/* network configuration */
regval
=
0
;
regval
|=
XEMACPS_NWCFG_FDEN_MASK
;
regval
|=
XEMACPS_NWCFG_RXCHKSUMEN_MASK
;
regval
|=
XEMACPS_NWCFG_PAUSECOPYDI_MASK
;
regval
|=
XEMACPS_NWCFG_FCSREM_MASK
;
regval
|=
XEMACPS_NWCFG_PAUSEEN_MASK
;
regval
|=
XEMACPS_NWCFG_100_MASK
;
regval
|=
XEMACPS_NWCFG_HDRXEN_MASK
;
regval
|=
(
MDC_DIV_224
<<
XEMACPS_NWCFG_MDC_SHIFT_MASK
);
if
(
lp
->
ndev
->
flags
&
IFF_PROMISC
)
/* copy all */
regval
|=
XEMACPS_NWCFG_COPYALLEN_MASK
;
if
(
!
(
lp
->
ndev
->
flags
&
IFF_BROADCAST
))
/* No broadcast */
regval
|=
XEMACPS_NWCFG_BCASTDI_MASK
;
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_NWCFG_OFFSET
,
regval
);
/* Init TX and RX DMA Q address */
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_RXQBASE_OFFSET
,
lp
->
rx_bd_dma
);
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_TXQBASE_OFFSET
,
lp
->
tx_bd_dma
);
/* DMACR configurations */
regval
=
(((
XEMACPS_RX_BUF_SIZE
/
XEMACPS_RX_BUF_UNIT
)
+
((
XEMACPS_RX_BUF_SIZE
%
XEMACPS_RX_BUF_UNIT
)
?
1
:
0
))
<<
XEMACPS_DMACR_RXBUF_SHIFT
);
regval
|=
XEMACPS_DMACR_RXSIZE_MASK
;
regval
|=
XEMACPS_DMACR_TXSIZE_MASK
;
regval
|=
XEMACPS_DMACR_TCPCKSUM_MASK
;
#ifdef __LITTLE_ENDIAN
regval
&=
~
XEMACPS_DMACR_ENDIAN_MASK
;
#endif
#ifdef __BIG_ENDIAN
regval
|=
XEMACPS_DMACR_ENDIAN_MASK
;
#endif
regval
|=
XEMACPS_DMACR_BLENGTH_INCR16
;
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_DMACR_OFFSET
,
regval
);
/* Enable TX, RX and MDIO port */
regval
=
0
;
regval
|=
XEMACPS_NWCTRL_MDEN_MASK
;
regval
|=
XEMACPS_NWCTRL_TXEN_MASK
;
regval
|=
XEMACPS_NWCTRL_RXEN_MASK
;
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_NWCTRL_OFFSET
,
regval
);
#ifdef CONFIG_XILINX_PS_EMAC_HWTSTAMP
/* Initialize the ptp clock */
xemacps_ptp_init
(
lp
);
#endif
/* Enable interrupts */
regval
=
XEMACPS_IXR_ALL_MASK
;
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_IER_OFFSET
,
regval
);
}
/**
* xemacps_resetrx_for_no_rxdata - Resets the Rx if there is no data
* for a while (presently 100 msecs)
* @data: Used for net_local instance pointer
*/
static
void
xemacps_resetrx_for_no_rxdata
(
unsigned
long
data
)
{
struct
net_local
*
lp
=
(
struct
net_local
*
)
data
;
unsigned
long
regctrl
;
unsigned
long
tempcntr
;
unsigned
long
flags
;
tempcntr
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_RXCNT_OFFSET
);
if
((
!
tempcntr
)
&&
(
!
(
lp
->
lastrxfrmscntr
)))
{
spin_lock_irqsave
(
&
lp
->
nwctrlreg_lock
,
flags
);
regctrl
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_NWCTRL_OFFSET
);
regctrl
&=
(
~
XEMACPS_NWCTRL_RXEN_MASK
);
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_NWCTRL_OFFSET
,
regctrl
);
regctrl
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_NWCTRL_OFFSET
);
regctrl
|=
(
XEMACPS_NWCTRL_RXEN_MASK
);
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_NWCTRL_OFFSET
,
regctrl
);
spin_unlock_irqrestore
(
&
lp
->
nwctrlreg_lock
,
flags
);
}
lp
->
lastrxfrmscntr
=
tempcntr
;
}
/**
* xemacps_update_stats - Update the statistic structure entries from
* the corresponding emacps hardware statistic registers
* @data: Used for net_local instance pointer
*/
static
void
xemacps_update_stats
(
unsigned
long
data
)
{
struct
net_local
*
lp
=
(
struct
net_local
*
)
data
;
struct
net_device_stats
*
nstat
=
&
lp
->
stats
;
u32
cnt
;
cnt
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_RXUNDRCNT_OFFSET
);
nstat
->
rx_errors
+=
cnt
;
nstat
->
rx_length_errors
+=
cnt
;
cnt
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_RXOVRCNT_OFFSET
);
nstat
->
rx_errors
+=
cnt
;
nstat
->
rx_length_errors
+=
cnt
;
cnt
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_RXJABCNT_OFFSET
);
nstat
->
rx_errors
+=
cnt
;
nstat
->
rx_length_errors
+=
cnt
;
cnt
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_RXFCSCNT_OFFSET
);
nstat
->
rx_errors
+=
cnt
;
nstat
->
rx_crc_errors
+=
cnt
;
cnt
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_RXLENGTHCNT_OFFSET
);
nstat
->
rx_errors
+=
cnt
;
nstat
->
rx_length_errors
+=
cnt
;
cnt
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_RXALIGNCNT_OFFSET
);
nstat
->
rx_errors
+=
cnt
;
nstat
->
rx_frame_errors
+=
cnt
;
cnt
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_RXRESERRCNT_OFFSET
);
nstat
->
rx_errors
+=
cnt
;
nstat
->
rx_missed_errors
+=
cnt
;
cnt
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_RXORCNT_OFFSET
);
nstat
->
rx_errors
+=
cnt
;
nstat
->
rx_fifo_errors
+=
cnt
;
cnt
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_TXURUNCNT_OFFSET
);
nstat
->
tx_errors
+=
cnt
;
nstat
->
tx_fifo_errors
+=
cnt
;
cnt
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_SNGLCOLLCNT_OFFSET
);
nstat
->
collisions
+=
cnt
;
cnt
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_MULTICOLLCNT_OFFSET
);
nstat
->
collisions
+=
cnt
;
cnt
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_EXCESSCOLLCNT_OFFSET
);
nstat
->
tx_errors
+=
cnt
;
nstat
->
tx_aborted_errors
+=
cnt
;
nstat
->
collisions
+=
cnt
;
cnt
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_LATECOLLCNT_OFFSET
);
nstat
->
tx_errors
+=
cnt
;
nstat
->
collisions
+=
cnt
;
cnt
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_CSENSECNT_OFFSET
);
nstat
->
tx_errors
+=
cnt
;
nstat
->
tx_carrier_errors
+=
cnt
;
}
/**
* xemacps_gen_purpose_timerhandler - Timer handler that is called at regular
* intervals upon expiry of the gen_purpose_timer defined in net_local struct.
* @data: Used for net_local instance pointer
*
* This timer handler is used to update the statistics by calling the API
* xemacps_update_stats. The statistics register can typically overflow pretty
* quickly under heavy load conditions. This timer is used to periodically
* read the stats registers and update the corresponding stats structure
* entries. The stats registers when read reset to 0.
*/
static
void
xemacps_gen_purpose_timerhandler
(
unsigned
long
data
)
{
struct
net_local
*
lp
=
(
struct
net_local
*
)
data
;
xemacps_update_stats
(
data
);
xemacps_resetrx_for_no_rxdata
(
data
);
mod_timer
(
&
(
lp
->
gen_purpose_timer
),
jiffies
+
msecs_to_jiffies
(
XEAMCPS_GEN_PURPOSE_TIMER_LOAD
));
}
/**
* xemacps_open - Called when a network device is made active
* @ndev: network interface device structure
* Return: 0 on success, negative value if error
*
* The open entry point is called when a network interface is made active
* by the system (IFF_UP). At this point all resources needed for transmit
* and receive operations are allocated, the interrupt handler is
* registered with OS, the watchdog timer is started, and the stack is
* notified that the interface is ready.
*
* note: if error(s), allocated resources before error require to be
* released or system issues (such as memory) leak might happen.
*/
static
int
xemacps_open
(
struct
net_device
*
ndev
)
{
struct
net_local
*
lp
=
netdev_priv
(
ndev
);
int
rc
;
dev_dbg
(
&
lp
->
pdev
->
dev
,
"open
\n
"
);
if
(
!
is_valid_ether_addr
(
ndev
->
dev_addr
))
return
-
EADDRNOTAVAIL
;
rc
=
xemacps_descriptor_init
(
lp
);
if
(
rc
)
{
dev_err
(
&
lp
->
pdev
->
dev
,
"Unable to allocate DMA memory, rc %d
\n
"
,
rc
);
return
rc
;
}
rc
=
pm_runtime_get_sync
(
&
lp
->
pdev
->
dev
);
if
(
rc
<
0
)
{
dev_err
(
&
lp
->
pdev
->
dev
,
"pm_runtime_get_sync() failed, rc %d
\n
"
,
rc
);
goto
err_free_rings
;
}
napi_enable
(
&
lp
->
napi
);
xemacps_init_hw
(
lp
);
setup_timer
(
&
(
lp
->
gen_purpose_timer
),
xemacps_gen_purpose_timerhandler
,
(
unsigned
long
)
lp
);
lp
->
timerready
=
true
;
netif_carrier_off
(
ndev
);
rc
=
xemacps_mii_probe
(
ndev
);
if
(
rc
!=
0
)
{
dev_err
(
&
lp
->
pdev
->
dev
,
"%s mii_probe fail.
\n
"
,
lp
->
mii_bus
->
name
);
rc
=
-
ENXIO
;
goto
err_pm_put
;
}
mod_timer
(
&
(
lp
->
gen_purpose_timer
),
jiffies
+
msecs_to_jiffies
(
XEAMCPS_GEN_PURPOSE_TIMER_LOAD
));
netif_start_queue
(
ndev
);
tasklet_enable
(
&
lp
->
tx_bdreclaim_tasklet
);
return
0
;
err_pm_put:
napi_disable
(
&
lp
->
napi
);
xemacps_reset_hw
(
lp
);
if
(
lp
->
timerready
)
{
del_timer_sync
(
&
(
lp
->
gen_purpose_timer
));
lp
->
timerready
=
false
;
}
pm_runtime_put
(
&
lp
->
pdev
->
dev
);
err_free_rings:
xemacps_descriptor_free
(
lp
);
return
rc
;
}
/**
* xemacps_close - disable a network interface
* @ndev: network interface device structure
* Return: 0
*
* The close entry point is called when a network interface is de-activated
* by OS. The hardware is still under the driver control, but needs to be
* disabled. A global MAC reset is issued to stop the hardware, and all
* transmit and receive resources are freed.
*/
static
int
xemacps_close
(
struct
net_device
*
ndev
)
{
struct
net_local
*
lp
=
netdev_priv
(
ndev
);
if
(
lp
->
timerready
)
del_timer_sync
(
&
(
lp
->
gen_purpose_timer
));
netif_stop_queue
(
ndev
);
napi_disable
(
&
lp
->
napi
);
tasklet_disable
(
&
lp
->
tx_bdreclaim_tasklet
);
if
(
lp
->
phy_dev
)
phy_disconnect
(
lp
->
phy_dev
);
if
(
lp
->
gmii2rgmii_phy_dev
)
phy_disconnect
(
lp
->
gmii2rgmii_phy_dev
);
netif_carrier_off
(
ndev
);
xemacps_reset_hw
(
lp
);
#ifdef CONFIG_XILINX_PS_EMAC_HWTSTAMP
xemacps_ptp_close
(
lp
);
#endif
mdelay
(
500
);
xemacps_descriptor_free
(
lp
);
pm_runtime_put
(
&
lp
->
pdev
->
dev
);
return
0
;
}
/**
* xemacps_reinit_for_txtimeout - work queue scheduled for the tx timeout
* handling.
* @data: queue work structure
*/
static
void
xemacps_reinit_for_txtimeout
(
struct
work_struct
*
data
)
{
struct
net_local
*
lp
=
container_of
(
data
,
struct
net_local
,
txtimeout_reinit
);
int
rc
;
netif_stop_queue
(
lp
->
ndev
);
napi_disable
(
&
lp
->
napi
);
tasklet_disable
(
&
lp
->
tx_bdreclaim_tasklet
);
spin_lock_bh
(
&
lp
->
tx_lock
);
xemacps_reset_hw
(
lp
);
spin_unlock_bh
(
&
lp
->
tx_lock
);
if
(
lp
->
phy_dev
)
phy_stop
(
lp
->
phy_dev
);
xemacps_descriptor_free
(
lp
);
rc
=
xemacps_descriptor_init
(
lp
);
if
(
rc
)
{
dev_err
(
&
lp
->
pdev
->
dev
,
"Unable to allocate DMA memory, rc %d
\n
"
,
rc
);
return
;
}
xemacps_init_hw
(
lp
);
lp
->
link
=
0
;
lp
->
speed
=
0
;
lp
->
duplex
=
-
1
;
if
(
lp
->
phy_dev
)
phy_start
(
lp
->
phy_dev
);
napi_enable
(
&
lp
->
napi
);
tasklet_enable
(
&
lp
->
tx_bdreclaim_tasklet
);
netif_trans_update
(
lp
->
ndev
);
netif_wake_queue
(
lp
->
ndev
);
}
/**
* xemacps_tx_timeout - callback used when the transmitter has not made
* any progress for dev->watchdog ticks.
* @ndev: network interface device structure
*/
static
void
xemacps_tx_timeout
(
struct
net_device
*
ndev
)
{
struct
net_local
*
lp
=
netdev_priv
(
ndev
);
dev_err
(
&
lp
->
pdev
->
dev
,
"transmit timeout %lu ms, reseting...
\n
"
,
TX_TIMEOUT
*
1000UL
/
HZ
);
queue_work
(
lp
->
txtimeout_handler_wq
,
&
lp
->
txtimeout_reinit
);
}
/**
* xemacps_clear_csum - Clear the csum field for transport protocols
* @skb: socket buffer
* @ndev: network interface device structure
* Return: 0 on success, other value if error
*/
static
int
xemacps_clear_csum
(
struct
sk_buff
*
skb
,
struct
net_device
*
ndev
)
{
/* Only run for packets requiring a checksum. */
if
(
skb
->
ip_summed
!=
CHECKSUM_PARTIAL
)
return
0
;
if
(
unlikely
(
skb_cow_head
(
skb
,
0
)))
return
-
1
;
*
(
__sum16
*
)(
skb
->
head
+
skb
->
csum_start
+
skb
->
csum_offset
)
=
0
;
return
0
;
}
/**
* unwind_tx_frag_mapping - unwind the tx fragment mapping
* @lp: driver control structure
* @fragcnt: fragment count
*/
static
void
unwind_tx_frag_mapping
(
struct
net_local
*
lp
,
int
fragcnt
)
{
struct
xemacps_bd
*
cur_p
;
for
(;
fragcnt
>
0
;
fragcnt
--
)
{
cur_p
=
&
lp
->
tx_bd
[
lp
->
tx_bd_freecnt
];
dma_unmap_single
(
&
lp
->
pdev
->
dev
,
cur_p
->
addr
,
(
cur_p
->
ctrl
&
XEMACPS_TXBUF_LEN_MASK
),
DMA_TO_DEVICE
);
cur_p
->
ctrl
|=
XEMACPS_TXBUF_USED_MASK
;
if
(
lp
->
tx_bd_freecnt
)
lp
->
tx_bd_freecnt
--
;
else
lp
->
tx_bd_freecnt
=
XEMACPS_SEND_BD_CNT
-
1
;
}
}
/**
* xemacps_start_xmit - transmit a packet (called by kernel)
* @skb: socket buffer
* @ndev: network interface device structure
* Return: 0 on success, other value if error
*/
static
int
xemacps_start_xmit
(
struct
sk_buff
*
skb
,
struct
net_device
*
ndev
)
{
struct
net_local
*
lp
=
netdev_priv
(
ndev
);
dma_addr_t
mapping
;
unsigned
int
nr_frags
,
len
;
int
i
;
u32
regval
;
void
*
virt_addr
;
skb_frag_t
*
frag
;
struct
xemacps_bd
*
cur_p
;
unsigned
long
flags
;
u32
bd_tail
;
nr_frags
=
skb_shinfo
(
skb
)
->
nr_frags
+
1
;
if
(
nr_frags
>
lp
->
tx_bd_freecnt
)
{
netif_stop_queue
(
ndev
);
/* stop send queue */
return
NETDEV_TX_BUSY
;
}
if
(
xemacps_clear_csum
(
skb
,
ndev
))
{
kfree
(
skb
);
return
NETDEV_TX_OK
;
}
bd_tail
=
lp
->
tx_bd_tail
;
cur_p
=
&
lp
->
tx_bd
[
bd_tail
];
frag
=
&
skb_shinfo
(
skb
)
->
frags
[
0
];
for
(
i
=
0
;
i
<
nr_frags
;
i
++
)
{
if
(
i
==
0
)
{
len
=
skb_headlen
(
skb
);
mapping
=
dma_map_single
(
&
lp
->
pdev
->
dev
,
skb
->
data
,
len
,
DMA_TO_DEVICE
);
}
else
{
len
=
skb_frag_size
(
frag
);
virt_addr
=
skb_frag_address
(
frag
);
mapping
=
dma_map_single
(
&
lp
->
pdev
->
dev
,
virt_addr
,
len
,
DMA_TO_DEVICE
);
frag
++
;
skb_get
(
skb
);
}
if
(
dma_mapping_error
(
&
lp
->
pdev
->
dev
,
mapping
))
{
if
(
i
)
unwind_tx_frag_mapping
(
lp
,
i
);
goto
dma_err
;
}
lp
->
tx_skb
[
lp
->
tx_bd_tail
].
skb
=
skb
;
lp
->
tx_skb
[
lp
->
tx_bd_tail
].
mapping
=
mapping
;
lp
->
tx_skb
[
lp
->
tx_bd_tail
].
len
=
len
;
cur_p
->
addr
=
mapping
;
/* preserve critical status bits */
regval
=
cur_p
->
ctrl
;
regval
&=
(
XEMACPS_TXBUF_USED_MASK
|
XEMACPS_TXBUF_WRAP_MASK
);
/* update length field */
regval
|=
((
regval
&
~
XEMACPS_TXBUF_LEN_MASK
)
|
len
);
/* commit second to last buffer to hardware */
if
(
i
!=
0
)
regval
&=
~
XEMACPS_TXBUF_USED_MASK
;
/* last fragment of this packet? */
if
(
i
==
(
nr_frags
-
1
))
regval
|=
XEMACPS_TXBUF_LAST_MASK
;
cur_p
->
ctrl
=
regval
;
lp
->
tx_bd_tail
++
;
lp
->
tx_bd_tail
=
lp
->
tx_bd_tail
%
XEMACPS_SEND_BD_CNT
;
cur_p
=
&
(
lp
->
tx_bd
[
lp
->
tx_bd_tail
]);
}
/* commit first buffer to hardware -- do this after
* committing the other buffers to avoid an underrun */
cur_p
=
&
lp
->
tx_bd
[
bd_tail
];
regval
=
cur_p
->
ctrl
;
regval
&=
~
XEMACPS_TXBUF_USED_MASK
;
cur_p
->
ctrl
=
regval
;
spin_lock_bh
(
&
lp
->
tx_lock
);
lp
->
tx_bd_freecnt
-=
nr_frags
;
spin_unlock_bh
(
&
lp
->
tx_lock
);
spin_lock_irqsave
(
&
lp
->
nwctrlreg_lock
,
flags
);
regval
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_NWCTRL_OFFSET
);
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_NWCTRL_OFFSET
,
(
regval
|
XEMACPS_NWCTRL_STARTTX_MASK
));
spin_unlock_irqrestore
(
&
lp
->
nwctrlreg_lock
,
flags
);
netif_trans_update
(
ndev
);
return
0
;
dma_err:
kfree_skb
(
skb
);
return
NETDEV_TX_OK
;
}
/*
* Get the MAC Address bit from the specified position
*/
static
unsigned
get_bit
(
u8
*
mac
,
unsigned
bit
)
{
unsigned
byte
;
byte
=
mac
[
bit
/
8
];
byte
>>=
(
bit
&
0x7
);
byte
&=
1
;
return
byte
;
}
/*
* Calculate a GEM MAC Address hash index
*/
static
unsigned
calc_mac_hash
(
u8
*
mac
)
{
int
index_bit
,
mac_bit
;
unsigned
hash_index
;
hash_index
=
0
;
mac_bit
=
5
;
for
(
index_bit
=
5
;
index_bit
>=
0
;
index_bit
--
)
{
hash_index
|=
(
get_bit
(
mac
,
mac_bit
)
^
get_bit
(
mac
,
mac_bit
+
6
)
^
get_bit
(
mac
,
mac_bit
+
12
)
^
get_bit
(
mac
,
mac_bit
+
18
)
^
get_bit
(
mac
,
mac_bit
+
24
)
^
get_bit
(
mac
,
mac_bit
+
30
)
^
get_bit
(
mac
,
mac_bit
+
36
)
^
get_bit
(
mac
,
mac_bit
+
42
))
<<
index_bit
;
mac_bit
--
;
}
return
hash_index
;
}
/**
* xemacps_set_hashtable - Add multicast addresses to the internal
* multicast-hash table. Called from xemac_set_rx_mode().
* @ndev: network interface device structure
*
* The hash address register is 64 bits long and takes up two
* locations in the memory map. The least significant bits are stored
* in EMAC_HSL and the most significant bits in EMAC_HSH.
*
* The unicast hash enable and the multicast hash enable bits in the
* network configuration register enable the reception of hash matched
* frames. The destination address is reduced to a 6 bit index into
* the 64 bit hash register using the following hash function. The
* hash function is an exclusive or of every sixth bit of the
* destination address.
*
* hi[5] = da[5] ^ da[11] ^ da[17] ^ da[23] ^ da[29] ^ da[35] ^ da[41] ^ da[47]
* hi[4] = da[4] ^ da[10] ^ da[16] ^ da[22] ^ da[28] ^ da[34] ^ da[40] ^ da[46]
* hi[3] = da[3] ^ da[09] ^ da[15] ^ da[21] ^ da[27] ^ da[33] ^ da[39] ^ da[45]
* hi[2] = da[2] ^ da[08] ^ da[14] ^ da[20] ^ da[26] ^ da[32] ^ da[38] ^ da[44]
* hi[1] = da[1] ^ da[07] ^ da[13] ^ da[19] ^ da[25] ^ da[31] ^ da[37] ^ da[43]
* hi[0] = da[0] ^ da[06] ^ da[12] ^ da[18] ^ da[24] ^ da[30] ^ da[36] ^ da[42]
*
* da[0] represents the least significant bit of the first byte
* received, that is, the multicast/unicast indicator, and da[47]
* represents the most significant bit of the last byte received. If
* the hash index, hi[n], points to a bit that is set in the hash
* register then the frame will be matched according to whether the
* frame is multicast or unicast. A multicast match will be signalled
* if the multicast hash enable bit is set, da[0] is 1 and the hash
* index points to a bit set in the hash register. A unicast match
* will be signalled if the unicast hash enable bit is set, da[0] is 0
* and the hash index points to a bit set in the hash register. To
* receive all multicast frames, the hash register should be set with
* all ones and the multicast hash enable bit should be set in the
* network configuration register.
*/
static
void
xemacps_set_hashtable
(
struct
net_device
*
ndev
)
{
struct
netdev_hw_addr
*
curr
;
u32
regvalh
,
regvall
,
hash_index
;
u8
*
mc_addr
;
struct
net_local
*
lp
;
lp
=
netdev_priv
(
ndev
);
regvalh
=
regvall
=
0
;
netdev_for_each_mc_addr
(
curr
,
ndev
)
{
if
(
!
curr
)
/* end of list */
break
;
mc_addr
=
curr
->
addr
;
hash_index
=
calc_mac_hash
(
mc_addr
);
if
(
hash_index
>=
XEMACPS_MAX_HASH_BITS
)
{
dev_err
(
&
lp
->
pdev
->
dev
,
"hash calculation out of range %d
\n
"
,
hash_index
);
break
;
}
if
(
hash_index
<
32
)
regvall
|=
(
1
<<
hash_index
);
else
regvalh
|=
(
1
<<
(
hash_index
-
32
));
}
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_HASHL_OFFSET
,
regvall
);
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_HASHH_OFFSET
,
regvalh
);
}
/**
* xemacps_set_rx_mode - enable/disable promiscuous and multicast modes
* @ndev: network interface device structure
*/
static
void
xemacps_set_rx_mode
(
struct
net_device
*
ndev
)
{
struct
net_local
*
lp
=
netdev_priv
(
ndev
);
u32
regval
;
regval
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_NWCFG_OFFSET
);
/* promisc mode */
if
(
ndev
->
flags
&
IFF_PROMISC
)
regval
|=
XEMACPS_NWCFG_COPYALLEN_MASK
;
if
(
!
(
ndev
->
flags
&
IFF_PROMISC
))
regval
&=
~
XEMACPS_NWCFG_COPYALLEN_MASK
;
/* All multicast mode */
if
(
ndev
->
flags
&
IFF_ALLMULTI
)
{
regval
|=
XEMACPS_NWCFG_MCASTHASHEN_MASK
;
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_HASHL_OFFSET
,
~
0UL
);
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_HASHH_OFFSET
,
~
0UL
);
/* Specific multicast mode */
}
else
if
((
ndev
->
flags
&
IFF_MULTICAST
)
&&
(
netdev_mc_count
(
ndev
)
>
0
))
{
regval
|=
XEMACPS_NWCFG_MCASTHASHEN_MASK
;
xemacps_set_hashtable
(
ndev
);
/* Disable multicast mode */
}
else
{
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_HASHL_OFFSET
,
0x0
);
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_HASHH_OFFSET
,
0x0
);
regval
&=
~
XEMACPS_NWCFG_MCASTHASHEN_MASK
;
}
/* broadcast mode */
if
(
ndev
->
flags
&
IFF_BROADCAST
)
regval
&=
~
XEMACPS_NWCFG_BCASTDI_MASK
;
/* No broadcast */
if
(
!
(
ndev
->
flags
&
IFF_BROADCAST
))
regval
|=
XEMACPS_NWCFG_BCASTDI_MASK
;
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_NWCFG_OFFSET
,
regval
);
}
/**
* xemacps_get_settings - get device specific settings.
* Usage: Issue "ethtool ethX" under linux prompt.
* @ndev: network device
* @ecmd: ethtool command structure
* Return: 0 on success, negative value if error.
*/
static
int
xemacps_get_settings
(
struct
net_device
*
ndev
,
struct
ethtool_cmd
*
ecmd
)
{
struct
net_local
*
lp
=
netdev_priv
(
ndev
);
struct
phy_device
*
phydev
=
lp
->
phy_dev
;
if
(
!
phydev
)
return
-
ENODEV
;
return
phy_ethtool_gset
(
phydev
,
ecmd
);
}
/**
* xemacps_set_settings - set device specific settings.
* Usage: Issue "ethtool -s ethX speed 1000" under linux prompt
* to change speed
* @ndev: network device
* @ecmd: ethtool command structure
* Return: 0 on success, negative value if error.
*/
static
int
xemacps_set_settings
(
struct
net_device
*
ndev
,
struct
ethtool_cmd
*
ecmd
)
{
struct
net_local
*
lp
=
netdev_priv
(
ndev
);
struct
phy_device
*
phydev
=
lp
->
phy_dev
;
if
(
!
phydev
)
return
-
ENODEV
;
return
phy_ethtool_sset
(
phydev
,
ecmd
);
}
/**
* xemacps_get_drvinfo - report driver information
* Usage: Issue "ethtool -i ethX" under linux prompt
* @ndev: network device
* @ed: device driver information structure
*/
static
void
xemacps_get_drvinfo
(
struct
net_device
*
ndev
,
struct
ethtool_drvinfo
*
ed
)
{
struct
net_local
*
lp
=
netdev_priv
(
ndev
);
memset
(
ed
,
0
,
sizeof
(
struct
ethtool_drvinfo
));
strcpy
(
ed
->
driver
,
lp
->
pdev
->
dev
.
driver
->
name
);
strcpy
(
ed
->
version
,
DRIVER_VERSION
);
}
/**
* xemacps_get_ringparam - get device dma ring information.
* Usage: Issue "ethtool -g ethX" under linux prompt
* @ndev: network device
* @erp: ethtool ring parameter structure
*/
static
void
xemacps_get_ringparam
(
struct
net_device
*
ndev
,
struct
ethtool_ringparam
*
erp
)
{
memset
(
erp
,
0
,
sizeof
(
struct
ethtool_ringparam
));
erp
->
rx_max_pending
=
XEMACPS_RECV_BD_CNT
;
erp
->
tx_max_pending
=
XEMACPS_SEND_BD_CNT
;
erp
->
rx_pending
=
0
;
erp
->
tx_pending
=
0
;
}
/**
* xemacps_get_wol - get device wake on lan status
* Usage: Issue "ethtool ethX" under linux prompt
* @ndev: network device
* @ewol: wol status
*/
static
void
xemacps_get_wol
(
struct
net_device
*
ndev
,
struct
ethtool_wolinfo
*
ewol
)
{
struct
net_local
*
lp
=
netdev_priv
(
ndev
);
u32
regval
;
ewol
->
supported
=
WAKE_MAGIC
|
WAKE_ARP
|
WAKE_UCAST
|
WAKE_MCAST
;
regval
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_WOL_OFFSET
);
if
(
regval
&
XEMACPS_WOL_MCAST_MASK
)
ewol
->
wolopts
|=
WAKE_MCAST
;
if
(
regval
&
XEMACPS_WOL_ARP_MASK
)
ewol
->
wolopts
|=
WAKE_ARP
;
if
(
regval
&
XEMACPS_WOL_SPEREG1_MASK
)
ewol
->
wolopts
|=
WAKE_UCAST
;
if
(
regval
&
XEMACPS_WOL_MAGIC_MASK
)
ewol
->
wolopts
|=
WAKE_MAGIC
;
}
/**
* xemacps_set_wol - set device wake on lan configuration
* Usage: Issue "ethtool -s ethX wol u|m|b|g" under linux prompt to enable
* specified type of packet.
* Issue "ethtool -s ethX wol d" under linux prompt to disable this feature.
* @ndev: network device
* @ewol: wol status
* Return: 0 on success, negative value if not supported
*/
static
int
xemacps_set_wol
(
struct
net_device
*
ndev
,
struct
ethtool_wolinfo
*
ewol
)
{
struct
net_local
*
lp
=
netdev_priv
(
ndev
);
u32
regval
;
if
(
ewol
->
wolopts
&
~
(
WAKE_MAGIC
|
WAKE_ARP
|
WAKE_UCAST
|
WAKE_MCAST
))
return
-
EOPNOTSUPP
;
regval
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_WOL_OFFSET
);
regval
&=
~
(
XEMACPS_WOL_MCAST_MASK
|
XEMACPS_WOL_ARP_MASK
|
XEMACPS_WOL_SPEREG1_MASK
|
XEMACPS_WOL_MAGIC_MASK
);
if
(
ewol
->
wolopts
&
WAKE_MAGIC
)
regval
|=
XEMACPS_WOL_MAGIC_MASK
;
if
(
ewol
->
wolopts
&
WAKE_ARP
)
regval
|=
XEMACPS_WOL_ARP_MASK
;
if
(
ewol
->
wolopts
&
WAKE_UCAST
)
regval
|=
XEMACPS_WOL_SPEREG1_MASK
;
if
(
ewol
->
wolopts
&
WAKE_MCAST
)
regval
|=
XEMACPS_WOL_MCAST_MASK
;
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_WOL_OFFSET
,
regval
);
return
0
;
}
/**
* xemacps_get_pauseparam - get device pause status
* Usage: Issue "ethtool -a ethX" under linux prompt
* @ndev: network device
* @epauseparm: pause parameter
*
* note: hardware supports only tx flow control
*/
static
void
xemacps_get_pauseparam
(
struct
net_device
*
ndev
,
struct
ethtool_pauseparam
*
epauseparm
)
{
struct
net_local
*
lp
=
netdev_priv
(
ndev
);
u32
regval
;
epauseparm
->
autoneg
=
0
;
epauseparm
->
rx_pause
=
0
;
regval
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_NWCFG_OFFSET
);
epauseparm
->
tx_pause
=
regval
&
XEMACPS_NWCFG_PAUSEEN_MASK
;
}
/**
* xemacps_set_pauseparam - set device pause parameter(flow control)
* Usage: Issue "ethtool -A ethX tx on|off" under linux prompt
* @ndev: network device
* @epauseparm: pause parameter
* Return: 0 on success, negative value if not supported
*
* note: hardware supports only tx flow control
*/
static
int
xemacps_set_pauseparam
(
struct
net_device
*
ndev
,
struct
ethtool_pauseparam
*
epauseparm
)
{
struct
net_local
*
lp
=
netdev_priv
(
ndev
);
u32
regval
;
if
(
netif_running
(
ndev
))
{
dev_err
(
&
lp
->
pdev
->
dev
,
"Please stop netif before apply configruation
\n
"
);
return
-
EFAULT
;
}
regval
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_NWCFG_OFFSET
);
if
(
epauseparm
->
tx_pause
)
regval
|=
XEMACPS_NWCFG_PAUSEEN_MASK
;
if
(
!
(
epauseparm
->
tx_pause
))
regval
&=
~
XEMACPS_NWCFG_PAUSEEN_MASK
;
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_NWCFG_OFFSET
,
regval
);
return
0
;
}
/**
* xemacps_get_stats - get device statistic raw data in 64bit mode
* @ndev: network device
* Return: Pointer to network device statistic
*/
static
struct
net_device_stats
*
xemacps_get_stats
(
struct
net_device
*
ndev
)
{
struct
net_local
*
lp
=
netdev_priv
(
ndev
);
struct
net_device_stats
*
nstat
=
&
lp
->
stats
;
xemacps_update_stats
((
unsigned
long
)
lp
);
return
nstat
;
}
#ifdef CONFIG_XILINX_PS_EMAC_HWTSTAMP
/**
* xemacps_get_ts_info - Get the interface timestamp capabilities
* @dev: Network device
* @info: Holds the interface timestamp capability info
* Return: Always return zero
*/
static
int
xemacps_get_ts_info
(
struct
net_device
*
dev
,
struct
ethtool_ts_info
*
info
)
{
struct
net_local
*
lp
=
netdev_priv
(
dev
);
info
->
so_timestamping
=
SOF_TIMESTAMPING_TX_HARDWARE
|
SOF_TIMESTAMPING_RX_HARDWARE
|
SOF_TIMESTAMPING_RAW_HARDWARE
;
info
->
phc_index
=
lp
->
phc_index
;
info
->
tx_types
=
(
1
<<
HWTSTAMP_TX_OFF
)
|
(
1
<<
HWTSTAMP_TX_ON
);
info
->
rx_filters
=
(
1
<<
HWTSTAMP_FILTER_NONE
)
|
(
1
<<
HWTSTAMP_FILTER_ALL
);
return
0
;
}
#endif
static
struct
ethtool_ops
xemacps_ethtool_ops
=
{
.
get_settings
=
xemacps_get_settings
,
.
set_settings
=
xemacps_set_settings
,
.
get_drvinfo
=
xemacps_get_drvinfo
,
.
get_link
=
ethtool_op_get_link
,
/* ethtool default */
.
get_ringparam
=
xemacps_get_ringparam
,
.
get_wol
=
xemacps_get_wol
,
.
set_wol
=
xemacps_set_wol
,
.
get_pauseparam
=
xemacps_get_pauseparam
,
.
set_pauseparam
=
xemacps_set_pauseparam
,
#ifdef CONFIG_XILINX_PS_EMAC_HWTSTAMP
.
get_ts_info
=
xemacps_get_ts_info
,
#endif
};
#ifdef CONFIG_XILINX_PS_EMAC_HWTSTAMP
static
int
xemacps_hwtstamp_ioctl
(
struct
net_device
*
netdev
,
struct
ifreq
*
ifr
,
int
cmd
)
{
struct
hwtstamp_config
config
;
struct
net_local
*
lp
;
u32
regval
;
lp
=
netdev_priv
(
netdev
);
if
(
copy_from_user
(
&
config
,
ifr
->
ifr_data
,
sizeof
(
config
)))
return
-
EFAULT
;
/* reserved for future extensions */
if
(
config
.
flags
)
return
-
EINVAL
;
if
((
config
.
tx_type
!=
HWTSTAMP_TX_OFF
)
&&
(
config
.
tx_type
!=
HWTSTAMP_TX_ON
))
return
-
ERANGE
;
switch
(
config
.
rx_filter
)
{
case
HWTSTAMP_FILTER_NONE
:
break
;
case
HWTSTAMP_FILTER_PTP_V1_L4_EVENT
:
case
HWTSTAMP_FILTER_PTP_V2_L4_EVENT
:
case
HWTSTAMP_FILTER_PTP_V2_L2_EVENT
:
case
HWTSTAMP_FILTER_ALL
:
case
HWTSTAMP_FILTER_PTP_V1_L4_SYNC
:
case
HWTSTAMP_FILTER_PTP_V1_L4_DELAY_REQ
:
case
HWTSTAMP_FILTER_PTP_V2_L2_SYNC
:
case
HWTSTAMP_FILTER_PTP_V2_L4_SYNC
:
case
HWTSTAMP_FILTER_PTP_V2_L2_DELAY_REQ
:
case
HWTSTAMP_FILTER_PTP_V2_L4_DELAY_REQ
:
case
HWTSTAMP_FILTER_PTP_V2_EVENT
:
case
HWTSTAMP_FILTER_PTP_V2_SYNC
:
case
HWTSTAMP_FILTER_PTP_V2_DELAY_REQ
:
config
.
rx_filter
=
HWTSTAMP_FILTER_ALL
;
regval
=
xemacps_read
(
lp
->
baseaddr
,
XEMACPS_NWCTRL_OFFSET
);
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_NWCTRL_OFFSET
,
(
regval
|
XEMACPS_NWCTRL_RXTSTAMP_MASK
));
break
;
default:
return
-
ERANGE
;
}
config
.
tx_type
=
HWTSTAMP_TX_ON
;
lp
->
hwtstamp_config
=
config
;
return
copy_to_user
(
ifr
->
ifr_data
,
&
config
,
sizeof
(
config
))
?
-
EFAULT
:
0
;
}
#endif
/* CONFIG_XILINX_PS_EMAC_HWTSTAMP */
/**
* xemacps_ioctl - ioctl entry point
* @ndev: network device
* @rq: interface request ioctl
* @cmd: command code
*
* Called when user issues an ioctl request to the network device.
*
* Return: 0 on success, negative value if error
*/
static
int
xemacps_ioctl
(
struct
net_device
*
ndev
,
struct
ifreq
*
rq
,
int
cmd
)
{
struct
net_local
*
lp
=
netdev_priv
(
ndev
);
struct
phy_device
*
phydev
=
lp
->
phy_dev
;
if
(
!
netif_running
(
ndev
))
return
-
EINVAL
;
if
(
!
phydev
)
return
-
ENODEV
;
switch
(
cmd
)
{
case
SIOCGMIIPHY
:
case
SIOCGMIIREG
:
case
SIOCSMIIREG
:
return
phy_mii_ioctl
(
phydev
,
rq
,
cmd
);
#ifdef CONFIG_XILINX_PS_EMAC_HWTSTAMP
case
SIOCSHWTSTAMP
:
return
xemacps_hwtstamp_ioctl
(
ndev
,
rq
,
cmd
);
#endif
default:
dev_info
(
&
lp
->
pdev
->
dev
,
"ioctl %d not implemented.
\n
"
,
cmd
);
return
-
EOPNOTSUPP
;
}
}
/**
* xemacps_probe - Platform driver probe
* @pdev: Pointer to platform device structure
*
* Return: 0 on success, negative value if error
*/
static
int
xemacps_probe
(
struct
platform_device
*
pdev
)
{
struct
resource
*
r_mem
=
NULL
;
struct
resource
*
r_irq
=
NULL
;
struct
net_device
*
ndev
;
struct
net_local
*
lp
;
u32
regval
=
0
;
int
rc
=
-
ENXIO
;
const
u8
*
mac_address
;
r_mem
=
platform_get_resource
(
pdev
,
IORESOURCE_MEM
,
0
);
r_irq
=
platform_get_resource
(
pdev
,
IORESOURCE_IRQ
,
0
);
if
(
!
r_mem
||
!
r_irq
)
{
dev_err
(
&
pdev
->
dev
,
"no IO resource defined.
\n
"
);
return
-
ENXIO
;
}
ndev
=
alloc_etherdev
(
sizeof
(
*
lp
));
if
(
!
ndev
)
{
dev_err
(
&
pdev
->
dev
,
"etherdev allocation failed.
\n
"
);
return
-
ENOMEM
;
}
SET_NETDEV_DEV
(
ndev
,
&
pdev
->
dev
);
lp
=
netdev_priv
(
ndev
);
lp
->
pdev
=
pdev
;
lp
->
ndev
=
ndev
;
spin_lock_init
(
&
lp
->
tx_lock
);
spin_lock_init
(
&
lp
->
rx_lock
);
spin_lock_init
(
&
lp
->
nwctrlreg_lock
);
spin_lock_init
(
&
lp
->
mdio_lock
);
lp
->
baseaddr
=
devm_ioremap_resource
(
&
pdev
->
dev
,
r_mem
);
if
(
IS_ERR
(
lp
->
baseaddr
))
{
rc
=
PTR_ERR
(
lp
->
baseaddr
);
goto
err_out_free_netdev
;
}
dev_dbg
(
&
lp
->
pdev
->
dev
,
"BASEADDRESS hw: %p virt: %p
\n
"
,
(
void
*
)
r_mem
->
start
,
lp
->
baseaddr
);
ndev
->
irq
=
platform_get_irq
(
pdev
,
0
);
ndev
->
netdev_ops
=
&
netdev_ops
;
ndev
->
watchdog_timeo
=
TX_TIMEOUT
;
ndev
->
ethtool_ops
=
&
xemacps_ethtool_ops
;
ndev
->
base_addr
=
r_mem
->
start
;
ndev
->
features
=
NETIF_F_IP_CSUM
|
NETIF_F_SG
;
netif_napi_add
(
ndev
,
&
lp
->
napi
,
xemacps_rx_poll
,
XEMACPS_NAPI_WEIGHT
);
lp
->
ip_summed
=
CHECKSUM_UNNECESSARY
;
rc
=
register_netdev
(
ndev
);
if
(
rc
)
{
dev_err
(
&
pdev
->
dev
,
"Cannot register net device, aborting.
\n
"
);
goto
err_out_free_netdev
;
}
if
(
ndev
->
irq
==
54
)
lp
->
enetnum
=
0
;
else
lp
->
enetnum
=
1
;
lp
->
aperclk
=
devm_clk_get
(
&
pdev
->
dev
,
"aper_clk"
);
if
(
IS_ERR
(
lp
->
aperclk
))
{
dev_err
(
&
pdev
->
dev
,
"aper_clk clock not found.
\n
"
);
rc
=
PTR_ERR
(
lp
->
aperclk
);
goto
err_out_unregister_netdev
;
}
lp
->
devclk
=
devm_clk_get
(
&
pdev
->
dev
,
"ref_clk"
);
if
(
IS_ERR
(
lp
->
devclk
))
{
dev_err
(
&
pdev
->
dev
,
"ref_clk clock not found.
\n
"
);
rc
=
PTR_ERR
(
lp
->
devclk
);
goto
err_out_unregister_netdev
;
}
rc
=
clk_prepare_enable
(
lp
->
aperclk
);
if
(
rc
)
{
dev_err
(
&
pdev
->
dev
,
"Unable to enable APER clock.
\n
"
);
goto
err_out_unregister_netdev
;
}
rc
=
clk_prepare_enable
(
lp
->
devclk
);
if
(
rc
)
{
dev_err
(
&
pdev
->
dev
,
"Unable to enable device clock.
\n
"
);
goto
err_out_clk_dis_aper
;
}
rc
=
of_property_read_u32
(
lp
->
pdev
->
dev
.
of_node
,
"xlnx,has-mdio"
,
&
lp
->
has_mdio
);
lp
->
phy_node
=
of_parse_phandle
(
lp
->
pdev
->
dev
.
of_node
,
"phy-handle"
,
0
);
lp
->
gmii2rgmii_phy_node
=
of_parse_phandle
(
lp
->
pdev
->
dev
.
of_node
,
"gmii2rgmii-phy-handle"
,
0
);
rc
=
of_get_phy_mode
(
lp
->
pdev
->
dev
.
of_node
);
if
(
rc
<
0
)
{
dev_err
(
&
lp
->
pdev
->
dev
,
"error in getting phy i/f
\n
"
);
goto
err_out_clk_dis_all
;
}
lp
->
phy_interface
=
rc
;
/* Set MDIO clock divider */
regval
=
(
MDC_DIV_224
<<
XEMACPS_NWCFG_MDC_SHIFT_MASK
);
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_NWCFG_OFFSET
,
regval
);
regval
=
XEMACPS_NWCTRL_MDEN_MASK
;
xemacps_write
(
lp
->
baseaddr
,
XEMACPS_NWCTRL_OFFSET
,
regval
);
rc
=
xemacps_mii_init
(
lp
);
if
(
rc
)
{
dev_err
(
&
lp
->
pdev
->
dev
,
"error in xemacps_mii_init
\n
"
);
goto
err_out_clk_dis_all
;
}
mac_address
=
of_get_mac_address
(
lp
->
pdev
->
dev
.
of_node
);
if
(
mac_address
)
{
ether_addr_copy
(
lp
->
ndev
->
dev_addr
,
mac_address
);
xemacps_set_hwaddr
(
lp
);
}
else
{
xemacps_update_hwaddr
(
lp
);
}
tasklet_init
(
&
lp
->
tx_bdreclaim_tasklet
,
xemacps_tx_poll
,
(
unsigned
long
)
ndev
);
tasklet_disable
(
&
lp
->
tx_bdreclaim_tasklet
);
lp
->
txtimeout_handler_wq
=
create_singlethread_workqueue
(
DRIVER_NAME
);
INIT_WORK
(
&
lp
->
txtimeout_reinit
,
xemacps_reinit_for_txtimeout
);
platform_set_drvdata
(
pdev
,
ndev
);
pm_runtime_set_active
(
&
pdev
->
dev
);
pm_runtime_enable
(
&
pdev
->
dev
);
dev_info
(
&
lp
->
pdev
->
dev
,
"pdev->id %d, baseaddr 0x%08lx, irq %d
\n
"
,
pdev
->
id
,
ndev
->
base_addr
,
ndev
->
irq
);
rc
=
devm_request_irq
(
&
pdev
->
dev
,
ndev
->
irq
,
&
xemacps_interrupt
,
0
,
ndev
->
name
,
ndev
);
if
(
rc
)
{
dev_err
(
&
lp
->
pdev
->
dev
,
"Unable to request IRQ %p, error %d
\n
"
,
r_irq
,
rc
);
goto
err_out_clk_dis_all
;
}
return
0
;
err_out_clk_dis_all:
clk_disable_unprepare
(
lp
->
devclk
);
err_out_clk_dis_aper:
clk_disable_unprepare
(
lp
->
aperclk
);
err_out_unregister_netdev:
unregister_netdev
(
ndev
);
err_out_free_netdev:
free_netdev
(
ndev
);
return
rc
;
}
/**
* xemacps_remove - called when platform driver is unregistered
* @pdev: Pointer to the platform device structure
*
* Return: 0 on success
*/
static
int
xemacps_remove
(
struct
platform_device
*
pdev
)
{
struct
net_device
*
ndev
=
platform_get_drvdata
(
pdev
);
struct
net_local
*
lp
;
if
(
ndev
)
{
lp
=
netdev_priv
(
ndev
);
if
(
lp
->
has_mdio
)
{
mdiobus_unregister
(
lp
->
mii_bus
);
kfree
(
lp
->
mii_bus
->
irq
);
mdiobus_free
(
lp
->
mii_bus
);
}
unregister_netdev
(
ndev
);
if
(
!
pm_runtime_suspended
(
&
pdev
->
dev
))
{
clk_disable_unprepare
(
lp
->
devclk
);
clk_disable_unprepare
(
lp
->
aperclk
);
}
else
{
clk_unprepare
(
lp
->
devclk
);
clk_unprepare
(
lp
->
aperclk
);
}
free_netdev
(
ndev
);
}
return
0
;
}
#ifdef CONFIG_PM
/**
* xemacps_suspend - Suspend event
* @device: Pointer to device structure
*
* Return: 0
*/
static
int
__maybe_unused
xemacps_suspend
(
struct
device
*
device
)
{
struct
platform_device
*
pdev
=
container_of
(
device
,
struct
platform_device
,
dev
);
struct
net_device
*
ndev
=
platform_get_drvdata
(
pdev
);
struct
net_local
*
lp
=
netdev_priv
(
ndev
);
netif_device_detach
(
ndev
);
if
(
!
pm_runtime_suspended
(
device
))
{
clk_disable
(
lp
->
devclk
);
clk_disable
(
lp
->
aperclk
);
}
return
0
;
}
/**
* xemacps_resume - Resume after previous suspend
* @device: Pointer to device structure
*
* Return: 0 on success, errno otherwise.
*/
static
int
__maybe_unused
xemacps_resume
(
struct
device
*
device
)
{
struct
platform_device
*
pdev
=
container_of
(
device
,
struct
platform_device
,
dev
);
struct
net_device
*
ndev
=
platform_get_drvdata
(
pdev
);
struct
net_local
*
lp
=
netdev_priv
(
ndev
);
if
(
!
pm_runtime_suspended
(
device
))
{
int
ret
;
ret
=
clk_enable
(
lp
->
aperclk
);
if
(
ret
)
return
ret
;
ret
=
clk_enable
(
lp
->
devclk
);
if
(
ret
)
{
clk_disable
(
lp
->
aperclk
);
return
ret
;
}
}
netif_device_attach
(
ndev
);
return
0
;
}
static
int
__maybe_unused
xemacps_runtime_idle
(
struct
device
*
dev
)
{
return
pm_schedule_suspend
(
dev
,
1
);
}
static
int
__maybe_unused
xemacps_runtime_resume
(
struct
device
*
device
)
{
int
ret
;
struct
platform_device
*
pdev
=
container_of
(
device
,
struct
platform_device
,
dev
);
struct
net_device
*
ndev
=
platform_get_drvdata
(
pdev
);
struct
net_local
*
lp
=
netdev_priv
(
ndev
);
ret
=
clk_enable
(
lp
->
aperclk
);
if
(
ret
)
return
ret
;
ret
=
clk_enable
(
lp
->
devclk
);
if
(
ret
)
{
clk_disable
(
lp
->
aperclk
);
return
ret
;
}
return
0
;
}
static
int
__maybe_unused
xemacps_runtime_suspend
(
struct
device
*
device
)
{
struct
platform_device
*
pdev
=
container_of
(
device
,
struct
platform_device
,
dev
);
struct
net_device
*
ndev
=
platform_get_drvdata
(
pdev
);
struct
net_local
*
lp
=
netdev_priv
(
ndev
);
clk_disable
(
lp
->
devclk
);
clk_disable
(
lp
->
aperclk
);
return
0
;
}
static
const
struct
dev_pm_ops
xemacps_dev_pm_ops
=
{
SET_SYSTEM_SLEEP_PM_OPS
(
xemacps_suspend
,
xemacps_resume
)
SET_RUNTIME_PM_OPS
(
xemacps_runtime_suspend
,
xemacps_runtime_resume
,
xemacps_runtime_idle
)
};
#define XEMACPS_PM (&xemacps_dev_pm_ops)
#else
/* ! CONFIG_PM */
#define XEMACPS_PM NULL
#endif
/* ! CONFIG_PM */
static
struct
net_device_ops
netdev_ops
=
{
.
ndo_open
=
xemacps_open
,
.
ndo_stop
=
xemacps_close
,
.
ndo_start_xmit
=
xemacps_start_xmit
,
.
ndo_set_rx_mode
=
xemacps_set_rx_mode
,
.
ndo_set_mac_address
=
eth_mac_addr
,
.
ndo_do_ioctl
=
xemacps_ioctl
,
.
ndo_change_mtu
=
eth_change_mtu
,
.
ndo_tx_timeout
=
xemacps_tx_timeout
,
.
ndo_get_stats
=
xemacps_get_stats
,
};
static
struct
of_device_id
xemacps_of_match
[]
=
{
{
.
compatible
=
"xlnx,ps7-ethernet-1.00.a"
,
},
{
/* end of table */
}
};
MODULE_DEVICE_TABLE
(
of
,
xemacps_of_match
);
static
struct
platform_driver
xemacps_driver
=
{
.
probe
=
xemacps_probe
,
.
remove
=
xemacps_remove
,
.
driver
=
{
.
name
=
DRIVER_NAME
,
.
of_match_table
=
xemacps_of_match
,
.
pm
=
XEMACPS_PM
,
},
};
module_platform_driver
(
xemacps_driver
);
MODULE_AUTHOR
(
"Xilinx, Inc."
);
MODULE_DESCRIPTION
(
"Xilinx Ethernet driver"
);
MODULE_LICENSE
(
"GPL v2"
);
src/patches/xilinx_emacps.c.patch
→
src/patches/xilinx_emacps.c.patch
_noneed
View file @
25f54b0e
...
@@ -23,7 +23,7 @@ index a4289f9..c28e6da 100644
...
@@ -23,7 +23,7 @@ index a4289f9..c28e6da 100644
+ u16 val;
+ u16 val;
+ // Elphel: phy_device has changed
+ // Elphel: phy_device has changed
+ //struct net_local *lp = dev->bus->priv;
+ //struct net_local *lp = dev->bus->priv;
+ struct net_local *lp = dev->
&mdio
->bus->priv;
+ struct net_local *lp = dev->
(&mdio)
->bus->priv;
+ dev_dbg(&lp->pdev->dev,"fixup start");
+ dev_dbg(&lp->pdev->dev,"fixup start");
+
+
+ /* Ar803x phy SmartEEE feature cause link status generates glitch,
+ /* Ar803x phy SmartEEE feature cause link status generates glitch,
...
...
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