Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Linus Walleij | 4641 | 94.68% | 1 | 11.11% |
Pawel Dembicki | 151 | 3.08% | 2 | 22.22% |
Vladimir Oltean | 68 | 1.39% | 1 | 11.11% |
Vivien Didelot | 26 | 0.53% | 1 | 11.11% |
Florian Fainelli | 12 | 0.24% | 2 | 22.22% |
Wei Yongjun | 3 | 0.06% | 1 | 11.11% |
Colin Ian King | 1 | 0.02% | 1 | 11.11% |
Total | 4902 | 9 |
// SPDX-License-Identifier: GPL-2.0 /* DSA driver for: * Vitesse VSC7385 SparX-G5 5+1-port Integrated Gigabit Ethernet Switch * Vitesse VSC7388 SparX-G8 8-port Integrated Gigabit Ethernet Switch * Vitesse VSC7395 SparX-G5e 5+1-port Integrated Gigabit Ethernet Switch * Vitesse VSC7398 SparX-G8e 8-port Integrated Gigabit Ethernet Switch * * These switches have a built-in 8051 CPU and can download and execute a * firmware in this CPU. They can also be configured to use an external CPU * handling the switch in a memory-mapped manner by connecting to that external * CPU's memory bus. * * Copyright (C) 2018 Linus Wallej <linus.walleij@linaro.org> * Includes portions of code from the firmware uploader by: * Copyright (C) 2009 Gabor Juhos <juhosg@openwrt.org> */ #include <linux/kernel.h> #include <linux/module.h> #include <linux/device.h> #include <linux/of.h> #include <linux/of_device.h> #include <linux/of_mdio.h> #include <linux/bitops.h> #include <linux/if_bridge.h> #include <linux/etherdevice.h> #include <linux/gpio/consumer.h> #include <linux/gpio/driver.h> #include <linux/random.h> #include <net/dsa.h> #include "vitesse-vsc73xx.h" #define VSC73XX_BLOCK_MAC 0x1 /* Subblocks 0-4, 6 (CPU port) */ #define VSC73XX_BLOCK_ANALYZER 0x2 /* Only subblock 0 */ #define VSC73XX_BLOCK_MII 0x3 /* Subblocks 0 and 1 */ #define VSC73XX_BLOCK_MEMINIT 0x3 /* Only subblock 2 */ #define VSC73XX_BLOCK_CAPTURE 0x4 /* Only subblock 2 */ #define VSC73XX_BLOCK_ARBITER 0x5 /* Only subblock 0 */ #define VSC73XX_BLOCK_SYSTEM 0x7 /* Only subblock 0 */ #define CPU_PORT 6 /* CPU port */ /* MAC Block registers */ #define VSC73XX_MAC_CFG 0x00 #define VSC73XX_MACHDXGAP 0x02 #define VSC73XX_FCCONF 0x04 #define VSC73XX_FCMACHI 0x08 #define VSC73XX_FCMACLO 0x0c #define VSC73XX_MAXLEN 0x10 #define VSC73XX_ADVPORTM 0x19 #define VSC73XX_TXUPDCFG 0x24 #define VSC73XX_TXQ_SELECT_CFG 0x28 #define VSC73XX_RXOCT 0x50 #define VSC73XX_TXOCT 0x51 #define VSC73XX_C_RX0 0x52 #define VSC73XX_C_RX1 0x53 #define VSC73XX_C_RX2 0x54 #define VSC73XX_C_TX0 0x55 #define VSC73XX_C_TX1 0x56 #define VSC73XX_C_TX2 0x57 #define VSC73XX_C_CFG 0x58 #define VSC73XX_CAT_DROP 0x6e #define VSC73XX_CAT_PR_MISC_L2 0x6f #define VSC73XX_CAT_PR_USR_PRIO 0x75 #define VSC73XX_Q_MISC_CONF 0xdf /* MAC_CFG register bits */ #define VSC73XX_MAC_CFG_WEXC_DIS BIT(31) #define VSC73XX_MAC_CFG_PORT_RST BIT(29) #define VSC73XX_MAC_CFG_TX_EN BIT(28) #define VSC73XX_MAC_CFG_SEED_LOAD BIT(27) #define VSC73XX_MAC_CFG_SEED_MASK GENMASK(26, 19) #define VSC73XX_MAC_CFG_SEED_OFFSET 19 #define VSC73XX_MAC_CFG_FDX BIT(18) #define VSC73XX_MAC_CFG_GIGA_MODE BIT(17) #define VSC73XX_MAC_CFG_RX_EN BIT(16) #define VSC73XX_MAC_CFG_VLAN_DBLAWR BIT(15) #define VSC73XX_MAC_CFG_VLAN_AWR BIT(14) #define VSC73XX_MAC_CFG_100_BASE_T BIT(13) /* Not in manual */ #define VSC73XX_MAC_CFG_TX_IPG_MASK GENMASK(10, 6) #define VSC73XX_MAC_CFG_TX_IPG_OFFSET 6 #define VSC73XX_MAC_CFG_TX_IPG_1000M (6 << VSC73XX_MAC_CFG_TX_IPG_OFFSET) #define VSC73XX_MAC_CFG_TX_IPG_100_10M (17 << VSC73XX_MAC_CFG_TX_IPG_OFFSET) #define VSC73XX_MAC_CFG_MAC_RX_RST BIT(5) #define VSC73XX_MAC_CFG_MAC_TX_RST BIT(4) #define VSC73XX_MAC_CFG_CLK_SEL_MASK GENMASK(2, 0) #define VSC73XX_MAC_CFG_CLK_SEL_OFFSET 0 #define VSC73XX_MAC_CFG_CLK_SEL_1000M 1 #define VSC73XX_MAC_CFG_CLK_SEL_100M 2 #define VSC73XX_MAC_CFG_CLK_SEL_10M 3 #define VSC73XX_MAC_CFG_CLK_SEL_EXT 4 #define VSC73XX_MAC_CFG_1000M_F_PHY (VSC73XX_MAC_CFG_FDX | \ VSC73XX_MAC_CFG_GIGA_MODE | \ VSC73XX_MAC_CFG_TX_IPG_1000M | \ VSC73XX_MAC_CFG_CLK_SEL_EXT) #define VSC73XX_MAC_CFG_100_10M_F_PHY (VSC73XX_MAC_CFG_FDX | \ VSC73XX_MAC_CFG_TX_IPG_100_10M | \ VSC73XX_MAC_CFG_CLK_SEL_EXT) #define VSC73XX_MAC_CFG_100_10M_H_PHY (VSC73XX_MAC_CFG_TX_IPG_100_10M | \ VSC73XX_MAC_CFG_CLK_SEL_EXT) #define VSC73XX_MAC_CFG_1000M_F_RGMII (VSC73XX_MAC_CFG_FDX | \ VSC73XX_MAC_CFG_GIGA_MODE | \ VSC73XX_MAC_CFG_TX_IPG_1000M | \ VSC73XX_MAC_CFG_CLK_SEL_1000M) #define VSC73XX_MAC_CFG_RESET (VSC73XX_MAC_CFG_PORT_RST | \ VSC73XX_MAC_CFG_MAC_RX_RST | \ VSC73XX_MAC_CFG_MAC_TX_RST) /* Flow control register bits */ #define VSC73XX_FCCONF_ZERO_PAUSE_EN BIT(17) #define VSC73XX_FCCONF_FLOW_CTRL_OBEY BIT(16) #define VSC73XX_FCCONF_PAUSE_VAL_MASK GENMASK(15, 0) /* ADVPORTM advanced port setup register bits */ #define VSC73XX_ADVPORTM_IFG_PPM BIT(7) #define VSC73XX_ADVPORTM_EXC_COL_CONT BIT(6) #define VSC73XX_ADVPORTM_EXT_PORT BIT(5) #define VSC73XX_ADVPORTM_INV_GTX BIT(4) #define VSC73XX_ADVPORTM_ENA_GTX BIT(3) #define VSC73XX_ADVPORTM_DDR_MODE BIT(2) #define VSC73XX_ADVPORTM_IO_LOOPBACK BIT(1) #define VSC73XX_ADVPORTM_HOST_LOOPBACK BIT(0) /* CAT_DROP categorizer frame dropping register bits */ #define VSC73XX_CAT_DROP_DROP_MC_SMAC_ENA BIT(6) #define VSC73XX_CAT_DROP_FWD_CTRL_ENA BIT(4) #define VSC73XX_CAT_DROP_FWD_PAUSE_ENA BIT(3) #define VSC73XX_CAT_DROP_UNTAGGED_ENA BIT(2) #define VSC73XX_CAT_DROP_TAGGED_ENA BIT(1) #define VSC73XX_CAT_DROP_NULL_MAC_ENA BIT(0) #define VSC73XX_Q_MISC_CONF_EXTENT_MEM BIT(31) #define VSC73XX_Q_MISC_CONF_EARLY_TX_MASK GENMASK(4, 1) #define VSC73XX_Q_MISC_CONF_EARLY_TX_512 (1 << 1) #define VSC73XX_Q_MISC_CONF_MAC_PAUSE_MODE BIT(0) /* Frame analyzer block 2 registers */ #define VSC73XX_STORMLIMIT 0x02 #define VSC73XX_ADVLEARN 0x03 #define VSC73XX_IFLODMSK 0x04 #define VSC73XX_VLANMASK 0x05 #define VSC73XX_MACHDATA 0x06 #define VSC73XX_MACLDATA 0x07 #define VSC73XX_ANMOVED 0x08 #define VSC73XX_ANAGEFIL 0x09 #define VSC73XX_ANEVENTS 0x0a #define VSC73XX_ANCNTMASK 0x0b #define VSC73XX_ANCNTVAL 0x0c #define VSC73XX_LEARNMASK 0x0d #define VSC73XX_UFLODMASK 0x0e #define VSC73XX_MFLODMASK 0x0f #define VSC73XX_RECVMASK 0x10 #define VSC73XX_AGGRCTRL 0x20 #define VSC73XX_AGGRMSKS 0x30 /* Until 0x3f */ #define VSC73XX_DSTMASKS 0x40 /* Until 0x7f */ #define VSC73XX_SRCMASKS 0x80 /* Until 0x87 */ #define VSC73XX_CAPENAB 0xa0 #define VSC73XX_MACACCESS 0xb0 #define VSC73XX_IPMCACCESS 0xb1 #define VSC73XX_MACTINDX 0xc0 #define VSC73XX_VLANACCESS 0xd0 #define VSC73XX_VLANTIDX 0xe0 #define VSC73XX_AGENCTRL 0xf0 #define VSC73XX_CAPRST 0xff #define VSC73XX_MACACCESS_CPU_COPY BIT(14) #define VSC73XX_MACACCESS_FWD_KILL BIT(13) #define VSC73XX_MACACCESS_IGNORE_VLAN BIT(12) #define VSC73XX_MACACCESS_AGED_FLAG BIT(11) #define VSC73XX_MACACCESS_VALID BIT(10) #define VSC73XX_MACACCESS_LOCKED BIT(9) #define VSC73XX_MACACCESS_DEST_IDX_MASK GENMASK(8, 3) #define VSC73XX_MACACCESS_CMD_MASK GENMASK(2, 0) #define VSC73XX_MACACCESS_CMD_IDLE 0 #define VSC73XX_MACACCESS_CMD_LEARN 1 #define VSC73XX_MACACCESS_CMD_FORGET 2 #define VSC73XX_MACACCESS_CMD_AGE_TABLE 3 #define VSC73XX_MACACCESS_CMD_FLUSH_TABLE 4 #define VSC73XX_MACACCESS_CMD_CLEAR_TABLE 5 #define VSC73XX_MACACCESS_CMD_READ_ENTRY 6 #define VSC73XX_MACACCESS_CMD_WRITE_ENTRY 7 #define VSC73XX_VLANACCESS_LEARN_DISABLED BIT(30) #define VSC73XX_VLANACCESS_VLAN_MIRROR BIT(29) #define VSC73XX_VLANACCESS_VLAN_SRC_CHECK BIT(28) #define VSC73XX_VLANACCESS_VLAN_PORT_MASK GENMASK(9, 2) #define VSC73XX_VLANACCESS_VLAN_TBL_CMD_MASK GENMASK(2, 0) #define VSC73XX_VLANACCESS_VLAN_TBL_CMD_IDLE 0 #define VSC73XX_VLANACCESS_VLAN_TBL_CMD_READ_ENTRY 1 #define VSC73XX_VLANACCESS_VLAN_TBL_CMD_WRITE_ENTRY 2 #define VSC73XX_VLANACCESS_VLAN_TBL_CMD_CLEAR_TABLE 3 /* MII block 3 registers */ #define VSC73XX_MII_STAT 0x0 #define VSC73XX_MII_CMD 0x1 #define VSC73XX_MII_DATA 0x2 /* Arbiter block 5 registers */ #define VSC73XX_ARBEMPTY 0x0c #define VSC73XX_ARBDISC 0x0e #define VSC73XX_SBACKWDROP 0x12 #define VSC73XX_DBACKWDROP 0x13 #define VSC73XX_ARBBURSTPROB 0x15 /* System block 7 registers */ #define VSC73XX_ICPU_SIPAD 0x01 #define VSC73XX_GMIIDELAY 0x05 #define VSC73XX_ICPU_CTRL 0x10 #define VSC73XX_ICPU_ADDR 0x11 #define VSC73XX_ICPU_SRAM 0x12 #define VSC73XX_HWSEM 0x13 #define VSC73XX_GLORESET 0x14 #define VSC73XX_ICPU_MBOX_VAL 0x15 #define VSC73XX_ICPU_MBOX_SET 0x16 #define VSC73XX_ICPU_MBOX_CLR 0x17 #define VSC73XX_CHIPID 0x18 #define VSC73XX_GPIO 0x34 #define VSC73XX_GMIIDELAY_GMII0_GTXDELAY_NONE 0 #define VSC73XX_GMIIDELAY_GMII0_GTXDELAY_1_4_NS 1 #define VSC73XX_GMIIDELAY_GMII0_GTXDELAY_1_7_NS 2 #define VSC73XX_GMIIDELAY_GMII0_GTXDELAY_2_0_NS 3 #define VSC73XX_GMIIDELAY_GMII0_RXDELAY_NONE (0 << 4) #define VSC73XX_GMIIDELAY_GMII0_RXDELAY_1_4_NS (1 << 4) #define VSC73XX_GMIIDELAY_GMII0_RXDELAY_1_7_NS (2 << 4) #define VSC73XX_GMIIDELAY_GMII0_RXDELAY_2_0_NS (3 << 4) #define VSC73XX_ICPU_CTRL_WATCHDOG_RST BIT(31) #define VSC73XX_ICPU_CTRL_CLK_DIV_MASK GENMASK(12, 8) #define VSC73XX_ICPU_CTRL_SRST_HOLD BIT(7) #define VSC73XX_ICPU_CTRL_ICPU_PI_EN BIT(6) #define VSC73XX_ICPU_CTRL_BOOT_EN BIT(3) #define VSC73XX_ICPU_CTRL_EXT_ACC_EN BIT(2) #define VSC73XX_ICPU_CTRL_CLK_EN BIT(1) #define VSC73XX_ICPU_CTRL_SRST BIT(0) #define VSC73XX_CHIPID_ID_SHIFT 12 #define VSC73XX_CHIPID_ID_MASK 0xffff #define VSC73XX_CHIPID_REV_SHIFT 28 #define VSC73XX_CHIPID_REV_MASK 0xf #define VSC73XX_CHIPID_ID_7385 0x7385 #define VSC73XX_CHIPID_ID_7388 0x7388 #define VSC73XX_CHIPID_ID_7395 0x7395 #define VSC73XX_CHIPID_ID_7398 0x7398 #define VSC73XX_GLORESET_STROBE BIT(4) #define VSC73XX_GLORESET_ICPU_LOCK BIT(3) #define VSC73XX_GLORESET_MEM_LOCK BIT(2) #define VSC73XX_GLORESET_PHY_RESET BIT(1) #define VSC73XX_GLORESET_MASTER_RESET BIT(0) #define VSC7385_CLOCK_DELAY ((3 << 4) | 3) #define VSC7385_CLOCK_DELAY_MASK ((3 << 4) | 3) #define VSC73XX_ICPU_CTRL_STOP (VSC73XX_ICPU_CTRL_SRST_HOLD | \ VSC73XX_ICPU_CTRL_BOOT_EN | \ VSC73XX_ICPU_CTRL_EXT_ACC_EN) #define VSC73XX_ICPU_CTRL_START (VSC73XX_ICPU_CTRL_CLK_DIV | \ VSC73XX_ICPU_CTRL_BOOT_EN | \ VSC73XX_ICPU_CTRL_CLK_EN | \ VSC73XX_ICPU_CTRL_SRST) #define IS_7385(a) ((a)->chipid == VSC73XX_CHIPID_ID_7385) #define IS_7388(a) ((a)->chipid == VSC73XX_CHIPID_ID_7388) #define IS_7395(a) ((a)->chipid == VSC73XX_CHIPID_ID_7395) #define IS_7398(a) ((a)->chipid == VSC73XX_CHIPID_ID_7398) #define IS_739X(a) (IS_7395(a) || IS_7398(a)) struct vsc73xx_counter { u8 counter; const char *name; }; /* Counters are named according to the MIB standards where applicable. * Some counters are custom, non-standard. The standard counters are * named in accordance with RFC2819, RFC2021 and IEEE Std 802.3-2002 Annex * 30A Counters. */ static const struct vsc73xx_counter vsc73xx_rx_counters[] = { { 0, "RxEtherStatsPkts" }, { 1, "RxBroadcast+MulticastPkts" }, /* non-standard counter */ { 2, "RxTotalErrorPackets" }, /* non-standard counter */ { 3, "RxEtherStatsBroadcastPkts" }, { 4, "RxEtherStatsMulticastPkts" }, { 5, "RxEtherStatsPkts64Octets" }, { 6, "RxEtherStatsPkts65to127Octets" }, { 7, "RxEtherStatsPkts128to255Octets" }, { 8, "RxEtherStatsPkts256to511Octets" }, { 9, "RxEtherStatsPkts512to1023Octets" }, { 10, "RxEtherStatsPkts1024to1518Octets" }, { 11, "RxJumboFrames" }, /* non-standard counter */ { 12, "RxaPauseMACControlFramesTransmitted" }, { 13, "RxFIFODrops" }, /* non-standard counter */ { 14, "RxBackwardDrops" }, /* non-standard counter */ { 15, "RxClassifierDrops" }, /* non-standard counter */ { 16, "RxEtherStatsCRCAlignErrors" }, { 17, "RxEtherStatsUndersizePkts" }, { 18, "RxEtherStatsOversizePkts" }, { 19, "RxEtherStatsFragments" }, { 20, "RxEtherStatsJabbers" }, { 21, "RxaMACControlFramesReceived" }, /* 22-24 are undefined */ { 25, "RxaFramesReceivedOK" }, { 26, "RxQoSClass0" }, /* non-standard counter */ { 27, "RxQoSClass1" }, /* non-standard counter */ { 28, "RxQoSClass2" }, /* non-standard counter */ { 29, "RxQoSClass3" }, /* non-standard counter */ }; static const struct vsc73xx_counter vsc73xx_tx_counters[] = { { 0, "TxEtherStatsPkts" }, { 1, "TxBroadcast+MulticastPkts" }, /* non-standard counter */ { 2, "TxTotalErrorPackets" }, /* non-standard counter */ { 3, "TxEtherStatsBroadcastPkts" }, { 4, "TxEtherStatsMulticastPkts" }, { 5, "TxEtherStatsPkts64Octets" }, { 6, "TxEtherStatsPkts65to127Octets" }, { 7, "TxEtherStatsPkts128to255Octets" }, { 8, "TxEtherStatsPkts256to511Octets" }, { 9, "TxEtherStatsPkts512to1023Octets" }, { 10, "TxEtherStatsPkts1024to1518Octets" }, { 11, "TxJumboFrames" }, /* non-standard counter */ { 12, "TxaPauseMACControlFramesTransmitted" }, { 13, "TxFIFODrops" }, /* non-standard counter */ { 14, "TxDrops" }, /* non-standard counter */ { 15, "TxEtherStatsCollisions" }, { 16, "TxEtherStatsCRCAlignErrors" }, { 17, "TxEtherStatsUndersizePkts" }, { 18, "TxEtherStatsOversizePkts" }, { 19, "TxEtherStatsFragments" }, { 20, "TxEtherStatsJabbers" }, /* 21-24 are undefined */ { 25, "TxaFramesReceivedOK" }, { 26, "TxQoSClass0" }, /* non-standard counter */ { 27, "TxQoSClass1" }, /* non-standard counter */ { 28, "TxQoSClass2" }, /* non-standard counter */ { 29, "TxQoSClass3" }, /* non-standard counter */ }; int vsc73xx_is_addr_valid(u8 block, u8 subblock) { switch (block) { case VSC73XX_BLOCK_MAC: switch (subblock) { case 0 ... 4: case 6: return 1; } break; case VSC73XX_BLOCK_ANALYZER: case VSC73XX_BLOCK_SYSTEM: switch (subblock) { case 0: return 1; } break; case VSC73XX_BLOCK_MII: case VSC73XX_BLOCK_CAPTURE: case VSC73XX_BLOCK_ARBITER: switch (subblock) { case 0 ... 1: return 1; } break; } return 0; } EXPORT_SYMBOL(vsc73xx_is_addr_valid); static int vsc73xx_read(struct vsc73xx *vsc, u8 block, u8 subblock, u8 reg, u32 *val) { return vsc->ops->read(vsc, block, subblock, reg, val); } static int vsc73xx_write(struct vsc73xx *vsc, u8 block, u8 subblock, u8 reg, u32 val) { return vsc->ops->write(vsc, block, subblock, reg, val); } static int vsc73xx_update_bits(struct vsc73xx *vsc, u8 block, u8 subblock, u8 reg, u32 mask, u32 val) { u32 tmp, orig; int ret; /* Same read-modify-write algorithm as e.g. regmap */ ret = vsc73xx_read(vsc, block, subblock, reg, &orig); if (ret) return ret; tmp = orig & ~mask; tmp |= val & mask; return vsc73xx_write(vsc, block, subblock, reg, tmp); } static int vsc73xx_detect(struct vsc73xx *vsc) { bool icpu_si_boot_en; bool icpu_pi_en; u32 val; u32 rev; int ret; u32 id; ret = vsc73xx_read(vsc, VSC73XX_BLOCK_SYSTEM, 0, VSC73XX_ICPU_MBOX_VAL, &val); if (ret) { dev_err(vsc->dev, "unable to read mailbox (%d)\n", ret); return ret; } if (val == 0xffffffff) { dev_info(vsc->dev, "chip seems dead.\n"); return -EAGAIN; } ret = vsc73xx_read(vsc, VSC73XX_BLOCK_SYSTEM, 0, VSC73XX_CHIPID, &val); if (ret) { dev_err(vsc->dev, "unable to read chip id (%d)\n", ret); return ret; } id = (val >> VSC73XX_CHIPID_ID_SHIFT) & VSC73XX_CHIPID_ID_MASK; switch (id) { case VSC73XX_CHIPID_ID_7385: case VSC73XX_CHIPID_ID_7388: case VSC73XX_CHIPID_ID_7395: case VSC73XX_CHIPID_ID_7398: break; default: dev_err(vsc->dev, "unsupported chip, id=%04x\n", id); return -ENODEV; } vsc->chipid = id; rev = (val >> VSC73XX_CHIPID_REV_SHIFT) & VSC73XX_CHIPID_REV_MASK; dev_info(vsc->dev, "VSC%04X (rev: %d) switch found\n", id, rev); ret = vsc73xx_read(vsc, VSC73XX_BLOCK_SYSTEM, 0, VSC73XX_ICPU_CTRL, &val); if (ret) { dev_err(vsc->dev, "unable to read iCPU control\n"); return ret; } /* The iCPU can always be used but can boot in different ways. * If it is initially disabled and has no external memory, * we are in control and can do whatever we like, else we * are probably in trouble (we need some way to communicate * with the running firmware) so we bail out for now. */ icpu_pi_en = !!(val & VSC73XX_ICPU_CTRL_ICPU_PI_EN); icpu_si_boot_en = !!(val & VSC73XX_ICPU_CTRL_BOOT_EN); if (icpu_si_boot_en && icpu_pi_en) { dev_err(vsc->dev, "iCPU enabled boots from SI, has external memory\n"); dev_err(vsc->dev, "no idea how to deal with this\n"); return -ENODEV; } if (icpu_si_boot_en && !icpu_pi_en) { dev_err(vsc->dev, "iCPU enabled boots from PI/SI, no external memory\n"); return -EAGAIN; } if (!icpu_si_boot_en && icpu_pi_en) { dev_err(vsc->dev, "iCPU enabled, boots from PI external memory\n"); dev_err(vsc->dev, "no idea how to deal with this\n"); return -ENODEV; } /* !icpu_si_boot_en && !cpu_pi_en */ dev_info(vsc->dev, "iCPU disabled, no external memory\n"); return 0; } static int vsc73xx_phy_read(struct dsa_switch *ds, int phy, int regnum) { struct vsc73xx *vsc = ds->priv; u32 cmd; u32 val; int ret; /* Setting bit 26 means "read" */ cmd = BIT(26) | (phy << 21) | (regnum << 16); ret = vsc73xx_write(vsc, VSC73XX_BLOCK_MII, 0, 1, cmd); if (ret) return ret; msleep(2); ret = vsc73xx_read(vsc, VSC73XX_BLOCK_MII, 0, 2, &val); if (ret) return ret; if (val & BIT(16)) { dev_err(vsc->dev, "reading reg %02x from phy%d failed\n", regnum, phy); return -EIO; } val &= 0xFFFFU; dev_dbg(vsc->dev, "read reg %02x from phy%d = %04x\n", regnum, phy, val); return val; } static int vsc73xx_phy_write(struct dsa_switch *ds, int phy, int regnum, u16 val) { struct vsc73xx *vsc = ds->priv; u32 cmd; int ret; /* It was found through tedious experiments that this router * chip really hates to have it's PHYs reset. They * never recover if that happens: autonegotiation stops * working after a reset. Just filter out this command. * (Resetting the whole chip is OK.) */ if (regnum == 0 && (val & BIT(15))) { dev_info(vsc->dev, "reset PHY - disallowed\n"); return 0; } cmd = (phy << 21) | (regnum << 16); ret = vsc73xx_write(vsc, VSC73XX_BLOCK_MII, 0, 1, cmd); if (ret) return ret; dev_dbg(vsc->dev, "write %04x to reg %02x in phy%d\n", val, regnum, phy); return 0; } static enum dsa_tag_protocol vsc73xx_get_tag_protocol(struct dsa_switch *ds, int port, enum dsa_tag_protocol mp) { /* The switch internally uses a 8 byte header with length, * source port, tag, LPA and priority. This is supposedly * only accessible when operating the switch using the internal * CPU or with an external CPU mapping the device in, but not * when operating the switch over SPI and putting frames in/out * on port 6 (the CPU port). So far we must assume that we * cannot access the tag. (See "Internal frame header" section * 3.9.1 in the manual.) */ return DSA_TAG_PROTO_NONE; } static int vsc73xx_setup(struct dsa_switch *ds) { struct vsc73xx *vsc = ds->priv; int i; dev_info(vsc->dev, "set up the switch\n"); /* Issue RESET */ vsc73xx_write(vsc, VSC73XX_BLOCK_SYSTEM, 0, VSC73XX_GLORESET, VSC73XX_GLORESET_MASTER_RESET); usleep_range(125, 200); /* Initialize memory, initialize RAM bank 0..15 except 6 and 7 * This sequence appears in the * VSC7385 SparX-G5 datasheet section 6.6.1 * VSC7395 SparX-G5e datasheet section 6.6.1 * "initialization sequence". * No explanation is given to the 0x1010400 magic number. */ for (i = 0; i <= 15; i++) { if (i != 6 && i != 7) { vsc73xx_write(vsc, VSC73XX_BLOCK_MEMINIT, 2, 0, 0x1010400 + i); mdelay(1); } } mdelay(30); /* Clear MAC table */ vsc73xx_write(vsc, VSC73XX_BLOCK_ANALYZER, 0, VSC73XX_MACACCESS, VSC73XX_MACACCESS_CMD_CLEAR_TABLE); /* Clear VLAN table */ vsc73xx_write(vsc, VSC73XX_BLOCK_ANALYZER, 0, VSC73XX_VLANACCESS, VSC73XX_VLANACCESS_VLAN_TBL_CMD_CLEAR_TABLE); msleep(40); /* Use 20KiB buffers on all ports on VSC7395 * The VSC7385 has 16KiB buffers and that is the * default if we don't set this up explicitly. * Port "31" is "all ports". */ if (IS_739X(vsc)) vsc73xx_write(vsc, VSC73XX_BLOCK_MAC, 0x1f, VSC73XX_Q_MISC_CONF, VSC73XX_Q_MISC_CONF_EXTENT_MEM); /* Put all ports into reset until enabled */ for (i = 0; i < 7; i++) { if (i == 5) continue; vsc73xx_write(vsc, VSC73XX_BLOCK_MAC, 4, VSC73XX_MAC_CFG, VSC73XX_MAC_CFG_RESET); } /* MII delay, set both GTX and RX delay to 2 ns */ vsc73xx_write(vsc, VSC73XX_BLOCK_SYSTEM, 0, VSC73XX_GMIIDELAY, VSC73XX_GMIIDELAY_GMII0_GTXDELAY_2_0_NS | VSC73XX_GMIIDELAY_GMII0_RXDELAY_2_0_NS); /* Enable reception of frames on all ports */ vsc73xx_write(vsc, VSC73XX_BLOCK_ANALYZER, 0, VSC73XX_RECVMASK, 0x5f); /* IP multicast flood mask (table 144) */ vsc73xx_write(vsc, VSC73XX_BLOCK_ANALYZER, 0, VSC73XX_IFLODMSK, 0xff); mdelay(50); /* Release reset from the internal PHYs */ vsc73xx_write(vsc, VSC73XX_BLOCK_SYSTEM, 0, VSC73XX_GLORESET, VSC73XX_GLORESET_PHY_RESET); udelay(4); return 0; } static void vsc73xx_init_port(struct vsc73xx *vsc, int port) { u32 val; /* MAC configure, first reset the port and then write defaults */ vsc73xx_write(vsc, VSC73XX_BLOCK_MAC, port, VSC73XX_MAC_CFG, VSC73XX_MAC_CFG_RESET); /* Take up the port in 1Gbit mode by default, this will be * augmented after auto-negotiation on the PHY-facing * ports. */ if (port == CPU_PORT) val = VSC73XX_MAC_CFG_1000M_F_RGMII; else val = VSC73XX_MAC_CFG_1000M_F_PHY; vsc73xx_write(vsc, VSC73XX_BLOCK_MAC, port, VSC73XX_MAC_CFG, val | VSC73XX_MAC_CFG_TX_EN | VSC73XX_MAC_CFG_RX_EN); /* Flow control for the CPU port: * Use a zero delay pause frame when pause condition is left * Obey pause control frames */ vsc73xx_write(vsc, VSC73XX_BLOCK_MAC, port, VSC73XX_FCCONF, VSC73XX_FCCONF_ZERO_PAUSE_EN | VSC73XX_FCCONF_FLOW_CTRL_OBEY); /* Issue pause control frames on PHY facing ports. * Allow early initiation of MAC transmission if the amount * of egress data is below 512 bytes on CPU port. * FIXME: enable 20KiB buffers? */ if (port == CPU_PORT) val = VSC73XX_Q_MISC_CONF_EARLY_TX_512; else val = VSC73XX_Q_MISC_CONF_MAC_PAUSE_MODE; val |= VSC73XX_Q_MISC_CONF_EXTENT_MEM; vsc73xx_write(vsc, VSC73XX_BLOCK_MAC, port, VSC73XX_Q_MISC_CONF, val); /* Flow control MAC: a MAC address used in flow control frames */ val = (vsc->addr[5] << 16) | (vsc->addr[4] << 8) | (vsc->addr[3]); vsc73xx_write(vsc, VSC73XX_BLOCK_MAC, port, VSC73XX_FCMACHI, val); val = (vsc->addr[2] << 16) | (vsc->addr[1] << 8) | (vsc->addr[0]); vsc73xx_write(vsc, VSC73XX_BLOCK_MAC, port, VSC73XX_FCMACLO, val); /* Tell the categorizer to forward pause frames, not control * frame. Do not drop anything. */ vsc73xx_write(vsc, VSC73XX_BLOCK_MAC, port, VSC73XX_CAT_DROP, VSC73XX_CAT_DROP_FWD_PAUSE_ENA); /* Clear all counters */ vsc73xx_write(vsc, VSC73XX_BLOCK_MAC, port, VSC73XX_C_RX0, 0); } static void vsc73xx_adjust_enable_port(struct vsc73xx *vsc, int port, struct phy_device *phydev, u32 initval) { u32 val = initval; u8 seed; /* Reset this port FIXME: break out subroutine */ val |= VSC73XX_MAC_CFG_RESET; vsc73xx_write(vsc, VSC73XX_BLOCK_MAC, port, VSC73XX_MAC_CFG, val); /* Seed the port randomness with randomness */ get_random_bytes(&seed, 1); val |= seed << VSC73XX_MAC_CFG_SEED_OFFSET; val |= VSC73XX_MAC_CFG_SEED_LOAD; val |= VSC73XX_MAC_CFG_WEXC_DIS; vsc73xx_write(vsc, VSC73XX_BLOCK_MAC, port, VSC73XX_MAC_CFG, val); /* Flow control for the PHY facing ports: * Use a zero delay pause frame when pause condition is left * Obey pause control frames * When generating pause frames, use 0xff as pause value */ vsc73xx_write(vsc, VSC73XX_BLOCK_MAC, port, VSC73XX_FCCONF, VSC73XX_FCCONF_ZERO_PAUSE_EN | VSC73XX_FCCONF_FLOW_CTRL_OBEY | 0xff); /* Disallow backward dropping of frames from this port */ vsc73xx_update_bits(vsc, VSC73XX_BLOCK_ARBITER, 0, VSC73XX_SBACKWDROP, BIT(port), 0); /* Enable TX, RX, deassert reset, stop loading seed */ vsc73xx_update_bits(vsc, VSC73XX_BLOCK_MAC, port, VSC73XX_MAC_CFG, VSC73XX_MAC_CFG_RESET | VSC73XX_MAC_CFG_SEED_LOAD | VSC73XX_MAC_CFG_TX_EN | VSC73XX_MAC_CFG_RX_EN, VSC73XX_MAC_CFG_TX_EN | VSC73XX_MAC_CFG_RX_EN); } static void vsc73xx_adjust_link(struct dsa_switch *ds, int port, struct phy_device *phydev) { struct vsc73xx *vsc = ds->priv; u32 val; /* Special handling of the CPU-facing port */ if (port == CPU_PORT) { /* Other ports are already initialized but not this one */ vsc73xx_init_port(vsc, CPU_PORT); /* Select the external port for this interface (EXT_PORT) * Enable the GMII GTX external clock * Use double data rate (DDR mode) */ vsc73xx_write(vsc, VSC73XX_BLOCK_MAC, CPU_PORT, VSC73XX_ADVPORTM, VSC73XX_ADVPORTM_EXT_PORT | VSC73XX_ADVPORTM_ENA_GTX | VSC73XX_ADVPORTM_DDR_MODE); } /* This is the MAC confiuration that always need to happen * after a PHY or the CPU port comes up or down. */ if (!phydev->link) { int maxloop = 10; dev_dbg(vsc->dev, "port %d: went down\n", port); /* Disable RX on this port */ vsc73xx_update_bits(vsc, VSC73XX_BLOCK_MAC, port, VSC73XX_MAC_CFG, VSC73XX_MAC_CFG_RX_EN, 0); /* Discard packets */ vsc73xx_update_bits(vsc, VSC73XX_BLOCK_ARBITER, 0, VSC73XX_ARBDISC, BIT(port), BIT(port)); /* Wait until queue is empty */ vsc73xx_read(vsc, VSC73XX_BLOCK_ARBITER, 0, VSC73XX_ARBEMPTY, &val); while (!(val & BIT(port))) { msleep(1); vsc73xx_read(vsc, VSC73XX_BLOCK_ARBITER, 0, VSC73XX_ARBEMPTY, &val); if (--maxloop == 0) { dev_err(vsc->dev, "timeout waiting for block arbiter\n"); /* Continue anyway */ break; } } /* Put this port into reset */ vsc73xx_write(vsc, VSC73XX_BLOCK_MAC, port, VSC73XX_MAC_CFG, VSC73XX_MAC_CFG_RESET); /* Accept packets again */ vsc73xx_update_bits(vsc, VSC73XX_BLOCK_ARBITER, 0, VSC73XX_ARBDISC, BIT(port), 0); /* Allow backward dropping of frames from this port */ vsc73xx_update_bits(vsc, VSC73XX_BLOCK_ARBITER, 0, VSC73XX_SBACKWDROP, BIT(port), BIT(port)); /* Receive mask (disable forwarding) */ vsc73xx_update_bits(vsc, VSC73XX_BLOCK_ANALYZER, 0, VSC73XX_RECVMASK, BIT(port), 0); return; } /* Figure out what speed was negotiated */ if (phydev->speed == SPEED_1000) { dev_dbg(vsc->dev, "port %d: 1000 Mbit mode full duplex\n", port); /* Set up default for internal port or external RGMII */ if (phydev->interface == PHY_INTERFACE_MODE_RGMII) val = VSC73XX_MAC_CFG_1000M_F_RGMII; else val = VSC73XX_MAC_CFG_1000M_F_PHY; vsc73xx_adjust_enable_port(vsc, port, phydev, val); } else if (phydev->speed == SPEED_100) { if (phydev->duplex == DUPLEX_FULL) { val = VSC73XX_MAC_CFG_100_10M_F_PHY; dev_dbg(vsc->dev, "port %d: 100 Mbit full duplex mode\n", port); } else { val = VSC73XX_MAC_CFG_100_10M_H_PHY; dev_dbg(vsc->dev, "port %d: 100 Mbit half duplex mode\n", port); } vsc73xx_adjust_enable_port(vsc, port, phydev, val); } else if (phydev->speed == SPEED_10) { if (phydev->duplex == DUPLEX_FULL) { val = VSC73XX_MAC_CFG_100_10M_F_PHY; dev_dbg(vsc->dev, "port %d: 10 Mbit full duplex mode\n", port); } else { val = VSC73XX_MAC_CFG_100_10M_H_PHY; dev_dbg(vsc->dev, "port %d: 10 Mbit half duplex mode\n", port); } vsc73xx_adjust_enable_port(vsc, port, phydev, val); } else { dev_err(vsc->dev, "could not adjust link: unknown speed\n"); } /* Enable port (forwarding) in the receieve mask */ vsc73xx_update_bits(vsc, VSC73XX_BLOCK_ANALYZER, 0, VSC73XX_RECVMASK, BIT(port), BIT(port)); } static int vsc73xx_port_enable(struct dsa_switch *ds, int port, struct phy_device *phy) { struct vsc73xx *vsc = ds->priv; dev_info(vsc->dev, "enable port %d\n", port); vsc73xx_init_port(vsc, port); return 0; } static void vsc73xx_port_disable(struct dsa_switch *ds, int port) { struct vsc73xx *vsc = ds->priv; /* Just put the port into reset */ vsc73xx_write(vsc, VSC73XX_BLOCK_MAC, port, VSC73XX_MAC_CFG, VSC73XX_MAC_CFG_RESET); } static const struct vsc73xx_counter * vsc73xx_find_counter(struct vsc73xx *vsc, u8 counter, bool tx) { const struct vsc73xx_counter *cnts; int num_cnts; int i; if (tx) { cnts = vsc73xx_tx_counters; num_cnts = ARRAY_SIZE(vsc73xx_tx_counters); } else { cnts = vsc73xx_rx_counters; num_cnts = ARRAY_SIZE(vsc73xx_rx_counters); } for (i = 0; i < num_cnts; i++) { const struct vsc73xx_counter *cnt; cnt = &cnts[i]; if (cnt->counter == counter) return cnt; } return NULL; } static void vsc73xx_get_strings(struct dsa_switch *ds, int port, u32 stringset, uint8_t *data) { const struct vsc73xx_counter *cnt; struct vsc73xx *vsc = ds->priv; u8 indices[6]; int i, j; u32 val; int ret; if (stringset != ETH_SS_STATS) return; ret = vsc73xx_read(vsc, VSC73XX_BLOCK_MAC, port, VSC73XX_C_CFG, &val); if (ret) return; indices[0] = (val & 0x1f); /* RX counter 0 */ indices[1] = ((val >> 5) & 0x1f); /* RX counter 1 */ indices[2] = ((val >> 10) & 0x1f); /* RX counter 2 */ indices[3] = ((val >> 16) & 0x1f); /* TX counter 0 */ indices[4] = ((val >> 21) & 0x1f); /* TX counter 1 */ indices[5] = ((val >> 26) & 0x1f); /* TX counter 2 */ /* The first counters is the RX octets */ j = 0; strncpy(data + j * ETH_GSTRING_LEN, "RxEtherStatsOctets", ETH_GSTRING_LEN); j++; /* Each port supports recording 3 RX counters and 3 TX counters, * figure out what counters we use in this set-up and return the * names of them. The hardware default counters will be number of * packets on RX/TX, combined broadcast+multicast packets RX/TX and * total error packets RX/TX. */ for (i = 0; i < 3; i++) { cnt = vsc73xx_find_counter(vsc, indices[i], false); if (cnt) strncpy(data + j * ETH_GSTRING_LEN, cnt->name, ETH_GSTRING_LEN); j++; } /* TX stats begins with the number of TX octets */ strncpy(data + j * ETH_GSTRING_LEN, "TxEtherStatsOctets", ETH_GSTRING_LEN); j++; for (i = 3; i < 6; i++) { cnt = vsc73xx_find_counter(vsc, indices[i], true); if (cnt) strncpy(data + j * ETH_GSTRING_LEN, cnt->name, ETH_GSTRING_LEN); j++; } } static int vsc73xx_get_sset_count(struct dsa_switch *ds, int port, int sset) { /* We only support SS_STATS */ if (sset != ETH_SS_STATS) return 0; /* RX and TX packets, then 3 RX counters, 3 TX counters */ return 8; } static void vsc73xx_get_ethtool_stats(struct dsa_switch *ds, int port, uint64_t *data) { struct vsc73xx *vsc = ds->priv; u8 regs[] = { VSC73XX_RXOCT, VSC73XX_C_RX0, VSC73XX_C_RX1, VSC73XX_C_RX2, VSC73XX_TXOCT, VSC73XX_C_TX0, VSC73XX_C_TX1, VSC73XX_C_TX2, }; u32 val; int ret; int i; for (i = 0; i < ARRAY_SIZE(regs); i++) { ret = vsc73xx_read(vsc, VSC73XX_BLOCK_MAC, port, regs[i], &val); if (ret) { dev_err(vsc->dev, "error reading counter %d\n", i); return; } data[i] = val; } } static int vsc73xx_change_mtu(struct dsa_switch *ds, int port, int new_mtu) { struct vsc73xx *vsc = ds->priv; return vsc73xx_write(vsc, VSC73XX_BLOCK_MAC, port, VSC73XX_MAXLEN, new_mtu); } /* According to application not "VSC7398 Jumbo Frames" setting * up the MTU to 9.6 KB does not affect the performance on standard * frames. It is clear from the application note that * "9.6 kilobytes" == 9600 bytes. */ static int vsc73xx_get_max_mtu(struct dsa_switch *ds, int port) { return 9600; } static const struct dsa_switch_ops vsc73xx_ds_ops = { .get_tag_protocol = vsc73xx_get_tag_protocol, .setup = vsc73xx_setup, .phy_read = vsc73xx_phy_read, .phy_write = vsc73xx_phy_write, .adjust_link = vsc73xx_adjust_link, .get_strings = vsc73xx_get_strings, .get_ethtool_stats = vsc73xx_get_ethtool_stats, .get_sset_count = vsc73xx_get_sset_count, .port_enable = vsc73xx_port_enable, .port_disable = vsc73xx_port_disable, .port_change_mtu = vsc73xx_change_mtu, .port_max_mtu = vsc73xx_get_max_mtu, }; static int vsc73xx_gpio_get(struct gpio_chip *chip, unsigned int offset) { struct vsc73xx *vsc = gpiochip_get_data(chip); u32 val; int ret; ret = vsc73xx_read(vsc, VSC73XX_BLOCK_SYSTEM, 0, VSC73XX_GPIO, &val); if (ret) return ret; return !!(val & BIT(offset)); } static void vsc73xx_gpio_set(struct gpio_chip *chip, unsigned int offset, int val) { struct vsc73xx *vsc = gpiochip_get_data(chip); u32 tmp = val ? BIT(offset) : 0; vsc73xx_update_bits(vsc, VSC73XX_BLOCK_SYSTEM, 0, VSC73XX_GPIO, BIT(offset), tmp); } static int vsc73xx_gpio_direction_output(struct gpio_chip *chip, unsigned int offset, int val) { struct vsc73xx *vsc = gpiochip_get_data(chip); u32 tmp = val ? BIT(offset) : 0; return vsc73xx_update_bits(vsc, VSC73XX_BLOCK_SYSTEM, 0, VSC73XX_GPIO, BIT(offset + 4) | BIT(offset), BIT(offset + 4) | tmp); } static int vsc73xx_gpio_direction_input(struct gpio_chip *chip, unsigned int offset) { struct vsc73xx *vsc = gpiochip_get_data(chip); return vsc73xx_update_bits(vsc, VSC73XX_BLOCK_SYSTEM, 0, VSC73XX_GPIO, BIT(offset + 4), 0); } static int vsc73xx_gpio_get_direction(struct gpio_chip *chip, unsigned int offset) { struct vsc73xx *vsc = gpiochip_get_data(chip); u32 val; int ret; ret = vsc73xx_read(vsc, VSC73XX_BLOCK_SYSTEM, 0, VSC73XX_GPIO, &val); if (ret) return ret; return !(val & BIT(offset + 4)); } static int vsc73xx_gpio_probe(struct vsc73xx *vsc) { int ret; vsc->gc.label = devm_kasprintf(vsc->dev, GFP_KERNEL, "VSC%04x", vsc->chipid); vsc->gc.ngpio = 4; vsc->gc.owner = THIS_MODULE; vsc->gc.parent = vsc->dev; #if IS_ENABLED(CONFIG_OF_GPIO) vsc->gc.of_node = vsc->dev->of_node; #endif vsc->gc.base = -1; vsc->gc.get = vsc73xx_gpio_get; vsc->gc.set = vsc73xx_gpio_set; vsc->gc.direction_input = vsc73xx_gpio_direction_input; vsc->gc.direction_output = vsc73xx_gpio_direction_output; vsc->gc.get_direction = vsc73xx_gpio_get_direction; vsc->gc.can_sleep = true; ret = devm_gpiochip_add_data(vsc->dev, &vsc->gc, vsc); if (ret) { dev_err(vsc->dev, "unable to register GPIO chip\n"); return ret; } return 0; } int vsc73xx_probe(struct vsc73xx *vsc) { struct device *dev = vsc->dev; int ret; /* Release reset, if any */ vsc->reset = devm_gpiod_get_optional(dev, "reset", GPIOD_OUT_LOW); if (IS_ERR(vsc->reset)) { dev_err(dev, "failed to get RESET GPIO\n"); return PTR_ERR(vsc->reset); } if (vsc->reset) /* Wait 20ms according to datasheet table 245 */ msleep(20); ret = vsc73xx_detect(vsc); if (ret == -EAGAIN) { dev_err(vsc->dev, "Chip seems to be out of control. Assert reset and try again.\n"); gpiod_set_value_cansleep(vsc->reset, 1); /* Reset pulse should be 20ns minimum, according to datasheet * table 245, so 10us should be fine */ usleep_range(10, 100); gpiod_set_value_cansleep(vsc->reset, 0); /* Wait 20ms according to datasheet table 245 */ msleep(20); ret = vsc73xx_detect(vsc); } if (ret) { dev_err(dev, "no chip found (%d)\n", ret); return -ENODEV; } eth_random_addr(vsc->addr); dev_info(vsc->dev, "MAC for control frames: %02X:%02X:%02X:%02X:%02X:%02X\n", vsc->addr[0], vsc->addr[1], vsc->addr[2], vsc->addr[3], vsc->addr[4], vsc->addr[5]); /* The VSC7395 switch chips have 5+1 ports which means 5 * ordinary ports and a sixth CPU port facing the processor * with an RGMII interface. These ports are numbered 0..4 * and 6, so they leave a "hole" in the port map for port 5, * which is invalid. * * The VSC7398 has 8 ports, port 7 is again the CPU port. * * We allocate 8 ports and avoid access to the nonexistant * ports. */ vsc->ds = devm_kzalloc(dev, sizeof(*vsc->ds), GFP_KERNEL); if (!vsc->ds) return -ENOMEM; vsc->ds->dev = dev; vsc->ds->num_ports = 8; vsc->ds->priv = vsc; vsc->ds->ops = &vsc73xx_ds_ops; ret = dsa_register_switch(vsc->ds); if (ret) { dev_err(dev, "unable to register switch (%d)\n", ret); return ret; } ret = vsc73xx_gpio_probe(vsc); if (ret) { dsa_unregister_switch(vsc->ds); return ret; } return 0; } EXPORT_SYMBOL(vsc73xx_probe); int vsc73xx_remove(struct vsc73xx *vsc) { dsa_unregister_switch(vsc->ds); gpiod_set_value(vsc->reset, 1); return 0; } EXPORT_SYMBOL(vsc73xx_remove); MODULE_AUTHOR("Linus Walleij <linus.walleij@linaro.org>"); MODULE_DESCRIPTION("Vitesse VSC7385/7388/7395/7398 driver"); MODULE_LICENSE("GPL v2");
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