tjh.dev / kernel
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kernel / drivers / net / dsa / rtl8366rb.c
at v5.13-rc6 1546 lines 47 kB view raw
1// SPDX-License-Identifier: GPL-2.0 2/* Realtek SMI subdriver for the Realtek RTL8366RB ethernet switch 3 * 4 * This is a sparsely documented chip, the only viable documentation seems 5 * to be a patched up code drop from the vendor that appear in various 6 * GPL source trees. 7 * 8 * Copyright (C) 2017 Linus Walleij <linus.walleij@linaro.org> 9 * Copyright (C) 2009-2010 Gabor Juhos <juhosg@openwrt.org> 10 * Copyright (C) 2010 Antti Seppälä <a.seppala@gmail.com> 11 * Copyright (C) 2010 Roman Yeryomin <roman@advem.lv> 12 * Copyright (C) 2011 Colin Leitner <colin.leitner@googlemail.com> 13 */ 14 15#include <linux/bitops.h> 16#include <linux/etherdevice.h> 17#include <linux/interrupt.h> 18#include <linux/irqdomain.h> 19#include <linux/irqchip/chained_irq.h> 20#include <linux/of_irq.h> 21#include <linux/regmap.h> 22 23#include "realtek-smi-core.h" 24 25#define RTL8366RB_PORT_NUM_CPU 5 26#define RTL8366RB_NUM_PORTS 6 27#define RTL8366RB_PHY_NO_MAX 4 28#define RTL8366RB_PHY_ADDR_MAX 31 29 30/* Switch Global Configuration register */ 31#define RTL8366RB_SGCR 0x0000 32#define RTL8366RB_SGCR_EN_BC_STORM_CTRL BIT(0) 33#define RTL8366RB_SGCR_MAX_LENGTH(a) ((a) << 4) 34#define RTL8366RB_SGCR_MAX_LENGTH_MASK RTL8366RB_SGCR_MAX_LENGTH(0x3) 35#define RTL8366RB_SGCR_MAX_LENGTH_1522 RTL8366RB_SGCR_MAX_LENGTH(0x0) 36#define RTL8366RB_SGCR_MAX_LENGTH_1536 RTL8366RB_SGCR_MAX_LENGTH(0x1) 37#define RTL8366RB_SGCR_MAX_LENGTH_1552 RTL8366RB_SGCR_MAX_LENGTH(0x2) 38#define RTL8366RB_SGCR_MAX_LENGTH_16000 RTL8366RB_SGCR_MAX_LENGTH(0x3) 39#define RTL8366RB_SGCR_EN_VLAN BIT(13) 40#define RTL8366RB_SGCR_EN_VLAN_4KTB BIT(14) 41 42/* Port Enable Control register */ 43#define RTL8366RB_PECR 0x0001 44 45/* Switch Security Control registers */ 46#define RTL8366RB_SSCR0 0x0002 47#define RTL8366RB_SSCR1 0x0003 48#define RTL8366RB_SSCR2 0x0004 49#define RTL8366RB_SSCR2_DROP_UNKNOWN_DA BIT(0) 50 51/* Port Mode Control registers */ 52#define RTL8366RB_PMC0 0x0005 53#define RTL8366RB_PMC0_SPI BIT(0) 54#define RTL8366RB_PMC0_EN_AUTOLOAD BIT(1) 55#define RTL8366RB_PMC0_PROBE BIT(2) 56#define RTL8366RB_PMC0_DIS_BISR BIT(3) 57#define RTL8366RB_PMC0_ADCTEST BIT(4) 58#define RTL8366RB_PMC0_SRAM_DIAG BIT(5) 59#define RTL8366RB_PMC0_EN_SCAN BIT(6) 60#define RTL8366RB_PMC0_P4_IOMODE_SHIFT 7 61#define RTL8366RB_PMC0_P4_IOMODE_MASK GENMASK(9, 7) 62#define RTL8366RB_PMC0_P5_IOMODE_SHIFT 10 63#define RTL8366RB_PMC0_P5_IOMODE_MASK GENMASK(12, 10) 64#define RTL8366RB_PMC0_SDSMODE_SHIFT 13 65#define RTL8366RB_PMC0_SDSMODE_MASK GENMASK(15, 13) 66#define RTL8366RB_PMC1 0x0006 67 68/* Port Mirror Control Register */ 69#define RTL8366RB_PMCR 0x0007 70#define RTL8366RB_PMCR_SOURCE_PORT(a) (a) 71#define RTL8366RB_PMCR_SOURCE_PORT_MASK 0x000f 72#define RTL8366RB_PMCR_MONITOR_PORT(a) ((a) << 4) 73#define RTL8366RB_PMCR_MONITOR_PORT_MASK 0x00f0 74#define RTL8366RB_PMCR_MIRROR_RX BIT(8) 75#define RTL8366RB_PMCR_MIRROR_TX BIT(9) 76#define RTL8366RB_PMCR_MIRROR_SPC BIT(10) 77#define RTL8366RB_PMCR_MIRROR_ISO BIT(11) 78 79/* bits 0..7 = port 0, bits 8..15 = port 1 */ 80#define RTL8366RB_PAACR0 0x0010 81/* bits 0..7 = port 2, bits 8..15 = port 3 */ 82#define RTL8366RB_PAACR1 0x0011 83/* bits 0..7 = port 4, bits 8..15 = port 5 */ 84#define RTL8366RB_PAACR2 0x0012 85#define RTL8366RB_PAACR_SPEED_10M 0 86#define RTL8366RB_PAACR_SPEED_100M 1 87#define RTL8366RB_PAACR_SPEED_1000M 2 88#define RTL8366RB_PAACR_FULL_DUPLEX BIT(2) 89#define RTL8366RB_PAACR_LINK_UP BIT(4) 90#define RTL8366RB_PAACR_TX_PAUSE BIT(5) 91#define RTL8366RB_PAACR_RX_PAUSE BIT(6) 92#define RTL8366RB_PAACR_AN BIT(7) 93 94#define RTL8366RB_PAACR_CPU_PORT (RTL8366RB_PAACR_SPEED_1000M | \ 95 RTL8366RB_PAACR_FULL_DUPLEX | \ 96 RTL8366RB_PAACR_LINK_UP | \ 97 RTL8366RB_PAACR_TX_PAUSE | \ 98 RTL8366RB_PAACR_RX_PAUSE) 99 100/* bits 0..7 = port 0, bits 8..15 = port 1 */ 101#define RTL8366RB_PSTAT0 0x0014 102/* bits 0..7 = port 2, bits 8..15 = port 3 */ 103#define RTL8366RB_PSTAT1 0x0015 104/* bits 0..7 = port 4, bits 8..15 = port 5 */ 105#define RTL8366RB_PSTAT2 0x0016 106 107#define RTL8366RB_POWER_SAVING_REG 0x0021 108 109/* CPU port control reg */ 110#define RTL8368RB_CPU_CTRL_REG 0x0061 111#define RTL8368RB_CPU_PORTS_MSK 0x00FF 112/* Disables inserting custom tag length/type 0x8899 */ 113#define RTL8368RB_CPU_NO_TAG BIT(15) 114 115#define RTL8366RB_SMAR0 0x0070 /* bits 0..15 */ 116#define RTL8366RB_SMAR1 0x0071 /* bits 16..31 */ 117#define RTL8366RB_SMAR2 0x0072 /* bits 32..47 */ 118 119#define RTL8366RB_RESET_CTRL_REG 0x0100 120#define RTL8366RB_CHIP_CTRL_RESET_HW BIT(0) 121#define RTL8366RB_CHIP_CTRL_RESET_SW BIT(1) 122 123#define RTL8366RB_CHIP_ID_REG 0x0509 124#define RTL8366RB_CHIP_ID_8366 0x5937 125#define RTL8366RB_CHIP_VERSION_CTRL_REG 0x050A 126#define RTL8366RB_CHIP_VERSION_MASK 0xf 127 128/* PHY registers control */ 129#define RTL8366RB_PHY_ACCESS_CTRL_REG 0x8000 130#define RTL8366RB_PHY_CTRL_READ BIT(0) 131#define RTL8366RB_PHY_CTRL_WRITE 0 132#define RTL8366RB_PHY_ACCESS_BUSY_REG 0x8001 133#define RTL8366RB_PHY_INT_BUSY BIT(0) 134#define RTL8366RB_PHY_EXT_BUSY BIT(4) 135#define RTL8366RB_PHY_ACCESS_DATA_REG 0x8002 136#define RTL8366RB_PHY_EXT_CTRL_REG 0x8010 137#define RTL8366RB_PHY_EXT_WRDATA_REG 0x8011 138#define RTL8366RB_PHY_EXT_RDDATA_REG 0x8012 139 140#define RTL8366RB_PHY_REG_MASK 0x1f 141#define RTL8366RB_PHY_PAGE_OFFSET 5 142#define RTL8366RB_PHY_PAGE_MASK (0xf << 5) 143#define RTL8366RB_PHY_NO_OFFSET 9 144#define RTL8366RB_PHY_NO_MASK (0x1f << 9) 145 146#define RTL8366RB_VLAN_INGRESS_CTRL2_REG 0x037f 147 148/* LED control registers */ 149#define RTL8366RB_LED_BLINKRATE_REG 0x0430 150#define RTL8366RB_LED_BLINKRATE_MASK 0x0007 151#define RTL8366RB_LED_BLINKRATE_28MS 0x0000 152#define RTL8366RB_LED_BLINKRATE_56MS 0x0001 153#define RTL8366RB_LED_BLINKRATE_84MS 0x0002 154#define RTL8366RB_LED_BLINKRATE_111MS 0x0003 155#define RTL8366RB_LED_BLINKRATE_222MS 0x0004 156#define RTL8366RB_LED_BLINKRATE_446MS 0x0005 157 158#define RTL8366RB_LED_CTRL_REG 0x0431 159#define RTL8366RB_LED_OFF 0x0 160#define RTL8366RB_LED_DUP_COL 0x1 161#define RTL8366RB_LED_LINK_ACT 0x2 162#define RTL8366RB_LED_SPD1000 0x3 163#define RTL8366RB_LED_SPD100 0x4 164#define RTL8366RB_LED_SPD10 0x5 165#define RTL8366RB_LED_SPD1000_ACT 0x6 166#define RTL8366RB_LED_SPD100_ACT 0x7 167#define RTL8366RB_LED_SPD10_ACT 0x8 168#define RTL8366RB_LED_SPD100_10_ACT 0x9 169#define RTL8366RB_LED_FIBER 0xa 170#define RTL8366RB_LED_AN_FAULT 0xb 171#define RTL8366RB_LED_LINK_RX 0xc 172#define RTL8366RB_LED_LINK_TX 0xd 173#define RTL8366RB_LED_MASTER 0xe 174#define RTL8366RB_LED_FORCE 0xf 175#define RTL8366RB_LED_0_1_CTRL_REG 0x0432 176#define RTL8366RB_LED_1_OFFSET 6 177#define RTL8366RB_LED_2_3_CTRL_REG 0x0433 178#define RTL8366RB_LED_3_OFFSET 6 179 180#define RTL8366RB_MIB_COUNT 33 181#define RTL8366RB_GLOBAL_MIB_COUNT 1 182#define RTL8366RB_MIB_COUNTER_PORT_OFFSET 0x0050 183#define RTL8366RB_MIB_COUNTER_BASE 0x1000 184#define RTL8366RB_MIB_CTRL_REG 0x13F0 185#define RTL8366RB_MIB_CTRL_USER_MASK 0x0FFC 186#define RTL8366RB_MIB_CTRL_BUSY_MASK BIT(0) 187#define RTL8366RB_MIB_CTRL_RESET_MASK BIT(1) 188#define RTL8366RB_MIB_CTRL_PORT_RESET(_p) BIT(2 + (_p)) 189#define RTL8366RB_MIB_CTRL_GLOBAL_RESET BIT(11) 190 191#define RTL8366RB_PORT_VLAN_CTRL_BASE 0x0063 192#define RTL8366RB_PORT_VLAN_CTRL_REG(_p) \ 193 (RTL8366RB_PORT_VLAN_CTRL_BASE + (_p) / 4) 194#define RTL8366RB_PORT_VLAN_CTRL_MASK 0xf 195#define RTL8366RB_PORT_VLAN_CTRL_SHIFT(_p) (4 * ((_p) % 4)) 196 197#define RTL8366RB_VLAN_TABLE_READ_BASE 0x018C 198#define RTL8366RB_VLAN_TABLE_WRITE_BASE 0x0185 199 200#define RTL8366RB_TABLE_ACCESS_CTRL_REG 0x0180 201#define RTL8366RB_TABLE_VLAN_READ_CTRL 0x0E01 202#define RTL8366RB_TABLE_VLAN_WRITE_CTRL 0x0F01 203 204#define RTL8366RB_VLAN_MC_BASE(_x) (0x0020 + (_x) * 3) 205 206#define RTL8366RB_PORT_LINK_STATUS_BASE 0x0014 207#define RTL8366RB_PORT_STATUS_SPEED_MASK 0x0003 208#define RTL8366RB_PORT_STATUS_DUPLEX_MASK 0x0004 209#define RTL8366RB_PORT_STATUS_LINK_MASK 0x0010 210#define RTL8366RB_PORT_STATUS_TXPAUSE_MASK 0x0020 211#define RTL8366RB_PORT_STATUS_RXPAUSE_MASK 0x0040 212#define RTL8366RB_PORT_STATUS_AN_MASK 0x0080 213 214#define RTL8366RB_NUM_VLANS 16 215#define RTL8366RB_NUM_LEDGROUPS 4 216#define RTL8366RB_NUM_VIDS 4096 217#define RTL8366RB_PRIORITYMAX 7 218#define RTL8366RB_FIDMAX 7 219 220#define RTL8366RB_PORT_1 BIT(0) /* In userspace port 0 */ 221#define RTL8366RB_PORT_2 BIT(1) /* In userspace port 1 */ 222#define RTL8366RB_PORT_3 BIT(2) /* In userspace port 2 */ 223#define RTL8366RB_PORT_4 BIT(3) /* In userspace port 3 */ 224#define RTL8366RB_PORT_5 BIT(4) /* In userspace port 4 */ 225 226#define RTL8366RB_PORT_CPU BIT(5) /* CPU port */ 227 228#define RTL8366RB_PORT_ALL (RTL8366RB_PORT_1 | \ 229 RTL8366RB_PORT_2 | \ 230 RTL8366RB_PORT_3 | \ 231 RTL8366RB_PORT_4 | \ 232 RTL8366RB_PORT_5 | \ 233 RTL8366RB_PORT_CPU) 234 235#define RTL8366RB_PORT_ALL_BUT_CPU (RTL8366RB_PORT_1 | \ 236 RTL8366RB_PORT_2 | \ 237 RTL8366RB_PORT_3 | \ 238 RTL8366RB_PORT_4 | \ 239 RTL8366RB_PORT_5) 240 241#define RTL8366RB_PORT_ALL_EXTERNAL (RTL8366RB_PORT_1 | \ 242 RTL8366RB_PORT_2 | \ 243 RTL8366RB_PORT_3 | \ 244 RTL8366RB_PORT_4) 245 246#define RTL8366RB_PORT_ALL_INTERNAL RTL8366RB_PORT_CPU 247 248/* First configuration word per member config, VID and prio */ 249#define RTL8366RB_VLAN_VID_MASK 0xfff 250#define RTL8366RB_VLAN_PRIORITY_SHIFT 12 251#define RTL8366RB_VLAN_PRIORITY_MASK 0x7 252/* Second configuration word per member config, member and untagged */ 253#define RTL8366RB_VLAN_UNTAG_SHIFT 8 254#define RTL8366RB_VLAN_UNTAG_MASK 0xff 255#define RTL8366RB_VLAN_MEMBER_MASK 0xff 256/* Third config word per member config, STAG currently unused */ 257#define RTL8366RB_VLAN_STAG_MBR_MASK 0xff 258#define RTL8366RB_VLAN_STAG_MBR_SHIFT 8 259#define RTL8366RB_VLAN_STAG_IDX_MASK 0x7 260#define RTL8366RB_VLAN_STAG_IDX_SHIFT 5 261#define RTL8366RB_VLAN_FID_MASK 0x7 262 263/* Port ingress bandwidth control */ 264#define RTL8366RB_IB_BASE 0x0200 265#define RTL8366RB_IB_REG(pnum) (RTL8366RB_IB_BASE + (pnum)) 266#define RTL8366RB_IB_BDTH_MASK 0x3fff 267#define RTL8366RB_IB_PREIFG BIT(14) 268 269/* Port egress bandwidth control */ 270#define RTL8366RB_EB_BASE 0x02d1 271#define RTL8366RB_EB_REG(pnum) (RTL8366RB_EB_BASE + (pnum)) 272#define RTL8366RB_EB_BDTH_MASK 0x3fff 273#define RTL8366RB_EB_PREIFG_REG 0x02f8 274#define RTL8366RB_EB_PREIFG BIT(9) 275 276#define RTL8366RB_BDTH_SW_MAX 1048512 /* 1048576? */ 277#define RTL8366RB_BDTH_UNIT 64 278#define RTL8366RB_BDTH_REG_DEFAULT 16383 279 280/* QOS */ 281#define RTL8366RB_QOS BIT(15) 282/* Include/Exclude Preamble and IFG (20 bytes). 0:Exclude, 1:Include. */ 283#define RTL8366RB_QOS_DEFAULT_PREIFG 1 284 285/* Interrupt handling */ 286#define RTL8366RB_INTERRUPT_CONTROL_REG 0x0440 287#define RTL8366RB_INTERRUPT_POLARITY BIT(0) 288#define RTL8366RB_P4_RGMII_LED BIT(2) 289#define RTL8366RB_INTERRUPT_MASK_REG 0x0441 290#define RTL8366RB_INTERRUPT_LINK_CHGALL GENMASK(11, 0) 291#define RTL8366RB_INTERRUPT_ACLEXCEED BIT(8) 292#define RTL8366RB_INTERRUPT_STORMEXCEED BIT(9) 293#define RTL8366RB_INTERRUPT_P4_FIBER BIT(12) 294#define RTL8366RB_INTERRUPT_P4_UTP BIT(13) 295#define RTL8366RB_INTERRUPT_VALID (RTL8366RB_INTERRUPT_LINK_CHGALL | \ 296 RTL8366RB_INTERRUPT_ACLEXCEED | \ 297 RTL8366RB_INTERRUPT_STORMEXCEED | \ 298 RTL8366RB_INTERRUPT_P4_FIBER | \ 299 RTL8366RB_INTERRUPT_P4_UTP) 300#define RTL8366RB_INTERRUPT_STATUS_REG 0x0442 301#define RTL8366RB_NUM_INTERRUPT 14 /* 0..13 */ 302 303/* bits 0..5 enable force when cleared */ 304#define RTL8366RB_MAC_FORCE_CTRL_REG 0x0F11 305 306#define RTL8366RB_OAM_PARSER_REG 0x0F14 307#define RTL8366RB_OAM_MULTIPLEXER_REG 0x0F15 308 309#define RTL8366RB_GREEN_FEATURE_REG 0x0F51 310#define RTL8366RB_GREEN_FEATURE_MSK 0x0007 311#define RTL8366RB_GREEN_FEATURE_TX BIT(0) 312#define RTL8366RB_GREEN_FEATURE_RX BIT(2) 313 314/** 315 * struct rtl8366rb - RTL8366RB-specific data 316 * @max_mtu: per-port max MTU setting 317 */ 318struct rtl8366rb { 319 unsigned int max_mtu[RTL8366RB_NUM_PORTS]; 320}; 321 322static struct rtl8366_mib_counter rtl8366rb_mib_counters[] = { 323 { 0, 0, 4, "IfInOctets" }, 324 { 0, 4, 4, "EtherStatsOctets" }, 325 { 0, 8, 2, "EtherStatsUnderSizePkts" }, 326 { 0, 10, 2, "EtherFragments" }, 327 { 0, 12, 2, "EtherStatsPkts64Octets" }, 328 { 0, 14, 2, "EtherStatsPkts65to127Octets" }, 329 { 0, 16, 2, "EtherStatsPkts128to255Octets" }, 330 { 0, 18, 2, "EtherStatsPkts256to511Octets" }, 331 { 0, 20, 2, "EtherStatsPkts512to1023Octets" }, 332 { 0, 22, 2, "EtherStatsPkts1024to1518Octets" }, 333 { 0, 24, 2, "EtherOversizeStats" }, 334 { 0, 26, 2, "EtherStatsJabbers" }, 335 { 0, 28, 2, "IfInUcastPkts" }, 336 { 0, 30, 2, "EtherStatsMulticastPkts" }, 337 { 0, 32, 2, "EtherStatsBroadcastPkts" }, 338 { 0, 34, 2, "EtherStatsDropEvents" }, 339 { 0, 36, 2, "Dot3StatsFCSErrors" }, 340 { 0, 38, 2, "Dot3StatsSymbolErrors" }, 341 { 0, 40, 2, "Dot3InPauseFrames" }, 342 { 0, 42, 2, "Dot3ControlInUnknownOpcodes" }, 343 { 0, 44, 4, "IfOutOctets" }, 344 { 0, 48, 2, "Dot3StatsSingleCollisionFrames" }, 345 { 0, 50, 2, "Dot3StatMultipleCollisionFrames" }, 346 { 0, 52, 2, "Dot3sDeferredTransmissions" }, 347 { 0, 54, 2, "Dot3StatsLateCollisions" }, 348 { 0, 56, 2, "EtherStatsCollisions" }, 349 { 0, 58, 2, "Dot3StatsExcessiveCollisions" }, 350 { 0, 60, 2, "Dot3OutPauseFrames" }, 351 { 0, 62, 2, "Dot1dBasePortDelayExceededDiscards" }, 352 { 0, 64, 2, "Dot1dTpPortInDiscards" }, 353 { 0, 66, 2, "IfOutUcastPkts" }, 354 { 0, 68, 2, "IfOutMulticastPkts" }, 355 { 0, 70, 2, "IfOutBroadcastPkts" }, 356}; 357 358static int rtl8366rb_get_mib_counter(struct realtek_smi *smi, 359 int port, 360 struct rtl8366_mib_counter *mib, 361 u64 *mibvalue) 362{ 363 u32 addr, val; 364 int ret; 365 int i; 366 367 addr = RTL8366RB_MIB_COUNTER_BASE + 368 RTL8366RB_MIB_COUNTER_PORT_OFFSET * (port) + 369 mib->offset; 370 371 /* Writing access counter address first 372 * then ASIC will prepare 64bits counter wait for being retrived 373 */ 374 ret = regmap_write(smi->map, addr, 0); /* Write whatever */ 375 if (ret) 376 return ret; 377 378 /* Read MIB control register */ 379 ret = regmap_read(smi->map, RTL8366RB_MIB_CTRL_REG, &val); 380 if (ret) 381 return -EIO; 382 383 if (val & RTL8366RB_MIB_CTRL_BUSY_MASK) 384 return -EBUSY; 385 386 if (val & RTL8366RB_MIB_CTRL_RESET_MASK) 387 return -EIO; 388 389 /* Read each individual MIB 16 bits at the time */ 390 *mibvalue = 0; 391 for (i = mib->length; i > 0; i--) { 392 ret = regmap_read(smi->map, addr + (i - 1), &val); 393 if (ret) 394 return ret; 395 *mibvalue = (*mibvalue << 16) | (val & 0xFFFF); 396 } 397 return 0; 398} 399 400static u32 rtl8366rb_get_irqmask(struct irq_data *d) 401{ 402 int line = irqd_to_hwirq(d); 403 u32 val; 404 405 /* For line interrupts we combine link down in bits 406 * 6..11 with link up in bits 0..5 into one interrupt. 407 */ 408 if (line < 12) 409 val = BIT(line) | BIT(line + 6); 410 else 411 val = BIT(line); 412 return val; 413} 414 415static void rtl8366rb_mask_irq(struct irq_data *d) 416{ 417 struct realtek_smi *smi = irq_data_get_irq_chip_data(d); 418 int ret; 419 420 ret = regmap_update_bits(smi->map, RTL8366RB_INTERRUPT_MASK_REG, 421 rtl8366rb_get_irqmask(d), 0); 422 if (ret) 423 dev_err(smi->dev, "could not mask IRQ\n"); 424} 425 426static void rtl8366rb_unmask_irq(struct irq_data *d) 427{ 428 struct realtek_smi *smi = irq_data_get_irq_chip_data(d); 429 int ret; 430 431 ret = regmap_update_bits(smi->map, RTL8366RB_INTERRUPT_MASK_REG, 432 rtl8366rb_get_irqmask(d), 433 rtl8366rb_get_irqmask(d)); 434 if (ret) 435 dev_err(smi->dev, "could not unmask IRQ\n"); 436} 437 438static irqreturn_t rtl8366rb_irq(int irq, void *data) 439{ 440 struct realtek_smi *smi = data; 441 u32 stat; 442 int ret; 443 444 /* This clears the IRQ status register */ 445 ret = regmap_read(smi->map, RTL8366RB_INTERRUPT_STATUS_REG, 446 &stat); 447 if (ret) { 448 dev_err(smi->dev, "can't read interrupt status\n"); 449 return IRQ_NONE; 450 } 451 stat &= RTL8366RB_INTERRUPT_VALID; 452 if (!stat) 453 return IRQ_NONE; 454 while (stat) { 455 int line = __ffs(stat); 456 int child_irq; 457 458 stat &= ~BIT(line); 459 /* For line interrupts we combine link down in bits 460 * 6..11 with link up in bits 0..5 into one interrupt. 461 */ 462 if (line < 12 && line > 5) 463 line -= 5; 464 child_irq = irq_find_mapping(smi->irqdomain, line); 465 handle_nested_irq(child_irq); 466 } 467 return IRQ_HANDLED; 468} 469 470static struct irq_chip rtl8366rb_irq_chip = { 471 .name = "RTL8366RB", 472 .irq_mask = rtl8366rb_mask_irq, 473 .irq_unmask = rtl8366rb_unmask_irq, 474}; 475 476static int rtl8366rb_irq_map(struct irq_domain *domain, unsigned int irq, 477 irq_hw_number_t hwirq) 478{ 479 irq_set_chip_data(irq, domain->host_data); 480 irq_set_chip_and_handler(irq, &rtl8366rb_irq_chip, handle_simple_irq); 481 irq_set_nested_thread(irq, 1); 482 irq_set_noprobe(irq); 483 484 return 0; 485} 486 487static void rtl8366rb_irq_unmap(struct irq_domain *d, unsigned int irq) 488{ 489 irq_set_nested_thread(irq, 0); 490 irq_set_chip_and_handler(irq, NULL, NULL); 491 irq_set_chip_data(irq, NULL); 492} 493 494static const struct irq_domain_ops rtl8366rb_irqdomain_ops = { 495 .map = rtl8366rb_irq_map, 496 .unmap = rtl8366rb_irq_unmap, 497 .xlate = irq_domain_xlate_onecell, 498}; 499 500static int rtl8366rb_setup_cascaded_irq(struct realtek_smi *smi) 501{ 502 struct device_node *intc; 503 unsigned long irq_trig; 504 int irq; 505 int ret; 506 u32 val; 507 int i; 508 509 intc = of_get_child_by_name(smi->dev->of_node, "interrupt-controller"); 510 if (!intc) { 511 dev_err(smi->dev, "missing child interrupt-controller node\n"); 512 return -EINVAL; 513 } 514 /* RB8366RB IRQs cascade off this one */ 515 irq = of_irq_get(intc, 0); 516 if (irq <= 0) { 517 dev_err(smi->dev, "failed to get parent IRQ\n"); 518 ret = irq ? irq : -EINVAL; 519 goto out_put_node; 520 } 521 522 /* This clears the IRQ status register */ 523 ret = regmap_read(smi->map, RTL8366RB_INTERRUPT_STATUS_REG, 524 &val); 525 if (ret) { 526 dev_err(smi->dev, "can't read interrupt status\n"); 527 goto out_put_node; 528 } 529 530 /* Fetch IRQ edge information from the descriptor */ 531 irq_trig = irqd_get_trigger_type(irq_get_irq_data(irq)); 532 switch (irq_trig) { 533 case IRQF_TRIGGER_RISING: 534 case IRQF_TRIGGER_HIGH: 535 dev_info(smi->dev, "active high/rising IRQ\n"); 536 val = 0; 537 break; 538 case IRQF_TRIGGER_FALLING: 539 case IRQF_TRIGGER_LOW: 540 dev_info(smi->dev, "active low/falling IRQ\n"); 541 val = RTL8366RB_INTERRUPT_POLARITY; 542 break; 543 } 544 ret = regmap_update_bits(smi->map, RTL8366RB_INTERRUPT_CONTROL_REG, 545 RTL8366RB_INTERRUPT_POLARITY, 546 val); 547 if (ret) { 548 dev_err(smi->dev, "could not configure IRQ polarity\n"); 549 goto out_put_node; 550 } 551 552 ret = devm_request_threaded_irq(smi->dev, irq, NULL, 553 rtl8366rb_irq, IRQF_ONESHOT, 554 "RTL8366RB", smi); 555 if (ret) { 556 dev_err(smi->dev, "unable to request irq: %d\n", ret); 557 goto out_put_node; 558 } 559 smi->irqdomain = irq_domain_add_linear(intc, 560 RTL8366RB_NUM_INTERRUPT, 561 &rtl8366rb_irqdomain_ops, 562 smi); 563 if (!smi->irqdomain) { 564 dev_err(smi->dev, "failed to create IRQ domain\n"); 565 ret = -EINVAL; 566 goto out_put_node; 567 } 568 for (i = 0; i < smi->num_ports; i++) 569 irq_set_parent(irq_create_mapping(smi->irqdomain, i), irq); 570 571out_put_node: 572 of_node_put(intc); 573 return ret; 574} 575 576static int rtl8366rb_set_addr(struct realtek_smi *smi) 577{ 578 u8 addr[ETH_ALEN]; 579 u16 val; 580 int ret; 581 582 eth_random_addr(addr); 583 584 dev_info(smi->dev, "set MAC: %02X:%02X:%02X:%02X:%02X:%02X\n", 585 addr[0], addr[1], addr[2], addr[3], addr[4], addr[5]); 586 val = addr[0] << 8 | addr[1]; 587 ret = regmap_write(smi->map, RTL8366RB_SMAR0, val); 588 if (ret) 589 return ret; 590 val = addr[2] << 8 | addr[3]; 591 ret = regmap_write(smi->map, RTL8366RB_SMAR1, val); 592 if (ret) 593 return ret; 594 val = addr[4] << 8 | addr[5]; 595 ret = regmap_write(smi->map, RTL8366RB_SMAR2, val); 596 if (ret) 597 return ret; 598 599 return 0; 600} 601 602/* Found in a vendor driver */ 603 604/* Struct for handling the jam tables' entries */ 605struct rtl8366rb_jam_tbl_entry { 606 u16 reg; 607 u16 val; 608}; 609 610/* For the "version 0" early silicon, appear in most source releases */ 611static const struct rtl8366rb_jam_tbl_entry rtl8366rb_init_jam_ver_0[] = { 612 {0x000B, 0x0001}, {0x03A6, 0x0100}, {0x03A7, 0x0001}, {0x02D1, 0x3FFF}, 613 {0x02D2, 0x3FFF}, {0x02D3, 0x3FFF}, {0x02D4, 0x3FFF}, {0x02D5, 0x3FFF}, 614 {0x02D6, 0x3FFF}, {0x02D7, 0x3FFF}, {0x02D8, 0x3FFF}, {0x022B, 0x0688}, 615 {0x022C, 0x0FAC}, {0x03D0, 0x4688}, {0x03D1, 0x01F5}, {0x0000, 0x0830}, 616 {0x02F9, 0x0200}, {0x02F7, 0x7FFF}, {0x02F8, 0x03FF}, {0x0080, 0x03E8}, 617 {0x0081, 0x00CE}, {0x0082, 0x00DA}, {0x0083, 0x0230}, {0xBE0F, 0x2000}, 618 {0x0231, 0x422A}, {0x0232, 0x422A}, {0x0233, 0x422A}, {0x0234, 0x422A}, 619 {0x0235, 0x422A}, {0x0236, 0x422A}, {0x0237, 0x422A}, {0x0238, 0x422A}, 620 {0x0239, 0x422A}, {0x023A, 0x422A}, {0x023B, 0x422A}, {0x023C, 0x422A}, 621 {0x023D, 0x422A}, {0x023E, 0x422A}, {0x023F, 0x422A}, {0x0240, 0x422A}, 622 {0x0241, 0x422A}, {0x0242, 0x422A}, {0x0243, 0x422A}, {0x0244, 0x422A}, 623 {0x0245, 0x422A}, {0x0246, 0x422A}, {0x0247, 0x422A}, {0x0248, 0x422A}, 624 {0x0249, 0x0146}, {0x024A, 0x0146}, {0x024B, 0x0146}, {0xBE03, 0xC961}, 625 {0x024D, 0x0146}, {0x024E, 0x0146}, {0x024F, 0x0146}, {0x0250, 0x0146}, 626 {0xBE64, 0x0226}, {0x0252, 0x0146}, {0x0253, 0x0146}, {0x024C, 0x0146}, 627 {0x0251, 0x0146}, {0x0254, 0x0146}, {0xBE62, 0x3FD0}, {0x0084, 0x0320}, 628 {0x0255, 0x0146}, {0x0256, 0x0146}, {0x0257, 0x0146}, {0x0258, 0x0146}, 629 {0x0259, 0x0146}, {0x025A, 0x0146}, {0x025B, 0x0146}, {0x025C, 0x0146}, 630 {0x025D, 0x0146}, {0x025E, 0x0146}, {0x025F, 0x0146}, {0x0260, 0x0146}, 631 {0x0261, 0xA23F}, {0x0262, 0x0294}, {0x0263, 0xA23F}, {0x0264, 0x0294}, 632 {0x0265, 0xA23F}, {0x0266, 0x0294}, {0x0267, 0xA23F}, {0x0268, 0x0294}, 633 {0x0269, 0xA23F}, {0x026A, 0x0294}, {0x026B, 0xA23F}, {0x026C, 0x0294}, 634 {0x026D, 0xA23F}, {0x026E, 0x0294}, {0x026F, 0xA23F}, {0x0270, 0x0294}, 635 {0x02F5, 0x0048}, {0xBE09, 0x0E00}, {0xBE1E, 0x0FA0}, {0xBE14, 0x8448}, 636 {0xBE15, 0x1007}, {0xBE4A, 0xA284}, {0xC454, 0x3F0B}, {0xC474, 0x3F0B}, 637 {0xBE48, 0x3672}, {0xBE4B, 0x17A7}, {0xBE4C, 0x0B15}, {0xBE52, 0x0EDD}, 638 {0xBE49, 0x8C00}, {0xBE5B, 0x785C}, {0xBE5C, 0x785C}, {0xBE5D, 0x785C}, 639 {0xBE61, 0x368A}, {0xBE63, 0x9B84}, {0xC456, 0xCC13}, {0xC476, 0xCC13}, 640 {0xBE65, 0x307D}, {0xBE6D, 0x0005}, {0xBE6E, 0xE120}, {0xBE2E, 0x7BAF}, 641}; 642 643/* This v1 init sequence is from Belkin F5D8235 U-Boot release */ 644static const struct rtl8366rb_jam_tbl_entry rtl8366rb_init_jam_ver_1[] = { 645 {0x0000, 0x0830}, {0x0001, 0x8000}, {0x0400, 0x8130}, {0xBE78, 0x3C3C}, 646 {0x0431, 0x5432}, {0xBE37, 0x0CE4}, {0x02FA, 0xFFDF}, {0x02FB, 0xFFE0}, 647 {0xC44C, 0x1585}, {0xC44C, 0x1185}, {0xC44C, 0x1585}, {0xC46C, 0x1585}, 648 {0xC46C, 0x1185}, {0xC46C, 0x1585}, {0xC451, 0x2135}, {0xC471, 0x2135}, 649 {0xBE10, 0x8140}, {0xBE15, 0x0007}, {0xBE6E, 0xE120}, {0xBE69, 0xD20F}, 650 {0xBE6B, 0x0320}, {0xBE24, 0xB000}, {0xBE23, 0xFF51}, {0xBE22, 0xDF20}, 651 {0xBE21, 0x0140}, {0xBE20, 0x00BB}, {0xBE24, 0xB800}, {0xBE24, 0x0000}, 652 {0xBE24, 0x7000}, {0xBE23, 0xFF51}, {0xBE22, 0xDF60}, {0xBE21, 0x0140}, 653 {0xBE20, 0x0077}, {0xBE24, 0x7800}, {0xBE24, 0x0000}, {0xBE2E, 0x7B7A}, 654 {0xBE36, 0x0CE4}, {0x02F5, 0x0048}, {0xBE77, 0x2940}, {0x000A, 0x83E0}, 655 {0xBE79, 0x3C3C}, {0xBE00, 0x1340}, 656}; 657 658/* This v2 init sequence is from Belkin F5D8235 U-Boot release */ 659static const struct rtl8366rb_jam_tbl_entry rtl8366rb_init_jam_ver_2[] = { 660 {0x0450, 0x0000}, {0x0400, 0x8130}, {0x000A, 0x83ED}, {0x0431, 0x5432}, 661 {0xC44F, 0x6250}, {0xC46F, 0x6250}, {0xC456, 0x0C14}, {0xC476, 0x0C14}, 662 {0xC44C, 0x1C85}, {0xC44C, 0x1885}, {0xC44C, 0x1C85}, {0xC46C, 0x1C85}, 663 {0xC46C, 0x1885}, {0xC46C, 0x1C85}, {0xC44C, 0x0885}, {0xC44C, 0x0881}, 664 {0xC44C, 0x0885}, {0xC46C, 0x0885}, {0xC46C, 0x0881}, {0xC46C, 0x0885}, 665 {0xBE2E, 0x7BA7}, {0xBE36, 0x1000}, {0xBE37, 0x1000}, {0x8000, 0x0001}, 666 {0xBE69, 0xD50F}, {0x8000, 0x0000}, {0xBE69, 0xD50F}, {0xBE6E, 0x0320}, 667 {0xBE77, 0x2940}, {0xBE78, 0x3C3C}, {0xBE79, 0x3C3C}, {0xBE6E, 0xE120}, 668 {0x8000, 0x0001}, {0xBE15, 0x1007}, {0x8000, 0x0000}, {0xBE15, 0x1007}, 669 {0xBE14, 0x0448}, {0xBE1E, 0x00A0}, {0xBE10, 0x8160}, {0xBE10, 0x8140}, 670 {0xBE00, 0x1340}, {0x0F51, 0x0010}, 671}; 672 673/* Appears in a DDWRT code dump */ 674static const struct rtl8366rb_jam_tbl_entry rtl8366rb_init_jam_ver_3[] = { 675 {0x0000, 0x0830}, {0x0400, 0x8130}, {0x000A, 0x83ED}, {0x0431, 0x5432}, 676 {0x0F51, 0x0017}, {0x02F5, 0x0048}, {0x02FA, 0xFFDF}, {0x02FB, 0xFFE0}, 677 {0xC456, 0x0C14}, {0xC476, 0x0C14}, {0xC454, 0x3F8B}, {0xC474, 0x3F8B}, 678 {0xC450, 0x2071}, {0xC470, 0x2071}, {0xC451, 0x226B}, {0xC471, 0x226B}, 679 {0xC452, 0xA293}, {0xC472, 0xA293}, {0xC44C, 0x1585}, {0xC44C, 0x1185}, 680 {0xC44C, 0x1585}, {0xC46C, 0x1585}, {0xC46C, 0x1185}, {0xC46C, 0x1585}, 681 {0xC44C, 0x0185}, {0xC44C, 0x0181}, {0xC44C, 0x0185}, {0xC46C, 0x0185}, 682 {0xC46C, 0x0181}, {0xC46C, 0x0185}, {0xBE24, 0xB000}, {0xBE23, 0xFF51}, 683 {0xBE22, 0xDF20}, {0xBE21, 0x0140}, {0xBE20, 0x00BB}, {0xBE24, 0xB800}, 684 {0xBE24, 0x0000}, {0xBE24, 0x7000}, {0xBE23, 0xFF51}, {0xBE22, 0xDF60}, 685 {0xBE21, 0x0140}, {0xBE20, 0x0077}, {0xBE24, 0x7800}, {0xBE24, 0x0000}, 686 {0xBE2E, 0x7BA7}, {0xBE36, 0x1000}, {0xBE37, 0x1000}, {0x8000, 0x0001}, 687 {0xBE69, 0xD50F}, {0x8000, 0x0000}, {0xBE69, 0xD50F}, {0xBE6B, 0x0320}, 688 {0xBE77, 0x2800}, {0xBE78, 0x3C3C}, {0xBE79, 0x3C3C}, {0xBE6E, 0xE120}, 689 {0x8000, 0x0001}, {0xBE10, 0x8140}, {0x8000, 0x0000}, {0xBE10, 0x8140}, 690 {0xBE15, 0x1007}, {0xBE14, 0x0448}, {0xBE1E, 0x00A0}, {0xBE10, 0x8160}, 691 {0xBE10, 0x8140}, {0xBE00, 0x1340}, {0x0450, 0x0000}, {0x0401, 0x0000}, 692}; 693 694/* Belkin F5D8235 v1, "belkin,f5d8235-v1" */ 695static const struct rtl8366rb_jam_tbl_entry rtl8366rb_init_jam_f5d8235[] = { 696 {0x0242, 0x02BF}, {0x0245, 0x02BF}, {0x0248, 0x02BF}, {0x024B, 0x02BF}, 697 {0x024E, 0x02BF}, {0x0251, 0x02BF}, {0x0254, 0x0A3F}, {0x0256, 0x0A3F}, 698 {0x0258, 0x0A3F}, {0x025A, 0x0A3F}, {0x025C, 0x0A3F}, {0x025E, 0x0A3F}, 699 {0x0263, 0x007C}, {0x0100, 0x0004}, {0xBE5B, 0x3500}, {0x800E, 0x200F}, 700 {0xBE1D, 0x0F00}, {0x8001, 0x5011}, {0x800A, 0xA2F4}, {0x800B, 0x17A3}, 701 {0xBE4B, 0x17A3}, {0xBE41, 0x5011}, {0xBE17, 0x2100}, {0x8000, 0x8304}, 702 {0xBE40, 0x8304}, {0xBE4A, 0xA2F4}, {0x800C, 0xA8D5}, {0x8014, 0x5500}, 703 {0x8015, 0x0004}, {0xBE4C, 0xA8D5}, {0xBE59, 0x0008}, {0xBE09, 0x0E00}, 704 {0xBE36, 0x1036}, {0xBE37, 0x1036}, {0x800D, 0x00FF}, {0xBE4D, 0x00FF}, 705}; 706 707/* DGN3500, "netgear,dgn3500", "netgear,dgn3500b" */ 708static const struct rtl8366rb_jam_tbl_entry rtl8366rb_init_jam_dgn3500[] = { 709 {0x0000, 0x0830}, {0x0400, 0x8130}, {0x000A, 0x83ED}, {0x0F51, 0x0017}, 710 {0x02F5, 0x0048}, {0x02FA, 0xFFDF}, {0x02FB, 0xFFE0}, {0x0450, 0x0000}, 711 {0x0401, 0x0000}, {0x0431, 0x0960}, 712}; 713 714/* This jam table activates "green ethernet", which means low power mode 715 * and is claimed to detect the cable length and not use more power than 716 * necessary, and the ports should enter power saving mode 10 seconds after 717 * a cable is disconnected. Seems to always be the same. 718 */ 719static const struct rtl8366rb_jam_tbl_entry rtl8366rb_green_jam[] = { 720 {0xBE78, 0x323C}, {0xBE77, 0x5000}, {0xBE2E, 0x7BA7}, 721 {0xBE59, 0x3459}, {0xBE5A, 0x745A}, {0xBE5B, 0x785C}, 722 {0xBE5C, 0x785C}, {0xBE6E, 0xE120}, {0xBE79, 0x323C}, 723}; 724 725/* Function that jams the tables in the proper registers */ 726static int rtl8366rb_jam_table(const struct rtl8366rb_jam_tbl_entry *jam_table, 727 int jam_size, struct realtek_smi *smi, 728 bool write_dbg) 729{ 730 u32 val; 731 int ret; 732 int i; 733 734 for (i = 0; i < jam_size; i++) { 735 if ((jam_table[i].reg & 0xBE00) == 0xBE00) { 736 ret = regmap_read(smi->map, 737 RTL8366RB_PHY_ACCESS_BUSY_REG, 738 &val); 739 if (ret) 740 return ret; 741 if (!(val & RTL8366RB_PHY_INT_BUSY)) { 742 ret = regmap_write(smi->map, 743 RTL8366RB_PHY_ACCESS_CTRL_REG, 744 RTL8366RB_PHY_CTRL_WRITE); 745 if (ret) 746 return ret; 747 } 748 } 749 if (write_dbg) 750 dev_dbg(smi->dev, "jam %04x into register %04x\n", 751 jam_table[i].val, 752 jam_table[i].reg); 753 ret = regmap_write(smi->map, 754 jam_table[i].reg, 755 jam_table[i].val); 756 if (ret) 757 return ret; 758 } 759 return 0; 760} 761 762static int rtl8366rb_setup(struct dsa_switch *ds) 763{ 764 struct realtek_smi *smi = ds->priv; 765 const struct rtl8366rb_jam_tbl_entry *jam_table; 766 struct rtl8366rb *rb; 767 u32 chip_ver = 0; 768 u32 chip_id = 0; 769 int jam_size; 770 u32 val; 771 int ret; 772 int i; 773 774 rb = smi->chip_data; 775 776 ret = regmap_read(smi->map, RTL8366RB_CHIP_ID_REG, &chip_id); 777 if (ret) { 778 dev_err(smi->dev, "unable to read chip id\n"); 779 return ret; 780 } 781 782 switch (chip_id) { 783 case RTL8366RB_CHIP_ID_8366: 784 break; 785 default: 786 dev_err(smi->dev, "unknown chip id (%04x)\n", chip_id); 787 return -ENODEV; 788 } 789 790 ret = regmap_read(smi->map, RTL8366RB_CHIP_VERSION_CTRL_REG, 791 &chip_ver); 792 if (ret) { 793 dev_err(smi->dev, "unable to read chip version\n"); 794 return ret; 795 } 796 797 dev_info(smi->dev, "RTL%04x ver %u chip found\n", 798 chip_id, chip_ver & RTL8366RB_CHIP_VERSION_MASK); 799 800 /* Do the init dance using the right jam table */ 801 switch (chip_ver) { 802 case 0: 803 jam_table = rtl8366rb_init_jam_ver_0; 804 jam_size = ARRAY_SIZE(rtl8366rb_init_jam_ver_0); 805 break; 806 case 1: 807 jam_table = rtl8366rb_init_jam_ver_1; 808 jam_size = ARRAY_SIZE(rtl8366rb_init_jam_ver_1); 809 break; 810 case 2: 811 jam_table = rtl8366rb_init_jam_ver_2; 812 jam_size = ARRAY_SIZE(rtl8366rb_init_jam_ver_2); 813 break; 814 default: 815 jam_table = rtl8366rb_init_jam_ver_3; 816 jam_size = ARRAY_SIZE(rtl8366rb_init_jam_ver_3); 817 break; 818 } 819 820 /* Special jam tables for special routers 821 * TODO: are these necessary? Maintainers, please test 822 * without them, using just the off-the-shelf tables. 823 */ 824 if (of_machine_is_compatible("belkin,f5d8235-v1")) { 825 jam_table = rtl8366rb_init_jam_f5d8235; 826 jam_size = ARRAY_SIZE(rtl8366rb_init_jam_f5d8235); 827 } 828 if (of_machine_is_compatible("netgear,dgn3500") || 829 of_machine_is_compatible("netgear,dgn3500b")) { 830 jam_table = rtl8366rb_init_jam_dgn3500; 831 jam_size = ARRAY_SIZE(rtl8366rb_init_jam_dgn3500); 832 } 833 834 ret = rtl8366rb_jam_table(jam_table, jam_size, smi, true); 835 if (ret) 836 return ret; 837 838 /* Set up the "green ethernet" feature */ 839 ret = rtl8366rb_jam_table(rtl8366rb_green_jam, 840 ARRAY_SIZE(rtl8366rb_green_jam), smi, false); 841 if (ret) 842 return ret; 843 844 ret = regmap_write(smi->map, 845 RTL8366RB_GREEN_FEATURE_REG, 846 (chip_ver == 1) ? 0x0007 : 0x0003); 847 if (ret) 848 return ret; 849 850 /* Vendor driver sets 0x240 in registers 0xc and 0xd (undocumented) */ 851 ret = regmap_write(smi->map, 0x0c, 0x240); 852 if (ret) 853 return ret; 854 ret = regmap_write(smi->map, 0x0d, 0x240); 855 if (ret) 856 return ret; 857 858 /* Set some random MAC address */ 859 ret = rtl8366rb_set_addr(smi); 860 if (ret) 861 return ret; 862 863 /* Enable CPU port with custom DSA tag 8899. 864 * 865 * If you set RTL8368RB_CPU_NO_TAG (bit 15) in this registers 866 * the custom tag is turned off. 867 */ 868 ret = regmap_update_bits(smi->map, RTL8368RB_CPU_CTRL_REG, 869 0xFFFF, 870 BIT(smi->cpu_port)); 871 if (ret) 872 return ret; 873 874 /* Make sure we default-enable the fixed CPU port */ 875 ret = regmap_update_bits(smi->map, RTL8366RB_PECR, 876 BIT(smi->cpu_port), 877 0); 878 if (ret) 879 return ret; 880 881 /* Set maximum packet length to 1536 bytes */ 882 ret = regmap_update_bits(smi->map, RTL8366RB_SGCR, 883 RTL8366RB_SGCR_MAX_LENGTH_MASK, 884 RTL8366RB_SGCR_MAX_LENGTH_1536); 885 if (ret) 886 return ret; 887 for (i = 0; i < RTL8366RB_NUM_PORTS; i++) 888 /* layer 2 size, see rtl8366rb_change_mtu() */ 889 rb->max_mtu[i] = 1532; 890 891 /* Enable learning for all ports */ 892 ret = regmap_write(smi->map, RTL8366RB_SSCR0, 0); 893 if (ret) 894 return ret; 895 896 /* Enable auto ageing for all ports */ 897 ret = regmap_write(smi->map, RTL8366RB_SSCR1, 0); 898 if (ret) 899 return ret; 900 901 /* Port 4 setup: this enables Port 4, usually the WAN port, 902 * common PHY IO mode is apparently mode 0, and this is not what 903 * the port is initialized to. There is no explanation of the 904 * IO modes in the Realtek source code, if your WAN port is 905 * connected to something exotic such as fiber, then this might 906 * be worth experimenting with. 907 */ 908 ret = regmap_update_bits(smi->map, RTL8366RB_PMC0, 909 RTL8366RB_PMC0_P4_IOMODE_MASK, 910 0 << RTL8366RB_PMC0_P4_IOMODE_SHIFT); 911 if (ret) 912 return ret; 913 914 /* Discard VLAN tagged packets if the port is not a member of 915 * the VLAN with which the packets is associated. 916 */ 917 ret = regmap_write(smi->map, RTL8366RB_VLAN_INGRESS_CTRL2_REG, 918 RTL8366RB_PORT_ALL); 919 if (ret) 920 return ret; 921 922 /* Don't drop packets whose DA has not been learned */ 923 ret = regmap_update_bits(smi->map, RTL8366RB_SSCR2, 924 RTL8366RB_SSCR2_DROP_UNKNOWN_DA, 0); 925 if (ret) 926 return ret; 927 928 /* Set blinking, TODO: make this configurable */ 929 ret = regmap_update_bits(smi->map, RTL8366RB_LED_BLINKRATE_REG, 930 RTL8366RB_LED_BLINKRATE_MASK, 931 RTL8366RB_LED_BLINKRATE_56MS); 932 if (ret) 933 return ret; 934 935 /* Set up LED activity: 936 * Each port has 4 LEDs, we configure all ports to the same 937 * behaviour (no individual config) but we can set up each 938 * LED separately. 939 */ 940 if (smi->leds_disabled) { 941 /* Turn everything off */ 942 regmap_update_bits(smi->map, 943 RTL8366RB_LED_0_1_CTRL_REG, 944 0x0FFF, 0); 945 regmap_update_bits(smi->map, 946 RTL8366RB_LED_2_3_CTRL_REG, 947 0x0FFF, 0); 948 regmap_update_bits(smi->map, 949 RTL8366RB_INTERRUPT_CONTROL_REG, 950 RTL8366RB_P4_RGMII_LED, 951 0); 952 val = RTL8366RB_LED_OFF; 953 } else { 954 /* TODO: make this configurable per LED */ 955 val = RTL8366RB_LED_FORCE; 956 } 957 for (i = 0; i < 4; i++) { 958 ret = regmap_update_bits(smi->map, 959 RTL8366RB_LED_CTRL_REG, 960 0xf << (i * 4), 961 val << (i * 4)); 962 if (ret) 963 return ret; 964 } 965 966 ret = rtl8366_init_vlan(smi); 967 if (ret) 968 return ret; 969 970 ret = rtl8366rb_setup_cascaded_irq(smi); 971 if (ret) 972 dev_info(smi->dev, "no interrupt support\n"); 973 974 ret = realtek_smi_setup_mdio(smi); 975 if (ret) { 976 dev_info(smi->dev, "could not set up MDIO bus\n"); 977 return -ENODEV; 978 } 979 980 ds->configure_vlan_while_not_filtering = false; 981 982 return 0; 983} 984 985static enum dsa_tag_protocol rtl8366_get_tag_protocol(struct dsa_switch *ds, 986 int port, 987 enum dsa_tag_protocol mp) 988{ 989 /* This switch uses the 4 byte protocol A Realtek DSA tag */ 990 return DSA_TAG_PROTO_RTL4_A; 991} 992 993static void 994rtl8366rb_mac_link_up(struct dsa_switch *ds, int port, unsigned int mode, 995 phy_interface_t interface, struct phy_device *phydev, 996 int speed, int duplex, bool tx_pause, bool rx_pause) 997{ 998 struct realtek_smi *smi = ds->priv; 999 int ret; 1000 1001 if (port != smi->cpu_port) 1002 return; 1003 1004 dev_dbg(smi->dev, "MAC link up on CPU port (%d)\n", port); 1005 1006 /* Force the fixed CPU port into 1Gbit mode, no autonegotiation */ 1007 ret = regmap_update_bits(smi->map, RTL8366RB_MAC_FORCE_CTRL_REG, 1008 BIT(port), BIT(port)); 1009 if (ret) { 1010 dev_err(smi->dev, "failed to force 1Gbit on CPU port\n"); 1011 return; 1012 } 1013 1014 ret = regmap_update_bits(smi->map, RTL8366RB_PAACR2, 1015 0xFF00U, 1016 RTL8366RB_PAACR_CPU_PORT << 8); 1017 if (ret) { 1018 dev_err(smi->dev, "failed to set PAACR on CPU port\n"); 1019 return; 1020 } 1021 1022 /* Enable the CPU port */ 1023 ret = regmap_update_bits(smi->map, RTL8366RB_PECR, BIT(port), 1024 0); 1025 if (ret) { 1026 dev_err(smi->dev, "failed to enable the CPU port\n"); 1027 return; 1028 } 1029} 1030 1031static void 1032rtl8366rb_mac_link_down(struct dsa_switch *ds, int port, unsigned int mode, 1033 phy_interface_t interface) 1034{ 1035 struct realtek_smi *smi = ds->priv; 1036 int ret; 1037 1038 if (port != smi->cpu_port) 1039 return; 1040 1041 dev_dbg(smi->dev, "MAC link down on CPU port (%d)\n", port); 1042 1043 /* Disable the CPU port */ 1044 ret = regmap_update_bits(smi->map, RTL8366RB_PECR, BIT(port), 1045 BIT(port)); 1046 if (ret) { 1047 dev_err(smi->dev, "failed to disable the CPU port\n"); 1048 return; 1049 } 1050} 1051 1052static void rb8366rb_set_port_led(struct realtek_smi *smi, 1053 int port, bool enable) 1054{ 1055 u16 val = enable ? 0x3f : 0; 1056 int ret; 1057 1058 if (smi->leds_disabled) 1059 return; 1060 1061 switch (port) { 1062 case 0: 1063 ret = regmap_update_bits(smi->map, 1064 RTL8366RB_LED_0_1_CTRL_REG, 1065 0x3F, val); 1066 break; 1067 case 1: 1068 ret = regmap_update_bits(smi->map, 1069 RTL8366RB_LED_0_1_CTRL_REG, 1070 0x3F << RTL8366RB_LED_1_OFFSET, 1071 val << RTL8366RB_LED_1_OFFSET); 1072 break; 1073 case 2: 1074 ret = regmap_update_bits(smi->map, 1075 RTL8366RB_LED_2_3_CTRL_REG, 1076 0x3F, val); 1077 break; 1078 case 3: 1079 ret = regmap_update_bits(smi->map, 1080 RTL8366RB_LED_2_3_CTRL_REG, 1081 0x3F << RTL8366RB_LED_3_OFFSET, 1082 val << RTL8366RB_LED_3_OFFSET); 1083 break; 1084 case 4: 1085 ret = regmap_update_bits(smi->map, 1086 RTL8366RB_INTERRUPT_CONTROL_REG, 1087 RTL8366RB_P4_RGMII_LED, 1088 enable ? RTL8366RB_P4_RGMII_LED : 0); 1089 break; 1090 default: 1091 dev_err(smi->dev, "no LED for port %d\n", port); 1092 return; 1093 } 1094 if (ret) 1095 dev_err(smi->dev, "error updating LED on port %d\n", port); 1096} 1097 1098static int 1099rtl8366rb_port_enable(struct dsa_switch *ds, int port, 1100 struct phy_device *phy) 1101{ 1102 struct realtek_smi *smi = ds->priv; 1103 int ret; 1104 1105 dev_dbg(smi->dev, "enable port %d\n", port); 1106 ret = regmap_update_bits(smi->map, RTL8366RB_PECR, BIT(port), 1107 0); 1108 if (ret) 1109 return ret; 1110 1111 rb8366rb_set_port_led(smi, port, true); 1112 return 0; 1113} 1114 1115static void 1116rtl8366rb_port_disable(struct dsa_switch *ds, int port) 1117{ 1118 struct realtek_smi *smi = ds->priv; 1119 int ret; 1120 1121 dev_dbg(smi->dev, "disable port %d\n", port); 1122 ret = regmap_update_bits(smi->map, RTL8366RB_PECR, BIT(port), 1123 BIT(port)); 1124 if (ret) 1125 return; 1126 1127 rb8366rb_set_port_led(smi, port, false); 1128} 1129 1130static int rtl8366rb_change_mtu(struct dsa_switch *ds, int port, int new_mtu) 1131{ 1132 struct realtek_smi *smi = ds->priv; 1133 struct rtl8366rb *rb; 1134 unsigned int max_mtu; 1135 u32 len; 1136 int i; 1137 1138 /* Cache the per-port MTU setting */ 1139 rb = smi->chip_data; 1140 rb->max_mtu[port] = new_mtu; 1141 1142 /* Roof out the MTU for the entire switch to the greatest 1143 * common denominator: the biggest set for any one port will 1144 * be the biggest MTU for the switch. 1145 * 1146 * The first setting, 1522 bytes, is max IP packet 1500 bytes, 1147 * plus ethernet header, 1518 bytes, plus CPU tag, 4 bytes. 1148 * This function should consider the parameter an SDU, so the 1149 * MTU passed for this setting is 1518 bytes. The same logic 1150 * of subtracting the DSA tag of 4 bytes apply to the other 1151 * settings. 1152 */ 1153 max_mtu = 1518; 1154 for (i = 0; i < RTL8366RB_NUM_PORTS; i++) { 1155 if (rb->max_mtu[i] > max_mtu) 1156 max_mtu = rb->max_mtu[i]; 1157 } 1158 if (max_mtu <= 1518) 1159 len = RTL8366RB_SGCR_MAX_LENGTH_1522; 1160 else if (max_mtu > 1518 && max_mtu <= 1532) 1161 len = RTL8366RB_SGCR_MAX_LENGTH_1536; 1162 else if (max_mtu > 1532 && max_mtu <= 1548) 1163 len = RTL8366RB_SGCR_MAX_LENGTH_1552; 1164 else 1165 len = RTL8366RB_SGCR_MAX_LENGTH_16000; 1166 1167 return regmap_update_bits(smi->map, RTL8366RB_SGCR, 1168 RTL8366RB_SGCR_MAX_LENGTH_MASK, 1169 len); 1170} 1171 1172static int rtl8366rb_max_mtu(struct dsa_switch *ds, int port) 1173{ 1174 /* The max MTU is 16000 bytes, so we subtract the CPU tag 1175 * and the max presented to the system is 15996 bytes. 1176 */ 1177 return 15996; 1178} 1179 1180static int rtl8366rb_get_vlan_4k(struct realtek_smi *smi, u32 vid, 1181 struct rtl8366_vlan_4k *vlan4k) 1182{ 1183 u32 data[3]; 1184 int ret; 1185 int i; 1186 1187 memset(vlan4k, '\0', sizeof(struct rtl8366_vlan_4k)); 1188 1189 if (vid >= RTL8366RB_NUM_VIDS) 1190 return -EINVAL; 1191 1192 /* write VID */ 1193 ret = regmap_write(smi->map, RTL8366RB_VLAN_TABLE_WRITE_BASE, 1194 vid & RTL8366RB_VLAN_VID_MASK); 1195 if (ret) 1196 return ret; 1197 1198 /* write table access control word */ 1199 ret = regmap_write(smi->map, RTL8366RB_TABLE_ACCESS_CTRL_REG, 1200 RTL8366RB_TABLE_VLAN_READ_CTRL); 1201 if (ret) 1202 return ret; 1203 1204 for (i = 0; i < 3; i++) { 1205 ret = regmap_read(smi->map, 1206 RTL8366RB_VLAN_TABLE_READ_BASE + i, 1207 &data[i]); 1208 if (ret) 1209 return ret; 1210 } 1211 1212 vlan4k->vid = vid; 1213 vlan4k->untag = (data[1] >> RTL8366RB_VLAN_UNTAG_SHIFT) & 1214 RTL8366RB_VLAN_UNTAG_MASK; 1215 vlan4k->member = data[1] & RTL8366RB_VLAN_MEMBER_MASK; 1216 vlan4k->fid = data[2] & RTL8366RB_VLAN_FID_MASK; 1217 1218 return 0; 1219} 1220 1221static int rtl8366rb_set_vlan_4k(struct realtek_smi *smi, 1222 const struct rtl8366_vlan_4k *vlan4k) 1223{ 1224 u32 data[3]; 1225 int ret; 1226 int i; 1227 1228 if (vlan4k->vid >= RTL8366RB_NUM_VIDS || 1229 vlan4k->member > RTL8366RB_VLAN_MEMBER_MASK || 1230 vlan4k->untag > RTL8366RB_VLAN_UNTAG_MASK || 1231 vlan4k->fid > RTL8366RB_FIDMAX) 1232 return -EINVAL; 1233 1234 data[0] = vlan4k->vid & RTL8366RB_VLAN_VID_MASK; 1235 data[1] = (vlan4k->member & RTL8366RB_VLAN_MEMBER_MASK) | 1236 ((vlan4k->untag & RTL8366RB_VLAN_UNTAG_MASK) << 1237 RTL8366RB_VLAN_UNTAG_SHIFT); 1238 data[2] = vlan4k->fid & RTL8366RB_VLAN_FID_MASK; 1239 1240 for (i = 0; i < 3; i++) { 1241 ret = regmap_write(smi->map, 1242 RTL8366RB_VLAN_TABLE_WRITE_BASE + i, 1243 data[i]); 1244 if (ret) 1245 return ret; 1246 } 1247 1248 /* write table access control word */ 1249 ret = regmap_write(smi->map, RTL8366RB_TABLE_ACCESS_CTRL_REG, 1250 RTL8366RB_TABLE_VLAN_WRITE_CTRL); 1251 1252 return ret; 1253} 1254 1255static int rtl8366rb_get_vlan_mc(struct realtek_smi *smi, u32 index, 1256 struct rtl8366_vlan_mc *vlanmc) 1257{ 1258 u32 data[3]; 1259 int ret; 1260 int i; 1261 1262 memset(vlanmc, '\0', sizeof(struct rtl8366_vlan_mc)); 1263 1264 if (index >= RTL8366RB_NUM_VLANS) 1265 return -EINVAL; 1266 1267 for (i = 0; i < 3; i++) { 1268 ret = regmap_read(smi->map, 1269 RTL8366RB_VLAN_MC_BASE(index) + i, 1270 &data[i]); 1271 if (ret) 1272 return ret; 1273 } 1274 1275 vlanmc->vid = data[0] & RTL8366RB_VLAN_VID_MASK; 1276 vlanmc->priority = (data[0] >> RTL8366RB_VLAN_PRIORITY_SHIFT) & 1277 RTL8366RB_VLAN_PRIORITY_MASK; 1278 vlanmc->untag = (data[1] >> RTL8366RB_VLAN_UNTAG_SHIFT) & 1279 RTL8366RB_VLAN_UNTAG_MASK; 1280 vlanmc->member = data[1] & RTL8366RB_VLAN_MEMBER_MASK; 1281 vlanmc->fid = data[2] & RTL8366RB_VLAN_FID_MASK; 1282 1283 return 0; 1284} 1285 1286static int rtl8366rb_set_vlan_mc(struct realtek_smi *smi, u32 index, 1287 const struct rtl8366_vlan_mc *vlanmc) 1288{ 1289 u32 data[3]; 1290 int ret; 1291 int i; 1292 1293 if (index >= RTL8366RB_NUM_VLANS || 1294 vlanmc->vid >= RTL8366RB_NUM_VIDS || 1295 vlanmc->priority > RTL8366RB_PRIORITYMAX || 1296 vlanmc->member > RTL8366RB_VLAN_MEMBER_MASK || 1297 vlanmc->untag > RTL8366RB_VLAN_UNTAG_MASK || 1298 vlanmc->fid > RTL8366RB_FIDMAX) 1299 return -EINVAL; 1300 1301 data[0] = (vlanmc->vid & RTL8366RB_VLAN_VID_MASK) | 1302 ((vlanmc->priority & RTL8366RB_VLAN_PRIORITY_MASK) << 1303 RTL8366RB_VLAN_PRIORITY_SHIFT); 1304 data[1] = (vlanmc->member & RTL8366RB_VLAN_MEMBER_MASK) | 1305 ((vlanmc->untag & RTL8366RB_VLAN_UNTAG_MASK) << 1306 RTL8366RB_VLAN_UNTAG_SHIFT); 1307 data[2] = vlanmc->fid & RTL8366RB_VLAN_FID_MASK; 1308 1309 for (i = 0; i < 3; i++) { 1310 ret = regmap_write(smi->map, 1311 RTL8366RB_VLAN_MC_BASE(index) + i, 1312 data[i]); 1313 if (ret) 1314 return ret; 1315 } 1316 1317 return 0; 1318} 1319 1320static int rtl8366rb_get_mc_index(struct realtek_smi *smi, int port, int *val) 1321{ 1322 u32 data; 1323 int ret; 1324 1325 if (port >= smi->num_ports) 1326 return -EINVAL; 1327 1328 ret = regmap_read(smi->map, RTL8366RB_PORT_VLAN_CTRL_REG(port), 1329 &data); 1330 if (ret) 1331 return ret; 1332 1333 *val = (data >> RTL8366RB_PORT_VLAN_CTRL_SHIFT(port)) & 1334 RTL8366RB_PORT_VLAN_CTRL_MASK; 1335 1336 return 0; 1337} 1338 1339static int rtl8366rb_set_mc_index(struct realtek_smi *smi, int port, int index) 1340{ 1341 if (port >= smi->num_ports || index >= RTL8366RB_NUM_VLANS) 1342 return -EINVAL; 1343 1344 return regmap_update_bits(smi->map, RTL8366RB_PORT_VLAN_CTRL_REG(port), 1345 RTL8366RB_PORT_VLAN_CTRL_MASK << 1346 RTL8366RB_PORT_VLAN_CTRL_SHIFT(port), 1347 (index & RTL8366RB_PORT_VLAN_CTRL_MASK) << 1348 RTL8366RB_PORT_VLAN_CTRL_SHIFT(port)); 1349} 1350 1351static bool rtl8366rb_is_vlan_valid(struct realtek_smi *smi, unsigned int vlan) 1352{ 1353 unsigned int max = RTL8366RB_NUM_VLANS; 1354 1355 if (smi->vlan4k_enabled) 1356 max = RTL8366RB_NUM_VIDS - 1; 1357 1358 if (vlan == 0 || vlan > max) 1359 return false; 1360 1361 return true; 1362} 1363 1364static int rtl8366rb_enable_vlan(struct realtek_smi *smi, bool enable) 1365{ 1366 dev_dbg(smi->dev, "%s VLAN\n", enable ? "enable" : "disable"); 1367 return regmap_update_bits(smi->map, 1368 RTL8366RB_SGCR, RTL8366RB_SGCR_EN_VLAN, 1369 enable ? RTL8366RB_SGCR_EN_VLAN : 0); 1370} 1371 1372static int rtl8366rb_enable_vlan4k(struct realtek_smi *smi, bool enable) 1373{ 1374 dev_dbg(smi->dev, "%s VLAN 4k\n", enable ? "enable" : "disable"); 1375 return regmap_update_bits(smi->map, RTL8366RB_SGCR, 1376 RTL8366RB_SGCR_EN_VLAN_4KTB, 1377 enable ? RTL8366RB_SGCR_EN_VLAN_4KTB : 0); 1378} 1379 1380static int rtl8366rb_phy_read(struct realtek_smi *smi, int phy, int regnum) 1381{ 1382 u32 val; 1383 u32 reg; 1384 int ret; 1385 1386 if (phy > RTL8366RB_PHY_NO_MAX) 1387 return -EINVAL; 1388 1389 ret = regmap_write(smi->map, RTL8366RB_PHY_ACCESS_CTRL_REG, 1390 RTL8366RB_PHY_CTRL_READ); 1391 if (ret) 1392 return ret; 1393 1394 reg = 0x8000 | (1 << (phy + RTL8366RB_PHY_NO_OFFSET)) | regnum; 1395 1396 ret = regmap_write(smi->map, reg, 0); 1397 if (ret) { 1398 dev_err(smi->dev, 1399 "failed to write PHY%d reg %04x @ %04x, ret %d\n", 1400 phy, regnum, reg, ret); 1401 return ret; 1402 } 1403 1404 ret = regmap_read(smi->map, RTL8366RB_PHY_ACCESS_DATA_REG, &val); 1405 if (ret) 1406 return ret; 1407 1408 dev_dbg(smi->dev, "read PHY%d register 0x%04x @ %08x, val <- %04x\n", 1409 phy, regnum, reg, val); 1410 1411 return val; 1412} 1413 1414static int rtl8366rb_phy_write(struct realtek_smi *smi, int phy, int regnum, 1415 u16 val) 1416{ 1417 u32 reg; 1418 int ret; 1419 1420 if (phy > RTL8366RB_PHY_NO_MAX) 1421 return -EINVAL; 1422 1423 ret = regmap_write(smi->map, RTL8366RB_PHY_ACCESS_CTRL_REG, 1424 RTL8366RB_PHY_CTRL_WRITE); 1425 if (ret) 1426 return ret; 1427 1428 reg = 0x8000 | (1 << (phy + RTL8366RB_PHY_NO_OFFSET)) | regnum; 1429 1430 dev_dbg(smi->dev, "write PHY%d register 0x%04x @ %04x, val -> %04x\n", 1431 phy, regnum, reg, val); 1432 1433 ret = regmap_write(smi->map, reg, val); 1434 if (ret) 1435 return ret; 1436 1437 return 0; 1438} 1439 1440static int rtl8366rb_reset_chip(struct realtek_smi *smi) 1441{ 1442 int timeout = 10; 1443 u32 val; 1444 int ret; 1445 1446 realtek_smi_write_reg_noack(smi, RTL8366RB_RESET_CTRL_REG, 1447 RTL8366RB_CHIP_CTRL_RESET_HW); 1448 do { 1449 usleep_range(20000, 25000); 1450 ret = regmap_read(smi->map, RTL8366RB_RESET_CTRL_REG, &val); 1451 if (ret) 1452 return ret; 1453 1454 if (!(val & RTL8366RB_CHIP_CTRL_RESET_HW)) 1455 break; 1456 } while (--timeout); 1457 1458 if (!timeout) { 1459 dev_err(smi->dev, "timeout waiting for the switch to reset\n"); 1460 return -EIO; 1461 } 1462 1463 return 0; 1464} 1465 1466static int rtl8366rb_detect(struct realtek_smi *smi) 1467{ 1468 struct device *dev = smi->dev; 1469 int ret; 1470 u32 val; 1471 1472 /* Detect device */ 1473 ret = regmap_read(smi->map, 0x5c, &val); 1474 if (ret) { 1475 dev_err(dev, "can't get chip ID (%d)\n", ret); 1476 return ret; 1477 } 1478 1479 switch (val) { 1480 case 0x6027: 1481 dev_info(dev, "found an RTL8366S switch\n"); 1482 dev_err(dev, "this switch is not yet supported, submit patches!\n"); 1483 return -ENODEV; 1484 case 0x5937: 1485 dev_info(dev, "found an RTL8366RB switch\n"); 1486 smi->cpu_port = RTL8366RB_PORT_NUM_CPU; 1487 smi->num_ports = RTL8366RB_NUM_PORTS; 1488 smi->num_vlan_mc = RTL8366RB_NUM_VLANS; 1489 smi->mib_counters = rtl8366rb_mib_counters; 1490 smi->num_mib_counters = ARRAY_SIZE(rtl8366rb_mib_counters); 1491 break; 1492 default: 1493 dev_info(dev, "found an Unknown Realtek switch (id=0x%04x)\n", 1494 val); 1495 break; 1496 } 1497 1498 ret = rtl8366rb_reset_chip(smi); 1499 if (ret) 1500 return ret; 1501 1502 return 0; 1503} 1504 1505static const struct dsa_switch_ops rtl8366rb_switch_ops = { 1506 .get_tag_protocol = rtl8366_get_tag_protocol, 1507 .setup = rtl8366rb_setup, 1508 .phylink_mac_link_up = rtl8366rb_mac_link_up, 1509 .phylink_mac_link_down = rtl8366rb_mac_link_down, 1510 .get_strings = rtl8366_get_strings, 1511 .get_ethtool_stats = rtl8366_get_ethtool_stats, 1512 .get_sset_count = rtl8366_get_sset_count, 1513 .port_vlan_filtering = rtl8366_vlan_filtering, 1514 .port_vlan_add = rtl8366_vlan_add, 1515 .port_vlan_del = rtl8366_vlan_del, 1516 .port_enable = rtl8366rb_port_enable, 1517 .port_disable = rtl8366rb_port_disable, 1518 .port_change_mtu = rtl8366rb_change_mtu, 1519 .port_max_mtu = rtl8366rb_max_mtu, 1520}; 1521 1522static const struct realtek_smi_ops rtl8366rb_smi_ops = { 1523 .detect = rtl8366rb_detect, 1524 .get_vlan_mc = rtl8366rb_get_vlan_mc, 1525 .set_vlan_mc = rtl8366rb_set_vlan_mc, 1526 .get_vlan_4k = rtl8366rb_get_vlan_4k, 1527 .set_vlan_4k = rtl8366rb_set_vlan_4k, 1528 .get_mc_index = rtl8366rb_get_mc_index, 1529 .set_mc_index = rtl8366rb_set_mc_index, 1530 .get_mib_counter = rtl8366rb_get_mib_counter, 1531 .is_vlan_valid = rtl8366rb_is_vlan_valid, 1532 .enable_vlan = rtl8366rb_enable_vlan, 1533 .enable_vlan4k = rtl8366rb_enable_vlan4k, 1534 .phy_read = rtl8366rb_phy_read, 1535 .phy_write = rtl8366rb_phy_write, 1536}; 1537 1538const struct realtek_smi_variant rtl8366rb_variant = { 1539 .ds_ops = &rtl8366rb_switch_ops, 1540 .ops = &rtl8366rb_smi_ops, 1541 .clk_delay = 10, 1542 .cmd_read = 0xa9, 1543 .cmd_write = 0xa8, 1544 .chip_data_sz = sizeof(struct rtl8366rb), 1545}; 1546EXPORT_SYMBOL_GPL(rtl8366rb_variant);