1 // SPDX-License-Identifier: GPL-2.0 2 /* 3 * Nuvoton NPCM7xx I2C Controller driver 4 * 5 * Copyright (C) 2020 Nuvoton Technologies tali.perry@nuvoton.com 6 */ 7 #include <linux/bitfield.h> 8 #include <linux/clk.h> 9 #include <linux/debugfs.h> 10 #include <linux/errno.h> 11 #include <linux/i2c.h> 12 #include <linux/interrupt.h> 13 #include <linux/iopoll.h> 14 #include <linux/irq.h> 15 #include <linux/jiffies.h> 16 #include <linux/kernel.h> 17 #include <linux/mfd/syscon.h> 18 #include <linux/module.h> 19 #include <linux/of.h> 20 #include <linux/platform_device.h> 21 #include <linux/regmap.h> 22 23 enum i2c_mode { 24 I2C_MASTER, 25 I2C_SLAVE, 26 }; 27 28 /* 29 * External I2C Interface driver xfer indication values, which indicate status 30 * of the bus. 31 */ 32 enum i2c_state_ind { 33 I2C_NO_STATUS_IND = 0, 34 I2C_SLAVE_RCV_IND, 35 I2C_SLAVE_XMIT_IND, 36 I2C_SLAVE_XMIT_MISSING_DATA_IND, 37 I2C_SLAVE_RESTART_IND, 38 I2C_SLAVE_DONE_IND, 39 I2C_MASTER_DONE_IND, 40 I2C_NACK_IND, 41 I2C_BUS_ERR_IND, 42 I2C_WAKE_UP_IND, 43 I2C_BLOCK_BYTES_ERR_IND, 44 I2C_SLAVE_RCV_MISSING_DATA_IND, 45 }; 46 47 /* 48 * Operation type values (used to define the operation currently running) 49 * module is interrupt driven, on each interrupt the current operation is 50 * checked to see if the module is currently reading or writing. 51 */ 52 enum i2c_oper { 53 I2C_NO_OPER = 0, 54 I2C_WRITE_OPER, 55 I2C_READ_OPER, 56 }; 57 58 /* I2C Bank (module had 2 banks of registers) */ 59 enum i2c_bank { 60 I2C_BANK_0 = 0, 61 I2C_BANK_1, 62 }; 63 64 /* Internal I2C states values (for the I2C module state machine). */ 65 enum i2c_state { 66 I2C_DISABLE = 0, 67 I2C_IDLE, 68 I2C_MASTER_START, 69 I2C_SLAVE_MATCH, 70 I2C_OPER_STARTED, 71 I2C_STOP_PENDING, 72 }; 73 74 #if IS_ENABLED(CONFIG_I2C_SLAVE) 75 /* Module supports setting multiple own slave addresses */ 76 enum i2c_addr { 77 I2C_SLAVE_ADDR1 = 0, 78 I2C_SLAVE_ADDR2, 79 I2C_SLAVE_ADDR3, 80 I2C_SLAVE_ADDR4, 81 I2C_SLAVE_ADDR5, 82 I2C_SLAVE_ADDR6, 83 I2C_SLAVE_ADDR7, 84 I2C_SLAVE_ADDR8, 85 I2C_SLAVE_ADDR9, 86 I2C_SLAVE_ADDR10, 87 I2C_GC_ADDR, 88 I2C_ARP_ADDR, 89 }; 90 #endif 91 92 /* init register and default value required to enable module */ 93 #define NPCM_I2CSEGCTL 0xE4 94 #define NPCM_I2CSEGCTL_INIT_VAL 0x0333F000 95 96 /* Common regs */ 97 #define NPCM_I2CSDA 0x00 98 #define NPCM_I2CST 0x02 99 #define NPCM_I2CCST 0x04 100 #define NPCM_I2CCTL1 0x06 101 #define NPCM_I2CADDR1 0x08 102 #define NPCM_I2CCTL2 0x0A 103 #define NPCM_I2CADDR2 0x0C 104 #define NPCM_I2CCTL3 0x0E 105 #define NPCM_I2CCST2 0x18 106 #define NPCM_I2CCST3 0x19 107 #define I2C_VER 0x1F 108 109 /*BANK0 regs*/ 110 #define NPCM_I2CADDR3 0x10 111 #define NPCM_I2CADDR7 0x11 112 #define NPCM_I2CADDR4 0x12 113 #define NPCM_I2CADDR8 0x13 114 #define NPCM_I2CADDR5 0x14 115 #define NPCM_I2CADDR9 0x15 116 #define NPCM_I2CADDR6 0x16 117 #define NPCM_I2CADDR10 0x17 118 119 #if IS_ENABLED(CONFIG_I2C_SLAVE) 120 /* 121 * npcm_i2caddr array: 122 * The module supports having multiple own slave addresses. 123 * Since the addr regs are sprinkled all over the address space, 124 * use this array to get the address or each register. 125 */ 126 #define I2C_NUM_OWN_ADDR 10 127 static const int npcm_i2caddr[I2C_NUM_OWN_ADDR] = { 128 NPCM_I2CADDR1, NPCM_I2CADDR2, NPCM_I2CADDR3, NPCM_I2CADDR4, 129 NPCM_I2CADDR5, NPCM_I2CADDR6, NPCM_I2CADDR7, NPCM_I2CADDR8, 130 NPCM_I2CADDR9, NPCM_I2CADDR10, 131 }; 132 #endif 133 134 #define NPCM_I2CCTL4 0x1A 135 #define NPCM_I2CCTL5 0x1B 136 #define NPCM_I2CSCLLT 0x1C /* SCL Low Time */ 137 #define NPCM_I2CFIF_CTL 0x1D /* FIFO Control */ 138 #define NPCM_I2CSCLHT 0x1E /* SCL High Time */ 139 140 /* BANK 1 regs */ 141 #define NPCM_I2CFIF_CTS 0x10 /* Both FIFOs Control and Status */ 142 #define NPCM_I2CTXF_CTL 0x12 /* Tx-FIFO Control */ 143 #define NPCM_I2CT_OUT 0x14 /* Bus T.O. */ 144 #define NPCM_I2CPEC 0x16 /* PEC Data */ 145 #define NPCM_I2CTXF_STS 0x1A /* Tx-FIFO Status */ 146 #define NPCM_I2CRXF_STS 0x1C /* Rx-FIFO Status */ 147 #define NPCM_I2CRXF_CTL 0x1E /* Rx-FIFO Control */ 148 149 /* NPCM_I2CST reg fields */ 150 #define NPCM_I2CST_XMIT BIT(0) 151 #define NPCM_I2CST_MASTER BIT(1) 152 #define NPCM_I2CST_NMATCH BIT(2) 153 #define NPCM_I2CST_STASTR BIT(3) 154 #define NPCM_I2CST_NEGACK BIT(4) 155 #define NPCM_I2CST_BER BIT(5) 156 #define NPCM_I2CST_SDAST BIT(6) 157 #define NPCM_I2CST_SLVSTP BIT(7) 158 159 /* NPCM_I2CCST reg fields */ 160 #define NPCM_I2CCST_BUSY BIT(0) 161 #define NPCM_I2CCST_BB BIT(1) 162 #define NPCM_I2CCST_MATCH BIT(2) 163 #define NPCM_I2CCST_GCMATCH BIT(3) 164 #define NPCM_I2CCST_TSDA BIT(4) 165 #define NPCM_I2CCST_TGSCL BIT(5) 166 #define NPCM_I2CCST_MATCHAF BIT(6) 167 #define NPCM_I2CCST_ARPMATCH BIT(7) 168 169 /* NPCM_I2CCTL1 reg fields */ 170 #define NPCM_I2CCTL1_START BIT(0) 171 #define NPCM_I2CCTL1_STOP BIT(1) 172 #define NPCM_I2CCTL1_INTEN BIT(2) 173 #define NPCM_I2CCTL1_EOBINTE BIT(3) 174 #define NPCM_I2CCTL1_ACK BIT(4) 175 #define NPCM_I2CCTL1_GCMEN BIT(5) 176 #define NPCM_I2CCTL1_NMINTE BIT(6) 177 #define NPCM_I2CCTL1_STASTRE BIT(7) 178 179 /* RW1S fields (inside a RW reg): */ 180 #define NPCM_I2CCTL1_RWS \ 181 (NPCM_I2CCTL1_START | NPCM_I2CCTL1_STOP | NPCM_I2CCTL1_ACK) 182 183 /* npcm_i2caddr reg fields */ 184 #define NPCM_I2CADDR_A GENMASK(6, 0) 185 #define NPCM_I2CADDR_SAEN BIT(7) 186 187 /* NPCM_I2CCTL2 reg fields */ 188 #define I2CCTL2_ENABLE BIT(0) 189 #define I2CCTL2_SCLFRQ6_0 GENMASK(7, 1) 190 191 /* NPCM_I2CCTL3 reg fields */ 192 #define I2CCTL3_SCLFRQ8_7 GENMASK(1, 0) 193 #define I2CCTL3_ARPMEN BIT(2) 194 #define I2CCTL3_IDL_START BIT(3) 195 #define I2CCTL3_400K_MODE BIT(4) 196 #define I2CCTL3_BNK_SEL BIT(5) 197 #define I2CCTL3_SDA_LVL BIT(6) 198 #define I2CCTL3_SCL_LVL BIT(7) 199 200 /* NPCM_I2CCST2 reg fields */ 201 #define NPCM_I2CCST2_MATCHA1F BIT(0) 202 #define NPCM_I2CCST2_MATCHA2F BIT(1) 203 #define NPCM_I2CCST2_MATCHA3F BIT(2) 204 #define NPCM_I2CCST2_MATCHA4F BIT(3) 205 #define NPCM_I2CCST2_MATCHA5F BIT(4) 206 #define NPCM_I2CCST2_MATCHA6F BIT(5) 207 #define NPCM_I2CCST2_MATCHA7F BIT(5) 208 #define NPCM_I2CCST2_INTSTS BIT(7) 209 210 /* NPCM_I2CCST3 reg fields */ 211 #define NPCM_I2CCST3_MATCHA8F BIT(0) 212 #define NPCM_I2CCST3_MATCHA9F BIT(1) 213 #define NPCM_I2CCST3_MATCHA10F BIT(2) 214 #define NPCM_I2CCST3_EO_BUSY BIT(7) 215 216 /* NPCM_I2CCTL4 reg fields */ 217 #define I2CCTL4_HLDT GENMASK(5, 0) 218 #define I2CCTL4_LVL_WE BIT(7) 219 220 /* NPCM_I2CCTL5 reg fields */ 221 #define I2CCTL5_DBNCT GENMASK(3, 0) 222 223 /* NPCM_I2CFIF_CTS reg fields */ 224 #define NPCM_I2CFIF_CTS_RXF_TXE BIT(1) 225 #define NPCM_I2CFIF_CTS_RFTE_IE BIT(3) 226 #define NPCM_I2CFIF_CTS_CLR_FIFO BIT(6) 227 #define NPCM_I2CFIF_CTS_SLVRSTR BIT(7) 228 229 /* NPCM_I2CTXF_CTL reg fields */ 230 #define NPCM_I2CTXF_CTL_TX_THR GENMASK(4, 0) 231 #define NPCM_I2CTXF_CTL_THR_TXIE BIT(6) 232 233 /* NPCM_I2CT_OUT reg fields */ 234 #define NPCM_I2CT_OUT_TO_CKDIV GENMASK(5, 0) 235 #define NPCM_I2CT_OUT_T_OUTIE BIT(6) 236 #define NPCM_I2CT_OUT_T_OUTST BIT(7) 237 238 /* NPCM_I2CTXF_STS reg fields */ 239 #define NPCM_I2CTXF_STS_TX_BYTES GENMASK(4, 0) 240 #define NPCM_I2CTXF_STS_TX_THST BIT(6) 241 242 /* NPCM_I2CRXF_STS reg fields */ 243 #define NPCM_I2CRXF_STS_RX_BYTES GENMASK(4, 0) 244 #define NPCM_I2CRXF_STS_RX_THST BIT(6) 245 246 /* NPCM_I2CFIF_CTL reg fields */ 247 #define NPCM_I2CFIF_CTL_FIFO_EN BIT(4) 248 249 /* NPCM_I2CRXF_CTL reg fields */ 250 #define NPCM_I2CRXF_CTL_RX_THR GENMASK(4, 0) 251 #define NPCM_I2CRXF_CTL_LAST_PEC BIT(5) 252 #define NPCM_I2CRXF_CTL_THR_RXIE BIT(6) 253 254 #define I2C_HW_FIFO_SIZE 16 255 256 /* I2C_VER reg fields */ 257 #define I2C_VER_VERSION GENMASK(6, 0) 258 #define I2C_VER_FIFO_EN BIT(7) 259 260 /* stall/stuck timeout in us */ 261 #define DEFAULT_STALL_COUNT 25 262 263 /* SCLFRQ field position */ 264 #define SCLFRQ_0_TO_6 GENMASK(6, 0) 265 #define SCLFRQ_7_TO_8 GENMASK(8, 7) 266 267 /* supported clk settings. values in Hz. */ 268 #define I2C_FREQ_MIN_HZ 10000 269 #define I2C_FREQ_MAX_HZ I2C_MAX_FAST_MODE_PLUS_FREQ 270 271 /* Status of one I2C module */ 272 struct npcm_i2c { 273 struct i2c_adapter adap; 274 struct device *dev; 275 unsigned char __iomem *reg; 276 spinlock_t lock; /* IRQ synchronization */ 277 struct completion cmd_complete; 278 int cmd_err; 279 struct i2c_msg *msgs; 280 int msgs_num; 281 int num; 282 u32 apb_clk; 283 struct i2c_bus_recovery_info rinfo; 284 enum i2c_state state; 285 enum i2c_oper operation; 286 enum i2c_mode master_or_slave; 287 enum i2c_state_ind stop_ind; 288 u8 dest_addr; 289 u8 *rd_buf; 290 u16 rd_size; 291 u16 rd_ind; 292 u8 *wr_buf; 293 u16 wr_size; 294 u16 wr_ind; 295 bool fifo_use; 296 u16 PEC_mask; /* PEC bit mask per slave address */ 297 bool PEC_use; 298 bool read_block_use; 299 unsigned long int_time_stamp; 300 unsigned long bus_freq; /* in Hz */ 301 #if IS_ENABLED(CONFIG_I2C_SLAVE) 302 u8 own_slave_addr; 303 struct i2c_client *slave; 304 int slv_rd_size; 305 int slv_rd_ind; 306 int slv_wr_size; 307 int slv_wr_ind; 308 u8 slv_rd_buf[I2C_HW_FIFO_SIZE]; 309 u8 slv_wr_buf[I2C_HW_FIFO_SIZE]; 310 #endif 311 struct dentry *debugfs; /* debugfs device directory */ 312 u64 ber_cnt; 313 u64 rec_succ_cnt; 314 u64 rec_fail_cnt; 315 u64 nack_cnt; 316 u64 timeout_cnt; 317 u64 tx_complete_cnt; 318 }; 319 320 static inline void npcm_i2c_select_bank(struct npcm_i2c *bus, 321 enum i2c_bank bank) 322 { 323 u8 i2cctl3 = ioread8(bus->reg + NPCM_I2CCTL3); 324 325 if (bank == I2C_BANK_0) 326 i2cctl3 = i2cctl3 & ~I2CCTL3_BNK_SEL; 327 else 328 i2cctl3 = i2cctl3 | I2CCTL3_BNK_SEL; 329 iowrite8(i2cctl3, bus->reg + NPCM_I2CCTL3); 330 } 331 332 static void npcm_i2c_init_params(struct npcm_i2c *bus) 333 { 334 bus->stop_ind = I2C_NO_STATUS_IND; 335 bus->rd_size = 0; 336 bus->wr_size = 0; 337 bus->rd_ind = 0; 338 bus->wr_ind = 0; 339 bus->read_block_use = false; 340 bus->int_time_stamp = 0; 341 bus->PEC_use = false; 342 bus->PEC_mask = 0; 343 #if IS_ENABLED(CONFIG_I2C_SLAVE) 344 if (bus->slave) 345 bus->master_or_slave = I2C_SLAVE; 346 #endif 347 } 348 349 static inline void npcm_i2c_wr_byte(struct npcm_i2c *bus, u8 data) 350 { 351 iowrite8(data, bus->reg + NPCM_I2CSDA); 352 } 353 354 static inline u8 npcm_i2c_rd_byte(struct npcm_i2c *bus) 355 { 356 return ioread8(bus->reg + NPCM_I2CSDA); 357 } 358 359 static int npcm_i2c_get_SCL(struct i2c_adapter *_adap) 360 { 361 struct npcm_i2c *bus = container_of(_adap, struct npcm_i2c, adap); 362 363 return !!(I2CCTL3_SCL_LVL & ioread8(bus->reg + NPCM_I2CCTL3)); 364 } 365 366 static int npcm_i2c_get_SDA(struct i2c_adapter *_adap) 367 { 368 struct npcm_i2c *bus = container_of(_adap, struct npcm_i2c, adap); 369 370 return !!(I2CCTL3_SDA_LVL & ioread8(bus->reg + NPCM_I2CCTL3)); 371 } 372 373 static inline u16 npcm_i2c_get_index(struct npcm_i2c *bus) 374 { 375 if (bus->operation == I2C_READ_OPER) 376 return bus->rd_ind; 377 if (bus->operation == I2C_WRITE_OPER) 378 return bus->wr_ind; 379 return 0; 380 } 381 382 /* quick protocol (just address) */ 383 static inline bool npcm_i2c_is_quick(struct npcm_i2c *bus) 384 { 385 return bus->wr_size == 0 && bus->rd_size == 0; 386 } 387 388 static void npcm_i2c_disable(struct npcm_i2c *bus) 389 { 390 u8 i2cctl2; 391 392 #if IS_ENABLED(CONFIG_I2C_SLAVE) 393 int i; 394 395 /* select bank 0 for I2C addresses */ 396 npcm_i2c_select_bank(bus, I2C_BANK_0); 397 398 /* Slave addresses removal */ 399 for (i = I2C_SLAVE_ADDR1; i < I2C_NUM_OWN_ADDR; i++) 400 iowrite8(0, bus->reg + npcm_i2caddr[i]); 401 402 npcm_i2c_select_bank(bus, I2C_BANK_1); 403 #endif 404 /* Disable module */ 405 i2cctl2 = ioread8(bus->reg + NPCM_I2CCTL2); 406 i2cctl2 = i2cctl2 & ~I2CCTL2_ENABLE; 407 iowrite8(i2cctl2, bus->reg + NPCM_I2CCTL2); 408 409 bus->state = I2C_DISABLE; 410 } 411 412 static void npcm_i2c_enable(struct npcm_i2c *bus) 413 { 414 u8 i2cctl2 = ioread8(bus->reg + NPCM_I2CCTL2); 415 416 i2cctl2 = i2cctl2 | I2CCTL2_ENABLE; 417 iowrite8(i2cctl2, bus->reg + NPCM_I2CCTL2); 418 bus->state = I2C_IDLE; 419 } 420 421 /* enable\disable end of busy (EOB) interrupts */ 422 static inline void npcm_i2c_eob_int(struct npcm_i2c *bus, bool enable) 423 { 424 u8 val; 425 426 /* Clear EO_BUSY pending bit: */ 427 val = ioread8(bus->reg + NPCM_I2CCST3); 428 val = val | NPCM_I2CCST3_EO_BUSY; 429 iowrite8(val, bus->reg + NPCM_I2CCST3); 430 431 val = ioread8(bus->reg + NPCM_I2CCTL1); 432 val &= ~NPCM_I2CCTL1_RWS; 433 if (enable) 434 val |= NPCM_I2CCTL1_EOBINTE; 435 else 436 val &= ~NPCM_I2CCTL1_EOBINTE; 437 iowrite8(val, bus->reg + NPCM_I2CCTL1); 438 } 439 440 static inline bool npcm_i2c_tx_fifo_empty(struct npcm_i2c *bus) 441 { 442 u8 tx_fifo_sts; 443 444 tx_fifo_sts = ioread8(bus->reg + NPCM_I2CTXF_STS); 445 /* check if TX FIFO is not empty */ 446 if ((tx_fifo_sts & NPCM_I2CTXF_STS_TX_BYTES) == 0) 447 return false; 448 449 /* check if TX FIFO status bit is set: */ 450 return !!FIELD_GET(NPCM_I2CTXF_STS_TX_THST, tx_fifo_sts); 451 } 452 453 static inline bool npcm_i2c_rx_fifo_full(struct npcm_i2c *bus) 454 { 455 u8 rx_fifo_sts; 456 457 rx_fifo_sts = ioread8(bus->reg + NPCM_I2CRXF_STS); 458 /* check if RX FIFO is not empty: */ 459 if ((rx_fifo_sts & NPCM_I2CRXF_STS_RX_BYTES) == 0) 460 return false; 461 462 /* check if rx fifo full status is set: */ 463 return !!FIELD_GET(NPCM_I2CRXF_STS_RX_THST, rx_fifo_sts); 464 } 465 466 static inline void npcm_i2c_clear_fifo_int(struct npcm_i2c *bus) 467 { 468 u8 val; 469 470 val = ioread8(bus->reg + NPCM_I2CFIF_CTS); 471 val = (val & NPCM_I2CFIF_CTS_SLVRSTR) | NPCM_I2CFIF_CTS_RXF_TXE; 472 iowrite8(val, bus->reg + NPCM_I2CFIF_CTS); 473 } 474 475 static inline void npcm_i2c_clear_tx_fifo(struct npcm_i2c *bus) 476 { 477 u8 val; 478 479 val = ioread8(bus->reg + NPCM_I2CTXF_STS); 480 val = val | NPCM_I2CTXF_STS_TX_THST; 481 iowrite8(val, bus->reg + NPCM_I2CTXF_STS); 482 } 483 484 static inline void npcm_i2c_clear_rx_fifo(struct npcm_i2c *bus) 485 { 486 u8 val; 487 488 val = ioread8(bus->reg + NPCM_I2CRXF_STS); 489 val = val | NPCM_I2CRXF_STS_RX_THST; 490 iowrite8(val, bus->reg + NPCM_I2CRXF_STS); 491 } 492 493 static void npcm_i2c_int_enable(struct npcm_i2c *bus, bool enable) 494 { 495 u8 val; 496 497 val = ioread8(bus->reg + NPCM_I2CCTL1); 498 val &= ~NPCM_I2CCTL1_RWS; 499 if (enable) 500 val |= NPCM_I2CCTL1_INTEN; 501 else 502 val &= ~NPCM_I2CCTL1_INTEN; 503 iowrite8(val, bus->reg + NPCM_I2CCTL1); 504 } 505 506 static inline void npcm_i2c_master_start(struct npcm_i2c *bus) 507 { 508 u8 val; 509 510 val = ioread8(bus->reg + NPCM_I2CCTL1); 511 val &= ~(NPCM_I2CCTL1_STOP | NPCM_I2CCTL1_ACK); 512 val |= NPCM_I2CCTL1_START; 513 iowrite8(val, bus->reg + NPCM_I2CCTL1); 514 } 515 516 static inline void npcm_i2c_master_stop(struct npcm_i2c *bus) 517 { 518 u8 val; 519 520 /* 521 * override HW issue: I2C may fail to supply stop condition in Master 522 * Write operation. 523 * Need to delay at least 5 us from the last int, before issueing a stop 524 */ 525 udelay(10); /* function called from interrupt, can't sleep */ 526 val = ioread8(bus->reg + NPCM_I2CCTL1); 527 val &= ~(NPCM_I2CCTL1_START | NPCM_I2CCTL1_ACK); 528 val |= NPCM_I2CCTL1_STOP; 529 iowrite8(val, bus->reg + NPCM_I2CCTL1); 530 531 if (!bus->fifo_use) 532 return; 533 534 npcm_i2c_select_bank(bus, I2C_BANK_1); 535 536 if (bus->operation == I2C_READ_OPER) 537 npcm_i2c_clear_rx_fifo(bus); 538 else 539 npcm_i2c_clear_tx_fifo(bus); 540 npcm_i2c_clear_fifo_int(bus); 541 iowrite8(0, bus->reg + NPCM_I2CTXF_CTL); 542 } 543 544 static inline void npcm_i2c_stall_after_start(struct npcm_i2c *bus, bool stall) 545 { 546 u8 val; 547 548 val = ioread8(bus->reg + NPCM_I2CCTL1); 549 val &= ~NPCM_I2CCTL1_RWS; 550 if (stall) 551 val |= NPCM_I2CCTL1_STASTRE; 552 else 553 val &= ~NPCM_I2CCTL1_STASTRE; 554 iowrite8(val, bus->reg + NPCM_I2CCTL1); 555 } 556 557 static inline void npcm_i2c_nack(struct npcm_i2c *bus) 558 { 559 u8 val; 560 561 val = ioread8(bus->reg + NPCM_I2CCTL1); 562 val &= ~(NPCM_I2CCTL1_STOP | NPCM_I2CCTL1_START); 563 val |= NPCM_I2CCTL1_ACK; 564 iowrite8(val, bus->reg + NPCM_I2CCTL1); 565 } 566 567 static inline void npcm_i2c_clear_master_status(struct npcm_i2c *bus) 568 { 569 u8 val; 570 571 /* Clear NEGACK, STASTR and BER bits */ 572 val = NPCM_I2CST_BER | NPCM_I2CST_NEGACK | NPCM_I2CST_STASTR; 573 iowrite8(val, bus->reg + NPCM_I2CST); 574 } 575 576 #if IS_ENABLED(CONFIG_I2C_SLAVE) 577 static void npcm_i2c_slave_int_enable(struct npcm_i2c *bus, bool enable) 578 { 579 u8 i2cctl1; 580 581 /* enable interrupt on slave match: */ 582 i2cctl1 = ioread8(bus->reg + NPCM_I2CCTL1); 583 i2cctl1 &= ~NPCM_I2CCTL1_RWS; 584 if (enable) 585 i2cctl1 |= NPCM_I2CCTL1_NMINTE; 586 else 587 i2cctl1 &= ~NPCM_I2CCTL1_NMINTE; 588 iowrite8(i2cctl1, bus->reg + NPCM_I2CCTL1); 589 } 590 591 static int npcm_i2c_slave_enable(struct npcm_i2c *bus, enum i2c_addr addr_type, 592 u8 addr, bool enable) 593 { 594 u8 i2cctl1; 595 u8 i2cctl3; 596 u8 sa_reg; 597 598 sa_reg = (addr & 0x7F) | FIELD_PREP(NPCM_I2CADDR_SAEN, enable); 599 if (addr_type == I2C_GC_ADDR) { 600 i2cctl1 = ioread8(bus->reg + NPCM_I2CCTL1); 601 if (enable) 602 i2cctl1 |= NPCM_I2CCTL1_GCMEN; 603 else 604 i2cctl1 &= ~NPCM_I2CCTL1_GCMEN; 605 iowrite8(i2cctl1, bus->reg + NPCM_I2CCTL1); 606 return 0; 607 } 608 if (addr_type == I2C_ARP_ADDR) { 609 i2cctl3 = ioread8(bus->reg + NPCM_I2CCTL3); 610 if (enable) 611 i2cctl3 |= I2CCTL3_ARPMEN; 612 else 613 i2cctl3 &= ~I2CCTL3_ARPMEN; 614 iowrite8(i2cctl3, bus->reg + NPCM_I2CCTL3); 615 return 0; 616 } 617 if (addr_type >= I2C_ARP_ADDR) 618 return -EFAULT; 619 /* select bank 0 for address 3 to 10 */ 620 if (addr_type > I2C_SLAVE_ADDR2) 621 npcm_i2c_select_bank(bus, I2C_BANK_0); 622 /* Set and enable the address */ 623 iowrite8(sa_reg, bus->reg + npcm_i2caddr[addr_type]); 624 npcm_i2c_slave_int_enable(bus, enable); 625 if (addr_type > I2C_SLAVE_ADDR2) 626 npcm_i2c_select_bank(bus, I2C_BANK_1); 627 return 0; 628 } 629 #endif 630 631 static void npcm_i2c_reset(struct npcm_i2c *bus) 632 { 633 /* 634 * Save I2CCTL1 relevant bits. It is being cleared when the module 635 * is disabled. 636 */ 637 u8 i2cctl1; 638 #if IS_ENABLED(CONFIG_I2C_SLAVE) 639 u8 addr; 640 #endif 641 642 i2cctl1 = ioread8(bus->reg + NPCM_I2CCTL1); 643 644 npcm_i2c_disable(bus); 645 npcm_i2c_enable(bus); 646 647 /* Restore NPCM_I2CCTL1 Status */ 648 i2cctl1 &= ~NPCM_I2CCTL1_RWS; 649 iowrite8(i2cctl1, bus->reg + NPCM_I2CCTL1); 650 651 /* Clear BB (BUS BUSY) bit */ 652 iowrite8(NPCM_I2CCST_BB, bus->reg + NPCM_I2CCST); 653 iowrite8(0xFF, bus->reg + NPCM_I2CST); 654 655 /* Clear and disable EOB */ 656 npcm_i2c_eob_int(bus, false); 657 658 /* Clear all fifo bits: */ 659 iowrite8(NPCM_I2CFIF_CTS_CLR_FIFO, bus->reg + NPCM_I2CFIF_CTS); 660 661 #if IS_ENABLED(CONFIG_I2C_SLAVE) 662 if (bus->slave) { 663 addr = bus->slave->addr; 664 npcm_i2c_slave_enable(bus, I2C_SLAVE_ADDR1, addr, true); 665 } 666 #endif 667 668 /* clear status bits for spurious interrupts */ 669 npcm_i2c_clear_master_status(bus); 670 671 bus->state = I2C_IDLE; 672 } 673 674 static inline bool npcm_i2c_is_master(struct npcm_i2c *bus) 675 { 676 return !!FIELD_GET(NPCM_I2CST_MASTER, ioread8(bus->reg + NPCM_I2CST)); 677 } 678 679 static void npcm_i2c_callback(struct npcm_i2c *bus, 680 enum i2c_state_ind op_status, u16 info) 681 { 682 struct i2c_msg *msgs; 683 int msgs_num; 684 685 msgs = bus->msgs; 686 msgs_num = bus->msgs_num; 687 /* 688 * check that transaction was not timed-out, and msgs still 689 * holds a valid value. 690 */ 691 if (!msgs) 692 return; 693 694 if (completion_done(&bus->cmd_complete)) 695 return; 696 697 switch (op_status) { 698 case I2C_MASTER_DONE_IND: 699 bus->cmd_err = bus->msgs_num; 700 if (bus->tx_complete_cnt < ULLONG_MAX) 701 bus->tx_complete_cnt++; 702 fallthrough; 703 case I2C_BLOCK_BYTES_ERR_IND: 704 /* Master tx finished and all transmit bytes were sent */ 705 if (bus->msgs) { 706 if (msgs[0].flags & I2C_M_RD) 707 msgs[0].len = info; 708 else if (msgs_num == 2 && 709 msgs[1].flags & I2C_M_RD) 710 msgs[1].len = info; 711 } 712 if (completion_done(&bus->cmd_complete) == false) 713 complete(&bus->cmd_complete); 714 break; 715 716 case I2C_NACK_IND: 717 /* MASTER transmit got a NACK before tx all bytes */ 718 bus->cmd_err = -ENXIO; 719 if (bus->master_or_slave == I2C_MASTER) 720 complete(&bus->cmd_complete); 721 722 break; 723 case I2C_BUS_ERR_IND: 724 /* Bus error */ 725 bus->cmd_err = -EAGAIN; 726 if (bus->master_or_slave == I2C_MASTER) 727 complete(&bus->cmd_complete); 728 729 break; 730 case I2C_WAKE_UP_IND: 731 /* I2C wake up */ 732 break; 733 default: 734 break; 735 } 736 737 bus->operation = I2C_NO_OPER; 738 #if IS_ENABLED(CONFIG_I2C_SLAVE) 739 if (bus->slave) 740 bus->master_or_slave = I2C_SLAVE; 741 #endif 742 } 743 744 static u8 npcm_i2c_fifo_usage(struct npcm_i2c *bus) 745 { 746 if (bus->operation == I2C_WRITE_OPER) 747 return FIELD_GET(NPCM_I2CTXF_STS_TX_BYTES, 748 ioread8(bus->reg + NPCM_I2CTXF_STS)); 749 if (bus->operation == I2C_READ_OPER) 750 return FIELD_GET(NPCM_I2CRXF_STS_RX_BYTES, 751 ioread8(bus->reg + NPCM_I2CRXF_STS)); 752 return 0; 753 } 754 755 static void npcm_i2c_write_to_fifo_master(struct npcm_i2c *bus, u16 max_bytes) 756 { 757 u8 size_free_fifo; 758 759 /* 760 * Fill the FIFO, while the FIFO is not full and there are more bytes 761 * to write 762 */ 763 size_free_fifo = I2C_HW_FIFO_SIZE - npcm_i2c_fifo_usage(bus); 764 while (max_bytes-- && size_free_fifo) { 765 if (bus->wr_ind < bus->wr_size) 766 npcm_i2c_wr_byte(bus, bus->wr_buf[bus->wr_ind++]); 767 else 768 npcm_i2c_wr_byte(bus, 0xFF); 769 size_free_fifo = I2C_HW_FIFO_SIZE - npcm_i2c_fifo_usage(bus); 770 } 771 } 772 773 /* 774 * npcm_i2c_set_fifo: 775 * configure the FIFO before using it. If nread is -1 RX FIFO will not be 776 * configured. same for nwrite 777 */ 778 static void npcm_i2c_set_fifo(struct npcm_i2c *bus, int nread, int nwrite) 779 { 780 u8 rxf_ctl = 0; 781 782 if (!bus->fifo_use) 783 return; 784 npcm_i2c_select_bank(bus, I2C_BANK_1); 785 npcm_i2c_clear_tx_fifo(bus); 786 npcm_i2c_clear_rx_fifo(bus); 787 788 /* configure RX FIFO */ 789 if (nread > 0) { 790 rxf_ctl = min_t(int, nread, I2C_HW_FIFO_SIZE); 791 792 /* set LAST bit. if LAST is set next FIFO packet is nacked */ 793 if (nread <= I2C_HW_FIFO_SIZE) 794 rxf_ctl |= NPCM_I2CRXF_CTL_LAST_PEC; 795 796 /* 797 * if we are about to read the first byte in blk rd mode, 798 * don't NACK it. If slave returns zero size HW can't NACK 799 * it immediately, it will read extra byte and then NACK. 800 */ 801 if (bus->rd_ind == 0 && bus->read_block_use) { 802 /* set fifo to read one byte, no last: */ 803 rxf_ctl = 1; 804 } 805 806 /* set fifo size: */ 807 iowrite8(rxf_ctl, bus->reg + NPCM_I2CRXF_CTL); 808 } 809 810 /* configure TX FIFO */ 811 if (nwrite > 0) { 812 if (nwrite > I2C_HW_FIFO_SIZE) 813 /* data to send is more then FIFO size. */ 814 iowrite8(I2C_HW_FIFO_SIZE, bus->reg + NPCM_I2CTXF_CTL); 815 else 816 iowrite8(nwrite, bus->reg + NPCM_I2CTXF_CTL); 817 818 npcm_i2c_clear_tx_fifo(bus); 819 } 820 } 821 822 static void npcm_i2c_read_fifo(struct npcm_i2c *bus, u8 bytes_in_fifo) 823 { 824 u8 data; 825 826 while (bytes_in_fifo--) { 827 data = npcm_i2c_rd_byte(bus); 828 if (bus->rd_ind < bus->rd_size) 829 bus->rd_buf[bus->rd_ind++] = data; 830 } 831 } 832 833 static void npcm_i2c_master_abort(struct npcm_i2c *bus) 834 { 835 /* Only current master is allowed to issue a stop condition */ 836 if (!npcm_i2c_is_master(bus)) 837 return; 838 839 npcm_i2c_eob_int(bus, true); 840 npcm_i2c_master_stop(bus); 841 npcm_i2c_clear_master_status(bus); 842 } 843 844 #if IS_ENABLED(CONFIG_I2C_SLAVE) 845 static u8 npcm_i2c_get_slave_addr(struct npcm_i2c *bus, enum i2c_addr addr_type) 846 { 847 u8 slave_add; 848 849 /* select bank 0 for address 3 to 10 */ 850 if (addr_type > I2C_SLAVE_ADDR2) 851 npcm_i2c_select_bank(bus, I2C_BANK_0); 852 853 slave_add = ioread8(bus->reg + npcm_i2caddr[(int)addr_type]); 854 855 if (addr_type > I2C_SLAVE_ADDR2) 856 npcm_i2c_select_bank(bus, I2C_BANK_1); 857 858 return slave_add; 859 } 860 861 static int npcm_i2c_remove_slave_addr(struct npcm_i2c *bus, u8 slave_add) 862 { 863 int i; 864 865 /* Set the enable bit */ 866 slave_add |= 0x80; 867 npcm_i2c_select_bank(bus, I2C_BANK_0); 868 for (i = I2C_SLAVE_ADDR1; i < I2C_NUM_OWN_ADDR; i++) { 869 if (ioread8(bus->reg + npcm_i2caddr[i]) == slave_add) 870 iowrite8(0, bus->reg + npcm_i2caddr[i]); 871 } 872 npcm_i2c_select_bank(bus, I2C_BANK_1); 873 return 0; 874 } 875 876 static void npcm_i2c_write_fifo_slave(struct npcm_i2c *bus, u16 max_bytes) 877 { 878 /* 879 * Fill the FIFO, while the FIFO is not full and there are more bytes 880 * to write 881 */ 882 npcm_i2c_clear_fifo_int(bus); 883 npcm_i2c_clear_tx_fifo(bus); 884 iowrite8(0, bus->reg + NPCM_I2CTXF_CTL); 885 while (max_bytes-- && I2C_HW_FIFO_SIZE != npcm_i2c_fifo_usage(bus)) { 886 if (bus->slv_wr_size <= 0) 887 break; 888 bus->slv_wr_ind = bus->slv_wr_ind % I2C_HW_FIFO_SIZE; 889 npcm_i2c_wr_byte(bus, bus->slv_wr_buf[bus->slv_wr_ind]); 890 bus->slv_wr_ind++; 891 bus->slv_wr_ind = bus->slv_wr_ind % I2C_HW_FIFO_SIZE; 892 bus->slv_wr_size--; 893 } 894 } 895 896 static void npcm_i2c_read_fifo_slave(struct npcm_i2c *bus, u8 bytes_in_fifo) 897 { 898 u8 data; 899 900 if (!bus->slave) 901 return; 902 903 while (bytes_in_fifo--) { 904 data = npcm_i2c_rd_byte(bus); 905 906 bus->slv_rd_ind = bus->slv_rd_ind % I2C_HW_FIFO_SIZE; 907 bus->slv_rd_buf[bus->slv_rd_ind] = data; 908 bus->slv_rd_ind++; 909 910 /* 1st byte is length in block protocol: */ 911 if (bus->slv_rd_ind == 1 && bus->read_block_use) 912 bus->slv_rd_size = data + bus->PEC_use + 1; 913 } 914 } 915 916 static int npcm_i2c_slave_get_wr_buf(struct npcm_i2c *bus) 917 { 918 int i; 919 u8 value; 920 int ind; 921 int ret = bus->slv_wr_ind; 922 923 /* fill a cyclic buffer */ 924 for (i = 0; i < I2C_HW_FIFO_SIZE; i++) { 925 if (bus->slv_wr_size >= I2C_HW_FIFO_SIZE) 926 break; 927 i2c_slave_event(bus->slave, I2C_SLAVE_READ_REQUESTED, &value); 928 ind = (bus->slv_wr_ind + bus->slv_wr_size) % I2C_HW_FIFO_SIZE; 929 bus->slv_wr_buf[ind] = value; 930 bus->slv_wr_size++; 931 i2c_slave_event(bus->slave, I2C_SLAVE_READ_PROCESSED, &value); 932 } 933 return I2C_HW_FIFO_SIZE - ret; 934 } 935 936 static void npcm_i2c_slave_send_rd_buf(struct npcm_i2c *bus) 937 { 938 int i; 939 940 for (i = 0; i < bus->slv_rd_ind; i++) 941 i2c_slave_event(bus->slave, I2C_SLAVE_WRITE_RECEIVED, 942 &bus->slv_rd_buf[i]); 943 /* 944 * once we send bytes up, need to reset the counter of the wr buf 945 * got data from master (new offset in device), ignore wr fifo: 946 */ 947 if (bus->slv_rd_ind) { 948 bus->slv_wr_size = 0; 949 bus->slv_wr_ind = 0; 950 } 951 952 bus->slv_rd_ind = 0; 953 bus->slv_rd_size = bus->adap.quirks->max_read_len; 954 955 npcm_i2c_clear_fifo_int(bus); 956 npcm_i2c_clear_rx_fifo(bus); 957 } 958 959 static void npcm_i2c_slave_receive(struct npcm_i2c *bus, u16 nread, 960 u8 *read_data) 961 { 962 bus->state = I2C_OPER_STARTED; 963 bus->operation = I2C_READ_OPER; 964 bus->slv_rd_size = nread; 965 bus->slv_rd_ind = 0; 966 967 iowrite8(0, bus->reg + NPCM_I2CTXF_CTL); 968 iowrite8(I2C_HW_FIFO_SIZE, bus->reg + NPCM_I2CRXF_CTL); 969 npcm_i2c_clear_tx_fifo(bus); 970 npcm_i2c_clear_rx_fifo(bus); 971 } 972 973 static void npcm_i2c_slave_xmit(struct npcm_i2c *bus, u16 nwrite, 974 u8 *write_data) 975 { 976 if (nwrite == 0) 977 return; 978 979 bus->state = I2C_OPER_STARTED; 980 bus->operation = I2C_WRITE_OPER; 981 982 /* get the next buffer */ 983 npcm_i2c_slave_get_wr_buf(bus); 984 npcm_i2c_write_fifo_slave(bus, nwrite); 985 } 986 987 /* 988 * npcm_i2c_slave_wr_buf_sync: 989 * currently slave IF only supports single byte operations. 990 * in order to utilize the npcm HW FIFO, the driver will ask for 16 bytes 991 * at a time, pack them in buffer, and then transmit them all together 992 * to the FIFO and onward to the bus. 993 * NACK on read will be once reached to bus->adap->quirks->max_read_len. 994 * sending a NACK wherever the backend requests for it is not supported. 995 * the next two functions allow reading to local buffer before writing it all 996 * to the HW FIFO. 997 */ 998 static void npcm_i2c_slave_wr_buf_sync(struct npcm_i2c *bus) 999 { 1000 int left_in_fifo; 1001 1002 left_in_fifo = FIELD_GET(NPCM_I2CTXF_STS_TX_BYTES, 1003 ioread8(bus->reg + NPCM_I2CTXF_STS)); 1004 1005 /* fifo already full: */ 1006 if (left_in_fifo >= I2C_HW_FIFO_SIZE || 1007 bus->slv_wr_size >= I2C_HW_FIFO_SIZE) 1008 return; 1009 1010 /* update the wr fifo index back to the untransmitted bytes: */ 1011 bus->slv_wr_ind = bus->slv_wr_ind - left_in_fifo; 1012 bus->slv_wr_size = bus->slv_wr_size + left_in_fifo; 1013 1014 if (bus->slv_wr_ind < 0) 1015 bus->slv_wr_ind += I2C_HW_FIFO_SIZE; 1016 } 1017 1018 static void npcm_i2c_slave_rd_wr(struct npcm_i2c *bus) 1019 { 1020 if (NPCM_I2CST_XMIT & ioread8(bus->reg + NPCM_I2CST)) { 1021 /* 1022 * Slave got an address match with direction bit 1 so it should 1023 * transmit data. Write till the master will NACK 1024 */ 1025 bus->operation = I2C_WRITE_OPER; 1026 npcm_i2c_slave_xmit(bus, bus->adap.quirks->max_write_len, 1027 bus->slv_wr_buf); 1028 } else { 1029 /* 1030 * Slave got an address match with direction bit 0 so it should 1031 * receive data. 1032 * this module does not support saying no to bytes. 1033 * it will always ACK. 1034 */ 1035 bus->operation = I2C_READ_OPER; 1036 npcm_i2c_read_fifo_slave(bus, npcm_i2c_fifo_usage(bus)); 1037 bus->stop_ind = I2C_SLAVE_RCV_IND; 1038 npcm_i2c_slave_send_rd_buf(bus); 1039 npcm_i2c_slave_receive(bus, bus->adap.quirks->max_read_len, 1040 bus->slv_rd_buf); 1041 } 1042 } 1043 1044 static irqreturn_t npcm_i2c_int_slave_handler(struct npcm_i2c *bus) 1045 { 1046 u8 val; 1047 irqreturn_t ret = IRQ_NONE; 1048 u8 i2cst = ioread8(bus->reg + NPCM_I2CST); 1049 1050 /* Slave: A NACK has occurred */ 1051 if (NPCM_I2CST_NEGACK & i2cst) { 1052 bus->stop_ind = I2C_NACK_IND; 1053 npcm_i2c_slave_wr_buf_sync(bus); 1054 if (bus->fifo_use) 1055 /* clear the FIFO */ 1056 iowrite8(NPCM_I2CFIF_CTS_CLR_FIFO, 1057 bus->reg + NPCM_I2CFIF_CTS); 1058 1059 /* In slave write, NACK is OK, otherwise it is a problem */ 1060 bus->stop_ind = I2C_NO_STATUS_IND; 1061 bus->operation = I2C_NO_OPER; 1062 bus->own_slave_addr = 0xFF; 1063 1064 /* 1065 * Slave has to wait for STOP to decide this is the end 1066 * of the transaction. tx is not yet considered as done 1067 */ 1068 iowrite8(NPCM_I2CST_NEGACK, bus->reg + NPCM_I2CST); 1069 1070 ret = IRQ_HANDLED; 1071 } 1072 1073 /* Slave mode: a Bus Error (BER) has been identified */ 1074 if (NPCM_I2CST_BER & i2cst) { 1075 /* 1076 * Check whether bus arbitration or Start or Stop during data 1077 * xfer bus arbitration problem should not result in recovery 1078 */ 1079 bus->stop_ind = I2C_BUS_ERR_IND; 1080 1081 /* wait for bus busy before clear fifo */ 1082 iowrite8(NPCM_I2CFIF_CTS_CLR_FIFO, bus->reg + NPCM_I2CFIF_CTS); 1083 1084 bus->state = I2C_IDLE; 1085 1086 /* 1087 * in BER case we might get 2 interrupts: one for slave one for 1088 * master ( for a channel which is master\slave switching) 1089 */ 1090 if (completion_done(&bus->cmd_complete) == false) { 1091 bus->cmd_err = -EIO; 1092 complete(&bus->cmd_complete); 1093 } 1094 bus->own_slave_addr = 0xFF; 1095 iowrite8(NPCM_I2CST_BER, bus->reg + NPCM_I2CST); 1096 ret = IRQ_HANDLED; 1097 } 1098 1099 /* A Slave Stop Condition has been identified */ 1100 if (NPCM_I2CST_SLVSTP & i2cst) { 1101 u8 bytes_in_fifo = npcm_i2c_fifo_usage(bus); 1102 1103 bus->stop_ind = I2C_SLAVE_DONE_IND; 1104 1105 if (bus->operation == I2C_READ_OPER) 1106 npcm_i2c_read_fifo_slave(bus, bytes_in_fifo); 1107 1108 /* if the buffer is empty nothing will be sent */ 1109 npcm_i2c_slave_send_rd_buf(bus); 1110 1111 /* Slave done transmitting or receiving */ 1112 bus->stop_ind = I2C_NO_STATUS_IND; 1113 1114 /* 1115 * Note, just because we got here, it doesn't mean we through 1116 * away the wr buffer. 1117 * we keep it until the next received offset. 1118 */ 1119 bus->operation = I2C_NO_OPER; 1120 bus->own_slave_addr = 0xFF; 1121 i2c_slave_event(bus->slave, I2C_SLAVE_STOP, 0); 1122 iowrite8(NPCM_I2CST_SLVSTP, bus->reg + NPCM_I2CST); 1123 if (bus->fifo_use) { 1124 npcm_i2c_clear_fifo_int(bus); 1125 npcm_i2c_clear_rx_fifo(bus); 1126 npcm_i2c_clear_tx_fifo(bus); 1127 1128 iowrite8(NPCM_I2CFIF_CTS_CLR_FIFO, 1129 bus->reg + NPCM_I2CFIF_CTS); 1130 } 1131 bus->state = I2C_IDLE; 1132 ret = IRQ_HANDLED; 1133 } 1134 1135 /* restart condition occurred and Rx-FIFO was not empty */ 1136 if (bus->fifo_use && FIELD_GET(NPCM_I2CFIF_CTS_SLVRSTR, 1137 ioread8(bus->reg + NPCM_I2CFIF_CTS))) { 1138 bus->stop_ind = I2C_SLAVE_RESTART_IND; 1139 bus->master_or_slave = I2C_SLAVE; 1140 if (bus->operation == I2C_READ_OPER) 1141 npcm_i2c_read_fifo_slave(bus, npcm_i2c_fifo_usage(bus)); 1142 bus->operation = I2C_WRITE_OPER; 1143 iowrite8(0, bus->reg + NPCM_I2CRXF_CTL); 1144 val = NPCM_I2CFIF_CTS_CLR_FIFO | NPCM_I2CFIF_CTS_SLVRSTR | 1145 NPCM_I2CFIF_CTS_RXF_TXE; 1146 iowrite8(val, bus->reg + NPCM_I2CFIF_CTS); 1147 npcm_i2c_slave_rd_wr(bus); 1148 ret = IRQ_HANDLED; 1149 } 1150 1151 /* A Slave Address Match has been identified */ 1152 if (NPCM_I2CST_NMATCH & i2cst) { 1153 u8 info = 0; 1154 1155 /* Address match automatically implies slave mode */ 1156 bus->master_or_slave = I2C_SLAVE; 1157 npcm_i2c_clear_fifo_int(bus); 1158 npcm_i2c_clear_rx_fifo(bus); 1159 npcm_i2c_clear_tx_fifo(bus); 1160 iowrite8(0, bus->reg + NPCM_I2CTXF_CTL); 1161 iowrite8(I2C_HW_FIFO_SIZE, bus->reg + NPCM_I2CRXF_CTL); 1162 if (NPCM_I2CST_XMIT & i2cst) { 1163 bus->operation = I2C_WRITE_OPER; 1164 } else { 1165 i2c_slave_event(bus->slave, I2C_SLAVE_WRITE_REQUESTED, 1166 &info); 1167 bus->operation = I2C_READ_OPER; 1168 } 1169 if (bus->own_slave_addr == 0xFF) { 1170 /* Check which type of address match */ 1171 val = ioread8(bus->reg + NPCM_I2CCST); 1172 if (NPCM_I2CCST_MATCH & val) { 1173 u16 addr; 1174 enum i2c_addr eaddr; 1175 u8 i2ccst2; 1176 u8 i2ccst3; 1177 1178 i2ccst3 = ioread8(bus->reg + NPCM_I2CCST3); 1179 i2ccst2 = ioread8(bus->reg + NPCM_I2CCST2); 1180 1181 /* 1182 * the i2c module can response to 10 own SA. 1183 * check which one was addressed by the master. 1184 * respond to the first one. 1185 */ 1186 addr = ((i2ccst3 & 0x07) << 7) | 1187 (i2ccst2 & 0x7F); 1188 info = ffs(addr); 1189 eaddr = (enum i2c_addr)info; 1190 addr = npcm_i2c_get_slave_addr(bus, eaddr); 1191 addr &= 0x7F; 1192 bus->own_slave_addr = addr; 1193 if (bus->PEC_mask & BIT(info)) 1194 bus->PEC_use = true; 1195 else 1196 bus->PEC_use = false; 1197 } else { 1198 if (NPCM_I2CCST_GCMATCH & val) 1199 bus->own_slave_addr = 0; 1200 if (NPCM_I2CCST_ARPMATCH & val) 1201 bus->own_slave_addr = 0x61; 1202 } 1203 } else { 1204 /* 1205 * Slave match can happen in two options: 1206 * 1. Start, SA, read (slave read without further ado) 1207 * 2. Start, SA, read, data, restart, SA, read, ... 1208 * (slave read in fragmented mode) 1209 * 3. Start, SA, write, data, restart, SA, read, .. 1210 * (regular write-read mode) 1211 */ 1212 if ((bus->state == I2C_OPER_STARTED && 1213 bus->operation == I2C_READ_OPER && 1214 bus->stop_ind == I2C_SLAVE_XMIT_IND) || 1215 bus->stop_ind == I2C_SLAVE_RCV_IND) { 1216 /* slave tx after slave rx w/o STOP */ 1217 bus->stop_ind = I2C_SLAVE_RESTART_IND; 1218 } 1219 } 1220 1221 if (NPCM_I2CST_XMIT & i2cst) 1222 bus->stop_ind = I2C_SLAVE_XMIT_IND; 1223 else 1224 bus->stop_ind = I2C_SLAVE_RCV_IND; 1225 bus->state = I2C_SLAVE_MATCH; 1226 npcm_i2c_slave_rd_wr(bus); 1227 iowrite8(NPCM_I2CST_NMATCH, bus->reg + NPCM_I2CST); 1228 ret = IRQ_HANDLED; 1229 } 1230 1231 /* Slave SDA status is set - tx or rx */ 1232 if ((NPCM_I2CST_SDAST & i2cst) || 1233 (bus->fifo_use && 1234 (npcm_i2c_tx_fifo_empty(bus) || npcm_i2c_rx_fifo_full(bus)))) { 1235 npcm_i2c_slave_rd_wr(bus); 1236 iowrite8(NPCM_I2CST_SDAST, bus->reg + NPCM_I2CST); 1237 ret = IRQ_HANDLED; 1238 } /* SDAST */ 1239 1240 /* 1241 * if irq is not one of the above, make sure EOB is disabled and all 1242 * status bits are cleared. 1243 */ 1244 if (ret == IRQ_NONE) { 1245 npcm_i2c_eob_int(bus, false); 1246 npcm_i2c_clear_master_status(bus); 1247 } 1248 1249 return IRQ_HANDLED; 1250 } 1251 1252 static int npcm_i2c_reg_slave(struct i2c_client *client) 1253 { 1254 unsigned long lock_flags; 1255 struct npcm_i2c *bus = i2c_get_adapdata(client->adapter); 1256 1257 bus->slave = client; 1258 1259 if (!bus->slave) 1260 return -EINVAL; 1261 1262 if (client->flags & I2C_CLIENT_TEN) 1263 return -EAFNOSUPPORT; 1264 1265 spin_lock_irqsave(&bus->lock, lock_flags); 1266 1267 npcm_i2c_init_params(bus); 1268 bus->slv_rd_size = 0; 1269 bus->slv_wr_size = 0; 1270 bus->slv_rd_ind = 0; 1271 bus->slv_wr_ind = 0; 1272 if (client->flags & I2C_CLIENT_PEC) 1273 bus->PEC_use = true; 1274 1275 dev_info(bus->dev, "i2c%d register slave SA=0x%x, PEC=%d\n", bus->num, 1276 client->addr, bus->PEC_use); 1277 1278 npcm_i2c_slave_enable(bus, I2C_SLAVE_ADDR1, client->addr, true); 1279 npcm_i2c_clear_fifo_int(bus); 1280 npcm_i2c_clear_rx_fifo(bus); 1281 npcm_i2c_clear_tx_fifo(bus); 1282 npcm_i2c_slave_int_enable(bus, true); 1283 1284 spin_unlock_irqrestore(&bus->lock, lock_flags); 1285 return 0; 1286 } 1287 1288 static int npcm_i2c_unreg_slave(struct i2c_client *client) 1289 { 1290 struct npcm_i2c *bus = client->adapter->algo_data; 1291 unsigned long lock_flags; 1292 1293 spin_lock_irqsave(&bus->lock, lock_flags); 1294 if (!bus->slave) { 1295 spin_unlock_irqrestore(&bus->lock, lock_flags); 1296 return -EINVAL; 1297 } 1298 npcm_i2c_slave_int_enable(bus, false); 1299 npcm_i2c_remove_slave_addr(bus, client->addr); 1300 bus->slave = NULL; 1301 spin_unlock_irqrestore(&bus->lock, lock_flags); 1302 return 0; 1303 } 1304 #endif /* CONFIG_I2C_SLAVE */ 1305 1306 static void npcm_i2c_master_fifo_read(struct npcm_i2c *bus) 1307 { 1308 int rcount; 1309 int fifo_bytes; 1310 enum i2c_state_ind ind = I2C_MASTER_DONE_IND; 1311 1312 fifo_bytes = npcm_i2c_fifo_usage(bus); 1313 rcount = bus->rd_size - bus->rd_ind; 1314 1315 /* 1316 * In order not to change the RX_TRH during transaction (we found that 1317 * this might be problematic if it takes too much time to read the FIFO) 1318 * we read the data in the following way. If the number of bytes to 1319 * read == FIFO Size + C (where C < FIFO Size)then first read C bytes 1320 * and in the next int we read rest of the data. 1321 */ 1322 if (rcount < (2 * I2C_HW_FIFO_SIZE) && rcount > I2C_HW_FIFO_SIZE) 1323 fifo_bytes = rcount - I2C_HW_FIFO_SIZE; 1324 1325 if (rcount <= fifo_bytes) { 1326 /* last bytes are about to be read - end of tx */ 1327 bus->state = I2C_STOP_PENDING; 1328 bus->stop_ind = ind; 1329 npcm_i2c_eob_int(bus, true); 1330 /* Stop should be set before reading last byte. */ 1331 npcm_i2c_master_stop(bus); 1332 npcm_i2c_read_fifo(bus, fifo_bytes); 1333 } else { 1334 npcm_i2c_read_fifo(bus, fifo_bytes); 1335 rcount = bus->rd_size - bus->rd_ind; 1336 npcm_i2c_set_fifo(bus, rcount, -1); 1337 } 1338 } 1339 1340 static void npcm_i2c_irq_master_handler_write(struct npcm_i2c *bus) 1341 { 1342 u16 wcount; 1343 1344 if (bus->fifo_use) 1345 npcm_i2c_clear_tx_fifo(bus); /* clear the TX fifo status bit */ 1346 1347 /* Master write operation - last byte handling */ 1348 if (bus->wr_ind == bus->wr_size) { 1349 if (bus->fifo_use && npcm_i2c_fifo_usage(bus) > 0) 1350 /* 1351 * No more bytes to send (to add to the FIFO), 1352 * however the FIFO is not empty yet. It is 1353 * still in the middle of tx. Currently there's nothing 1354 * to do except for waiting to the end of the tx 1355 * We will get an int when the FIFO will get empty. 1356 */ 1357 return; 1358 1359 if (bus->rd_size == 0) { 1360 /* all bytes have been written, in wr only operation */ 1361 npcm_i2c_eob_int(bus, true); 1362 bus->state = I2C_STOP_PENDING; 1363 bus->stop_ind = I2C_MASTER_DONE_IND; 1364 npcm_i2c_master_stop(bus); 1365 /* Clear SDA Status bit (by writing dummy byte) */ 1366 npcm_i2c_wr_byte(bus, 0xFF); 1367 1368 } else { 1369 /* last write-byte written on previous int - restart */ 1370 npcm_i2c_set_fifo(bus, bus->rd_size, -1); 1371 /* Generate repeated start upon next write to SDA */ 1372 npcm_i2c_master_start(bus); 1373 1374 /* 1375 * Receiving one byte only - stall after successful 1376 * completion of send address byte. If we NACK here, and 1377 * slave doesn't ACK the address, we might 1378 * unintentionally NACK the next multi-byte read. 1379 */ 1380 if (bus->rd_size == 1) 1381 npcm_i2c_stall_after_start(bus, true); 1382 1383 /* Next int will occur on read */ 1384 bus->operation = I2C_READ_OPER; 1385 /* send the slave address in read direction */ 1386 npcm_i2c_wr_byte(bus, bus->dest_addr | 0x1); 1387 } 1388 } else { 1389 /* write next byte not last byte and not slave address */ 1390 if (!bus->fifo_use || bus->wr_size == 1) { 1391 npcm_i2c_wr_byte(bus, bus->wr_buf[bus->wr_ind++]); 1392 } else { 1393 wcount = bus->wr_size - bus->wr_ind; 1394 npcm_i2c_set_fifo(bus, -1, wcount); 1395 if (wcount) 1396 npcm_i2c_write_to_fifo_master(bus, wcount); 1397 } 1398 } 1399 } 1400 1401 static void npcm_i2c_irq_master_handler_read(struct npcm_i2c *bus) 1402 { 1403 u16 block_extra_bytes_size; 1404 u8 data; 1405 1406 /* added bytes to the packet: */ 1407 block_extra_bytes_size = bus->read_block_use + bus->PEC_use; 1408 1409 /* 1410 * Perform master read, distinguishing between last byte and the rest of 1411 * the bytes. The last byte should be read when the clock is stopped 1412 */ 1413 if (bus->rd_ind == 0) { /* first byte handling: */ 1414 if (bus->read_block_use) { 1415 /* first byte in block protocol is the size: */ 1416 data = npcm_i2c_rd_byte(bus); 1417 data = clamp_val(data, 1, I2C_SMBUS_BLOCK_MAX); 1418 bus->rd_size = data + block_extra_bytes_size; 1419 bus->rd_buf[bus->rd_ind++] = data; 1420 1421 /* clear RX FIFO interrupt status: */ 1422 if (bus->fifo_use) { 1423 data = ioread8(bus->reg + NPCM_I2CFIF_CTS); 1424 data = data | NPCM_I2CFIF_CTS_RXF_TXE; 1425 iowrite8(data, bus->reg + NPCM_I2CFIF_CTS); 1426 } 1427 1428 npcm_i2c_set_fifo(bus, bus->rd_size - 1, -1); 1429 npcm_i2c_stall_after_start(bus, false); 1430 } else { 1431 npcm_i2c_clear_tx_fifo(bus); 1432 npcm_i2c_master_fifo_read(bus); 1433 } 1434 } else { 1435 if (bus->rd_size == block_extra_bytes_size && 1436 bus->read_block_use) { 1437 bus->state = I2C_STOP_PENDING; 1438 bus->stop_ind = I2C_BLOCK_BYTES_ERR_IND; 1439 bus->cmd_err = -EIO; 1440 npcm_i2c_eob_int(bus, true); 1441 npcm_i2c_master_stop(bus); 1442 npcm_i2c_read_fifo(bus, npcm_i2c_fifo_usage(bus)); 1443 } else { 1444 npcm_i2c_master_fifo_read(bus); 1445 } 1446 } 1447 } 1448 1449 static void npcm_i2c_irq_handle_nmatch(struct npcm_i2c *bus) 1450 { 1451 iowrite8(NPCM_I2CST_NMATCH, bus->reg + NPCM_I2CST); 1452 npcm_i2c_nack(bus); 1453 bus->stop_ind = I2C_BUS_ERR_IND; 1454 npcm_i2c_callback(bus, bus->stop_ind, npcm_i2c_get_index(bus)); 1455 } 1456 1457 /* A NACK has occurred */ 1458 static void npcm_i2c_irq_handle_nack(struct npcm_i2c *bus) 1459 { 1460 u8 val; 1461 1462 if (bus->nack_cnt < ULLONG_MAX) 1463 bus->nack_cnt++; 1464 1465 if (bus->fifo_use) { 1466 /* 1467 * if there are still untransmitted bytes in TX FIFO 1468 * reduce them from wr_ind 1469 */ 1470 if (bus->operation == I2C_WRITE_OPER) 1471 bus->wr_ind -= npcm_i2c_fifo_usage(bus); 1472 1473 /* clear the FIFO */ 1474 iowrite8(NPCM_I2CFIF_CTS_CLR_FIFO, bus->reg + NPCM_I2CFIF_CTS); 1475 } 1476 1477 /* In master write operation, got unexpected NACK */ 1478 bus->stop_ind = I2C_NACK_IND; 1479 /* Only current master is allowed to issue Stop Condition */ 1480 if (npcm_i2c_is_master(bus)) { 1481 /* stopping in the middle */ 1482 npcm_i2c_eob_int(bus, false); 1483 npcm_i2c_master_stop(bus); 1484 1485 /* Clear SDA Status bit (by reading dummy byte) */ 1486 npcm_i2c_rd_byte(bus); 1487 1488 /* 1489 * The bus is released from stall only after the SW clears 1490 * NEGACK bit. Then a Stop condition is sent. 1491 */ 1492 npcm_i2c_clear_master_status(bus); 1493 readx_poll_timeout_atomic(ioread8, bus->reg + NPCM_I2CCST, val, 1494 !(val & NPCM_I2CCST_BUSY), 10, 200); 1495 /* verify no status bits are still set after bus is released */ 1496 npcm_i2c_clear_master_status(bus); 1497 } 1498 bus->state = I2C_IDLE; 1499 1500 /* 1501 * In Master mode, NACK should be cleared only after STOP. 1502 * In such case, the bus is released from stall only after the 1503 * software clears NACK bit. Then a Stop condition is sent. 1504 */ 1505 npcm_i2c_callback(bus, bus->stop_ind, bus->wr_ind); 1506 } 1507 1508 /* Master mode: a Bus Error has been identified */ 1509 static void npcm_i2c_irq_handle_ber(struct npcm_i2c *bus) 1510 { 1511 if (bus->ber_cnt < ULLONG_MAX) 1512 bus->ber_cnt++; 1513 bus->stop_ind = I2C_BUS_ERR_IND; 1514 if (npcm_i2c_is_master(bus)) { 1515 npcm_i2c_master_abort(bus); 1516 } else { 1517 npcm_i2c_clear_master_status(bus); 1518 1519 /* Clear BB (BUS BUSY) bit */ 1520 iowrite8(NPCM_I2CCST_BB, bus->reg + NPCM_I2CCST); 1521 1522 bus->cmd_err = -EAGAIN; 1523 npcm_i2c_callback(bus, bus->stop_ind, npcm_i2c_get_index(bus)); 1524 } 1525 bus->state = I2C_IDLE; 1526 } 1527 1528 /* EOB: a master End Of Busy (meaning STOP completed) */ 1529 static void npcm_i2c_irq_handle_eob(struct npcm_i2c *bus) 1530 { 1531 npcm_i2c_eob_int(bus, false); 1532 bus->state = I2C_IDLE; 1533 npcm_i2c_callback(bus, bus->stop_ind, bus->rd_ind); 1534 } 1535 1536 /* Address sent and requested stall occurred (Master mode) */ 1537 static void npcm_i2c_irq_handle_stall_after_start(struct npcm_i2c *bus) 1538 { 1539 if (npcm_i2c_is_quick(bus)) { 1540 bus->state = I2C_STOP_PENDING; 1541 bus->stop_ind = I2C_MASTER_DONE_IND; 1542 npcm_i2c_eob_int(bus, true); 1543 npcm_i2c_master_stop(bus); 1544 } else if ((bus->rd_size == 1) && !bus->read_block_use) { 1545 /* 1546 * Receiving one byte only - set NACK after ensuring 1547 * slave ACKed the address byte. 1548 */ 1549 npcm_i2c_nack(bus); 1550 } 1551 1552 /* Reset stall-after-address-byte */ 1553 npcm_i2c_stall_after_start(bus, false); 1554 1555 /* Clear stall only after setting STOP */ 1556 iowrite8(NPCM_I2CST_STASTR, bus->reg + NPCM_I2CST); 1557 } 1558 1559 /* SDA status is set - TX or RX, master */ 1560 static void npcm_i2c_irq_handle_sda(struct npcm_i2c *bus, u8 i2cst) 1561 { 1562 u8 fif_cts; 1563 1564 if (!npcm_i2c_is_master(bus)) 1565 return; 1566 1567 if (bus->state == I2C_IDLE) { 1568 bus->stop_ind = I2C_WAKE_UP_IND; 1569 1570 if (npcm_i2c_is_quick(bus) || bus->read_block_use) 1571 /* 1572 * Need to stall after successful 1573 * completion of sending address byte 1574 */ 1575 npcm_i2c_stall_after_start(bus, true); 1576 else 1577 npcm_i2c_stall_after_start(bus, false); 1578 1579 /* 1580 * Receiving one byte only - stall after successful completion 1581 * of sending address byte If we NACK here, and slave doesn't 1582 * ACK the address, we might unintentionally NACK the next 1583 * multi-byte read 1584 */ 1585 if (bus->wr_size == 0 && bus->rd_size == 1) 1586 npcm_i2c_stall_after_start(bus, true); 1587 1588 /* Initiate I2C master tx */ 1589 1590 /* select bank 1 for FIFO regs */ 1591 npcm_i2c_select_bank(bus, I2C_BANK_1); 1592 1593 fif_cts = ioread8(bus->reg + NPCM_I2CFIF_CTS); 1594 fif_cts = fif_cts & ~NPCM_I2CFIF_CTS_SLVRSTR; 1595 1596 /* clear FIFO and relevant status bits. */ 1597 fif_cts = fif_cts | NPCM_I2CFIF_CTS_CLR_FIFO; 1598 iowrite8(fif_cts, bus->reg + NPCM_I2CFIF_CTS); 1599 1600 /* re-enable */ 1601 fif_cts = fif_cts | NPCM_I2CFIF_CTS_RXF_TXE; 1602 iowrite8(fif_cts, bus->reg + NPCM_I2CFIF_CTS); 1603 1604 /* 1605 * Configure the FIFO threshold: 1606 * according to the needed # of bytes to read. 1607 * Note: due to HW limitation can't config the rx fifo before it 1608 * got and ACK on the restart. LAST bit will not be reset unless 1609 * RX completed. It will stay set on the next tx. 1610 */ 1611 if (bus->wr_size) 1612 npcm_i2c_set_fifo(bus, -1, bus->wr_size); 1613 else 1614 npcm_i2c_set_fifo(bus, bus->rd_size, -1); 1615 1616 bus->state = I2C_OPER_STARTED; 1617 1618 if (npcm_i2c_is_quick(bus) || bus->wr_size) 1619 npcm_i2c_wr_byte(bus, bus->dest_addr); 1620 else 1621 npcm_i2c_wr_byte(bus, bus->dest_addr | BIT(0)); 1622 /* SDA interrupt, after start\restart */ 1623 } else { 1624 if (NPCM_I2CST_XMIT & i2cst) { 1625 bus->operation = I2C_WRITE_OPER; 1626 npcm_i2c_irq_master_handler_write(bus); 1627 } else { 1628 bus->operation = I2C_READ_OPER; 1629 npcm_i2c_irq_master_handler_read(bus); 1630 } 1631 } 1632 } 1633 1634 static int npcm_i2c_int_master_handler(struct npcm_i2c *bus) 1635 { 1636 u8 i2cst; 1637 int ret = -EIO; 1638 1639 i2cst = ioread8(bus->reg + NPCM_I2CST); 1640 1641 if (FIELD_GET(NPCM_I2CST_NMATCH, i2cst)) { 1642 npcm_i2c_irq_handle_nmatch(bus); 1643 return 0; 1644 } 1645 /* A NACK has occurred */ 1646 if (FIELD_GET(NPCM_I2CST_NEGACK, i2cst)) { 1647 npcm_i2c_irq_handle_nack(bus); 1648 return 0; 1649 } 1650 1651 /* Master mode: a Bus Error has been identified */ 1652 if (FIELD_GET(NPCM_I2CST_BER, i2cst)) { 1653 npcm_i2c_irq_handle_ber(bus); 1654 return 0; 1655 } 1656 1657 /* EOB: a master End Of Busy (meaning STOP completed) */ 1658 if ((FIELD_GET(NPCM_I2CCTL1_EOBINTE, 1659 ioread8(bus->reg + NPCM_I2CCTL1)) == 1) && 1660 (FIELD_GET(NPCM_I2CCST3_EO_BUSY, 1661 ioread8(bus->reg + NPCM_I2CCST3)))) { 1662 npcm_i2c_irq_handle_eob(bus); 1663 return 0; 1664 } 1665 1666 /* Address sent and requested stall occurred (Master mode) */ 1667 if (FIELD_GET(NPCM_I2CST_STASTR, i2cst)) { 1668 npcm_i2c_irq_handle_stall_after_start(bus); 1669 ret = 0; 1670 } 1671 1672 /* SDA status is set - TX or RX, master */ 1673 if (FIELD_GET(NPCM_I2CST_SDAST, i2cst) || 1674 (bus->fifo_use && 1675 (npcm_i2c_tx_fifo_empty(bus) || npcm_i2c_rx_fifo_full(bus)))) { 1676 npcm_i2c_irq_handle_sda(bus, i2cst); 1677 ret = 0; 1678 } 1679 1680 return ret; 1681 } 1682 1683 /* recovery using TGCLK functionality of the module */ 1684 static int npcm_i2c_recovery_tgclk(struct i2c_adapter *_adap) 1685 { 1686 u8 val; 1687 u8 fif_cts; 1688 bool done = false; 1689 int status = -ENOTRECOVERABLE; 1690 struct npcm_i2c *bus = container_of(_adap, struct npcm_i2c, adap); 1691 /* Allow 3 bytes (27 toggles) to be read from the slave: */ 1692 int iter = 27; 1693 1694 if ((npcm_i2c_get_SDA(_adap) == 1) && (npcm_i2c_get_SCL(_adap) == 1)) { 1695 dev_dbg(bus->dev, "bus%d-0x%x recovery skipped, bus not stuck", 1696 bus->num, bus->dest_addr); 1697 npcm_i2c_reset(bus); 1698 return 0; 1699 } 1700 1701 npcm_i2c_int_enable(bus, false); 1702 npcm_i2c_disable(bus); 1703 npcm_i2c_enable(bus); 1704 iowrite8(NPCM_I2CCST_BB, bus->reg + NPCM_I2CCST); 1705 npcm_i2c_clear_tx_fifo(bus); 1706 npcm_i2c_clear_rx_fifo(bus); 1707 iowrite8(0, bus->reg + NPCM_I2CRXF_CTL); 1708 iowrite8(0, bus->reg + NPCM_I2CTXF_CTL); 1709 npcm_i2c_stall_after_start(bus, false); 1710 1711 /* select bank 1 for FIFO regs */ 1712 npcm_i2c_select_bank(bus, I2C_BANK_1); 1713 1714 /* clear FIFO and relevant status bits. */ 1715 fif_cts = ioread8(bus->reg + NPCM_I2CFIF_CTS); 1716 fif_cts &= ~NPCM_I2CFIF_CTS_SLVRSTR; 1717 fif_cts |= NPCM_I2CFIF_CTS_CLR_FIFO; 1718 iowrite8(fif_cts, bus->reg + NPCM_I2CFIF_CTS); 1719 npcm_i2c_set_fifo(bus, -1, 0); 1720 1721 /* Repeat the following sequence until SDA is released */ 1722 do { 1723 /* Issue a single SCL toggle */ 1724 iowrite8(NPCM_I2CCST_TGSCL, bus->reg + NPCM_I2CCST); 1725 usleep_range(20, 30); 1726 /* If SDA line is inactive (high), stop */ 1727 if (npcm_i2c_get_SDA(_adap)) { 1728 done = true; 1729 status = 0; 1730 } 1731 } while (!done && iter--); 1732 1733 /* If SDA line is released: send start-addr-stop, to re-sync. */ 1734 if (npcm_i2c_get_SDA(_adap)) { 1735 /* Send an address byte in write direction: */ 1736 npcm_i2c_wr_byte(bus, bus->dest_addr); 1737 npcm_i2c_master_start(bus); 1738 /* Wait until START condition is sent */ 1739 status = readx_poll_timeout(npcm_i2c_get_SCL, _adap, val, !val, 1740 20, 200); 1741 /* If START condition was sent */ 1742 if (npcm_i2c_is_master(bus) > 0) { 1743 usleep_range(20, 30); 1744 npcm_i2c_master_stop(bus); 1745 usleep_range(200, 500); 1746 } 1747 } 1748 npcm_i2c_reset(bus); 1749 npcm_i2c_int_enable(bus, true); 1750 1751 if ((npcm_i2c_get_SDA(_adap) == 1) && (npcm_i2c_get_SCL(_adap) == 1)) 1752 status = 0; 1753 else 1754 status = -ENOTRECOVERABLE; 1755 if (status) { 1756 if (bus->rec_fail_cnt < ULLONG_MAX) 1757 bus->rec_fail_cnt++; 1758 } else { 1759 if (bus->rec_succ_cnt < ULLONG_MAX) 1760 bus->rec_succ_cnt++; 1761 } 1762 return status; 1763 } 1764 1765 /* recovery using bit banging functionality of the module */ 1766 static void npcm_i2c_recovery_init(struct i2c_adapter *_adap) 1767 { 1768 struct npcm_i2c *bus = container_of(_adap, struct npcm_i2c, adap); 1769 struct i2c_bus_recovery_info *rinfo = &bus->rinfo; 1770 1771 rinfo->recover_bus = npcm_i2c_recovery_tgclk; 1772 1773 /* 1774 * npcm i2c HW allows direct reading of SCL and SDA. 1775 * However, it does not support setting SCL and SDA directly. 1776 * The recovery function can toggle SCL when SDA is low (but not set) 1777 * Getter functions used internally, and can be used externally. 1778 */ 1779 rinfo->get_scl = npcm_i2c_get_SCL; 1780 rinfo->get_sda = npcm_i2c_get_SDA; 1781 _adap->bus_recovery_info = rinfo; 1782 } 1783 1784 /* SCLFRQ min/max field values */ 1785 #define SCLFRQ_MIN 10 1786 #define SCLFRQ_MAX 511 1787 #define clk_coef(freq, mul) DIV_ROUND_UP((freq) * (mul), 1000000) 1788 1789 /* 1790 * npcm_i2c_init_clk: init HW timing parameters. 1791 * NPCM7XX i2c module timing parameters are dependent on module core clk (APB) 1792 * and bus frequency. 1793 * 100kHz bus requires tSCL = 4 * SCLFRQ * tCLK. LT and HT are symmetric. 1794 * 400kHz bus requires asymmetric HT and LT. A different equation is recommended 1795 * by the HW designer, given core clock range (equations in comments below). 1796 * 1797 */ 1798 static int npcm_i2c_init_clk(struct npcm_i2c *bus, u32 bus_freq_hz) 1799 { 1800 u32 k1 = 0; 1801 u32 k2 = 0; 1802 u8 dbnct = 0; 1803 u32 sclfrq = 0; 1804 u8 hldt = 7; 1805 u8 fast_mode = 0; 1806 u32 src_clk_khz; 1807 u32 bus_freq_khz; 1808 1809 src_clk_khz = bus->apb_clk / 1000; 1810 bus_freq_khz = bus_freq_hz / 1000; 1811 bus->bus_freq = bus_freq_hz; 1812 1813 /* 100KHz and below: */ 1814 if (bus_freq_hz <= I2C_MAX_STANDARD_MODE_FREQ) { 1815 sclfrq = src_clk_khz / (bus_freq_khz * 4); 1816 1817 if (sclfrq < SCLFRQ_MIN || sclfrq > SCLFRQ_MAX) 1818 return -EDOM; 1819 1820 if (src_clk_khz >= 40000) 1821 hldt = 17; 1822 else if (src_clk_khz >= 12500) 1823 hldt = 15; 1824 else 1825 hldt = 7; 1826 } 1827 1828 /* 400KHz: */ 1829 else if (bus_freq_hz <= I2C_MAX_FAST_MODE_FREQ) { 1830 sclfrq = 0; 1831 fast_mode = I2CCTL3_400K_MODE; 1832 1833 if (src_clk_khz < 7500) 1834 /* 400KHZ cannot be supported for core clock < 7.5MHz */ 1835 return -EDOM; 1836 1837 else if (src_clk_khz >= 50000) { 1838 k1 = 80; 1839 k2 = 48; 1840 hldt = 12; 1841 dbnct = 7; 1842 } 1843 1844 /* Master or Slave with frequency > 25MHz */ 1845 else if (src_clk_khz > 25000) { 1846 hldt = clk_coef(src_clk_khz, 300) + 7; 1847 k1 = clk_coef(src_clk_khz, 1600); 1848 k2 = clk_coef(src_clk_khz, 900); 1849 } 1850 } 1851 1852 /* 1MHz: */ 1853 else if (bus_freq_hz <= I2C_MAX_FAST_MODE_PLUS_FREQ) { 1854 sclfrq = 0; 1855 fast_mode = I2CCTL3_400K_MODE; 1856 1857 /* 1MHZ cannot be supported for core clock < 24 MHz */ 1858 if (src_clk_khz < 24000) 1859 return -EDOM; 1860 1861 k1 = clk_coef(src_clk_khz, 620); 1862 k2 = clk_coef(src_clk_khz, 380); 1863 1864 /* Core clk > 40 MHz */ 1865 if (src_clk_khz > 40000) { 1866 /* 1867 * Set HLDT: 1868 * SDA hold time: (HLDT-7) * T(CLK) >= 120 1869 * HLDT = 120/T(CLK) + 7 = 120 * FREQ(CLK) + 7 1870 */ 1871 hldt = clk_coef(src_clk_khz, 120) + 7; 1872 } else { 1873 hldt = 7; 1874 dbnct = 2; 1875 } 1876 } 1877 1878 /* Frequency larger than 1 MHz is not supported */ 1879 else 1880 return -EINVAL; 1881 1882 if (bus_freq_hz >= I2C_MAX_FAST_MODE_FREQ) { 1883 k1 = round_up(k1, 2); 1884 k2 = round_up(k2 + 1, 2); 1885 if (k1 < SCLFRQ_MIN || k1 > SCLFRQ_MAX || 1886 k2 < SCLFRQ_MIN || k2 > SCLFRQ_MAX) 1887 return -EDOM; 1888 } 1889 1890 /* write sclfrq value. bits [6:0] are in I2CCTL2 reg */ 1891 iowrite8(FIELD_PREP(I2CCTL2_SCLFRQ6_0, sclfrq & 0x7F), 1892 bus->reg + NPCM_I2CCTL2); 1893 1894 /* bits [8:7] are in I2CCTL3 reg */ 1895 iowrite8(fast_mode | FIELD_PREP(I2CCTL3_SCLFRQ8_7, (sclfrq >> 7) & 0x3), 1896 bus->reg + NPCM_I2CCTL3); 1897 1898 /* Select Bank 0 to access NPCM_I2CCTL4/NPCM_I2CCTL5 */ 1899 npcm_i2c_select_bank(bus, I2C_BANK_0); 1900 1901 if (bus_freq_hz >= I2C_MAX_FAST_MODE_FREQ) { 1902 /* 1903 * Set SCL Low/High Time: 1904 * k1 = 2 * SCLLT7-0 -> Low Time = k1 / 2 1905 * k2 = 2 * SCLLT7-0 -> High Time = k2 / 2 1906 */ 1907 iowrite8(k1 / 2, bus->reg + NPCM_I2CSCLLT); 1908 iowrite8(k2 / 2, bus->reg + NPCM_I2CSCLHT); 1909 1910 iowrite8(dbnct, bus->reg + NPCM_I2CCTL5); 1911 } 1912 1913 iowrite8(hldt, bus->reg + NPCM_I2CCTL4); 1914 1915 /* Return to Bank 1, and stay there by default: */ 1916 npcm_i2c_select_bank(bus, I2C_BANK_1); 1917 1918 return 0; 1919 } 1920 1921 static int npcm_i2c_init_module(struct npcm_i2c *bus, enum i2c_mode mode, 1922 u32 bus_freq_hz) 1923 { 1924 u8 val; 1925 int ret; 1926 1927 /* Check whether module already enabled or frequency is out of bounds */ 1928 if ((bus->state != I2C_DISABLE && bus->state != I2C_IDLE) || 1929 bus_freq_hz < I2C_FREQ_MIN_HZ || bus_freq_hz > I2C_FREQ_MAX_HZ) 1930 return -EINVAL; 1931 1932 npcm_i2c_int_enable(bus, false); 1933 npcm_i2c_disable(bus); 1934 1935 /* Configure FIFO mode : */ 1936 if (FIELD_GET(I2C_VER_FIFO_EN, ioread8(bus->reg + I2C_VER))) { 1937 bus->fifo_use = true; 1938 npcm_i2c_select_bank(bus, I2C_BANK_0); 1939 val = ioread8(bus->reg + NPCM_I2CFIF_CTL); 1940 val |= NPCM_I2CFIF_CTL_FIFO_EN; 1941 iowrite8(val, bus->reg + NPCM_I2CFIF_CTL); 1942 npcm_i2c_select_bank(bus, I2C_BANK_1); 1943 } else { 1944 bus->fifo_use = false; 1945 } 1946 1947 /* Configure I2C module clock frequency */ 1948 ret = npcm_i2c_init_clk(bus, bus_freq_hz); 1949 if (ret) { 1950 dev_err(bus->dev, "npcm_i2c_init_clk failed\n"); 1951 return ret; 1952 } 1953 1954 /* Enable module (before configuring CTL1) */ 1955 npcm_i2c_enable(bus); 1956 bus->state = I2C_IDLE; 1957 val = ioread8(bus->reg + NPCM_I2CCTL1); 1958 val = (val | NPCM_I2CCTL1_NMINTE) & ~NPCM_I2CCTL1_RWS; 1959 iowrite8(val, bus->reg + NPCM_I2CCTL1); 1960 1961 npcm_i2c_reset(bus); 1962 1963 /* check HW is OK: SDA and SCL should be high at this point. */ 1964 if ((npcm_i2c_get_SDA(&bus->adap) == 0) || (npcm_i2c_get_SCL(&bus->adap) == 0)) { 1965 dev_err(bus->dev, "I2C%d init fail: lines are low\n", bus->num); 1966 dev_err(bus->dev, "SDA=%d SCL=%d\n", npcm_i2c_get_SDA(&bus->adap), 1967 npcm_i2c_get_SCL(&bus->adap)); 1968 return -ENXIO; 1969 } 1970 1971 npcm_i2c_int_enable(bus, true); 1972 return 0; 1973 } 1974 1975 static int __npcm_i2c_init(struct npcm_i2c *bus, struct platform_device *pdev) 1976 { 1977 u32 clk_freq_hz; 1978 int ret; 1979 1980 /* Initialize the internal data structures */ 1981 bus->state = I2C_DISABLE; 1982 bus->master_or_slave = I2C_SLAVE; 1983 bus->int_time_stamp = 0; 1984 #if IS_ENABLED(CONFIG_I2C_SLAVE) 1985 bus->slave = NULL; 1986 #endif 1987 1988 ret = device_property_read_u32(&pdev->dev, "clock-frequency", 1989 &clk_freq_hz); 1990 if (ret) { 1991 dev_info(&pdev->dev, "Could not read clock-frequency property"); 1992 clk_freq_hz = I2C_MAX_STANDARD_MODE_FREQ; 1993 } 1994 1995 ret = npcm_i2c_init_module(bus, I2C_MASTER, clk_freq_hz); 1996 if (ret) { 1997 dev_err(&pdev->dev, "npcm_i2c_init_module failed\n"); 1998 return ret; 1999 } 2000 2001 return 0; 2002 } 2003 2004 static irqreturn_t npcm_i2c_bus_irq(int irq, void *dev_id) 2005 { 2006 struct npcm_i2c *bus = dev_id; 2007 2008 if (npcm_i2c_is_master(bus)) 2009 bus->master_or_slave = I2C_MASTER; 2010 2011 if (bus->master_or_slave == I2C_MASTER) { 2012 bus->int_time_stamp = jiffies; 2013 if (!npcm_i2c_int_master_handler(bus)) 2014 return IRQ_HANDLED; 2015 } 2016 #if IS_ENABLED(CONFIG_I2C_SLAVE) 2017 if (bus->slave) { 2018 bus->master_or_slave = I2C_SLAVE; 2019 if (npcm_i2c_int_slave_handler(bus)) 2020 return IRQ_HANDLED; 2021 } 2022 #endif 2023 /* clear status bits for spurious interrupts */ 2024 npcm_i2c_clear_master_status(bus); 2025 2026 return IRQ_HANDLED; 2027 } 2028 2029 static bool npcm_i2c_master_start_xmit(struct npcm_i2c *bus, 2030 u8 slave_addr, u16 nwrite, u16 nread, 2031 u8 *write_data, u8 *read_data, 2032 bool use_PEC, bool use_read_block) 2033 { 2034 if (bus->state != I2C_IDLE) { 2035 bus->cmd_err = -EBUSY; 2036 return false; 2037 } 2038 bus->dest_addr = slave_addr << 1; 2039 bus->wr_buf = write_data; 2040 bus->wr_size = nwrite; 2041 bus->wr_ind = 0; 2042 bus->rd_buf = read_data; 2043 bus->rd_size = nread; 2044 bus->rd_ind = 0; 2045 bus->PEC_use = 0; 2046 2047 /* for tx PEC is appended to buffer from i2c IF. PEC flag is ignored */ 2048 if (nread) 2049 bus->PEC_use = use_PEC; 2050 2051 bus->read_block_use = use_read_block; 2052 if (nread && !nwrite) 2053 bus->operation = I2C_READ_OPER; 2054 else 2055 bus->operation = I2C_WRITE_OPER; 2056 if (bus->fifo_use) { 2057 u8 i2cfif_cts; 2058 2059 npcm_i2c_select_bank(bus, I2C_BANK_1); 2060 /* clear FIFO and relevant status bits. */ 2061 i2cfif_cts = ioread8(bus->reg + NPCM_I2CFIF_CTS); 2062 i2cfif_cts &= ~NPCM_I2CFIF_CTS_SLVRSTR; 2063 i2cfif_cts |= NPCM_I2CFIF_CTS_CLR_FIFO; 2064 iowrite8(i2cfif_cts, bus->reg + NPCM_I2CFIF_CTS); 2065 } 2066 2067 bus->state = I2C_IDLE; 2068 npcm_i2c_stall_after_start(bus, true); 2069 npcm_i2c_master_start(bus); 2070 return true; 2071 } 2072 2073 static int npcm_i2c_master_xfer(struct i2c_adapter *adap, struct i2c_msg *msgs, 2074 int num) 2075 { 2076 struct npcm_i2c *bus = container_of(adap, struct npcm_i2c, adap); 2077 struct i2c_msg *msg0, *msg1; 2078 unsigned long time_left, flags; 2079 u16 nwrite, nread; 2080 u8 *write_data, *read_data; 2081 u8 slave_addr; 2082 unsigned long timeout; 2083 bool read_block = false; 2084 bool read_PEC = false; 2085 u8 bus_busy; 2086 unsigned long timeout_usec; 2087 2088 if (bus->state == I2C_DISABLE) { 2089 dev_err(bus->dev, "I2C%d module is disabled", bus->num); 2090 return -EINVAL; 2091 } 2092 2093 msg0 = &msgs[0]; 2094 slave_addr = msg0->addr; 2095 if (msg0->flags & I2C_M_RD) { /* read */ 2096 nwrite = 0; 2097 write_data = NULL; 2098 read_data = msg0->buf; 2099 if (msg0->flags & I2C_M_RECV_LEN) { 2100 nread = 1; 2101 read_block = true; 2102 if (msg0->flags & I2C_CLIENT_PEC) 2103 read_PEC = true; 2104 } else { 2105 nread = msg0->len; 2106 } 2107 } else { /* write */ 2108 nwrite = msg0->len; 2109 write_data = msg0->buf; 2110 nread = 0; 2111 read_data = NULL; 2112 if (num == 2) { 2113 msg1 = &msgs[1]; 2114 read_data = msg1->buf; 2115 if (msg1->flags & I2C_M_RECV_LEN) { 2116 nread = 1; 2117 read_block = true; 2118 if (msg1->flags & I2C_CLIENT_PEC) 2119 read_PEC = true; 2120 } else { 2121 nread = msg1->len; 2122 read_block = false; 2123 } 2124 } 2125 } 2126 2127 /* 2128 * Adaptive TimeOut: estimated time in usec + 100% margin: 2129 * 2: double the timeout for clock stretching case 2130 * 9: bits per transaction (including the ack/nack) 2131 */ 2132 timeout_usec = (2 * 9 * USEC_PER_SEC / bus->bus_freq) * (2 + nread + nwrite); 2133 timeout = max_t(unsigned long, bus->adap.timeout, usecs_to_jiffies(timeout_usec)); 2134 if (nwrite >= 32 * 1024 || nread >= 32 * 1024) { 2135 dev_err(bus->dev, "i2c%d buffer too big\n", bus->num); 2136 return -EINVAL; 2137 } 2138 2139 time_left = jiffies + timeout + 1; 2140 do { 2141 /* 2142 * we must clear slave address immediately when the bus is not 2143 * busy, so we spinlock it, but we don't keep the lock for the 2144 * entire while since it is too long. 2145 */ 2146 spin_lock_irqsave(&bus->lock, flags); 2147 bus_busy = ioread8(bus->reg + NPCM_I2CCST) & NPCM_I2CCST_BB; 2148 #if IS_ENABLED(CONFIG_I2C_SLAVE) 2149 if (!bus_busy && bus->slave) 2150 iowrite8((bus->slave->addr & 0x7F), 2151 bus->reg + NPCM_I2CADDR1); 2152 #endif 2153 spin_unlock_irqrestore(&bus->lock, flags); 2154 2155 } while (time_is_after_jiffies(time_left) && bus_busy); 2156 2157 if (bus_busy) { 2158 iowrite8(NPCM_I2CCST_BB, bus->reg + NPCM_I2CCST); 2159 npcm_i2c_reset(bus); 2160 i2c_recover_bus(adap); 2161 return -EAGAIN; 2162 } 2163 2164 npcm_i2c_init_params(bus); 2165 bus->dest_addr = slave_addr; 2166 bus->msgs = msgs; 2167 bus->msgs_num = num; 2168 bus->cmd_err = 0; 2169 bus->read_block_use = read_block; 2170 2171 reinit_completion(&bus->cmd_complete); 2172 2173 npcm_i2c_int_enable(bus, true); 2174 2175 if (npcm_i2c_master_start_xmit(bus, slave_addr, nwrite, nread, 2176 write_data, read_data, read_PEC, 2177 read_block)) { 2178 time_left = wait_for_completion_timeout(&bus->cmd_complete, 2179 timeout); 2180 2181 if (time_left == 0) { 2182 if (bus->timeout_cnt < ULLONG_MAX) 2183 bus->timeout_cnt++; 2184 if (bus->master_or_slave == I2C_MASTER) { 2185 i2c_recover_bus(adap); 2186 bus->cmd_err = -EIO; 2187 bus->state = I2C_IDLE; 2188 } 2189 } 2190 } 2191 2192 /* if there was BER, check if need to recover the bus: */ 2193 if (bus->cmd_err == -EAGAIN) 2194 bus->cmd_err = i2c_recover_bus(adap); 2195 2196 /* 2197 * After any type of error, check if LAST bit is still set, 2198 * due to a HW issue. 2199 * It cannot be cleared without resetting the module. 2200 */ 2201 else if (bus->cmd_err && 2202 (NPCM_I2CRXF_CTL_LAST_PEC & ioread8(bus->reg + NPCM_I2CRXF_CTL))) 2203 npcm_i2c_reset(bus); 2204 2205 /* after any xfer, successful or not, stall and EOB must be disabled */ 2206 npcm_i2c_stall_after_start(bus, false); 2207 npcm_i2c_eob_int(bus, false); 2208 2209 #if IS_ENABLED(CONFIG_I2C_SLAVE) 2210 /* reenable slave if it was enabled */ 2211 if (bus->slave) 2212 iowrite8((bus->slave->addr & 0x7F) | NPCM_I2CADDR_SAEN, 2213 bus->reg + NPCM_I2CADDR1); 2214 #else 2215 npcm_i2c_int_enable(bus, false); 2216 #endif 2217 return bus->cmd_err; 2218 } 2219 2220 static u32 npcm_i2c_functionality(struct i2c_adapter *adap) 2221 { 2222 return I2C_FUNC_I2C | 2223 I2C_FUNC_SMBUS_EMUL | 2224 I2C_FUNC_SMBUS_BLOCK_DATA | 2225 I2C_FUNC_SMBUS_PEC | 2226 I2C_FUNC_SLAVE; 2227 } 2228 2229 static const struct i2c_adapter_quirks npcm_i2c_quirks = { 2230 .max_read_len = 32768, 2231 .max_write_len = 32768, 2232 .flags = I2C_AQ_COMB_WRITE_THEN_READ, 2233 }; 2234 2235 static const struct i2c_algorithm npcm_i2c_algo = { 2236 .master_xfer = npcm_i2c_master_xfer, 2237 .functionality = npcm_i2c_functionality, 2238 #if IS_ENABLED(CONFIG_I2C_SLAVE) 2239 .reg_slave = npcm_i2c_reg_slave, 2240 .unreg_slave = npcm_i2c_unreg_slave, 2241 #endif 2242 }; 2243 2244 /* i2c debugfs directory: used to keep health monitor of i2c devices */ 2245 static struct dentry *npcm_i2c_debugfs_dir; 2246 2247 static void npcm_i2c_init_debugfs(struct platform_device *pdev, 2248 struct npcm_i2c *bus) 2249 { 2250 struct dentry *d; 2251 2252 if (!npcm_i2c_debugfs_dir) 2253 return; 2254 d = debugfs_create_dir(dev_name(&pdev->dev), npcm_i2c_debugfs_dir); 2255 if (IS_ERR_OR_NULL(d)) 2256 return; 2257 debugfs_create_u64("ber_cnt", 0444, d, &bus->ber_cnt); 2258 debugfs_create_u64("nack_cnt", 0444, d, &bus->nack_cnt); 2259 debugfs_create_u64("rec_succ_cnt", 0444, d, &bus->rec_succ_cnt); 2260 debugfs_create_u64("rec_fail_cnt", 0444, d, &bus->rec_fail_cnt); 2261 debugfs_create_u64("timeout_cnt", 0444, d, &bus->timeout_cnt); 2262 debugfs_create_u64("tx_complete_cnt", 0444, d, &bus->tx_complete_cnt); 2263 2264 bus->debugfs = d; 2265 } 2266 2267 static int npcm_i2c_probe_bus(struct platform_device *pdev) 2268 { 2269 struct device_node *np = pdev->dev.of_node; 2270 static struct regmap *gcr_regmap; 2271 struct i2c_adapter *adap; 2272 struct npcm_i2c *bus; 2273 struct clk *i2c_clk; 2274 int irq; 2275 int ret; 2276 2277 bus = devm_kzalloc(&pdev->dev, sizeof(*bus), GFP_KERNEL); 2278 if (!bus) 2279 return -ENOMEM; 2280 2281 bus->dev = &pdev->dev; 2282 2283 bus->num = of_alias_get_id(pdev->dev.of_node, "i2c"); 2284 /* core clk must be acquired to calculate module timing settings */ 2285 i2c_clk = devm_clk_get(&pdev->dev, NULL); 2286 if (IS_ERR(i2c_clk)) 2287 return PTR_ERR(i2c_clk); 2288 bus->apb_clk = clk_get_rate(i2c_clk); 2289 2290 gcr_regmap = syscon_regmap_lookup_by_phandle(np, "nuvoton,sys-mgr"); 2291 if (IS_ERR(gcr_regmap)) 2292 gcr_regmap = syscon_regmap_lookup_by_compatible("nuvoton,npcm750-gcr"); 2293 2294 if (IS_ERR(gcr_regmap)) 2295 return PTR_ERR(gcr_regmap); 2296 regmap_write(gcr_regmap, NPCM_I2CSEGCTL, NPCM_I2CSEGCTL_INIT_VAL); 2297 2298 bus->reg = devm_platform_ioremap_resource(pdev, 0); 2299 if (IS_ERR(bus->reg)) 2300 return PTR_ERR(bus->reg); 2301 2302 spin_lock_init(&bus->lock); 2303 init_completion(&bus->cmd_complete); 2304 2305 adap = &bus->adap; 2306 adap->owner = THIS_MODULE; 2307 adap->retries = 3; 2308 adap->timeout = msecs_to_jiffies(35); 2309 adap->algo = &npcm_i2c_algo; 2310 adap->quirks = &npcm_i2c_quirks; 2311 adap->algo_data = bus; 2312 adap->dev.parent = &pdev->dev; 2313 adap->dev.of_node = pdev->dev.of_node; 2314 adap->nr = pdev->id; 2315 2316 irq = platform_get_irq(pdev, 0); 2317 if (irq < 0) 2318 return irq; 2319 2320 ret = devm_request_irq(bus->dev, irq, npcm_i2c_bus_irq, 0, 2321 dev_name(bus->dev), bus); 2322 if (ret) 2323 return ret; 2324 2325 ret = __npcm_i2c_init(bus, pdev); 2326 if (ret) 2327 return ret; 2328 2329 npcm_i2c_recovery_init(adap); 2330 2331 i2c_set_adapdata(adap, bus); 2332 2333 snprintf(bus->adap.name, sizeof(bus->adap.name), "npcm_i2c_%d", 2334 bus->num); 2335 ret = i2c_add_numbered_adapter(&bus->adap); 2336 if (ret) 2337 return ret; 2338 2339 platform_set_drvdata(pdev, bus); 2340 npcm_i2c_init_debugfs(pdev, bus); 2341 return 0; 2342 } 2343 2344 static int npcm_i2c_remove_bus(struct platform_device *pdev) 2345 { 2346 unsigned long lock_flags; 2347 struct npcm_i2c *bus = platform_get_drvdata(pdev); 2348 2349 debugfs_remove_recursive(bus->debugfs); 2350 spin_lock_irqsave(&bus->lock, lock_flags); 2351 npcm_i2c_disable(bus); 2352 spin_unlock_irqrestore(&bus->lock, lock_flags); 2353 i2c_del_adapter(&bus->adap); 2354 return 0; 2355 } 2356 2357 static const struct of_device_id npcm_i2c_bus_of_table[] = { 2358 { .compatible = "nuvoton,npcm750-i2c", }, 2359 {} 2360 }; 2361 MODULE_DEVICE_TABLE(of, npcm_i2c_bus_of_table); 2362 2363 static struct platform_driver npcm_i2c_bus_driver = { 2364 .probe = npcm_i2c_probe_bus, 2365 .remove = npcm_i2c_remove_bus, 2366 .driver = { 2367 .name = "nuvoton-i2c", 2368 .of_match_table = npcm_i2c_bus_of_table, 2369 } 2370 }; 2371 2372 static int __init npcm_i2c_init(void) 2373 { 2374 npcm_i2c_debugfs_dir = debugfs_create_dir("npcm_i2c", NULL); 2375 return platform_driver_register(&npcm_i2c_bus_driver); 2376 } 2377 module_init(npcm_i2c_init); 2378 2379 static void __exit npcm_i2c_exit(void) 2380 { 2381 platform_driver_unregister(&npcm_i2c_bus_driver); 2382 debugfs_remove_recursive(npcm_i2c_debugfs_dir); 2383 } 2384 module_exit(npcm_i2c_exit); 2385 2386 MODULE_AUTHOR("Avi Fishman <avi.fishman@gmail.com>"); 2387 MODULE_AUTHOR("Tali Perry <tali.perry@nuvoton.com>"); 2388 MODULE_AUTHOR("Tyrone Ting <kfting@nuvoton.com>"); 2389 MODULE_DESCRIPTION("Nuvoton I2C Bus Driver"); 2390 MODULE_LICENSE("GPL v2"); 2391