mvebu-uart.c 41 KB

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  1. // SPDX-License-Identifier: GPL-2.0+
  2. /*
  3. * ***************************************************************************
  4. * Marvell Armada-3700 Serial Driver
  5. * Author: Wilson Ding <dingwei@marvell.com>
  6. * Copyright (C) 2015 Marvell International Ltd.
  7. * ***************************************************************************
  8. */
  9. #include <linux/clk.h>
  10. #include <linux/clk-provider.h>
  11. #include <linux/console.h>
  12. #include <linux/delay.h>
  13. #include <linux/device.h>
  14. #include <linux/init.h>
  15. #include <linux/io.h>
  16. #include <linux/iopoll.h>
  17. #include <linux/math64.h>
  18. #include <linux/of.h>
  19. #include <linux/of_address.h>
  20. #include <linux/of_device.h>
  21. #include <linux/of_irq.h>
  22. #include <linux/of_platform.h>
  23. #include <linux/platform_device.h>
  24. #include <linux/serial.h>
  25. #include <linux/serial_core.h>
  26. #include <linux/slab.h>
  27. #include <linux/tty.h>
  28. #include <linux/tty_flip.h>
  29. /* Register Map */
  30. #define UART_STD_RBR 0x00
  31. #define UART_EXT_RBR 0x18
  32. #define UART_STD_TSH 0x04
  33. #define UART_EXT_TSH 0x1C
  34. #define UART_STD_CTRL1 0x08
  35. #define UART_EXT_CTRL1 0x04
  36. #define CTRL_SOFT_RST BIT(31)
  37. #define CTRL_TXFIFO_RST BIT(15)
  38. #define CTRL_RXFIFO_RST BIT(14)
  39. #define CTRL_SND_BRK_SEQ BIT(11)
  40. #define CTRL_BRK_DET_INT BIT(3)
  41. #define CTRL_FRM_ERR_INT BIT(2)
  42. #define CTRL_PAR_ERR_INT BIT(1)
  43. #define CTRL_OVR_ERR_INT BIT(0)
  44. #define CTRL_BRK_INT (CTRL_BRK_DET_INT | CTRL_FRM_ERR_INT | \
  45. CTRL_PAR_ERR_INT | CTRL_OVR_ERR_INT)
  46. #define UART_STD_CTRL2 UART_STD_CTRL1
  47. #define UART_EXT_CTRL2 0x20
  48. #define CTRL_STD_TX_RDY_INT BIT(5)
  49. #define CTRL_EXT_TX_RDY_INT BIT(6)
  50. #define CTRL_STD_RX_RDY_INT BIT(4)
  51. #define CTRL_EXT_RX_RDY_INT BIT(5)
  52. #define UART_STAT 0x0C
  53. #define STAT_TX_FIFO_EMP BIT(13)
  54. #define STAT_TX_FIFO_FUL BIT(11)
  55. #define STAT_TX_EMP BIT(6)
  56. #define STAT_STD_TX_RDY BIT(5)
  57. #define STAT_EXT_TX_RDY BIT(15)
  58. #define STAT_STD_RX_RDY BIT(4)
  59. #define STAT_EXT_RX_RDY BIT(14)
  60. #define STAT_BRK_DET BIT(3)
  61. #define STAT_FRM_ERR BIT(2)
  62. #define STAT_PAR_ERR BIT(1)
  63. #define STAT_OVR_ERR BIT(0)
  64. #define STAT_BRK_ERR (STAT_BRK_DET | STAT_FRM_ERR \
  65. | STAT_PAR_ERR | STAT_OVR_ERR)
  66. /*
  67. * Marvell Armada 3700 Functional Specifications describes that bit 21 of UART
  68. * Clock Control register controls UART1 and bit 20 controls UART2. But in
  69. * reality bit 21 controls UART2 and bit 20 controls UART1. This seems to be an
  70. * error in Marvell's documentation. Hence following CLK_DIS macros are swapped.
  71. */
  72. #define UART_BRDV 0x10
  73. /* These bits are located in UART1 address space and control UART2 */
  74. #define UART2_CLK_DIS BIT(21)
  75. /* These bits are located in UART1 address space and control UART1 */
  76. #define UART1_CLK_DIS BIT(20)
  77. /* These bits are located in UART1 address space and control both UARTs */
  78. #define CLK_NO_XTAL BIT(19)
  79. #define CLK_TBG_DIV1_SHIFT 15
  80. #define CLK_TBG_DIV1_MASK 0x7
  81. #define CLK_TBG_DIV1_MAX 6
  82. #define CLK_TBG_DIV2_SHIFT 12
  83. #define CLK_TBG_DIV2_MASK 0x7
  84. #define CLK_TBG_DIV2_MAX 6
  85. #define CLK_TBG_SEL_SHIFT 10
  86. #define CLK_TBG_SEL_MASK 0x3
  87. /* These bits are located in both UARTs address space */
  88. #define BRDV_BAUD_MASK 0x3FF
  89. #define BRDV_BAUD_MAX BRDV_BAUD_MASK
  90. #define UART_OSAMP 0x14
  91. #define OSAMP_DEFAULT_DIVISOR 16
  92. #define OSAMP_DIVISORS_MASK 0x3F3F3F3F
  93. #define OSAMP_MAX_DIVISOR 63
  94. #define MVEBU_NR_UARTS 2
  95. #define MVEBU_UART_TYPE "mvebu-uart"
  96. #define DRIVER_NAME "mvebu_serial"
  97. enum {
  98. /* Either there is only one summed IRQ... */
  99. UART_IRQ_SUM = 0,
  100. /* ...or there are two separate IRQ for RX and TX */
  101. UART_RX_IRQ = 0,
  102. UART_TX_IRQ,
  103. UART_IRQ_COUNT
  104. };
  105. /* Diverging register offsets */
  106. struct uart_regs_layout {
  107. unsigned int rbr;
  108. unsigned int tsh;
  109. unsigned int ctrl;
  110. unsigned int intr;
  111. };
  112. /* Diverging flags */
  113. struct uart_flags {
  114. unsigned int ctrl_tx_rdy_int;
  115. unsigned int ctrl_rx_rdy_int;
  116. unsigned int stat_tx_rdy;
  117. unsigned int stat_rx_rdy;
  118. };
  119. /* Driver data, a structure for each UART port */
  120. struct mvebu_uart_driver_data {
  121. bool is_ext;
  122. struct uart_regs_layout regs;
  123. struct uart_flags flags;
  124. };
  125. /* Saved registers during suspend */
  126. struct mvebu_uart_pm_regs {
  127. unsigned int rbr;
  128. unsigned int tsh;
  129. unsigned int ctrl;
  130. unsigned int intr;
  131. unsigned int stat;
  132. unsigned int brdv;
  133. unsigned int osamp;
  134. };
  135. /* MVEBU UART driver structure */
  136. struct mvebu_uart {
  137. struct uart_port *port;
  138. struct clk *clk;
  139. int irq[UART_IRQ_COUNT];
  140. struct mvebu_uart_driver_data *data;
  141. #if defined(CONFIG_PM)
  142. struct mvebu_uart_pm_regs pm_regs;
  143. #endif /* CONFIG_PM */
  144. };
  145. static struct mvebu_uart *to_mvuart(struct uart_port *port)
  146. {
  147. return (struct mvebu_uart *)port->private_data;
  148. }
  149. #define IS_EXTENDED(port) (to_mvuart(port)->data->is_ext)
  150. #define UART_RBR(port) (to_mvuart(port)->data->regs.rbr)
  151. #define UART_TSH(port) (to_mvuart(port)->data->regs.tsh)
  152. #define UART_CTRL(port) (to_mvuart(port)->data->regs.ctrl)
  153. #define UART_INTR(port) (to_mvuart(port)->data->regs.intr)
  154. #define CTRL_TX_RDY_INT(port) (to_mvuart(port)->data->flags.ctrl_tx_rdy_int)
  155. #define CTRL_RX_RDY_INT(port) (to_mvuart(port)->data->flags.ctrl_rx_rdy_int)
  156. #define STAT_TX_RDY(port) (to_mvuart(port)->data->flags.stat_tx_rdy)
  157. #define STAT_RX_RDY(port) (to_mvuart(port)->data->flags.stat_rx_rdy)
  158. static struct uart_port mvebu_uart_ports[MVEBU_NR_UARTS];
  159. static DEFINE_SPINLOCK(mvebu_uart_lock);
  160. /* Core UART Driver Operations */
  161. static unsigned int mvebu_uart_tx_empty(struct uart_port *port)
  162. {
  163. unsigned long flags;
  164. unsigned int st;
  165. uart_port_lock_irqsave(port, &flags);
  166. st = readl(port->membase + UART_STAT);
  167. uart_port_unlock_irqrestore(port, flags);
  168. return (st & STAT_TX_EMP) ? TIOCSER_TEMT : 0;
  169. }
  170. static unsigned int mvebu_uart_get_mctrl(struct uart_port *port)
  171. {
  172. return TIOCM_CTS | TIOCM_DSR | TIOCM_CAR;
  173. }
  174. static void mvebu_uart_set_mctrl(struct uart_port *port,
  175. unsigned int mctrl)
  176. {
  177. /*
  178. * Even if we do not support configuring the modem control lines, this
  179. * function must be proided to the serial core
  180. */
  181. }
  182. static void mvebu_uart_stop_tx(struct uart_port *port)
  183. {
  184. unsigned int ctl = readl(port->membase + UART_INTR(port));
  185. ctl &= ~CTRL_TX_RDY_INT(port);
  186. writel(ctl, port->membase + UART_INTR(port));
  187. }
  188. static void mvebu_uart_start_tx(struct uart_port *port)
  189. {
  190. unsigned int ctl;
  191. unsigned char c;
  192. if (IS_EXTENDED(port) && uart_fifo_get(port, &c))
  193. writel(c, port->membase + UART_TSH(port));
  194. ctl = readl(port->membase + UART_INTR(port));
  195. ctl |= CTRL_TX_RDY_INT(port);
  196. writel(ctl, port->membase + UART_INTR(port));
  197. }
  198. static void mvebu_uart_stop_rx(struct uart_port *port)
  199. {
  200. unsigned int ctl;
  201. ctl = readl(port->membase + UART_CTRL(port));
  202. ctl &= ~CTRL_BRK_INT;
  203. writel(ctl, port->membase + UART_CTRL(port));
  204. ctl = readl(port->membase + UART_INTR(port));
  205. ctl &= ~CTRL_RX_RDY_INT(port);
  206. writel(ctl, port->membase + UART_INTR(port));
  207. }
  208. static void mvebu_uart_break_ctl(struct uart_port *port, int brk)
  209. {
  210. unsigned int ctl;
  211. unsigned long flags;
  212. uart_port_lock_irqsave(port, &flags);
  213. ctl = readl(port->membase + UART_CTRL(port));
  214. if (brk == -1)
  215. ctl |= CTRL_SND_BRK_SEQ;
  216. else
  217. ctl &= ~CTRL_SND_BRK_SEQ;
  218. writel(ctl, port->membase + UART_CTRL(port));
  219. uart_port_unlock_irqrestore(port, flags);
  220. }
  221. static void mvebu_uart_rx_chars(struct uart_port *port, unsigned int status)
  222. {
  223. struct tty_port *tport = &port->state->port;
  224. unsigned char ch = 0;
  225. char flag = 0;
  226. int ret;
  227. do {
  228. if (status & STAT_RX_RDY(port)) {
  229. ch = readl(port->membase + UART_RBR(port));
  230. ch &= 0xff;
  231. flag = TTY_NORMAL;
  232. port->icount.rx++;
  233. if (status & STAT_PAR_ERR)
  234. port->icount.parity++;
  235. }
  236. /*
  237. * For UART2, error bits are not cleared on buffer read.
  238. * This causes interrupt loop and system hang.
  239. */
  240. if (IS_EXTENDED(port) && (status & STAT_BRK_ERR)) {
  241. ret = readl(port->membase + UART_STAT);
  242. ret |= STAT_BRK_ERR;
  243. writel(ret, port->membase + UART_STAT);
  244. }
  245. if (status & STAT_BRK_DET) {
  246. port->icount.brk++;
  247. status &= ~(STAT_FRM_ERR | STAT_PAR_ERR);
  248. if (uart_handle_break(port))
  249. goto ignore_char;
  250. }
  251. if (status & STAT_OVR_ERR)
  252. port->icount.overrun++;
  253. if (status & STAT_FRM_ERR)
  254. port->icount.frame++;
  255. if (uart_handle_sysrq_char(port, ch))
  256. goto ignore_char;
  257. if (status & port->ignore_status_mask & STAT_PAR_ERR)
  258. status &= ~STAT_RX_RDY(port);
  259. status &= port->read_status_mask;
  260. if (status & STAT_PAR_ERR)
  261. flag = TTY_PARITY;
  262. status &= ~port->ignore_status_mask;
  263. if (status & STAT_RX_RDY(port))
  264. tty_insert_flip_char(tport, ch, flag);
  265. if (status & STAT_BRK_DET)
  266. tty_insert_flip_char(tport, 0, TTY_BREAK);
  267. if (status & STAT_FRM_ERR)
  268. tty_insert_flip_char(tport, 0, TTY_FRAME);
  269. if (status & STAT_OVR_ERR)
  270. tty_insert_flip_char(tport, 0, TTY_OVERRUN);
  271. ignore_char:
  272. status = readl(port->membase + UART_STAT);
  273. } while (status & (STAT_RX_RDY(port) | STAT_BRK_DET));
  274. tty_flip_buffer_push(tport);
  275. }
  276. static void mvebu_uart_tx_chars(struct uart_port *port, unsigned int status)
  277. {
  278. u8 ch;
  279. uart_port_tx_limited(port, ch, port->fifosize,
  280. !(readl(port->membase + UART_STAT) & STAT_TX_FIFO_FUL),
  281. writel(ch, port->membase + UART_TSH(port)),
  282. ({}));
  283. }
  284. static irqreturn_t mvebu_uart_isr(int irq, void *dev_id)
  285. {
  286. struct uart_port *port = (struct uart_port *)dev_id;
  287. unsigned int st = readl(port->membase + UART_STAT);
  288. if (st & (STAT_RX_RDY(port) | STAT_OVR_ERR | STAT_FRM_ERR |
  289. STAT_BRK_DET))
  290. mvebu_uart_rx_chars(port, st);
  291. if (st & STAT_TX_RDY(port))
  292. mvebu_uart_tx_chars(port, st);
  293. return IRQ_HANDLED;
  294. }
  295. static irqreturn_t mvebu_uart_rx_isr(int irq, void *dev_id)
  296. {
  297. struct uart_port *port = (struct uart_port *)dev_id;
  298. unsigned int st = readl(port->membase + UART_STAT);
  299. if (st & (STAT_RX_RDY(port) | STAT_OVR_ERR | STAT_FRM_ERR |
  300. STAT_BRK_DET))
  301. mvebu_uart_rx_chars(port, st);
  302. return IRQ_HANDLED;
  303. }
  304. static irqreturn_t mvebu_uart_tx_isr(int irq, void *dev_id)
  305. {
  306. struct uart_port *port = (struct uart_port *)dev_id;
  307. unsigned int st = readl(port->membase + UART_STAT);
  308. if (st & STAT_TX_RDY(port))
  309. mvebu_uart_tx_chars(port, st);
  310. return IRQ_HANDLED;
  311. }
  312. static int mvebu_uart_startup(struct uart_port *port)
  313. {
  314. struct mvebu_uart *mvuart = to_mvuart(port);
  315. unsigned int ctl;
  316. int ret;
  317. writel(CTRL_TXFIFO_RST | CTRL_RXFIFO_RST,
  318. port->membase + UART_CTRL(port));
  319. udelay(1);
  320. /* Clear the error bits of state register before IRQ request */
  321. ret = readl(port->membase + UART_STAT);
  322. ret |= STAT_BRK_ERR;
  323. writel(ret, port->membase + UART_STAT);
  324. writel(CTRL_BRK_INT, port->membase + UART_CTRL(port));
  325. ctl = readl(port->membase + UART_INTR(port));
  326. ctl |= CTRL_RX_RDY_INT(port);
  327. writel(ctl, port->membase + UART_INTR(port));
  328. if (!mvuart->irq[UART_TX_IRQ]) {
  329. /* Old bindings with just one interrupt (UART0 only) */
  330. ret = devm_request_irq(port->dev, mvuart->irq[UART_IRQ_SUM],
  331. mvebu_uart_isr, port->irqflags,
  332. dev_name(port->dev), port);
  333. if (ret) {
  334. dev_err(port->dev, "unable to request IRQ %d\n",
  335. mvuart->irq[UART_IRQ_SUM]);
  336. return ret;
  337. }
  338. } else {
  339. /* New bindings with an IRQ for RX and TX (both UART) */
  340. ret = devm_request_irq(port->dev, mvuart->irq[UART_RX_IRQ],
  341. mvebu_uart_rx_isr, port->irqflags,
  342. dev_name(port->dev), port);
  343. if (ret) {
  344. dev_err(port->dev, "unable to request IRQ %d\n",
  345. mvuart->irq[UART_RX_IRQ]);
  346. return ret;
  347. }
  348. ret = devm_request_irq(port->dev, mvuart->irq[UART_TX_IRQ],
  349. mvebu_uart_tx_isr, port->irqflags,
  350. dev_name(port->dev),
  351. port);
  352. if (ret) {
  353. dev_err(port->dev, "unable to request IRQ %d\n",
  354. mvuart->irq[UART_TX_IRQ]);
  355. devm_free_irq(port->dev, mvuart->irq[UART_RX_IRQ],
  356. port);
  357. return ret;
  358. }
  359. }
  360. return 0;
  361. }
  362. static void mvebu_uart_shutdown(struct uart_port *port)
  363. {
  364. struct mvebu_uart *mvuart = to_mvuart(port);
  365. writel(0, port->membase + UART_INTR(port));
  366. if (!mvuart->irq[UART_TX_IRQ]) {
  367. devm_free_irq(port->dev, mvuart->irq[UART_IRQ_SUM], port);
  368. } else {
  369. devm_free_irq(port->dev, mvuart->irq[UART_RX_IRQ], port);
  370. devm_free_irq(port->dev, mvuart->irq[UART_TX_IRQ], port);
  371. }
  372. }
  373. static unsigned int mvebu_uart_baud_rate_set(struct uart_port *port, unsigned int baud)
  374. {
  375. unsigned int d_divisor, m_divisor;
  376. unsigned long flags;
  377. u32 brdv, osamp;
  378. if (!port->uartclk)
  379. return 0;
  380. /*
  381. * The baudrate is derived from the UART clock thanks to divisors:
  382. * > d1 * d2 ("TBG divisors"): can divide only TBG clock from 1 to 6
  383. * > D ("baud generator"): can divide the clock from 1 to 1023
  384. * > M ("fractional divisor"): allows a better accuracy (from 1 to 63)
  385. *
  386. * Exact formulas for calculating baudrate:
  387. *
  388. * with default x16 scheme:
  389. * baudrate = xtal / (d * 16)
  390. * baudrate = tbg / (d1 * d2 * d * 16)
  391. *
  392. * with fractional divisor:
  393. * baudrate = 10 * xtal / (d * (3 * (m1 + m2) + 2 * (m3 + m4)))
  394. * baudrate = 10 * tbg / (d1*d2 * d * (3 * (m1 + m2) + 2 * (m3 + m4)))
  395. *
  396. * Oversampling value:
  397. * osamp = (m1 << 0) | (m2 << 8) | (m3 << 16) | (m4 << 24);
  398. *
  399. * Where m1 controls number of clock cycles per bit for bits 1,2,3;
  400. * m2 for bits 4,5,6; m3 for bits 7,8 and m4 for bits 9,10.
  401. *
  402. * To simplify baudrate setup set all the M prescalers to the same
  403. * value. For baudrates 9600 Bd and higher, it is enough to use the
  404. * default (x16) divisor or fractional divisor with M = 63, so there
  405. * is no need to use real fractional support (where the M prescalers
  406. * are not equal).
  407. *
  408. * When all the M prescalers are zeroed then default (x16) divisor is
  409. * used. Default x16 scheme is more stable than M (fractional divisor),
  410. * so use M only when D divisor is not enough to derive baudrate.
  411. *
  412. * Member port->uartclk is either xtal clock rate or TBG clock rate
  413. * divided by (d1 * d2). So d1 and d2 are already set by the UART clock
  414. * driver (and UART driver itself cannot change them). Moreover they are
  415. * shared between both UARTs.
  416. */
  417. m_divisor = OSAMP_DEFAULT_DIVISOR;
  418. d_divisor = DIV_ROUND_CLOSEST(port->uartclk, baud * m_divisor);
  419. if (d_divisor > BRDV_BAUD_MAX) {
  420. /*
  421. * Experiments show that small M divisors are unstable.
  422. * Use maximal possible M = 63 and calculate D divisor.
  423. */
  424. m_divisor = OSAMP_MAX_DIVISOR;
  425. d_divisor = DIV_ROUND_CLOSEST(port->uartclk, baud * m_divisor);
  426. }
  427. if (d_divisor < 1)
  428. d_divisor = 1;
  429. else if (d_divisor > BRDV_BAUD_MAX)
  430. d_divisor = BRDV_BAUD_MAX;
  431. spin_lock_irqsave(&mvebu_uart_lock, flags);
  432. brdv = readl(port->membase + UART_BRDV);
  433. brdv &= ~BRDV_BAUD_MASK;
  434. brdv |= d_divisor;
  435. writel(brdv, port->membase + UART_BRDV);
  436. spin_unlock_irqrestore(&mvebu_uart_lock, flags);
  437. osamp = readl(port->membase + UART_OSAMP);
  438. osamp &= ~OSAMP_DIVISORS_MASK;
  439. if (m_divisor != OSAMP_DEFAULT_DIVISOR)
  440. osamp |= (m_divisor << 0) | (m_divisor << 8) |
  441. (m_divisor << 16) | (m_divisor << 24);
  442. writel(osamp, port->membase + UART_OSAMP);
  443. return DIV_ROUND_CLOSEST(port->uartclk, d_divisor * m_divisor);
  444. }
  445. static void mvebu_uart_set_termios(struct uart_port *port,
  446. struct ktermios *termios,
  447. const struct ktermios *old)
  448. {
  449. unsigned long flags;
  450. unsigned int baud, min_baud, max_baud;
  451. uart_port_lock_irqsave(port, &flags);
  452. port->read_status_mask = STAT_RX_RDY(port) | STAT_OVR_ERR |
  453. STAT_TX_RDY(port) | STAT_TX_FIFO_FUL;
  454. if (termios->c_iflag & INPCK)
  455. port->read_status_mask |= STAT_FRM_ERR | STAT_PAR_ERR;
  456. port->ignore_status_mask = 0;
  457. if (termios->c_iflag & IGNPAR)
  458. port->ignore_status_mask |=
  459. STAT_FRM_ERR | STAT_PAR_ERR | STAT_OVR_ERR;
  460. if ((termios->c_cflag & CREAD) == 0)
  461. port->ignore_status_mask |= STAT_RX_RDY(port) | STAT_BRK_ERR;
  462. /*
  463. * Maximal divisor is 1023 and maximal fractional divisor is 63. And
  464. * experiments show that baudrates above 1/80 of parent clock rate are
  465. * not stable. So disallow baudrates above 1/80 of the parent clock
  466. * rate. If port->uartclk is not available, then
  467. * mvebu_uart_baud_rate_set() fails, so values min_baud and max_baud
  468. * in this case do not matter.
  469. */
  470. min_baud = DIV_ROUND_UP(port->uartclk, BRDV_BAUD_MAX *
  471. OSAMP_MAX_DIVISOR);
  472. max_baud = port->uartclk / 80;
  473. baud = uart_get_baud_rate(port, termios, old, min_baud, max_baud);
  474. baud = mvebu_uart_baud_rate_set(port, baud);
  475. /* In case baudrate cannot be changed, report previous old value */
  476. if (baud == 0 && old)
  477. baud = tty_termios_baud_rate(old);
  478. /* Only the following flag changes are supported */
  479. if (old) {
  480. termios->c_iflag &= INPCK | IGNPAR;
  481. termios->c_iflag |= old->c_iflag & ~(INPCK | IGNPAR);
  482. termios->c_cflag &= CREAD | CBAUD;
  483. termios->c_cflag |= old->c_cflag & ~(CREAD | CBAUD);
  484. termios->c_cflag |= CS8;
  485. }
  486. if (baud != 0) {
  487. tty_termios_encode_baud_rate(termios, baud, baud);
  488. uart_update_timeout(port, termios->c_cflag, baud);
  489. }
  490. uart_port_unlock_irqrestore(port, flags);
  491. }
  492. static const char *mvebu_uart_type(struct uart_port *port)
  493. {
  494. return MVEBU_UART_TYPE;
  495. }
  496. static void mvebu_uart_release_port(struct uart_port *port)
  497. {
  498. /* Nothing to do here */
  499. }
  500. static int mvebu_uart_request_port(struct uart_port *port)
  501. {
  502. return 0;
  503. }
  504. #ifdef CONFIG_CONSOLE_POLL
  505. static int mvebu_uart_get_poll_char(struct uart_port *port)
  506. {
  507. unsigned int st = readl(port->membase + UART_STAT);
  508. if (!(st & STAT_RX_RDY(port)))
  509. return NO_POLL_CHAR;
  510. return readl(port->membase + UART_RBR(port));
  511. }
  512. static void mvebu_uart_put_poll_char(struct uart_port *port, unsigned char c)
  513. {
  514. unsigned int st;
  515. for (;;) {
  516. st = readl(port->membase + UART_STAT);
  517. if (!(st & STAT_TX_FIFO_FUL))
  518. break;
  519. udelay(1);
  520. }
  521. writel(c, port->membase + UART_TSH(port));
  522. }
  523. #endif
  524. static const struct uart_ops mvebu_uart_ops = {
  525. .tx_empty = mvebu_uart_tx_empty,
  526. .set_mctrl = mvebu_uart_set_mctrl,
  527. .get_mctrl = mvebu_uart_get_mctrl,
  528. .stop_tx = mvebu_uart_stop_tx,
  529. .start_tx = mvebu_uart_start_tx,
  530. .stop_rx = mvebu_uart_stop_rx,
  531. .break_ctl = mvebu_uart_break_ctl,
  532. .startup = mvebu_uart_startup,
  533. .shutdown = mvebu_uart_shutdown,
  534. .set_termios = mvebu_uart_set_termios,
  535. .type = mvebu_uart_type,
  536. .release_port = mvebu_uart_release_port,
  537. .request_port = mvebu_uart_request_port,
  538. #ifdef CONFIG_CONSOLE_POLL
  539. .poll_get_char = mvebu_uart_get_poll_char,
  540. .poll_put_char = mvebu_uart_put_poll_char,
  541. #endif
  542. };
  543. /* Console Driver Operations */
  544. #ifdef CONFIG_SERIAL_MVEBU_CONSOLE
  545. /* Early Console */
  546. static void mvebu_uart_putc(struct uart_port *port, unsigned char c)
  547. {
  548. unsigned int st;
  549. for (;;) {
  550. st = readl(port->membase + UART_STAT);
  551. if (!(st & STAT_TX_FIFO_FUL))
  552. break;
  553. }
  554. /* At early stage, DT is not parsed yet, only use UART0 */
  555. writel(c, port->membase + UART_STD_TSH);
  556. for (;;) {
  557. st = readl(port->membase + UART_STAT);
  558. if (st & STAT_TX_FIFO_EMP)
  559. break;
  560. }
  561. }
  562. static void mvebu_uart_putc_early_write(struct console *con,
  563. const char *s,
  564. unsigned int n)
  565. {
  566. struct earlycon_device *dev = con->data;
  567. uart_console_write(&dev->port, s, n, mvebu_uart_putc);
  568. }
  569. static int __init
  570. mvebu_uart_early_console_setup(struct earlycon_device *device,
  571. const char *opt)
  572. {
  573. if (!device->port.membase)
  574. return -ENODEV;
  575. device->con->write = mvebu_uart_putc_early_write;
  576. return 0;
  577. }
  578. EARLYCON_DECLARE(ar3700_uart, mvebu_uart_early_console_setup);
  579. OF_EARLYCON_DECLARE(ar3700_uart, "marvell,armada-3700-uart",
  580. mvebu_uart_early_console_setup);
  581. static void wait_for_xmitr(struct uart_port *port)
  582. {
  583. u32 val;
  584. readl_poll_timeout_atomic(port->membase + UART_STAT, val,
  585. (val & STAT_TX_RDY(port)), 1, 10000);
  586. }
  587. static void wait_for_xmite(struct uart_port *port)
  588. {
  589. u32 val;
  590. readl_poll_timeout_atomic(port->membase + UART_STAT, val,
  591. (val & STAT_TX_EMP), 1, 10000);
  592. }
  593. static void mvebu_uart_console_putchar(struct uart_port *port, unsigned char ch)
  594. {
  595. wait_for_xmitr(port);
  596. writel(ch, port->membase + UART_TSH(port));
  597. }
  598. static void mvebu_uart_console_write(struct console *co, const char *s,
  599. unsigned int count)
  600. {
  601. struct uart_port *port = &mvebu_uart_ports[co->index];
  602. unsigned long flags;
  603. unsigned int ier, intr, ctl;
  604. int locked = 1;
  605. if (oops_in_progress)
  606. locked = uart_port_trylock_irqsave(port, &flags);
  607. else
  608. uart_port_lock_irqsave(port, &flags);
  609. ier = readl(port->membase + UART_CTRL(port)) & CTRL_BRK_INT;
  610. intr = readl(port->membase + UART_INTR(port)) &
  611. (CTRL_RX_RDY_INT(port) | CTRL_TX_RDY_INT(port));
  612. writel(0, port->membase + UART_CTRL(port));
  613. writel(0, port->membase + UART_INTR(port));
  614. uart_console_write(port, s, count, mvebu_uart_console_putchar);
  615. wait_for_xmite(port);
  616. if (ier)
  617. writel(ier, port->membase + UART_CTRL(port));
  618. if (intr) {
  619. ctl = intr | readl(port->membase + UART_INTR(port));
  620. writel(ctl, port->membase + UART_INTR(port));
  621. }
  622. if (locked)
  623. uart_port_unlock_irqrestore(port, flags);
  624. }
  625. static int mvebu_uart_console_setup(struct console *co, char *options)
  626. {
  627. struct uart_port *port;
  628. int baud = 9600;
  629. int bits = 8;
  630. int parity = 'n';
  631. int flow = 'n';
  632. if (co->index < 0 || co->index >= MVEBU_NR_UARTS)
  633. return -EINVAL;
  634. port = &mvebu_uart_ports[co->index];
  635. if (!port->mapbase || !port->membase) {
  636. pr_debug("console on ttyMV%i not present\n", co->index);
  637. return -ENODEV;
  638. }
  639. if (options)
  640. uart_parse_options(options, &baud, &parity, &bits, &flow);
  641. return uart_set_options(port, co, baud, parity, bits, flow);
  642. }
  643. static struct uart_driver mvebu_uart_driver;
  644. static struct console mvebu_uart_console = {
  645. .name = "ttyMV",
  646. .write = mvebu_uart_console_write,
  647. .device = uart_console_device,
  648. .setup = mvebu_uart_console_setup,
  649. .flags = CON_PRINTBUFFER,
  650. .index = -1,
  651. .data = &mvebu_uart_driver,
  652. };
  653. static int __init mvebu_uart_console_init(void)
  654. {
  655. register_console(&mvebu_uart_console);
  656. return 0;
  657. }
  658. console_initcall(mvebu_uart_console_init);
  659. #endif /* CONFIG_SERIAL_MVEBU_CONSOLE */
  660. static struct uart_driver mvebu_uart_driver = {
  661. .owner = THIS_MODULE,
  662. .driver_name = DRIVER_NAME,
  663. .dev_name = "ttyMV",
  664. .nr = MVEBU_NR_UARTS,
  665. #ifdef CONFIG_SERIAL_MVEBU_CONSOLE
  666. .cons = &mvebu_uart_console,
  667. #endif
  668. };
  669. #if defined(CONFIG_PM)
  670. static int mvebu_uart_suspend(struct device *dev)
  671. {
  672. struct mvebu_uart *mvuart = dev_get_drvdata(dev);
  673. struct uart_port *port = mvuart->port;
  674. unsigned long flags;
  675. uart_suspend_port(&mvebu_uart_driver, port);
  676. mvuart->pm_regs.rbr = readl(port->membase + UART_RBR(port));
  677. mvuart->pm_regs.tsh = readl(port->membase + UART_TSH(port));
  678. mvuart->pm_regs.ctrl = readl(port->membase + UART_CTRL(port));
  679. mvuart->pm_regs.intr = readl(port->membase + UART_INTR(port));
  680. mvuart->pm_regs.stat = readl(port->membase + UART_STAT);
  681. spin_lock_irqsave(&mvebu_uart_lock, flags);
  682. mvuart->pm_regs.brdv = readl(port->membase + UART_BRDV);
  683. spin_unlock_irqrestore(&mvebu_uart_lock, flags);
  684. mvuart->pm_regs.osamp = readl(port->membase + UART_OSAMP);
  685. device_set_wakeup_enable(dev, true);
  686. return 0;
  687. }
  688. static int mvebu_uart_resume(struct device *dev)
  689. {
  690. struct mvebu_uart *mvuart = dev_get_drvdata(dev);
  691. struct uart_port *port = mvuart->port;
  692. unsigned long flags;
  693. writel(mvuart->pm_regs.rbr, port->membase + UART_RBR(port));
  694. writel(mvuart->pm_regs.tsh, port->membase + UART_TSH(port));
  695. writel(mvuart->pm_regs.ctrl, port->membase + UART_CTRL(port));
  696. writel(mvuart->pm_regs.intr, port->membase + UART_INTR(port));
  697. writel(mvuart->pm_regs.stat, port->membase + UART_STAT);
  698. spin_lock_irqsave(&mvebu_uart_lock, flags);
  699. writel(mvuart->pm_regs.brdv, port->membase + UART_BRDV);
  700. spin_unlock_irqrestore(&mvebu_uart_lock, flags);
  701. writel(mvuart->pm_regs.osamp, port->membase + UART_OSAMP);
  702. uart_resume_port(&mvebu_uart_driver, port);
  703. return 0;
  704. }
  705. static const struct dev_pm_ops mvebu_uart_pm_ops = {
  706. .suspend = mvebu_uart_suspend,
  707. .resume = mvebu_uart_resume,
  708. };
  709. #endif /* CONFIG_PM */
  710. static const struct of_device_id mvebu_uart_of_match[];
  711. /* Counter to keep track of each UART port id when not using CONFIG_OF */
  712. static int uart_num_counter;
  713. static int mvebu_uart_probe(struct platform_device *pdev)
  714. {
  715. const struct of_device_id *match = of_match_device(mvebu_uart_of_match,
  716. &pdev->dev);
  717. struct uart_port *port;
  718. struct mvebu_uart *mvuart;
  719. struct resource *reg;
  720. int id, irq;
  721. /* Assume that all UART ports have a DT alias or none has */
  722. id = of_alias_get_id(pdev->dev.of_node, "serial");
  723. if (!pdev->dev.of_node || id < 0)
  724. pdev->id = uart_num_counter++;
  725. else
  726. pdev->id = id;
  727. if (pdev->id >= MVEBU_NR_UARTS) {
  728. dev_err(&pdev->dev, "cannot have more than %d UART ports\n",
  729. MVEBU_NR_UARTS);
  730. return -EINVAL;
  731. }
  732. port = &mvebu_uart_ports[pdev->id];
  733. spin_lock_init(&port->lock);
  734. port->dev = &pdev->dev;
  735. port->type = PORT_MVEBU;
  736. port->ops = &mvebu_uart_ops;
  737. port->regshift = 0;
  738. port->fifosize = 32;
  739. port->iotype = UPIO_MEM32;
  740. port->flags = UPF_FIXED_PORT;
  741. port->line = pdev->id;
  742. /*
  743. * IRQ number is not stored in this structure because we may have two of
  744. * them per port (RX and TX). Instead, use the driver UART structure
  745. * array so called ->irq[].
  746. */
  747. port->irq = 0;
  748. port->irqflags = 0;
  749. port->membase = devm_platform_get_and_ioremap_resource(pdev, 0, &reg);
  750. if (IS_ERR(port->membase))
  751. return PTR_ERR(port->membase);
  752. port->mapbase = reg->start;
  753. mvuart = devm_kzalloc(&pdev->dev, sizeof(struct mvebu_uart),
  754. GFP_KERNEL);
  755. if (!mvuart)
  756. return -ENOMEM;
  757. /* Get controller data depending on the compatible string */
  758. mvuart->data = (struct mvebu_uart_driver_data *)match->data;
  759. mvuart->port = port;
  760. port->private_data = mvuart;
  761. platform_set_drvdata(pdev, mvuart);
  762. /* Get fixed clock frequency */
  763. mvuart->clk = devm_clk_get(&pdev->dev, NULL);
  764. if (IS_ERR(mvuart->clk)) {
  765. if (PTR_ERR(mvuart->clk) == -EPROBE_DEFER)
  766. return PTR_ERR(mvuart->clk);
  767. if (IS_EXTENDED(port)) {
  768. dev_err(&pdev->dev, "unable to get UART clock\n");
  769. return PTR_ERR(mvuart->clk);
  770. }
  771. } else {
  772. if (!clk_prepare_enable(mvuart->clk))
  773. port->uartclk = clk_get_rate(mvuart->clk);
  774. }
  775. /* Manage interrupts */
  776. if (platform_irq_count(pdev) == 1) {
  777. /* Old bindings: no name on the single unamed UART0 IRQ */
  778. irq = platform_get_irq(pdev, 0);
  779. if (irq < 0)
  780. return irq;
  781. mvuart->irq[UART_IRQ_SUM] = irq;
  782. } else {
  783. /*
  784. * New bindings: named interrupts (RX, TX) for both UARTS,
  785. * only make use of uart-rx and uart-tx interrupts, do not use
  786. * uart-sum of UART0 port.
  787. */
  788. irq = platform_get_irq_byname(pdev, "uart-rx");
  789. if (irq < 0)
  790. return irq;
  791. mvuart->irq[UART_RX_IRQ] = irq;
  792. irq = platform_get_irq_byname(pdev, "uart-tx");
  793. if (irq < 0)
  794. return irq;
  795. mvuart->irq[UART_TX_IRQ] = irq;
  796. }
  797. /* UART Soft Reset*/
  798. writel(CTRL_SOFT_RST, port->membase + UART_CTRL(port));
  799. udelay(1);
  800. writel(0, port->membase + UART_CTRL(port));
  801. return uart_add_one_port(&mvebu_uart_driver, port);
  802. }
  803. static struct mvebu_uart_driver_data uart_std_driver_data = {
  804. .is_ext = false,
  805. .regs.rbr = UART_STD_RBR,
  806. .regs.tsh = UART_STD_TSH,
  807. .regs.ctrl = UART_STD_CTRL1,
  808. .regs.intr = UART_STD_CTRL2,
  809. .flags.ctrl_tx_rdy_int = CTRL_STD_TX_RDY_INT,
  810. .flags.ctrl_rx_rdy_int = CTRL_STD_RX_RDY_INT,
  811. .flags.stat_tx_rdy = STAT_STD_TX_RDY,
  812. .flags.stat_rx_rdy = STAT_STD_RX_RDY,
  813. };
  814. static struct mvebu_uart_driver_data uart_ext_driver_data = {
  815. .is_ext = true,
  816. .regs.rbr = UART_EXT_RBR,
  817. .regs.tsh = UART_EXT_TSH,
  818. .regs.ctrl = UART_EXT_CTRL1,
  819. .regs.intr = UART_EXT_CTRL2,
  820. .flags.ctrl_tx_rdy_int = CTRL_EXT_TX_RDY_INT,
  821. .flags.ctrl_rx_rdy_int = CTRL_EXT_RX_RDY_INT,
  822. .flags.stat_tx_rdy = STAT_EXT_TX_RDY,
  823. .flags.stat_rx_rdy = STAT_EXT_RX_RDY,
  824. };
  825. /* Match table for of_platform binding */
  826. static const struct of_device_id mvebu_uart_of_match[] = {
  827. {
  828. .compatible = "marvell,armada-3700-uart",
  829. .data = (void *)&uart_std_driver_data,
  830. },
  831. {
  832. .compatible = "marvell,armada-3700-uart-ext",
  833. .data = (void *)&uart_ext_driver_data,
  834. },
  835. {}
  836. };
  837. static struct platform_driver mvebu_uart_platform_driver = {
  838. .probe = mvebu_uart_probe,
  839. .driver = {
  840. .name = "mvebu-uart",
  841. .of_match_table = of_match_ptr(mvebu_uart_of_match),
  842. .suppress_bind_attrs = true,
  843. #if defined(CONFIG_PM)
  844. .pm = &mvebu_uart_pm_ops,
  845. #endif /* CONFIG_PM */
  846. },
  847. };
  848. /* This code is based on clk-fixed-factor.c driver and modified. */
  849. struct mvebu_uart_clock {
  850. struct clk_hw clk_hw;
  851. int clock_idx;
  852. u32 pm_context_reg1;
  853. u32 pm_context_reg2;
  854. };
  855. struct mvebu_uart_clock_base {
  856. struct mvebu_uart_clock clocks[2];
  857. unsigned int parent_rates[5];
  858. int parent_idx;
  859. unsigned int div;
  860. void __iomem *reg1;
  861. void __iomem *reg2;
  862. bool configured;
  863. };
  864. #define PARENT_CLOCK_XTAL 4
  865. #define to_uart_clock(hw) container_of(hw, struct mvebu_uart_clock, clk_hw)
  866. #define to_uart_clock_base(uart_clock) container_of(uart_clock, \
  867. struct mvebu_uart_clock_base, clocks[uart_clock->clock_idx])
  868. static int mvebu_uart_clock_prepare(struct clk_hw *hw)
  869. {
  870. struct mvebu_uart_clock *uart_clock = to_uart_clock(hw);
  871. struct mvebu_uart_clock_base *uart_clock_base =
  872. to_uart_clock_base(uart_clock);
  873. unsigned int prev_clock_idx, prev_clock_rate, prev_d1d2;
  874. unsigned int parent_clock_idx, parent_clock_rate;
  875. unsigned long flags;
  876. unsigned int d1, d2;
  877. u64 divisor;
  878. u32 val;
  879. /*
  880. * This function just reconfigures UART Clock Control register (located
  881. * in UART1 address space which controls both UART1 and UART2) to
  882. * selected UART base clock and recalculates current UART1/UART2
  883. * divisors in their address spaces, so that final baudrate will not be
  884. * changed by switching UART parent clock. This is required for
  885. * otherwise kernel's boot log stops working - we need to ensure that
  886. * UART baudrate does not change during this setup. It is a one time
  887. * operation, it will execute only once and set `configured` to true,
  888. * and be skipped on subsequent calls. Because this UART Clock Control
  889. * register (UART_BRDV) is shared between UART1 baudrate function,
  890. * UART1 clock selector and UART2 clock selector, every access to
  891. * UART_BRDV (reg1) needs to be protected by a lock.
  892. */
  893. spin_lock_irqsave(&mvebu_uart_lock, flags);
  894. if (uart_clock_base->configured) {
  895. spin_unlock_irqrestore(&mvebu_uart_lock, flags);
  896. return 0;
  897. }
  898. parent_clock_idx = uart_clock_base->parent_idx;
  899. parent_clock_rate = uart_clock_base->parent_rates[parent_clock_idx];
  900. val = readl(uart_clock_base->reg1);
  901. if (uart_clock_base->div > CLK_TBG_DIV1_MAX) {
  902. d1 = CLK_TBG_DIV1_MAX;
  903. d2 = uart_clock_base->div / CLK_TBG_DIV1_MAX;
  904. } else {
  905. d1 = uart_clock_base->div;
  906. d2 = 1;
  907. }
  908. if (val & CLK_NO_XTAL) {
  909. prev_clock_idx = (val >> CLK_TBG_SEL_SHIFT) & CLK_TBG_SEL_MASK;
  910. prev_d1d2 = ((val >> CLK_TBG_DIV1_SHIFT) & CLK_TBG_DIV1_MASK) *
  911. ((val >> CLK_TBG_DIV2_SHIFT) & CLK_TBG_DIV2_MASK);
  912. } else {
  913. prev_clock_idx = PARENT_CLOCK_XTAL;
  914. prev_d1d2 = 1;
  915. }
  916. /* Note that uart_clock_base->parent_rates[i] may not be available */
  917. prev_clock_rate = uart_clock_base->parent_rates[prev_clock_idx];
  918. /* Recalculate UART1 divisor so UART1 baudrate does not change */
  919. if (prev_clock_rate) {
  920. divisor = DIV_U64_ROUND_CLOSEST((u64)(val & BRDV_BAUD_MASK) *
  921. parent_clock_rate * prev_d1d2,
  922. prev_clock_rate * d1 * d2);
  923. if (divisor < 1)
  924. divisor = 1;
  925. else if (divisor > BRDV_BAUD_MAX)
  926. divisor = BRDV_BAUD_MAX;
  927. val = (val & ~BRDV_BAUD_MASK) | divisor;
  928. }
  929. if (parent_clock_idx != PARENT_CLOCK_XTAL) {
  930. /* Do not use XTAL, select TBG clock and TBG d1 * d2 divisors */
  931. val |= CLK_NO_XTAL;
  932. val &= ~(CLK_TBG_DIV1_MASK << CLK_TBG_DIV1_SHIFT);
  933. val |= d1 << CLK_TBG_DIV1_SHIFT;
  934. val &= ~(CLK_TBG_DIV2_MASK << CLK_TBG_DIV2_SHIFT);
  935. val |= d2 << CLK_TBG_DIV2_SHIFT;
  936. val &= ~(CLK_TBG_SEL_MASK << CLK_TBG_SEL_SHIFT);
  937. val |= parent_clock_idx << CLK_TBG_SEL_SHIFT;
  938. } else {
  939. /* Use XTAL, TBG bits are then ignored */
  940. val &= ~CLK_NO_XTAL;
  941. }
  942. writel(val, uart_clock_base->reg1);
  943. /* Recalculate UART2 divisor so UART2 baudrate does not change */
  944. if (prev_clock_rate) {
  945. val = readl(uart_clock_base->reg2);
  946. divisor = DIV_U64_ROUND_CLOSEST((u64)(val & BRDV_BAUD_MASK) *
  947. parent_clock_rate * prev_d1d2,
  948. prev_clock_rate * d1 * d2);
  949. if (divisor < 1)
  950. divisor = 1;
  951. else if (divisor > BRDV_BAUD_MAX)
  952. divisor = BRDV_BAUD_MAX;
  953. val = (val & ~BRDV_BAUD_MASK) | divisor;
  954. writel(val, uart_clock_base->reg2);
  955. }
  956. uart_clock_base->configured = true;
  957. spin_unlock_irqrestore(&mvebu_uart_lock, flags);
  958. return 0;
  959. }
  960. static int mvebu_uart_clock_enable(struct clk_hw *hw)
  961. {
  962. struct mvebu_uart_clock *uart_clock = to_uart_clock(hw);
  963. struct mvebu_uart_clock_base *uart_clock_base =
  964. to_uart_clock_base(uart_clock);
  965. unsigned long flags;
  966. u32 val;
  967. spin_lock_irqsave(&mvebu_uart_lock, flags);
  968. val = readl(uart_clock_base->reg1);
  969. if (uart_clock->clock_idx == 0)
  970. val &= ~UART1_CLK_DIS;
  971. else
  972. val &= ~UART2_CLK_DIS;
  973. writel(val, uart_clock_base->reg1);
  974. spin_unlock_irqrestore(&mvebu_uart_lock, flags);
  975. return 0;
  976. }
  977. static void mvebu_uart_clock_disable(struct clk_hw *hw)
  978. {
  979. struct mvebu_uart_clock *uart_clock = to_uart_clock(hw);
  980. struct mvebu_uart_clock_base *uart_clock_base =
  981. to_uart_clock_base(uart_clock);
  982. unsigned long flags;
  983. u32 val;
  984. spin_lock_irqsave(&mvebu_uart_lock, flags);
  985. val = readl(uart_clock_base->reg1);
  986. if (uart_clock->clock_idx == 0)
  987. val |= UART1_CLK_DIS;
  988. else
  989. val |= UART2_CLK_DIS;
  990. writel(val, uart_clock_base->reg1);
  991. spin_unlock_irqrestore(&mvebu_uart_lock, flags);
  992. }
  993. static int mvebu_uart_clock_is_enabled(struct clk_hw *hw)
  994. {
  995. struct mvebu_uart_clock *uart_clock = to_uart_clock(hw);
  996. struct mvebu_uart_clock_base *uart_clock_base =
  997. to_uart_clock_base(uart_clock);
  998. u32 val;
  999. val = readl(uart_clock_base->reg1);
  1000. if (uart_clock->clock_idx == 0)
  1001. return !(val & UART1_CLK_DIS);
  1002. else
  1003. return !(val & UART2_CLK_DIS);
  1004. }
  1005. static int mvebu_uart_clock_save_context(struct clk_hw *hw)
  1006. {
  1007. struct mvebu_uart_clock *uart_clock = to_uart_clock(hw);
  1008. struct mvebu_uart_clock_base *uart_clock_base =
  1009. to_uart_clock_base(uart_clock);
  1010. unsigned long flags;
  1011. spin_lock_irqsave(&mvebu_uart_lock, flags);
  1012. uart_clock->pm_context_reg1 = readl(uart_clock_base->reg1);
  1013. uart_clock->pm_context_reg2 = readl(uart_clock_base->reg2);
  1014. spin_unlock_irqrestore(&mvebu_uart_lock, flags);
  1015. return 0;
  1016. }
  1017. static void mvebu_uart_clock_restore_context(struct clk_hw *hw)
  1018. {
  1019. struct mvebu_uart_clock *uart_clock = to_uart_clock(hw);
  1020. struct mvebu_uart_clock_base *uart_clock_base =
  1021. to_uart_clock_base(uart_clock);
  1022. unsigned long flags;
  1023. spin_lock_irqsave(&mvebu_uart_lock, flags);
  1024. writel(uart_clock->pm_context_reg1, uart_clock_base->reg1);
  1025. writel(uart_clock->pm_context_reg2, uart_clock_base->reg2);
  1026. spin_unlock_irqrestore(&mvebu_uart_lock, flags);
  1027. }
  1028. static unsigned long mvebu_uart_clock_recalc_rate(struct clk_hw *hw,
  1029. unsigned long parent_rate)
  1030. {
  1031. struct mvebu_uart_clock *uart_clock = to_uart_clock(hw);
  1032. struct mvebu_uart_clock_base *uart_clock_base =
  1033. to_uart_clock_base(uart_clock);
  1034. return parent_rate / uart_clock_base->div;
  1035. }
  1036. static int mvebu_uart_clock_determine_rate(struct clk_hw *hw,
  1037. struct clk_rate_request *req)
  1038. {
  1039. struct mvebu_uart_clock *uart_clock = to_uart_clock(hw);
  1040. struct mvebu_uart_clock_base *uart_clock_base =
  1041. to_uart_clock_base(uart_clock);
  1042. req->rate = req->best_parent_rate / uart_clock_base->div;
  1043. return 0;
  1044. }
  1045. static int mvebu_uart_clock_set_rate(struct clk_hw *hw, unsigned long rate,
  1046. unsigned long parent_rate)
  1047. {
  1048. /*
  1049. * We must report success but we can do so unconditionally because
  1050. * mvebu_uart_clock_round_rate returns values that ensure this call is a
  1051. * nop.
  1052. */
  1053. return 0;
  1054. }
  1055. static const struct clk_ops mvebu_uart_clock_ops = {
  1056. .prepare = mvebu_uart_clock_prepare,
  1057. .enable = mvebu_uart_clock_enable,
  1058. .disable = mvebu_uart_clock_disable,
  1059. .is_enabled = mvebu_uart_clock_is_enabled,
  1060. .save_context = mvebu_uart_clock_save_context,
  1061. .restore_context = mvebu_uart_clock_restore_context,
  1062. .determine_rate = mvebu_uart_clock_determine_rate,
  1063. .set_rate = mvebu_uart_clock_set_rate,
  1064. .recalc_rate = mvebu_uart_clock_recalc_rate,
  1065. };
  1066. static int mvebu_uart_clock_register(struct device *dev,
  1067. struct mvebu_uart_clock *uart_clock,
  1068. const char *name,
  1069. const char *parent_name)
  1070. {
  1071. struct clk_init_data init = { };
  1072. uart_clock->clk_hw.init = &init;
  1073. init.name = name;
  1074. init.ops = &mvebu_uart_clock_ops;
  1075. init.flags = 0;
  1076. init.num_parents = 1;
  1077. init.parent_names = &parent_name;
  1078. return devm_clk_hw_register(dev, &uart_clock->clk_hw);
  1079. }
  1080. static int mvebu_uart_clock_probe(struct platform_device *pdev)
  1081. {
  1082. static const char *const uart_clk_names[] = { "uart_1", "uart_2" };
  1083. static const char *const parent_clk_names[] = { "TBG-A-P", "TBG-B-P",
  1084. "TBG-A-S", "TBG-B-S",
  1085. "xtal" };
  1086. struct clk *parent_clks[ARRAY_SIZE(parent_clk_names)];
  1087. struct mvebu_uart_clock_base *uart_clock_base;
  1088. struct clk_hw_onecell_data *hw_clk_data;
  1089. struct device *dev = &pdev->dev;
  1090. int i, parent_clk_idx, ret;
  1091. unsigned long div, rate;
  1092. struct resource *res;
  1093. unsigned int d1, d2;
  1094. BUILD_BUG_ON(ARRAY_SIZE(uart_clk_names) !=
  1095. ARRAY_SIZE(uart_clock_base->clocks));
  1096. BUILD_BUG_ON(ARRAY_SIZE(parent_clk_names) !=
  1097. ARRAY_SIZE(uart_clock_base->parent_rates));
  1098. uart_clock_base = devm_kzalloc(dev,
  1099. sizeof(*uart_clock_base),
  1100. GFP_KERNEL);
  1101. if (!uart_clock_base)
  1102. return -ENOMEM;
  1103. res = platform_get_resource(pdev, IORESOURCE_MEM, 0);
  1104. if (!res) {
  1105. dev_err(dev, "Couldn't get first register\n");
  1106. return -ENOENT;
  1107. }
  1108. /*
  1109. * UART Clock Control register (reg1 / UART_BRDV) is in the address
  1110. * space of UART1 (standard UART variant), controls parent clock and
  1111. * dividers for both UART1 and UART2 and is supplied via DT as the first
  1112. * resource. Therefore use ioremap() rather than ioremap_resource() to
  1113. * avoid conflicts with UART1 driver. Access to UART_BRDV is protected
  1114. * by a lock shared between clock and UART driver.
  1115. */
  1116. uart_clock_base->reg1 = devm_ioremap(dev, res->start,
  1117. resource_size(res));
  1118. if (!uart_clock_base->reg1)
  1119. return -ENOMEM;
  1120. res = platform_get_resource(pdev, IORESOURCE_MEM, 1);
  1121. if (!res) {
  1122. dev_err(dev, "Couldn't get second register\n");
  1123. return -ENOENT;
  1124. }
  1125. /*
  1126. * UART 2 Baud Rate Divisor register (reg2 / UART_BRDV) is in address
  1127. * space of UART2 (extended UART variant), controls only one UART2
  1128. * specific divider and is supplied via DT as second resource.
  1129. * Therefore use ioremap() rather than ioremap_resource() to avoid
  1130. * conflicts with UART2 driver. Access to UART_BRDV is protected by a
  1131. * by lock shared between clock and UART driver.
  1132. */
  1133. uart_clock_base->reg2 = devm_ioremap(dev, res->start,
  1134. resource_size(res));
  1135. if (!uart_clock_base->reg2)
  1136. return -ENOMEM;
  1137. hw_clk_data = devm_kzalloc(dev,
  1138. struct_size(hw_clk_data, hws,
  1139. ARRAY_SIZE(uart_clk_names)),
  1140. GFP_KERNEL);
  1141. if (!hw_clk_data)
  1142. return -ENOMEM;
  1143. hw_clk_data->num = ARRAY_SIZE(uart_clk_names);
  1144. for (i = 0; i < ARRAY_SIZE(uart_clk_names); i++) {
  1145. hw_clk_data->hws[i] = &uart_clock_base->clocks[i].clk_hw;
  1146. uart_clock_base->clocks[i].clock_idx = i;
  1147. }
  1148. parent_clk_idx = -1;
  1149. for (i = 0; i < ARRAY_SIZE(parent_clk_names); i++) {
  1150. parent_clks[i] = devm_clk_get(dev, parent_clk_names[i]);
  1151. if (IS_ERR(parent_clks[i])) {
  1152. if (PTR_ERR(parent_clks[i]) == -EPROBE_DEFER)
  1153. return -EPROBE_DEFER;
  1154. dev_warn(dev, "Couldn't get the parent clock %s: %ld\n",
  1155. parent_clk_names[i], PTR_ERR(parent_clks[i]));
  1156. continue;
  1157. }
  1158. ret = clk_prepare_enable(parent_clks[i]);
  1159. if (ret) {
  1160. dev_warn(dev, "Couldn't enable parent clock %s: %d\n",
  1161. parent_clk_names[i], ret);
  1162. continue;
  1163. }
  1164. rate = clk_get_rate(parent_clks[i]);
  1165. uart_clock_base->parent_rates[i] = rate;
  1166. if (i != PARENT_CLOCK_XTAL) {
  1167. /*
  1168. * Calculate the smallest TBG d1 and d2 divisors that
  1169. * still can provide 9600 baudrate.
  1170. */
  1171. d1 = DIV_ROUND_UP(rate, 9600 * OSAMP_MAX_DIVISOR *
  1172. BRDV_BAUD_MAX);
  1173. if (d1 < 1)
  1174. d1 = 1;
  1175. else if (d1 > CLK_TBG_DIV1_MAX)
  1176. d1 = CLK_TBG_DIV1_MAX;
  1177. d2 = DIV_ROUND_UP(rate, 9600 * OSAMP_MAX_DIVISOR *
  1178. BRDV_BAUD_MAX * d1);
  1179. if (d2 < 1)
  1180. d2 = 1;
  1181. else if (d2 > CLK_TBG_DIV2_MAX)
  1182. d2 = CLK_TBG_DIV2_MAX;
  1183. } else {
  1184. /*
  1185. * When UART clock uses XTAL clock as a source then it
  1186. * is not possible to use d1 and d2 divisors.
  1187. */
  1188. d1 = d2 = 1;
  1189. }
  1190. /* Skip clock source which cannot provide 9600 baudrate */
  1191. if (rate > 9600 * OSAMP_MAX_DIVISOR * BRDV_BAUD_MAX * d1 * d2)
  1192. continue;
  1193. /*
  1194. * Choose TBG clock source with the smallest divisors. Use XTAL
  1195. * clock source only in case TBG is not available as XTAL cannot
  1196. * be used for baudrates higher than 230400.
  1197. */
  1198. if (parent_clk_idx == -1 ||
  1199. (i != PARENT_CLOCK_XTAL && div > d1 * d2)) {
  1200. parent_clk_idx = i;
  1201. div = d1 * d2;
  1202. }
  1203. }
  1204. for (i = 0; i < ARRAY_SIZE(parent_clk_names); i++) {
  1205. if (i == parent_clk_idx || IS_ERR(parent_clks[i]))
  1206. continue;
  1207. clk_disable_unprepare(parent_clks[i]);
  1208. devm_clk_put(dev, parent_clks[i]);
  1209. }
  1210. if (parent_clk_idx == -1) {
  1211. dev_err(dev, "No usable parent clock\n");
  1212. return -ENOENT;
  1213. }
  1214. uart_clock_base->parent_idx = parent_clk_idx;
  1215. uart_clock_base->div = div;
  1216. dev_notice(dev, "Using parent clock %s as base UART clock\n",
  1217. __clk_get_name(parent_clks[parent_clk_idx]));
  1218. for (i = 0; i < ARRAY_SIZE(uart_clk_names); i++) {
  1219. ret = mvebu_uart_clock_register(dev,
  1220. &uart_clock_base->clocks[i],
  1221. uart_clk_names[i],
  1222. __clk_get_name(parent_clks[parent_clk_idx]));
  1223. if (ret) {
  1224. dev_err(dev, "Can't register UART clock %d: %d\n",
  1225. i, ret);
  1226. return ret;
  1227. }
  1228. }
  1229. return devm_of_clk_add_hw_provider(dev, of_clk_hw_onecell_get,
  1230. hw_clk_data);
  1231. }
  1232. static const struct of_device_id mvebu_uart_clock_of_match[] = {
  1233. { .compatible = "marvell,armada-3700-uart-clock", },
  1234. { }
  1235. };
  1236. static struct platform_driver mvebu_uart_clock_platform_driver = {
  1237. .probe = mvebu_uart_clock_probe,
  1238. .driver = {
  1239. .name = "mvebu-uart-clock",
  1240. .of_match_table = mvebu_uart_clock_of_match,
  1241. },
  1242. };
  1243. static int __init mvebu_uart_init(void)
  1244. {
  1245. int ret;
  1246. ret = uart_register_driver(&mvebu_uart_driver);
  1247. if (ret)
  1248. return ret;
  1249. ret = platform_driver_register(&mvebu_uart_clock_platform_driver);
  1250. if (ret) {
  1251. uart_unregister_driver(&mvebu_uart_driver);
  1252. return ret;
  1253. }
  1254. ret = platform_driver_register(&mvebu_uart_platform_driver);
  1255. if (ret) {
  1256. platform_driver_unregister(&mvebu_uart_clock_platform_driver);
  1257. uart_unregister_driver(&mvebu_uart_driver);
  1258. return ret;
  1259. }
  1260. return 0;
  1261. }
  1262. arch_initcall(mvebu_uart_init);