include/asm-v850/v850e_uarta.h - pub/scm/linux/kernel/git/horms/ipvs-next - Git at Google

 /*
  * include/asm-v850/v850e_uarta.h -- original V850E on-chip UART
  *
  *  Copyright (C) 2001,02,03  NEC Electronics Corporation
  *  Copyright (C) 2001,02,03  Miles Bader <miles@gnu.org>
  *
  * This file is subject to the terms and conditions of the GNU General
  * Public License.  See the file COPYING in the main directory of this
  * archive for more details.
  *
  * Written by Miles Bader <miles@gnu.org>
  */

 /* This is the original V850E UART implementation is called just `UART' in
    the docs, but we name this header file <asm/v850e_uarta.h> because the
    name <asm/v850e_uart.h> is used for the common driver that handles both
    `UART' and `UARTB' implementations.  */

 #ifndef __V850_V850E_UARTA_H__
 #define __V850_V850E_UARTA_H__


 /* Raw hardware interface.  */

 /* The base address of the UART control registers for channel N.
    The default is the address used on the V850E/MA1.  */
 #ifndef V850E_UART_BASE_ADDR
 #define V850E_UART_BASE_ADDR(n)		(0xFFFFFA00 + 0x10 * (n))
 #endif

 /* Addresses of specific UART control registers for channel N.
    The defaults are the addresses used on the V850E/MA1; if a platform
    wants to redefine any of these, it must redefine them all.  */
 #ifndef V850E_UART_ASIM_ADDR
 #define V850E_UART_ASIM_ADDR(n)		(V850E_UART_BASE_ADDR(n) + 0x0)
 #define V850E_UART_RXB_ADDR(n)		(V850E_UART_BASE_ADDR(n) + 0x2)
 #define V850E_UART_ASIS_ADDR(n)		(V850E_UART_BASE_ADDR(n) + 0x3)
 #define V850E_UART_TXB_ADDR(n)		(V850E_UART_BASE_ADDR(n) + 0x4)
 #define V850E_UART_ASIF_ADDR(n)		(V850E_UART_BASE_ADDR(n) + 0x5)
 #define V850E_UART_CKSR_ADDR(n)		(V850E_UART_BASE_ADDR(n) + 0x6)
 #define V850E_UART_BRGC_ADDR(n)		(V850E_UART_BASE_ADDR(n) + 0x7)
 #endif

 /* UART config registers.  */
 #define V850E_UART_ASIM(n)	(*(volatile u8 *)V850E_UART_ASIM_ADDR(n))
 /* Control bits for config registers.  */
 #define V850E_UART_ASIM_CAE	0x80 /* clock enable */
 #define V850E_UART_ASIM_TXE	0x40 /* transmit enable */
 #define V850E_UART_ASIM_RXE	0x20 /* receive enable */
 #define V850E_UART_ASIM_PS_MASK	0x18 /* mask covering parity-select bits */
 #define V850E_UART_ASIM_PS_NONE	0x00 /* no parity */
 #define V850E_UART_ASIM_PS_ZERO	0x08 /* zero parity */
 #define V850E_UART_ASIM_PS_ODD	0x10 /* odd parity */
 #define V850E_UART_ASIM_PS_EVEN	0x18 /* even parity */
 #define V850E_UART_ASIM_CL_8	0x04 /* char len is 8 bits (otherwise, 7) */
 #define V850E_UART_ASIM_SL_2	0x02 /* 2 stop bits (otherwise, 1) */
 #define V850E_UART_ASIM_ISRM	0x01 /* generate INTSR interrupt on errors
 					(otherwise, generate INTSER) */

 /* UART serial interface status registers.  */
 #define V850E_UART_ASIS(n)	(*(volatile u8 *)V850E_UART_ASIS_ADDR(n))
 /* Control bits for status registers.  */
 #define V850E_UART_ASIS_PE	0x04 /* parity error */
 #define V850E_UART_ASIS_FE	0x02 /* framing error */
 #define V850E_UART_ASIS_OVE	0x01 /* overrun error */

 /* UART serial interface transmission status registers.  */
 #define V850E_UART_ASIF(n)	(*(volatile u8 *)V850E_UART_ASIF_ADDR(n))
 #define V850E_UART_ASIF_TXBF	0x02 /* transmit buffer flag (data in TXB) */
 #define V850E_UART_ASIF_TXSF	0x01 /* transmit shift flag (sending data) */

 /* UART receive buffer register.  */
 #define V850E_UART_RXB(n)	(*(volatile u8 *)V850E_UART_RXB_ADDR(n))

 /* UART transmit buffer register.  */
 #define V850E_UART_TXB(n)	(*(volatile u8 *)V850E_UART_TXB_ADDR(n))

 /* UART baud-rate generator control registers.  */
 #define V850E_UART_CKSR(n)	(*(volatile u8 *)V850E_UART_CKSR_ADDR(n))
 #define V850E_UART_CKSR_MAX	11
 #define V850E_UART_BRGC(n)	(*(volatile u8 *)V850E_UART_BRGC_ADDR(n))
 #define V850E_UART_BRGC_MIN	8


 #ifndef V850E_UART_CKSR_MAX_FREQ
 #define V850E_UART_CKSR_MAX_FREQ (25*1000*1000)
 #endif

 /* Calculate the minimum value for CKSR on this processor.  */
 static inline unsigned v850e_uart_cksr_min (void)
 {
 	int min = 0;
 	unsigned freq = V850E_UART_BASE_FREQ;
 	while (freq > V850E_UART_CKSR_MAX_FREQ) {
 		freq >>= 1;
 		min++;
 	}
 	return min;
 }


 /* Slightly abstract interface used by driver.  */


 /* Interrupts used by the UART.  */

 /* Received when the most recently transmitted character has been sent.  */
 #define V850E_UART_TX_IRQ(chan)		IRQ_INTST (chan)
 /* Received when a new character has been received.  */
 #define V850E_UART_RX_IRQ(chan)		IRQ_INTSR (chan)


 /* UART clock generator interface.  */

 /* This type encapsulates a particular uart frequency.  */
 typedef struct {
 	unsigned clk_divlog2;
 	unsigned brgen_count;
 } v850e_uart_speed_t;

 /* Calculate a uart speed from BAUD for this uart.  */
 static inline v850e_uart_speed_t v850e_uart_calc_speed (unsigned baud)
 {
 	v850e_uart_speed_t speed;

 	/* Calculate the log2 clock divider and baud-rate counter values
 	   (note that the UART divides the resulting clock by 2, so
 	   multiply BAUD by 2 here to compensate).  */
 	calc_counter_params (V850E_UART_BASE_FREQ, baud * 2,
 			     v850e_uart_cksr_min(),
 			     V850E_UART_CKSR_MAX, 8/*bits*/,
 			     &speed.clk_divlog2, &speed.brgen_count);

 	return speed;
 }

 /* Return the current speed of uart channel CHAN.  */
 static inline v850e_uart_speed_t v850e_uart_speed (unsigned chan)
 {
 	v850e_uart_speed_t speed;
 	speed.clk_divlog2 = V850E_UART_CKSR (chan);
 	speed.brgen_count = V850E_UART_BRGC (chan);
 	return speed;
 }

 /* Set the current speed of uart channel CHAN.  */
 static inline void v850e_uart_set_speed(unsigned chan,v850e_uart_speed_t speed)
 {
 	V850E_UART_CKSR (chan) = speed.clk_divlog2;
 	V850E_UART_BRGC (chan) = speed.brgen_count;
 }

 static inline int
 v850e_uart_speed_eq (v850e_uart_speed_t speed1, v850e_uart_speed_t speed2)
 {
 	return speed1.clk_divlog2 == speed2.clk_divlog2
 		&& speed1.brgen_count == speed2.brgen_count;
 }

 /* Minimum baud rate possible.  */
 #define v850e_uart_min_baud() \
    ((V850E_UART_BASE_FREQ >> V850E_UART_CKSR_MAX) / (2 * 255) + 1)

 /* Maximum baud rate possible.  The error is quite high at max, though.  */
 #define v850e_uart_max_baud() \
    ((V850E_UART_BASE_FREQ >> v850e_uart_cksr_min()) / (2 *V850E_UART_BRGC_MIN))

 /* The `maximum' clock rate the uart can used, which is wanted (though not
    really used in any useful way) by the serial framework.  */
 #define v850e_uart_max_clock() \
    ((V850E_UART_BASE_FREQ >> v850e_uart_cksr_min()) / 2)


 /* UART configuration interface.  */

 /* Type of the uart config register; must be a scalar.  */
 typedef u16 v850e_uart_config_t;

 /* The uart hardware config register for channel CHAN.  */
 #define V850E_UART_CONFIG(chan)		V850E_UART_ASIM (chan)

 /* This config bit set if the uart is enabled.  */
 #define V850E_UART_CONFIG_ENABLED	V850E_UART_ASIM_CAE
 /* If the uart _isn't_ enabled, store this value to it to do so.  */
 #define V850E_UART_CONFIG_INIT		V850E_UART_ASIM_CAE
 /* Store this config value to disable the uart channel completely.  */
 #define V850E_UART_CONFIG_FINI		0

 /* Setting/clearing these bits enable/disable TX/RX, respectively (but
    otherwise generally leave things running).  */
 #define V850E_UART_CONFIG_RX_ENABLE	V850E_UART_ASIM_RXE
 #define V850E_UART_CONFIG_TX_ENABLE	V850E_UART_ASIM_TXE

 /* These masks define which config bits affect TX/RX modes, respectively.  */
 #define V850E_UART_CONFIG_RX_BITS \
   (V850E_UART_ASIM_PS_MASK | V850E_UART_ASIM_CL_8 | V850E_UART_ASIM_ISRM)
 #define V850E_UART_CONFIG_TX_BITS \
   (V850E_UART_ASIM_PS_MASK | V850E_UART_ASIM_CL_8 | V850E_UART_ASIM_SL_2)

 static inline v850e_uart_config_t v850e_uart_calc_config (unsigned cflags)
 {
 	v850e_uart_config_t config = 0;

 	/* Figure out new configuration of control register.  */
 	if (cflags & CSTOPB)
 		/* Number of stop bits, 1 or 2.  */
 		config |= V850E_UART_ASIM_SL_2;
 	if ((cflags & CSIZE) == CS8)
 		/* Number of data bits, 7 or 8.  */
 		config |= V850E_UART_ASIM_CL_8;
 	if (! (cflags & PARENB))
 		/* No parity check/generation.  */
 		config |= V850E_UART_ASIM_PS_NONE;
 	else if (cflags & PARODD)
 		/* Odd parity check/generation.  */
 		config |= V850E_UART_ASIM_PS_ODD;
 	else
 		/* Even parity check/generation.  */
 		config |= V850E_UART_ASIM_PS_EVEN;
 	if (cflags & CREAD)
 		/* Reading enabled.  */
 		config |= V850E_UART_ASIM_RXE;

 	config |= V850E_UART_ASIM_CAE;
 	config |= V850E_UART_ASIM_TXE; /* Writing is always enabled.  */
 	config |= V850E_UART_ASIM_ISRM; /* Errors generate a read-irq.  */

 	return config;
 }

 /* This should delay as long as necessary for a recently written config
    setting to settle, before we turn the uart back on.  */
 static inline void
 v850e_uart_config_delay (v850e_uart_config_t config, v850e_uart_speed_t speed)
 {
 	/* The UART may not be reset properly unless we wait at least 2
 	   `basic-clocks' until turning on the TXE/RXE bits again.
 	   A `basic clock' is the clock used by the baud-rate generator,
 	   i.e., the cpu clock divided by the 2^new_clk_divlog2.
 	   The loop takes 2 insns, so loop CYCLES / 2 times.  */
 	register unsigned count = 1 << speed.clk_divlog2;
 	while (--count != 0)
 		/* nothing */;
 }


 /* RX/TX interface.  */

 /* Return true if all characters awaiting transmission on uart channel N
    have been transmitted.  */
 #define v850e_uart_xmit_done(n)						      \
    (! (V850E_UART_ASIF(n) & V850E_UART_ASIF_TXBF))
 /* Wait for this to be true.  */
 #define v850e_uart_wait_for_xmit_done(n)				      \
    do { } while (! v850e_uart_xmit_done (n))

 /* Return true if uart channel N is ready to transmit a character.  */
 #define v850e_uart_xmit_ok(n)						      \
    (v850e_uart_xmit_done(n) && v850e_uart_cts(n))
 /* Wait for this to be true.  */
 #define v850e_uart_wait_for_xmit_ok(n)					      \
    do { } while (! v850e_uart_xmit_ok (n))

 /* Write character CH to uart channel CHAN.  */
 #define v850e_uart_putc(chan, ch)	(V850E_UART_TXB(chan) = (ch))

 /* Return latest character read on channel CHAN.  */
 #define v850e_uart_getc(chan)		V850E_UART_RXB (chan)

 /* Return bit-mask of uart error status.  */
 #define v850e_uart_err(chan)		V850E_UART_ASIS (chan)
 /* Various error bits set in the error result.  */
 #define V850E_UART_ERR_OVERRUN		V850E_UART_ASIS_OVE
 #define V850E_UART_ERR_FRAME		V850E_UART_ASIS_FE
 #define V850E_UART_ERR_PARITY		V850E_UART_ASIS_PE


 #endif /* __V850_V850E_UARTA_H__ */
	/*
	* include/asm-v850/v850e_uarta.h -- original V850E on-chip UART
	*
	* Copyright (C) 2001,02,03 NEC Electronics Corporation
	* Copyright (C) 2001,02,03 Miles Bader <miles@gnu.org>
	*
	* This file is subject to the terms and conditions of the GNU General
	* Public License. See the file COPYING in the main directory of this
	* archive for more details.
	*
	* Written by Miles Bader <miles@gnu.org>
	*/

	/* This is the original V850E UART implementation is called just `UART' in
	the docs, but we name this header file <asm/v850e_uarta.h> because the
	name <asm/v850e_uart.h> is used for the common driver that handles both
	`UART' and `UARTB' implementations. */

	#ifndef __V850_V850E_UARTA_H__
	#define __V850_V850E_UARTA_H__


	/* Raw hardware interface. */

	/* The base address of the UART control registers for channel N.
	The default is the address used on the V850E/MA1. */
	#ifndef V850E_UART_BASE_ADDR
	#define V850E_UART_BASE_ADDR(n) (0xFFFFFA00 + 0x10 * (n))
	#endif

	/* Addresses of specific UART control registers for channel N.
	The defaults are the addresses used on the V850E/MA1; if a platform
	wants to redefine any of these, it must redefine them all. */
	#ifndef V850E_UART_ASIM_ADDR
	#define V850E_UART_ASIM_ADDR(n) (V850E_UART_BASE_ADDR(n) + 0x0)
	#define V850E_UART_RXB_ADDR(n) (V850E_UART_BASE_ADDR(n) + 0x2)
	#define V850E_UART_ASIS_ADDR(n) (V850E_UART_BASE_ADDR(n) + 0x3)
	#define V850E_UART_TXB_ADDR(n) (V850E_UART_BASE_ADDR(n) + 0x4)
	#define V850E_UART_ASIF_ADDR(n) (V850E_UART_BASE_ADDR(n) + 0x5)
	#define V850E_UART_CKSR_ADDR(n) (V850E_UART_BASE_ADDR(n) + 0x6)
	#define V850E_UART_BRGC_ADDR(n) (V850E_UART_BASE_ADDR(n) + 0x7)
	#endif

	/* UART config registers. */
	#define V850E_UART_ASIM(n) ((volatile u8 )V850E_UART_ASIM_ADDR(n))
	/* Control bits for config registers. */
	#define V850E_UART_ASIM_CAE 0x80 /* clock enable */
	#define V850E_UART_ASIM_TXE 0x40 /* transmit enable */
	#define V850E_UART_ASIM_RXE 0x20 /* receive enable */
	#define V850E_UART_ASIM_PS_MASK 0x18 /* mask covering parity-select bits */
	#define V850E_UART_ASIM_PS_NONE 0x00 /* no parity */
	#define V850E_UART_ASIM_PS_ZERO 0x08 /* zero parity */
	#define V850E_UART_ASIM_PS_ODD 0x10 /* odd parity */
	#define V850E_UART_ASIM_PS_EVEN 0x18 /* even parity */
	#define V850E_UART_ASIM_CL_8 0x04 /* char len is 8 bits (otherwise, 7) */
	#define V850E_UART_ASIM_SL_2 0x02 /* 2 stop bits (otherwise, 1) */
	#define V850E_UART_ASIM_ISRM 0x01 /* generate INTSR interrupt on errors
	(otherwise, generate INTSER) */

	/* UART serial interface status registers. */
	#define V850E_UART_ASIS(n) ((volatile u8 )V850E_UART_ASIS_ADDR(n))
	/* Control bits for status registers. */
	#define V850E_UART_ASIS_PE 0x04 /* parity error */
	#define V850E_UART_ASIS_FE 0x02 /* framing error */
	#define V850E_UART_ASIS_OVE 0x01 /* overrun error */

	/* UART serial interface transmission status registers. */
	#define V850E_UART_ASIF(n) ((volatile u8 )V850E_UART_ASIF_ADDR(n))
	#define V850E_UART_ASIF_TXBF 0x02 /* transmit buffer flag (data in TXB) */
	#define V850E_UART_ASIF_TXSF 0x01 /* transmit shift flag (sending data) */

	/* UART receive buffer register. */
	#define V850E_UART_RXB(n) ((volatile u8 )V850E_UART_RXB_ADDR(n))

	/* UART transmit buffer register. */
	#define V850E_UART_TXB(n) ((volatile u8 )V850E_UART_TXB_ADDR(n))

	/* UART baud-rate generator control registers. */
	#define V850E_UART_CKSR(n) ((volatile u8 )V850E_UART_CKSR_ADDR(n))
	#define V850E_UART_CKSR_MAX 11
	#define V850E_UART_BRGC(n) ((volatile u8 )V850E_UART_BRGC_ADDR(n))
	#define V850E_UART_BRGC_MIN 8


	#ifndef V850E_UART_CKSR_MAX_FREQ
	#define V850E_UART_CKSR_MAX_FREQ (2510001000)
	#endif

	/* Calculate the minimum value for CKSR on this processor. */
	static inline unsigned v850e_uart_cksr_min (void)
	{
	int min = 0;
	unsigned freq = V850E_UART_BASE_FREQ;
	while (freq > V850E_UART_CKSR_MAX_FREQ) {
	freq >>= 1;
	min++;
	}
	return min;
	}


	/* Slightly abstract interface used by driver. */


	/* Interrupts used by the UART. */

	/* Received when the most recently transmitted character has been sent. */
	#define V850E_UART_TX_IRQ(chan) IRQ_INTST (chan)
	/* Received when a new character has been received. */
	#define V850E_UART_RX_IRQ(chan) IRQ_INTSR (chan)


	/* UART clock generator interface. */

	/* This type encapsulates a particular uart frequency. */
	typedef struct {
	unsigned clk_divlog2;
	unsigned brgen_count;
	} v850e_uart_speed_t;

	/* Calculate a uart speed from BAUD for this uart. */
	static inline v850e_uart_speed_t v850e_uart_calc_speed (unsigned baud)
	{
	v850e_uart_speed_t speed;

	/* Calculate the log2 clock divider and baud-rate counter values
	(note that the UART divides the resulting clock by 2, so
	multiply BAUD by 2 here to compensate). */
	calc_counter_params (V850E_UART_BASE_FREQ, baud * 2,
	v850e_uart_cksr_min(),
	V850E_UART_CKSR_MAX, 8/bits/,
	&speed.clk_divlog2, &speed.brgen_count);

	return speed;
	}

	/* Return the current speed of uart channel CHAN. */
	static inline v850e_uart_speed_t v850e_uart_speed (unsigned chan)
	{
	v850e_uart_speed_t speed;
	speed.clk_divlog2 = V850E_UART_CKSR (chan);
	speed.brgen_count = V850E_UART_BRGC (chan);
	return speed;
	}

	/* Set the current speed of uart channel CHAN. */
	static inline void v850e_uart_set_speed(unsigned chan,v850e_uart_speed_t speed)
	{
	V850E_UART_CKSR (chan) = speed.clk_divlog2;
	V850E_UART_BRGC (chan) = speed.brgen_count;
	}

	static inline int
	v850e_uart_speed_eq (v850e_uart_speed_t speed1, v850e_uart_speed_t speed2)
	{
	return speed1.clk_divlog2 == speed2.clk_divlog2
	&& speed1.brgen_count == speed2.brgen_count;
	}

	/* Minimum baud rate possible. */
	#define v850e_uart_min_baud() \
	((V850E_UART_BASE_FREQ >> V850E_UART_CKSR_MAX) / (2 * 255) + 1)

	/* Maximum baud rate possible. The error is quite high at max, though. */
	#define v850e_uart_max_baud() \
	((V850E_UART_BASE_FREQ >> v850e_uart_cksr_min()) / (2 *V850E_UART_BRGC_MIN))

	/* The `maximum' clock rate the uart can used, which is wanted (though not
	really used in any useful way) by the serial framework. */
	#define v850e_uart_max_clock() \
	((V850E_UART_BASE_FREQ >> v850e_uart_cksr_min()) / 2)


	/* UART configuration interface. */

	/* Type of the uart config register; must be a scalar. */
	typedef u16 v850e_uart_config_t;

	/* The uart hardware config register for channel CHAN. */
	#define V850E_UART_CONFIG(chan) V850E_UART_ASIM (chan)

	/* This config bit set if the uart is enabled. */
	#define V850E_UART_CONFIG_ENABLED V850E_UART_ASIM_CAE
	/* If the uart _isn't_ enabled, store this value to it to do so. */
	#define V850E_UART_CONFIG_INIT V850E_UART_ASIM_CAE
	/* Store this config value to disable the uart channel completely. */
	#define V850E_UART_CONFIG_FINI 0

	/* Setting/clearing these bits enable/disable TX/RX, respectively (but
	otherwise generally leave things running). */
	#define V850E_UART_CONFIG_RX_ENABLE V850E_UART_ASIM_RXE
	#define V850E_UART_CONFIG_TX_ENABLE V850E_UART_ASIM_TXE

	/* These masks define which config bits affect TX/RX modes, respectively. */
	#define V850E_UART_CONFIG_RX_BITS \
	(V850E_UART_ASIM_PS_MASK \| V850E_UART_ASIM_CL_8 \| V850E_UART_ASIM_ISRM)
	#define V850E_UART_CONFIG_TX_BITS \
	(V850E_UART_ASIM_PS_MASK \| V850E_UART_ASIM_CL_8 \| V850E_UART_ASIM_SL_2)

	static inline v850e_uart_config_t v850e_uart_calc_config (unsigned cflags)
	{
	v850e_uart_config_t config = 0;

	/* Figure out new configuration of control register. */
	if (cflags & CSTOPB)
	/* Number of stop bits, 1 or 2. */
	config \|= V850E_UART_ASIM_SL_2;
	if ((cflags & CSIZE) == CS8)
	/* Number of data bits, 7 or 8. */
	config \|= V850E_UART_ASIM_CL_8;
	if (! (cflags & PARENB))
	/* No parity check/generation. */
	config \|= V850E_UART_ASIM_PS_NONE;
	else if (cflags & PARODD)
	/* Odd parity check/generation. */
	config \|= V850E_UART_ASIM_PS_ODD;
	else
	/* Even parity check/generation. */
	config \|= V850E_UART_ASIM_PS_EVEN;
	if (cflags & CREAD)
	/* Reading enabled. */
	config \|= V850E_UART_ASIM_RXE;

	config \|= V850E_UART_ASIM_CAE;
	config \|= V850E_UART_ASIM_TXE; /* Writing is always enabled. */
	config \|= V850E_UART_ASIM_ISRM; /* Errors generate a read-irq. */

	return config;
	}

	/* This should delay as long as necessary for a recently written config
	setting to settle, before we turn the uart back on. */
	static inline void
	v850e_uart_config_delay (v850e_uart_config_t config, v850e_uart_speed_t speed)
	{
	/* The UART may not be reset properly unless we wait at least 2
	`basic-clocks' until turning on the TXE/RXE bits again.
	A `basic clock' is the clock used by the baud-rate generator,
	i.e., the cpu clock divided by the 2^new_clk_divlog2.
	The loop takes 2 insns, so loop CYCLES / 2 times. */
	register unsigned count = 1 << speed.clk_divlog2;
	while (--count != 0)
	/* nothing */;
	}


	/* RX/TX interface. */

	/* Return true if all characters awaiting transmission on uart channel N
	have been transmitted. */
	#define v850e_uart_xmit_done(n) \
	(! (V850E_UART_ASIF(n) & V850E_UART_ASIF_TXBF))
	/* Wait for this to be true. */
	#define v850e_uart_wait_for_xmit_done(n) \
	do { } while (! v850e_uart_xmit_done (n))

	/* Return true if uart channel N is ready to transmit a character. */
	#define v850e_uart_xmit_ok(n) \
	(v850e_uart_xmit_done(n) && v850e_uart_cts(n))
	/* Wait for this to be true. */
	#define v850e_uart_wait_for_xmit_ok(n) \
	do { } while (! v850e_uart_xmit_ok (n))

	/* Write character CH to uart channel CHAN. */
	#define v850e_uart_putc(chan, ch) (V850E_UART_TXB(chan) = (ch))

	/* Return latest character read on channel CHAN. */
	#define v850e_uart_getc(chan) V850E_UART_RXB (chan)

	/* Return bit-mask of uart error status. */
	#define v850e_uart_err(chan) V850E_UART_ASIS (chan)
	/* Various error bits set in the error result. */
	#define V850E_UART_ERR_OVERRUN V850E_UART_ASIS_OVE
	#define V850E_UART_ERR_FRAME V850E_UART_ASIS_FE
	#define V850E_UART_ERR_PARITY V850E_UART_ASIS_PE


	#endif /* __V850_V850E_UARTA_H__ */