arch/blackfin/cpu/serial.h - platform/external/u-boot - Gitiles

 /*
  * serial.h - common serial defines for early debug and serial driver.
  *            any functions defined here must be always_inline since
  *            initcode cannot have function calls.
  *
  * Copyright (c) 2004-2007 Analog Devices Inc.
  *
  * Licensed under the GPL-2 or later.
  */

 #ifndef __BFIN_CPU_SERIAL_H__
 #define __BFIN_CPU_SERIAL_H__

 #include <asm/blackfin.h>
 #include <asm/mach-common/bits/uart.h>

 #ifndef CONFIG_UART_CONSOLE
 # define CONFIG_UART_CONSOLE 0
 #endif

 #ifdef CONFIG_DEBUG_EARLY_SERIAL
 # define BFIN_DEBUG_EARLY_SERIAL 1
 #else
 # define BFIN_DEBUG_EARLY_SERIAL 0
 #endif

 #ifndef __ASSEMBLY__

 #include <asm/portmux.h>

 #define LOB(x) ((x) & 0xFF)
 #define HIB(x) (((x) >> 8) & 0xFF)

 #if defined(__ADSPBF50x__) || defined(__ADSPBF54x__)
 # define BFIN_UART_HW_VER 2
 #else
 # define BFIN_UART_HW_VER 1
 #endif

 /*
  * All Blackfin system MMRs are padded to 32bits even if the register
  * itself is only 16bits.  So use a helper macro to streamline this.
  */
 #define __BFP(m) u16 m; u16 __pad_##m
 struct bfin_mmr_serial {
 #if BFIN_UART_HW_VER == 2
 	__BFP(dll);
 	__BFP(dlh);
 	__BFP(gctl);
 	__BFP(lcr);
 	__BFP(mcr);
 	__BFP(lsr);
 	__BFP(msr);
 	__BFP(scr);
 	__BFP(ier_set);
 	__BFP(ier_clear);
 	__BFP(thr);
 	__BFP(rbr);
 #else
 	union {
 		u16 dll;
 		u16 thr;
 		const u16 rbr;
 	};
 	const u16 __spad0;
 	union {
 		u16 dlh;
 		u16 ier;
 	};
 	const u16 __spad1;
 	const __BFP(iir);
 	__BFP(lcr);
 	__BFP(mcr);
 	__BFP(lsr);
 	__BFP(msr);
 	__BFP(scr);
 	const u32 __spad2;
 	__BFP(gctl);
 #endif
 };
 #undef __BFP

 #define __PASTE_UART(num, pfx, sfx) pfx##num##_##sfx
 #define _PASTE_UART(num, pfx, sfx) __PASTE_UART(num, pfx, sfx)
 #define MMR_UART(n) _PASTE_UART(n, UART, DLL)
 #define _P_UART(n, pin) _PASTE_UART(n, P_UART, pin)
 #define P_UART(pin) _P_UART(CONFIG_UART_CONSOLE, pin)

 #ifndef UART_DLL
 # define UART_DLL MMR_UART(CONFIG_UART_CONSOLE)
 #else
 # define UART0_DLL UART_DLL
 # if CONFIG_UART_CONSOLE != 0
 #  error CONFIG_UART_CONSOLE must be 0 on parts with only one UART
 # endif
 #endif
 #define pUART ((volatile struct bfin_mmr_serial *)uart_base)

 #if BFIN_UART_HW_VER == 2
 # define ACCESS_LATCH()
 # define ACCESS_PORT_IER()
 #else
 # define ACCESS_LATCH() \
 	bfin_write(&pUART->lcr, bfin_read(&pUART->lcr) | DLAB)
 # define ACCESS_PORT_IER() \
 	bfin_write(&pUART->lcr, bfin_read(&pUART->lcr) & ~DLAB)
 #endif

 __attribute__((always_inline))
 static inline void serial_do_portmux(void)
 {
 	if (!BFIN_DEBUG_EARLY_SERIAL) {
 		const unsigned short pins[] = { P_UART(RX), P_UART(TX), 0, };
 		peripheral_request_list(pins, "bfin-uart");
 		return;
 	}

 #if defined(__ADSPBF50x__)
 # define DO_MUX(port, mux_tx, mux_rx, tx, rx) \
 	bfin_write_PORT##port##_MUX((bfin_read_PORT##port##_MUX() & ~(PORT_x_MUX_##mux_tx##_MASK | PORT_x_MUX_##mux_rx##_MASK)) | PORT_x_MUX_##mux_tx##_FUNC_1 | PORT_x_MUX_##mux_rx##_FUNC_1); \
 	bfin_write_PORT##port##_FER(bfin_read_PORT##port##_FER() | P##port##tx | P##port##rx);
 	switch (CONFIG_UART_CONSOLE) {
 	case 0: DO_MUX(G, 7, 7, 12, 13); break;	/* Port G; mux 7; PG12 and PG13 */
 	case 1: DO_MUX(F, 3, 3, 6, 7);   break;	/* Port F; mux 3; PF6 and PF7 */
 	}
 	SSYNC();
 #elif defined(__ADSPBF51x__)
 # define DO_MUX(port, mux_tx, mux_rx, tx, rx) \
 	bfin_write_PORT##port##_MUX((bfin_read_PORT##port##_MUX() & ~(PORT_x_MUX_##mux_tx##_MASK | PORT_x_MUX_##mux_rx##_MASK)) | PORT_x_MUX_##mux_tx##_FUNC_2 | PORT_x_MUX_##mux_rx##_FUNC_2); \
 	bfin_write_PORT##port##_FER(bfin_read_PORT##port##_FER() | P##port##tx | P##port##rx);
 	switch (CONFIG_UART_CONSOLE) {
 	case 0: DO_MUX(G, 5, 5, 9, 10);  break;	/* Port G; mux 5; PG9 and PG10 */
 	case 1: DO_MUX(F, 2, 3, 14, 15); break;	/* Port H; mux 2/3; PH14 and PH15 */
 	}
 	SSYNC();
 #elif defined(__ADSPBF52x__)
 # define DO_MUX(port, mux, tx, rx) \
 	bfin_write_PORT##port##_MUX((bfin_read_PORT##port##_MUX() & ~PORT_x_MUX_##mux##_MASK) | PORT_x_MUX_##mux##_FUNC_3); \
 	bfin_write_PORT##port##_FER(bfin_read_PORT##port##_FER() | P##port##tx | P##port##rx);
 	switch (CONFIG_UART_CONSOLE) {
 	case 0: DO_MUX(G, 2, 7, 8);   break;	/* Port G; mux 2; PG2 and PG8 */
 	case 1: DO_MUX(F, 5, 14, 15); break;	/* Port F; mux 5; PF14 and PF15 */
 	}
 	SSYNC();
 #elif defined(__ADSPBF537__) || defined(__ADSPBF536__) || defined(__ADSPBF534__)
 	const uint16_t func[] = { PFDE, PFTE, };
 	bfin_write_PORT_MUX(bfin_read_PORT_MUX() & ~func[CONFIG_UART_CONSOLE]);
 	bfin_write_PORTF_FER(bfin_read_PORTF_FER() |
 	                     (1 << P_IDENT(P_UART(RX))) |
 	                     (1 << P_IDENT(P_UART(TX))));
 	SSYNC();
 #elif defined(__ADSPBF54x__)
 # define DO_MUX(port, tx, rx) \
 	bfin_write_PORT##port##_MUX((bfin_read_PORT##port##_MUX() & ~(PORT_x_MUX_##tx##_MASK | PORT_x_MUX_##rx##_MASK)) | PORT_x_MUX_##tx##_FUNC_1 | PORT_x_MUX_##rx##_FUNC_1); \
 	bfin_write_PORT##port##_FER(bfin_read_PORT##port##_FER() | P##port##tx | P##port##rx);
 	switch (CONFIG_UART_CONSOLE) {
 	case 0: DO_MUX(E, 7, 8); break;	/* Port E; PE7 and PE8 */
 	case 1: DO_MUX(H, 0, 1); break;	/* Port H; PH0 and PH1 */
 	case 2: DO_MUX(B, 4, 5); break;	/* Port B; PB4 and PB5 */
 	case 3: DO_MUX(B, 6, 7); break;	/* Port B; PB6 and PB7 */
 	}
 	SSYNC();
 #elif defined(__ADSPBF561__)
 	/* UART pins could be GPIO, but they aren't pin muxed.  */
 #else
 # if (P_UART(RX) & P_DEFINED) || (P_UART(TX) & P_DEFINED)
 #  error "missing portmux logic for UART"
 # endif
 #endif
 }

 __attribute__((always_inline))
 static inline int uart_init(uint32_t uart_base)
 {
 	/* always enable UART -- avoids anomalies 05000309 and 05000350 */
 	bfin_write(&pUART->gctl, UCEN);

 	/* Set LCR to Word Lengh 8-bit word select */
 	bfin_write(&pUART->lcr, WLS_8);

 	SSYNC();

 	return 0;
 }

 __attribute__((always_inline))
 static inline int serial_early_init(uint32_t uart_base)
 {
 	/* handle portmux crap on different Blackfins */
 	serial_do_portmux();

 	return uart_init(uart_base);
 }

 __attribute__((always_inline))
 static inline int serial_early_uninit(uint32_t uart_base)
 {
 	/* disable the UART by clearing UCEN */
 	bfin_write(&pUART->gctl, 0);

 	return 0;
 }

 __attribute__((always_inline))
 static inline void serial_early_put_div(uint32_t uart_base, uint16_t divisor)
 {
 	/* Set DLAB in LCR to Access DLL and DLH */
 	ACCESS_LATCH();
 	SSYNC();

 	/* Program the divisor to get the baud rate we want */
 	bfin_write(&pUART->dll, LOB(divisor));
 	bfin_write(&pUART->dlh, HIB(divisor));
 	SSYNC();

 	/* Clear DLAB in LCR to Access THR RBR IER */
 	ACCESS_PORT_IER();
 	SSYNC();
 }

 __attribute__((always_inline))
 static inline uint16_t serial_early_get_div(void)
 {
 	uint32_t uart_base = UART_DLL;

 	/* Set DLAB in LCR to Access DLL and DLH */
 	ACCESS_LATCH();
 	SSYNC();

 	uint8_t dll = bfin_read(&pUART->dll);
 	uint8_t dlh = bfin_read(&pUART->dlh);
 	uint16_t divisor = (dlh << 8) | dll;

 	/* Clear DLAB in LCR to Access THR RBR IER */
 	ACCESS_PORT_IER();
 	SSYNC();

 	return divisor;
 }

 /* We cannot use get_sclk() early on as it uses caches in external memory */
 #if defined(BFIN_IN_INITCODE) || defined(CONFIG_DEBUG_EARLY_SERIAL)
 # define get_sclk() (CONFIG_CLKIN_HZ * CONFIG_VCO_MULT / CONFIG_SCLK_DIV)
 #endif

 __attribute__((always_inline))
 static inline void serial_early_set_baud(uint32_t uart_base, uint32_t baud)
 {
 	/* Translate from baud into divisor in terms of SCLK.  The
 	 * weird multiplication is to make sure we over sample just
 	 * a little rather than under sample the incoming signals.
 	 */
 	serial_early_put_div(uart_base,
 		(get_sclk() + (baud * 8)) / (baud * 16) - ANOMALY_05000230);
 }

 #ifndef BFIN_IN_INITCODE
 __attribute__((always_inline))
 static inline void serial_early_puts(const char *s)
 {
 	if (BFIN_DEBUG_EARLY_SERIAL) {
 		serial_puts("Early: ");
 		serial_puts(s);
 	}
 }
 #endif

 #else

 .macro serial_early_init
 #ifdef CONFIG_DEBUG_EARLY_SERIAL
 	call _serial_initialize;
 #endif
 .endm

 .macro serial_early_set_baud
 #ifdef CONFIG_DEBUG_EARLY_SERIAL
 	R0.L = LO(CONFIG_BAUDRATE);
 	R0.H = HI(CONFIG_BAUDRATE);
 	call _serial_set_baud;
 #endif
 .endm

 /* Since we embed the string right into our .text section, we need
  * to find its address.  We do this by getting our PC and adding 2
  * bytes (which is the length of the jump instruction).  Then we
  * pass this address to serial_puts().
  */
 #ifdef CONFIG_DEBUG_EARLY_SERIAL
 # define serial_early_puts(str) \
 	.section .rodata; \
 	7: \
 	.ascii "Early:"; \
 	.ascii __FILE__; \
 	.ascii ": "; \
 	.ascii str; \
 	.asciz "\n"; \
 	.previous; \
 	R0.L = 7b; \
 	R0.H = 7b; \
 	call _serial_puts;
 #else
 # define serial_early_puts(str)
 #endif

 #endif

 #endif
	/*
	* serial.h - common serial defines for early debug and serial driver.
	* any functions defined here must be always_inline since
	* initcode cannot have function calls.
	*
	* Copyright (c) 2004-2007 Analog Devices Inc.
	*
	* Licensed under the GPL-2 or later.
	*/

	#ifndef __BFIN_CPU_SERIAL_H__
	#define __BFIN_CPU_SERIAL_H__

	#include <asm/blackfin.h>
	#include <asm/mach-common/bits/uart.h>

	#ifndef CONFIG_UART_CONSOLE
	# define CONFIG_UART_CONSOLE 0
	#endif

	#ifdef CONFIG_DEBUG_EARLY_SERIAL
	# define BFIN_DEBUG_EARLY_SERIAL 1
	#else
	# define BFIN_DEBUG_EARLY_SERIAL 0
	#endif

	#ifndef __ASSEMBLY__

	#include <asm/portmux.h>

	#define LOB(x) ((x) & 0xFF)
	#define HIB(x) (((x) >> 8) & 0xFF)

	#if defined(__ADSPBF50x__) \|\| defined(__ADSPBF54x__)
	# define BFIN_UART_HW_VER 2
	#else
	# define BFIN_UART_HW_VER 1
	#endif

	/*
	* All Blackfin system MMRs are padded to 32bits even if the register
	* itself is only 16bits. So use a helper macro to streamline this.
	*/
	#define __BFP(m) u16 m; u16 __pad_##m
	struct bfin_mmr_serial {
	#if BFIN_UART_HW_VER == 2
	__BFP(dll);
	__BFP(dlh);
	__BFP(gctl);
	__BFP(lcr);
	__BFP(mcr);
	__BFP(lsr);
	__BFP(msr);
	__BFP(scr);
	__BFP(ier_set);
	__BFP(ier_clear);
	__BFP(thr);
	__BFP(rbr);
	#else
	union {
	u16 dll;
	u16 thr;
	const u16 rbr;
	};
	const u16 __spad0;
	union {
	u16 dlh;
	u16 ier;
	};
	const u16 __spad1;
	const __BFP(iir);
	__BFP(lcr);
	__BFP(mcr);
	__BFP(lsr);
	__BFP(msr);
	__BFP(scr);
	const u32 __spad2;
	__BFP(gctl);
	#endif
	};
	#undef __BFP

	#define __PASTE_UART(num, pfx, sfx) pfx##num##_##sfx
	#define _PASTE_UART(num, pfx, sfx) __PASTE_UART(num, pfx, sfx)
	#define MMR_UART(n) _PASTE_UART(n, UART, DLL)
	#define _P_UART(n, pin) _PASTE_UART(n, P_UART, pin)
	#define P_UART(pin) _P_UART(CONFIG_UART_CONSOLE, pin)

	#ifndef UART_DLL
	# define UART_DLL MMR_UART(CONFIG_UART_CONSOLE)
	#else
	# define UART0_DLL UART_DLL
	# if CONFIG_UART_CONSOLE != 0
	# error CONFIG_UART_CONSOLE must be 0 on parts with only one UART
	# endif
	#endif
	#define pUART ((volatile struct bfin_mmr_serial *)uart_base)

	#if BFIN_UART_HW_VER == 2
	# define ACCESS_LATCH()
	# define ACCESS_PORT_IER()
	#else
	# define ACCESS_LATCH() \
	bfin_write(&pUART->lcr, bfin_read(&pUART->lcr) \| DLAB)
	# define ACCESS_PORT_IER() \
	bfin_write(&pUART->lcr, bfin_read(&pUART->lcr) & ~DLAB)
	#endif

	__attribute__((always_inline))
	static inline void serial_do_portmux(void)
	{
	if (!BFIN_DEBUG_EARLY_SERIAL) {
	const unsigned short pins[] = { P_UART(RX), P_UART(TX), 0, };
	peripheral_request_list(pins, "bfin-uart");
	return;
	}

	#if defined(__ADSPBF50x__)
	# define DO_MUX(port, mux_tx, mux_rx, tx, rx) \
	bfin_write_PORT##port##_MUX((bfin_read_PORT##port##_MUX() & ~(PORT_x_MUX_##mux_tx##_MASK \| PORT_x_MUX_##mux_rx##_MASK)) \| PORT_x_MUX_##mux_tx##_FUNC_1 \| PORT_x_MUX_##mux_rx##_FUNC_1); \
	bfin_write_PORT##port##_FER(bfin_read_PORT##port##_FER() \| P##port##tx \| P##port##rx);
	switch (CONFIG_UART_CONSOLE) {
	case 0: DO_MUX(G, 7, 7, 12, 13); break; /* Port G; mux 7; PG12 and PG13 */
	case 1: DO_MUX(F, 3, 3, 6, 7); break; /* Port F; mux 3; PF6 and PF7 */
	}
	SSYNC();
	#elif defined(__ADSPBF51x__)
	# define DO_MUX(port, mux_tx, mux_rx, tx, rx) \
	bfin_write_PORT##port##_MUX((bfin_read_PORT##port##_MUX() & ~(PORT_x_MUX_##mux_tx##_MASK \| PORT_x_MUX_##mux_rx##_MASK)) \| PORT_x_MUX_##mux_tx##_FUNC_2 \| PORT_x_MUX_##mux_rx##_FUNC_2); \
	bfin_write_PORT##port##_FER(bfin_read_PORT##port##_FER() \| P##port##tx \| P##port##rx);
	switch (CONFIG_UART_CONSOLE) {
	case 0: DO_MUX(G, 5, 5, 9, 10); break; /* Port G; mux 5; PG9 and PG10 */
	case 1: DO_MUX(F, 2, 3, 14, 15); break; /* Port H; mux 2/3; PH14 and PH15 */
	}
	SSYNC();
	#elif defined(__ADSPBF52x__)
	# define DO_MUX(port, mux, tx, rx) \
	bfin_write_PORT##port##_MUX((bfin_read_PORT##port##_MUX() & ~PORT_x_MUX_##mux##_MASK) \| PORT_x_MUX_##mux##_FUNC_3); \
	bfin_write_PORT##port##_FER(bfin_read_PORT##port##_FER() \| P##port##tx \| P##port##rx);
	switch (CONFIG_UART_CONSOLE) {
	case 0: DO_MUX(G, 2, 7, 8); break; /* Port G; mux 2; PG2 and PG8 */
	case 1: DO_MUX(F, 5, 14, 15); break; /* Port F; mux 5; PF14 and PF15 */
	}
	SSYNC();
	#elif defined(__ADSPBF537__) \|\| defined(__ADSPBF536__) \|\| defined(__ADSPBF534__)
	const uint16_t func[] = { PFDE, PFTE, };
	bfin_write_PORT_MUX(bfin_read_PORT_MUX() & ~func[CONFIG_UART_CONSOLE]);
	bfin_write_PORTF_FER(bfin_read_PORTF_FER() \|
	(1 << P_IDENT(P_UART(RX))) \|
	(1 << P_IDENT(P_UART(TX))));
	SSYNC();
	#elif defined(__ADSPBF54x__)
	# define DO_MUX(port, tx, rx) \
	bfin_write_PORT##port##_MUX((bfin_read_PORT##port##_MUX() & ~(PORT_x_MUX_##tx##_MASK \| PORT_x_MUX_##rx##_MASK)) \| PORT_x_MUX_##tx##_FUNC_1 \| PORT_x_MUX_##rx##_FUNC_1); \
	bfin_write_PORT##port##_FER(bfin_read_PORT##port##_FER() \| P##port##tx \| P##port##rx);
	switch (CONFIG_UART_CONSOLE) {
	case 0: DO_MUX(E, 7, 8); break; /* Port E; PE7 and PE8 */
	case 1: DO_MUX(H, 0, 1); break; /* Port H; PH0 and PH1 */
	case 2: DO_MUX(B, 4, 5); break; /* Port B; PB4 and PB5 */
	case 3: DO_MUX(B, 6, 7); break; /* Port B; PB6 and PB7 */
	}
	SSYNC();
	#elif defined(__ADSPBF561__)
	/* UART pins could be GPIO, but they aren't pin muxed. */
	#else
	# if (P_UART(RX) & P_DEFINED) \|\| (P_UART(TX) & P_DEFINED)
	# error "missing portmux logic for UART"
	# endif
	#endif
	}

	__attribute__((always_inline))
	static inline int uart_init(uint32_t uart_base)
	{
	/* always enable UART -- avoids anomalies 05000309 and 05000350 */
	bfin_write(&pUART->gctl, UCEN);

	/* Set LCR to Word Lengh 8-bit word select */
	bfin_write(&pUART->lcr, WLS_8);

	SSYNC();

	return 0;
	}

	__attribute__((always_inline))
	static inline int serial_early_init(uint32_t uart_base)
	{
	/* handle portmux crap on different Blackfins */
	serial_do_portmux();

	return uart_init(uart_base);
	}

	__attribute__((always_inline))
	static inline int serial_early_uninit(uint32_t uart_base)
	{
	/* disable the UART by clearing UCEN */
	bfin_write(&pUART->gctl, 0);

	return 0;
	}

	__attribute__((always_inline))
	static inline void serial_early_put_div(uint32_t uart_base, uint16_t divisor)
	{
	/* Set DLAB in LCR to Access DLL and DLH */
	ACCESS_LATCH();
	SSYNC();

	/* Program the divisor to get the baud rate we want */
	bfin_write(&pUART->dll, LOB(divisor));
	bfin_write(&pUART->dlh, HIB(divisor));
	SSYNC();

	/* Clear DLAB in LCR to Access THR RBR IER */
	ACCESS_PORT_IER();
	SSYNC();
	}

	__attribute__((always_inline))
	static inline uint16_t serial_early_get_div(void)
	{
	uint32_t uart_base = UART_DLL;

	/* Set DLAB in LCR to Access DLL and DLH */
	ACCESS_LATCH();
	SSYNC();

	uint8_t dll = bfin_read(&pUART->dll);
	uint8_t dlh = bfin_read(&pUART->dlh);
	uint16_t divisor = (dlh << 8) \| dll;

	/* Clear DLAB in LCR to Access THR RBR IER */
	ACCESS_PORT_IER();
	SSYNC();

	return divisor;
	}

	/* We cannot use get_sclk() early on as it uses caches in external memory */
	#if defined(BFIN_IN_INITCODE) \|\| defined(CONFIG_DEBUG_EARLY_SERIAL)
	# define get_sclk() (CONFIG_CLKIN_HZ * CONFIG_VCO_MULT / CONFIG_SCLK_DIV)
	#endif

	__attribute__((always_inline))
	static inline void serial_early_set_baud(uint32_t uart_base, uint32_t baud)
	{
	/* Translate from baud into divisor in terms of SCLK. The
	* weird multiplication is to make sure we over sample just
	* a little rather than under sample the incoming signals.
	*/
	serial_early_put_div(uart_base,
	(get_sclk() + (baud * 8)) / (baud * 16) - ANOMALY_05000230);
	}

	#ifndef BFIN_IN_INITCODE
	__attribute__((always_inline))
	static inline void serial_early_puts(const char *s)
	{
	if (BFIN_DEBUG_EARLY_SERIAL) {
	serial_puts("Early: ");
	serial_puts(s);
	}
	}
	#endif

	#else

	.macro serial_early_init
	#ifdef CONFIG_DEBUG_EARLY_SERIAL
	call _serial_initialize;
	#endif
	.endm

	.macro serial_early_set_baud
	#ifdef CONFIG_DEBUG_EARLY_SERIAL
	R0.L = LO(CONFIG_BAUDRATE);
	R0.H = HI(CONFIG_BAUDRATE);
	call _serial_set_baud;
	#endif
	.endm

	/* Since we embed the string right into our .text section, we need
	* to find its address. We do this by getting our PC and adding 2
	* bytes (which is the length of the jump instruction). Then we
	* pass this address to serial_puts().
	*/
	#ifdef CONFIG_DEBUG_EARLY_SERIAL
	# define serial_early_puts(str) \
	.section .rodata; \
	7: \
	.ascii "Early:"; \
	.ascii __FILE__; \
	.ascii ": "; \
	.ascii str; \
	.asciz "\n"; \
	.previous; \
	R0.L = 7b; \
	R0.H = 7b; \
	call _serial_puts;
	#else
	# define serial_early_puts(str)
	#endif

	#endif

	#endif