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u-boot-brain/arch/blackfin/cpu/serial.h
Mike Frysinger a409fdd8fe Blackfin: serial: convert to portmux framework 
Use the new portmux framework to handle the details when possible.
Unfortunately, we cannot yet use this in the standalone initialization
logic, so we need to keep around the old portmux writes for now.

Signed-off-by: Mike Frysinger <vapier@gentoo.org>
2010-07-13 17:50:50 -04:00

283 lines
7.1 KiB
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/*
* 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)
/*
* 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 {
#ifdef __ADSPBF54x__
__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
#ifndef UART_LSR
# if (CONFIG_UART_CONSOLE == 3)
# define UART_BASE UART3_DLL
# elif (CONFIG_UART_CONSOLE == 2)
# define UART_BASE UART2_DLL
# elif (CONFIG_UART_CONSOLE == 1)
# define UART_BASE UART1_DLL
# elif (CONFIG_UART_CONSOLE == 0)
# define UART_BASE UART0_DLL
# endif
#else
# if CONFIG_UART_CONSOLE != 0
# error CONFIG_UART_CONSOLE must be 0 on parts with only one UART
# endif
# define UART_BASE UART_DLL
#endif
#define pUART ((volatile struct bfin_mmr_serial *)UART_BASE)
#ifdef __ADSPBF54x__
# define ACCESS_LATCH()
# define ACCESS_PORT_IER()
#else
# define ACCESS_LATCH() \
bfin_write16(&pUART->lcr, bfin_read16(&pUART->lcr) | DLAB)
# define ACCESS_PORT_IER() \
bfin_write16(&pUART->lcr, bfin_read16(&pUART->lcr) & ~DLAB)
#endif
__attribute__((always_inline))
static inline void serial_do_portmux(void)
{
if (!BFIN_DEBUG_EARLY_SERIAL) {
const unsigned short pins[] = {
#if CONFIG_UART_CONSOLE == 0
P_UART0_TX, P_UART0_RX,
#elif CONFIG_UART_CONSOLE == 1
P_UART1_TX, P_UART1_RX,
#elif CONFIG_UART_CONSOLE == 2
P_UART2_TX, P_UART2_RX,
#elif CONFIG_UART_CONSOLE == 3
P_UART3_TX, P_UART3_RX,
#endif
0,
};
peripheral_request_list(pins, "bfin-uart");
return;
}
#if 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__)
# define DO_MUX(func, tx, rx) \
bfin_write_PORT_MUX(bfin_read_PORT_MUX() & ~(func)); \
bfin_write_PORTF_FER(bfin_read_PORTF_FER() | PF##tx | PF##rx);
switch (CONFIG_UART_CONSOLE) {
case 0: DO_MUX(PFDE, 0, 1); break;
case 1: DO_MUX(PFTE, 2, 3); break;
}
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();
#endif
}
__attribute__((always_inline))
static inline void serial_early_init(void)
{
/* handle portmux crap on different Blackfins */
serial_do_portmux();
/* always enable UART -- avoids anomalies 05000309 and 05000350 */
bfin_write16(&pUART->gctl, UCEN);
/* Set LCR to Word Lengh 8-bit word select */
bfin_write16(&pUART->lcr, WLS_8);
SSYNC();
}
__attribute__((always_inline))
static inline void serial_early_put_div(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_write16(&pUART->dll, LOB(divisor));
bfin_write16(&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)
{
/* Set DLAB in LCR to Access DLL and DLH */
ACCESS_LATCH();
SSYNC();
uint8_t dll = bfin_read16(&pUART->dll);
uint8_t dlh = bfin_read16(&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 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((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) \
call _get_pc; \
jump 1f; \
.ascii "Early:"; \
.ascii __FILE__; \
.ascii ": "; \
.ascii str; \
.asciz "\n"; \
.align 4; \
1: \
R0 += 2; \
call _serial_puts;
#else
# define serial_early_puts(str)
#endif
#endif
#endif
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