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/*****************************************************************************
* DANUBE BootROM
* Copyright (c) 2005, Infineon Technologies AG, All rights reserved
* IFAP DC COM SD
*****************************************************************************/
#include <config.h>
//#include <lib.h>
#include <asm/danube.h>
#include <asm/addrspace.h>
#include <asm/ifx_asc.h>
#define ASC_FIFO_PRESENT
#define SET_BIT(reg, mask) reg |= (mask)
#define CLEAR_BIT(reg, mask) reg &= (~mask)
#define CLEAR_BITS(reg, mask) CLEAR_BIT(reg, mask)
#define SET_BITS(reg, mask) SET_BIT(reg, mask)
#define SET_BITFIELD(reg, mask, off, val) {reg &= (~mask); reg |= (val << off);}
typedef unsigned char u8;
typedef unsigned short u16;
typedef unsigned long u32;
typedef signed long s32;
typedef unsigned int uint;
typedef unsigned long ulong;
typedef volatile unsigned short vuint;
void serial_setbrg (void);
/*TODO: undefine this !!!*/
#undef DEBUG_ASC_RAW
#ifdef DEBUG_ASC_RAW
#define DEBUG_ASC_RAW_RX_BUF 0xA0800000
#define DEBUG_ASC_RAW_TX_BUF 0xA0900000
#endif
static volatile DanubeAsc_t *pAsc = (DanubeAsc_t *)DANUBE_ASC1;
typedef struct{
u16 fdv; /* 0~511 fractional divider value*/
u16 reload; /* 13 bit reload value*/
} ifx_asc_baud_reg_t;
#ifdef ON_VENUS
/*9600 @1.25M rel 00.08*/
//#define FDV 503
//#define RELOAD 7
/*9600 @0.625M rel final00.01 & rtl_freeze*/
#define FDV 503
#define RELOAD 3
/* first index is DDR_SEL, second index is FPI_SEL */
#endif
static ifx_asc_baud_reg_t g_danube_asc_baud[4][2] =
{
#ifdef ON_VENUS
{{503,3},{503,3}}, /* 1152000 @ 166.67M and half*/
{{503,3},{503,3}}, /* 1152000 @ 133.3M and half*/
{{503,3},{503,3}}, /* 1152000 @ 111.11M and half*/
{{503.3},{503,3}} /* 1152000 @ 83.33M and half*/
#else
/* TAPEOUT table */
{{436,76},{419,36}}, /* 1152000 @ 166.67M and half*/
{{453,63},{453,31}}, /* 1152000 @ 133.3M and half*/
{{501,58},{510,29}}, /* 1152000 @ 111.11M and half*/
{{419.36},{453,19}} /* 1152000 @ 83.33M and half*/
#endif
};
/******************************************************************************
*
* asc_init - initialize a Danube ASC channel
*
* This routine initializes the number of data bits, parity
* and set the selected baud rate. Interrupts are disabled.
* Set the modem control signals if the option is selected.
*
* RETURNS: N/A
*/
int serial_init (void)
{
/* and we have to set CLC register*/
CLEAR_BIT(pAsc->asc_clc, ASCCLC_DISS);
SET_BITFIELD(pAsc->asc_clc, ASCCLC_RMCMASK, ASCCLC_RMCOFFSET, 0x0001);
/* initialy we are in async mode */
pAsc->asc_con = ASCCON_M_8ASYNC;
/* select input port */
pAsc->asc_pisel = (CONSOLE_TTY & 0x1);
/* TXFIFO's filling level */
SET_BITFIELD(pAsc->asc_txfcon, ASCTXFCON_TXFITLMASK,
ASCTXFCON_TXFITLOFF, DANUBEASC_TXFIFO_FL);
/* enable TXFIFO */
SET_BIT(pAsc->asc_txfcon, ASCTXFCON_TXFEN);
/* RXFIFO's filling level */
SET_BITFIELD(pAsc->asc_txfcon, ASCRXFCON_RXFITLMASK,
ASCRXFCON_RXFITLOFF, DANUBEASC_RXFIFO_FL);
/* enable RXFIFO */
SET_BIT(pAsc->asc_rxfcon, ASCRXFCON_RXFEN);
/* set baud rate */
serial_setbrg();
/* enable error signals & Receiver enable */
SET_BIT(pAsc->asc_whbstate, ASCWHBSTATE_SETREN|ASCCON_FEN|ASCCON_TOEN|ASCCON_ROEN);
return 0;
}
void serial_setbrg (void)
{
u32 uiReloadValue, fdv;
#if defined(ON_IKOS)
/*1200 @77K */
fdv=472;
uiReloadValue=5;
#else
/*venus & tapeout */
u32 ddr_sel,fpi_sel;
ddr_sel = (* DANUBE_CGU_SYS) & 0x3;
fpi_sel = ((* DANUBE_CGU_SYS) & 0x40)?1:0;
fdv= g_danube_asc_baud[ddr_sel][fpi_sel].fdv;
uiReloadValue=g_danube_asc_baud[ddr_sel][fpi_sel].reload;
#endif //ON_IKOS
/* Disable Baud Rate Generator; BG should only be written when R=0 */
CLEAR_BIT(pAsc->asc_con, ASCCON_R);
/* Enable Fractional Divider */
SET_BIT(pAsc->asc_con, ASCCON_FDE); /* FDE = 1 */
/* Set fractional divider value */
pAsc->asc_fdv = fdv & ASCFDV_VALUE_MASK;
/* Set reload value in BG */
pAsc->asc_bg = uiReloadValue;
/* Enable Baud Rate Generator */
SET_BIT(pAsc->asc_con, ASCCON_R); /* R = 1 */
}
void serial_putc (const char c)
{
u32 txFl = 0;
#ifdef DEBUG_ASC_RAW
static u8 * debug = (u8 *) DEBUG_ASC_RAW_TX_BUF;
*debug++=c;
#endif
if (c == '\n')
serial_putc ('\r');
/* check do we have a free space in the TX FIFO */
/* get current filling level */
do
{
txFl = ( pAsc->asc_fstat & ASCFSTAT_TXFFLMASK ) >> ASCFSTAT_TXFFLOFF;
}
while ( txFl == DANUBEASC_TXFIFO_FULL );
pAsc->asc_tbuf = c; /* write char to Transmit Buffer Register */
/* check for errors */
if ( pAsc->asc_state & ASCSTATE_TOE )
{
SET_BIT(pAsc->asc_whbstate, ASCWHBSTATE_CLRTOE);
return;
}
}
void serial_puts (const char *s)
{
while (*s)
{
serial_putc (*s++);
}
}
int asc_inb(int timeout)
{
u32 symbol_mask;
char c;
while ((pAsc->asc_fstat & ASCFSTAT_RXFFLMASK) == 0 ) {
}
symbol_mask = ((ASC_OPTIONS & ASCOPT_CSIZE) == ASCOPT_CS7) ? (0x7f) : (0xff);
c = (char)(pAsc->asc_rbuf & symbol_mask);
return (c);
}
int serial_getc (void)
{
char c;
while ((pAsc->asc_fstat & ASCFSTAT_RXFFLMASK) == 0 );
c = (char)(pAsc->asc_rbuf & 0xff);
#ifdef DEBUG_ASC_RAW
static u8* debug=(u8*)(DEBUG_ASC_RAW_RX_BUF);
*debug++=c;
#endif
return c;
}
int serial_tstc (void)
{
int res = 1;
#ifdef ASC_FIFO_PRESENT
if ( (pAsc->asc_fstat & ASCFSTAT_RXFFLMASK) == 0 )
{
res = 0;
}
#else
if (!(*(volatile unsigned long*)(SFPI_INTCON_BASEADDR + FBS_ISR) &
FBS_ISR_AR))
{
res = 0;
}
#endif
#if 0
else if ( pAsc->asc_con & ASCCON_FE )
{
SET_BIT(pAsc->asc_whbcon, ASCWHBCON_CLRFE);
res = 0;
}
else if ( pAsc->asc_con & ASCCON_PE )
{
SET_BIT(pAsc->asc_whbcon, ASCWHBCON_CLRPE);
res = 0;
}
else if ( pAsc->asc_con & ASCCON_OE )
{
SET_BIT(pAsc->asc_whbcon, ASCWHBCON_CLROE);
res = 0;
}
#endif
return res;
}
int serial_start(void)
{
return 1;
}
int serial_stop(void)
{
return 1;
}
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