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* Patch by Andreas Oberritter, 09 Nov 2002: 

Change behaviour of NetLoop(): return -1 for errors, filesize
  otherwise; return code 0 is valid an means no file loaded - in this
  case the environment still gets updated!

* Patches by Jon Diekema, 9 Nov 2002:
  - improve ADC/DAC clocking on the SACSng board to align
    the failing edges of LRCLK and SCLK
  - sbc8260 configuration tweaks
  - add status LED support for 82xx systems
  - wire sspi/sspo commands into command handler; improved error
    handlering
  - add timestamp support and alternate memory test to the
    SACSng configuration
This commit is contained in:
wdenk 2002-11-11 02:11:37 +00:00
parent 7f6c2cbc2b
commit eb9401e3eb
11 changed files with 430 additions and 226 deletions
Show Stats Download Patch File Download Diff File Expand all files Collapse all files

17
CHANGELOG
View File

@ -2,7 +2,22 @@
Changes since for U-Boot 0.1.0:
======================================================================
* Vince Husovsky, 7 Nov 2002:
* Patch by Andreas Oberritter, 09 Nov 2002:
Change behaviour of NetLoop(): return -1 for errors, filesize
otherwise; return code 0 is valid an means no file loaded - in this
case the environment still gets updated!
* Patches by Jon Diekema, 9 Nov 2002:
- improve ADC/DAC clocking on the SACSng board to align
the failing edges of LRCLK and SCLK
- sbc8260 configuration tweaks
- add status LED support for 82xx systems
- wire sspi/sspo commands into command handler; improved error
handlering
- add timestamp support and alternate memory test to the
SACSng configuration
* Patch by Vince Husovsky, 7 Nov 2002:
Add "-n" to linker options to get rid of "Not enough room for
program headers" problem

2
board/hymod/bsp.c
View File

@ -197,7 +197,7 @@ do_fpga (cmd_tbl_t * cmdtp, int flag, int argc, char *argv[])
copy_filename (BootFile, argv[2], sizeof (BootFile));
load_addr = simple_strtoul (argv[3], NULL, 16);
if (NetLoop (TFTP) == 0) {
if (NetLoop (TFTP) <= 0) {
printf ("tftp transfer failed - aborting fgpa load\n");
return 1;
}

2
board/hymod/fetch.c
View File

@ -89,7 +89,7 @@ fetch_and_parse(bd_t *bd, char *fn, ulong addr, int (*cback)(uchar *, uchar *))
copy_filename(BootFile, fn, sizeof (BootFile));
load_addr = addr;
if (NetLoop(TFTP) == 0) {
if (NetLoop(TFTP) <= 0) {
printf("tftp transfer of file '%s' failed\n", fn);
return (0);
}

531
board/sacsng/clkinit.c
View File

@ -286,7 +286,6 @@ uint Daq_BRG_Rate(uint brg)
}
uint Daq_Get_SampleRate(void)
{
/*
* Read the BRG's to return the actual sample rate.
@ -294,68 +293,12 @@ uint Daq_Get_SampleRate(void)
return (Daq_BRG_Rate(MCLK_BRG) / (MCLK_DIVISOR * SCLK_DIVISOR));
}
uint Daq_Set_SampleRate(uint rate, uint force)
void Daq_Init_Clocks(int sample_rate, int sample_64x)
{
DECLARE_GLOBAL_DATA_PTR;
uint mclk_divisor; /* MCLK divisor */
uint rate_curr; /* Current sample rate */
/*
* Limit the sample rate to some sensible values.
*/
if (Daq64xSampling) {
if (rate > MAX_64x_SAMPLE_RATE) {
rate = MAX_64x_SAMPLE_RATE;
}
}
else {
if (rate > MAX_128x_SAMPLE_RATE) {
rate = MAX_128x_SAMPLE_RATE;
}
}
if (rate < MIN_SAMPLE_RATE) {
rate = MIN_SAMPLE_RATE;
}
/* Check to see if we are really changing rates */
rate_curr = Daq_Get_SampleRate();
if ((rate != rate_curr) || force) {
/*
* Dynamically adjust MCLK based on the new sample rate.
*/
/* Compute the divisors */
mclk_divisor = BRG_INT_CLK / (rate * MCLK_DIVISOR * SCLK_DIVISOR);
/* Setup MCLK */
Daq_BRG_Set_Count(MCLK_BRG, mclk_divisor);
/* Setup SCLK */
# ifdef RUN_SCLK_ON_BRG_INT
Daq_BRG_Set_Count(SCLK_BRG, mclk_divisor * MCLK_DIVISOR);
# else
Daq_BRG_Set_Count(SCLK_BRG, MCLK_DIVISOR);
# endif
# ifdef RUN_LRCLK_ON_BRG_INT
Daq_BRG_Set_Count(LRCLK_BRG,
mclk_divisor * MCLK_DIVISOR * SCLK_DIVISOR);
# else
Daq_BRG_Set_Count(LRCLK_BRG, SCLK_DIVISOR);
# endif
/* Read the BRG's to return the actual sample rate. */
rate_curr = Daq_Get_SampleRate();
}
return (rate_curr);
}
void Daq_Init_Clocks(int sample_rate, int sample_64x)
{
volatile ioport_t *iopa = ioport_addr((immap_t *)CFG_IMMR, 0 /* port A */);
uint mclk_divisor; /* MCLK divisor */
int flag; /* Interrupt state */
/* Save off the clocking data */
Daq64xSampling = sample_64x;
@ -363,18 +306,11 @@ void Daq_Init_Clocks(int sample_rate, int sample_64x)
/*
* Limit the sample rate to some sensible values.
*/
if (Daq64xSampling) {
if (sample_rate > MAX_64x_SAMPLE_RATE) {
sample_rate = MAX_64x_SAMPLE_RATE;
}
}
else {
if (sample_rate > MAX_128x_SAMPLE_RATE) {
sample_rate = MAX_128x_SAMPLE_RATE;
}
if (sample_rate > MAX_64x_SAMPLE_RATE) {
sample_rate = MAX_64x_SAMPLE_RATE;
}
if (sample_rate < MIN_SAMPLE_RATE) {
sample_rate = MIN_SAMPLE_RATE;
sample_rate = MIN_SAMPLE_RATE;
}
/*
@ -398,8 +334,41 @@ void Daq_Init_Clocks(int sample_rate, int sample_64x)
Daq_BRG_Set_ExtClk(LRCLK_BRG, CPM_BRG_EXTC_CLK5);
# endif
/* Setup the BRG rates */
Daq_Set_SampleRate(sample_rate, TRUE);
/*
* Dynamically adjust MCLK based on the new sample rate.
*/
/* Compute the divisors */
mclk_divisor = BRG_INT_CLK / (sample_rate * MCLK_DIVISOR * SCLK_DIVISOR);
/*
* Disable interrupt and save the current state
*/
flag = disable_interrupts();
/* Setup MCLK */
Daq_BRG_Set_Count(MCLK_BRG, mclk_divisor);
/* Setup SCLK */
# ifdef RUN_SCLK_ON_BRG_INT
Daq_BRG_Set_Count(SCLK_BRG, mclk_divisor * MCLK_DIVISOR);
# else
Daq_BRG_Set_Count(SCLK_BRG, MCLK_DIVISOR);
# endif
# ifdef RUN_LRCLK_ON_BRG_INT
Daq_BRG_Set_Count(LRCLK_BRG,
mclk_divisor * MCLK_DIVISOR * SCLK_DIVISOR);
# else
Daq_BRG_Set_Count(LRCLK_BRG, SCLK_DIVISOR);
# endif
/*
* Restore the Interrupt state
*/
if (flag) {
enable_interrupts();
}
/* Enable the clock drivers */
iopa->pdat &= ~SLRCLK_EN_MASK;
@ -410,116 +379,276 @@ void Daq_Stop_Clocks(void)
{
#ifdef TIGHTEN_UP_BRG_TIMING
volatile immap_t *immr = (immap_t *)CFG_IMMR;
register uint mclk_brg; /* MCLK BRG value */
register uint sclk_brg; /* SCLK BRG value */
register uint lrclk_brg; /* LRCLK BRG value */
unsigned long flag; /* Interrupt flags */
#endif
# ifdef TIGHTEN_UP_BRG_TIMING
/*
* Reset MCLK BRG
/*
* Obtain MCLK BRG reset/disabled value
*/
# if (MCLK_BRG == 0)
immr->im_brgc1 |= CPM_BRG_RST;
immr->im_brgc1 &= ~CPM_BRG_RST;
mclk_brg = (*IM_BRGC1 | CPM_BRG_RST) & ~CPM_BRG_EN;
# endif
# if (MCLK_BRG == 1)
immr->im_brgc2 |= CPM_BRG_RST;
immr->im_brgc2 &= ~CPM_BRG_RST;
mclk_brg = (*IM_BRGC2 | CPM_BRG_RST) & ~CPM_BRG_EN;
# endif
# if (MCLK_BRG == 2)
immr->im_brgc3 |= CPM_BRG_RST;
immr->im_brgc3 &= ~CPM_BRG_RST;
mclk_brg = (*IM_BRGC3 | CPM_BRG_RST) & ~CPM_BRG_EN;
# endif
# if (MCLK_BRG == 3)
immr->im_brgc4 |= CPM_BRG_RST;
immr->im_brgc4 &= ~CPM_BRG_RST;
mclk_brg = (*IM_BRGC4 | CPM_BRG_RST) & ~CPM_BRG_EN;
# endif
# if (MCLK_BRG == 4)
immr->im_brgc5 |= CPM_BRG_RST;
immr->im_brgc5 &= ~CPM_BRG_RST;
mclk_brg = (*IM_BRGC5 | CPM_BRG_RST) & ~CPM_BRG_EN;
# endif
# if (MCLK_BRG == 5)
immr->im_brgc6 |= CPM_BRG_RST;
immr->im_brgc6 &= ~CPM_BRG_RST;
mclk_brg = (*IM_BRGC6 | CPM_BRG_RST) & ~CPM_BRG_EN;
# endif
# if (MCLK_BRG == 6)
immr->im_brgc7 |= CPM_BRG_RST;
immr->im_brgc7 &= ~CPM_BRG_RST;
mclk_brg = (*IM_BRGC7 | CPM_BRG_RST) & ~CPM_BRG_EN;
# endif
# if (MCLK_BRG == 7)
immr->im_brgc8 |= CPM_BRG_RST;
immr->im_brgc8 &= ~CPM_BRG_RST;
mclk_brg = (*IM_BRGC8 | CPM_BRG_RST) & ~CPM_BRG_EN;
# endif
/*
* Reset SCLK BRG
/*
* Obtain SCLK BRG reset/disabled value
*/
# if (SCLK_BRG == 0)
immr->im_brgc1 |= CPM_BRG_RST;
immr->im_brgc1 &= ~CPM_BRG_RST;
sclk_brg = (*IM_BRGC1 | CPM_BRG_RST) & ~CPM_BRG_EN;
# endif
# if (SCLK_BRG == 1)
immr->im_brgc2 |= CPM_BRG_RST;
immr->im_brgc2 &= ~CPM_BRG_RST;
sclk_brg = (*IM_BRGC2 | CPM_BRG_RST) & ~CPM_BRG_EN;
# endif
# if (SCLK_BRG == 2)
immr->im_brgc3 |= CPM_BRG_RST;
immr->im_brgc3 &= ~CPM_BRG_RST;
sclk_brg = (*IM_BRGC3 | CPM_BRG_RST) & ~CPM_BRG_EN;
# endif
# if (SCLK_BRG == 3)
immr->im_brgc4 |= CPM_BRG_RST;
immr->im_brgc4 &= ~CPM_BRG_RST;
sclk_brg = (*IM_BRGC4 | CPM_BRG_RST) & ~CPM_BRG_EN;
# endif
# if (SCLK_BRG == 4)
immr->im_brgc5 |= CPM_BRG_RST;
immr->im_brgc5 &= ~CPM_BRG_RST;
sclk_brg = (*IM_BRGC5 | CPM_BRG_RST) & ~CPM_BRG_EN;
# endif
# if (SCLK_BRG == 5)
immr->im_brgc6 |= CPM_BRG_RST;
immr->im_brgc6 &= ~CPM_BRG_RST;
sclk_brg = (*IM_BRGC6 | CPM_BRG_RST) & ~CPM_BRG_EN;
# endif
# if (SCLK_BRG == 6)
immr->im_brgc7 |= CPM_BRG_RST;
immr->im_brgc7 &= ~CPM_BRG_RST;
sclk_brg = (*IM_BRGC7 | CPM_BRG_RST) & ~CPM_BRG_EN;
# endif
# if (SCLK_BRG == 7)
immr->im_brgc8 |= CPM_BRG_RST;
immr->im_brgc8 &= ~CPM_BRG_RST;
sclk_brg = (*IM_BRGC8 | CPM_BRG_RST) & ~CPM_BRG_EN;
# endif
/*
* Reset LRCLK BRG
/*
* Obtain LRCLK BRG reset/disabled value
*/
# if (LRCLK_BRG == 0)
immr->im_brgc1 |= CPM_BRG_RST;
immr->im_brgc1 &= ~CPM_BRG_RST;
lrclk_brg = (*IM_BRGC1 | CPM_BRG_RST) & ~CPM_BRG_EN;
# endif
# if (LRCLK_BRG == 1)
immr->im_brgc2 |= CPM_BRG_RST;
immr->im_brgc2 &= ~CPM_BRG_RST;
lrclk_brg = (*IM_BRGC2 | CPM_BRG_RST) & ~CPM_BRG_EN;
# endif
# if (LRCLK_BRG == 2)
immr->im_brgc3 |= CPM_BRG_RST;
immr->im_brgc3 &= ~CPM_BRG_RST;
lrclk_brg = (*IM_BRGC3 | CPM_BRG_RST) & ~CPM_BRG_EN;
# endif
# if (LRCLK_BRG == 3)
immr->im_brgc4 |= CPM_BRG_RST;
immr->im_brgc4 &= ~CPM_BRG_RST;
lrclk_brg = (*IM_BRGC4 | CPM_BRG_RST) & ~CPM_BRG_EN;
# endif
# if (LRCLK_BRG == 4)
immr->im_brgc5 |= CPM_BRG_RST;
immr->im_brgc5 &= ~CPM_BRG_RST;
lrclk_brg = (*IM_BRGC5 | CPM_BRG_RST) & ~CPM_BRG_EN;
# endif
# if (LRCLK_BRG == 5)
immr->im_brgc6 |= CPM_BRG_RST;
immr->im_brgc6 &= ~CPM_BRG_RST;
lrclk_brg = (*IM_BRGC6 | CPM_BRG_RST) & ~CPM_BRG_EN;
# endif
# if (LRCLK_BRG == 6)
immr->im_brgc7 |= CPM_BRG_RST;
immr->im_brgc7 &= ~CPM_BRG_RST;
lrclk_brg = (*IM_BRGC7 | CPM_BRG_RST) & ~CPM_BRG_EN;
# endif
# if (LRCLK_BRG == 7)
immr->im_brgc8 |= CPM_BRG_RST;
immr->im_brgc8 &= ~CPM_BRG_RST;
lrclk_brg = (*IM_BRGC8 | CPM_BRG_RST) & ~CPM_BRG_EN;
# endif
/*
* Disable interrupt and save the current state
*/
flag = disable_interrupts();
/*
* Set reset on MCLK BRG
*/
# if (MCLK_BRG == 0)
*IM_BRGC1 = mclk_brg;
# endif
# if (MCLK_BRG == 1)
*IM_BRGC2 = mclk_brg;
# endif
# if (MCLK_BRG == 2)
*IM_BRGC3 = mclk_brg;
# endif
# if (MCLK_BRG == 3)
*IM_BRGC4 = mclk_brg;
# endif
# if (MCLK_BRG == 4)
*IM_BRGC5 = mclk_brg;
# endif
# if (MCLK_BRG == 5)
*IM_BRGC6 = mclk_brg;
# endif
# if (MCLK_BRG == 6)
*IM_BRGC7 = mclk_brg;
# endif
# if (MCLK_BRG == 7)
*IM_BRGC8 = mclk_brg;
# endif
/*
* Set reset on SCLK BRG
*/
# if (SCLK_BRG == 0)
*IM_BRGC1 = sclk_brg;
# endif
# if (SCLK_BRG == 1)
*IM_BRGC2 = sclk_brg;
# endif
# if (SCLK_BRG == 2)
*IM_BRGC3 = sclk_brg;
# endif
# if (SCLK_BRG == 3)
*IM_BRGC4 = sclk_brg;
# endif
# if (SCLK_BRG == 4)
*IM_BRGC5 = sclk_brg;
# endif
# if (SCLK_BRG == 5)
*IM_BRGC6 = sclk_brg;
# endif
# if (SCLK_BRG == 6)
*IM_BRGC7 = sclk_brg;
# endif
# if (SCLK_BRG == 7)
*IM_BRGC8 = sclk_brg;
# endif
/*
* Set reset on LRCLK BRG
*/
# if (LRCLK_BRG == 0)
*IM_BRGC1 = lrclk_brg;
# endif
# if (LRCLK_BRG == 1)
*IM_BRGC2 = lrclk_brg;
# endif
# if (LRCLK_BRG == 2)
*IM_BRGC3 = lrclk_brg;
# endif
# if (LRCLK_BRG == 3)
*IM_BRGC4 = lrclk_brg;
# endif
# if (LRCLK_BRG == 4)
*IM_BRGC5 = lrclk_brg;
# endif
# if (LRCLK_BRG == 5)
*IM_BRGC6 = lrclk_brg;
# endif
# if (LRCLK_BRG == 6)
*IM_BRGC7 = lrclk_brg;
# endif
# if (LRCLK_BRG == 7)
*IM_BRGC8 = lrclk_brg;
# endif
/*
* Clear reset on MCLK BRG
*/
# if (MCLK_BRG == 0)
*IM_BRGC1 = mclk_brg & ~CPM_BRG_RST;
# endif
# if (MCLK_BRG == 1)
*IM_BRGC2 = mclk_brg & ~CPM_BRG_RST;
# endif
# if (MCLK_BRG == 2)
*IM_BRGC3 = mclk_brg & ~CPM_BRG_RST;
# endif
# if (MCLK_BRG == 3)
*IM_BRGC4 = mclk_brg & ~CPM_BRG_RST;
# endif
# if (MCLK_BRG == 4)
*IM_BRGC5 = mclk_brg & ~CPM_BRG_RST;
# endif
# if (MCLK_BRG == 5)
*IM_BRGC6 = mclk_brg & ~CPM_BRG_RST;
# endif
# if (MCLK_BRG == 6)
*IM_BRGC7 = mclk_brg & ~CPM_BRG_RST;
# endif
# if (MCLK_BRG == 7)
*IM_BRGC8 = mclk_brg & ~CPM_BRG_RST;
# endif
/*
* Clear reset on SCLK BRG
*/
# if (SCLK_BRG == 0)
*IM_BRGC1 = sclk_brg & ~CPM_BRG_RST;
# endif
# if (SCLK_BRG == 1)
*IM_BRGC2 = sclk_brg & ~CPM_BRG_RST;
# endif
# if (SCLK_BRG == 2)
*IM_BRGC3 = sclk_brg & ~CPM_BRG_RST;
# endif
# if (SCLK_BRG == 3)
*IM_BRGC4 = sclk_brg & ~CPM_BRG_RST;
# endif
# if (SCLK_BRG == 4)
*IM_BRGC5 = sclk_brg & ~CPM_BRG_RST;
# endif
# if (SCLK_BRG == 5)
*IM_BRGC6 = sclk_brg & ~CPM_BRG_RST;
# endif
# if (SCLK_BRG == 6)
*IM_BRGC7 = sclk_brg & ~CPM_BRG_RST;
# endif
# if (SCLK_BRG == 7)
*IM_BRGC8 = sclk_brg & ~CPM_BRG_RST;
# endif
/*
* Clear reset on LRCLK BRG
*/
# if (LRCLK_BRG == 0)
*IM_BRGC1 = lrclk_brg & ~CPM_BRG_RST;
# endif
# if (LRCLK_BRG == 1)
*IM_BRGC2 = lrclk_brg & ~CPM_BRG_RST;
# endif
# if (LRCLK_BRG == 2)
*IM_BRGC3 = lrclk_brg & ~CPM_BRG_RST;
# endif
# if (LRCLK_BRG == 3)
*IM_BRGC4 = lrclk_brg & ~CPM_BRG_RST;
# endif
# if (LRCLK_BRG == 4)
*IM_BRGC5 = lrclk_brg & ~CPM_BRG_RST;
# endif
# if (LRCLK_BRG == 5)
*IM_BRGC6 = lrclk_brg & ~CPM_BRG_RST;
# endif
# if (LRCLK_BRG == 6)
*IM_BRGC7 = lrclk_brg & ~CPM_BRG_RST;
# endif
# if (LRCLK_BRG == 7)
*IM_BRGC8 = lrclk_brg & ~CPM_BRG_RST;
# endif
/*
* Restore the Interrupt state
*/
if (flag) {
enable_interrupts();
}
# else
/*
* Reset the clocks
@ -536,99 +665,99 @@ void Daq_Start_Clocks(int sample_rate)
#ifdef TIGHTEN_UP_BRG_TIMING
volatile immap_t *immr = (immap_t *)CFG_IMMR;
uint mclk_brg; /* MCLK BRG value */
uint sclk_brg; /* SCLK BRG value */
register uint mclk_brg; /* MCLK BRG value */
register uint sclk_brg; /* SCLK BRG value */
register uint temp_lrclk_brg; /* Temporary LRCLK BRG value */
register uint real_lrclk_brg; /* Permanent LRCLK BRG value */
uint lrclk_brg; /* LRCLK BRG value */
uint temp_lrclk_brg; /* Temporary LRCLK BRG value */
uint real_lrclk_brg; /* Permanent LRCLK BRG value */
unsigned long flags; /* Interrupt flags */
uint sclk_cnt; /* SCLK count */
uint delay_cnt; /* Delay count */
#endif
# ifdef TIGHTEN_UP_BRG_TIMING
/*
/*
* Obtain the enabled MCLK BRG value
*/
# if (MCLK_BRG == 0)
mclk_brg = (immr->im_brgc1 & ~CPM_BRG_RST) | CPM_BRG_EN;
mclk_brg = (*IM_BRGC1 & ~CPM_BRG_RST) | CPM_BRG_EN;
# endif
# if (MCLK_BRG == 1)
mclk_brg = (immr->im_brgc2 & ~CPM_BRG_RST) | CPM_BRG_EN;
mclk_brg = (*IM_BRGC2 & ~CPM_BRG_RST) | CPM_BRG_EN;
# endif
# if (MCLK_BRG == 2)
mclk_brg = (immr->im_brgc3 & ~CPM_BRG_RST) | CPM_BRG_EN;
mclk_brg = (*IM_BRGC3 & ~CPM_BRG_RST) | CPM_BRG_EN;
# endif
# if (MCLK_BRG == 3)
mclk_brg = (immr->im_brgc4 & ~CPM_BRG_RST) | CPM_BRG_EN;
mclk_brg = (*IM_BRGC4 & ~CPM_BRG_RST) | CPM_BRG_EN;
# endif
# if (MCLK_BRG == 4)
mclk_brg = (immr->im_brgc5 & ~CPM_BRG_RST) | CPM_BRG_EN;
mclk_brg = (*IM_BRGC5 & ~CPM_BRG_RST) | CPM_BRG_EN;
# endif
# if (MCLK_BRG == 5)
mclk_brg = (immr->im_brgc6 & ~CPM_BRG_RST) | CPM_BRG_EN;
mclk_brg = (*IM_BRGC6 & ~CPM_BRG_RST) | CPM_BRG_EN;
# endif
# if (MCLK_BRG == 6)
mclk_brg = (immr->im_brgc7 & ~CPM_BRG_RST) | CPM_BRG_EN;
mclk_brg = (*IM_BRGC7 & ~CPM_BRG_RST) | CPM_BRG_EN;
# endif
# if (MCLK_BRG == 7)
mclk_brg = (immr->im_brgc8 & ~CPM_BRG_RST) | CPM_BRG_EN;
mclk_brg = (*IM_BRGC8 & ~CPM_BRG_RST) | CPM_BRG_EN;
# endif
/*
/*
* Obtain the enabled SCLK BRG value
*/
# if (SCLK_BRG == 0)
sclk_brg = (immr->im_brgc1 & ~CPM_BRG_RST) | CPM_BRG_EN;
sclk_brg = (*IM_BRGC1 & ~CPM_BRG_RST) | CPM_BRG_EN;
# endif
# if (SCLK_BRG == 1)
sclk_brg = (immr->im_brgc2 & ~CPM_BRG_RST) | CPM_BRG_EN;
sclk_brg = (*IM_BRGC2 & ~CPM_BRG_RST) | CPM_BRG_EN;
# endif
# if (SCLK_BRG == 2)
sclk_brg = (immr->im_brgc3 & ~CPM_BRG_RST) | CPM_BRG_EN;
sclk_brg = (*IM_BRGC3 & ~CPM_BRG_RST) | CPM_BRG_EN;
# endif
# if (SCLK_BRG == 3)
sclk_brg = (immr->im_brgc4 & ~CPM_BRG_RST) | CPM_BRG_EN;
sclk_brg = (*IM_BRGC4 & ~CPM_BRG_RST) | CPM_BRG_EN;
# endif
# if (SCLK_BRG == 4)
sclk_brg = (immr->im_brgc5 & ~CPM_BRG_RST) | CPM_BRG_EN;
sclk_brg = (*IM_BRGC5 & ~CPM_BRG_RST) | CPM_BRG_EN;
# endif
# if (SCLK_BRG == 5)
sclk_brg = (immr->im_brgc6 & ~CPM_BRG_RST) | CPM_BRG_EN;
sclk_brg = (*IM_BRGC6 & ~CPM_BRG_RST) | CPM_BRG_EN;
# endif
# if (SCLK_BRG == 6)
sclk_brg = (immr->im_brgc7 & ~CPM_BRG_RST) | CPM_BRG_EN;
sclk_brg = (*IM_BRGC7 & ~CPM_BRG_RST) | CPM_BRG_EN;
# endif
# if (SCLK_BRG == 7)
sclk_brg = (immr->im_brgc8 & ~CPM_BRG_RST) | CPM_BRG_EN;
sclk_brg = (*IM_BRGC8 & ~CPM_BRG_RST) | CPM_BRG_EN;
# endif
/*
/*
* Obtain the enabled LRCLK BRG value
*/
# if (LRCLK_BRG == 0)
lrclk_brg = (immr->im_brgc1 & ~CPM_BRG_RST) | CPM_BRG_EN;
lrclk_brg = (*IM_BRGC1 & ~CPM_BRG_RST) | CPM_BRG_EN;
# endif
# if (LRCLK_BRG == 1)
lrclk_brg = (immr->im_brgc2 & ~CPM_BRG_RST) | CPM_BRG_EN;
lrclk_brg = (*IM_BRGC2 & ~CPM_BRG_RST) | CPM_BRG_EN;
# endif
# if (LRCLK_BRG == 2)
lrclk_brg = (immr->im_brgc3 & ~CPM_BRG_RST) | CPM_BRG_EN;
lrclk_brg = (*IM_BRGC3 & ~CPM_BRG_RST) | CPM_BRG_EN;
# endif
# if (LRCLK_BRG == 3)
lrclk_brg = (immr->im_brgc4 & ~CPM_BRG_RST) | CPM_BRG_EN;
lrclk_brg = (*IM_BRGC4 & ~CPM_BRG_RST) | CPM_BRG_EN;
# endif
# if (LRCLK_BRG == 4)
lrclk_brg = (immr->im_brgc5 & ~CPM_BRG_RST) | CPM_BRG_EN;
lrclk_brg = (*IM_BRGC5 & ~CPM_BRG_RST) | CPM_BRG_EN;
# endif
# if (LRCLK_BRG == 5)
lrclk_brg = (immr->im_brgc6 & ~CPM_BRG_RST) | CPM_BRG_EN;
lrclk_brg = (*IM_BRGC6 & ~CPM_BRG_RST) | CPM_BRG_EN;
# endif
# if (LRCLK_BRG == 6)
lrclk_brg = (immr->im_brgc7 & ~CPM_BRG_RST) | CPM_BRG_EN;
lrclk_brg = (*IM_BRGC7 & ~CPM_BRG_RST) | CPM_BRG_EN;
# endif
# if (LRCLK_BRG == 7)
lrclk_brg = (immr->im_brgc8 & ~CPM_BRG_RST) | CPM_BRG_EN;
lrclk_brg = (*IM_BRGC8 & ~CPM_BRG_RST) | CPM_BRG_EN;
# endif
/* Save off the real LRCLK value */
@ -639,7 +768,7 @@ void Daq_Start_Clocks(int sample_rate)
/* Compute the delay as a function of SCLK count */
delay_cnt = ((sclk_cnt / 4) - 2) * 10 + 6;
if (sample_rate == 43402) {
if (DaqSampleRate == 43402) {
delay_cnt++;
}
@ -649,117 +778,129 @@ void Daq_Start_Clocks(int sample_rate)
/* Insert the count */
temp_lrclk_brg |= ((delay_cnt + (sclk_cnt / 2) - 1) << 1) & 0x00001FFE;
/*
/*
* Disable interrupt and save the current state
*/
flag = disable_interrupts();
/*
* Enable MCLK BRG
*/
# if (MCLK_BRG == 0)
immr->im_brgc1 = mclk_brg;
*IM_BRGC1 = mclk_brg;
# endif
# if (MCLK_BRG == 1)
immr->im_brgc2 = mclk_brg;
*IM_BRGC2 = mclk_brg;
# endif
# if (MCLK_BRG == 2)
immr->im_brgc3 = mclk_brg;
*IM_BRGC3 = mclk_brg;
# endif
# if (MCLK_BRG == 3)
immr->im_brgc4 = mclk_brg;
*IM_BRGC4 = mclk_brg;
# endif
# if (MCLK_BRG == 4)
immr->im_brgc5 = mclk_brg;
*IM_BRGC5 = mclk_brg;
# endif
# if (MCLK_BRG == 5)
immr->im_brgc6 = mclk_brg;
*IM_BRGC6 = mclk_brg;
# endif
# if (MCLK_BRG == 6)
immr->im_brgc7 = mclk_brg;
*IM_BRGC7 = mclk_brg;
# endif
# if (MCLK_BRG == 7)
immr->im_brgc8 = mclk_brg;
*IM_BRGC8 = mclk_brg;
# endif
/*
/*
* Enable SCLK BRG
*/
# if (SCLK_BRG == 0)
immr->im_brgc1 = sclk_brg;
*IM_BRGC1 = sclk_brg;
# endif
# if (SCLK_BRG == 1)
immr->im_brgc2 = sclk_brg;
*IM_BRGC2 = sclk_brg;
# endif
# if (SCLK_BRG == 2)
immr->im_brgc3 = sclk_brg;
*IM_BRGC3 = sclk_brg;
# endif
# if (SCLK_BRG == 3)
immr->im_brgc4 = sclk_brg;
*IM_BRGC4 = sclk_brg;
# endif
# if (SCLK_BRG == 4)
immr->im_brgc5 = sclk_brg;
*IM_BRGC5 = sclk_brg;
# endif
# if (SCLK_BRG == 5)
immr->im_brgc6 = sclk_brg;
*IM_BRGC6 = sclk_brg;
# endif
# if (SCLK_BRG == 6)
immr->im_brgc7 = sclk_brg;
*IM_BRGC7 = sclk_brg;
# endif
# if (SCLK_BRG == 7)
immr->im_brgc8 = sclk_brg;
*IM_BRGC8 = sclk_brg;
# endif
/*
/*
* Enable LRCLK BRG (1st time - temporary)
*/
# if (LRCLK_BRG == 0)
immr->im_brgc1 = temp_lrclk_brg;
*IM_BRGC1 = temp_lrclk_brg;
# endif
# if (LRCLK_BRG == 1)
immr->im_brgc2 = temp_lrclk_brg;
*IM_BRGC2 = temp_lrclk_brg;
# endif
# if (LRCLK_BRG == 2)
immr->im_brgc3 = temp_lrclk_brg;
*IM_BRGC3 = temp_lrclk_brg;
# endif
# if (LRCLK_BRG == 3)
immr->im_brgc4 = temp_lrclk_brg;
*IM_BRGC4 = temp_lrclk_brg;
# endif
# if (LRCLK_BRG == 4)
immr->im_brgc5 = temp_lrclk_brg;
*IM_BRGC5 = temp_lrclk_brg;
# endif
# if (LRCLK_BRG == 5)
immr->im_brgc6 = temp_lrclk_brg;
*IM_BRGC6 = temp_lrclk_brg;
# endif
# if (LRCLK_BRG == 6)
immr->im_brgc7 = temp_lrclk_brg;
*IM_BRGC7 = temp_lrclk_brg;
# endif
# if (LRCLK_BRG == 7)
immr->im_brgc8 = temp_lrclk_brg;
*IM_BRGC8 = temp_lrclk_brg;
# endif
/*
/*
* Enable LRCLK BRG (2nd time - permanent)
*/
# if (LRCLK_BRG == 0)
immr->im_brgc1 = real_lrclk_brg;
*IM_BRGC1 = real_lrclk_brg;
# endif
# if (LRCLK_BRG == 1)
immr->im_brgc2 = real_lrclk_brg;
*IM_BRGC2 = real_lrclk_brg;
# endif
# if (LRCLK_BRG == 2)
immr->im_brgc3 = real_lrclk_brg;
*IM_BRGC3 = real_lrclk_brg;
# endif
# if (LRCLK_BRG == 3)
immr->im_brgc4 = real_lrclk_brg;
*IM_BRGC4 = real_lrclk_brg;
# endif
# if (LRCLK_BRG == 4)
immr->im_brgc5 = real_lrclk_brg;
*IM_BRGC5 = real_lrclk_brg;
# endif
# if (LRCLK_BRG == 5)
immr->im_brgc6 = real_lrclk_brg;
*IM_BRGC6 = real_lrclk_brg;
# endif
# if (LRCLK_BRG == 6)
immr->im_brgc7 = real_lrclk_brg;
*IM_BRGC7 = real_lrclk_brg;
# endif
# if (LRCLK_BRG == 7)
immr->im_brgc8 = real_lrclk_brg;
*IM_BRGC8 = real_lrclk_brg;
# endif
/*
* Restore the Interrupt state
*/
if (flag) {
enable_interrupts();
}
# else
/*
* Enable the clocks

13
board/sacsng/clkinit.h
View File

@ -61,6 +61,9 @@
/* The 8260 (Mask B.3) seems to have */
/* problems generating LRCLK from SCLK */
#define NUM_LRCLKS_TO_STABILIZE 1 /* Number of LRCLK period (sample) */
/* to wait for the clock to stabilize */
#define CPM_CLK (gd->bd->bi_cpmfreq)
#define DFBRG 4
#define BRG_INT_CLK (CPM_CLK * 2 / DFBRG)
@ -80,6 +83,15 @@
#define CPM_BRG_EXTC_CLK5 2
#define CPM_BRG_EXTC_CLK15 CPM_BRG_EXTC_CLK5
#define IM_BRGC1 ((uint *)0xf00119f0)
#define IM_BRGC2 ((uint *)0xf00119f4)
#define IM_BRGC3 ((uint *)0xf00119f8)
#define IM_BRGC4 ((uint *)0xf00119fc)
#define IM_BRGC5 ((uint *)0xf00115f0)
#define IM_BRGC6 ((uint *)0xf00115f4)
#define IM_BRGC7 ((uint *)0xf00115f8)
#define IM_BRGC8 ((uint *)0xf00115fc)
/*
* External declarations
*/
@ -105,7 +117,6 @@ extern void Daq_BRG_Set_ExtClk(uint brg, uint extc);
extern uint Daq_BRG_Rate(uint brg);
extern uint Daq_Get_SampleRate(void);
extern uint Daq_Set_SampleRate(uint rate, uint force);
extern void Daq_Init_Clocks(int sample_rate, int sample_64x);
extern void Daq_Stop_Clocks(void);

21
board/sacsng/sacsng.c
View File

@ -26,7 +26,6 @@
#include <common.h>
#include <ioports.h>
#include <mpc8260.h>
/*NO// #include <memtest.h> */
#include <i2c.h>
#include <spi.h>
@ -486,9 +485,25 @@ int misc_init_r(void)
}
}
/*
* Stop the clocks and wait for at least 1 LRCLK period
* to make sure the clocking has really stopped.
*/
Daq_Stop_Clocks();
udelay((1000000 / sample_rate) * NUM_LRCLKS_TO_STABILIZE);
/*
* Initialize the clocks with the new rates
*/
Daq_Init_Clocks(sample_rate, sample_64x);
sample_rate = Daq_Get_SampleRate();
/*
* Start the clocks and wait for at least 1 LRCLK period
* to make sure the clocking has become stable.
*/
Daq_Start_Clocks(sample_rate);
udelay((1000000 / sample_rate) * NUM_LRCLKS_TO_STABILIZE);
sprintf(str_buf, "%d", sample_rate);
setenv("DaqSampleRate", str_buf);
@ -792,10 +807,12 @@ void spi_dac_chipsel(int cs)
* chip selects: it calls the appropriate function to control the SPI
* chip selects.
*/
spi_chipsel_type spi_chipsel[2] = {
spi_chipsel_type spi_chipsel[] = {
spi_adc_chipsel,
spi_dac_chipsel
};
int spi_chipsel_cnt = sizeof(spi_chipsel) / sizeof(spi_chipsel[0]);
#endif /* CFG_CMD_SPI */
#endif /* CONFIG_MISC_INIT_R */

2
common/cmd_elf.c
View File

@ -111,7 +111,7 @@ int do_bootvx ( cmd_tbl_t *cmdtp, int flag, int argc, char *argv[])
/* Check to see if we need to tftp the image ourselves before starting */
if ((argc == 2) && (strcmp (argv[1], "tftp") == 0)) {
if (NetLoop (TFTP) == 0)
if (NetLoop (TFTP) <= 0)
return 1;
printf ("Automatic boot of VxWorks image at address 0x%08lx ... \n", addr);
}

6
common/cmd_net.c
View File

@ -132,12 +132,16 @@ netboot_common (int proto, cmd_tbl_t *cmdtp, int argc, char *argv[])
return 1;
}
if ((size = NetLoop(proto)) == 0)
if ((size = NetLoop(proto)) < 0)
return 1;
/* NetLoop ok, update environment */
netboot_update_env();
/* done if no file was loaded (no errors though) */
if (size == 0)
return 0;
/* flush cache */
flush_cache(load_addr, size);

57
common/cmd_spi.c
View File

@ -32,14 +32,20 @@
#if (CONFIG_COMMANDS & CFG_CMD_SPI)
#define MAX_SPI_BYTES 32 /* max number of bytes we can handle */
/*-----------------------------------------------------------------------
* Definitions
*/
#ifndef MAX_SPI_BYTES
# define MAX_SPI_BYTES 32 /* Maximum number of bytes we can handle */
#endif
/*
* External table of chip select functions (see the appropriate board
* support for the actual definition of the table).
*/
extern spi_chipsel_type spi_chipsel[];
extern int spi_chipsel_cnt;
/*
* Values from last command.
@ -60,7 +66,7 @@ static uchar din[MAX_SPI_BYTES];
* The command prints out the hexadecimal string received via SPI.
*/
int do_spi (cmd_tbl_t *cmdtp, bd_t *bd, int flag, int argc, char *argv[])
int do_spi (cmd_tbl_t *cmdtp, int flag, int argc, char *argv[])
{
char *cp = 0;
uchar tmp;
@ -78,26 +84,38 @@ int do_spi (cmd_tbl_t *cmdtp, bd_t *bd, int flag, int argc, char *argv[])
device = simple_strtoul(argv[1], NULL, 10);
if (argc >= 3)
bitlen = simple_strtoul(argv[2], NULL, 10);
if (argc >= 4)
cp = argv[3];
for(j = 0; *cp; j++, cp++) {
tmp = *cp - '0';
if(tmp > 9)
tmp -= ('A' - '0') - 10;
if(tmp > 15)
tmp -= ('a' - 'A');
if(tmp > 15) {
printf("Conversion error on %c, bailing out.\n", *cp);
break;
if (argc >= 4) {
cp = argv[3];
for(j = 0; *cp; j++, cp++) {
tmp = *cp - '0';
if(tmp > 9)
tmp -= ('A' - '0') - 10;
if(tmp > 15)
tmp -= ('a' - 'A');
if(tmp > 15) {
printf("Hex conversion error on %c, giving up.\n", *cp);
return 1;
}
if((j % 2) == 0)
dout[j / 2] = (tmp << 4);
else
dout[j / 2] |= tmp;
}
if((j % 2) == 0)
dout[j / 2] = (tmp << 4);
else
dout[j / 2] |= tmp;
}
}
printf("spi_chipsel[%d] = %08X\n", device, (uint)spi_chipsel[device]);
if ((device < 0) || (device >= spi_chipsel_cnt)) {
printf("Invalid device %d, giving up.\n", device);
return 1;
}
if ((bitlen < 0) || (bitlen > (MAX_SPI_BYTES * 8))) {
printf("Invalid bitlen %d, giving up.\n", bitlen);
return 1;
}
debug ("spi_chipsel[%d] = %08X\n",
device, (uint)spi_chipsel[device]);
if(spi_xfer(spi_chipsel[device], bitlen, dout, din) != 0) {
printf("Error with the SPI transaction.\n");
rcode = 1;
@ -113,4 +131,3 @@ printf("spi_chipsel[%d] = %08X\n", device, (uint)spi_chipsel[device]);
}
#endif /* CFG_CMD_SPI */

2
common/command.c
View File

@ -46,6 +46,7 @@
#include <cmd_eeprom.h>
#include <cmd_i2c.h>
#include <cmd_spi.h>
#include <cmd_immap.h>
#include <cmd_rtc.h>
@ -316,6 +317,7 @@ cmd_tbl_t cmd_tbl[] = {
CMD_TBL_MISC /* sleep */
CMD_TBL_SMCINFO
CMD_TBL_SPIINFO
CMD_TBL_SPI
CMD_TBL_STACK
CMD_TBL_STEP
CMD_TBL_TFTPB

3
common/soft_spi.c
View File

@ -29,9 +29,6 @@
#if defined(CONFIG_SOFT_SPI)
#define DEBUG_SPI
/*-----------------------------------------------------------------------
* Definitions
*/