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openocd/tcl/board/at91sam9g20-ek.cfg
David Brownell 3e6f9e8d1e target.cfg: remove "-work-area-virt 0" 
The semantics of "-work-area-virt 0" (or phys) changed with
the patch to require specifying physical or virtrual work
area addresses.  Specifying zero was previously a NOP.  Now
it means that address zero is valid.

This patch addresses three related issues:

 - MMU-less processors should never specify work-area-virt;
   remove those specifications.  Such processors include
   ARM7TDMI, Cortex-M3, and ARM966.

 - MMU-equipped processors *can* specify work-area-virt...
   but zero won't be appropriate, except in mischievous
   contexts (which hide null pointer exceptions).

   Remove those specs from those processors too.  If any of
   those mappings is valid, someone will need to submit a
   patch adding it ... along with a comment saying what OS
   provides the mapping, and in which context.  Example,
   say "works with Linux 2.6.30+, in kernel mode".  (Note
   that ARM Linux doesn't map kernel memory to zero ...)

 - Clarify docs on that "-virt" and other work area stuff.

Seems to me work-area-virt is quite problematic; not every
operating system provides such static mappings; if they do,
they're not in every MMU context...

Signed-off-by: David Brownell <dbrownell@users.sourceforge.net>
2009-11-08 08:52:40 -08:00

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#################################################################################################
# #
# Author: Gary Carlson (gcarlson@carlson-minot.com) #
# Generated for Atmel AT91SAM9G20-EK evaluation board using Atmel SAM-ICE (J-Link) version 8. #
# #
#################################################################################################
# Define basic characteristics for the CPU. The AT91SAM9G20 processor is a subtle variant of
# the AT91SAM9260 and shares the same tap ID as it.
set _CHIPNAME at91sam9g20
set _ENDIAN little
set _CPUTAPID 0x0792603f
# Set reset type. Note that the AT91SAM9G20-EK board has the trst signal disconnected. In theory this script
# therefore should require "srst_only". With some J-Link debuggers at least, "srst_only" causes a temporary USB
# communication fault. This appears to be more likely attributed to an internal proprietary firmware quirk inside the
# dongle itself. Using "trst_and_srst" works fine, however. So if you can't beat them -- join them. If you are using
# something other the a J-Link dongle you may be able to change this back to "srst_only".
reset_config trst_and_srst
# Set up the CPU and generate a new jtag tap for AT91SAM9G20.
jtag newtap $_CHIPNAME cpu -irlen 4 -ircapture 0x1 -irmask 0xf -expected-id $_CPUTAPID
# Use caution changing the delays listed below. These seem to be affected by the board and type of
# debugger dongle. A value of 200 ms seems to work reliably for the configuration listed in the file header above.
jtag_nsrst_delay 200
jtag_ntrst_delay 200
# Set fallback clock to 1/6 of worst-case clock speed (which would be the 32.768 kHz slow clock).
jtag_rclk 5
set _TARGETNAME [format "%s.cpu" $_CHIPNAME]
target create $_TARGETNAME arm926ejs -endian $_ENDIAN -chain-position $_TARGETNAME -variant arm926ejs
# Establish internal SRAM memory work areas that are important to pre-bootstrap loaders, etc. The
# AT91SAM9G20 has two SRAM areas, one starting at 0x00200000 and the other starting at 0x00300000.
# Both areas are 16 kB long.
#$_TARGETNAME configure -work-area-phys 0x00200000 -work-area-size 0x4000 -work-area-backup 1
$_TARGETNAME configure -work-area-phys 0x00300000 -work-area-size 0x4000 -work-area-backup 1
# If you don't want to execute built-in boot rom code (and there are good reasons at times not to do that) in the
# AT91SAM9 family, the microcontroller is a lump on a log without initialization. Because this family has
# some powerful features, we want to have a special function that handles "reset init". To do this we declare
# an event handler where these special activities can take place.
scan_chain
$_TARGETNAME configure -event reset-init {at91sam9g20_init}
# NandFlash configuration and definition
# Future TBD
proc read_register {register} {
set result ""
ocd_mem2array result 32 $register 1
return $result(0)
}
proc at91sam9g20_init { } {
# At reset AT91SAM9G20 chip runs on slow clock (32.768 kHz). To shift over to a normal clock requires
# a number of steps that must be carefully performed. The process outline below follows the
# recommended procedure outlined in the AT91SAM9G20 technical manual.
#
# Several key and very important things to keep in mind:
# The SDRAM parts used currently on the Atmel evaluation board are -75 grade parts. This
# means the master clock (MCLK) must be at or below 133 MHz or timing errors will occur. The processor
# core can operate up to 400 MHz and therefore PCLK must be at or below this to function properly.
jtag_khz 2 # Slow-speed oscillator enabled at reset, so run jtag speed slow.
halt # Make sure processor is halted, or error will result in following steps.
mww 0xfffffd08 0xa5000501 # RSTC_MR : enable user reset.
mww 0xfffffd44 0x00008000 # WDT_MR : disable watchdog.
# Enable the main 18.432 MHz oscillator in CKGR_MOR register.
# Wait for MOSCS in PMC_SR to assert indicating oscillator is again stable after change to CKGR_MOR.
mww 0xfffffc20 0x00004001
while { [expr [read_register 0xfffffc68] & 0x01] != 1 } { sleep 1 }
# Set PLLA Register for 792.576 MHz (divider: bypass, multiplier: 43).
# Wait for LOCKA signal in PMC_SR to assert indicating PLLA is stable.
mww 0xfffffc28 0x202a3f01
while { [expr [read_register 0xfffffc68] & 0x02] != 2 } { sleep 1 }
# Set master system clock prescaler divide by 6 and processor clock divide by 2 in PMC_MCKR.
# Wait for MCKRDY signal from PMC_SR to assert.
mww 0xfffffc30 0x00000101
while { [expr [read_register 0xfffffc68] & 0x08] != 8 } { sleep 1 }
# Now change PMC_MCKR register to select PLLA.
# Wait for MCKRDY signal from PMC_SR to assert.
mww 0xfffffc30 0x00001302
while { [expr [read_register 0xfffffc68] & 0x08] != 8 } { sleep 1 }
# Processor and master clocks are now operating and stable at maximum frequency possible:
# -> MCLK = 132.096 MHz
# -> PCLK = 396.288 MHz
# Switch over to adaptive clocking.
jtag_khz 0
# Enable faster DCC downloads.
arm7_9 dcc_downloads enable
# To be able to use external SDRAM, several peripheral configuration registers must
# be modified. The first change is made to PIO_ASR to select peripheral functions
# for D15 through D31. The second change is made to the PIO_PDR register to disable
# this for D15 through D31.
mww 0xfffff870 0xffff0000
mww 0xfffff804 0xffff0000
# The EBI chip select register EBI_CS must be specifically configured to enable the internal SDRAM controller
# using CS1. Additionally we want CS3 assigned to NandFlash. Also VDDIO is connected physically on
# the board to the 3.3 VDC power supply so set the appropriate register bit to notify the micrcontroller.
mww 0xffffef1c 0x000100a
# The AT91SAM9G20-EK evaluation board has built-in NandFlash. The exact physical timing characteristics
# for the memory type used on the current board (MT29F2G08AACWP) can be established by setting
# four registers in order: SMC_SETUP3, SMC_PULSE3, SMC_CYCLE3, and SMC_MODE3.
mww 0xffffec30 0x00020002
mww 0xffffec34 0x04040404
mww 0xffffec38 0x00070007
mww 0xffffec3c 0x00030003
# Identify NandFlash bank 0. Disabled at the moment because a memory driver is not yet complete.
# nand probe 0
# Now setup SDRAM. This is tricky and configuration is very important for reliability! The current calculations
# are based on 2 x Micron MT48LC16M16A2-75 memory (4 M x 16 bit x 4 banks). If you use this file as a reference
# for a new board that uses different SDRAM devices or clock rates, you need to recalculate the value inserted
# into the SDRAM_CR register. Using the memory datasheet for the -75 grade part and assuming a master clock
# of 132.096 MHz then the SDCLK period is equal to 7.6 ns. This means the device requires:
#
# CAS latency = 3 cycles
# TXSR = 10 cycles
# TRAS = 6 cycles
# TRCD = 3 cycles
# TRP = 3 cycles
# TRC = 9 cycles
# TWR = 2 cycles
# 9 column, 13 row, 4 banks
# refresh equal to or less then 7.8 us for commerical/industrial rated devices
#
# Thus SDRAM_CR = 0xa6339279
mww 0xffffea08 0xa6339279
# Next issue a 'NOP' command through the SDRAMC_MR register followed by writing a zero value into
# the starting memory location for the SDRAM.
mww 0xffffea00 0x00000001
mww 0x20000000 0
# Issue an 'All Banks Precharge' command through the SDRAMC_MR register followed by writing a zero
# value into the starting memory location for the SDRAM.
mww 0xffffea00 0x00000002
mww 0x20000000 0
# Now issue an 'Auto-Refresh' command through the SDRAMC_MR register. Follow this operation by writing
# zero values eight times into the starting memory location for the SDRAM.
mww 0xffffea00 0x4
mww 0x20000000 0
mww 0x20000000 0
mww 0x20000000 0
mww 0x20000000 0
mww 0x20000000 0
mww 0x20000000 0
mww 0x20000000 0
mww 0x20000000 0
# Almost done, so next issue a 'Load Mode Register' command followed by a zero value write to the
# the starting memory location for the SDRAM.
mww 0xffffea00 0x3
mww 0x20000000 0
# Signal normal mode using the SDRAMC_MR register and follow with a zero value write the the starting
# memory location for the SDRAM.
mww 0xffffea00 0x0
mww 0x20000000 0
# Finally set the refresh rate to about every 7 us (7.5 ns x 924 cycles).
mww 0xffffea04 0x0000039c
}
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