X-Git-Url: https://review.openocd.org/gitweb?p=openocd.git;a=blobdiff_plain;f=tcl%2Fboard%2Fat91sam9g20-ek.cfg;h=741d6018dc467e6feecf91cd1b711187e818dc15;hp=f24f1a13d895186f329233dbf376f8bf80f9d4aa;hb=05c6c871e3328dd38dc46ea11b3b9b546feb7850;hpb=96f9790279f74f39b35fc3ad09340fd03123180c

diff --git a/tcl/board/at91sam9g20-ek.cfg b/tcl/board/at91sam9g20-ek.cfg
index f24f1a13d8..741d6018dc 100644
--- a/tcl/board/at91sam9g20-ek.cfg
+++ b/tcl/board/at91sam9g20-ek.cfg
@@ -9,64 +9,58 @@
 #
 #	source [find target/...cfg]
 
-# Define basic characteristics for the CPU.  The AT91SAM9G20 processor is a subtle variant of
-# the AT91SAM9260 and shares the same tap ID as it.
+source [find target/at91sam9g20.cfg]
 
-set _CHIPNAME at91sam9g20
-set _ENDIAN little
-set _CPUTAPID 0x0792603f
+set _FLASHTYPE nandflash_cs3
 
-# 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".
+# Set reset type.  Note that the AT91SAM9G20-EK board has the trst signal disconnected.  Therefore
+# the reset needs to be configured for "srst_only".  If for some reason, a zero-ohm jumper is
+# added to the board to connect the trst signal, then this parameter may need to be changed.
 
-reset_config trst_and_srst
+reset_config srst_only
 
-# 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 JTAG adapter.  A value of 200 ms seems
-# to work reliably for the configuration listed in the file header above.
-
-jtag_nsrst_delay 200
+adapter_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 $_CHIPNAME.cpu
-target create $_TARGETNAME arm926ejs -endian $_ENDIAN -chain-position $_TARGETNAME
-
-# Establish internal SRAM memory work areas that are important to pre-bootstrap loaders, etc.  The
-# AT91SAM9G20 has two SRAM areas, one starting at 0x00200000 and the other starting at 0x00300000.
-# Both areas are 16 kB long.
-
-#$_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
-$_TARGETNAME configure -event reset-init {at91sam9g20_init}
+$_TARGETNAME configure -event reset-init {at91sam9g20_reset_init}
+$_TARGETNAME configure -event reset-start {at91sam9g20_reset_start}
 
 # NandFlash configuration and definition
-# Future TBD
+
+nand device nandflash_cs3 at91sam9 $_TARGETNAME 0x40000000 0xfffffe800
+at91sam9 cle 0 22
+at91sam9 ale 0 21
+at91sam9 rdy_busy 0 0xfffff800 13
+at91sam9 ce 0 0xfffff800 14
 
 proc read_register {register} {
         set result ""
-        ocd_mem2array result 32 $register 1
+        mem2array result 32 $register 1
         return $result(0)
 }
 
-proc at91sam9g20_init { } {
+proc at91sam9g20_reset_start { } {
+
+	# Make sure that the the jtag is running slow, since there are a number of different ways the board
+	# can be configured coming into this state that can cause communication problems with the jtag
+	# adapter.  Also since this call can be made following a "reset init" where fast memory accesses
+	# are enabled, need to temporarily shut this down so that the RSTC_MR register can be written at slower
+	# jtag speed without causing GDB keep alive problem.
+
+	arm7_9 fast_memory_access disable
+	adapter_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.
+	wait_halt 10000
+	mww 0xfffffd08 0xa5000501       ;# RSTC_MR : enable user reset.
+}
+
+proc at91sam9g20_reset_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
@@ -77,10 +71,7 @@ proc at91sam9g20_init { } {
 	# 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.
 
-	adapter_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.
+	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.
@@ -114,9 +105,10 @@ proc at91sam9g20_init { } {
 
 	adapter_khz 0
 
-	# Enable faster DCC downloads.
+	# Enable faster DCC downloads and memory accesses.
 
 	arm7_9 dcc_downloads enable
+	arm7_9 fast_memory_access 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
@@ -134,16 +126,34 @@ proc at91sam9g20_init { } {
 
 	# 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
+	# a number of registers.  The first step involves setting up the general I/O pins on the processor
+	# to be able to interface and support the external memory.
+
+	mww 0xfffffc10 0x00000010	;# PMC_PCER : enable PIOC clock
+	mww 0xfffff800 0x00006000	;# PIOC_PER : enable PIO function for 13(RDY/~BSY) and 14(~CS)
+	mww 0xfffff810 0x00004000	;# PIOC_OER : enable output on 14
+	mww 0xfffff814 0x00002000	;# PIOC_ODR : disable output on 13
+    	mww 0xfffff830 0x00004000	;# PIOC_SODR : set 14 to disable NAND
+
+	# 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.  Computing the exact values of these registers
+	# is a little tedious to do here.  If you have questions about how to do this, Atmel has
+	# a decent application note #6255B that covers this process. 
+
+	mww 0xffffec30 0x00020002	;# SMC_SETUP3 : 2 clock cycle setup for NRD and NWE
+	mww 0xffffec34 0x04040404	;# SMC_PULSE3 : 4 clock cycle pulse for all signals
+	mww 0xffffec38 0x00070006	;# SMC_CYCLE3 : 7 clock cycle NRD and 6 NWE cycle
+	mww 0xffffec3C 0x00020003	;# SMC_MODE3 : NRD and NWE control, no NWAIT, 8-bit DBW, 
+   
+	mww 0xffffe800 0x00000001	;# ECC_CR : reset the ECC parity registers
+	mww 0xffffe804 0x00000002	;# ECC_MR : page size is 2112 words (word is 8 bits)
+
+	# Identify NandFlash bank 0.
+
+	nand probe nandflash_cs3
+
+	# The AT91SAM9G20-EK evaluation board has build-in serial data flash also.
 
 	# 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