riscv-openocd/tcl/target/gd32vf103.cfg

100 lines
3.7 KiB
INI

adapter speed 1000
transport select jtag
reset_config srst_nogate
set _CHIPNAME gd32vf103
# The vendor's configuration expects an ID of 0x1e200a6d, but this one is what
# I have on my board (Sipeed Longan Nano, GD32VF103CBT6).
jtag newtap $_CHIPNAME cpu -irlen 5 -expected-id 0x1000563d
jtag newtap $_CHIPNAME bs -irlen 5 -expected-id 0x790007a3
set _TARGETNAME $_CHIPNAME.cpu
target create $_TARGETNAME riscv -chain-position $_TARGETNAME
$_TARGETNAME riscv set_enable_virt2phys off
proc default_mem_access {} {
riscv set_mem_access progbuf
}
default_mem_access
$_TARGETNAME configure -work-area-phys 0x20000000 -work-area-size 0x1000 -work-area-backup 1
set _FLASHNAME $_CHIPNAME.flash
flash bank $_FLASHNAME stm32f1x 0x08000000 0 0 0 $_TARGETNAME
# Address 0 is only aliased to main flash when the chip is not running its
# built-in bootloader. When it is, it's instead aliased to a read only section
# of flash at 0x1fffb000. However, we can't detect or dynamically switch this,
# so just pretend it's always aliased to main flash. We need to tell OpenOCD
# about this alias because otherwise we'll try to use software breakpoints on
# code in flash, which don't work because flash mappings are read-only.
flash bank $_CHIPNAME.flashalias virtual 0x0 0 0 0 $_TARGETNAME $_FLASHNAME
# On this chip, ndmreset (the debug module bit that triggers a software reset)
# doesn't work. So for JTAG connections without an SRST, we need to trigger a
# reset manually. This is an undocumented reset sequence that's used by the
# JTAG flashing script in the vendor-supplied GD32VF103 PlatformIO plugin:
#
# https://github.com/sipeed/platform-gd32v/commit/f9cbb44819bc05dd2010cc815c32be0486800cc2
#
$_TARGETNAME configure -event reset-assert {
set dmcontrol 0x10
set dmcontrol_dmactive [expr 1 << 0]
set dmcontrol_haltreq [expr 1 << 31]
global _RESETMODE
global _TARGETNAME
# Halt the core so that we can write to memory. We do this first so
# that it doesn't clobber our dmcontrol configuration.
halt
# Set haltreq appropriately for the type of reset we're doing. This
# replicates what the generic RISC-V reset_assert() function would
# do if we weren't overriding it. The $_RESETMODE hack sucks, but
# it's the least invasive way to determine whether we need to halt,
# and psoc6.cfg already uses the same trick. (reset_deassert(), which
# does run, also does this, but at that point it may be too late: the
# reset has already been triggered, so there's a race between it and
# the haltreq write.)
#
# If we didn't override the generic handler, we'd actually still have
# to do this: the default handler sets ndmreset, which prevents memory
# access even though it doesn't actually trigger a reset on this chip.
# So we'd need to unset it here, which involves a write to dmcontrol,
# Since haltreq is write-only and there's no way to leave it unchanged,
# we'd have to figure out its proper value anyway.
set val $dmcontrol_dmactive
if {$_RESETMODE ne "run"} {
set val [expr $val | $dmcontrol_haltreq]
}
$_TARGETNAME riscv dmi_write $dmcontrol $val
# Unlock 0xe0042008 so that the next write triggers a reset
$_TARGETNAME mww 0xe004200c 0x4b5a6978
# We need to trigger the reset using abstract memory access, since
# progbuf access tries to read a status code out of a core register
# after the write happens, which fails when the core is in reset.
riscv set_mem_access abstract
# Go!
$_TARGETNAME mww 0xe0042008 0x1
# Put the memory access mode back to what it was.
default_mem_access
}
# Capture the mode of a given reset so that we can use it later in the
# reset-assert handler.
proc init_reset { mode } {
global _RESETMODE
set _RESETMODE $mode
if {[using_jtag]} {
jtag arp_init-reset
}
}