riscv-openocd/tcl/target/ti_k3.cfg

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INI

# SPDX-License-Identifier: GPL-2.0-or-later
# Copyright (C) 2019-2021 Texas Instruments Incorporated - http://www.ti.com/
#
# Texas Instruments K3 devices:
# * AM654x: https://www.ti.com/lit/pdf/spruid7
# Has 4 ARMV8 Cores and 2 R5 Cores and an M3
# * J721E: https://www.ti.com/lit/pdf/spruil1
# Has 2 ARMV8 Cores and 6 R5 Cores and an M3
# * J7200: https://www.ti.com/lit/pdf/spruiu1
# Has 2 ARMV8 Cores and 4 R5 Cores and an M3
# * J721S2: https://www.ti.com/lit/pdf/spruj28
# Has 2 ARMV8 Cores and 6 R5 Cores and an M4F
# * J784S4/AM69: http://www.ti.com/lit/zip/spruj52
# Has 8 ARMV8 Cores and 8 R5 Cores
# * AM642: https://www.ti.com/lit/pdf/spruim2
# Has 2 ARMV8 Cores and 4 R5 Cores, M4F and an M3
# * AM625: https://www.ti.com/lit/pdf/spruiv7a
# Has 4 ARMV8 Cores and 1 R5 Core and an M4F
# * AM62a7: https://www.ti.com/lit/pdf/spruj16a
# Has 4 ARMV8 Cores and 2 R5 Cores
# * AM62P: https://www.ti.com/lit/pdf/spruj83
# Has 4 ARMV8 Cores and 2 R5 Cores
#
source [find target/swj-dp.tcl]
if { [info exists SOC] } {
set _soc $SOC
} else {
set _soc am654
}
# set V8_SMP_DEBUG to non 0 value in board if you'd like to use SMP debug
if { [info exists V8_SMP_DEBUG] } {
set _v8_smp_debug $V8_SMP_DEBUG
} else {
set _v8_smp_debug 0
}
# Common Definitions
# System Controller is the very first processor - all current SoCs have it.
set CM3_CTIBASE {0x3C016000}
# sysctrl power-ap unlock offsets
set _sysctrl_ap_unlock_offsets {0xf0 0x44}
# All the ARMV8s are the next processors.
# CL0,CORE0 CL0,CORE1 CL1,CORE0 CL1,CORE1
set ARMV8_DBGBASE {0x90410000 0x90510000 0x90810000 0x90910000}
set ARMV8_CTIBASE {0x90420000 0x90520000 0x90820000 0x90920000}
# And we add up the R5s
# (0)MCU 0 (1)MCU 1 (2)MAIN_0_0 (3)MAIN_0_1 (4)MAIN_1_0 (5)MAIN_1_1
set R5_DBGBASE {0x9d010000 0x9d012000 0x9d410000 0x9d412000 0x9d510000 0x9d512000}
set R5_CTIBASE {0x9d018000 0x9d019000 0x9d418000 0x9d419000 0x9d518000 0x9d519000}
set R5_NAMES {mcu_r5.0 mcu_r5.1 main0_r5.0 main0_r5.1 main1_r5.0 main1_r5.1}
# Finally an General Purpose(GP) MCU
set CM4_CTIBASE {0x20001000}
# General Purpose MCU (M4) may be present on some very few SoCs
set _gp_mcu_cores 0
# General Purpose MCU power-ap unlock offsets
set _gp_mcu_ap_unlock_offsets {0xf0 0x60}
# Set configuration overrides for each SOC
switch $_soc {
am654 {
set _K3_DAP_TAPID 0x0bb5a02f
# AM654 has 2 clusters of 2 A53 cores each.
set _armv8_cpu_name a53
set _armv8_cores 4
# AM654 has 1 cluster of 2 R5s cores.
set _r5_cores 2
set R5_NAMES {mcu_r5.0 mcu_r5.1}
# Sysctrl power-ap unlock offsets
set _sysctrl_ap_unlock_offsets {0xf0 0x50}
}
am642 {
set _K3_DAP_TAPID 0x0bb3802f
# AM642 has 1 clusters of 2 A53 cores each.
set _armv8_cpu_name a53
set _armv8_cores 2
set ARMV8_DBGBASE {0x90010000 0x90110000}
set ARMV8_CTIBASE {0x90020000 0x90120000}
# AM642 has 2 cluster of 2 R5s cores.
set _r5_cores 4
set R5_NAMES {main0_r5.0 main0_r5.1 main1_r5.0 main1_r5.1}
set R5_DBGBASE {0x9d410000 0x9d412000 0x9d510000 0x9d512000}
set R5_CTIBASE {0x9d418000 0x9d419000 0x9d518000 0x9d519000}
# M4 processor
set _gp_mcu_cores 1
}
am625 {
set _K3_DAP_TAPID 0x0bb7e02f
# AM625 has 1 clusters of 4 A53 cores.
set _armv8_cpu_name a53
set _armv8_cores 4
set ARMV8_DBGBASE {0x90010000 0x90110000 0x90210000 0x90310000}
set ARMV8_CTIBASE {0x90020000 0x90120000 0x90220000 0x90320000}
# AM625 has 1 cluster of 1 R5s core.
set _r5_cores 1
set R5_NAMES {main0_r5.0}
set R5_DBGBASE {0x9d410000}
set R5_CTIBASE {0x9d418000}
# sysctrl CTI base
set CM3_CTIBASE {0x20001000}
# Sysctrl power-ap unlock offsets
set _sysctrl_ap_unlock_offsets {0xf0 0x78}
# M4 processor
set _gp_mcu_cores 1
set _gp_mcu_ap_unlock_offsets {0xf0 0x7c}
# Setup DMEM access descriptions
# DAPBUS (Debugger) description
set _dmem_base_address 0x740002000
set _dmem_ap_address_offset 0x100
set _dmem_max_aps 10
# Emulated AP description
set _dmem_emu_base_address 0x760000000
set _dmem_emu_base_address_map_to 0x1d500000
set _dmem_emu_ap_list 1
}
am62p -
am62a7 {
set _K3_DAP_TAPID 0x0bb8d02f
# AM62a7/AM62P has 1 cluster of 4 A53 cores.
set _armv8_cpu_name a53
set _armv8_cores 4
set ARMV8_DBGBASE {0x90010000 0x90110000 0x90210000 0x90310000}
set ARMV8_CTIBASE {0x90020000 0x90120000 0x90220000 0x90320000}
# AM62a7/AM62P has 2 cluster of 1 R5 core.
set _r5_cores 2
set R5_NAMES {main0_r5.0 mcu0_r5.0}
set R5_DBGBASE {0x9d410000 0x9d810000}
set R5_CTIBASE {0x9d418000 0x9d818000}
# sysctrl CTI base
set CM3_CTIBASE {0x20001000}
# Sysctrl power-ap unlock offsets
set _sysctrl_ap_unlock_offsets {0xf0 0x78}
# Overrides for am62p
if { "$_soc" == "am62p" } {
set _K3_DAP_TAPID 0x0bb9d02f
set R5_NAMES {wkup0_r5.0 mcu0_r5.0}
}
}
j721e {
set _K3_DAP_TAPID 0x0bb6402f
# J721E has 1 cluster of 2 A72 cores.
set _armv8_cpu_name a72
set _armv8_cores 2
# J721E has 3 clusters of 2 R5 cores each.
set _r5_cores 6
# Setup DMEM access descriptions
# DAPBUS (Debugger) description
set _dmem_base_address 0x4c40002000
set _dmem_ap_address_offset 0x100
set _dmem_max_aps 8
# Emulated AP description
set _dmem_emu_base_address 0x4c60000000
set _dmem_emu_base_address_map_to 0x1d600000
set _dmem_emu_ap_list 1
}
j7200 {
set _K3_DAP_TAPID 0x0bb6d02f
# J7200 has 1 cluster of 2 A72 cores.
set _armv8_cpu_name a72
set _armv8_cores 2
# J7200 has 2 clusters of 2 R5 cores each.
set _r5_cores 4
set R5_DBGBASE {0x9d010000 0x9d012000 0x9d110000 0x9d112000}
set R5_CTIBASE {0x9d018000 0x9d019000 0x9d118000 0x9d119000}
# M3 CTI base
set CM3_CTIBASE {0x20001000}
}
j721s2 {
set _K3_DAP_TAPID 0x0bb7502f
# J721s2 has 1 cluster of 2 A72 cores.
set _armv8_cpu_name a72
set _armv8_cores 2
# J721s2 has 3 clusters of 2 R5 cores each.
set _r5_cores 6
# sysctrl CTI base
set CM3_CTIBASE {0x20001000}
# Sysctrl power-ap unlock offsets
set _sysctrl_ap_unlock_offsets {0xf0 0x78}
# M4 processor
set _gp_mcu_cores 1
set _gp_mcu_ap_unlock_offsets {0xf0 0x7c}
}
j784s4 {
set _K3_DAP_TAPID 0x0bb8002f
# j784s4 has 2 cluster of 4 A72 cores each.
set _armv8_cpu_name a72
set _armv8_cores 8
set ARMV8_DBGBASE {0x90410000 0x90510000 0x90610000 0x90710000
0x90810000 0x90910000 0x90a10000 0x90b10000}
set ARMV8_CTIBASE {0x90420000 0x90520000 0x90620000 0x90720000
0x90820000 0x90920000 0x90a20000 0x90b20000}
# J721s2 has 4 clusters of 2 R5 cores each.
set _r5_cores 8
set R5_DBGBASE {0x9d010000 0x9d012000
0x9d410000 0x9d412000
0x9d510000 0x9d512000
0x9d610000 0x9d612000}
set R5_CTIBASE {0x9d018000 0x9d019000
0x9d418000 0x9d419000
0x9d518000 0x9d519000
0x9d618000 0x9d619000}
set R5_NAMES {mcu_r5.0 mcu_r5.1
main0_r5.0 main0_r5.1
main1_r5.0 main1_r5.1
main2_r5.0 main2_r5.1}
# sysctrl CTI base
set CM3_CTIBASE {0x20001000}
# Sysctrl power-ap unlock offsets
set _sysctrl_ap_unlock_offsets {0xf0 0x78}
}
default {
echo "'$_soc' is invalid!"
}
}
proc _get_rtos_type_for_cpu { target_name } {
if { [info exists ::RTOS($target_name)] } {
return $::RTOS($target_name)
}
return none
}
set _CHIPNAME $_soc
swj_newdap $_CHIPNAME cpu -irlen 4 -expected-id $_K3_DAP_TAPID -ignore-version
dap create $_CHIPNAME.dap -chain-position $_CHIPNAME.cpu
set _TARGETNAME $_CHIPNAME.cpu
set _CTINAME $_CHIPNAME.cti
# sysctrl is always present
cti create $_CTINAME.sysctrl -dap $_CHIPNAME.dap -ap-num 7 -baseaddr [lindex $CM3_CTIBASE 0]
target create $_TARGETNAME.sysctrl cortex_m -dap $_CHIPNAME.dap -ap-num 7 -defer-examine \
-rtos [_get_rtos_type_for_cpu $_TARGETNAME.sysctrl]
$_TARGETNAME.sysctrl configure -event reset-assert { }
proc sysctrl_up {} {
# To access sysctrl, we need to enable the JTAG access for the same.
# Ensure Power-AP unlocked
$::_CHIPNAME.dap apreg 3 [lindex $::_sysctrl_ap_unlock_offsets 0] 0x00190000
$::_CHIPNAME.dap apreg 3 [lindex $::_sysctrl_ap_unlock_offsets 1] 0x00102098
$::_TARGETNAME.sysctrl arp_examine
}
$_TARGETNAME.sysctrl configure -event gdb-attach {
sysctrl_up
# gdb-attach default rule
halt 1000
}
proc _cpu_no_smp_up {} {
set _current_target [target current]
set _current_type [$_current_target cget -type]
$_current_target arp_examine
$_current_target $_current_type dbginit
}
proc _armv8_smp_up {} {
for { set _core 0 } { $_core < $::_armv8_cores } { incr _core } {
$::_TARGETNAME.$::_armv8_cpu_name.$_core arp_examine
$::_TARGETNAME.$::_armv8_cpu_name.$_core aarch64 dbginit
$::_TARGETNAME.$::_armv8_cpu_name.$_core aarch64 smp on
}
# Set Default target as core 0
targets $::_TARGETNAME.$::_armv8_cpu_name.0
}
set _v8_smp_targets ""
for { set _core 0 } { $_core < $_armv8_cores } { incr _core } {
cti create $_CTINAME.$_armv8_cpu_name.$_core -dap $_CHIPNAME.dap -ap-num 1 \
-baseaddr [lindex $ARMV8_CTIBASE $_core]
target create $_TARGETNAME.$_armv8_cpu_name.$_core aarch64 -dap $_CHIPNAME.dap -coreid $_core \
-dbgbase [lindex $ARMV8_DBGBASE $_core] -cti $_CTINAME.$_armv8_cpu_name.$_core -defer-examine \
-rtos [_get_rtos_type_for_cpu $_TARGETNAME.$_armv8_cpu_name.$_core]
set _v8_smp_targets "$_v8_smp_targets $_TARGETNAME.$_armv8_cpu_name.$_core"
if { $_v8_smp_debug == 0 } {
$_TARGETNAME.$_armv8_cpu_name.$_core configure -event gdb-attach {
_cpu_no_smp_up
# gdb-attach default rule
halt 1000
}
} else {
$_TARGETNAME.$_armv8_cpu_name.$_core configure -event gdb-attach {
_armv8_smp_up
# gdb-attach default rule
halt 1000
}
}
}
# Setup ARMV8 proc commands based on CPU to prevent people confusing SoCs
set _armv8_up_cmd "$_armv8_cpu_name"_up
# Available if V8_SMP_DEBUG is set to non-zero value
set _armv8_smp_cmd "$_armv8_cpu_name"_smp
if { $_v8_smp_debug == 0 } {
proc $_armv8_up_cmd { args } {
foreach _core $args {
targets $_core
_cpu_no_smp_up
}
}
} else {
proc $_armv8_smp_cmd { args } {
_armv8_smp_up
}
# Declare SMP
target smp {*}$_v8_smp_targets
}
for { set _core 0 } { $_core < $_r5_cores } { incr _core } {
set _r5_name [lindex $R5_NAMES $_core]
cti create $_CTINAME.$_r5_name -dap $_CHIPNAME.dap -ap-num 1 \
-baseaddr [lindex $R5_CTIBASE $_core]
# inactive core examination will fail - wait till startup of additional core
target create $_TARGETNAME.$_r5_name cortex_r4 -dap $_CHIPNAME.dap \
-dbgbase [lindex $R5_DBGBASE $_core] -ap-num 1 -defer-examine \
-rtos [_get_rtos_type_for_cpu $_TARGETNAME.$_r5_name]
$_TARGETNAME.$_r5_name configure -event gdb-attach {
_cpu_no_smp_up
# gdb-attach default rule
halt 1000
}
}
proc r5_up { args } {
foreach _core $args {
targets $_core
_cpu_no_smp_up
}
}
if { $_gp_mcu_cores != 0 } {
cti create $_CTINAME.gp_mcu -dap $_CHIPNAME.dap -ap-num 8 -baseaddr [lindex $CM4_CTIBASE 0]
target create $_TARGETNAME.gp_mcu cortex_m -dap $_CHIPNAME.dap -ap-num 8 -defer-examine \
-rtos [_get_rtos_type_for_cpu $_TARGETNAME.gp_mcu]
$_TARGETNAME.gp_mcu configure -event reset-assert { }
proc gp_mcu_up {} {
# To access GP MCU, we need to enable the JTAG access for the same.
# Ensure Power-AP unlocked
$::_CHIPNAME.dap apreg 3 [lindex $::_gp_mcu_ap_unlock_offsets 0] 0x00190000
$::_CHIPNAME.dap apreg 3 [lindex $::_gp_mcu_ap_unlock_offsets 1] 0x00102098
$::_TARGETNAME.gp_mcu arp_examine
}
$_TARGETNAME.gp_mcu configure -event gdb-attach {
gp_mcu_up
# gdb-attach default rule
halt 1000
}
}
# In case of DMEM access, configure the dmem adapter with offsets from above.
if { 0 == [string compare [adapter name] dmem ] } {
if { [info exists _dmem_base_address] } {
# DAPBUS (Debugger) description
dmem base_address $_dmem_base_address
dmem ap_address_offset $_dmem_ap_address_offset
dmem max_aps $_dmem_max_aps
# The following are the details of APs to be emulated for direct address access.
# Debug Config (Debugger) description
dmem emu_base_address_range $_dmem_emu_base_address $_dmem_emu_base_address_map_to
dmem emu_ap_list $_dmem_emu_ap_list
# We are going local bus, so speed is really dummy here.
adapter speed 2500
} else {
puts "ERROR: ${SOC} data is missing to support dmem access!"
}
} else {
# AXI AP access port for SoC address map
target create $_CHIPNAME.axi_ap mem_ap -dap $_CHIPNAME.dap -ap-num 2
}