Cortex-M3 vector_catch testing support

The "cm3-ftest.cfg" can be used to verify that OpenOCD handles
certain faults correctly:

 - Test #1: it ignores faults that it wasn't told to catch
 - Test #2: if vector_catch is told to catch, it catches

The "fault.c" generates ASM code to trigger faults, while the
config script loads and runs pre-compiled code.

This covers most, but not all, of the vector_catch options.

Signed-off-by: David Brownell <dbrownell@users.sourceforge.net>
This commit is contained in:
David Brownell 2010-01-20 11:07:42 -08:00
parent 22d25e6921
commit 2a0c9b08d7
2 changed files with 295 additions and 0 deletions

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#
# For each named Cortex-M3 vector_catch flag VECTOR ...
# bus_err state_err
# chk_err nocp_err
# mm_err reset
#
# BUT NYET hard_err, int_err (their test cases don't yet work) ...
#
# Do the following:
#
# - Test #1: verify that OpenOCD ignores exceptions by default
# + l_VECTOR (loads testcase to RAM)
# + fault triggers loop-to-self exception "handler"
# + "halt"
# + observe fault "handling" -- loop-to-self from load_and_run (below)
#
# - Test #2: verify that "vector_catch" makes OpenOCD stops ignoring them
# + cortex_m3 vector_catch none
# + cortex_m3 vector_catch VECTOR
# + l_VECTOR (loads testcase to RAM)
# + fault triggers vector catch hardware
# + observe OpenOCD entering debug state with no assistance
#
# NOTE "reset" includes the NVIC, so that test case gets its reset vector
# from the flash, not from the vector table set up here. Which means that
# for that vector_catch option, the Test #1 (above) "observe" step won't
# use the SRAM address.
#
# we can fully automate test #2
proc vector_test {tag} {
halt
# REVISIT -- annoying, we'd like to scrap vector_catch output
cortex_m3 vector_catch none
cortex_m3 vector_catch $tag
eval "l_$tag"
}
#
# Load and start one vector_catch test case.
#
# name -- tag for the vector_catch flag being tested
# halfwords -- array of instructions (some wide, some narrow)
# n_instr -- how many instructions are in $halfwords
#
proc load_and_run { name halfwords n_instr } {
reset halt
# Load code at beginning of SRAM.
echo "# code to trigger $name vector"
set addr 0x20000000
# ocd_array2mem should be faster, though we'd need to
# compute the resulting $addr ourselves
foreach opcode $halfwords {
mwh $addr $opcode
incr addr 2
}
# create default loop-to-self at $addr ... it serves as
# (a) "main loop" on error
# (b) handler for all exceptions that get triggered
mwh $addr 0xe7fe
# disassemble, as sanity check and what's-happening trace
cortex_m3 disassemble 0x20000000 [expr 1 + $n_instr ]
# Assume that block of code is at most 16 halfwords long.
# Create a basic table of loop-to-self exception handlers.
mww 0x20000020 $addr 16
# Store its address in VTOR
mww 0xe000ed08 0x20000020
# Use SHCSR to ensure nothing escalates to a HardFault
mww 0xe000ed24 0x00070000
# now start, trigering the $name vector catch logic
resume 0x20000000
}
#proc l_hard_err {} {
# IMPLEMENT ME
# FORCED -- escalate something to HardFault
#}
#proc l_int_err {} {
# IMPLEMENT ME
# STKERR -- exception stack BusFault
#}
# BusFault, escalates to HardFault
proc l_bus_err {} {
# PRECISERR -- assume less than 512 MBytes of SRAM
load_and_run bus_err {
0xf06f 0x4040
0x7800
} 2
}
# UsageFault, escalates to HardFault
proc l_state_err {} {
# UNDEFINSTR -- issue architecturally undefined instruction
load_and_run state_err {
0xde00
} 1
}
# UsageFault, escalates to HardFault
proc l_chk_err {} {
# UNALIGNED -- LDM through unaligned pointer
load_and_run chk_err {
0xf04f 0x0001
0xe890 0x0006
} 2
}
# UsageFault, escalates to HardFault
proc l_nocp_err {} {
# NOCP -- issue cp14 DCC instruction
load_and_run nocp_err {
0xee10 0x0e15
} 1
}
# MemManage, escalates to HardFault
proc l_mm_err {} {
# IACCVIOL -- instruction fetch from an XN region
load_and_run mm_err {
0xf04f 0x4060
0x4687
} 2
}
proc l_reset {} {
# issue SYSRESETREQ via AIRCR
load_and_run reset {
0xf04f 0x0104
0xf2c0 0x51fa
0xf44f 0x406d
0xf100 0x000c
0xf2ce 0x0000
0x6001
} 6
}

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/*
* COMPILE: arm-none-eabi-gcc -mthumb -march=armv7-m ...
* ... plus, provide at least a default exception vector table.
*
* RUN: this is best run from SRAM. It starts at main() then triggers
* a fault before more than a handful of instructions have executed.
* Run each test case in two modes:
*
* (1) Faults caught on the Cortex-M3. Default handlers are usually
* loop-to-self NOPs, so a debugger won't notice faults until they
* halt the core and examine xSPR and other registers.
*
* To verify the fault triggered, issue "halt" from OpenOCD; you
* should be told about the fault and (some of) its details.
* Then it's time to run the next test.
*
* NOTE however that "reset" will restart everything; verify that
* case by observing your reset handler doing its normal work.
*
* (2) Faults intercepted by OpenOCD "vector_catch ..." commands.
*
* OpenOCD should tell you about the fault, and show the same
* details, without your "halt" command.
*
* Someday, a fancy version of this code could provide a vector table and
* fault handlers which use semihosting (when that works on Cortex-M3) to
* report what happened, again without needing a "halt" command.
*/
/* These symbols match the OpenOCD "cortex_m3 vector_catch" bit names. */
enum vc_case {
hard_err,
int_err,
bus_err,
state_err,
chk_err,
nocp_err,
mm_err,
reset,
};
/* REVISIT come up with a way to avoid recompiling, maybe:
* - write it in RAM before starting
* - compiled-in BKPT, manual patch of r0, then resume
* - ...
*/
#ifndef VC_ID
#warning "no VC_ID ... using reset"
#define VC_ID reset
#endif
int main(void) __attribute__ ((externally_visible, noreturn));
/*
* Trigger various Cortex-M3 faults to verify that OpenOCD behaves OK
* in terms of its vector_catch handling.
*
* Fault handling should be left entirely up to the application code
* UNLESS a "vector_catch" command tells OpenOCD to intercept a fault.
*
* See ARMv7-M architecure spec table B1-9 for the list of faults and
* their mappings to the vector catch bits.
*/
int main(void)
{
/* One test case for each vector catch bit. We're not doing
* hardware testing; so it doesn't matter when some DEMCR bits
* could apply in multiple ways.
*/
switch (VC_ID) {
/* "cortex_m3 vector_catch hard_err" */
case hard_err:
/* FORCED - Fault escalation */
/* FIXME code this */
break;
/* "cortex_m3 vector_catch int_err" */
case int_err:
/* STKERR -- Exception stack BusFault */
/* FIXME code this */
break;
/* "cortex_m3 vector_catch bus_err" */
case bus_err:
/* PRECISERR -- precise data bus read
* Here we assume a Cortex-M3 with 512 MBytes SRAM is very
* unlikely, so the last SRAM byte isn't a valid address.
*/
__asm__ volatile(
"mov r0, #0x3fffffff\n"
"ldrb r0, [r0]\n"
);
break;
/* "cortex_m3 vector_catch state_err" */
case state_err:
/* UNDEFINSTR -- architectural undefined instruction */
__asm__ volatile(".hword 0xde00");
break;
/* "cortex_m3 vector_catch chk_err" */
case chk_err:
/* UNALIGNED ldm */
__asm__ volatile(
"mov r0, #1\n"
"ldm r0, {r1, r2}\n"
);
break;
/* "cortex_m3 vector_catch nocp_err" */
case nocp_err:
/* NOCP ... Cortex-M3 has no coprocessors (like CP14 DCC),
* but these instructions are allowed by ARMv7-M.
*/
__asm__ volatile("mrc p14, 0, r0, c0, c5, 0");
break;
/* "cortex_m3 vector_catch mm_err" */
case mm_err:
/* IACCVIOL -- instruction fetch from an XN region */
__asm__ volatile(
"mov r0, #0xe0000000\n"
"mov pc, r0\n"
);
break;
/* "cortex_m3 vector_catch reset" */
case reset:
__asm__ volatile(
/* r1 = SYSRESETREQ */
"mov r1, #0x0004\n"
/* r1 |= VECTKEY */
"movt r1, #0x05fa\n"
/* r0 = &AIRCR */
"mov r0, #0xed00\n"
"add r0, #0xc\n"
"movt r0, #0xe000\n"
/* AIRCR = ... */
"str r1, [r0, #0]\n"
);
break;
}
/* don't return */
while (1)
continue;
}