Although not a Cortex-M1, the example below seems to work on both the micro:bit (Cortex-M0, ZFP runtime) and the STM32F407 (SFP runtime, same result, not shown).
procedure Main is
type Byte_Array is array (Natural range 0 .. 3) of Interfaces.Unsigned_8;
Bytes : Byte_Array with
Address => System.Storage_Elements.To_Address (16#0#);
Other_Bytes : Byte_Array;
Other_Bytes := Bytes; -- Line 17
-- Output via semihosting.
for I in Other_Bytes'Range loop
Ada.Text_IO.Put (Other_Bytes (I)'Image);
Ada.Text_IO.New_Line; -- Required to flush semihosting output buffer.
null; -- Line 26
debug session (Cortex-M0, using
pyocd as server)
$ arm-eabi-gdb main
GNU gdb (GDB) 8.3 for GNAT Community 2019 [rev=gdb-8.3-ref-194-g3fc1095]
Copyright (C) 2019 Free Software Foundation, Inc.
Reading symbols from main...
(gdb) target remote :3333
Remote debugging using :3333
0x0000020a in _start ()
Loading section .text, size 0x4fc lma 0x0
Loading section .rodata, size 0x20 lma 0x4e8
Loading section .data, size 0x4 lma 0x4fc
Start address 0x20a, load size 1312
Transfer rate: 3 KB/sec, 437 bytes/write.
(gdb) b 26
Breakpoint 1 at 0x14a: file [...]/src/main.adb, line 26.
Note: automatically using hardware breakpoints for read-only addresses.
Breakpoint 1, main () at [...]/src/main.adb:26
26 null; -- Line 26
(gdb) p/x Other_Bytes
$1 = (0 => 0x88, 0x8, 0x0, 0x20)
(gdb) x/4xb 0
0x0 <__vectors>: 0x88 0x08 0x00 0x20
(gdb) p/x Bytes (0)'Address
$2 = 0x0
(gdb) p/x Other_Bytes (0)'Address
$3 = 0x20000848
output (semihosting, run in separate terminal)
$ nc localhost 4444
136 8 0 32
Note on the usage of
Note that I previously used
System.Null_Address to reference address
0. In this case (and most of the time) this will work. However,
System.Null_Address does not represent memory location
0 by definition. Hence,
To_Address (16#0#) might indeed be more safe (see also ARM 34/2 and ARM 37.c).
Hints that might identify cause.
Based on the provided information (unexpected invocation of the
SVCall exception handler and different behavior depending on optimization level) I would suspect some memory corruption (e.g. because of writes to incorrect memory locations; in C often caused by dangling pointers; in Ada might be because of using "unsafe" language features like
Unrestricted_Access and the
Tracking down memory corruption can be very challenging as the (source code) location where the damage is done may not even be close to where you actually observe the problem.
The first thing I would start to investigate is the invocation of the
SVCall exception handler. I would not expect an ARM
svc instruction to be executed in your case. Some steps I would try (no guarantee this will bring you closer to the solution):
- Disassemble parts of the relevant code around near the problem (in your case
arm-eabi-objdump -d -S and keep it as reference.
- Hook up the
gdb debugger, load the program and inspect if the disassembly near
Other_Bytes := Bytes; and that of
memcpy is comparable with what
objdump returned. Using my own example:
(gdb) info line main.adb:17
Line 17 of "[...]/src/main.adb" starts at address 0xca <_ada_main+10> and ends at 0xe6 <_ada_main+38>.
(gdb) x/14i 0xca
(gdb) info address memcpy
Symbol "memcpy" is at 0x300 in a file compiled without debugging.
(gdb) x/100i 0x300
- Set option to show disassembly per line and set a breakpoint just before reading the memory (i.e.
Other_bytes := Bytes;). Again, using my own example:
(gdb) set disassemble-next-line on
(gdb) b 17
- Start the program (using
c) and once halted at the breakpoint, inspect the disassembled instructions again. Continue step-by-step (using
stepi and then subsequently pressing
<return> to repeat the last command) and monitor the processor instructions shown closely. Check if they are as expected (output of
objdump). I expect that, at some point, the actual and expected program flow starts to deviate. Try to see if/where this happens at the level of processor instructions.