Minimal semihosted ARM Cortex-M "Hello World"
The following is a minimal, semihosted "Hello World" D program for ARM Cortex-M processors.
Contents
Goals
- Verify the ARM Cortex-M toolchain (compiler-->linker-->debugger)
- Demonstrate that a full port of the D runtime and D standard library are not mandatory
- Demonstrate that linking to C code is not necessary
- Demonstrate that all required assembly code can be done within D
- Provide a starting point, with a low barrier to entry, for developers to begin testing the toolchain, porting the D runtime and libraries to the ARM Cortex-M platform, and programming their ARM Cortex-M software in D
Tools
- (host computer) Arch Linux 64-bit
- (compiler) LDC with ARM backend, or GDC cross-compiler for arm-none-eabi 4.9.2
- (GDB client) GNU Tools for GNU Tools for ARM Embedded Processors
- (GDB server) OpenOCD 0.9.0
- (In Circuit Emulator) STLink v2 on STM32F429I-DISCO board
The Code
Program Source Code (start.d)
module start;
version(LDC)
{
import ldc.llvmasm;
}
//Must be stored as second 32-bit word in .text section
alias void function() ISR;
extern(C) immutable ISR ResetHandler = &OnReset;
void SendCommand(int command, void* message)
{
version(LDC)
{
__asm
(
"mov r0, $0;
mov r1, $1;
bkpt #0xAB",
"r,r,~{r0},~{r1}",
command, message
);
}
else version(GNU)
{
asm
{
"mov r0, %[cmd];
mov r1, %[msg];
bkpt #0xAB"
:
: [cmd] "r" command, [msg] "r" message
: "r0", "r1", "memory";
}
}
}
void OnReset()
{
while(true)
{
// Create semihosting message
uint[3] message =
[
2, //stderr
cast(uint)"hello\r\n".ptr, //ptr to string
7 //size of string
];
//Send semihosting command
SendCommand(0x05, &message);
}
}
Minimal Runtime Implementation (object.d) (GDC only)
GDC requires the following minimal object.d file in compiler's import path, which by default is the compiler's working directory. If compiling from within folder that contains start.d, simply add object.d to that folder. It is imported automatically.
module object;
Compiling
NOTE: You will have to change the -mcpu option for your processor accordingly (e.g. cortex-m0, cortex-m3, etc...)
LDC
ldc2 -mtriple=thumb-none-linux-eabi -mcpu=cortex-m4 -c -betterC start.d
For LDC, object.d must NOT exist, or it will try to import it automatically.
GDC
arm-none-eabi-gdc -mthumb -mcpu=cortex-m4 -fno-emit-moduleinfo -c -fdata-sections start.d
For GDC, object.d MUST exist in the compiler's import path, and it is imported automatically.
Linking
NOTE: This linker scripts were written specifically for an STM32F4 MCU. The MEMORY section and _stackStart will have to be tailored to your hardware.
Linker Script (link.ld)
MEMORY
{
CCRAM (rxw) : ORIGIN = 0x10000000, LENGTH = 64k
SRAM (rxw) : ORIGIN = 0x20000000, LENGTH = 128k
FLASH (rx) : ORIGIN = 0x08000000, LENGTH = 1024k
}
_stackStart = ORIGIN(CCRAM) + LENGTH(CCRAM);
SECTIONS
{
/* We don't need exceptions, and discarding these sections
prevents linker errors with LDC */
/DISCARD/ :
{
*(.ARM.extab*)
*(.ARM.exidx*)
}
.text :
{
LONG(_stackStart); /* Initial stack pointer */
KEEP(start.o(*.ResetHandler)) /* Interrupt vector table (Entry point) */
/* the code */
*(.text)
*(.text*)
/* for "hello\r\n" string constant */
. = ALIGN(4);
*(.rodata)
*(.rodata*)
}>FLASH
/* Need .data, .bss, .ctors and probably more as program becomes
More complex */
}
Link with:
arm-none-eabi-ld -T link.ld --gc-sections start.o -o start.elf
Execution
Start OpenOCD:
openocd -f board/stm32f429discovery.cfg
Start GDB:
arm-none-eabi-gdb start.elf
In GDB, attach to OpenOCD, reset the hardware, load the executable, and begin execution
target remote localhost:3333
monitor arm semihosting enable
monitor reset halt
load
monitor reset init
continue
Output (in OpenOCD window):
hello
hello
...
