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# Enabling trace resource in the message_handler_openamp application
The message_handler_openamp application provides support for logging to a trace buffer via the trace entry in the resource table. The following instructions briefly describe one way of enabling the trace resource in the firmware's resource table:
1. Enable building message_handler_openamp with trace buffer support by setting the CMake BOOL cache entry ENABLE_REMOTEPROC_TRACE_BUFFER to ON in the target's CMakeLists.txt
2. Update the target's linker scripts to include an `ethosu_core_trace_buffer` section that is placed in the DRAM as shown in the examples below. The linker-defined symbols for the trace buffer's address and size are later used by the message_handler_openamp to setup the trace buffer in the resource table.
linker-script.ld:
```
SECTIONS
{
.dram ():
{
/* Trace buffer */
__ethosu_core_trace_buffer_start__ = .;
*(ethosu_core_trace_buffer)
__ethosu_core_trace_buffer_size__ = ABSOLUTE(. - __ethosu_core_trace_buffer_start__);
} > DRAM_REGION
```
scatter-file.scatter:
```
LOAD_REGION_DRAM DRAM_ADDRESS DRAM_SIZE
{
/* Trace buffer */
trace_buffer (DRAM_ADDRESS + 0x20000) FIXED
{
* (ethosu_core_trace_buffer)
}
}
```
3. Allocate the trace buffer and place it in the section defined above using the `section` attribute. Finally, implement the `fputc` function in the retarget file so that writes to stderr and stdout are redirected to the trace buffer. Example:
retarget.c:
```
#define TRACE_BUFFER_SIZE 0xXXXX
__attribute__((section("ethosu_core_trace_buffer"))) char trace_buffer[TRACE_BUFFER_SIZE] = {0};
int fputc(int ch, FILE *f) {
(void)f;
uint8_t c = (uint8_t)ch;
static uint32_t write = 0;
trace_buffer[write % TRACE_BUFFER_SIZE] = c;
write++;
return c;
}
```
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