问题
I would like to capture, decode, and view ITM trace information for a Cortex-M4 MCU (in my case, an Atmel SAM4S). In particular, I want to capture exceptions and user trace data relative to other signals on my board (i.e. show all signals and trace information on same timeline).
回答1:
This can be done using the following steps:
- Place debugger in SWD mode. If using J-Link Segger on Linux, this can be done with
JLinkGDBServer -if swd - Add code to the MCU to enable trace. Set the bit rate to a value suitable for your needs (I used 8 MHz). Example Ada code is below.
- Use logic analyzer to capture trace data on TRACESWO line from SAM4S processor. I used a Saleae Logic Pro 16 with 100 MHz sample rate.
Convert the data to a format usable by sigrok. Using the Saleae to capture the data, this comprises the following steps:
- Capture using only the first 8 channels (so one byte per sample is exported).
- Export data as binary to
trace.bin, writing a byte for every sample. Convert to a trace.sr file using:
sigrok-cli -i trace.bin -I binary:samplerate=100000000,numchannels=4 -o trace.sr
- Open the
trace.srfile in PulseView. - Add UART decoder to TRACESWO channel, bit rate 8000000.
- Stack ARM-ITM decoder.
See http://www.sigrok.org/blog/new-protocol-decoders-arm-tpiu-itm-etmv3 for more information.
Example Ada code for SAM4S Trace:
sam4s-trace.ads:
with Interfaces;
package SAM4S.Trace is
pragma Preelaborate;
type Channel_Type is new Integer range 0 .. 31;
type Value_Type is new Interfaces.Unsigned_32;
procedure Initialize;
procedure Put (Channel : Channel_Type;
Value : Value_Type);
procedure Put (Channel : Channel_Type;
Message : String);
end SAM4S.Trace;
sam4s-trace.adb:
with System;
with System.Storage_Elements; use System.Storage_Elements;
package body SAM4S.Trace is
procedure Initialize is
ITM_LAR : Interfaces.Unsigned_32
with Address => System'To_Address (16#E000_0FB0#), Volatile;
ITM_TCR : Interfaces.Unsigned_32
with Address => System'To_Address (16#E000_0E80#), Volatile;
ITM_TER : Interfaces.Unsigned_32
with Address => System'To_Address (16#E000_0E00#), Volatile;
ITM_TPR : Interfaces.Unsigned_32
with Address => System'To_Address (16#E000_0E40#), Volatile;
DEMR : Interfaces.Unsigned_32
with Address => System'To_Address (16#E000_EDFC#), Volatile;
TPIU_SPP : Interfaces.Unsigned_32
with Address => System'To_Address (16#E004_00F0#), Volatile;
TPIU_FFCR : Interfaces.Unsigned_32
with Address => System'To_Address (16#E004_0304#), Volatile;
TPIU_ACPR : Interfaces.Unsigned_32
with Address => System'To_Address (16#E004_0010#), Volatile;
DWT_CTRL : Interfaces.Unsigned_32
with Address => System'To_Address (16#E000_1000#), Volatile;
use Interfaces;
begin
-- Enable write access via the Lock Access Register.
ITM_LAR := 16#C5AC_CE55#;
-- Enable the ITM, enable SWO mode behavior, enable synchronization
-- packets, enable DWT event submission, enable timestamps.
ITM_TCR := 16#0001_001F#;
-- Enable access in user mode to all 32 channels.
ITM_TPR := 16#0000_0000#;
-- Enable all 32 trace channels.
ITM_TER := 16#FFFF_FFFF#;
-- Set TRCENA bit to 1 in Debug Exception and Monitor Register.
DEMR := DEMR or 16#0100_0000#;
-- Select NRZ serial wire output.
TPIU_SPP := 16#0000_0002#;
-- Deactivate formatter.
TPIU_FFCR := 16#0000_0100#;
-- Set prescalar (/10).
-- TPIU_ACPR := 16#0000_0009#;
-- Set prescalar (/15).
TPIU_ACPR := 14;
-- Enable exception trace and exception overhead.
DWT_CTRL := DWT_CTRL or 16#0005_0000#;
end Initialize;
procedure Put (Channel : Channel_Type;
Value : Value_Type) is
Port_Reg : Value_Type with Address => System'To_Address (16#E000_0000#) +
4 * Channel_Type'Pos (Channel), Volatile;
begin
-- Port register lsb is set when the the FIFO can accept at least one
-- word.
while Port_Reg = 0 loop
null;
end loop;
Port_Reg := Value;
end Put;
procedure Put (Channel : Channel_Type;
Message : String) is
Port_Reg : Value_Type with Address => System'To_Address (16#E000_0000#) +
4 * Channel_Type'Pos (Channel), Volatile;
begin
-- Port register lsb is set when the the FIFO can accept at least one
-- word.
for Index in Message'Range loop
while Port_Reg = 0 loop
null;
end loop;
Port_Reg := Value_Type (Character'Pos (Message (Index)));
end loop;
end Put;
end SAM4S.Trace;
回答2:
As you tagged it with "logic analyzer", this may be off-topic, but I found the following extremely helpful. With Keil uVision (and probably with other IDEs as well) you can reroute ITM data to file using a custom .ini file.
Enable SWJ in your debugger, use SW Port. Enable Trace, enable the stimulus ports that you want to use.
Write a .ini file with an content like this:
ITMLOG 0 > "debug.log"
ITMLOG 1 > "testlog.xml"
This wil reroute ITM channel 0 to a file named "debug.log", and channel 1 to "testlog.xml" (file syntax from here).
To use the channels easily with fprinf in you c-code I use following setup:
struct __FILE { int channel; };
#include <stdio.h>
#define ITM_Port8(n) (*((volatile unsigned char *)(0xE0000000+4*n)))
#define ITM_Port16(n) (*((volatile unsigned short*)(0xE0000000+4*n)))
#define ITM_Port32(n) (*((volatile unsigned long *)(0xE0000000+4*n)))
#define DEMCR (*((volatile unsigned long *)(0xE000EDFC)))
#define TRCENA 0x01000000
int fputc(int ch, FILE *f) {
if (DEMCR & TRCENA) {
while (ITM_Port32(f->channel) == 0);
ITM_Port8(f->channel) = ch;
}
return(ch);
}
And usage within the project:
FILE debug_stream = { .channel = 0 };
FILE test_stream = { .channel = 1 };
int main(void) {
fprinf(&debug_stream, "this is a debug message, it will be rerouted to debug.log");
fprinf(&test_stream, "this is a test message, it will be placed in testlog.xml");
}
Reference: link
来源:https://stackoverflow.com/questions/32123443/how-do-i-capture-and-view-itm-trace-information-on-a-cortex-m4-mcu