Debugging

External Resources

Debug Interfaces

The CC26x2 platform supports both the cJTAG and JTAG debug interfaces. Debug probes that support cJTAG, like the TI XDS110 and XDS100v3, can work natively with the CC26x2. Other Debug probes that only support JTAG, like the IAR I-Jet and Segger J-Link, need to inject a cJTAG sequence to enable JTAG functionality. The hardware resources included on the devices for debugging are listed as follows. Not all debugging functionality is available in all combinations of debug probe and IDE.

  • Flash Patch and Breakpoint Unit (FPB) - 6 instruction comparators, 2 literal comparators
  • Data Watchpoint and Trace Unit (DWT) - 5 watchpoints on memory access
  • Instrumentation Trace Macrocell (ITM) - 32 x 32 bit stimulus registers
  • Trace Port Interface Unit (TPIU) - serialization and time-stamping of DWT and ITM events

XDS110 Debug Probe

The CC26x2 LaunchPad have an on-board XDS110, and this is the assumed debug probe for most development.

The XDS110 is the latest entry level debug probe (emulators) for TI embedded processors. Designed to be a complete solution that delivers JTAG and SWD connectivity at a low cost, the XDS110 is the debug probe of choice for entry-level debugging of TI microcontrollers, processors and SimpleLink devices. Also, both Core Processor and System Trace are available for all ARM and DSP devices that support Embedded Trace Buffer (ETB).

Configuring Debugger in CCS

If only one debug probe is attached, CCS will automatically select the connected debug probe when a debug session is started. You can start a debug session by clicking the debug icon img_icon_debug_ccs on the toolbar.

If more than one debug probe is attached when a debug session is started, CCS will prompt you to select a debug probe as seen in Figure 36. CCS will save the selected debug probe in the target configuration for the project.

../_images/ccs_probe_select.png

To set or change the selected debug probe for a project, it is necessary to set the serial number for the probe in the project’s target configuration.

Find The Serial Number

To find the serial number for XDS110 debug probe, open a command prompt and run the command c:\ti\ccs_7_3_0_00019\ccsv7\ccs_base\common\uscif\xds110\xdsdfu.exe -e. This will enumerate all the attached XDS110 debug probes. This should result in output like the following.

C:\>c:\ti\ccs_7_3_0_00019\ccsv7\ccs_base\common\uscif\xds110\xdsdfu.exe -e

USB Device Firmware Upgrade Utility
Copyright (c) 2008-2015 Texas Instruments Incorporated.  All rights reserved.

Scanning USB buses for supported XDS110 devices...


<<<< Device 0 >>>>

VID: 0x0451    PID: 0xbef3
Device Name:   XDS110 Embed with CMSIS-DAP
Version:       2.3.0.9
Manufacturer:  Texas Instruments
Serial Num:    L1100017
Mode:          Runtime

<<<< Device 1 >>>>

VID: 0x0451    PID: 0xbef3
Device Name:   XDS110 Embed with CMSIS-DAP
Version:       2.3.0.9
Manufacturer:  Texas Instruments
Serial Num:    L11000EN
Mode:          Runtime

Found 2 devices.

C:\>

For XDS100 series debug probes, open a command prompt and run the command c:\ti\ccs_7_3_0_00019\ccsv7\ccs_base\common\uscif\xds100serial.exe. This should result in output like the following.

C:\>c:\ti\ccs_7_3_0_00019\ccsv7\ccs_base\common\uscif\xds100serial.exe
Scanning for XDS100 emulators...

VID/PID    Type            Serial #    Description
0403/a6d1  XDS100v3        06EB12213144  Texas Instruments XDS100v3

C:\>

Configure Serial Number

It may be necessary to set or unset the selected debug probe. Use the following steps to do this.

  1. Open the target configuration file.
../_images/ccs_targetconfig_file.png
  1. Open the Advanced pane.
 
  1. Choose the top-level debugger entry.
../_images/ccs_targetconfig_probe.png
  1. Enter the serial number.
../_images/ccs_targetconfig_serial.png

Breakpoints

Comparators in the FPB of the CC26x2 are used to break on an instruction fetch. This can be used to patch a function as it is fetched from instruction memory. Or these comparators can be used to supply a Breakpoint (BKPT) instruction to the CPU. These instructions halt the processors operation, waiting for the debug probe.

Considerations

While breakpoints are a useful tool for debugging code online, they have the possibility of altering the execution flow of a piece of code.

Breakpoints and Timing

Synchronous RF protocols are timing sensitive. Breakpoints can easily halt the execution long enough to lose network timing and break the link.

To still be able to debug, place breakpoints as close as possible to where the relevant debug information can be read or step through the relevant code segment to debug.

After you hit a breakpoint and read out the necessary debug information, it is recommended that you reset the device and re-establish the connection.

Breakpoints and Optimization

When compiler optimizations are enabled, toggling a breakpoint on a line of C code may not result in the expected behavior. Some examples include the following.

Code is removed or not compiled in
Toggling a breakpoint in the IDE results in a breakpoint somewhere other than the intended line. Some IDEs disable breakpoints on nonexistent code.
Code block is part of a common subexpression
A breakpoint might be trigged from a function or piece of code near the marked line. This might have been due to the compiler reusing sections.
An if clause is represented by a conditional branch in assembly
A breakpoint inside an if clause always breaks on the conditional statement, even when the condition is not true.

TI recommends selecting an optimization level as low as possible when debugging. See Optimizations for information on modifying optimization levels.

Breakpoints in CCS

Note

CCS reserves one hardware breakpoint for instruction stepping.

To toggle a breakpoint, do any of the following.

  • Double-click the area to the left of the line number.
  • Press Ctrl + Shift + B.
  • Right-click on the line.

A breakpoint set on line 207 looks like the following.

../_images/ccs_breakpoint_ex.png

Figure 37. Breakpoint on line 207. Debugger halted at start of main().

For an overview of the active and inactive breakpoints, click on ViewBreakpoints.

../_images/ccs_breakpoint_list.png

Figure 38. List of breakpoints. Right-click to edit options, or de-select to deactivate.

To set a conditional break, do as follows.

  1. Right-click the breakpoint in the overview.
  2. Choose Properties.

When debugging, Skip Count and Condition can help skip a number of breaks or only break if a variable is a certain value.

Note

Conditional breaks require a debugger response and may halt the processor long enough to break an active RF connection, or otherwise disrupt timing on the debug target.

Watching Variables and Registers

Debuggers offer several ways of viewing the state of a halted program. Global variables are statically placed during link-time and can end up anywhere in the RAM or Flash of the chip. These variables can be viewed when then target is halted by the debugger through the Watch and Expression windows.

Unless removed due to optimizations, global variables are always available in these views. Local variables or variables that are only valid inside a limited scope are only viewable in that scope. Such variables can also be viewed with the Watch or Expression views, and may also be automatically displayed when breaking or stepping through code.

Considerations

Local variables are often placed in CPU registers and not on the stack. These variables also have a limited lifetime even within the scope in which they are valid. Depending on the optimization performed, a variable placed in a register may not have a cohesive view of the current state of the variable. Some possible solutions are:

  • Move the variable to global scope, so it remains accessible in RAM.
  • Make the variable volatile, so the compiler doesn’t place the value in a register.
  • Make a shadow copy of the variable that is global and volatile.

Variables in CCS

You can view Global Variables by doing either of the following.

  • Select ViewExpressions.
  • Select a variable name in code.
  • Right-click and select Add Watch Expression.
../_images/ccs_watch.png

Figure 39. Variable watch window. Note that you can cast values, get address and sizeof, etc.

  • Select ViewVariables to auto-variables that are present at the current location when stepping through code.
../_images/ccs_locals.png

Figure 40. Local variables. This screenshot is taken during execution of the Simple Peripheral init function.

Memory Watchpoints

As mentioned in Debug Interfaces, the DWT module contains four memory watchpoints that allow breakpoints on memory access. The hardware match functionality looks only at the address. If intended for use on a variable, the variable must be statically allocated.

Note

If a data watchpoint with value match is used, two of the four watchpoints are used.

Watchpoints in CCS

  1. Right-click on a global variable.
  2. Select BreakpointHardware Watchpoint.
  3. Go to the list of breakpoints (ViewBreakpoints).
  4. Right-click and edit the Breakpoint Properties to configure the watchpoint.
../_images/ccs_watchpoint_add.png

Figure 41. Adding a watchpoint on a variable.

This example configuration ensures that if 0x42 is written to the memory location for Characteristic 1 in the Bluetooth low energy simple_peripheral example project the device halts execution.

../_images/ccs_watchpoint_configure.png

Figure 42. Configuring a hardware watchpoint to break on 8-bit write with value 0x42.

TI-RTOS Object Viewer

Debuggers may include the RTOS Object Viewer (ROV) plug-in that provides insight into the current state of TI-RTOS, including task states, stacks, and so forth.

This section discusses some ROV views useful for debugging and profiling. More details can be found in the TI-RTOS User’s Guide, including documentation on how to add log events to application code.

Scanning the BIOS for Errors

The BIOS Scan for errors view goes through the available ROV modules and reports on errors. This functionality can be a good point to start if anything has gone wrong. This scan only shows errors related to TI-RTOS modules and only the errors it can catch.

../_images/rov_bios_scan.png

Figure 43. Scan for errors. Here a Task Stack has been overrun.

Viewing the State of Each Task

The Task Detailed view is useful for seeing the state of each task and its related runtime stack usage. This example shows the state the first time the user-thread is called. Figure 44. shows the Bluetooth low energy stack task, represented by its ICall proxy, the Idle task, the simple_peripheral task and the GAPRole task.

../_images/rov_task_detailed.png

Figure 44. Detailed view of the Tasks. Notice the address of the overrun task matches the instance id from Scan for errors.

The following list explains the column in Figure 44.

address
This column shows the memory location of the Task_Struct instance for each task.
priority
This column shows the TI-RTOS priority for the task.
mode
This column shows the current state of the task.
fxn
This column shows the name of the entry function of the task.
arg0, arg1
These columns show arbitrary values that can be given to entry function of the task. In the image, the ICall_taskEntry is given 0xb001, which is the flash location of the entry function of the RF stack image and 0x20003a30 (the location of bleUserCfg_t user0Cfg, defined in main()).
stackPeak
This column shows the maximum run-time stack memory used based on watermark in RAM, where the stacks are prefilled with 0xBE and there is a sentinel word at the end of the run-time stack.

Note

Function calls may push the stack pointer out of the run-time stack, but not actually write to the entire area. A stack peak near stackSize but not exceeding it may indicate stack overflow.

stackSize
This column shows the size of the runtime stack, configured when instantiating a task.
stackBase
This column shows the logical top of the runtime stack of the task (usage starts at stackBase + stackSize and grows down to this address).

Viewing the System Stack

The Hwi Module view allows profiling of the system stack used during boot or for main(), Hwi execution, and Swi execution. See System Stack for more information on the system stack.

../_images/rov_hwi_module.png

Figure 45. Viewing the System Stack in Hwi

The hwiStackPeak, hwiStackSize, and hwiStackBase can be used to check for system stack overflow.

ROV in CCS

To access the ROV while in a debug session in CCS:

  • Click the Tools menu.
  • Click RTOS Object View (ROV).

Warning

When using autosized heap, the ROV may display errors when accessing modules such as Task and Heap for ROV Classic. In order to use ROV with an autosized heap you can use ROV2, or do the following:

  • Apply the following patch to the function init() in \kernel\tirtos\packages\ti\sysbios\heaps\package.xs. The lines highlited below should be added.
function init()
{
  /* Add HeapMem's primaryHeap addresses range to ROV's memory sections */
  if (xdc.om.$name == "rov") {
      var HeapMem = xdc.module('ti.sysbios.heaps.HeapMem');
//        if (xdc.om['ti.sysbios.heaps'].HeapMem.$used) {
          var Program = xdc.useModule('xdc.rov.Program');
          var HeapMemCfg =  Program.getModuleConfig(HeapMem.$name);
          if  (HeapMemCfg.primaryHeapBaseAddr != null) {
              var base = Program.getSymbolValue(HeapMemCfg.primaryHeapBaseAddr.substr(1));
              var end = Program.getSymbolValue(HeapMemCfg.primaryHeapEndAddr.substr(1));
              /* Retrieve the MemoryImage java object. */
              var Model = xdc.module("xdc.rov.Model");
              var memReader = Model.getMemoryImageInst();

              /* retrieve the sections list and add a new section */
              var sections = memReader.getSections();
              sections.addSection(base, end-base);
          }
//        }
          /* Retrieve the MemoryImage java object. */
          var Model = xdc.module("xdc.rov.Model");
          var memReader = Model.getMemoryImageInst();

          /* retrieve the sections list and add a new section */
          var sections = memReader.getSections();
          sections.addSection(0x20000000, 0x20005000);
  }
}

Using the Memory Browser

Debuggers are able to show a representation of the memory on the CC26x2. In CCS, you can index by address or by symbol name. As an example, consider the stack that was overrun in Figure 44.:

Simple Peripheral Task’s stack. Note BE watermark GAPRole Task’s stack. Note it’s completely filled.
../_images/mem_browser_sbp_stack.png
../_images/mem_browser_gaprole_stack.png

The solution in this case would be to increase the stack size for the failing task and see what the stack peak really is. The stackPeak reported is relying on how many watermark bytes are overwritten, so it can’t know how much the overrun amounts to.

Because stacks are utilized from higher addresses towards lower addressed (upwards in the picture), stacks that overrun will tend to overwrite data at locations immediately before the stack.

Optimizations

Compiler optimizations are great for saving space or speeding up execution. However, these optimizations can be very difficult to debug around. There are multiple levels at which optimization can be turned on or off.

Project-wide optimization settings are the most general. Sometimes, given the constraints of the device, it is impossible to lower the size optimization level. File-wide optimization settings can be used like project-wide optimizations to turn on or off certain settings. The most granular control is using compiler directives to control optimization at a function level.

Optimizations in CCS

Project-Wide Optimizations

Open the project optimization settings by going to Project PropertiesCCS BuildARM CompilerOptimization

../_images/ccs_optim_level_project.png

Figure 46. Project-level optimization setting in CCS

Single-File Optimizations

Note

Do single-file optimizations with care because this also overrides the project-wide preprocessor symbols.

  1. Right-click on the file in the Workspace pane.
  2. Choose Properties.
  3. Change the optimization level of the file using the same menu in the CCS project-wide optimization menu.

Single-Function Optimizations

Warning

Pragmas are very specific to the toolchain, and may lead to non-reusable code. Be careful where you use these.

Listing 20. Function-level optimization setting in ti-cgt
#pragma FUNCTION_OPTIONS(myFunction, "--opt_level=0")
static void myFunction(int number)
{
    // ...
    return yourFunction(other_number);
}
Listing 21. Function-level optimization setting in gcc
#pragma GCC push_options
#pragma GCC optimize ("O0")
static void myFunction(int number)
{
    // ...
    return yourFunction(other_number);
}
#pragma GCC pop_options

Loading TI-RTOS in ROM Symbols

Some of the TI-RTOS kernel modules are included in ROM, and executed from ROM in order to save Flash space for the application. This can lead to some confusion, when only addresses are shown in the disassembly view and the call-stack view.

All TI-RTOS kernel code in ROM starts with address 0x1001xxxx. In order to make sense of the ROM’ed code, you need to include the symbol files in your debug session.

Import in CCS

../_images/rtos_symbols_add_ccs.png

Figure 47. Adding symbol information for the BIOS kernel in ROM, via Add Symbols.

  • While in debug mode, click the drop-down button next to the Load Program icon
  • Select Add Symbols ...
  • Select Browse ... and find <SDK_INSTALL_DIR>\kernel\tirtos\packages\ti\sysbios\rom\cortexm\cc26xx\r2\golden\CC26xx\rtos_rom.xem3

Deciphering CPU Exceptions

Several possible exception causes exist. If an exception is caught, an exception handler function can be called. Depending on the project settings, this handler may be a default handler in ROM, which is just an infinite loop or a custom function called from this default handler instead of a loop.

When an exception occurs, the exception may be caught and halted in debug mode immediately, depending on the debugger. If the execution halted manually later through the Break debugger, it is then stopped within the exception handler loop.

Exception Cause

With the default setup using TI-RTOS, the exception cause can be found in the System Control Space register group (CPU_SCS) in the register CFSR (Configurable Fault Status Register). The ARM Cortex-M3 User Guide describes this register. Most exception causes fall into the following three categories.

  • Stack overflow or corruption leads to arbitrary code execution.
    • Almost any exception is possible.
  • A NULL pointer has been dereferenced and written to.
    • Typically (IM)PRECISERR exceptions
  • A peripheral module (like UART, Timer, and so forth) is accessed without being powered.
    • Typically (IM)PRECISERR exceptions

The CFSR register is available in ViewRegisters.

When an access violation occurs, the exception type is IMPRECISERR because writes to flash and peripheral memory regions are mostly buffered writes.

If the CFSR:BFARVALID flag is set when the exception occurs (typical for PRECISERR), the BFAR register in CPU_SCS can be read out to find which memory address caused the exception.

If the exception is IMPRECISERR, PRECISERR can be forced by manually disabling buffered writes. Set [CPU_SCS:ACTRL:DISDEFWBUF] to 1, by either manually setting the bit in the register view in the debugger or by including <hw_cpu_scs.h> from Driverlib and calling the following.

#include <ti/devices/cc26x0r2/inc/hw_cpu_scs.h>
//..
int main()
{
    // Disable write-buffering. Note that this negatively affect performance.
    HWREG(CPU_SCS_BASE + CPU_SCS_O_ACTLR) = CPU_SCS_ACTLR_DISDEFWBUF;
    // ..
}

Using TI-RTOS and ROV to Parse Exceptions

To enable exception decoding in the RTOS Object View (ROV) without using too much memory, use the Minimal exception handler in TI-RTOS. The default choice in the TI-OpenThread Stack projects is to use no exception handler.

To set this up, change the section of the TI-RTOS configuration file that relates to M3Hwi so that it looks like the code below:

//m3Hwi.enableException = true;
m3Hwi.enableException = false;
//m3Hwi.excHandlerFunc = null;
m3Hwi.excHookFunc = "&execHandlerHook";

Then, make a function somewhere with the signature void (*Hwi_ExceptionHookFuncPtr)(Hwi_ExcContext*); such as the one below:

#include <ti/sysbios/family/arm/m3/Hwi.h>
// ...
volatile uintptr_t *excPC = 0;
volatile uintptr_t *excCaller = 0;
// ...
void execHandlerHook(Hwi_ExcContext *ctx)
{
    excPC = ctx->pc;     // Program counter where exception occurred
    excCaller = ctx->lr; // Link Register when exception occurred

    while(2);
}

Setting m3Hwi.enableException to false enables the minimal handler, which fills out the global Hwi_ExcContext structure that the ROV looks at to show the decoded exception. By setting up an excHookFunc, the minimal exception handler will call this function and pass along a pointer to the exception context for the user to work with. This structure is defined in <ti/sysbios/family/arm/m3/Hwi.h>.

When an exception occurs, the device should end up in that infinite loop. Inspect the ROVHwiException information.

../_images/rov_hwi_exception.png

Figure 48. Decoded exception, intentional write to address 0x0013 which is illegal. Note that writebuffering has been disabled to get a precise error location, and that m3Hwi.enableException has been set to false to get the decoding.

In this case, a bus fault was forced in the function writeToAddress by dereferencing address 0x0013 and trying to write to it:

Listing 22. Write to an address in the FLASH memory region.
void writeToAddress(uintptr_t *addr, int val)
{
    *(int *)addr = val;
}

// ..

void taskFxn(...)
{
    // ..
    writeToAddress( (void*)19, 4 ); // Randomly chosen values
}

The write instruction was placed on line 79 of application.c, as indicated. To get a precise location, the write buffer was disabled as described earlier.

It can be instructive to look at the disassembly view for the locations specified by PC (program counter) and LR (link register). PC is the presumed exception location, and LR is normally the location the failing function should have returned to. As an example, the PC at this exception:

../_images/exception_pc_of_write.png

Figure 49. Here the pc from the decoded exception was looked up in the disassembly view.

Some forensics is required here. We have from the Hwi decoding in ROV (and from the exception context in the exception hook) that the program counter was 0x708e when the exception occurred.

At that location there is a store instruction str r0, [r1] meaning, store in R0 the value of what the memory address in R1 points to. The business with SP in the figure above is related to optimization being turned off, so all local variables are stored on the stack, even though in this case R0 and R1 could have been used directly from the caller.

Now we know that the exception occurred because someone called writeToAddress with an invalid address.

Thanks to the exception decoder we can easily find the call site by looking at the call stack, but if the call stack isn’t helpful, we can look at lr, which is seen in the exception decoder to be 0x198f

../_images/exception_lr_of_write.png

Figure 50. Call site as specified in lr. Note that lr is the instruction after the call to writeToAddress because execution would have resumed here.

We can see here that R0 and R1 are initialized with constants. This means that some programmer has intentionally called the write function with an address that causes a busfault.

Most often the reason for a bus-fault is that a pointer is not initialized and a function like writeToAddress gets the pointer, assumes it’s valid and dereferences the pointer and writes to the invalid address.

OpenThread Logging & The Debug Uart

OpenThread provides and extensive debug & logging facility, but in the embedded environment there is often no place to send or save the log output. In addition depending upon what is enabled, and what level is enabled the log may become voluminous. Often the log output is better suited for a simple serial terminal. For these reasons, a debug uart feature was introduced.

Controlling Log Output

Logging is controlled via #defines in these source files:

${workspace}/libopenthread-{ftd|mtd}-{chipname}-launchxl-{gcc|ccs}/openthread-config-{chipname}-{gcc|ccs}-{ftd|mtd}.h

Resolving the choices above, an actual filename might be:

${workspace}/libopenthread-ftd-cc2652-launchxl-ccs/openthread-config-cc2652-ccs-ftd.h

Where ${workspace} is your CCS workspace, and the other {brace-names} are specific to the configuration at hand.

Specifically search for #define ENABLE_ALL_LOGS_TO_UART 0, change this to 1. There are numerous other log settings can be found in this header file.

Also review:

  • ${sdk_root}/source/third_party/openthread/include/openthread/platform/logging.h
  • ${sdk_root}/source/third_party/openthread/src/core/common/logging.h
  • ${sdk_root}/source/third_party/openthread/src/core/common/logging.cpp

Where ${sdk_root} is the installation directory of the SDK.

Logging Macros

OpenThread uses many layers of #define macros, in the end after all of the macro expansion is complete, the macro expands to either (a) an empty statement, or (b) invokes otPlatLog()

The otPlatLog() Function

The otPlatLog() function is nothing more then a fancy printf() function with a few extra parameters.

If memory, flash space, and performance where not an obstacle otPlatLog() could, in theory, dynamically control logging. However in the embedded world resources are at a premium. Thus logging is controlled via multiple compile time macros described above.

The final log output is controlled by the macro: OPENTHREAD_CONFIG_LOG_OUTPUT

The default value is: OPENTHREAD_CONFIG_LOG_OUTPUT_NONE which resolves to a stub function provided by ${sdk_root}/source/third_party/openthread/src/core/common/logging.cpp

If OPENTHREAD_CONFIG_LOG_OUTPUT_DEBUG_UART is selected, the otPlatLog() function is provided by the debug uart feature. The relevant source files are:

  • ${sdk_root}/source/third_party/openthread/examples/platform/utils/debug_uart.h
  • ${sdk_root}/source/third_party/openthread/examples/platform/utils/debug_uart.c

Which, call otPlatDebugUart_putchar_raw() to output each byte of the log.

Lowest Level Log Output otPlatDebugUart_putchar_raw()

The function otPlatDebugUart_putchar_raw() can be found here:

  • ${workspace}/platform/debug_uart.c

This file also provides default GPIO ids for the debug uart TXD and RXD signals.

Warning

Enabling the Debug Uart feature disables device sleep. See the initialization function in debug_uart.c for details.

Other uses for the Debug Uart

It should be noted that OpenThread runs within a single RTOS task. Thus from OpenThread’s perspective logging operations are never re-entrant, and thus no serialization protections are made within the OpenThread logging routines.

However it often very helpful to use features like the debug uart outside of the OpenThread context. The three most probable places are:

  1. Within a hardware or software interrupt service routine, for example during a callback
  2. Within another execution thread
  3. As a means of last resort, when things crash, OS data structures may be inconsistent and if used may leading to a cascade of other crashes.

For the above reasons, certain design decisions where taken:

  1. The debug uart is completely blocking, or polled mode of operation.
  2. The debug uart does not make use of any OS services (queues, etc.)
  3. There are no serialization, or access controls that surrounding the debug uart operation.

This can result in jumbled output:

As a result, if there are context switches the log output may jumble. This comes at a cost of possibly jumbled output, it is assumed the human reader can adapt and understand the output.

The alternative (by introducing synchronization) may render the feature unusable and a cascade of other problems.

Thus the debug uart output is always available, even in the most catastrophic crash scenario.

Additional stack requirement:

The function: otPlatDebugUart_printf() routine uses the underlying printf() feature of the run-time library and creates an output buffer on the call stack. Thus, stack usage is something to consider.

In those situations, the alternative that requires far less stack space would be: otPlatDebugUart_puts().

Example Output

The default UART settings are: 115200, 8 bits, No parity, 1 stop bit

Below is an example output from the CLI application. The engineer has typed a few commands to start the thread network.

../_images/thread-debug-uart-output.png

Figure 51. Example otPlatLog() output via the debug uart.

Notes:

  1. Output from otPlatLog() starts with SECONDS (dot) MILLISECONDS (bar) where time zero begins at system reset.
  2. Output that did not go through the otPlatLog() function (calling otPlatDebugUart_printf() directly) does not have the timestamp prefix. An example of this is shown where the CLI commands are duplicated to the debug uart output.

Connections

Consult the Debug Serial Back Channel Connection section Debug Serial Back Channel Connection for details on connecting a USB-to-Serial adaptor.