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RTIC Scope application example on a Microchip ATSAME51N20A MCU running a trivial RTIC application

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RTIC Scope application example

This repository is an application example of RTIC Scope v0.3 on a Microchip ATSAME51N20A MCU running a trivial RTIC application. The SWO pin of the MCU is used to asynchronously exfiltrate the trace stream from the device. It it assumed that the serial communication (NRZ) on this SWO pin is exposed as a serial device on your (Linux) host system.

The application configures tracing via cortex_m_rtic_trace::{configure, trace} and pends a app::hardware task. This hardware task spawns a software task, app::software, with higher priority that instantly exits. Both tasks are traced.

Installing RTIC Scope

Install the toolset via

$ cargo install --git https://github.com/rtic-scope/cargo-rtic-scope  --branch v0.3.x cargo-rtic-scope rtic-scope-frontend-dummy

It is also recommended to install itm-decode for debugging purposes:

$ cargo install --git https://github.com/rtic-scope/itm --branch v0.8.x itm-decode

Preparing the target

Attach to the target via openocd or equivalent:

$ openocd -f openocd.cfg

Flash the target via arm-none-eabi-gdb or equivalent (adapt runner in .cargo/config for your system):

$ cargo run
[...]
(gdb) continue
Program received signal SIGTRAP, Trace/breakpoint trap.
[...]
(gdb) frame 2
#2  rtic_scope_atsame_example::app::init (ctx=...) at src/main.rs:41
41              cortex_m::asm::bkpt(); // interactive escape from SWO pin transient
(gdb)

Testing the communication with itm-decode (optional)

The flashed application configures the trace subsystem so communicate with a baud rate of 1000000 Bps, via

// configure tracing
cortex_m_rtic_trace::configure(
    ..,
    &TraceConfiguration {
        ..,
        tpiu_baud: 1_000_000, // B/s
    },
)
.unwrap();

Logically, we use the same baud rate on the host:

$ itm-decode /path/to/dev/tty --itm-freq 1000000

After which we resume execution on the device:

(gdb) continue

which yields

ExceptionTrace { exception: Interrupt { irqn: 12 }, action: Entered }
ExceptionTrace { exception: Interrupt { irqn: 13 }, action: Entered }
LocalTimestamp1 { ts: 24, data_relation: Sync }
DataTraceValue { comparator: 1, access_type: Write, value: [0] }
LocalTimestamp1 { ts: 45, data_relation: Sync }
DataTraceValue { comparator: 2, access_type: Write, value: [0] }
ExceptionTrace { exception: Interrupt { irqn: 13 }, action: Exited }
LocalTimestamp2 { ts: 5 }
ExceptionTrace { exception: Interrupt { irqn: 12 }, action: Returned }
ExceptionTrace { exception: Interrupt { irqn: 12 }, action: Exited }
LocalTimestamp2 { ts: 2 }
ExceptionTrace { exception: ThreadMode, action: Returned }

With a verified connection, we continue with RTIC Scope proper after first resetting the target:

(gdb) reflash
(gdb) continue
Program received signal SIGTRAP, Trace/breakpoint trap.
[...]
(gdb) frame 2
#2  rtic_scope_atsame_example::app::init (ctx=...) at src/main.rs:41
41              cortex_m::asm::bkpt(); // interactive escape from SWO pin transient
(gdb)

Recording a trace with cargo rtic-scope trace

RTIC Scope resolves the RTIC tasks responsible for the emission of the ExceptionTraces and DataTraceValues above, but requires user-supplied metadata in order to do so. This metadata is provided in a metadata block in Cargo.toml:

[package.metadata.rtic-scope]
pac_name = "atsamd51n"                  # Crate in which the Interrupt enum lives. Used for hardware task resolving.
pac_features = []
pac_version = "0.11"
interrupt_path = "atsamd51n::Interrupt" # Module path to the Interrupt enum.
tpiu_freq = 12000000                    # Frequency of the clock sourcing the TPIU perhipheral
tpiu_baud = 1000000                     # Target-side SWO baud rate
dwt_enter_id = 1                        # DWT comparator ID for software task enter events
dwt_exit_id = 2                         # DWT comparator ID for software task exit events
lts_prescaler = 1                       # The prescaler for local (delta) timestamps
expect_malformed = false                # We do not expect malformed trace packets in the stream. Used for debugging purposes. To be deprecated in a future release.

This metadata should match the call to cortex_m_rtic_trace::configure:

// configure tracing
cortex_m_rtic_trace::configure(
    &mut ctx.core.DCB,
    &mut ctx.core.TPIU,
    &mut ctx.core.DWT,
    &mut ctx.core.ITM,
    1, // task enter DWT comparator ID
    2, // task exit DWT comparator ID
    &TraceConfiguration {
        delta_timestamps: LocalTimestampOptions::Enabled, // enabled with a bypassed (= 1) prescaler
        absolute_timestamps: GlobalTimestampOptions::Disabled, // disable absolute timestamps
        timestamp_clk_src: TimestampClkSrc::AsyncTPIU,
        tpiu_freq: freq, // Hz
        tpiu_baud: 1_000_000, // B/s
        protocol: TraceProtocol::AsyncSWONRZ,
    },
)
.unwrap();

With the metadata supplied, we start recording the trace:

$ cargo rtic-scope trace --serial /path/to/dev/tty --dont-touch-target
    Building RTIC target application...
  Recovering metadata for rtic-scope-atsame-example (/path/to/rtic-scope-atsame-example/src/main.rs)...
   Recovered 2 task(s) from rtic-scope-atsame-example: 1 hard, 1 soft.
[...]

resume target execution:

(gdb) continue

and send SIGINT (<C-c>) after 10 seconds which ends the recording, yielding

    Frontend dummy: @2000 ns (+2000 ns) [good]: [Task { name: "app::hardware", action: Entered }]
    Frontend dummy: @5750 ns (+3750 ns) [good]: [Task { name: "app::software", action: Entered }]
    Frontend dummy: @6167 ns (+417 ns) [good]: [Task { name: "app::software", action: Exited }]
    Frontend dummy: @6334 ns (+167 ns) [good]: [Task { name: "app::hardware", action: Returned }, Task { name: "app::hardware", action: Exited }]
      Traced rtic-scope-atsame-example: 10 packets processed in 10s (~1.0 packets/s; 0 malformed, 0 non-mappable); 2/2 sinks operational.

Replaying a trace with cargo rtic-scope replay

With a trace recorded we can now replay it offline for post-mortem analysis. All recorded traces can be listed via

$ cargo rtic-scope replay --list
0       /path/to/rtic-scope-atsame-example/target/rtic-traces/rtic-scope-atsame-example-gf7dd449-dirty-2022-03-21T11:16:31.trace

By use of the index on the left-hand side we replay the trace:

$ cargo rtic-scope replay 0
    Frontend dummy: @2000 ns (+2000 ns) [good]: [Task { name: "app::hardware", action: Entered }]
    Frontend dummy: @5750 ns (+3750 ns) [good]: [Task { name: "app::software", action: Entered }]
    Frontend dummy: @6167 ns (+417 ns) [good]: [Task { name: "app::software", action: Exited }]
    Frontend dummy: @6334 ns (+167 ns) [good]: [Task { name: "app::hardware", action: Returned }, Task { name: "app::hardware", action: Exited }]
    Replayed rtic-scope-atsame-example: 10 packets processed in 0s (~inf packets/s; 0 malformed, 0 non-mappable); 1/1 sinks operational.

A trace can also be selected via replay --trace-file /path/to/rtic-scope-atsame-example-*.trace.

Graphically plotting the recorded trace with the feat/auto-plot fork

An experimental fork of rtic-scope-frontend-dummy can plot the run-time of the two traces tasks using pandas and matplotlib.pyplot for Python 3:

$ cargo install --git https://github.com/rtic-scope/cargo-rtic-scope --branch feat/auto-plot rtic-scope-frontend-dummy
$ cargo rtic-scope replay 0

which produces the plot seen below, in which app::software preempts app::hardware:

Graphical representation of the recorded trace

Note that app::software does fake work for 100 ms:

#[trace]
#[task(priority = 2, local = [delay])]
fn software(ctx: software::Context) {
    ctx.local.delay.delay_ms(100_u8); // fake work
}

so the timestamps both in the plot and recorded trace is wildly incorrect. This discrepancy has yet to be investigated.


Related issue: #139.

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RTIC Scope application example on a Microchip ATSAME51N20A MCU running a trivial RTIC application

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