6.11 On-Chip Debug

Debugging a system that contains an embedded processor involves an environment that connects high-level debugging software running on a host computer to a low-level debug interface supported by the target device. Between these levels, a debug and trace controller (DTC) facilitates communication between the host debugger and the debug support logic on the target chip.

The DTC is a combination of hardware and software that connects the host debugger to the target system. The DTC uses one or more hardware interfaces and/or protocols to convert actions dictated by the debugger user to JTAG® commands and scans that execute the core hardware.

The debug software and hardware components let the user control multiple central processing unit (CPU) cores embedded in the device in a global or local manner. This environment provides:

• Synchronized global starting and stopping of multiple processors
• Starting and stopping of an individual processor
• Each processor can generate triggers that can be used to alter the execution flow of other processors

System topics include but are not limited to:

• System clocking and power-down issues
• Interconnection of multiple devices
• Trigger channels

The device deploys Texas Instrument's CTools debug technology for on-chip debug and trace support. It provides the following features:

• External debug interfaces:
  • Primary debug interface - IEEE1149.1 (JTAG) or IEEE1149.7 (complementary superset of JTAG)
    • Used for debugger connection
    • Default mode is IEEE1149.1 but debugger can switch to IEEE1149.7 via an IEEE1149.7 adapter module
    • Controls ICEPick™ (generic test access port [TAP] for dynamic TAP insertion) to allow the debugger to access several debug resources through its secondary (output) JTAG ports (for more information, see section ICEPick Secondary TAPs in chapter On-Chip Debug Support of the Device TRM).
  • Debug (trace) port
    • Can be used to export processor or system trace off-chip (to an external trace receiver)
    • Can be used for cross-triggering with an external device
    • Configured through debug resources manager (DRM) module instantiated in the debug subsystem
    • For more information about debug (trace) port, see sections Debug (Trace) Port and Concurrent Debug Modes in chapter On-Chip Debug Support of the Device TRM.
• JTAG based processor debug on:
  • C66x in DSP1, DSP2
  • Cortex-M4 (x2) in IPU
• Dynamic TAP insertion
  • Controlled by ICEPick
  • For more information, see section Dynamic TAP Insertion in chapter On-Chip Debug Support of the Device TRM
• Power and clock management
  • Debugger can get the status of the power domain associated to each TAP.
  • Debugger may prevent the application software switching off the power domain.
  • Application power management behavior can be preserved during debug across power transitions.
  • For more information, see section Power and Clock Management in chapter On-Chip Debug Support of the Device TRM.
• Reset management
  • Debugger can configure ICEPick to assert, block, or extend the reset of a given subsystem.
  • For more information, see section Reset Management in chapter On-Chip Debug Support of the Device TRM.
• Cross-triggering
  • Provides a way to propagate debug (trigger) events from one processor, subsystem, or module to another:
    • Subsystem A can be programmed to generate a debug event, which can then be exported as a global trigger across the device.
    • Subsystem B can be programmed to be sensitive to the trigger line input and to generate an action on trigger detection.
  • Two global trigger lines are implemented
  • Device-level cross-triggering is handled by the XTRIG (TI cross-trigger) module implemented in the debug subsystem
  • For more information about cross-triggering, see section Cross-Triggering in chapter On-Chip Debug Support of the Device TRM.
• Suspend
  • Provides a way to stop a closely coupled hardware process running on a peripheral module when the host processor enters debug state
  • For more information about suspend, see section Suspend in chapter On-Chip Debug Support of the Device TRM.
• Processor trace
  • C66x (DSP) processor trace is supported
  • Two exclusive trace sinks:
    • CoreSight Trace Port Interface Unit (CS_TPIU) – trace export to an external trace receiver
  • For more information, see section Processor Trace in chapter On-Chip Debug Support of the Device TRM.
• System instrumentation (trace)
  • Supported by a CTools System Trace Module (CT_STM), implementing MIPI System Trace Protocol (STP) (rev 2.0)
  • Real-time software trace
    • System-on-chip (SoC) software instrumentation through CT_STM (STP2.0)
  • OCP watchpoint (OCP_WP_NOC)
    • OCP target traffic monitoring: OCP_WP_NOC can be configured to generate a trigger upon watchpoint match (that is, when target transaction attributes match the user-defined attributes).
    • SoC events trace
    • DMA transfer profiling
  • Statistics collector (performance probes)
    • Computes traffic statistics within a user-defined window and periodically reports to the user through the CT_STM interface
    • Embedded in the L3_MAIN interconnect
    • 10 instances:
      • 1 instance dedicated to target (SDRAM) load monitoring
      • 9 instances dedicated to master latency monitoring
  • Power-management events profiling (PM instrumentation [PMI])
    • Monitoring major power-management events. The PM state changes are handled as generic events and encapsulated in STP messages.
  • Clock-management events profiling CM instrumentation [CMI]) for CM_CORE_AON clocks
    • Monitoring major clock management events. The CM state changes are handled as generic events and encapsulated in STP messages.
    • One instances
      • CM1 Instrumentation (CMI1) module mapped in the PD_CORE_AON power domain
  • For more information, see section System Instrumentation in chapter On-Chip Debug Support of the Device TRM.
• Performance monitoring
  • Supported by subsystem counter timer module (SCTM) for IPU

For more information, see chapter On-Chip Debug Support of the device TRM.