ZHCSG69E November 2016 – May 2018 DM505
PRODUCTION DATA.
The device has a large number of interrupts to service the needs of its many peripherals and subsystems. The DSP (x2), and IPU, and EVE subsystems are capable of servicing these interrupts via their integrated interrupt controllers. In addition, each processor's interrupt controller is preceded by an Interrupt Controller Crossbar (IRQ_CROSSBAR) that provides flexibility in mapping the device interrupts to processor interrupt inputs. For more information about IRQ crossbar, see chapter Control Module of the Device TRM.
C66x DSP Subsystem Interrupt Controller (DSPx_INTC, where x = 1, 2)
There are two Digital Signal Processing (DSP) subsystems in the device - DSP1, and DSP2. Each DSP subsystem integrates an interrupt controller - DSPx_INTC, which interfaces the system events to the C66x core interrupt and exceptions inputs. It combines up to 128 interrupts into 12 prioritized interrupts presented to the C66x CPU.
For detailed information about this module, see chapter DSP Subsystems of the Device TRM.
Dual Cortex-M4 IPU Subsystem Interrupt Controller (IPU_Cx_INTC, where x = 1, 2)
There is one Image Processing Unit (IPU) subsystem in the device. The IPU subsystem integrates two Arm® Cortex-M4 cores.
A Nested Vectored Interrupt Controller (NVIC) is integrated within each Cortex-M4. The interrupt mapping is the same for the two cores to facilitate parallel processing. The NVIC supports:
For detailed information about this module, refer to Arm Cortex-M4 Technical Reference Manual (available at infocenter.arm.com/help/index.jsp).
EVE Subsystem Interrupt Controller (EVE_INTC)
There is one Embedded Video Engine (EVE) subsystems in the device. The EVE subsystem integrates an interrupt controller - EVE_INTC, which handles incoming interrupts, merging them with internal interrupt sources to drive ARP32's interrupt inputs. It also allows ARP32 to generate outgoing interrupts or events to synchronize with other system processors and EDMA.
The EVE_INTC supports up to 32 active-high level interrupt inputs. Its architecture allows both hardware and software prioritization.
For detailed information about this module, see chapter Embedded Vision Engine of the Device TRM.