SPRUI30H November   2015  – May 2024 DRA745 , DRA746 , DRA750 , DRA756

 

  1.   1
  2.   Read This First
    1.     Support Resources
    2.     Glossary
    3.     About This Manual
    4.     Information About Cautions and Warnings
    5.     Register, Field, and Bit Calls
    6.     Coding Rules
    7.     Flow Chart Rules
    8.     Export Control Notice
    9.     DRA75x, DRA74x MIPI® Disclaimer
    10.     Trademarks
  3. Introduction
    1. 1.1 DRA75x, DRA74x Overview
    2. 1.2 DRA75x, DRA74x Environment
    3. 1.3 DRA75x, DRA74x Description
      1. 1.3.1  MPU Subsystem
      2. 1.3.2  DSP Subsystems
      3. 1.3.3  EVE Subsystems
      4. 1.3.4  IPU Subsystems
      5. 1.3.5  IVA-HD Subsystem
      6. 1.3.6  Display Subsystem
      7. 1.3.7  Video Processing Subsystem
      8. 1.3.8  Video Capture
      9. 1.3.9  3D GPU Subsystem
      10. 1.3.10 BB2D Subsystem
      11. 1.3.11 On-Chip Debug Support
      12. 1.3.12 Power, Reset, and Clock Management
      13. 1.3.13 On-Chip Memory
      14. 1.3.14 Memory Management
      15. 1.3.15 External Memory Interfaces
      16. 1.3.16 System and Connectivity Peripherals
        1. 1.3.16.1 System Peripherals
        2. 1.3.16.2 Media Connectivity Peripherals
        3. 1.3.16.3 Car Connectivity Peripherals
        4. 1.3.16.4 Audio Connectivity Peripherals
        5. 1.3.16.5 Serial Control Peripherals
        6. 1.3.16.6 Radio Accelerators
    4. 1.4 DRA75x, DRA74x Family
    5. 1.5 DRA75x, DRA74x Device Identification
    6. 1.6 DRA75x, DRA74x Package Characteristics Overview
  4. Memory Mapping
    1. 2.1 Introduction
    2. 2.2 L3_MAIN Memory Map
      1. 2.2.1 L3_INSTR Memory Map
    3. 2.3 L4 Memory Map
      1. 2.3.1 L4_CFG Memory Map
      2. 2.3.2 L4_WKUP Memory Map
    4. 2.4 L4_PER Memory Map
      1. 2.4.1 L4_PER1 Memory Space Mapping
      2. 2.4.2 L4_PER2 Memory Map
      3. 2.4.3 L4_PER3 Memory Map
    5. 2.5 MPU Memory Map
    6. 2.6 IPU Memory Map
    7. 2.7 DSP Memory Map
    8. 2.8 EVE Memory Map
    9. 2.9 TILER View Memory Map
  5. Power, Reset, and Clock Management
    1. 3.1  Device Power Management Introduction
      1. 3.1.1 Device Power-Management Architecture Building Blocks
        1. 3.1.1.1 Clock Management
          1. 3.1.1.1.1 Module Interface and Functional Clocks
          2. 3.1.1.1.2 63
          3. 3.1.1.1.3 Module-Level Clock Management
          4. 3.1.1.1.4 Clock Domain
          5. 3.1.1.1.5 Clock Domain-Level Clock Management
          6. 3.1.1.1.6 Clock Domain HW_AUTO Mode Sequences
          7. 3.1.1.1.7 Clock Domain Sleep/Wake-up
          8. 3.1.1.1.8 Clock Domain Dependency
            1. 3.1.1.1.8.1 Static Dependency
            2. 3.1.1.1.8.2 Dynamic Dependency
            3. 3.1.1.1.8.3 Wake-Up Dependency
        2. 3.1.1.2 Power Management
          1. 3.1.1.2.1 Power Domain
          2. 3.1.1.2.2 Module Logic and Memory Context
          3. 3.1.1.2.3 Power Domain Management
        3. 3.1.1.3 Voltage Management
          1. 3.1.1.3.1 Voltage Domain
          2. 3.1.1.3.2 Voltage Domain Management
          3. 3.1.1.3.3 AVS Overview
            1. 3.1.1.3.3.1 AVS Class 0 (SmartReflex™) Voltage Control
      2. 3.1.2 Power-Management Techniques
        1. 3.1.2.1 Standby Leakage Management
        2. 3.1.2.2 Dynamic Voltage and Frequency Scaling
        3. 3.1.2.3 Dynamic Power Switching
        4. 3.1.2.4 Adaptive Voltage Scaling
        5. 3.1.2.5 Adaptive Body Bias
        6. 3.1.2.6 SR3-APG (Automatic Power Gating)
        7. 3.1.2.7 Combining Power-Management Techniques
          1. 3.1.2.7.1 DPS Versus SLM
    2. 3.2  PRCM Subsystem Overview
      1. 3.2.1 Introduction
      2. 3.2.2 Power-Management Framework Features
    3. 3.3  PRCM Subsystem Environment
      1. 3.3.1 External Clock Signals
      2. 3.3.2 External Boot Signals
      3. 3.3.3 External Reset Signals
      4. 3.3.4 External Voltage Inputs
    4. 3.4  PRCM Subsystem Integration
      1. 3.4.1 Device Power-Management Layout
      2. 3.4.2 Power-Management Scheme, Reset, and Interrupt Requests
        1. 3.4.2.1 Power Domain
        2. 3.4.2.2 Resets
        3. 3.4.2.3 PRCM Interrupt Requests
        4. 3.4.2.4 105
    5. 3.5  Reset Management Functional Description
      1. 3.5.1 Overview
        1. 3.5.1.1 PRCM Reset Management Functional Description
          1. 3.5.1.1.1 Power-On Reset
          2. 3.5.1.1.2 Warm Reset
        2. 3.5.1.2 PRM Reset Management Functional Description
      2. 3.5.2 General Characteristics of Reset Signals
        1. 3.5.2.1 Scope
        2. 3.5.2.2 Occurrence
        3. 3.5.2.3 Source Type
        4. 3.5.2.4 Retention Type
      3. 3.5.3 Reset Sources
        1. 3.5.3.1 Global Reset Sources
        2. 3.5.3.2 Local Reset Sources
      4. 3.5.4 Reset Logging
      5. 3.5.5 Reset Domains
      6. 3.5.6 Reset Sequences
        1. 3.5.6.1  MPU Subsystem Power-On Reset Sequence
        2. 3.5.6.2  MPU Subsystem Warm Reset Sequence
        3. 3.5.6.3  MPU Subsystem Reset Sequence on Sleep and Wake-Up Transitions From RETENTION State
        4. 3.5.6.4  IVA Subsystem Power-On Reset Sequence
        5. 3.5.6.5  IVA Subsystem Software Warm Reset Sequence
        6. 3.5.6.6  DSP1 Subsystem Power-On Reset Sequence
        7. 3.5.6.7  DSP1 Subsystem Software Warm Reset Sequence
        8. 3.5.6.8  DSP2 Subsystem Power-On Reset Sequence
        9. 3.5.6.9  DSP2 Subsystem Software Warm Reset Sequence
        10. 3.5.6.10 IPU1 Subsystem Power-On Reset Sequence
        11. 3.5.6.11 IPU1 Subsystem Software Warm Reset Sequence
        12. 3.5.6.12 IPU2 Subsystem Power-On Reset Sequence
        13. 3.5.6.13 IPU2 Subsystem Software Warm Reset Sequence
        14. 3.5.6.14 EVE1 Subsystem Power-On Reset Sequence
        15. 3.5.6.15 EVE1 Subsystem Software Warm Reset Sequence
        16. 3.5.6.16 EVE2 Subsystem Power-On Reset Sequence
        17. 3.5.6.17 EVE2 Subsystem Software Warm Reset Sequence
        18. 3.5.6.18 Global Warm Reset Sequence
    6. 3.6  Clock Management Functional Description
      1. 3.6.1 Overview
      2. 3.6.2 External Clock Inputs
        1. 3.6.2.1 FUNC_32K_CLK Clock
        2. 3.6.2.2 High-Frequency System Clock Input
        3. 3.6.2.3 External Reference Clock Input
      3. 3.6.3 Internal Clock Sources and Generators
        1. 3.6.3.1  PRM Clock Source
        2. 3.6.3.2  CM Clock Source
          1. 3.6.3.2.1 CM_CORE_AON Clock Generator
          2. 3.6.3.2.2 CM_CORE_AON_CLKOUTMUX Overview
          3. 3.6.3.2.3 CM_CORE_AON_TIMER Overview
          4. 3.6.3.2.4 CM_CORE_AON_MCASP Overview
        3. 3.6.3.3  Generic DPLL Overview
          1. 3.6.3.3.1 Generic APLL Overview
          2. 3.6.3.3.2 DPLLs Output Clocks Parameters
          3. 3.6.3.3.3 Enable Control, Status, and Low-Power Operation Mode
          4. 3.6.3.3.4 DPLL Power Modes
          5. 3.6.3.3.5 DPLL Recalibration
          6. 3.6.3.3.6 DPLL Output Power Down
        4. 3.6.3.4  DPLL_PER Description
          1. 3.6.3.4.1 DPLL_PER Overview
          2. 3.6.3.4.2 DPLL_PER Synthesized Clock Parameters
          3. 3.6.3.4.3 DPLL_PER Power Modes
          4. 3.6.3.4.4 DPLL_PER Recalibration
        5. 3.6.3.5  DPLL_CORE Description
          1. 3.6.3.5.1 DPLL_CORE Overview
          2. 3.6.3.5.2 DPLL_CORE Synthesized Clock Parameters
          3. 3.6.3.5.3 DPLL_CORE Power Modes
          4. 3.6.3.5.4 DPLL_CORE Recalibration
        6. 3.6.3.6  DPLL_ABE Description
          1. 3.6.3.6.1 DPLL_ABE Overview
          2. 3.6.3.6.2 DPLL_ABE Synthesized Clock Parameters
          3. 3.6.3.6.3 DPLL_ABE Power Modes
          4. 3.6.3.6.4 DPLL_ABE Recalibration
        7. 3.6.3.7  DPLL_MPU Description
          1. 3.6.3.7.1 DPLL_MPU Overview
          2. 3.6.3.7.2 DPLL_MPU Tactical Clocking Adjustment
          3. 3.6.3.7.3 DPLL_MPU Synthesized Clock Parameters
          4. 3.6.3.7.4 DPLL_MPU Power Modes
          5. 3.6.3.7.5 DPLL_MPU Recalibration
        8. 3.6.3.8  DPLL_IVA Description
          1. 3.6.3.8.1 DPLL_IVA Overview
          2. 3.6.3.8.2 DPLL_IVA Synthesized Clock Parameters
          3. 3.6.3.8.3 DPLL_IVA Power Modes
          4. 3.6.3.8.4 DPLL_IVA Recalibration
        9. 3.6.3.9  DPLL_USB Description
          1. 3.6.3.9.1 DPLL_USB Overview
          2. 3.6.3.9.2 DPLL_USB Synthesized Clock Parameters
          3. 3.6.3.9.3 DPLL_USB Power Modes
          4. 3.6.3.9.4 DPLL_USB Recalibration
        10. 3.6.3.10 DPLL_EVE Description
          1. 3.6.3.10.1 DPLL_EVE Overview
          2. 3.6.3.10.2 DPLL_EVE Synthesized Clock Parameters
          3. 3.6.3.10.3 DPLL_EVE Power Modes
          4. 3.6.3.10.4 DPLL_EVE Recalibration
        11. 3.6.3.11 DPLL_DSP Description
          1. 3.6.3.11.1 DPLL_DSP Overview
          2. 3.6.3.11.2 DPLL_DSP Synthesized Clock Parameters
          3. 3.6.3.11.3 DPLL_DSP Power Modes
          4. 3.6.3.11.4 DPLL_DSP Recalibration
        12. 3.6.3.12 DPLL_GMAC Description
          1. 3.6.3.12.1 DPLL_GMAC Overview
          2. 3.6.3.12.2 DPLL_GMAC Synthesized Clock Parameters
          3. 3.6.3.12.3 DPLL_GMAC Power Modes
          4. 3.6.3.12.4 DPLL_GMAC Recalibration
        13. 3.6.3.13 DPLL_GPU Description
          1. 3.6.3.13.1 DPLL_GPU Overview
          2. 3.6.3.13.2 DPLL_GPU Synthesized Clock Parameters
          3. 3.6.3.13.3 DPLL_GPU Power Modes
          4. 3.6.3.13.4 DPLL_GPU Recalibration
        14. 3.6.3.14 DPLL_DDR Description
          1. 3.6.3.14.1 DPLL_DDR Overview
          2. 3.6.3.14.2 DPLL_DDR Synthesized Clock Parameters
          3. 3.6.3.14.3 DPLL_DDR Power Modes
          4. 3.6.3.14.4 DPLL_DDR Recalibration
        15. 3.6.3.15 DPLL_PCIE_REF Description
          1. 3.6.3.15.1 DPLL_PCIE_REF Overview
          2. 3.6.3.15.2 DPLL_PCIE_REF Synthesized Clock Parameters
          3. 3.6.3.15.3 DPLL_PCIE_REF Power Modes
        16. 3.6.3.16 APLL_PCIE Description
          1. 3.6.3.16.1 APLL_PCIE Overview
          2. 3.6.3.16.2 APLL_PCIE Synthesized Clock Parameters
          3. 3.6.3.16.3 APLL_PCIE Power Modes
      4. 3.6.4 Clock Domains
        1. 3.6.4.1  CD_WKUPAON Clock Domain
          1. 3.6.4.1.1 Overview
          2. 3.6.4.1.2 Clock Domain Modes
          3. 3.6.4.1.3 Clock Domain Dependency
            1. 3.6.4.1.3.1 Wake-Up Dependency
          4. 3.6.4.1.4 Clock Domain Module Attributes
        2. 3.6.4.2  CD_DSP1 Clock Domain
          1. 3.6.4.2.1 Overview
          2. 3.6.4.2.2 Clock Domain Modes
          3. 3.6.4.2.3 Clock Domain Dependency
            1. 3.6.4.2.3.1 Static Dependency
            2. 3.6.4.2.3.2 Dynamic Dependency
          4. 3.6.4.2.4 Clock Domain Module Attributes
        3. 3.6.4.3  CD_DSP2 Clock Domain
          1. 3.6.4.3.1 Overview
          2. 3.6.4.3.2 Clock Domain Modes
          3. 3.6.4.3.3 Clock Domain Dependency
            1. 3.6.4.3.3.1 Static Dependency
            2. 3.6.4.3.3.2 Dynamic Dependency
          4. 3.6.4.3.4 Clock Domain Module Attributes
        4. 3.6.4.4  CD_CUSTEFUSE Clock Domain
          1. 3.6.4.4.1 Overview
          2. 3.6.4.4.2 Clock Domain Modes
          3. 3.6.4.4.3 Clock Domain Dependency
          4. 3.6.4.4.4 Clock Domain Module Attributes
        5. 3.6.4.5  CD_MPU Clock Domain
          1. 3.6.4.5.1 Overview
          2. 3.6.4.5.2 Clock Domain Modes
          3. 3.6.4.5.3 Clock Domain Dependency
            1. 3.6.4.5.3.1 Static Dependency
            2. 3.6.4.5.3.2 Dynamic Dependency
          4. 3.6.4.5.4 Clock Domain Module Attributes
        6. 3.6.4.6  CD_L4PER1 Clock Domain
          1. 3.6.4.6.1 Overview
          2. 3.6.4.6.2 Clock Domain Modes
          3. 3.6.4.6.3 Clock Domain Dependency
            1. 3.6.4.6.3.1 Dynamic Dependency
            2. 3.6.4.6.3.2 Wake-Up Dependency
          4. 3.6.4.6.4 Clock Domain Module Attributes
        7. 3.6.4.7  CD_L4PER2 Clock Domain
          1. 3.6.4.7.1 Overview
          2. 3.6.4.7.2 Clock Domain Modes
          3. 3.6.4.7.3 Clock Domain Dependency
            1. 3.6.4.7.3.1 Dynamic Dependency
            2. 3.6.4.7.3.2 Wake-Up Dependency
          4. 3.6.4.7.4 Clock Domain Module Attributes
        8. 3.6.4.8  CD_L4PER3 Clock Domain
          1. 3.6.4.8.1 Overview
          2. 3.6.4.8.2 Clock Domain Modes
          3. 3.6.4.8.3 Clock Domain Dependency
            1. 3.6.4.8.3.1 Dynamic Dependency
            2. 3.6.4.8.3.2 Wake-Up Dependency
          4. 3.6.4.8.4 Clock Domain Module Attributes
        9. 3.6.4.9  CD_L4SEC Clock Domain
          1. 3.6.4.9.1 Overview
          2. 3.6.4.9.2 Clock Domain Modes
          3. 3.6.4.9.3 Clock Domain Dependency
            1. 3.6.4.9.3.1 Static Dependency
            2. 3.6.4.9.3.2 Dynamic Dependency
          4. 3.6.4.9.4 Clock Domain Module Attributes
          5. 3.6.4.9.5 286
        10. 3.6.4.10 CD_L3INIT Clock Domain
          1. 3.6.4.10.1 Overview
          2. 3.6.4.10.2 Clock Domain Modes
          3. 3.6.4.10.3 Clock Domain Dependency
            1. 3.6.4.10.3.1 Static Dependency
            2. 3.6.4.10.3.2 Dynamic Dependency
            3. 3.6.4.10.3.3 Wake-Up Dependency
          4. 3.6.4.10.4 Clock Domain Module Attributes
        11. 3.6.4.11 CD_IVA Clock Domain
          1. 3.6.4.11.1 Overview
          2. 3.6.4.11.2 Clock Domain Modes
          3. 3.6.4.11.3 Clock Domain Dependency
            1. 3.6.4.11.3.1 Static Dependency
            2. 3.6.4.11.3.2 Dynamic Dependency
          4. 3.6.4.11.4 Clock Domain Module Attributes
        12. 3.6.4.12 CD_GPU Description
          1. 3.6.4.12.1 Overview
          2. 3.6.4.12.2 Clock Domain Modes
          3. 3.6.4.12.3 Clock Domain Dependency
            1. 3.6.4.12.3.1 Static Dependency
            2. 3.6.4.12.3.2 Dynamic Dependency
          4. 3.6.4.12.4 Clock Domain Module Attributes
        13. 3.6.4.13 CD_EMU Clock Domain
          1. 3.6.4.13.1 Overview
          2. 3.6.4.13.2 Clock Domain Modes
          3. 3.6.4.13.3 Clock Domain Dependency
            1. 3.6.4.13.3.1 Dynamic Dependency
          4. 3.6.4.13.4 Clock Domain Module Attributes
        14. 3.6.4.14 CD_DSS Clock Domain
          1. 3.6.4.14.1 Overview
          2. 3.6.4.14.2 Clock Domain Modes
          3. 3.6.4.14.3 Clock Domain Dependency
            1. 3.6.4.14.3.1 Static Dependency
            2. 3.6.4.14.3.2 Dynamic Dependency
            3. 3.6.4.14.3.3 Wake-Up Dependency
          4. 3.6.4.14.4 Clock Domain Module Attributes
        15. 3.6.4.15 CD_L4_CFG Clock Domain
          1. 3.6.4.15.1 Overview
          2. 3.6.4.15.2 Clock Domain Modes
          3. 3.6.4.15.3 Clock Domain Dependency
            1. 3.6.4.15.3.1 Dynamic Dependency
          4. 3.6.4.15.4 Clock Domain Module Attributes
        16. 3.6.4.16 CD_L3_INSTR Clock Domain
          1. 3.6.4.16.1 Overview
          2. 3.6.4.16.2 Clock Domain Modes
          3. 3.6.4.16.3 Clock Domain Dependency
          4. 3.6.4.16.4 Clock Domain Module Attributes
        17. 3.6.4.17 CD_L3_MAIN1 Clock Domain
          1. 3.6.4.17.1 Overview
          2. 3.6.4.17.2 Clock Domain Modes
          3. 3.6.4.17.3 Clock Domain Dependency
            1. 3.6.4.17.3.1 Dynamic Dependency
          4. 3.6.4.17.4 Clock Domain Module Attributes
        18. 3.6.4.18 CD_EMIF Clock Domain
          1. 3.6.4.18.1 Overview
          2. 3.6.4.18.2 Clock Domain Modes
          3. 3.6.4.18.3 Clock Domain Dependency
          4. 3.6.4.18.4 Clock Domain Module Attributes
        19. 3.6.4.19 CD_IPU Clock Domain
          1. 3.6.4.19.1 Overview
          2. 3.6.4.19.2 Clock Domain Modes
          3. 3.6.4.19.3 Clock Domain Dependency
            1. 3.6.4.19.3.1 Static Dependency
            2. 3.6.4.19.3.2 Dynamic Dependency
          4. 3.6.4.19.4 Clock Domain Module Attributes
        20. 3.6.4.20 CD_IPU1 Clock Domain
          1. 3.6.4.20.1 Overview
          2. 3.6.4.20.2 Clock Domain Modes
          3. 3.6.4.20.3 Clock Domain Dependency
            1. 3.6.4.20.3.1 Static Dependency
            2. 3.6.4.20.3.2 Dynamic Dependency
          4. 3.6.4.20.4 Clock Domain Module Attributes
        21. 3.6.4.21 CD_IPU2 Clock Domain
          1. 3.6.4.21.1 Overview
          2. 3.6.4.21.2 Clock Domain Modes
          3. 3.6.4.21.3 Clock Domain Dependency
            1. 3.6.4.21.3.1 Static Dependency
            2. 3.6.4.21.3.2 Dynamic Dependency
          4. 3.6.4.21.4 Clock Domain Module Attributes
        22. 3.6.4.22 CD_DMA Clock Domain
          1. 3.6.4.22.1 Overview
          2. 3.6.4.22.2 Clock Domain Modes
          3. 3.6.4.22.3 Clock Domain Dependency
            1. 3.6.4.22.3.1 Static Dependency
            2. 3.6.4.22.3.2 Dynamic Dependency
          4. 3.6.4.22.4 Clock Domain Module Attributes
        23. 3.6.4.23 CD_ATL Clock Domain
          1. 3.6.4.23.1 Overview
          2. 3.6.4.23.2 Clock Domain Modes
          3. 3.6.4.23.3 Clock Domain Module Attributes
        24. 3.6.4.24 CD_CAM Clock Domain
          1. 3.6.4.24.1 Overview
          2. 3.6.4.24.2 Clock Domain Modes
          3. 3.6.4.24.3 Clock Domain Dependency
            1. 3.6.4.24.3.1 Static Dependency
            2. 3.6.4.24.3.2 Dynamic Dependency
          4. 3.6.4.24.4 Clock Domain Module Attributes
          5. 3.6.4.24.5 384
        25. 3.6.4.25 CD_GMAC Clock Domain
          1. 3.6.4.25.1 Overview
          2. 3.6.4.25.2 Clock Domain Modes
          3. 3.6.4.25.3 Clock Domain Dependency
            1. 3.6.4.25.3.1 Static Dependency
            2. 3.6.4.25.3.2 Dynamic Dependency
          4. 3.6.4.25.4 Clock Domain Module Attributes
        26. 3.6.4.26 CD_VPE Clock Domain
          1. 3.6.4.26.1 CD_VPE Overview
          2. 3.6.4.26.2 Clock Domain Modes
          3. 3.6.4.26.3 Clock Domain Dependency
            1. 3.6.4.26.3.1 Wake-Up Dependency
          4. 3.6.4.26.4 Clock Domain Module Attributes
        27. 3.6.4.27 CD_EVE1 Clock Domain
          1. 3.6.4.27.1 CD_EVE1 Overview
          2. 3.6.4.27.2 Clock Domain Modes
          3. 3.6.4.27.3 Clock Domain Dependency
            1. 3.6.4.27.3.1 Wake-Up Dependency
          4. 3.6.4.27.4 Clock Domain Module Attributes
        28. 3.6.4.28 CD_EVE2 Clock Domain
          1. 3.6.4.28.1 CD_EVE2 Overview
          2. 3.6.4.28.2 Clock Domain Modes
          3. 3.6.4.28.3 Clock Domain Dependency
            1. 3.6.4.28.3.1 Wake-Up Dependency
          4. 3.6.4.28.4 Clock Domain Module Attributes
        29. 3.6.4.29 CD_RTC Clock Domain
          1. 3.6.4.29.1 CD_RTC Overview
          2. 3.6.4.29.2 Clock Domain Modes
          3. 3.6.4.29.3 Clock Domain Dependency
            1. 3.6.4.29.3.1 Wake-Up Dependency
          4. 3.6.4.29.4 Clock Domain Module Attributes
        30. 3.6.4.30 CD_PCIE Clock Domain
          1. 3.6.4.30.1 CD_PCIE Overview
          2. 3.6.4.30.2 Clock Domain Modes
          3. 3.6.4.30.3 Clock Domain Dependency
            1. 3.6.4.30.3.1 Wake-Up Dependency
          4. 3.6.4.30.4 Clock Domain Module Attributes
    7. 3.7  Power Management Functional Description
      1. 3.7.1  PD_WKUPAON Description
        1. 3.7.1.1 Power Domain Modes
          1. 3.7.1.1.1 Logic and Memory Area Power Modes
      2. 3.7.2  PD_DSP1 Description
        1. 3.7.2.1 Power Domain Modes
          1. 3.7.2.1.1 Logic and Memory Area Power Modes
          2. 3.7.2.1.2 Logic and Memory Area Power Modes Control and Status
      3. 3.7.3  PD_DSP2 Description
        1. 3.7.3.1 Power Domain Modes
          1. 3.7.3.1.1 Logic and Memory Area Power Modes
          2. 3.7.3.1.2 Logic and Memory Area Power Modes Control and Status
      4. 3.7.4  PD_CUSTEFUSE Description
        1. 3.7.4.1 Power Domain Modes
          1. 3.7.4.1.1 Logic and Memory Area Power Modes
          2. 3.7.4.1.2 Logic and Memory Area Power Modes Control and Status
      5. 3.7.5  PD_MPU Description
        1. 3.7.5.1 Power Domain Modes
          1. 3.7.5.1.1 Logic and Memory Area Power Modes
          2. 3.7.5.1.2 Logic and Memory Area Power Modes Control and Status
          3. 3.7.5.1.3 Power State Override
      6. 3.7.6  PD_IPU Description
        1. 3.7.6.1 Power Domain Modes
          1. 3.7.6.1.1 Logic and Memory Area Power Modes
          2. 3.7.6.1.2 Logic and Memory Area Power Modes Control and Status
      7. 3.7.7  PD_L3INIT Description
        1. 3.7.7.1 Power Domain Modes
          1. 3.7.7.1.1 Logic and Memory Area Power Modes
          2. 3.7.7.1.2 Logic and Memory Area Power Modes Control and Status
      8. 3.7.8  PD_L4PER Description
        1. 3.7.8.1 Power Domain Modes
          1. 3.7.8.1.1 Logic and Memory Area Power Modes
          2. 3.7.8.1.2 Logic and Memory Area Power Modes Control and Status
      9. 3.7.9  PD_IVA Description
        1. 3.7.9.1 Power Domain Modes
          1. 3.7.9.1.1 Logic and Memory Area Power Modes
          2. 3.7.9.1.2 Logic and Memory Area Power Modes Control and Status
      10. 3.7.10 PD_GPU Description
        1. 3.7.10.1 Power Domain Modes
          1. 3.7.10.1.1 Logic and Memory Area Power Modes
          2. 3.7.10.1.2 Logic and Memory Area Power Modes Control and Status
      11. 3.7.11 PD_EMU Description
        1. 3.7.11.1 Power Domain Modes
          1. 3.7.11.1.1 Logic and Memory Area Power Modes
          2. 3.7.11.1.2 Logic and Memory Area Power Modes Control and Status
      12. 3.7.12 PD_DSS Description
        1. 3.7.12.1 Power Domain Modes
          1. 3.7.12.1.1 Logic and Memory Area Power Modes
          2. 3.7.12.1.2 Logic and Memory Area Power Mode Control and Status
      13. 3.7.13 PD_CORE Description
        1. 3.7.13.1 Power Domain Modes
          1. 3.7.13.1.1 Logic and Memory Area Power Modes
          2. 3.7.13.1.2 Logic and Memory Area Power Mode Control and Status
      14. 3.7.14 PD_CAM Description
        1. 3.7.14.1 Power Domain Modes
          1. 3.7.14.1.1 Logic and Memory Area Power Modes
          2. 3.7.14.1.2 Logic and Memory Area Power Mode Control and Status
      15. 3.7.15 PD_MPUAON Description
        1. 3.7.15.1 Power Domain Modes
      16. 3.7.16 PD_MMAON Description
        1. 3.7.16.1 Power Domain Modes
      17. 3.7.17 PD_COREAON Description
        1. 3.7.17.1 Power Domain Modes
      18. 3.7.18 PD_VPE Description
        1. 3.7.18.1 Power Domain Modes
          1. 3.7.18.1.1 Logic and Memory Area Power Modes
          2. 3.7.18.1.2 Logic and Memory Area Power Modes Control and Status
      19. 3.7.19 PD_EVE1 Description
        1. 3.7.19.1 Power Domain Modes
          1. 3.7.19.1.1 Logic and Memory Area Power Modes
          2. 3.7.19.1.2 Logic and Memory Area Power Modes Control and Status
      20. 3.7.20 PD_EVE2 Description
        1. 3.7.20.1 Power Domain Modes
          1. 3.7.20.1.1 Logic and Memory Area Power Modes
          2. 3.7.20.1.2 Logic and Memory Area Power Modes Control and Status
      21. 3.7.21 PD_RTC Description
        1. 3.7.21.1 Power Domain Modes
          1. 3.7.21.1.1 Logic and Memory Area Power Modes
    8. 3.8  Voltage-Management Functional Description
      1. 3.8.1 Overview
      2. 3.8.2 Voltage-Control Architecture
      3. 3.8.3 Internal LDOs Control
        1. 3.8.3.1 VDD_MPU_L, VDD_CORE_L, and VDD_IVAHD_L, VDD_GPU_L, VDD_DSPEVE_L Control
          1. 3.8.3.1.1 Adaptive Voltage Scaling
            1. 3.8.3.1.1.1 SmartReflex in the Device
        2. 3.8.3.2 Memory LDOs
        3. 3.8.3.3 ABB LDOs Control
        4. 3.8.3.4 ABB LDO Programming Sequence
          1. 3.8.3.4.1 ABB LDO Enable Sequence
          2. 3.8.3.4.2 ABB LDO Disable Sequence (Entering in Bypass Mode)
        5. 3.8.3.5 BANDGAPs Control
      4. 3.8.4 DVFS
    9. 3.9  Device Low-Power States
      1. 3.9.1 Device Wake-Up Source Summary
      2. 3.9.2 Wakeup Upon Global Warm Reset
      3. 3.9.3 Global Warm Reset During a Device Wake-Up Sequence
      4. 3.9.4 I/O Management
        1. 3.9.4.1 Isolation / Wakeup Sequence
          1. 3.9.4.1.1 Software-Controlled I/O Isolation
    10. 3.10 PRCM Module Programming Guide
      1. 3.10.1 DPLLs Low-Level Programming Models
        1. 3.10.1.1 Global Initialization
          1. 3.10.1.1.1 Surrounding Module Global Initialization
          2. 3.10.1.1.2 DPLL Global Initialization
            1. 3.10.1.1.2.1 Main Sequence – DPLL Global Initialization
            2. 3.10.1.1.2.2 Subsequence – Recalibration Parameter Configuration
            3. 3.10.1.1.2.3 Subsequence – Synthesized Clock Parameter Configuration
            4. 3.10.1.1.2.4 Subsequence – Output Clock Parameter Configuration
        2. 3.10.1.2 DPLL Output Frequency Change
      2. 3.10.2 Clock Management Low-Level Programming Models
        1. 3.10.2.1 Global Initialization
          1. 3.10.2.1.1 Surrounding Module Global Initialization
          2. 3.10.2.1.2 Clock Management Global Initialization
            1. 3.10.2.1.2.1 Main Sequence – Clock Domain Global Initialization
            2. 3.10.2.1.2.2 Subsequence – Slave Module Clock-Management Parameters Configuration
        2. 3.10.2.2 Clock Domain Sleep Transition and Troubleshooting
        3. 3.10.2.3 Enable/Disable Software-Programmable Static Dependency
      3. 3.10.3 Power Management Low-Level Programming Models
        1. 3.10.3.1 Global Initialization
          1. 3.10.3.1.1 Surrounding Module Global Initialization
          2. 3.10.3.1.2 Power Management Global Initialization
            1. 3.10.3.1.2.1 Main Sequence – Power Domain Global Initialization and Setting
        2. 3.10.3.2 Forced Memory Area State Change With Power Domain ON
        3. 3.10.3.3 Forced Power Domain Low-Power State Transition
    11. 3.11 546
    12. 3.12 PRCM Software Configuration for OPP_PLUS
    13. 3.13 PRCM Register Manual
      1. 3.13.1  PRCM Instance Summary
      2. 3.13.2  CM_CORE_AON__CKGEN Registers
        1. 3.13.2.1 CM_CORE_AON__CKGEN Register Summary
        2. 3.13.2.2 CM_CORE_AON__CKGEN Register Description
      3. 3.13.3  CM_CORE_AON__DSP1 Registers
        1. 3.13.3.1 CM_CORE_AON__DSP1 Register Summary
        2. 3.13.3.2 CM_CORE_AON__DSP1 Register Description
      4. 3.13.4  CM_CORE_AON__DSP2 Registers
        1. 3.13.4.1 CM_CORE_AON__DSP2 Register Summary
        2. 3.13.4.2 CM_CORE_AON__DSP2 Register Description
      5. 3.13.5  CM_CORE_AON__EVE1 Registers
        1. 3.13.5.1 CM_CORE_AON__EVE1 Register Summary
        2. 3.13.5.2 CM_CORE_AON__EVE1 Register Description
      6. 3.13.6  CM_CORE_AON__EVE2 Registers
        1. 3.13.6.1 CM_CORE_AON__EVE2 Register Summary
        2. 3.13.6.2 CM_CORE_AON__EVE2 Register Description
      7. 3.13.7  CM_CORE_AON__INSTR Registers
        1. 3.13.7.1 CM_CORE_AON__INSTR Register Summary
        2. 3.13.7.2 CM_CORE_AON__INSTR Register Description
      8. 3.13.8  CM_CORE_AON__IPU Registers
        1. 3.13.8.1 CM_CORE_AON__IPU Register Summary
        2. 3.13.8.2 CM_CORE_AON__IPU Register Description
      9. 3.13.9  CM_CORE_AON__MPU Registers
        1. 3.13.9.1 CM_CORE_AON__MPU Register Summary
        2. 3.13.9.2 CM_CORE_AON__MPU Register Description
      10. 3.13.10 CM_CORE_AON__OCP_SOCKET Registers
        1. 3.13.10.1 CM_CORE_AON__OCP_SOCKET Register Summary
        2. 3.13.10.2 CM_CORE_AON__OCP_SOCKET Register Description
      11. 3.13.11 CM_CORE_AON__RESTORE Registers
        1. 3.13.11.1 CM_CORE_AON__RESTORE Register Summary
        2. 3.13.11.2 CM_CORE_AON__RESTORE Register Description
      12. 3.13.12 CM_CORE_AON__RTC Registers
        1. 3.13.12.1 CM_CORE_AON__RTC Register Summary
        2. 3.13.12.2 CM_CORE_AON__RTC Register Description
      13. 3.13.13 CM_CORE_AON__VPE Registers
        1. 3.13.13.1 CM_CORE_AON__VPE Register Summary
        2. 3.13.13.2 CM_CORE_AON__VPE Register Description
      14. 3.13.14 CM_CORE__CAM Registers
        1. 3.13.14.1 CM_CORE__CAM Register Summary
        2. 3.13.14.2 CM_CORE__CAM Register Description
      15. 3.13.15 CM_CORE__CKGEN Registers
        1. 3.13.15.1 CM_CORE__CKGEN Register Summary
        2. 3.13.15.2 CM_CORE__CKGEN Register Description
      16. 3.13.16 CM_CORE__COREAON Registers
        1. 3.13.16.1 CM_CORE__COREAON Register Summary
        2. 3.13.16.2 CM_CORE__COREAON Register Description
      17. 3.13.17 CM_CORE__CORE Registers
        1. 3.13.17.1 CM_CORE__CORE Register Summary
        2. 3.13.17.2 CM_CORE__CORE Register Description
      18. 3.13.18 CM_CORE__CUSTEFUSE Registers
        1. 3.13.18.1 CM_CORE__CUSTEFUSE Register Summary
        2. 3.13.18.2 CM_CORE__CUSTEFUSE Register Description
      19. 3.13.19 CM_CORE__DSS Registers
        1. 3.13.19.1 CM_CORE__DSS Register Summary
        2. 3.13.19.2 CM_CORE__DSS Register Description
      20. 3.13.20 CM_CORE__GPU Registers
        1. 3.13.20.1 CM_CORE__GPU Register Summary
        2. 3.13.20.2 CM_CORE__GPU Register Description
      21. 3.13.21 CM_CORE__IVA Registers
        1. 3.13.21.1 CM_CORE__IVA Register Summary
        2. 3.13.21.2 CM_CORE__IVA Register Description
      22. 3.13.22 CM_CORE__L3INIT Registers
        1. 3.13.22.1 CM_CORE__L3INIT Register Summary
        2. 3.13.22.2 CM_CORE__L3INIT Register Description
      23. 3.13.23 CM_CORE__L4PER Registers
        1. 3.13.23.1 CM_CORE__L4PER Register Summary
        2. 3.13.23.2 CM_CORE__L4PER Register Description
      24. 3.13.24 CM_CORE__OCP_SOCKET Registers
        1. 3.13.24.1 CM_CORE__OCP_SOCKET Register Summary
        2. 3.13.24.2 CM_CORE__OCP_SOCKET Register Description
      25. 3.13.25 CM_CORE__RESTORE Registers
        1. 3.13.25.1 CM_CORE__RESTORE Register Summary
        2. 3.13.25.2 CM_CORE__RESTORE Register Description
      26. 3.13.26 CAM_PRM Registers
        1. 3.13.26.1 CAM_PRM Register Summary
        2. 3.13.26.2 CAM_PRM Register Description
      27. 3.13.27 CKGEN_PRM Registers
        1. 3.13.27.1 CKGEN_PRM Register Summary
        2. 3.13.27.2 CKGEN_PRM Register Description
      28. 3.13.28 CORE_PRM Registers
        1. 3.13.28.1 CORE_PRM Register Summary
        2. 3.13.28.2 CORE_PRM Register Description
      29. 3.13.29 CUSTEFUSE_PRM Registers
        1. 3.13.29.1 CUSTEFUSE_PRM Register Summary
        2. 3.13.29.2 CUSTEFUSE_PRM Register Description
      30. 3.13.30 DEVICE_PRM Registers
        1. 3.13.30.1 DEVICE_PRM Register Summary
        2. 3.13.30.2 DEVICE_PRM Register Description
      31. 3.13.31 DSP1_PRM Registers
        1. 3.13.31.1 DSP1_PRM Register Summary
        2. 3.13.31.2 DSP1_PRM Register Description
      32. 3.13.32 DSP2_PRM Registers
        1. 3.13.32.1 DSP2_PRM Register Summary
        2. 3.13.32.2 DSP2_PRM Register Description
      33. 3.13.33 DSS_PRM Registers
        1. 3.13.33.1 DSS_PRM Register Summary
        2. 3.13.33.2 DSS_PRM Register Description
      34. 3.13.34 EMU_CM Registers
        1. 3.13.34.1 EMU_CM Register Summary
        2. 3.13.34.2 EMU_CM Register Description
      35. 3.13.35 EMU_PRM Registers
        1. 3.13.35.1 EMU_PRM Register Summary
        2. 3.13.35.2 EMU_PRM Register Description
      36. 3.13.36 EVE1_PRM Registers
        1. 3.13.36.1 EVE1_PRM Register Summary
        2. 3.13.36.2 EVE1_PRM Register Description
      37. 3.13.37 EVE2_PRM Registers
        1. 3.13.37.1 EVE2_PRM Register Summary
        2. 3.13.37.2 EVE2_PRM Register Description
      38. 3.13.38 GPU_PRM Registers
        1. 3.13.38.1 GPU_PRM Register Summary
        2. 3.13.38.2 GPU_PRM Register Description
      39. 3.13.39 INSTR_PRM Registers
        1. 3.13.39.1 INSTR_PRM Register Summary
        2. 3.13.39.2 INSTR_PRM Register Description
      40. 3.13.40 IPU_PRM Registers
        1. 3.13.40.1 IPU_PRM Register Summary
        2. 3.13.40.2 IPU_PRM Register Description
      41. 3.13.41 IVA_PRM Registers
        1. 3.13.41.1 IVA_PRM Register Summary
        2. 3.13.41.2 IVA_PRM Register Description
      42. 3.13.42 L3INIT_PRM Registers
        1. 3.13.42.1 L3INIT_PRM Register Summary
        2. 3.13.42.2 L3INIT_PRM Register Description
      43. 3.13.43 L4PER_PRM Registers
        1. 3.13.43.1 L4PER_PRM Register Summary
        2. 3.13.43.2 L4PER_PRM Register Description
      44. 3.13.44 MPU_PRM Registers
        1. 3.13.44.1 MPU_PRM Register Summary
        2. 3.13.44.2 MPU_PRM Register Description
      45. 3.13.45 OCP_SOCKET_PRM Registers
        1. 3.13.45.1 OCP_SOCKET_PRM Register Summary
        2. 3.13.45.2 OCP_SOCKET_PRM Register Description
      46. 3.13.46 RTC_PRM Registers
        1. 3.13.46.1 RTC_PRM Register Summary
        2. 3.13.46.2 RTC_PRM Register Description
      47. 3.13.47 VPE_PRM Registers
        1. 3.13.47.1 VPE_PRM Register Summary
        2. 3.13.47.2 VPE_PRM Register Description
      48. 3.13.48 WKUPAON_CM Registers
        1. 3.13.48.1 WKUPAON_CM Register Summary
        2. 3.13.48.2 WKUPAON_CM Register Description
      49. 3.13.49 WKUPAON_PRM Registers
        1. 3.13.49.1 WKUPAON_PRM Register Summary
        2. 3.13.49.2 WKUPAON_PRM Register Description
  6. Dual Cortex-A15 MPU Subsystem
    1. 4.1 Dual Cortex-A15 MPU Subsystem Overview
      1. 4.1.1 Introduction
      2. 4.1.2 Features
    2. 4.2 Dual Cortex-A15 MPU Subsystem Integration
      1. 4.2.1 Clock Distribution
      2. 4.2.2 Reset Distribution
    3. 4.3 Dual Cortex-A15 MPU Subsystem Functional Description
      1. 4.3.1 MPU Subsystem Block Diagram
      2. 4.3.2 Cortex-A15 MPCore (MPU_CLUSTER)
        1. 4.3.2.1 MPU L2 Cache Memory System
          1. 4.3.2.1.1 MPU L2 Cache Architecture
          2. 4.3.2.1.2 MPU L2 Cache Controller
          3. 4.3.2.1.3 707
      3. 4.3.3 MPU_AXI2OCP
      4. 4.3.4 Memory Adapter
        1. 4.3.4.1 MPU_MA Overview
        2. 4.3.4.2 AXI Input Interface
        3. 4.3.4.3 Interleaving
          1. 4.3.4.3.1 High-Order Fixed Interleaving Model
          2. 4.3.4.3.2 Lower 2-GiB Programmable Interleaving Model
          3. 4.3.4.3.3 Local Interconnect and Synchronization Agent (LISA) Section Manager
          4. 4.3.4.3.4 MA_LSM Registers
          5. 4.3.4.3.5 Posted and Nonposted Writes
          6. 4.3.4.3.6 Errors
        4. 4.3.4.4 Statistics Collector Probe Ports
        5. 4.3.4.5 MPU_MA Firewall
        6. 4.3.4.6 MPU_MA Power and Reset Management
        7. 4.3.4.7 MPU_MA Watchpoint
          1. 4.3.4.7.1 Watchpoint Types
          2. 4.3.4.7.2 Transaction Filtering Options
          3. 4.3.4.7.3 Transaction Match Effects
          4. 4.3.4.7.4 Trigger Generation
          5. 4.3.4.7.5 Programming Options Summary
      5. 4.3.5 Realtime Counter (Master Counter)
        1. 4.3.5.1 Counter Operation
        2. 4.3.5.2 Frequency Change Procedure
      6. 4.3.6 MPU Watchdog Timer
      7. 4.3.7 MPU Subsystem Power Management
        1. 4.3.7.1 Power Domains
        2. 4.3.7.2 Power States of MPU_Cx
        3. 4.3.7.3 Power States of MPU Subsystem
        4. 4.3.7.4 MPU_WUGEN
        5. 4.3.7.5 Power Transition Sequence
        6. 4.3.7.6 SR3-APG Technology Fail-Safe Mode
      8. 4.3.8 MPU Subsystem AMBA Interface Configuration
    4. 4.4 Dual Cortex-A15 MPU Subsystem Register Manual
      1. 4.4.1  Dual Cortex-A15 MPU Subsystem Instance Summary
      2. 4.4.2  MPU_CS_STM Registers
      3. 4.4.3  MPU_INTC Registers
      4. 4.4.4  MPU_PRCM_OCP_SOCKET Registers
        1. 4.4.4.1 MPU_PRCM_OCP_SOCKET Register Summary
        2. 4.4.4.2 MPU_PRCM_OCP_SOCKET Register Description
      5. 4.4.5  MPU_PRCM_DEVICE Registers
        1. 4.4.5.1 MPU_PRCM_DEVICE Register Summary
        2. 4.4.5.2 MPU_PRCM_DEVICE Register Description
      6. 4.4.6  MPU_PRCM_PRM_C0 Registers
        1. 4.4.6.1 MPU_PRCM_PRM_C0 Register Summary
        2. 4.4.6.2 MPU_PRCM_PRM_C0 Register Description
      7. 4.4.7  MPU_PRCM_CM_C0 Registers
        1. 4.4.7.1 MPU_PRCM_CM_C0 Register Summary
        2. 4.4.7.2 MPU_PRCM_CM_C0 Register Description
      8. 4.4.8  MPU_PRCM_PRM_C1 Registers
        1. 4.4.8.1 MPU_PRCM_PRM_C1 Register Summary
        2. 4.4.8.2 MPU_PRCM_PRM_C1 Register Description
      9. 4.4.9  MPU_PRCM_CM_C1 Registers
        1. 4.4.9.1 MPU_PRCM_CM_C1 Register Summary
        2. 4.4.9.2 MPU_PRCM_CM_C1 Register Description
      10. 4.4.10 MPU_WUGEN Registers
        1. 4.4.10.1 MPU_WUGEN Register Summary
        2. 4.4.10.2 MPU_WUGEN Register Description
      11. 4.4.11 MPU_WD_TIMER Registers
        1. 4.4.11.1 MPU_WD_TIMER Register Summary
        2. 4.4.11.2 MPU_WD_TIMER Register Description
      12. 4.4.12 MPU_AXI2OCP_MISC Registers
        1. 4.4.12.1 MPU_AXI2OCP_MISC Register Summary
        2. 4.4.12.2 MPU_AXI2OCP_MISC Register Description
      13. 4.4.13 MPU_MA_LSM Registers
        1. 4.4.13.1 MPU_MA_LSM Register Summary
        2. 4.4.13.2 MPU_MA_LSM Register Description
      14. 4.4.14 MPU_MA_WP Registers
        1. 4.4.14.1 MPU_MA_WP Register Summary
        2. 4.4.14.2 MPU_MA_WP Register Description
  7. DSP Subsystems
    1. 5.1 DSP Subsystems Overview
      1. 5.1.1 DSP Subsystems Key Features
    2. 5.2 DSP Subsystem Integration
    3. 5.3 DSP Subsystems Functional Description
      1. 5.3.1  DSP Subsystems Block Diagram
      2. 5.3.2  DSP Subsystem Components
        1. 5.3.2.1 C66x DSP Subsystem Introduction
        2. 5.3.2.2 DSP TMS320C66x CorePac
          1. 5.3.2.2.1 DSP TMS320C66x CorePac CPU
          2. 5.3.2.2.2 DSP TMS320C66x CorePac Internal Memory Controllers and Memories
            1. 5.3.2.2.2.1 Level 1 Memories
            2. 5.3.2.2.2.2 Level 2 Memory
          3. 5.3.2.2.3 DSP C66x CorePac Internal Peripherals
            1. 5.3.2.2.3.1 DSP C66x CorePac Interrupt Controller (DSP INTC)
            2. 5.3.2.2.3.2 DSP C66x CorePac Power-Down Controller (DSP PDC)
            3. 5.3.2.2.3.3 DSP C66x CorePac Bandwidth Manager (BWM)
            4. 5.3.2.2.3.4 DSP C66x CorePac Memory Protection Hardware
            5. 5.3.2.2.3.5 DSP C66x CorePac Internal DMA (IDMA) Controller
            6. 5.3.2.2.3.6 DSP C66x CorePac External Memory Controller
            7. 5.3.2.2.3.7 DSP C66x CorePac Extended Memory Controller
              1. 5.3.2.2.3.7.1 XMC MDMA Accesses at DSP System Level
                1. 5.3.2.2.3.7.1.1 DSP System MPAX Logic
                2. 5.3.2.2.3.7.1.2 MDMA Non-Post Override Control
            8. 5.3.2.2.3.8 L1P Memory Error Detection Logic
            9. 5.3.2.2.3.9 L2 Memory Error Detection and Correction Logic
        3. 5.3.2.3 DSP Debug and Trace Support
          1. 5.3.2.3.1 DSP Advanced Event Triggering (AET)
          2. 5.3.2.3.2 DSP Trace Support
          3. 5.3.2.3.3 806
      3. 5.3.3  DSP System Control Logic
        1. 5.3.3.1 DSP System Clocks
        2. 5.3.3.2 DSP Hardware Resets
        3. 5.3.3.3 DSP Software Resets
        4. 5.3.3.4 DSP Power Management
          1. 5.3.3.4.1 DSP System Powerdown Protocols
          2. 5.3.3.4.2 DSP Software and Hardware Power Down Sequence Overview
          3. 5.3.3.4.3 DSP IDLE Wakeup
          4. 5.3.3.4.4 DSP SYSTEM IRQWAKEEN registers
          5. 5.3.3.4.5 DSP Automatic Power Transition
      4. 5.3.4  DSP Interrupt Requests
        1. 5.3.4.1 DSP Input Interrupts
          1. 5.3.4.1.1 DSP Non-maskable Interrupt Input
        2. 5.3.4.2 DSP Event and Interrupt Generation Outputs
          1. 5.3.4.2.1 DSP MDMA and DSP EDMA Mflag Event Outputs
          2. 5.3.4.2.2 DSP Aggregated Error Interrupt Output
          3. 5.3.4.2.3 Non-DSP C66x CorePac Generated Peripheral Interrupt Outputs
      5. 5.3.5  DSP DMA Requests
        1. 5.3.5.1 DSP EDMA Wakeup Interrupt
      6. 5.3.6  DSP Intergated Memory Management Units
        1. 5.3.6.1 DSP MMUs Overview
        2. 5.3.6.2 Routing MDMA Traffic through DSP MMU0
        3. 5.3.6.3 Routing EDMA Traffic thorugh DSP MMU1
      7. 5.3.7  DSP Integrated EDMA Subsystem
        1. 5.3.7.1 DSP EDMA Overview
        2. 5.3.7.2 DSP System and Device Level Settings of DSP EDMA
      8. 5.3.8  DSP L2 interconnect Network
        1. 5.3.8.1 DSP Public Firewall Settings
        2. 5.3.8.2 DSP NoC Flag Mux and Error Log Registers
        3. 5.3.8.3 DSP NoC Arbitration
      9. 5.3.9  DSP Boot Configuration
      10. 5.3.10 DSP Internal and External Memory Views
        1. 5.3.10.1 C66x CPU View of the Address Space
        2. 5.3.10.2 DSP_EDMA View of the Address Space
        3. 5.3.10.3 L3_MAIN View of the DSP Address Space
    4. 5.4 DSP Subsystem Register Manual
      1. 5.4.1 DSP Subsystem Instance Summary
      2. 5.4.2 DSP_ICFG Registers
        1. 5.4.2.1 DSP_ICFG Register Summary
        2. 5.4.2.2 DSP_ICFG Register Description
      3. 5.4.3 DSP_SYSTEM Registers
        1. 5.4.3.1 DSP_SYSTEM Register Summary
        2. 5.4.3.2 DSP_SYSTEM Register Description
      4. 5.4.4 DSP_FW_L2_NOC_CFG Registers
        1. 5.4.4.1 DSP_FW_L2_NOC_CFG Register Summary
        2. 5.4.4.2 DSP_FW_L2_NOC_CFG Register Description
  8. IVA Subsystem
  9. Dual Cortex-M4 IPU Subsystem
    1. 7.1 Dual Cortex-M4 IPU Subsystem Overview
      1. 7.1.1 Introduction
      2. 7.1.2 Features
    2. 7.2 Dual Cortex-M4 IPU Subsystem Integration
      1. 7.2.1 Dual Cortex-M4 IPU Subsystem Clock and Reset Distribution
        1. 7.2.1.1 Clock Distribution
        2. 7.2.1.2 Reset Distribution
    3. 7.3 Dual Cortex-M4 IPU Subsystem Functional Description
      1. 7.3.1 IPUx Subsystem Block Diagram
      2. 7.3.2 Power Management
        1. 7.3.2.1 Local Power Management
        2. 7.3.2.2 Power Domains
        3. 7.3.2.3 867
        4. 7.3.2.4 Voltage Domain
        5. 7.3.2.5 Power States and Modes
        6. 7.3.2.6 Wake-Up Generator (IPUx_WUGEN)
          1. 7.3.2.6.1 IPUx_WUGEN Main Features
      3. 7.3.3 IPUx_UNICACHE
      4. 7.3.4 IPUx_UNICACHE_MMU
      5. 7.3.5 IPUx_UNICACHE_SCTM
        1. 7.3.5.1 Counter Functions
          1. 7.3.5.1.1 Input Events
          2. 7.3.5.1.2 Counters
            1. 7.3.5.1.2.1 Counting Modes
            2. 7.3.5.1.2.2 Counter Overflow
            3. 7.3.5.1.2.3 Counters and Processor State
            4. 7.3.5.1.2.4 Chaining Counters
            5. 7.3.5.1.2.5 Enabling and Disabling Counters
            6. 7.3.5.1.2.6 Resetting Counters
        2. 7.3.5.2 Timer Functions
          1. 7.3.5.2.1 Periodic Intervals
          2. 7.3.5.2.2 Event Generation
      6. 7.3.6 IPUx_MMU
        1. 7.3.6.1 IPUx_MMU Behavior on Page-Fault in IPUx Subsystem
      7. 7.3.7 Interprocessor Communication (IPC)
        1. 7.3.7.1 Use of WFE and SEV
        2. 7.3.7.2 Use of Interrupt for IPC
        3. 7.3.7.3 Use of the Bit-Band Feature for Semaphore Operations
        4. 7.3.7.4 Private Memory Space
      8. 7.3.8 IPU Boot Options
    4. 7.4 Dual Cortex-M4 IPU Subsystem Register Manual
      1. 7.4.1 IPUx Subsystem Instance Summary
      2. 7.4.2 IPUx_UNICACHE_CFG Registers
        1. 7.4.2.1 IPUx_UNICACHE_CFG Register Summary
        2. 7.4.2.2 IPUx_UNICACHE_CFG Register Description
      3. 7.4.3 IPUx_UNICACHE_SCTM Registers
        1. 7.4.3.1 IPUx_UNICACHE_SCTM Register Summary
        2. 7.4.3.2 IPUx_UNICACHE_SCTM Register Description
      4. 7.4.4 IPUx_UNICACHE_MMU (AMMU) Registers
        1. 7.4.4.1 IPUx_UNICACHE_MMU (AMMU) Register Summary
        2. 7.4.4.2 IPUx_UNICACHE_MMU (AMMU) Register Description
      5. 7.4.5 IPUx_MMU Registers
      6. 7.4.6 IPUx_Cx_INTC Registers
      7. 7.4.7 IPUx_WUGEN Registers
        1. 7.4.7.1 IPUx_WUGEN Register Summary
        2. 7.4.7.2 IPUx_WUGEN Register Description
      8. 7.4.8 IPUx_Cx_RW_TABLE Registers
        1. 7.4.8.1 IPUx_Cx_RW_TABLE Register Summary
        2. 7.4.8.2 IPUx_Cx_RW_TABLE Register Description
  10. Embedded Vision Engine
    1. 8.1 Embedded Vision Engine (EVE) Subsystem
      1. 8.1.1 EVE Overview
        1. 8.1.1.1 EVE Memories
      2. 8.1.2 EVE Integration
        1. 8.1.2.1 Multi-EVE Recommended Connections
      3. 8.1.3 EVE Functional Description
        1. 8.1.3.1  EVE Connection ID (ConnID) Mapping
        2. 8.1.3.2  EVE Processors Overview
          1. 8.1.3.2.1 Scalar Core (ARP32)
          2. 8.1.3.2.2 VCOP
          3. 8.1.3.2.3 Scalar-Vector Interaction
        3. 8.1.3.3  Internal Memory Overview
          1. 8.1.3.3.1 Program Cache/Memory
          2. 8.1.3.3.2 ARP32 Data Memory (DMEM)
          3. 8.1.3.3.3 WBUF
          4. 8.1.3.3.4 Image Buffers–IBUFLA, IBUFLB, IBUFHA, and IBUFHB
          5. 8.1.3.3.5 Memory Switch Error Registers
          6. 8.1.3.3.6 Memory Error Detection
            1. 8.1.3.3.6.1 Captured Address – EDADDR and EDADDR_BO
            2. 8.1.3.3.6.2 Modes of Operation
            3. 8.1.3.3.6.3 Parity Error Testability
            4. 8.1.3.3.6.4 Parity Error Recovery
          7. 8.1.3.3.7 VCOP System Error Halt Conditions
        4. 8.1.3.4  Program Cache Architecture
          1. 8.1.3.4.1 Basic Operation
          2. 8.1.3.4.2 Line Buffer
          3. 8.1.3.4.3 Software Direct Preload
          4. 8.1.3.4.4 User Coherence Operation
            1. 8.1.3.4.4.1 Global Invalidate
            2. 8.1.3.4.4.2 Range-Based Invalidate
            3. 8.1.3.4.4.3 Single-Address Invalidate – For Breakpoint Operation
          5. 8.1.3.4.5 Demand-Based Prefetch
          6. 8.1.3.4.6 Debug Support
            1. 8.1.3.4.6.1 Read/Write Accessibility through OCP Debug Target Port
            2. 8.1.3.4.6.2 Breakpoint Support
            3. 8.1.3.4.6.3 Cache Profiling
          7. 8.1.3.4.7 Error Detection
        5. 8.1.3.5  EDMA
          1. 8.1.3.5.1 DMA Channel Events
          2. 8.1.3.5.2 DMA Parameter Set
          3. 8.1.3.5.3 Channel Controller
          4. 8.1.3.5.4 EVE-Level Bus Width and Throughput
            1. 8.1.3.5.4.1 Concurrent Transfer Requirements
        6. 8.1.3.6  General-Purpose Inputs/Outputs
        7. 8.1.3.7  CME Signaling
        8. 8.1.3.8  Multi-EVE and VIP Usage Models
          1. 8.1.3.8.1 Data Partitioning
          2. 8.1.3.8.2 Task Partitioning
          3. 8.1.3.8.3 963
        9. 8.1.3.9  Memory Management Unit
        10. 8.1.3.10 Interrupt Control
          1. 8.1.3.10.1 EVE Interrupt Sources – Memory Switch and Parity Error Interrupts
          2. 8.1.3.10.2 ARP32 INTC
          3. 8.1.3.10.3 Output Interrupt Reduction
          4. 8.1.3.10.4 End of Interrupt Mapping
        11. 8.1.3.11 Interprocessor Communication
          1. 8.1.3.11.1 Mailbox Configuration
            1. 8.1.3.11.1.1 Mailbox 0 – EVE to DSP1, DSP2 and MPU
            2. 8.1.3.11.1.2 Mailbox 1 – EVE to Other Hosts
            3. 8.1.3.11.1.3 Mailbox 2 – EVE to EVE in a 2x EVE System
        12. 8.1.3.12 Powerdown
          1. 8.1.3.12.1 Extended Duration Sleep
            1. 8.1.3.12.1.1 Sequence Overview
            2. 8.1.3.12.1.2 Idle Protocol Overview
            3. 8.1.3.12.1.3 Mstandby Protocol Overview
            4. 8.1.3.12.1.4 IDLE Wakeup
        13. 8.1.3.13 Hardware-Assisted Software Self-Test – MISRs
          1. 8.1.3.13.1 Mapping of MISRs to Different Width Buses
          2. 8.1.3.13.2 Detection of Valid Address and Data Cycles
          3. 8.1.3.13.3 Creating a Unique Signature – Software Self-Test Implications
          4. 8.1.3.13.4 Multipass Tests Using WBUF MISR
        14. 8.1.3.14 Error Recovery – ARP32 and OCP Disconnect
          1. 8.1.3.14.1 ARP32 Disconnect
          2. 8.1.3.14.2 OCP Initiator Disconnect
        15. 8.1.3.15 Lock and Unlock Feature
        16. 8.1.3.16 EVE Memory Map
          1. 8.1.3.16.1 VCOP and Local EDMA: IBUF Memory Map Aliasing
          2. 8.1.3.16.2 ARP32 Write Model – Avoiding Race Conditions
        17. 8.1.3.17 Debug Support
          1. 8.1.3.17.1 ARP32 Debug Support
          2. 8.1.3.17.2 SCTM
            1. 8.1.3.17.2.1 SCTM Configuration
            2. 8.1.3.17.2.2 SCTM Resources Reserved for BIOS
            3. 8.1.3.17.2.3 SCTM Event Mapping
            4. 8.1.3.17.2.4 SCTM Halt and Idle Modes
          3. 8.1.3.17.3 SMSET
            1. 8.1.3.17.3.1 SMSET Configuration
            2. 8.1.3.17.3.2 SMSET Event Mapping
        18. 8.1.3.18 EVE L2_FNOC Interconnect
          1. 8.1.3.18.1 EVE L2_FNOC Flag Mux and Error Log Registers
      4. 8.1.4 EVE Programming Model
        1. 8.1.4.1 Boot
        2. 8.1.4.2 Task Change and Program Cache Prefetch
          1. 8.1.4.2.1 Simple or Unoptimized Branch to New Task
          2. 8.1.4.2.2 Prefetch, Wait, then Branch to New Task
          3. 8.1.4.2.3 Hidden Prefetch
        3. 8.1.4.3 Interrupts
        4. 8.1.4.4 Safety Considerations
          1. 8.1.4.4.1 Memory Error Detection
          2. 8.1.4.4.2 MMU
          3. 8.1.4.4.3 Firewall
          4. 8.1.4.4.4 Interconnect
          5. 8.1.4.4.5 Application Stability/Sequencing
          6. 8.1.4.4.6 Interrupt Servicing
      5. 8.1.5 EVE Subsystem Register Manual
        1. 8.1.5.1 EVE Instance Summary
        2. 8.1.5.2 EVE Register Summary and Description
          1. 8.1.5.2.1 EVE Register Summary
          2. 8.1.5.2.2 EVE Register Description
        3. 8.1.5.3 EVE L2_FNOC Register Summary and Description
          1. 8.1.5.3.1 EVE L2_FNOC Register Summary
          2. 8.1.5.3.2 EVE L2_FNOC Register Description
      6. 8.1.6 Subsystem Counter Timer Module
        1. 8.1.6.1 Introduction
          1. 8.1.6.1.1 Overview
          2. 8.1.6.1.2 Top-Level Requirements
          3. 8.1.6.1.3 Configuration
          4. 8.1.6.1.4 Block Diagram
        2. 8.1.6.2 Functional Description
          1. 8.1.6.2.1 Configuration Interface
          2. 8.1.6.2.2 Counter Function
            1. 8.1.6.2.2.1 Input Events
            2. 8.1.6.2.2.2 Counters
            3. 8.1.6.2.2.3 Counting Mode
            4. 8.1.6.2.2.4 Counter Overflow
            5. 8.1.6.2.2.5 Counters and Processor State
            6. 8.1.6.2.2.6 Chaining Counters
              1. 8.1.6.2.2.6.1 Reading Chained Counters
            7. 8.1.6.2.2.7 Enabling and Disabling Counters
            8. 8.1.6.2.2.8 Resetting Counters
          3. 8.1.6.2.3 Timer Function
            1. 8.1.6.2.3.1 Periodic Intervals
            2. 8.1.6.2.3.2 Event Generation
            3. 8.1.6.2.3.3 Watchdog Timer Function
          4. 8.1.6.2.4 System Trace Integration
            1. 8.1.6.2.4.1 Overview
            2. 8.1.6.2.4.2 STM Configuration
              1. 8.1.6.2.4.2.1 Periodic Counter State Export
              2. 8.1.6.2.4.2.2 Application Control of Counter State Export
              3. 8.1.6.2.4.2.3 Application Control of the Counter Configuration Export
        3. 8.1.6.3 Use Case Examples
          1. 8.1.6.3.1 Counter Enable
            1. 8.1.6.3.1.1 Enabling a Single Counter
            2. 8.1.6.3.1.2 Reading a Single Counter
            3. 8.1.6.3.1.3 Enabling a Group of Counters Simultaneously
            4. 8.1.6.3.1.4 Reading a Group of Counters Simultaneously
            5. 8.1.6.3.1.5 Configuring a Chained Counter
          2. 8.1.6.3.2 Timer Enable
          3. 8.1.6.3.3 Periodic STM Export Enable
          4. 8.1.6.3.4 Disabling the SCTM
        4. 8.1.6.4 SCTM Register Manual
          1. 8.1.6.4.1 SCTM Instance Summary
          2. 8.1.6.4.2 SCTM Registers
            1. 8.1.6.4.2.1 SCTM Register Summary
            2. 8.1.6.4.2.2 SCTM Register Description
      7. 8.1.7 Software Message and System Event Trace
        1. 8.1.7.1 Introduction
          1. 8.1.7.1.1 Overview
          2. 8.1.7.1.2 Configuration
          3. 8.1.7.1.3 Block Diagram
        2. 8.1.7.2 Functional Description
          1. 8.1.7.2.1 Connectivity
          2. 8.1.7.2.2 SMSET Event Mapping
          3. 8.1.7.2.3 Software Messages
          4. 8.1.7.2.4 SMSET Master Port
            1. 8.1.7.2.4.1 OCP Disconnect
          5. 8.1.7.2.5 SMSET Debug Features
          6. 8.1.7.2.6 Component Ownership
            1. 8.1.7.2.6.1 Ownership State
              1. 8.1.7.2.6.1.1 Available State
              2. 8.1.7.2.6.1.2 Claimed State
              3. 8.1.7.2.6.1.3 Enabled State
            2. 8.1.7.2.6.2 Ownership Commands
            3. 8.1.7.2.6.3 Claim Reset
        3. 8.1.7.3 Use Case Examples
          1. 8.1.7.3.1 Procedure to Enable System Event Capture
          2. 8.1.7.3.2 Procedure to Start and Stop System Event Capture from External Trigger Detection
          3. 8.1.7.3.3 Procedure to Disable System Event Capture
        4. 8.1.7.4 SMSET Register Manual
          1. 8.1.7.4.1 SMSET Instance Summary
          2. 8.1.7.4.2 SMSET Register Summary
          3. 8.1.7.4.3 SMSET Register Description
    2. 8.2 ARP32 CPU and Instruction Set
      1. 8.2.1 Overview
      2. 8.2.2 Features
      3. 8.2.3 Block Diagram
      4. 8.2.4 Architecture
        1. 8.2.4.1  Interface Description
          1. 8.2.4.1.1 Data Memory Interface
          2. 8.2.4.1.2 Instruction Memory Interface
        2. 8.2.4.2  Pipeline
          1. 8.2.4.2.1 Overview
          2. 8.2.4.2.2 Pipeline Operation
            1. 8.2.4.2.2.1 ARP32 CPU Pipeline Operation
            2. 8.2.4.2.2.2 1109
          3. 8.2.4.2.3 Pipeline Interlocks
        3. 8.2.4.3  Data Format
        4. 8.2.4.4  Endian Support
        5. 8.2.4.5  Architectural Register File
        6. 8.2.4.6  CPU Control Registers
          1. 8.2.4.6.1  Control Status Register (CSR)
          2. 8.2.4.6.2  Interrupt Enable Register (IER)
          3. 8.2.4.6.3  Interrupt Flag Register (IFR)
          4. 8.2.4.6.4  Interrupt Set Register (ISR)
          5. 8.2.4.6.5  Interrupt Clear Register (ICR)
          6. 8.2.4.6.6  Nonmaskable Interrupt (NMI) Return Pointer Register (NRP)
          7. 8.2.4.6.7  Interrupt Return Pointer Register (IRP)
          8. 8.2.4.6.8  Stack Pointer Register (SP)
          9. 8.2.4.6.9  Global Data Pointer Register (GDP)
          10. 8.2.4.6.10 Link Register (LR)
          11. 8.2.4.6.11 Loop 0 Start Address Register (LSA0)
          12. 8.2.4.6.12 Loop 0 End Address Register (LEA0)
          13. 8.2.4.6.13 Loop 0 Iteration Count Register (LCNT0)
          14. 8.2.4.6.14 Loop 1 Start Address Register (LSA1)
          15. 8.2.4.6.15 Loop 1 End Address Register (LEA1)
          16. 8.2.4.6.16 Loop 1 Iteration Count Register (LCNT1)
          17. 8.2.4.6.17 Loop 0 Iteration Count Reload Value Register (LCNT0RLD)
          18. 8.2.4.6.18 Shadow Control Status Register (SCSR)
          19. 8.2.4.6.19 NMI Shadow Control Status Register (NMISCSR)
          20. 8.2.4.6.20 CPU Identification Register (CPUID)
          21. 8.2.4.6.21 Decode Program Counter Register (DPC)
          22. 8.2.4.6.22 Time Stamp Counter Registers (TSCL and TSCH)
            1. 8.2.4.6.22.1 Initialization
            2. 8.2.4.6.22.2 Enabling Counting
            3. 8.2.4.6.22.3 Disabling Counting
            4. 8.2.4.6.22.4 Reading the Counter
        7. 8.2.4.7  CPU Shadow Registers
        8. 8.2.4.8  Functional Units
        9. 8.2.4.9  Instruction Fetch
        10. 8.2.4.10 Alignment of 32-bit Instructions
        11. 8.2.4.11 Instruction Execution in Branch Delay Slot
        12. 8.2.4.12 Address Space
        13. 8.2.4.13 Program Counter Convention
        14. 8.2.4.14 Stack Pointer Convention
        15. 8.2.4.15 Global Data Pointer Convention
        16. 8.2.4.16 Conditional Execution
        17. 8.2.4.17 Hardware Loop Acceleration
          1. 8.2.4.17.1  Overview
          2. 8.2.4.17.2  Loop Registers
          3. 8.2.4.17.3  Loop Setup Instructions
          4. 8.2.4.17.4  Loop Operation
          5. 8.2.4.17.5  Call and Branch within Loop Context
          6. 8.2.4.17.6  Dynamic Changes to Loop Iteration Count
          7. 8.2.4.17.7  Interrupt Processing During HLA
          8. 8.2.4.17.8  HLA Usage in Interrupt Context
          9. 8.2.4.17.9  HLA Usage Restrictions
          10. 8.2.4.17.10 HLA Mapping Examples
            1. 8.2.4.17.10.1 Loops With Single Level of Nesting
              1. 8.2.4.17.10.1.1 C memset-like Loop, Single Level, Minimum Instructions
              2. 8.2.4.17.10.1.2 1164
              3. 8.2.4.17.10.1.3 C memcpy-like Loop, Single Level, Minimum Instructions
              4. 8.2.4.17.10.1.4 1166
            2. 8.2.4.17.10.2 Loops With Two Levels of Nesting
              1. 8.2.4.17.10.2.1 Two-level Nesting, Both Loops Ending at Same Instruction
              2. 8.2.4.17.10.2.2 1169
              3. 8.2.4.17.10.2.3 Two-level Nesting, Different Ending Instructions for Two Levels
              4. 8.2.4.17.10.2.4 1171
        18. 8.2.4.18 Interrupts
          1. 8.2.4.18.1  Overview
          2. 8.2.4.18.2  Interrupt Processing
          3. 8.2.4.18.3  Interrupt Acknowledgment
          4. 8.2.4.18.4  Interrupt Priorities
          5. 8.2.4.18.5  Interrupt Service Table (IST)
          6. 8.2.4.18.6  Interrupt Flags
            1. 8.2.4.18.6.1 Setting Interrupt Flag
            2. 8.2.4.18.6.2 Setting Interrupt Flag
            3. 8.2.4.18.6.3 1181
          7. 8.2.4.18.7  Interrupt Behavior
            1. 8.2.4.18.7.1 Reset Interrupt
            2. 8.2.4.18.7.2 Non-maskable Interrupt (NMI)
            3. 8.2.4.18.7.3 SWI Interrupt
            4. 8.2.4.18.7.4 Maskable Interrupts
            5. 8.2.4.18.7.5 UNDEF Interrupt
          8. 8.2.4.18.8  Interrupt Context Save and Restore
          9. 8.2.4.18.9  Nested Interrupts
            1. 8.2.4.18.9.1 Non-nested Interrupt Model
            2. 8.2.4.18.9.2 Nested Interrupt Model
          10. 8.2.4.18.10 Non-nested Interrupt Latency
            1. 8.2.4.18.10.1 Best Case Interrupt Latency
            2. 8.2.4.18.10.2 Worst Case Interrupt Latency
      5.      8.2.A Instruction Set
        1.       8.2.A.1 Instruction Operation and Execution Notations
        2.       8.2.A.2 Instruction Syntax and Opcode Notations
        3.       8.2.A.3 Instruction Scheduling Restrictions
          1.        8.2.A.3.1 Restrictions Applicable to a Branch Delay Slot
          2.        8.2.A.3.2 Restrictions on Loops Using Hardware Loop Assist (HLA)
          3.        8.2.A.3.3 Restrictions on Other Types of Control Flow Instructions
          4.        8.2.A.3.4 Restrictions for Write Data Bypass to Control Register Reads
          5.        8.2.A.3.5 Restrictions for Write Data Bypass to Shadow Register Reads
          6.        8.2.A.3.6 Restrictions for Link Register Update
        4.       8.2.A.4 Instruction Set Encoding
        5.       8.2.A.5 Instruction Descriptions
          1.        ABS
          2.        ADD
          3.        ADD
          4.        ADD
          5.        ADD
          6.        ADD
          7.        AND
          8.        AND
          9.        B(cc)
          10.        B(cc)
          11.        B(cc)
          12.        BIRP
          13.        BKPT
          14.        BNRP
          15.        CALL
          16.        CALL
          17.        CLR
          18.        CLR
          19.        CMP
          20.        CMP
          21.        CMP
          22.        CMPU
          23.        CMPU
          24.        CMPU
          25.        DIV
          26.        DIVU
          27.        EXT
          28.        EXT
          29.        EXTU
          30.        EXTU
          31.        IDLE
          32.        LDB(U)
          33.        LDB(U)
          34.        LDB(U)
          35.        LDB(U)
          36.        LDB(U)
          37.        LDB(U)
          38.        LDB(U)
          39.        LDB(U)
          40.        LDH(U)
          41.        LDH(U)
          42.        LDH(U)
          43.        LDH(U)
          44.        LDH(U)
          45.        LDH(U)
          46.        LDH(U)
          47.        LDH(U)
          48.        LDW
          49.        LDW
          50.        LDW
          51.        LDW
          52.        LDW
          53.        LDW
          54.        LDW
          55.        LDW
          56.        LDRF
          57.        LMBD
          58.        MAX
          59.        MAXU
          60.        MIN
          61.        MINU
          62.        MOD
          63.        MODU
          64.        MPY
          65.        MPYU
          66.        MV
          67.        MVC
          68.        MVC
          69.        MVC
          70.        MVCH
          71.        MVK
          72.        MVKH
          73.        MVKLS
          74.        MVKS
          75.        MVS
          76.        MVS
          77.        NEG
          78.        NOP
          79.        NOT
          80.        OR
          81.        OR
          82.        RET
          83.        REV
          84.        ROT
          85.        ROTC
          86.        SADD
          87.        SATN
          88.        SET
          89.        SET
          90.        SHL
          91.        SHL
          92.        SHRA
          93.        SHRA
          94.        SHRU
          95.        SHRU
          96.        SLA
          97.        SSUB
          98.        STB
          99.        STB
          100.        STB
          101.        STB
          102.        STB
          103.        STB
          104.        STB
          105.        STB
          106.        STH
          107.        STH
          108.        STH
          109.        STH
          110.        STH
          111.        STH
          112.        STH
          113.        STH
          114.        STW
          115.        STW
          116.        STW
          117.        STW
          118.        STW
          119.        STW
          120.        STW
          121.        STW
          122.        STHI
          123.        STRF
          124.        SUB
          125.        SUB
          126.        SUB
          127.        SUB
          128.        SUB
          129.        SWI
          130.        XOR
          131.        XOR
      6.      8.2.B Clock, Reset, and Dynamic Power Management
        1.       8.2.B.1 Introduction
        2.       8.2.B.2 CPU Reset Modes
        3.       8.2.B.3 Dynamic Power Management
      7.      8.2.C Notes on Programming Model
        1.       8.2.C.1 Booting
        2.       8.2.C.2 Enabling and Disabling Interrupts
          1.        8.2.C.2.1 Globally Enabling or Disabling Maskable Interrupts
          2.        8.2.C.2.2 Enabling or Disabling Individual Interrupts
        3.       8.2.C.3 Stack Usage in Interrupt Service Routine
        4.       8.2.C.4 General Restrictions
    3. 8.3 VCOP CPU and Instruction Set
      1. 8.3.1 Module Overview
      2. 8.3.2 Features
      3. 8.3.3 Block Diagram
      4. 8.3.4 System Interfaces
        1. 8.3.4.1 Interrupts
        2. 8.3.4.2 Configuration Bus Slave Port
        3. 8.3.4.3 Performance Counter Interface
        4. 8.3.4.4 Data Memory Map
      5. 8.3.5 Functional Description
        1. 8.3.5.1 Scalar-Vector Architecture
          1. 8.3.5.1.1 Scalar Core
          2. 8.3.5.1.2 Scalar-Vector Interaction
        2. 8.3.5.2 Vector Core Overview
          1. 8.3.5.2.1 Nested for Loop Model
            1. 8.3.5.2.1.1 Nested Loop Model Skeleton
            2. 8.3.5.2.1.2 1365
          2. 8.3.5.2.2 Instruction Organization
        3. 8.3.5.3 Vector Control
          1. 8.3.5.3.1 Repeat End Count
          2. 8.3.5.3.2 Parameter Pointer
          3. 8.3.5.3.3 Switch Buffers
        4. 8.3.5.4 Vector-Scalar Synchronization
          1. 8.3.5.4.1 Wait for Vector Core Done
          2. 8.3.5.4.2 Wait for Vector Core Ready
        5. 8.3.5.5 Vector Computation
          1. 8.3.5.5.1  Vector Loop
            1. 8.3.5.5.1.1 Retention of State Between VLOOPs
          2. 8.3.5.5.2  Vector Register Initialization
          3. 8.3.5.5.3  Address Generator (agen)
          4. 8.3.5.5.4  Vector Load
          5. 8.3.5.5.5  Vector Arithmetic/Logic Operations
          6. 8.3.5.5.6  Vector Store
          7. 8.3.5.5.7  Table Lookup Operation
          8. 8.3.5.5.8  Histogram Operation
          9. 8.3.5.5.9  Circular Buffer Addressing Support
          10. 8.3.5.5.10 Load/Store Address Alignment Constraints
        6. 8.3.5.6 Load/Store Buffer and Scheduling
          1. 8.3.5.6.1 3-Tap Horizontal Filtering, Byte Type
          2. 8.3.5.6.2 1388
          3. 8.3.5.6.3 Horizontal Filtering, Short Type
          4. 8.3.5.6.4 1390
        7. 8.3.5.7 VCOP Per-Loop Overhead
        8. 8.3.5.8 VCOP Error Handling
        9. 8.3.5.9 Vector Operation Details
          1. 8.3.5.9.1  VABS
          2. 8.3.5.9.2  VABSDIF
          3. 8.3.5.9.3  VADD
          4. 8.3.5.9.4  VADDH
          5. 8.3.5.9.5  VADDSUB
          6. 8.3.5.9.6  VADD3
          7. 8.3.5.9.7  VADIF3
          8. 8.3.5.9.8  VAND
          9. 8.3.5.9.9  VANDN
          10. 8.3.5.9.10 VAND3
          11. 8.3.5.9.11 VBINLOG
          12. 8.3.5.9.12 VBITC
          13. 8.3.5.9.13 VBITDI
          14. 8.3.5.9.14 VBITI
          15. 8.3.5.9.15 VBITPK
          16. 8.3.5.9.16 VBITR
          17. 8.3.5.9.17 VBITTR
          18. 8.3.5.9.18 VBITUNPK
          19. 8.3.5.9.19 VCMOV
          20. 8.3.5.9.20 VCMPEQ
          21. 8.3.5.9.21 VCMPGE
          22. 8.3.5.9.22 VCMPGT
          23. 8.3.5.9.23 VDINTRLV
          24. 8.3.5.9.24 VDINTRLV2
          25. 8.3.5.9.25 VEXITNZ
          26. 8.3.5.9.26 VINTRLV
          27. 8.3.5.9.27 VINTRLV2
          28. 8.3.5.9.28 VINTRLV4
          29. 8.3.5.9.29 VLMBD
          30. 8.3.5.9.30 VMADD
          31. 8.3.5.9.31 VMAX
          32. 8.3.5.9.32 VMAXSETF
          33. 8.3.5.9.33 VMIN
          34. 8.3.5.9.34 VMINSETF
          35. 8.3.5.9.35 VMPY
          36. 8.3.5.9.36 VMSUB
          37. 8.3.5.9.37 VNOP
          38. 8.3.5.9.38 VNOT
          39. 8.3.5.9.39 VOR
          40. 8.3.5.9.40 VOR3
          41. 8.3.5.9.41 VRND
          42. 8.3.5.9.42 VSAD
          43. 8.3.5.9.43 VSEL
          44. 8.3.5.9.44 VSHF
          45. 8.3.5.9.45 VSHFOR
          46. 8.3.5.9.46 VSHF16
          47. 8.3.5.9.47 VSIGN
          48. 8.3.5.9.48 VSORT2
          49. 8.3.5.9.49 VSUB
          50. 8.3.5.9.50 VSWAP
          51. 8.3.5.9.51 VXOR
      6. 8.3.6 Debug Support
      7. 8.3.7 VCOP Register Manual
        1. 8.3.7.1 VCOP Instance Summary
        2. 8.3.7.2 VCOP Registers
          1. 8.3.7.2.1 VCOP Registers Mapping Summary
          2. 8.3.7.2.2 VCOP Register Description
  11. Video Input Port
    1. 9.1 VIP Overview
    2. 9.2 VIP Environment
    3. 9.3 VIP Integration
    4. 9.4 VIP Functional Description
      1. 9.4.1 VIP Block Diagram
      2. 9.4.2 VIP Software Reset
      3. 9.4.3 VIP Power and Clocks Management
        1. 9.4.3.1 VIP Clocks
        2. 9.4.3.2 VIP Idle Mode
        3. 9.4.3.3 VIP StandBy Mode
      4. 9.4.4 VIP Slice
        1. 9.4.4.1 VIP Slice Processing Path Overview
        2. 9.4.4.2 VIP Slice Processing Path Multiplexers
          1. 9.4.4.2.1 VIP_CSC Multiplexers
          2. 9.4.4.2.2 VIP_SC Multiplexer
          3. 9.4.4.2.3 Output to VPDMA Multiplexers
        3. 9.4.4.3 VIP Slice Processing Path Examples
          1. 9.4.4.3.1 Input: A=RGB, B=YUV422; Output: A=RGB, B=RGB
          2. 9.4.4.3.2 Input: A=YUV422 8/16, B=YUV422; Output: A=Scaled YUV420, B=RGB
          3. 9.4.4.3.3 Input: A=RGB, B=YUV422; Output: A=RGB, B=Scaled YUV420
          4. 9.4.4.3.4 Input: A=YUV444, B=YUV422; Output: A=YUV422, A=Scaled YUV422, B=YUV422
          5. 9.4.4.3.5 Input: A=YUV444; Output: A=Scaled YUV420, A=YUV420
          6. 9.4.4.3.6 Input: A=YUV444; Output: A=Scaled YUV420, A=YUV444
          7. 9.4.4.3.7 Input: A=YUV422 8/16; Output: A=Scaled YUV420, A=YUV444
          8. 9.4.4.3.8 Input: A=YUV422 8/16, B=YUV422; Output: A=Scaled YUV420, B=YUV420
          9. 9.4.4.3.9 Input: A=YUV422 8/16, B=YUV422; Output: A=YUV420, B=YUV420
      5. 9.4.5 VIP Parser
        1. 9.4.5.1  Features
        2. 9.4.5.2  Repacker
        3. 9.4.5.3  Analog Video
        4. 9.4.5.4  Digitized Video
        5. 9.4.5.5  Frame Buffers
        6. 9.4.5.6  Input Data Interface
          1. 9.4.5.6.1  8b Interface Mode
          2. 9.4.5.6.2  16b Interface Mode
          3. 9.4.5.6.3  24b Interface Mode
          4. 9.4.5.6.4  Signal Relationships
          5. 9.4.5.6.5  General 5 Pin Interfaces
          6. 9.4.5.6.6  Signal Subsets—4 Pin VSYNC, ACTVID, and FID
          7. 9.4.5.6.7  Signal Subsets—4 Pin VSYNC, HSYNC, and FID
          8. 9.4.5.6.8  Vertical Sync
          9. 9.4.5.6.9  Field ID Determination Using Dedicated Signal
          10. 9.4.5.6.10 Field ID Determination Using VSYNC Skew
          11. 9.4.5.6.11 Rationale for FID Determination By VSYNC Skew
          12. 9.4.5.6.12 ACTVID Framing
          13. 9.4.5.6.13 Ancillary Data Storage in Descrete Sync Mode
        7. 9.4.5.7  BT.656 Style Embedded Sync
          1. 9.4.5.7.1 Data Input
          2. 9.4.5.7.2 Sync Words
          3. 9.4.5.7.3 Error Correction
          4. 9.4.5.7.4 Embedded Sync Ancillary Data
          5. 9.4.5.7.5 Embedded Sync RGB 24-bit Data
        8. 9.4.5.8  Source Multiplexing
          1. 9.4.5.8.1  Multiplexing Scenarios
          2. 9.4.5.8.2  2-Way Multiplexing
          3. 9.4.5.8.3  4-Way Multiplexing
          4. 9.4.5.8.4  Line Multiplexing
          5. 9.4.5.8.5  Super Frame Concept in Line Multiplexing
          6. 9.4.5.8.6  8-bit Data Interface in Line Multiplexing
          7. 9.4.5.8.7  16-bit Data Interface in Line Multiplexing
          8. 9.4.5.8.8  Split Lines in Line Multiplex Mode
          9. 9.4.5.8.9  Meta Data
          10. 9.4.5.8.10 TI Line Mux Mode, Split Lines, and Channel ID Remapping
        9. 9.4.5.9  Channel ID Extraction for 2x/4x Multiplexed Source
          1. 9.4.5.9.1 Channel ID Extraction Overview
          2. 9.4.5.9.2 Channel ID Embedded in Protection Bits for 2- and 4-Way Multiplexing
          3. 9.4.5.9.3 Channel ID Embedded in Horizontal Blanking Pixel Data for 2- and 4-Way Multiplexing
        10. 9.4.5.10 Embedded Sync Mux Modes and Data Bus Widths
        11. 9.4.5.11 Ancillary and Active Video Cropping
        12. 9.4.5.12 Interrupts
        13. 9.4.5.13 VDET Interrupt
        14. 9.4.5.14 Source Video Size
        15. 9.4.5.15 Clipping
        16. 9.4.5.16 Current and Last FID Value
        17. 9.4.5.17 Disable Handling
        18. 9.4.5.18 Picture Size Interrupt
        19. 9.4.5.19 Discrete Sync Signals
          1. 9.4.5.19.1 VBLNK and HBLNK
          2. 9.4.5.19.2 BLNK and ACTVID (1)
          3. 9.4.5.19.3 VBLNK and ACTVID(2)
          4. 9.4.5.19.4 VBLNK and HSYNC
          5. 9.4.5.19.5 VSYNC and HBLNK
          6. 9.4.5.19.6 VSYNC and ACTIVID(1)
          7. 9.4.5.19.7 VSYNC and ACTIVID(2)
          8. 9.4.5.19.8 VSYNC and HSYNC
          9. 9.4.5.19.9 Line and Pixel Capture Examples
        20. 9.4.5.20 VIP Overflow Detection and Recovery
      6. 9.4.6 VIP Color Space Converter (CSC)
        1. 9.4.6.1 CSC Features
        2. 9.4.6.2 CSC Functional Description
          1. 9.4.6.2.1 HDTV Application
            1. 9.4.6.2.1.1 HDTV Application with Video Data Range
            2. 9.4.6.2.1.2 HDTV Application with Graphics Data Range
            3. 9.4.6.2.1.3 Quantized Coefficients for Color Space Converter in HDTV
          2. 9.4.6.2.2 SDTV Application
            1. 9.4.6.2.2.1 SDTV Application with Video Data Range
            2. 9.4.6.2.2.2 SDTV Application with Graphics Data Range
            3. 9.4.6.2.2.3 Quantized Coefficients for Color Space Converter in SDTV
        3. 9.4.6.3 CSC Bypass Mode
      7. 9.4.7 VIP Scaler (SC)
        1. 9.4.7.1 SC Features
        2. 9.4.7.2 SC Functional Description
          1. 9.4.7.2.1 Trimmer
          2. 9.4.7.2.2 1555
          3. 9.4.7.2.3 Peaking
          4. 9.4.7.2.4 Vertical Scaler
            1. 9.4.7.2.4.1 Running Average Filter
            2. 9.4.7.2.4.2 Vertical Scaler Configuration Parameters
          5. 9.4.7.2.5 Horizontal Scaler
            1. 9.4.7.2.5.1 Half Decimation Filter
            2. 9.4.7.2.5.2 Polyphase Filter
            3. 9.4.7.2.5.3 Nonlinear Horizontal Scaling
            4. 9.4.7.2.5.4 Horizontal Scaler Configuration Registers
          6. 9.4.7.2.6 Basic Configurations
          7. 9.4.7.2.7 Coefficient Memory
            1. 9.4.7.2.7.1 Overview
            2. 9.4.7.2.7.2 Physical Coefficient SRAM Layout
            3. 9.4.7.2.7.3 Scaler Coefficients Packing on 128-bit VPI Control I/F
            4. 9.4.7.2.7.4 VPI Control I/F Memory Map for Scaler Coefficients
            5. 9.4.7.2.7.5 VPI Control Interface
            6. 9.4.7.2.7.6 Coefficient Table Selection Guide
        3. 9.4.7.3 SC Code
          1. 9.4.7.3.1 Generate Coefficient Memory Image
          2. 9.4.7.3.2 Scaler Configuration Calculation
          3. 9.4.7.3.3 Typical Configuration Values
        4. 9.4.7.4 SC Coefficient Data Files
          1. 9.4.7.4.1 HS Polyphase Filter Coefficients
            1. 9.4.7.4.1.1 ppfcoef_scale_eq_1_32_phases_flip.dat
            2. 9.4.7.4.1.2 ppfcoef_scale_eq_8div16_32_phases_flip.dat
            3. 9.4.7.4.1.3 ppfcoef_scale_eq_9div16_32_phases_flip.dat
            4. 9.4.7.4.1.4 ppfcoef_scale_eq_10div16_32_phases_flip.dat
            5. 9.4.7.4.1.5 ppfcoef_scale_eq_11div16_32_phases_flip.dat
            6. 9.4.7.4.1.6 ppfcoef_scale_eq_12div16_32_phases_flip.dat
            7. 9.4.7.4.1.7 ppfcoef_scale_eq_13div16_32_phases_flip.dat
            8. 9.4.7.4.1.8 ppfcoef_scale_eq_14div16_32_phases_flip.dat
            9. 9.4.7.4.1.9 ppfcoef_scale_eq_15div16_32_phases_flip.dat
          2. 9.4.7.4.2 VS Polyphase Filter Coefficients
            1. 9.4.7.4.2.1 ppfcoef_scale_eq_1_32_phases_ver_5tap_flip.dat
            2. 9.4.7.4.2.2 ppfcoef_scale_eq_3_32_phases_flip.dat
            3. 9.4.7.4.2.3 ppfcoef_scale_eq_4_32_phases_flip.dat
            4. 9.4.7.4.2.4 ppfcoef_scale_eq_5_32_phases_flip.dat
            5. 9.4.7.4.2.5 ppfcoef_scale_eq_6_32_phases_flip.dat
            6. 9.4.7.4.2.6 ppfcoef_scale_eq_7_32_phases_flip.dat
              1. 9.4.7.4.2.6.1 ppfcoef_scale_eq_8div16_32_phases_ver_5tap_flip.dat
              2. 9.4.7.4.2.6.2 ppfcoef_scale_eq_9div16_32_phases_ver_5tap_flip.dat
              3. 9.4.7.4.2.6.3 ppfcoef_scale_eq_10div16_32_phases_ver_5tap_flip.dat
              4. 9.4.7.4.2.6.4 ppfcoef_scale_eq_11div16_32_phases_ver_5tap_flip.dat
              5. 9.4.7.4.2.6.5 ppfcoef_scale_eq_12div16_32_phases_ver_5tap_flip.dat
              6. 9.4.7.4.2.6.6 ppfcoef_scale_eq_13div16_32_phases_ver_5tap_flip.dat
              7. 9.4.7.4.2.6.7 ppfcoef_scale_eq_14div16_32_phases_ver_5tap_flip.dat
              8. 9.4.7.4.2.6.8 ppfcoef_scale_eq_15div16_32_phases_ver_5tap_flip.dat
          3. 9.4.7.4.3 VS (Bilinear Filter Coefficients)
            1. 9.4.7.4.3.1 ppfcoef_scale_eq_1_32_phases_flip_PPF3_peak5_gain_eq_1_25.dat
      8. 9.4.8 VIP Video Port Direct Memory Access (VPDMA)
        1. 9.4.8.1  VPDMA Introduction
        2. 9.4.8.2  VPDMA Basic Definitions
          1. 9.4.8.2.1 Client
          2. 9.4.8.2.2 Channel
          3. 9.4.8.2.3 List
          4. 9.4.8.2.4 Data Formats Supported
        3. 9.4.8.3  1612
        4. 9.4.8.4  VPDMA Client Buffering and Functionality
        5. 9.4.8.5  VPDMA Channels Assignment
        6. 9.4.8.6  VPDMA MFLAG Mechanism
        7. 9.4.8.7  VPDMA Interrupts
        8. 9.4.8.8  VPDMA Descriptors
          1. 9.4.8.8.1 Data Transfer Descriptors
            1. 9.4.8.8.1.1 Data Packet Descriptor Word 0 (Data)
              1. 9.4.8.8.1.1.1 Data Type
              2. 9.4.8.8.1.1.2 Notify
              3. 9.4.8.8.1.1.3 Field
              4. 9.4.8.8.1.1.4 Even Line Skip
              5. 9.4.8.8.1.1.5 Odd Line Skip
              6. 9.4.8.8.1.1.6 Line Stride
            2. 9.4.8.8.1.2 Data Packet Descriptor Word 1
              1. 9.4.8.8.1.2.1 Line Length
              2. 9.4.8.8.1.2.2 Transfer Height
            3. 9.4.8.8.1.3 Data Packet Descriptor Word 2
              1. 9.4.8.8.1.3.1 Start Address
            4. 9.4.8.8.1.4 Data Packet Descriptor Word 3
              1. 9.4.8.8.1.4.1 Packet Type
              2. 9.4.8.8.1.4.2 Mode
              3. 9.4.8.8.1.4.3 Direction
              4. 9.4.8.8.1.4.4 Channel
              5. 9.4.8.8.1.4.5 Priority
              6. 9.4.8.8.1.4.6 Next Channel
            5. 9.4.8.8.1.5 Data Packet Descriptor Word 4
              1. 9.4.8.8.1.5.1 Inbound data
                1. 9.4.8.8.1.5.1.1 Frame Width
                2. 9.4.8.8.1.5.1.2 Frame Height
              2. 9.4.8.8.1.5.2 Outbound data
                1. 9.4.8.8.1.5.2.1 Descriptor Write Address
                2. 9.4.8.8.1.5.2.2 Write Descriptor
                3. 9.4.8.8.1.5.2.3 Drop Data
            6. 9.4.8.8.1.6 Data Packet Descriptor Word 5
              1. 9.4.8.8.1.6.1 Outbound data
                1. 9.4.8.8.1.6.1.1 Max Width
                2. 9.4.8.8.1.6.1.2 Max Height
          2. 9.4.8.8.2 Configuration Descriptor
            1. 9.4.8.8.2.1 Configuration Descriptor Header Word0
            2. 9.4.8.8.2.2 Configuration Descriptor Header Word1
              1. 9.4.8.8.2.2.1 Number of Data Words
            3. 9.4.8.8.2.3 Configuration Descriptor Header Word2
              1. 9.4.8.8.2.3.1 Payload Location
            4. 9.4.8.8.2.4 Configuration Descriptor Header Word3
              1. 9.4.8.8.2.4.1 Packet Type
              2. 9.4.8.8.2.4.2 Direct
              3. 9.4.8.8.2.4.3 Class
                1. 9.4.8.8.2.4.3.1 Address Data Block Format
              4. 9.4.8.8.2.4.4 Destination
              5. 9.4.8.8.2.4.5 Descriptor Length
          3. 9.4.8.8.3 Control Descriptor
            1. 9.4.8.8.3.1 Generic Control Descriptor Format
            2. 9.4.8.8.3.2 Control Descriptor Header Description
              1. 9.4.8.8.3.2.1 Packet Type
              2. 9.4.8.8.3.2.2 Source
              3. 9.4.8.8.3.2.3 Control
            3. 9.4.8.8.3.3 Control Descriptor Types
              1. 9.4.8.8.3.3.1 Sync on Client
              2. 9.4.8.8.3.3.2 Sync on List
              3. 9.4.8.8.3.3.3 Sync on External Event
              4. 9.4.8.8.3.3.4 Sync on Channel
              5. 9.4.8.8.3.3.5 Sync on LM Timer
              6. 9.4.8.8.3.3.6 Change Client Interrupt
              7. 9.4.8.8.3.3.7 Send Interrupt
              8. 9.4.8.8.3.3.8 Reload List
              9. 9.4.8.8.3.3.9 Abort Channel
        9. 9.4.8.9  VPDMA Configuration
          1. 9.4.8.9.1 Regular List
          2. 9.4.8.9.2 Video Input Ports
            1. 9.4.8.9.2.1 Multiplexed Data Streams
            2. 9.4.8.9.2.2 Single YUV Color Separate
            3. 9.4.8.9.2.3 Dual YUV Interleaved
        10. 9.4.8.10 VPDMA Data Formats
          1. 9.4.8.10.1 YUV Data Formats
            1. 9.4.8.10.1.1 Y 4:4:4 (Data Type 0)
            2. 9.4.8.10.1.2 Y 4:2:2 (Data Type 1)
            3. 9.4.8.10.1.3 Y 4:2:0 (Data Type 2)
            4. 9.4.8.10.1.4 C 4:4:4 (Data Type 4)
            5. 9.4.8.10.1.5 C 4:2:2 (Data Type 5)
            6. 9.4.8.10.1.6 C 4:2:0 (Data Type 6)
            7. 9.4.8.10.1.7 YC 4:2:2 (Data Type 7)
            8. 9.4.8.10.1.8 YC 4:4:4 (Data Type 8)
            9. 9.4.8.10.1.9 CY 4:2:2 (Data Type 23)
          2. 9.4.8.10.2 RGB Data Formats
            1. 9.4.8.10.2.1  RGB16-565 (Data Type 0)
            2. 9.4.8.10.2.2  ARGB-1555 (Data Type 1)
            3. 9.4.8.10.2.3  ARGB-4444 (Data Type 2)
            4. 9.4.8.10.2.4  RGBA-5551 (Data Type 3)
            5. 9.4.8.10.2.5  RGBA-4444 (Data Type 4)
            6. 9.4.8.10.2.6  ARGB24-6666 (Data Type 5)
            7. 9.4.8.10.2.7  RGB24-888 (Data Type 6)
            8. 9.4.8.10.2.8  ARGB32-8888 (Data Type 7)
            9. 9.4.8.10.2.9  RGBA24-6666 (Data Type 8)
            10. 9.4.8.10.2.10 RGBA32-8888 (Data Type 9)
          3. 9.4.8.10.3 Miscellaneous Data Type
    5. 9.5 VIP Register Manual
      1. 9.5.1 VIP Instance Summary
      2. 9.5.2 VIP Top Level Registers
        1. 9.5.2.1 VIP Top Level Register Summary
        2. 9.5.2.2 VIP Top Level Register Description
      3. 9.5.3 VIP Parser Registers
        1. 9.5.3.1 VIP Parser Register Summary
        2. 9.5.3.2 VIP Parser Register Description
      4. 9.5.4 VIP CSC Registers
        1. 9.5.4.1 VIP CSC Register Summary
        2. 9.5.4.2 VIP CSC Register Description
      5. 9.5.5 VIP SC registers
        1. 9.5.5.1 VIP SC Register Summary
        2. 9.5.5.2 VIP SC Register Description
      6. 9.5.6 VIP VPDMA Registers
        1. 9.5.6.1 VIP VPDMA Register Summary
        2. 9.5.6.2 VIP VPDMA Register Description
  12. 10Video Processing Engine
    1. 10.1 VPE Overview
    2. 10.2 VPE Integration
    3. 10.3 VPE Functional Description
      1. 10.3.1  VPE Block Diagram
      2. 10.3.2  VPE VC1 Range Mapping/Range Reduction
      3. 10.3.3  VPE Deinterlacer (DEI)
        1. 10.3.3.1 Functional Description
        2. 10.3.3.2 Bypass Mode
        3. 10.3.3.3 1734
          1. 10.3.3.3.1 VPDMA Interface
          2. 10.3.3.3.2 MDT
          3. 10.3.3.3.3 EDI
          4. 10.3.3.3.4 FMD
          5. 10.3.3.3.5 MUX
          6. 10.3.3.3.6 LINE BUFFER
      4. 10.3.4  VPE Scaler (SC)
        1. 10.3.4.1 SC Features
        2. 10.3.4.2 SC Functional Description
          1. 10.3.4.2.1 Trimmer
          2. 10.3.4.2.2 1745
          3. 10.3.4.2.3 Peaking
          4. 10.3.4.2.4 Vertical Scaler
            1. 10.3.4.2.4.1 Running Average Filter
            2. 10.3.4.2.4.2 Vertical Scaler Configuration Parameters
          5. 10.3.4.2.5 Horizontal Scaler
            1. 10.3.4.2.5.1 Half Decimation Filter
            2. 10.3.4.2.5.2 Polyphase Filter
            3. 10.3.4.2.5.3 Nonlinear Horizontal Scaling
            4. 10.3.4.2.5.4 Horizontal Scaler Configuration Registers
          6. 10.3.4.2.6 Basic Configurations
          7. 10.3.4.2.7 Coefficient Memory
            1. 10.3.4.2.7.1 Overview
            2. 10.3.4.2.7.2 Physical Coefficient SRAM Layout
            3. 10.3.4.2.7.3 Scaler Coefficients Packing on 128-bit VPI Control I/F
            4. 10.3.4.2.7.4 VPI Control I/F Memory Map for Scaler Coefficients
            5. 10.3.4.2.7.5 VPI Control Interface
            6. 10.3.4.2.7.6 Coefficient Table Selection Guide
        3. 10.3.4.3 SC Code
          1. 10.3.4.3.1 Generate Coefficient Memory Image
          2. 10.3.4.3.2 Scaler Configuration Calculation
          3. 10.3.4.3.3 Typical Configuration Values
        4. 10.3.4.4 SC Coefficient Data Files
          1. 10.3.4.4.1 HS Polyphase Filter Coefficients
            1. 10.3.4.4.1.1 ppfcoef_scale_eq_1_32_phases_flip.dat
            2. 10.3.4.4.1.2 ppfcoef_scale_eq_8div16_32_phases_flip.dat
            3. 10.3.4.4.1.3 ppfcoef_scale_eq_9div16_32_phases_flip.dat
            4. 10.3.4.4.1.4 ppfcoef_scale_eq_10div16_32_phases_flip.dat
            5. 10.3.4.4.1.5 ppfcoef_scale_eq_11div16_32_phases_flip.dat
            6. 10.3.4.4.1.6 ppfcoef_scale_eq_12div16_32_phases_flip.dat
            7. 10.3.4.4.1.7 ppfcoef_scale_eq_13div16_32_phases_flip.dat
            8. 10.3.4.4.1.8 ppfcoef_scale_eq_14div16_32_phases_flip.dat
            9. 10.3.4.4.1.9 ppfcoef_scale_eq_15div16_32_phases_flip.dat
          2. 10.3.4.4.2 VS Polyphase Filter Coefficients
            1. 10.3.4.4.2.1 ppfcoef_scale_eq_1_32_phases_ver_5tap_flip.dat
            2. 10.3.4.4.2.2 ppfcoef_scale_eq_3_32_phases_flip.dat
            3. 10.3.4.4.2.3 ppfcoef_scale_eq_4_32_phases_flip.dat
            4. 10.3.4.4.2.4 ppfcoef_scale_eq_5_32_phases_flip.dat
            5. 10.3.4.4.2.5 ppfcoef_scale_eq_6_32_phases_flip.dat
            6. 10.3.4.4.2.6 ppfcoef_scale_eq_7_32_phases_flip.dat
              1. 10.3.4.4.2.6.1 ppfcoef_scale_eq_8div16_32_phases_ver_5tap_flip.dat
              2. 10.3.4.4.2.6.2 ppfcoef_scale_eq_9div16_32_phases_ver_5tap_flip.dat
              3. 10.3.4.4.2.6.3 ppfcoef_scale_eq_10div16_32_phases_ver_5tap_flip.dat
              4. 10.3.4.4.2.6.4 ppfcoef_scale_eq_11div16_32_phases_ver_5tap_flip.dat
              5. 10.3.4.4.2.6.5 ppfcoef_scale_eq_12div16_32_phases_ver_5tap_flip.dat
              6. 10.3.4.4.2.6.6 ppfcoef_scale_eq_13div16_32_phases_ver_5tap_flip.dat
              7. 10.3.4.4.2.6.7 ppfcoef_scale_eq_14div16_32_phases_ver_5tap_flip.dat
              8. 10.3.4.4.2.6.8 ppfcoef_scale_eq_15div16_32_phases_ver_5tap_flip.dat
              9. 10.3.4.4.2.6.9 ppcoef_scale_1x_ver_5tap.dat
          3. 10.3.4.4.3 VS (Bilinear Filter Coefficients)
            1. 10.3.4.4.3.1 ppfcoef_scale_eq_1_32_phases_flip_PPF3_peak5_gain_eq_1_25.dat
      5. 10.3.5  VPE Color Space Converter (CSC)
        1. 10.3.5.1 CSC Features
        2. 10.3.5.2 CSC Functional Description
        3. 10.3.5.3 1799
          1. 10.3.5.3.1 HDTV Application
            1. 10.3.5.3.1.1 HDTV Application with Video Data Range
            2. 10.3.5.3.1.2 HDTV Application with Graphics Data Range
            3. 10.3.5.3.1.3 Quantized Coefficients for Color Space Converter in HDTV
          2. 10.3.5.3.2 SDTV Application
            1. 10.3.5.3.2.1 SDTV Application with Video Data Range
            2. 10.3.5.3.2.2 SDTV Application with Graphics Data Range
            3. 10.3.5.3.2.3 Quantized Coefficients for Color Space Converter in SDTV
        4. 10.3.5.4 CSC Bypass Mode
      6. 10.3.6  VPE Chroma Up-Sampler (CHR_US)
        1. 10.3.6.1 Features
        2. 10.3.6.2 Functional Description
        3. 10.3.6.3 For Interlaced YUV420 Input Data
        4. 10.3.6.4 Edge Effects
        5. 10.3.6.5 Modes of Operation (VPDMA)
        6. 10.3.6.6 Coefficient Configuration
      7. 10.3.7  VPE Chroma Down-Sampler (CHR_DS)
      8. 10.3.8  VPE YUV422 to YUV444 Conversion
      9. 10.3.9  VPE Video Port Direct Memory Access (VPDMA)
        1. 10.3.9.1 VPDMA Introduction
        2. 10.3.9.2 VPDMA Basic Definitions
          1. 10.3.9.2.1 Client
          2. 10.3.9.2.2 Channel
          3. 10.3.9.2.3 List
          4. 10.3.9.2.4 Data Formats Supported
        3. 10.3.9.3 VPDMA Client Buffering and Functionality
        4. 10.3.9.4 VPDMA Channels Assignment
        5. 10.3.9.5 VPDMA Interrupts
        6. 10.3.9.6 VPDMA Descriptors
          1. 10.3.9.6.1 Data Transfer Descriptors
            1. 10.3.9.6.1.1 Data Packet Descriptor Word 0 (Data)
              1. 10.3.9.6.1.1.1 Data Type
              2. 10.3.9.6.1.1.2 Notify
              3. 10.3.9.6.1.1.3 Field
              4. 10.3.9.6.1.1.4 1D
              5. 10.3.9.6.1.1.5 Even Line Skip
              6. 10.3.9.6.1.1.6 Odd Line Skip
              7. 10.3.9.6.1.1.7 Line Stride
            2. 10.3.9.6.1.2 Data Packet Descriptor Word 1
              1. 10.3.9.6.1.2.1 Line Length
              2. 10.3.9.6.1.2.2 Transfer Height
            3. 10.3.9.6.1.3 Data Packet Descriptor Word 2
              1. 10.3.9.6.1.3.1 Start Address
            4. 10.3.9.6.1.4 Data Packet Descriptor Word 3
              1. 10.3.9.6.1.4.1 Packet Type
              2. 10.3.9.6.1.4.2 Mode
              3. 10.3.9.6.1.4.3 Direction
              4. 10.3.9.6.1.4.4 Channel
              5. 10.3.9.6.1.4.5 Priority
              6. 10.3.9.6.1.4.6 Next Channel
            5. 10.3.9.6.1.5 Data Packet Descriptor Word 4
              1. 10.3.9.6.1.5.1 Inbound data
                1. 10.3.9.6.1.5.1.1 Frame Width
                2. 10.3.9.6.1.5.1.2 Frame Height
              2. 10.3.9.6.1.5.2 Outbound data
                1. 10.3.9.6.1.5.2.1 Descriptor Write Address
                2. 10.3.9.6.1.5.2.2 Write Descriptor
                3. 10.3.9.6.1.5.2.3 Drop Data
                4. 10.3.9.6.1.5.2.4 Use Descriptor Register
            6. 10.3.9.6.1.6 Data Packet Descriptor Word 5
              1. 10.3.9.6.1.6.1 Outbound data
                1. 10.3.9.6.1.6.1.1 Max Width
                2. 10.3.9.6.1.6.1.2 Max Height
            7. 10.3.9.6.1.7 Data Packet Descriptor Word 6/7 (Data)
          2. 10.3.9.6.2 Configuration Descriptor
            1. 10.3.9.6.2.1 Configuration Descriptor Header Word0
            2. 10.3.9.6.2.2 Configuration Descriptor Header Word1
              1. 10.3.9.6.2.2.1 Number of Data Words
            3. 10.3.9.6.2.3 Configuration Descriptor Header Word2
              1. 10.3.9.6.2.3.1 Payload Location
            4. 10.3.9.6.2.4 Configuration Descriptor Header Word3
              1. 10.3.9.6.2.4.1 Packet Type
              2. 10.3.9.6.2.4.2 Direct
              3. 10.3.9.6.2.4.3 Class
                1. 10.3.9.6.2.4.3.1 Address Data Block Format
              4. 10.3.9.6.2.4.4 Destination
              5. 10.3.9.6.2.4.5 Descriptor Length
          3. 10.3.9.6.3 Control Descriptor
            1. 10.3.9.6.3.1 Generic Control Descriptor Format
            2. 10.3.9.6.3.2 Control Descriptor Header Description
              1. 10.3.9.6.3.2.1 Packet Type
              2. 10.3.9.6.3.2.2 Source
              3. 10.3.9.6.3.2.3 Control
            3. 10.3.9.6.3.3 Control Descriptor Types
              1. 10.3.9.6.3.3.1 Sync on Client
              2. 10.3.9.6.3.3.2 Sync on List
              3. 10.3.9.6.3.3.3 Sync on External Event
              4. 10.3.9.6.3.3.4 Sync on Channel
              5. 10.3.9.6.3.3.5 Sync on LM Timer
              6. 10.3.9.6.3.3.6 Change Client Interrupt
              7. 10.3.9.6.3.3.7 Send Interrupt
              8. 10.3.9.6.3.3.8 Reload List
              9. 10.3.9.6.3.3.9 Abort Channel
        7. 10.3.9.7 VPDMA Configuration
          1. 10.3.9.7.1 Regular List
          2. 10.3.9.7.2 Video Input Ports
            1. 10.3.9.7.2.1 Single YUV Color Separate
            2. 10.3.9.7.2.2 Dual YUV Interleaved
            3. 10.3.9.7.2.3 Single RGB Stream
        8. 10.3.9.8 VPDMA Data Formats
          1. 10.3.9.8.1 YUV Data Formats
            1. 10.3.9.8.1.1 Y 4:4:4 (Data Type 0)
            2. 10.3.9.8.1.2 Y 4:2:2 (Data Type 1)
            3. 10.3.9.8.1.3 Y 4:2:0 (Data Type 2)
            4. 10.3.9.8.1.4 C 4:4:4 (Data Type 4)
            5. 10.3.9.8.1.5 C 4:2:2 (Data Type 5)
            6. 10.3.9.8.1.6 C 4:2:0 (Data Type 6)
            7. 10.3.9.8.1.7 YC 4:2:2 (Data Type 7)
            8. 10.3.9.8.1.8 YC 4:4:4 (Data Type 8)
            9. 10.3.9.8.1.9 CY 4:2:2 (Data Type 23)
          2. 10.3.9.8.2 RGB Data Formats
            1. 10.3.9.8.2.1 Input Data Formats
              1. 10.3.9.8.2.1.1  RGB16-565 (Data Type 0)
              2. 10.3.9.8.2.1.2  ARGB-1555 (Data Type 1)
              3. 10.3.9.8.2.1.3  ARGB-4444 (Data Type 2)
              4. 10.3.9.8.2.1.4  RGBA-5551 (Data Type 3)
              5. 10.3.9.8.2.1.5  RGBA-4444 (Data Type 4)
              6. 10.3.9.8.2.1.6  ARGB24-6666 (Data Type 5)
              7. 10.3.9.8.2.1.7  RGB24-888 (Data Type 6)
              8. 10.3.9.8.2.1.8  ARGB32-8888 (Data Type 7)
              9. 10.3.9.8.2.1.9  RGBA24-6666 (Data Type 8)
              10. 10.3.9.8.2.1.10 RGBA32-8888 (Data Type 9)
            2. 10.3.9.8.2.2 Output Data Formats
              1. 10.3.9.8.2.2.1  RGB16-565 (Data Type 0)
              2. 10.3.9.8.2.2.2  ARGB-1555 (Data Type 1)
              3. 10.3.9.8.2.2.3  ARGB-4444 (Data Type 2)
              4. 10.3.9.8.2.2.4  RGBA-5551 (Data Type 3)
              5. 10.3.9.8.2.2.5  RGBA-4444 (Data Type 4)
              6. 10.3.9.8.2.2.6  ARGB24-6666 (Data Type 5)
              7. 10.3.9.8.2.2.7  RGB24-888 (Data Type 6)
              8. 10.3.9.8.2.2.8  ARGB32-8888 (Data Type 7)
              9. 10.3.9.8.2.2.9  RGBA24-6666 (Data Type 8)
              10. 10.3.9.8.2.2.10 RGBA32-8888 (Data Type 9)
          3. 10.3.9.8.3 Miscellaneous Data Type
      10. 10.3.10 VPE Software Reset
      11. 10.3.11 VPE Power and Clocks Management
        1. 10.3.11.1 VPE Clocks
        2. 10.3.11.2 VPE Idle Mode
        3. 10.3.11.3 VPE StandBy Mode
    4. 10.4 VPE Register Manual
      1. 10.4.1 VPE Instance Summary
      2. 10.4.2 VPE_CSC Registers
        1. 10.4.2.1 VPE_CSC Register Summary
        2. 10.4.2.2 VPE_CSC Register Description
      3. 10.4.3 VPE_SC Registers
        1. 10.4.3.1 VPE_SC Register Summary
        2. 10.4.3.2 VPE_SC Register Description
      4. 10.4.4 VPE_CHR_US Registers
        1. 10.4.4.1 VPE_CHR_US Register Summary
        2. 10.4.4.2 VPE_CHR_US Register Description
      5. 10.4.5 VPE_DEI Registers
        1. 10.4.5.1 VPE_DEI Register Summary
        2. 10.4.5.2 VPE_DEI Register Description
      6. 10.4.6 VPE_VPDMA Registers
        1. 10.4.6.1 VPE_VPDMA Register Summary
        2. 10.4.6.2 VPE_VPDMA Register Description
      7. 10.4.7 VPE_TOP_LEVEL Registers
        1. 10.4.7.1 VPE_TOP_LEVEL Register Summary
        2. 10.4.7.2 VPE_TOP_LEVEL Register Description
  13. 11Display Subsystem
    1. 11.1 Display Subsystem Overview
      1. 11.1.1 Display Subsystem Environment
        1. 11.1.1.1 Display Subsystem LCD Support
          1. 11.1.1.1.1 Display Subsystem LCD with Parallel Interfaces
        2. 11.1.1.2 Display Subsystem TV Display Support
          1. 11.1.1.2.1 Display Subsystem TV With Parallel Interfaces
          2. 11.1.1.2.2 Display Subsystem TV With Serial Interfaces
      2. 11.1.2 Display Subsystem Integration
        1. 11.1.2.1 Display Subsystem Clocks
        2. 11.1.2.2 Display Subsystem Resets
        3. 11.1.2.3 Display Subsystem Power Management
          1. 11.1.2.3.1 Display Subsystem Standby Mode
          2. 11.1.2.3.2 1972
          3. 11.1.2.3.3 Display Subsystem Wake-Up Mode
      3. 11.1.3 Display Subsystem DPLL Controllers Functional Description
        1. 11.1.3.1 DPLL Controllers Overview
        2. 11.1.3.2 OCP2SCP2 Functional Description
          1. 11.1.3.2.1 OCP2SCP2 Reset
            1. 11.1.3.2.1.1 Hardware Reset
            2. 11.1.3.2.1.2 Software Reset
          2. 11.1.3.2.2 OCP2SCP2 Power Management
            1. 11.1.3.2.2.1 Idle Mode
            2. 11.1.3.2.2.2 Clock Gating
          3. 11.1.3.2.3 OCP2SCP2 Timing Registers
        3. 11.1.3.3 DPLL_VIDEO Functional Description
          1. 11.1.3.3.1 DPLL_VIDEO Controller Architecture
          2. 11.1.3.3.2 DPLL_VIDEO Operations
          3. 11.1.3.3.3 DPLL_VIDEO Error Handling
          4. 11.1.3.3.4 DPLL_VIDEO Software Reset
          5. 11.1.3.3.5 DPLL_VIDEO Power Management
          6. 11.1.3.3.6 DPLL_VIDEO HSDIVIDER Loading Operation
          7. 11.1.3.3.7 DPLL_VIDEO Clock Sequence
          8. 11.1.3.3.8 DPLL_VIDEO Go Sequence
          9. 11.1.3.3.9 DPLL_VIDEO Recommended Values
        4. 11.1.3.4 DPLL_HDMI Functional Description
          1. 11.1.3.4.1  DPLL_HDMI and PLLCTRL_HDMI Overview
          2. 11.1.3.4.2  DPLL_HDMI and PLLCTRL_HDMI Architecture
          3. 11.1.3.4.3  DPLL_HDMI Operations
          4. 11.1.3.4.4  DPLL_HDMI Register Access
          5. 11.1.3.4.5  DPLL_HDMI Error Handling
          6. 11.1.3.4.6  DPLL_HDMI Software Reset
          7. 11.1.3.4.7  DPLL_HDMI Power Management
          8. 11.1.3.4.8  DPLL_HDMI Lock Sequence
          9. 11.1.3.4.9  DPLL_HDMI Go Sequence
          10. 11.1.3.4.10 DPLL_HDMI Recommended Values
      4. 11.1.4 Display Subsystem Programming Guide
      5. 11.1.5 Display Subsystem Register Manual
        1. 11.1.5.1 Display Subsystem Instance Summary
        2. 11.1.5.2 Display Subsystem Registers
          1. 11.1.5.2.1 Display Subsystem Registers Mapping Summary
          2. 11.1.5.2.2 Display Subsystem Register Description
        3. 11.1.5.3 OCP2SCP2 registers
          1. 11.1.5.3.1 OCP2SCP2 Register Summary
          2. 11.1.5.3.2 OCP2SCP Register Description
        4. 11.1.5.4 DPLL_VIDEO Registers
          1. 11.1.5.4.1 DPLL_VIDEO Register Summary
          2. 11.1.5.4.2 DPLL_VIDEO Register Description
        5. 11.1.5.5 DPLL_HDMI Registers
          1. 11.1.5.5.1 DPLL_HDMI Registers Mapping Summary
          2. 11.1.5.5.2 DPLL_HDMI Register Description
        6. 11.1.5.6 HDMI_WP Registers
          1. 11.1.5.6.1 HDMI_WP Registers Mapping Summary
          2. 11.1.5.6.2 HDMI_WP Register Description
        7. 11.1.5.7 DSI Registers
          1. 11.1.5.7.1 DSI Register Summary
          2. 11.1.5.7.2 DSI Register Description
    2. 11.2 Display Controller
      1. 11.2.1 DISPC Overview
      2. 11.2.2 DISPC Environment
        1. 11.2.2.1 DISPC LCD Output and Data Format for the Parallel Interface
        2. 11.2.2.2 DISPC Transaction Timing Diagrams
        3. 11.2.2.3 DISPC TV Output and Data Format for the Parallel Interface
      3. 11.2.3 DISPC Integration
      4. 11.2.4 DISPC Functional Description
        1. 11.2.4.1  DISPC Clock Configuration
        2. 11.2.4.2  DISPC Software Reset
        3. 11.2.4.3  DISPC Power Management
          1. 11.2.4.3.1 DISPC Idle Mode
          2. 11.2.4.3.2 DISPC StandBy Mode
          3. 11.2.4.3.3 DISPC Wakeup
        4. 11.2.4.4  DISPC Interrupt Requests
        5. 11.2.4.5  DISPC DMA Requests
        6. 11.2.4.6  DISPC DMA Engine
          1. 11.2.4.6.1 DISPC Addressing and Bursts
          2. 11.2.4.6.2 DISPC Immediate Base Address Flip Mechanism
          3. 11.2.4.6.3 DISPC DMA Buffers
            1. 11.2.4.6.3.1 DISPC READ DMA Buffers (GFX and VID Pipelines)
            2. 11.2.4.6.3.2 DISPC WRITE DMA Buffer (WB Pipeline)
          4. 11.2.4.6.4 DISPC MFLAG Mechanism and Arbitration
          5. 11.2.4.6.5 DISPC Predecimation
          6. 11.2.4.6.6 DISPC Progressive-to-Interlaced Format Conversion
          7. 11.2.4.6.7 DISPC Arbitration
          8. 11.2.4.6.8 DISPC DMA Power Modes
            1. 11.2.4.6.8.1 DISPC DMA Low-Power Mode
            2. 11.2.4.6.8.2 DISPC DMA Ultralow-Power Mode
        7. 11.2.4.7  DISPC Rotation and Mirroring
        8. 11.2.4.8  DISPC Memory Format
        9. 11.2.4.9  DISPC Graphics Pipeline
          1. 11.2.4.9.1 DISPC Replication Logic
          2. 11.2.4.9.2 DISPC Antiflicker Filter
        10. 11.2.4.10 DISPC Video Pipelines
          1. 11.2.4.10.1 DISPC Replication Logic
          2. 11.2.4.10.2 DISPC VC-1 Range Mapping Unit
          3. 11.2.4.10.3 DISPC CSC Unit YUV to RGB
            1. 11.2.4.10.3.1 DISPC Chrominance Resampling
          4. 11.2.4.10.4 DISPC Scaler Unit
            1. 11.2.4.10.4.1 DISPC Scaling Algorithms
            2. 11.2.4.10.4.2 DISPC Scaling limitations
        11. 11.2.4.11 DISPC Write-Back Pipeline
          1. 11.2.4.11.1 DISPC Write-Back CSC Unit RGB to YUV
          2. 11.2.4.11.2 DISPC Write-Back Scaler Unit
          3. 11.2.4.11.3 DISPC Write-Back RGB Truncation Logic
        12. 11.2.4.12 DISPC Hardware Cursor
        13. 11.2.4.13 DISPC LCD Outputs
          1. 11.2.4.13.1 DISPC Overlay Manager
            1. 11.2.4.13.1.1 DISPC Priority Rule
            2. 11.2.4.13.1.2 DISPC Alpha Blender
            3. 11.2.4.13.1.3 DISPC Transparency Color Keys
            4. 11.2.4.13.1.4 DISPC Overlay Optimization
          2. 11.2.4.13.2 DISPC Gamma Correction Unit
          3. 11.2.4.13.3 DISPC Color Phase Rotation Unit
          4. 11.2.4.13.4 DISPC Color Space Conversion
          5. 11.2.4.13.5 DISPC BT.656 and BT.1120 Modes
            1. 11.2.4.13.5.1 Blanking
            2. 11.2.4.13.5.2 EAV and SAV
          6. 11.2.4.13.6 DISPC Active Matrix
            1. 11.2.4.13.6.1 DISPC Spatial/Temporal Dithering
            2. 11.2.4.13.6.2 DISPC Multiple Cycle Output Format (TDM)
          7. 11.2.4.13.7 DISPC Synchronized Buffer Update
          8. 11.2.4.13.8 DISPC Timing Generator and Panel Settings
        14. 11.2.4.14 DISPC TV Output
          1. 11.2.4.14.1 DISPC Overlay Manager
          2. 11.2.4.14.2 DISPC Gamma Correction Unit
          3. 11.2.4.14.3 DISPC Synchronized Buffer Update
          4. 11.2.4.14.4 DISPC Timing and TV Format Settings
        15. 11.2.4.15 DISPC Frame Width Considerations
        16. 11.2.4.16 DISPC Extended 3D Support
          1. 11.2.4.16.1 DISPC Extended 3D Support - Line Alternative Format
          2. 11.2.4.16.2 2098
          3. 11.2.4.16.3 DISPC Extended 3D Support - Frame Packing Format Format
          4. 11.2.4.16.4 DISPC Extended 3D Support - DLP 3D Format
        17. 11.2.4.17 DISPC Shadow Registers
      5. 11.2.5 DISPC Programming Guide
        1. 11.2.5.1 DISPC Low-Level Programming Models
          1. 11.2.5.1.1 DISPC Global Initialization
            1. 11.2.5.1.1.1 DISPC Surrounding Modules Global Initialization
          2. 11.2.5.1.2 DISPC Operational Modes Configuration
            1. 11.2.5.1.2.1 DISPC DMA Configuration
              1. 11.2.5.1.2.1.1 DISPC Main Sequence – DISPC DMA Channel Configuration
            2. 11.2.5.1.2.2 DISPC GFX Pipeline Configuration
              1. 11.2.5.1.2.2.1 DISPC Main Sequence – Configure the GFX Pipeline
              2. 11.2.5.1.2.2.2 DISPC Subsequence – Configure the GFX Window
              3. 11.2.5.1.2.2.3 DISPC Subsequence – Configure the GFX Pipeline Processing
              4. 11.2.5.1.2.2.4 DISPC Subsequence – Configure the GFX Pipeline Layer Output
            3. 11.2.5.1.2.3 DISPC Video Pipeline Configuration
              1. 11.2.5.1.2.3.1 DISPC Main Sequence – Configure the Video Pipeline
              2. 11.2.5.1.2.3.2 DISPC Subsequence – Configure the Video Window
              3. 11.2.5.1.2.3.3 DISPC Subsequence – Configure the Video Pipeline Processing
              4. 11.2.5.1.2.3.4 DISPC Subsequence – Configure the VC-1 Range Mapping
              5. 11.2.5.1.2.3.5 DISPC Subsequence – Configure the Video Color Space Conversion
              6. 11.2.5.1.2.3.6 DISPC Subsequence – Configure the Video Scaler Unit
              7. 11.2.5.1.2.3.7 DISPC Subsequence – Configure the Video Pipeline Layer Output
            4. 11.2.5.1.2.4 DISPC WB Pipeline Configuration
              1. 11.2.5.1.2.4.1 DISPC Main Sequence – Configure the WB Pipeline
              2. 11.2.5.1.2.4.2 DISPC Subsequence – Configure the Capture Window
              3. 11.2.5.1.2.4.3 DISPC Subsequence – Configure the WB Scaler Unit
              4. 11.2.5.1.2.4.4 DISPC Subsequence – Configure the WB Color Space Conversion Unit
            5. 11.2.5.1.2.5 DISPC LCD Output Configuration
              1. 11.2.5.1.2.5.1 DISPC Main Sequence – Configure the LCD Output
              2. 11.2.5.1.2.5.2 DISPC Subsequence – Configure the Overlay Manager
              3. 11.2.5.1.2.5.3 DISPC Subsequence – Configure the Gamma Table for Gamma Correction
              4. 11.2.5.1.2.5.4 DISPC Subsequence – Configure the Color Phase Rotation
              5. 11.2.5.1.2.5.5 DISPC Subsequence – Configure the LCD Panel Timings and Parameters
              6. 11.2.5.1.2.5.6 DISPC Subsequence – Configure BT.656 or BT.1120 Mode
            6. 11.2.5.1.2.6 DISPC TV Output Configuration
              1. 11.2.5.1.2.6.1 DISPC Main Sequence – Configure the TV Output
                1. 11.2.5.1.2.6.1.1 DISPC Subsequence – Configure the TV Overlay Manager
                2. 11.2.5.1.2.6.1.2 DISPC Subsequence – Configure the Gamma Table for Gamma Correction
                3. 11.2.5.1.2.6.1.3 DISPC Subsequence – Configure the TV Panel Timings and Parameters
      6. 11.2.6 DISPC Register Manual
        1. 11.2.6.1 DISPC Instance Summary
        2. 11.2.6.2 DISPC Logical Register Mapping
        3. 11.2.6.3 DISPC Registers
          1. 11.2.6.3.1 DISPC Register Summary
          2. 11.2.6.3.2 DISPC Register Description
    3. 11.3 High-Definition Multimedia Interface
      1. 11.3.1 HDMI Overview
        1. 11.3.1.1 HDMI Main Features
        2. 11.3.1.2 HDMI Video Formats and Timings
          1. 11.3.1.2.1 HDMI CEA-861-D Video Formats and Timings
          2. 11.3.1.2.2 VESA DMT Video Formats and Timings
  14. 123D Graphics Accelerator
    1. 12.1 GPU Overview
      1. 12.1.1 GPU Features Overview
      2. 12.1.2 Graphics Feature Overview
    2. 12.2 GPU Integration
    3. 12.3 GPU Functional Description
      1. 12.3.1 GPU Block Diagram
      2. 12.3.2 GPU Clock Configuration
      3. 12.3.3 GPU Software Reset
      4. 12.3.4 GPU Power Management
      5. 12.3.5 GPU Thermal Management
      6. 12.3.6 GPU Interrupt Requests
    4. 12.4 GPU Register Manual
      1. 12.4.1 GPU Instance Summary
      2. 12.4.2 GPU Registers
        1. 12.4.2.1 GPU_WRAPPER Register Summary
        2. 12.4.2.2 GPU_WRAPPER Register Description
  15. 132D Graphics Accelerator
    1. 13.1 BB2D Overview
      1. 13.1.1 BB2D Key Features Overview
    2. 13.2 BB2D Integration
    3. 13.3 BB2D Functional Description
      1. 13.3.1 BB2D Block Diagram
      2. 13.3.2 BB2D Clock Configuration
      3. 13.3.3 BB2D Software Reset
      4. 13.3.4 BB2D Power Management
    4. 13.4 BB2D Register Manual
      1. 13.4.1 BB2D Instance Summary
      2. 13.4.2 BB2D Registers
        1. 13.4.2.1 BB2D Register Summary
        2. 13.4.2.2 BB2D Register Description
  16. 14Interconnect
    1. 14.1 Interconnect Overview
      1. 14.1.1 Terminology
      2. 14.1.2 Architecture Overview
    2. 14.2 L3_MAIN Interconnect
      1. 14.2.1 L3_MAIN Interconnect Overview
      2. 14.2.2 L3_MAIN Interconnect Integration
      3. 14.2.3 L3_MAIN Interconnect Functional Description
        1. 14.2.3.1 Module Use in L3_MAIN Interconnect
        2. 14.2.3.2 Module Distribution
          1. 14.2.3.2.1 L3_MAIN Interconnect Agents
          2. 14.2.3.2.2 L3_MAIN Connectivity Matrix
            1. 14.2.3.2.2.1 Clock Domain Mapping of the L3_MAIN Interconnect Modules
            2. 14.2.3.2.2.2 2195
          3. 14.2.3.2.3 Master NIU Identification
        3. 14.2.3.3 Bandwidth Regulators
        4. 14.2.3.4 Bandwidth Limiters
        5. 14.2.3.5 Flag Muxing
          1. 14.2.3.5.1 Flag Mux Time-out
        6. 14.2.3.6 Statistic Collectors Group
        7. 14.2.3.7 L3_MAIN Protection and Firewalls
          1. 14.2.3.7.1 L3_MAIN Firewall Reset
            1. 14.2.3.7.1.1 L3_MAIN Firewall – Exported Reset Values
          2. 14.2.3.7.2 Power Management
          3. 14.2.3.7.3 L3_MAIN Firewall Functionality
            1. 14.2.3.7.3.1 Protection Regions
            2. 14.2.3.7.3.2 L3_MAIN Firewall Registers Overview
            3. 14.2.3.7.3.3 Protection Mechanism per Region Examples
            4. 14.2.3.7.3.4 L3_MAIN Firewall Error Logging
            5. 14.2.3.7.3.5 L3_MAIN Firewall Default Configuration
        8. 14.2.3.8 L3_MAIN Interconnect Error Handling
          1. 14.2.3.8.1 Global Error-Routing Scheme
          2. 14.2.3.8.2 Slave NIU Error Logging
          3. 14.2.3.8.3 Flag Mux Error Logging
          4. 14.2.3.8.4 Severity Level of Standard and Custom Errors
          5. 14.2.3.8.5 Example for Decoding Standard/Custom Errors Logged in L3_MAIN
      4. 14.2.4 L3_MAIN Interconnect Programming Guide
        1. 14.2.4.1 L3 _MAIN Interconnect Low-Level Programming Models
          1. 14.2.4.1.1 Global Initialization
            1. 14.2.4.1.1.1 Global Initialization of Surrounding Modules
        2. 14.2.4.2 Operational Modes Configuration
          1. 14.2.4.2.1 L3_MAIN Interconnect Error Analysis Mode
            1. 14.2.4.2.1.1 Main Sequence: L3_MAIN Interconnect Error Analysis Mode
              1. 14.2.4.2.1.1.1 Subsequence: L3_MAIN Custom Error Identification
              2. 14.2.4.2.1.1.2 Subsequence: L3_MAIN Interconnect Protection Violation Error Identification
              3. 14.2.4.2.1.1.3 Subsequence: L3_MAIN Interconnect Standard Error Identification
              4. 14.2.4.2.1.1.4 Subsequence: L3_MAIN Interconnect FLAGMUX Configuration
      5. 14.2.5 L3_MAIN Interconnect Register Manual
        1. 14.2.5.1 L3_MAIN Register Group Summary
          1. 14.2.5.1.1 L3_MAIN Firewall Registers Summary and Description
            1. 14.2.5.1.1.1 L3_MAIN Firewall Registers Summary
            2. 14.2.5.1.1.2 L3_MAIN Firewall Registers Description
          2. 14.2.5.1.2 L3_MAIN Host Register Summary and Description
            1. 14.2.5.1.2.1 L3_MAIN HOST Register Summary
            2. 14.2.5.1.2.2 L3_MAIN HOST Register Description
          3. 14.2.5.1.3 L3_MAIN TARG Register Summary and Description
            1. 14.2.5.1.3.1 L3_MAIN TARG Register Summary
            2. 14.2.5.1.3.2 L3_MAIN TARG Register Description
          4. 14.2.5.1.4 L3_MAIN FLAGMUX Registers Summary and Description
            1. 14.2.5.1.4.1 L3_MAIN FLAGMUX Registers Summary
            2. 14.2.5.1.4.2 L3_MAIN FLAGMUX Rebisters Description
          5. 14.2.5.1.5 L3_MAIN FLAGMUX CLK1MERGE Registers Summary and Description
            1. 14.2.5.1.5.1 L3_MAIN FLAGMUX CLK1MERGE Registers Summary
            2. 14.2.5.1.5.2 L3_MAIN FLAGMUX CLK1MERGE Registers Description
          6. 14.2.5.1.6 L3_MAIN FLAGMUX TIMEOUT Registers Summary and Description
            1. 14.2.5.1.6.1 L3_MAIN FLAGMUX TIMEOUT Registers Summary
            2. 14.2.5.1.6.2 L3_MAIN FLAGMUX TIMEOUT Registers Description
          7. 14.2.5.1.7 L3_MAIN BW Regulator Register Summary and Description
            1. 14.2.5.1.7.1 L3_MAIN BW_REGULATOR Register Summary
            2. 14.2.5.1.7.2 L3_MAIN BW_REGULATOR Register Description
          8. 14.2.5.1.8 L3_MAIN Bandwidth Limiter Register Summary and Description
            1. 14.2.5.1.8.1 L3_MAIN BW Limiter Register Summary
            2. 14.2.5.1.8.2 L3_MAIN BW Limiter Register Description
          9. 14.2.5.1.9 L3_MAIN STATCOLL Register Summary and Description
            1. 14.2.5.1.9.1 L3_MAIN STATCOLL Register Summary
            2. 14.2.5.1.9.2 L3_MAIN STATCOLL Register Description
    3. 14.3 L4 Interconnects
      1. 14.3.1 L4 Interconnect Overview
      2. 14.3.2 L4 Interconnect Integration
      3. 14.3.3 L4 Interconnect Functional Description
        1. 14.3.3.1 Module Distribution
          1. 14.3.3.1.1 L4_PER1 Interconnect Agents
          2. 14.3.3.1.2 L4_PER2 Interconnect Agents
          3. 14.3.3.1.3 L4_PER3 Interconnect Agents
          4. 14.3.3.1.4 L4_CFG Interconnect Agents
          5. 14.3.3.1.5 L4_WKUP Interconnect Agents
        2. 14.3.3.2 Power Management
        3. 14.3.3.3 L4 Firewalls
          1. 14.3.3.3.1 Protection Group
          2. 14.3.3.3.2 Segments and Regions
          3. 14.3.3.3.3 L4 Firewall Address and Protection Register Settings
        4. 14.3.3.4 L4 Error Detection and Reporting
          1. 14.3.3.4.1 IA and TA Error Detection and Logging
          2. 14.3.3.4.2 Time-Out
          3. 14.3.3.4.3 Error Reporting
          4. 14.3.3.4.4 Error Recovery
          5. 14.3.3.4.5 Firewall Error Logging in the Control Module
      4. 14.3.4 L4 Interconnect Programming Guide
        1. 14.3.4.1 L4 Interconnect Low-level Programming Models
          1. 14.3.4.1.1 Global Initialization
            1. 14.3.4.1.1.1 Surrounding Modules Global Initialization
          2. 14.3.4.1.2 Operational Modes Configuration
            1. 14.3.4.1.2.1 L4 Interconnect Error Analysis Mode
              1. 14.3.4.1.2.1.1 Main Sequence: L4 Interconnect Error Analysis Mode
              2. 14.3.4.1.2.1.2 Subsequence: L4 Interconnect Protection Violation Error Identification
              3. 14.3.4.1.2.1.3 Subsequence: L4 Interconnect Unsupported Command/Address Hole Error Identification
              4. 14.3.4.1.2.1.4 Subsequence: L4 Interconnect Reset TA and Module
            2. 14.3.4.1.2.2 L4 Interconnect Time-Out Configuration Mode
              1. 14.3.4.1.2.2.1 Main Sequence: L4 Interconnect Time-Out Configuration Mode
            3. 14.3.4.1.2.3 L4 Interconnect Firewall Configuration Mode
              1. 14.3.4.1.2.3.1 Main Sequence: L4 Interconnect Firewall Configuration Mode
      5. 14.3.5 L4 Interconnects Register Manual
        1. 14.3.5.1 L4 Interconnects Instance Summary
        2. 14.3.5.2 L4 Initiator Agent (L4 IA)
          1. 14.3.5.2.1 L4 Initiator Agent (L4 IA) Register Summary
          2. 14.3.5.2.2 L4 Initiator Agent (L4 IA) Register Description
        3. 14.3.5.3 L4 Target Agent (L4 TA)
          1. 14.3.5.3.1 L4 Target Agent (L4 TA) Register Summary
          2. 14.3.5.3.2 L4 Target Agent (L4 TA) Register Description
        4. 14.3.5.4 L4 Link Agent (L4 LA)
          1. 14.3.5.4.1 L4 Link Agent (L4 LA) Register Summary
          2. 14.3.5.4.2 L4 Link Agent (L4 LA) Register Description
        5. 14.3.5.5 L4 Address Protection (L4 AP)
          1. 14.3.5.5.1 L4 Address Protection (L4 AP) Register Summary
          2. 14.3.5.5.2 L4 Address Protection (L4 AP) Register Description
  17. 15Memory Subsystem
    1. 15.1 Memory Subsystem Overview
      1. 15.1.1 DMM Overview
      2. 15.1.2 TILER Overview
      3. 15.1.3 EMIF Overview
      4. 15.1.4 GPMC Overview
      5. 15.1.5 ELM Overview
      6. 15.1.6 OCM Overview
    2. 15.2 Dynamic Memory Manager
      1. 15.2.1 DMM Overview
      2. 15.2.2 DMM Integration
        1. 15.2.2.1 DMM Configuration
      3. 15.2.3 DMM Functional Description
        1. 15.2.3.1 DMM Block Diagram
        2. 15.2.3.2 DMM Clock Configuration
        3. 15.2.3.3 DMM Power Management
        4. 15.2.3.4 DMM Interrupt Requests
        5. 15.2.3.5 DMM
          1. 15.2.3.5.1 DMM Concepts
            1. 15.2.3.5.1.1 Dynamic Mapping
            2. 15.2.3.5.1.2 Address Mapping
            3. 15.2.3.5.1.3 Address Translation
              1. 15.2.3.5.1.3.1 PAT View Mappings
              2. 15.2.3.5.1.3.2 PAT View Map Base Address
              3. 15.2.3.5.1.3.3 PAT Views
                1. 15.2.3.5.1.3.3.1 PAT Direct Access Translation
                2. 15.2.3.5.1.3.3.2 PAT Indirect Access Translation
                3. 15.2.3.5.1.3.3.3 PAT View Configuration
                4. 15.2.3.5.1.3.3.4 PAT Address Translation LUT
                5. 15.2.3.5.1.3.3.5 Direct Access to the PAT Table Vectors
                6. 15.2.3.5.1.3.3.6 Automatic Refill Through the Refill Engines
          2. 15.2.3.5.2 DMM Transaction Flows
            1. 15.2.3.5.2.1 Nontiled Transaction Flow
            2. 15.2.3.5.2.2 Tiled Transaction Flow
          3. 15.2.3.5.3 DMM Internal Macro-Architecture
            1. 15.2.3.5.3.1 LISA Description
            2. 15.2.3.5.3.2 PAT Description
            3. 15.2.3.5.3.3 PEG Description
            4. 15.2.3.5.3.4 LISA Interconnect Arbitration
            5. 15.2.3.5.3.5 ROBIN Description
            6. 15.2.3.5.3.6 TILER Description
        6. 15.2.3.6 TILER
          1. 15.2.3.6.1 TILER Concepts
            1. 15.2.3.6.1.1 TILER Rationale
              1. 15.2.3.6.1.1.1 The TILER is a 4-GiB Virtual Address Space Composed of Eight Views
              2. 15.2.3.6.1.1.2 A View is a 512-MiB Virtual Address Space Composed of Four Containers
              3. 15.2.3.6.1.1.3 A Container is a 128-MiB Virtual Address Space
              4. 15.2.3.6.1.1.4 A Page is a 4-kiB Virtual Address Space
              5. 15.2.3.6.1.1.5 A Tile is a 1-kiB Address Space
              6. 15.2.3.6.1.1.6 2356
              7. 15.2.3.6.1.1.7 A Subtile is a 128-Bit Address Space
            2. 15.2.3.6.1.2 TILER Modes
              1. 15.2.3.6.1.2.1 Bypass Mode
              2. 15.2.3.6.1.2.2 Page Mode
              3. 15.2.3.6.1.2.3 Tiled Mode
            3. 15.2.3.6.1.3 Object Container Definition
            4. 15.2.3.6.1.4 Page Definition
              1. 15.2.3.6.1.4.1 Container Geometry With 4-kiB Pages
              2. 15.2.3.6.1.4.2 Container Geometry and Page Mapping Summary
            5. 15.2.3.6.1.5 Orientation
            6. 15.2.3.6.1.6 Tile Definition
            7. 15.2.3.6.1.7 Subtiles
              1. 15.2.3.6.1.7.1 Subtiling Definition
            8. 15.2.3.6.1.8 TILER Virtual Addressing
              1. 15.2.3.6.1.8.1 Page Mode Virtual Addressing and Characteristics
              2. 15.2.3.6.1.8.2 Tiled Mode Virtual Addressing and Characteristics
              3. 15.2.3.6.1.8.3 Element Ordering in the TILER Container
                1. 15.2.3.6.1.8.3.1 Natural View or 0-Degree View (Orientation 0)
                2. 15.2.3.6.1.8.3.2 0-Degree View With Vertical Mirror or 180-Degree View With Horizontal Mirror (Orientation 1)
                3. 15.2.3.6.1.8.3.3 0-Degree View With Horizontal Mirror or 180-Degree View With Vertical Mirror (Orientation 2)
                4. 15.2.3.6.1.8.3.4 180-Degree View (Orientation 3)
                5. 15.2.3.6.1.8.3.5 90-Degree View With Vertical Mirror or 270-Degree View With Horizontal Mirror (Orientation 4)
                6. 15.2.3.6.1.8.3.6 270-Degree View (Orientation 5)
                7. 15.2.3.6.1.8.3.7 90-Degree View (Orientation 6)
                8. 15.2.3.6.1.8.3.8 90-Degree View With Horizontal Mirror or 270-Degree View With Vertical Mirror (Orientation 7)
          2. 15.2.3.6.2 TILER Macro-Architecture
          3. 15.2.3.6.3 TILER Guidelines for Initiators
            1. 15.2.3.6.3.1 Buffered Raster-Based Initiators
              1. 15.2.3.6.3.1.1 Buffer Size
              2. 15.2.3.6.3.1.2 Performance
      4. 15.2.4 DMM Use Cases and Tips
        1. 15.2.4.1 PAT Use Cases
          1. 15.2.4.1.1 Simple Manual Area Refill
          2. 15.2.4.1.2 Single Auto-Configured Area Refill
          3. 15.2.4.1.3 Chained Auto-Configured Area Refill
          4. 15.2.4.1.4 Synchronized Auto-Configured Area Refill
          5. 15.2.4.1.5 Cyclic Synchronized Auto-Configured Area Refill
        2. 15.2.4.2 Addressing Management with LISA
          1. 15.2.4.2.1 Case 1: Use of One Memory Controller
          2. 15.2.4.2.2 Case 2: Use of Two Memory Controllers
            1. 15.2.4.2.2.1 Address Upper Bits Shifting
      5. 15.2.5 DMM Basic Programming Model
        1. 15.2.5.1 Global Initialization
        2. 15.2.5.2 DMM Module Global Initialization
        3. 15.2.5.3 DMM Operational Modes Configuration
          1. 15.2.5.3.1 Different Operational Modes
          2. 15.2.5.3.2 Configuration Settings and LUT Refill
          3. 15.2.5.3.3 Interleaving Settings
          4. 15.2.5.3.4 Aliased Tiled View Orientation Settings and LUT Refill
          5. 15.2.5.3.5 Priority Settings
          6. 15.2.5.3.6 Error Handling
          7. 15.2.5.3.7 PAT Programming Model
            1. 15.2.5.3.7.1 PAT in Direct Translation Mode
            2. 15.2.5.3.7.2 PAT in Indirect Translation Mode
        4. 15.2.5.4 Addressing an Object in Tiled Mode
          1. 15.2.5.4.1 Frame-Buffer Addressing
          2. 15.2.5.4.2 TILER Page Mapping
        5. 15.2.5.5 Addressing an Object in Page Mode
        6. 15.2.5.6 Sharing Containers Between Different Modes
      6. 15.2.6 DMM Register Manual
        1. 15.2.6.1 DMM Instance Summary
        2. 15.2.6.2 DMM Registers
          1. 15.2.6.2.1 DMM Register Summary
          2. 15.2.6.2.2 DMM Register Description
    3. 15.3 EMIF Controller
      1. 15.3.1 EMIF Controller Overview
      2. 15.3.2 EMIF Module Environment
      3. 15.3.3 EMIF Module Integration
      4. 15.3.4 EMIF Functional Description
        1. 15.3.4.1  Block Diagram
          1. 15.3.4.1.1 Local Interface
          2. 15.3.4.1.2 FIFO Description
          3. 15.3.4.1.3 MPU Port Restrictions
          4. 15.3.4.1.4 Arbitration of Commands in the Command FIFO
        2. 15.3.4.2  Clock Management
          1. 15.3.4.2.1 EMIF_FICLK Overview
          2. 15.3.4.2.2 EMIF Dependency on MPU Clock Rate
        3. 15.3.4.3  Reset
        4. 15.3.4.4  System Power Management
          1. 15.3.4.4.1 Power-Down Mode
          2. 15.3.4.4.2 Self-Refresh Mode
        5. 15.3.4.5  Interrupt Requests
        6. 15.3.4.6  SDRAM Refresh Scheduling
        7. 15.3.4.7  SDRAM Initialization
          1. 15.3.4.7.1 DDR2 SDRAM Initialization
          2. 15.3.4.7.2 DDR3 SDRAM Initialization
        8. 15.3.4.8  DDR3 Read-Write Leveling
          1. 15.3.4.8.1 Full Leveling
          2. 15.3.4.8.2 Software Leveling
        9. 15.3.4.9  EMIF Access Cycles
        10. 15.3.4.10 Turnaround Time
        11. 15.3.4.11 PHY DLL Calibration
        12. 15.3.4.12 SDRAM Address Mapping
          1. 15.3.4.12.1 Address Mapping for IBANK_POS = 0 and EBANK_POS = 0
          2. 15.3.4.12.2 Address Mapping for IBANK_POS = 1 and EBANK_POS = 0
          3. 15.3.4.12.3 Address Mapping for IBANK_POS = 2 and EBANK_POS = 0
          4. 15.3.4.12.4 Address Mapping for IBANK_POS = 3 and EBANK_POS = 0
          5. 15.3.4.12.5 Address Mapping for IBANK_POS = 0 and EBANK_POS = 1
          6. 15.3.4.12.6 Address Mapping for IBANK_POS = 1 and EBANK_POS = 1
          7. 15.3.4.12.7 Address Mapping for IBANK_POS = 2 and EBANK_POS = 1
          8. 15.3.4.12.8 2457
          9. 15.3.4.12.9 Address Mapping for IBANK_POS = 3 and EBANK_POS = 1
        13. 15.3.4.13 DDR3 Output Impedance Calibration
        14. 15.3.4.14 Error Correction And Detection Feature
        15. 15.3.4.15 Class of Service
        16. 15.3.4.16 Performance Counters
          1. 15.3.4.16.1 Performance Counters General Examples
        17. 15.3.4.17 Forcing CKE to tri-state
      5. 15.3.5 EMIF Programming Guide
        1. 15.3.5.1 EMIF Low-Level Programming Models
          1. 15.3.5.1.1 Global Initialization
            1. 15.3.5.1.1.1 EMIF Configuration Sequence
          2. 15.3.5.1.2 Operational Modes Configuration
            1. 15.3.5.1.2.1 EMIF Output Impedance Calibration Mode
            2. 15.3.5.1.2.2 EMIF SDRAM Self-Refresh
            3. 15.3.5.1.2.3 EMIF SDRAM Power-Down Mode
            4. 15.3.5.1.2.4 EMIF ECC Configuration
      6. 15.3.6 EMIF Register Manual
        1. 15.3.6.1 EMIF Instance Summary
        2. 15.3.6.2 EMIF Registers
          1. 15.3.6.2.1 EMIF Register Summary
          2. 15.3.6.2.2 EMIF Register Description
    4. 15.4 General-Purpose Memory Controller
      1. 15.4.1 GPMC Overview
      2. 15.4.2 GPMC Environment
        1. 15.4.2.1 GPMC Modes
        2. 15.4.2.2 GPMC Signals
      3. 15.4.3 GPMC Integration
      4. 15.4.4 GPMC Functional Description
        1. 15.4.4.1  GPMC Block Diagram
        2. 15.4.4.2  GPMC Clock Configuration
        3. 15.4.4.3  GPMC Software Reset
        4. 15.4.4.4  GPMC Power Management
        5. 15.4.4.5  GPMC Interrupt Requests
        6. 15.4.4.6  L3 Interconnect Interface
        7. 15.4.4.7  GPMC Address and Data Bus
          1. 15.4.4.7.1 GPMC I/O Configuration Setting
          2. 15.4.4.7.2 GPMC CS0 Default Configuration at Device Reset
        8. 15.4.4.8  Address Decoder and Chip-Select Configuration
          1. 15.4.4.8.1 Chip-Select Base Address and Region Size
          2. 15.4.4.8.2 Access Protocol
            1. 15.4.4.8.2.1 Supported Devices
            2. 15.4.4.8.2.2 Access Size Adaptation and Device Width
            3. 15.4.4.8.2.3 Address/Data-Multiplexing Interface
          3. 15.4.4.8.3 External Signals
            1. 15.4.4.8.3.1 Wait Pin Monitoring Control
              1. 15.4.4.8.3.1.1 Wait Monitoring During Asynchronous Read Access
              2. 15.4.4.8.3.1.2 Wait Monitoring During Asynchronous Write Access
              3. 15.4.4.8.3.1.3 Wait Monitoring During Synchronous Read Access
              4. 15.4.4.8.3.1.4 Wait Monitoring During Synchronous Write Access
              5. 15.4.4.8.3.1.5 Wait With NAND Device
              6. 15.4.4.8.3.1.6 Idle Cycle Control Between Successive Accesses
                1. 15.4.4.8.3.1.6.1 Bus Turnaround (BUSTURNAROUND)
                2. 15.4.4.8.3.1.6.2 Idle Cycles Between Accesses to Same Chip-Select (CYCLE2CYCLESAMECSEN, CYCLE2CYCLEDELAY)
                3. 15.4.4.8.3.1.6.3 Idle Cycles Between Accesses to Different Chip-Select (CYCLE2CYCLEDIFFCSEN, CYCLE2CYCLEDELAY)
              7. 15.4.4.8.3.1.7 Slow Device Support (TIMEPARAGRANULARITY Parameter)
            2. 15.4.4.8.3.2 Reset
            3. 15.4.4.8.3.3 Byte Enable (nBE1/nBE0)
          4. 15.4.4.8.4 Error Handling
        9. 15.4.4.9  Timing Setting
          1. 15.4.4.9.1  Read Cycle Time and Write Cycle Time (RDCYCLETIME / WRCYCLETIME)
          2. 15.4.4.9.2  nCS: Chip-Select Signal Control Assertion/Deassertion Time (CSONTIME / CSRDOFFTIME / CSWROFFTIME / CSEXTRADELAY)
          3. 15.4.4.9.3  nADV/ALE: Address Valid/Address Latch Enable Signal Control Assertion/Deassertion Time (ADVONTIME / ADVRDOFFTIME / ADVWROFFTIME / ADVEXTRADELAY/ADVAADMUXONTIME/ADVAADMUXRDOFFTIME/ADVAADMUXWROFFTIME)
          4. 15.4.4.9.4  nOE/nRE: Output Enable/Read Enable Signal Control Assertion/Deassertion Time (OEONTIME / OEOFFTIME / OEEXTRADELAY / OEAADMUXONTIME / OEAADMUXOFFTIME)
          5. 15.4.4.9.5  nWE: Write Enable Signal Control Assertion/Deassertion Time (WEONTIME / WEOFFTIME / WEEXTRADELAY)
          6. 15.4.4.9.6  GPMC_CLK
          7. 15.4.4.9.7  GPMC_CLK and Control Signals Setup and Hold
          8. 15.4.4.9.8  Access Time (RDACCESSTIME / WRACCESSTIME)
            1. 15.4.4.9.8.1 Access Time on Read Access
            2. 15.4.4.9.8.2 Access Time on Write Access
          9. 15.4.4.9.9  Page Burst Access Time (PAGEBURSTACCESSTIME)
            1. 15.4.4.9.9.1 Page Burst Access Time on Read Access
            2. 15.4.4.9.9.2 Page Burst Access Time on Write Access
          10. 15.4.4.9.10 Bus Keeping Support
        10. 15.4.4.10 NOR Access Description
          1. 15.4.4.10.1 Asynchronous Access Description
            1. 15.4.4.10.1.1 Access on Address/Data Multiplexed Devices
              1. 15.4.4.10.1.1.1 Asynchronous Single-Read Operation on an Address/Data Multiplexed Device
              2. 15.4.4.10.1.1.2 Asynchronous Single-Write Operation on an Address/Data-Multiplexed Device
              3. 15.4.4.10.1.1.3 Asynchronous Multiple (Page) Write Operation on an Address/Data-Multiplexed Device
            2. 15.4.4.10.1.2 Access on Address/Address/Data-Multiplexed Devices
              1. 15.4.4.10.1.2.1 Asynchronous Single Read Operation on an AAD-Multiplexed Device
              2. 15.4.4.10.1.2.2 Asynchronous Single-Write Operation on an AAD-Multiplexed Device
              3. 15.4.4.10.1.2.3 Asynchronous Multiple (Page) Read Operation on an AAD-Multiplexed Device
          2. 15.4.4.10.2 Synchronous Access Description
            1. 15.4.4.10.2.1 Synchronous Single Read
            2. 15.4.4.10.2.2 Synchronous Multiple (Burst) Read (4-, 8-, 16-Word16 Burst With Wraparound Capability)
            3. 15.4.4.10.2.3 Synchronous Single Write
            4. 15.4.4.10.2.4 Synchronous Multiple (Burst) Write
          3. 15.4.4.10.3 Asynchronous and Synchronous Accesses in Nonmultiplexed Mode
            1. 15.4.4.10.3.1 Asynchronous Single-Read Operation on Nonmultiplexed Device
            2. 15.4.4.10.3.2 Asynchronous Single-Write Operation on Nonmultiplexed Device
            3. 15.4.4.10.3.3 Asynchronous Multiple (Page Mode) Read Operation on Nonmultiplexed Device
            4. 15.4.4.10.3.4 Synchronous Operations on a Nonmultiplexed Device
          4. 15.4.4.10.4 Page and Burst Support
          5. 15.4.4.10.5 System Burst vs External Device Burst Support
        11. 15.4.4.11 pSRAM Access Specificities
        12. 15.4.4.12 NAND Access Description
          1. 15.4.4.12.1 NAND Memory Device in Byte or 16-bit Word Stream Mode
            1. 15.4.4.12.1.1 Chip-Select Configuration for NAND Interfacing in Byte or Word Stream Mode
            2. 15.4.4.12.1.2 NAND Device Command and Address Phase Control
            3. 15.4.4.12.1.3 Command Latch Cycle
            4. 15.4.4.12.1.4 Address Latch Cycle
            5. 15.4.4.12.1.5 NAND Device Data Read and Write Phase Control in Stream Mode
            6. 15.4.4.12.1.6 NAND Device General Chip-Select Timing Control Requirement
            7. 15.4.4.12.1.7 Read and Write Access Size Adaptation
              1. 15.4.4.12.1.7.1 8-Bit-Wide NAND Device
              2. 15.4.4.12.1.7.2 16-Bit-Wide NAND Device
          2. 15.4.4.12.2 NAND Device-Ready Pin
            1. 15.4.4.12.2.1 Ready Pin Monitored by Software Polling
            2. 15.4.4.12.2.2 Ready Pin Monitored by Hardware Interrupt
          3. 15.4.4.12.3 ECC Calculator
            1. 15.4.4.12.3.1 Hamming Code
              1. 15.4.4.12.3.1.1 ECC Result Register and ECC Computation Accumulation Size
              2. 15.4.4.12.3.1.2 ECC Enabling
              3. 15.4.4.12.3.1.3 ECC Computation
              4. 15.4.4.12.3.1.4 ECC Comparison and Correction
              5. 15.4.4.12.3.1.5 ECC Calculation Based on 8-Bit Word
              6. 15.4.4.12.3.1.6 ECC Calculation Based on 16-Bit Word
            2. 15.4.4.12.3.2 BCH Code
              1. 15.4.4.12.3.2.1 Requirements
              2. 15.4.4.12.3.2.2 Memory Mapping of BCH Codeword
                1. 15.4.4.12.3.2.2.1 Memory Mapping of Data Message
                2. 15.4.4.12.3.2.2.2 Memory-Mapping of the ECC
                3. 15.4.4.12.3.2.2.3 Wrapping Modes
                  1. 4.4.12.3.2.2.3.1  Manual Mode (0x0)
                  2. 4.4.12.3.2.2.3.2  Mode 0x1
                  3. 4.4.12.3.2.2.3.3  Mode 0xA (10)
                  4. 4.4.12.3.2.2.3.4  Mode 0x2
                  5. 4.4.12.3.2.2.3.5  Mode 0x3
                  6. 4.4.12.3.2.2.3.6  Mode 0x7
                  7. 4.4.12.3.2.2.3.7  Mode 0x8
                  8. 4.4.12.3.2.2.3.8  Mode 0x4
                  9. 4.4.12.3.2.2.3.9  Mode 0x9
                  10. 4.4.12.3.2.2.3.10 Mode 0x5
                  11. 4.4.12.3.2.2.3.11 Mode 0xB (11)
                  12. 4.4.12.3.2.2.3.12 Mode 0x6
              3. 15.4.4.12.3.2.3 Supported NAND Page Mappings and ECC Schemes
                1. 15.4.4.12.3.2.3.1 Per-Sector Spare Mappings
                2. 15.4.4.12.3.2.3.2 Pooled Spare Mapping
                3. 15.4.4.12.3.2.3.3 Per-Sector Spare Mapping, with ECC Separated at the End of the Page
          4. 15.4.4.12.4 Prefetch and Write-Posting Engine
            1. 15.4.4.12.4.1 General Facts About the Engine Configuration
            2. 15.4.4.12.4.2 Prefetch Mode
            3. 15.4.4.12.4.3 FIFO Control in Prefetch Mode
            4. 15.4.4.12.4.4 Write-Posting Mode
            5. 15.4.4.12.4.5 FIFO Control in Write-Posting Mode
            6. 15.4.4.12.4.6 Optimizing NAND Access Using the Prefetch and Write-Posting Engine
            7. 15.4.4.12.4.7 Interleaved Accesses Between Prefetch and Write-Posting Engine and Other Chip-Selects
      5. 15.4.5 GPMC Basic Programming Model
        1. 15.4.5.1 GPMC High-Level Programming Model Overview
        2. 15.4.5.2 GPMC Initialization
        3. 15.4.5.3 GPMC Configuration in NOR Mode
        4. 15.4.5.4 GPMC Configuration in NAND Mode
        5. 15.4.5.5 Set Memory Access
        6. 15.4.5.6 GPMC Timing Parameters
          1. 15.4.5.6.1 GPMC Timing Parameters Formulas
            1. 15.4.5.6.1.1 NAND Flash Interface Timing Parameters Formulas
            2. 15.4.5.6.1.2 Synchronous NOR Flash Timing Parameters Formulas
            3. 15.4.5.6.1.3 Asynchronous NOR Flash Timing Parameters Formulas
      6. 15.4.6 GPMC Use Cases and Tips
        1. 15.4.6.1 How to Set GPMC Timing Parameters for Typical Accesses
          1. 15.4.6.1.1 External Memory Attached to the GPMC Module
          2. 15.4.6.1.2 Typical GPMC Setup
            1. 15.4.6.1.2.1 GPMC Configuration for Synchronous Burst Read Access
            2. 15.4.6.1.2.2 GPMC Configuration for Asynchronous Read Access
            3. 15.4.6.1.2.3 GPMC Configuration for Asynchronous Single Write Access
        2. 15.4.6.2 How to Choose a Suitable Memory to Use With the GPMC
          1. 15.4.6.2.1 Supported Memories or Devices
            1. 15.4.6.2.1.1 Memory Pin Multiplexing
            2. 15.4.6.2.1.2 NAND Interface Protocol
            3. 15.4.6.2.1.3 NOR Interface Protocol
            4. 15.4.6.2.1.4 Other Technologies
            5. 15.4.6.2.1.5 Supported Protocols
          2. 15.4.6.2.2 GPMC Features and Settings
      7. 15.4.7 GPMC Register Manual
        1. 15.4.7.1 GPMC Register Summary
        2. 15.4.7.2 GPMC Register Descriptions
    5. 15.5 Error Location Module
      1. 15.5.1 Error Location Module Overview
      2. 15.5.2 ELM Integration
      3. 15.5.3 ELM Functional Description
        1. 15.5.3.1 ELM Software Reset
        2. 15.5.3.2 ELM Power Management
        3. 15.5.3.3 ELM Interrupt Requests
        4. 15.5.3.4 Processing Initialization
        5. 15.5.3.5 Processing Sequence
        6. 15.5.3.6 Processing Completion
      4. 15.5.4 ELM Basic Programming Model
        1. 15.5.4.1 ELM Low-Level Programming Model
          1. 15.5.4.1.1 Processing Initialization
          2. 15.5.4.1.2 Read Results
          3. 15.5.4.1.3 2649
        2. 15.5.4.2 Use Case: ELM Used in Continuous Mode
        3. 15.5.4.3 Use Case: ELM Used in Page Mode
      5. 15.5.5 ELM Register Manual
        1. 15.5.5.1 ELM Instance Summary
        2. 15.5.5.2 ELM Registers
          1. 15.5.5.2.1 ELM Register Summary
          2. 15.5.5.2.2 ELM Register Description
    6. 15.6 On-Chip Memory (OCM) Subsystem
      1. 15.6.1 OCM Subsystem Overview
      2. 15.6.2 OCM Subsystem Integration
      3. 15.6.3 OCM Subsystem Functional Desctiption
        1. 15.6.3.1  Block Diagram
        2. 15.6.3.2  Resets
        3. 15.6.3.3  Clock Management
        4. 15.6.3.4  Interrupt Requests
        5. 15.6.3.5  OCM Subsystem Memory Regions
        6. 15.6.3.6  OCM Controller Modes Of Operation
        7. 15.6.3.7  ECC Associated FIFOs
        8. 15.6.3.8  ECC Counters And Corrected Bit Distribution Register
        9. 15.6.3.9  ECC Support
        10. 15.6.3.10 Circular Buffer (CBUF) Support
        11. 15.6.3.11 CBUF Mode Error Handling
          1. 15.6.3.11.1 VBUF Address Not Mapped to a CBUF Memory Space
          2. 15.6.3.11.2 VBUF Access Not Starting At The Base Address
          3. 15.6.3.11.3 Illegal Address Change Between Two Same Type Accesses
          4. 15.6.3.11.4 Illegal Frame SIze (Short Frame Detection)
          5. 15.6.3.11.5 CBUF Overflow
          6. 15.6.3.11.6 CBUF Underflow
        12. 15.6.3.12 Status Reporting
      4. 15.6.4 OCM Subsystem Register Manual
        1. 15.6.4.1 OCM Subsystem Instance Summary
        2. 15.6.4.2 OCM Subsystem Registers
          1. 15.6.4.2.1 OCM Subsystem Register Summary
          2. 15.6.4.2.2 OCM Subsystem Register Description
  18. 16DMA Controllers
    1. 16.1 System DMA
      1. 16.1.1 DMA_SYSTEM Module Overview
      2. 16.1.2 DMA_SYSTEM Controller Environment
      3. 16.1.3 DMA_SYSTEM Module Integration
        1. 16.1.3.1 DMA Requests to the DMA_SYSTEM Controller
        2. 16.1.3.2 Mapping of DMA Requests to DMA_CROSSBAR Inputs
      4. 16.1.4 DMA_SYSTEM Functional Description
        1. 16.1.4.1  DMA_SYSTEM Controller Power Management
        2. 16.1.4.2  DMA_SYSTEM Controller Interrupt Requests
          1. 16.1.4.2.1 Interrupt Generation
        3. 16.1.4.3  Logical Channel Transfer Overview
        4. 16.1.4.4  FIFO Queue Memory Pool
        5. 16.1.4.5  Addressing Modes
        6. 16.1.4.6  Packed Accesses
        7. 16.1.4.7  Burst Transactions
        8. 16.1.4.8  Endianism Conversion
        9. 16.1.4.9  Transfer Synchronization
          1. 16.1.4.9.1 Software Synchronization
          2. 16.1.4.9.2 Hardware Synchronization
        10. 16.1.4.10 Thread Budget Allocation
        11. 16.1.4.11 FIFO Budget Allocation
        12. 16.1.4.12 Chained Logical Channel Transfers
        13. 16.1.4.13 Reprogramming an Active Channel
        14. 16.1.4.14 Packet Synchronization
        15. 16.1.4.15 Graphics Acceleration Support
        16. 16.1.4.16 Supervisor Modes
        17. 16.1.4.17 Posted and Nonposted Writes
        18. 16.1.4.18 Disabling a Channel During Transfer
        19. 16.1.4.19 FIFO Draining Mechanism
        20. 16.1.4.20 Linked List
          1. 16.1.4.20.1 Overview
          2. 16.1.4.20.2 Link-List Transfer Profile
          3. 16.1.4.20.3 Descriptors
            1. 16.1.4.20.3.1 Type 1
            2. 16.1.4.20.3.2 Type 2
            3. 16.1.4.20.3.3 Type 3
          4. 16.1.4.20.4 Linked-List Control and Monitoring
            1. 16.1.4.20.4.1 Transfer Mode Setting
            2. 16.1.4.20.4.2 Starting a Linked List
            3. 16.1.4.20.4.3 Monitoring a Linked-List Progression
            4. 16.1.4.20.4.4 Interrupt During Linked-List Execution
            5. 16.1.4.20.4.5 Pause a Linked List
            6. 16.1.4.20.4.6 Stop a Linked List (Abort or Drain)
              1. 16.1.4.20.4.6.1 Drain
              2. 16.1.4.20.4.6.2 Abort
            7. 16.1.4.20.4.7 Status Bit Behavior
            8. 16.1.4.20.4.8 Linked-List Channel Linking
      5. 16.1.5 DMA_SYSTEM Basic Programming Model
        1. 16.1.5.1 Setup Configuration
        2. 16.1.5.2 Software-Triggered (Nonsynchronized) Transfer
        3. 16.1.5.3 Hardware-Synchronized Transfer
        4. 16.1.5.4 Synchronized Transfer Monitoring Using CDAC
        5. 16.1.5.5 Concurrent Software and Hardware Synchronization
        6. 16.1.5.6 Chained Transfer
        7. 16.1.5.7 90-Degree Clockwise Image Rotation
        8. 16.1.5.8 Graphic Operations
        9. 16.1.5.9 Linked-List Programming Guidelines
      6. 16.1.6 DMA_SYSTEM Register Manual
        1. 16.1.6.1 DMA_SYSTEM Instance Summary
        2. 16.1.6.2 DMA_SYSTEM Registers
          1. 16.1.6.2.1 DMA_SYSTEM Register Summary
          2. 16.1.6.2.2 DMA_SYSTEM Register Description
    2. 16.2 Enhanced DMA
      1. 16.2.1 EDMA Module Overview
        1. 16.2.1.1 EDMA Features
        2. 16.2.1.2 2750
        3. 16.2.1.3 EDMA Controllers Configuration
      2. 16.2.2 EDMA Controller Environment
      3. 16.2.3 EDMA Controller Integration
        1. 16.2.3.1 EDMA Requests to the EDMA Controller
      4. 16.2.4 EDMA Controller Functional Description
        1. 16.2.4.1  Block Diagram
          1. 16.2.4.1.1 Third-Party Channel Controller
          2. 16.2.4.1.2 Third-Party Transfer Controller
        2. 16.2.4.2  Types of EDMA controller Transfers
          1. 16.2.4.2.1 A-Synchronized Transfers
          2. 16.2.4.2.2 AB-Synchronized Transfers
        3. 16.2.4.3  Parameter RAM (PaRAM)
          1. 16.2.4.3.1 PaRAM
          2. 16.2.4.3.2 EDMA Channel PaRAM Set Entry Fields
            1. 16.2.4.3.2.1  Channel Options Parameter (OPT)
            2. 16.2.4.3.2.2  Channel Source Address (SRC)
            3. 16.2.4.3.2.3  Channel Destination Address (DST)
            4. 16.2.4.3.2.4  Count for 1st Dimension (ACNT)
            5. 16.2.4.3.2.5  Count for 2nd Dimension (BCNT)
            6. 16.2.4.3.2.6  Count for 3rd Dimension (CCNT)
            7. 16.2.4.3.2.7  BCNT Reload (BCNTRLD)
            8. 16.2.4.3.2.8  Source B Index (SBIDX)
            9. 16.2.4.3.2.9  Destination B Index (DBIDX)
            10. 16.2.4.3.2.10 Source C Index (SCIDX)
            11. 16.2.4.3.2.11 Destination C Index (DCIDX)
            12. 16.2.4.3.2.12 Link Address (LINK)
          3. 16.2.4.3.3 Null PaRAM Set
          4. 16.2.4.3.4 Dummy PaRAM Set
          5. 16.2.4.3.5 Dummy Versus Null Transfer Comparison
          6. 16.2.4.3.6 Parameter Set Updates
          7. 16.2.4.3.7 Linking Transfers
          8. 16.2.4.3.8 Constant Addressing Mode Transfers/Alignment Issues
          9. 16.2.4.3.9 Element Size
        4. 16.2.4.4  Initiating a DMA Transfer
          1. 16.2.4.4.1 DMA Channel
            1. 16.2.4.4.1.1 Event-Triggered Transfer Request
            2. 16.2.4.4.1.2 Manually-Triggered Transfer Request
            3. 16.2.4.4.1.3 Chain-Triggered Transfer Request
          2. 16.2.4.4.2 QDMA Channels
            1. 16.2.4.4.2.1 Auto-triggered and Link-Triggered Transfer Request
          3. 16.2.4.4.3 Comparison Between DMA and QDMA Channels
        5. 16.2.4.5  Completion of a DMA Transfer
          1. 16.2.4.5.1 Normal Completion
          2. 16.2.4.5.2 Early Completion
          3. 16.2.4.5.3 Dummy or Null Completion
        6. 16.2.4.6  Event, Channel, and PaRAM Mapping
          1. 16.2.4.6.1 DMA Channel to PaRAM Mapping
          2. 16.2.4.6.2 QDMA Channel to PaRAM Mapping
        7. 16.2.4.7  EDMA Channel Controller Regions
          1. 16.2.4.7.1 Region Overview
          2. 16.2.4.7.2 Channel Controller Regions
            1. 16.2.4.7.2.1 Resource Pool Division Across Two Regions
          3. 16.2.4.7.3 Region Interrupts
        8. 16.2.4.8  Chaining EDMA Channels
        9. 16.2.4.9  EDMA Interrupts
          1. 16.2.4.9.1 Transfer Completion Interrupts
            1. 16.2.4.9.1.1 Enabling Transfer Completion Interrupts
            2. 16.2.4.9.1.2 Clearing Transfer Completion Interrupts
          2. 16.2.4.9.2 EDMA Interrupt Servicing
          3. 16.2.4.9.3 Interrupt Servicing
          4. 16.2.4.9.4 2811
          5. 16.2.4.9.5 Interrupt Servicing
          6. 16.2.4.9.6 Interrupt Evaluation Operations
          7. 16.2.4.9.7 Error Interrupts
          8. 16.2.4.9.8 2815
        10. 16.2.4.10 Memory Protection
          1. 16.2.4.10.1 Active Memory Protection
          2. 16.2.4.10.2 Proxy Memory Protection
        11. 16.2.4.11 Event Queue(s)
          1. 16.2.4.11.1 DMA/QDMA Channel to Event Queue Mapping
          2. 16.2.4.11.2 Queue RAM Debug Visibility
          3. 16.2.4.11.3 Queue Resource Tracking
          4. 16.2.4.11.4 Performance Considerations
        12. 16.2.4.12 EDMA Transfer Controller (EDMA_TPTC)
          1. 16.2.4.12.1 Architecture Details
            1. 16.2.4.12.1.1 Command Fragmentation
            2. 16.2.4.12.1.2 TR Pipelining
            3. 16.2.4.12.1.3 Command Fragmentation (DBS = 64)
            4. 16.2.4.12.1.4 Performance Tuning
          2. 16.2.4.12.2 Memory Protection
          3. 16.2.4.12.3 Error Generation
          4. 16.2.4.12.4 Debug Features
            1. 16.2.4.12.4.1 Destination FIFO Register Pointer
          5. 16.2.4.12.5 EDMA_TPTC Configuration
        13. 16.2.4.13 Event Dataflow
        14. 16.2.4.14 EDMA controller Prioritization
          1. 16.2.4.14.1 Channel Priority
          2. 16.2.4.14.2 Trigger Source Priority
          3. 16.2.4.14.3 Dequeue Priority
        15. 16.2.4.15 EDMA Power, Reset and Clock Management
          1. 16.2.4.15.1 Clock and Power Management
          2. 16.2.4.15.2 Reset Considerations
        16. 16.2.4.16 Emulation Considerations
      5. 16.2.5 EDMA Transfer Examples
        1. 16.2.5.1 Block Move Example
        2. 16.2.5.2 Subframe Extraction Example
        3. 16.2.5.3 Data Sorting Example
        4. 16.2.5.4 Peripheral Servicing Example
          1. 16.2.5.4.1 Non-bursting Peripherals
          2. 16.2.5.4.2 Bursting Peripherals
          3. 16.2.5.4.3 Continuous Operation
            1. 16.2.5.4.3.1 Receive Channel
            2. 16.2.5.4.3.2 Transmit Channel
            3. 16.2.5.4.3.3 2854
          4. 16.2.5.4.4 Ping-Pong Buffering
            1. 16.2.5.4.4.1 Synchronization with the CPU
          5. 16.2.5.4.5 Transfer Chaining Examples
            1. 16.2.5.4.5.1 Servicing Input/Output FIFOs with a Single Event
            2. 16.2.5.4.5.2 Breaking Up Large Transfers with Intermediate Chaining
        5. 16.2.5.5 Setting Up an EDMA Transfer
          1. 16.2.5.5.1 2861
      6. 16.2.6 EDMA Debug Checklist and Programming Tips
        1. 16.2.6.1 EDMA Debug Checklist
        2. 16.2.6.2 EDMA Programming Tips
      7. 16.2.7 EDMA Register Manual
        1. 16.2.7.1 EDMA Instance Summary
        2. 16.2.7.2 EDMA Registers
          1. 16.2.7.2.1 EDMA Register Summary
          2. 16.2.7.2.2 EDMA Register Description
            1. 16.2.7.2.2.1 EDMA_TPCC Register Description
            2. 16.2.7.2.2.2 EDMA_TPTC0 and EDMA_TPTC1 Register Description
  19. 17Interrupt Controllers
    1. 17.1 Interrupt Controllers Overview
    2. 17.2 Interrupt Controllers Environment
    3. 17.3 Interrupt Controllers Integration
      1. 17.3.1 Interrupt Requests to MPU_INTC
      2. 17.3.2 Interrupt Requests to DSP1_INTC
      3. 17.3.3 Interrupt Requests to DSP2_INTC
      4. 17.3.4 Interrupt Requests to IPU1_Cx_INTC
      5. 17.3.5 Interrupt Requests to IPU2_Cx_INTC
      6. 17.3.6 Interrupt Requests to EVE1_INTC1
      7. 17.3.7 Interrupt Requests to EVE2_INTC1
      8. 17.3.8 Mapping of Device Interrupts to IRQ_CROSSBAR Inputs
    4. 17.4 Interrupt Controllers Functional Description
  20. 18Control Module
    1. 18.1 Control Module Overview
    2. 18.2 Control Module Environment
    3. 18.3 Control Module Integration
    4. 18.4 Control Module Functional Description
      1. 18.4.1 Control Module Clock Configuration
      2. 18.4.2 Control Module Resets
      3. 18.4.3 Control Module Power Management
        1. 18.4.3.1 Power Management Protocols
      4. 18.4.4 Hardware Requests
      5. 18.4.5 Control Module Initialization
      6. 18.4.6 Functional Description Of The Various Register Types In CTRL_MODULE_CORE Submodule
        1. 18.4.6.1  Pad Configuration
          1. 18.4.6.1.1 Pad Configuration Registers
            1. 18.4.6.1.1.1 Permanent PU/PD disabling (SR 2.0 only)
          2. 18.4.6.1.2 Pull Selection
          3. 18.4.6.1.3 Pad multiplexing
          4. 18.4.6.1.4 IOSETs
          5. 18.4.6.1.5 Virtual IO Timing Modes
          6. 18.4.6.1.6 Manual IO Timing Modes
          7. 18.4.6.1.7 Isolation Requirements
          8. 18.4.6.1.8 IO Delay Recalibration
        2. 18.4.6.2  Thermal Management Related Registers
          1. 18.4.6.2.1 Temperature Sensors Control Registers
          2. 18.4.6.2.2 Registers For The Thermal Alert Comparators
          3. 18.4.6.2.3 Thermal Shutdown Comparators
          4. 18.4.6.2.4 Temperature Timestamp Registers
          5. 18.4.6.2.5 Other Thermal Management Related Registers
          6. 18.4.6.2.6 Summary of the Thermal Management Related Registers
          7. 18.4.6.2.7 ADC Values Versus Temperature
        3. 18.4.6.3  PBIAS Cell And MMC1 I/O Cells Control Registers
        4. 18.4.6.4  IRQ_CROSSBAR Module Functional Description
        5. 18.4.6.5  DMA_CROSSBAR Module Functional Description
        6. 18.4.6.6  SDRAM Initiator Priority Registers
        7. 18.4.6.7  L3_MAIN Initiator Priority Registers
        8. 18.4.6.8  Memory Region Lock Registers
        9. 18.4.6.9  NMI Mapping To Respective Cores
        10. 18.4.6.10 Software Controls for the DDR2/DDR3 I/O Cells
        11. 18.4.6.11 Reference Voltage for the Device DDR2/DDR3 Receivers
        12. 18.4.6.12 AVS Class 0 Associated Registers
        13. 18.4.6.13 ABB Associated Registers
        14. 18.4.6.14 Registers For Other Miscellaneous Functions
          1. 18.4.6.14.1 System Boot Status Settings
          2. 18.4.6.14.2 Force MPU Write Nonposted Transactions
          3. 18.4.6.14.3 Firewall Error Status Registers
          4. 18.4.6.14.4 Settings Related To Different Peripheral Modules
      7. 18.4.7 Functional Description Of The Various Register Types In CTRL_MODULE_WKUP Submodule
        1. 18.4.7.1 Registers For Basic EMIF Configuration
    5. 18.5 Control Module Register Manual
    6. 18.6 IODELAYCONFIG Module Integration
    7. 18.7 IODELAYCONFIG Module Register Manual
  21. 19Mailbox
    1. 19.1 Mailbox Overview
    2. 19.2 Mailbox Integration
      1. 19.2.1 System MAILBOX Integration
      2. 19.2.2 IVA Mailbox Integration
      3. 19.2.3 EVE Mailbox Integration
    3. 19.3 Mailbox Functional Description
      1. 19.3.1 Mailbox Block Diagram
        1. 19.3.1.1 2944
      2. 19.3.2 Mailbox Software Reset
      3. 19.3.3 Mailbox Power Management
      4. 19.3.4 Mailbox Interrupt Requests
      5. 19.3.5 Mailbox Assignment
        1. 19.3.5.1 Description
      6. 19.3.6 Sending and Receiving Messages
        1. 19.3.6.1 Description
      7. 19.3.7 16-Bit Register Access
        1. 19.3.7.1 Description
      8. 19.3.8 Example of Communication
    4. 19.4 Mailbox Programming Guide
      1. 19.4.1 Mailbox Low-level Programming Models
        1. 19.4.1.1 Global Initialization
          1. 19.4.1.1.1 Surrounding Modules Global Initialization
          2. 19.4.1.1.2 Mailbox Global Initialization
            1. 19.4.1.1.2.1 Main Sequence - Mailbox Global Initialization
        2. 19.4.1.2 Mailbox Operational Modes Configuration
          1. 19.4.1.2.1 Mailbox Processing modes
            1. 19.4.1.2.1.1 Main Sequence - Sending a Message (Polling Method)
            2. 19.4.1.2.1.2 Main Sequence - Sending a Message (Interrupt Method)
            3. 19.4.1.2.1.3 Main Sequence - Receiving a Message (Polling Method)
            4. 19.4.1.2.1.4 Main Sequence - Receiving a Message (Interrupt Method)
        3. 19.4.1.3 Mailbox Events Servicing
          1. 19.4.1.3.1 Events Servicing in Sending Mode
          2. 19.4.1.3.2 Events Servicing in Receiving Mode
    5. 19.5 Mailbox Register Manual
      1. 19.5.1 Mailbox Instance Summary
      2. 19.5.2 Mailbox Registers
        1. 19.5.2.1 Mailbox Register Summary
        2. 19.5.2.2 Mailbox Register Description
  22. 20Memory Management Units
    1. 20.1 MMU Overview
    2. 20.2 MMU Integration
    3. 20.3 MMU Functional Description
      1. 20.3.1 MMU Block Diagram
        1. 20.3.1.1 MMU Address Translation Process
        2. 20.3.1.2 Translation Tables
          1. 20.3.1.2.1 Translation Table Hierarchy
          2. 20.3.1.2.2 First-Level Translation Table
            1. 20.3.1.2.2.1 First-Level Descriptor Format
            2. 20.3.1.2.2.2 First-Level Page Descriptor Format
            3. 20.3.1.2.2.3 First-Level Section Descriptor Format
            4. 20.3.1.2.2.4 Section Translation Summary
            5. 20.3.1.2.2.5 Supersection Translation Summary
          3. 20.3.1.2.3 Two-Level Translation
            1. 20.3.1.2.3.1 Second-Level Descriptor Format
            2. 20.3.1.2.3.2 Small Page Translation Summary
            3. 20.3.1.2.3.3 Large Page Translation Summary
        3. 20.3.1.3 Translation Lookaside Buffer
          1. 20.3.1.3.1 TLB Entry Format
        4. 20.3.1.4 No Translation (Bypass) Regions
      2. 20.3.2 MMU Software Reset
      3. 20.3.3 MMU Power Management
      4. 20.3.4 MMU Interrupt Requests
      5. 20.3.5 MMU Error Handling
    4. 20.4 MMU Low-level Programming Models
      1. 20.4.1 Global Initialization
        1. 20.4.1.1 Surrounding Modules Global Initialization
        2. 20.4.1.2 MMU Global Initialization
          1. 20.4.1.2.1 Main Sequence - MMU Global Initialization
          2. 20.4.1.2.2 Subsequence - Configure a TLB entry
        3. 20.4.1.3 Operational Modes Configuration
          1. 20.4.1.3.1 Main Sequence - Writing TLB Entries Statically
          2. 20.4.1.3.2 Main Sequence - Protecting TLB Entries
          3. 20.4.1.3.3 Main Sequence - Deleting TLB Entries
          4. 20.4.1.3.4 Main Sequence - Read TLB Entries
    5. 20.5 MMU Register Manual
      1. 20.5.1 MMU Instance Summary
      2. 20.5.2 MMU Registers
        1. 20.5.2.1 MMU Register Summary
        2. 20.5.2.2 MMU Register Description
  23. 21Spinlock
    1. 21.1 Spinlock Overview
    2. 21.2 Spinlock Integration
    3. 21.3 Spinlock Functional Description
      1. 21.3.1 Spinlock Software Reset
      2. 21.3.2 Spinlock Power Management
      3. 21.3.3 About Spinlocks
      4. 21.3.4 Spinlock Functional Operation
    4. 21.4 Spinlock Programming Guide
      1. 21.4.1 Spinlock Low-level Programming Models
        1. 21.4.1.1 Surrounding Modules Global Initialization
        2. 21.4.1.2 Basic Spinlock Operations
          1. 21.4.1.2.1 Spinlocks Clearing After a System Bug Recovery
          2. 21.4.1.2.2 Take and Release Spinlock
    5. 21.5 Spinlock Register Manual
      1. 21.5.1 Spinlock Instance Summary
      2. 21.5.2 Spinlock Registers
        1. 21.5.2.1 Spinlock Register Summary
        2. 21.5.2.2 Spinlock Register Description
  24. 22Timers
    1. 22.1 Timers Overview
    2. 22.2 General-Purpose Timers
      1. 22.2.1 General-Purpose Timers Overview
        1. 22.2.1.1 GP Timer Features
      2. 22.2.2 GP Timer Environment
        1. 22.2.2.1 GP Timer External System Interface
      3. 22.2.3 GP Timer Integration
      4. 22.2.4 GP Timer Functional Description
        1. 22.2.4.1  GP Timer Block Diagram
        2. 22.2.4.2  TIMER1, TIMER2 and TIMER10 Power Management
          1. 22.2.4.2.1 Wake-Up Capability
        3. 22.2.4.3  Power Management of Other GP Timers
          1. 22.2.4.3.1 Wake-Up Capability
        4. 22.2.4.4  Software Reset
        5. 22.2.4.5  GP Timer Interrupts
        6. 22.2.4.6  Timer Mode Functionality
          1. 22.2.4.6.1 1-ms Tick Generation (Only TIMER1, TIMER2 and TIMER10)
        7. 22.2.4.7  Capture Mode Functionality
        8. 22.2.4.8  Compare Mode Functionality
        9. 22.2.4.9  Prescaler Functionality
        10. 22.2.4.10 Pulse-Width Modulation
        11. 22.2.4.11 Timer Counting Rate
        12. 22.2.4.12 Timer Under Emulation
        13. 22.2.4.13 Accessing GP Timer Registers
          1. 22.2.4.13.1 Writing to Timer Registers
            1. 22.2.4.13.1.1 Write Posting Synchronization Mode
            2. 22.2.4.13.1.2 Write Nonposting Synchronization Mode
          2. 22.2.4.13.2 Reading From Timer Counter Registers
            1. 22.2.4.13.2.1 Read Posted
            2. 22.2.4.13.2.2 Read Non-Posted
        14. 22.2.4.14 Posted Mode Selection
      5. 22.2.5 GP Timer Low-Level Programming Models
        1. 22.2.5.1 Global Initialization
          1. 22.2.5.1.1 Global Initialization of Surrounding Modules
          2. 22.2.5.1.2 GP Timer Module Global Initialization
            1. 22.2.5.1.2.1 Main Sequence – GP Timer Module Global Initialization
        2. 22.2.5.2 Operational Mode Configuration
          1. 22.2.5.2.1 GP Timer Mode
            1. 22.2.5.2.1.1 Main Sequence – GP Timer Mode Configuration
          2. 22.2.5.2.2 GP Timer Compare Mode
            1. 22.2.5.2.2.1 Main Sequence – GP Timer Compare Mode Configuration
          3. 22.2.5.2.3 GP Timer Capture Mode
            1. 22.2.5.2.3.1 Main Sequence – GP Timer Capture Mode Configuration
            2. 22.2.5.2.3.2 Subsequence – Initialize Capture Mode
            3. 22.2.5.2.3.3 Subsequence – Detect Event
          4. 22.2.5.2.4 GP Timer PWM Mode
            1. 22.2.5.2.4.1 Main Sequence – GP Timer PWM Mode Configuration
      6. 22.2.6 GP Timer Register Manual
        1. 22.2.6.1 GP Timer Instance Summary
        2. 22.2.6.2 GP Timer Registers
          1. 22.2.6.2.1 GP Timer Register Summary
          2. 22.2.6.2.2 GP Timer Register Description
          3. 22.2.6.2.3 TIMER1, TIMER2, and TIMER10 Register Description
    3. 22.3 32-kHz Synchronized Timer (COUNTER_32K)
      1. 22.3.1 32-kHz Synchronized Timer Overview
        1. 22.3.1.1 32-kHz Synchronized Timer Features
      2. 22.3.2 32-kHz Synchronized Timer Integration
      3. 22.3.3 32-kHz Synchronized Timer Functional Description
        1. 22.3.3.1 Reading the 32-kHz Synchronized Timer
      4. 22.3.4 COUNTER_32K Timer Register Manual
        1. 22.3.4.1 COUNTER_32K Timer Register Mapping Summary
        2. 22.3.4.2 COUNTER_32K Timer Register Description
    4. 22.4 Watchdog Timer
      1. 22.4.1 Watchdog Timer Overview
        1. 22.4.1.1 Watchdog Timer Features
      2. 22.4.2 Watchdog Timer Integration
      3. 22.4.3 Watchdog Timer Functional Description
        1. 22.4.3.1  Power Management
          1. 22.4.3.1.1 Wake-Up Capability
        2. 22.4.3.2  Interrupts
        3. 22.4.3.3  General Watchdog Timer Operation
        4. 22.4.3.4  Reset Context
        5. 22.4.3.5  Overflow/Reset Generation
        6. 22.4.3.6  Prescaler Value/Timer Reset Frequency
        7. 22.4.3.7  Triggering a Timer Reload
        8. 22.4.3.8  Start/Stop Sequence for Watchdog Timer (Using the WSPR Register)
        9. 22.4.3.9  Modifying Timer Count/Load Values and Prescaler Setting
        10. 22.4.3.10 Watchdog Counter Register Access Restriction (WCRR)
        11. 22.4.3.11 Watchdog Timer Interrupt Generation
        12. 22.4.3.12 Watchdog Timer Under Emulation
        13. 22.4.3.13 Accessing Watchdog Timer Registers
      4. 22.4.4 Watchdog Timer Low-Level Programming Model
        1. 22.4.4.1 Global Initialization
          1. 22.4.4.1.1 Surrounding Modules Global Initialization
          2. 22.4.4.1.2 Watchdog Timer Module Global Initialization
            1. 22.4.4.1.2.1 Main Sequence – Watchdog Timer Module Global Initialization
        2. 22.4.4.2 Operational Mode Configuration
          1. 22.4.4.2.1 Watchdog Timer Basic Configuration
            1. 22.4.4.2.1.1 Main Sequence – Watchdog Timer Basic Configuration
            2. 22.4.4.2.1.2 Subsequence – Disable the Watchdog Timer
            3. 22.4.4.2.1.3 Subsequence – Enable the Watchdog Timer
      5. 22.4.5 Watchdog Timer Register Manual
        1. 22.4.5.1 Watchdog Timer Instance Summary
        2. 22.4.5.2 Watchdog Timer Registers
          1. 22.4.5.2.1 Watchdog Timer Register Summary
          2. 22.4.5.2.2 3131
          3. 22.4.5.2.3 Watchdog Timer Register Description
  25. 23Real-Time Clock (RTC)
    1. 23.1 RTC Overview
      1. 23.1.1 RTC Features
    2. 23.2 RTC Environment
      1. 23.2.1 RTC External Interface
    3. 23.3 RTC Integration
    4. 23.4 RTC Functional Description
      1. 23.4.1 Clock Source
      2. 23.4.2 Interrupt Support
        1. 23.4.2.1 CPU Interrupts
        2. 23.4.2.2 Interrupt Description
          1. 23.4.2.2.1 Timer Interrupt (timer_intr)
          2. 23.4.2.2.2 Alarm Interrupt (alarm_intr)
      3. 23.4.3 RTC Programming/Usage Guide
        1. 23.4.3.1 Time/Calendar Data Format
        2. 23.4.3.2 Register Access
        3. 23.4.3.3 Register Spurious Write Protection
        4. 23.4.3.4 Reading the Timer/Calendar (TC) Registers
          1. 23.4.3.4.1 Rounding Seconds
        5. 23.4.3.5 Modifying the TC Registers
          1. 23.4.3.5.1 General Registers
        6. 23.4.3.6 Crystal Compensation
      4. 23.4.4 Scratch Registers
      5. 23.4.5 Debouncing
      6. 23.4.6 Power Management
        1. 23.4.6.1 Device-Level Power Management
        2. 23.4.6.2 Subsystem-Level Power Management — PMIC Mode
    5. 23.5 RTC Low-Level Programming Guide
      1. 23.5.1 Global Initialization
        1. 23.5.1.1 Surrounding Modules Global Initialization
        2. 23.5.1.2 RTC Module Global Initialization
          1. 23.5.1.2.1 Main Sequence – RTC Module Global Initialization
    6. 23.6 RTC Register Manual
      1. 23.6.1 RTC Instance Summary
      2. 23.6.2 RTC_SS Registers
        1. 23.6.2.1 RTC_SS Register Summary
        2. 23.6.2.2 RTC_SS Register Description
  26. 24Serial Communication Interfaces
    1. 24.1  Multimaster High-Speed I2C Controller
      1. 24.1.1 HS I2C Overview
      2. 24.1.2 HS I2C Environment
        1. 24.1.2.1 HS I2C Typical Application
          1. 24.1.2.1.1 HS I2C Pins for Typical Connections in I2C Mode
          2. 24.1.2.1.2 HS I2C Interface Typical Connections
        2. 24.1.2.2 HS I2C Typical Connection Protocol and Data Format
          1. 24.1.2.2.1  HS I2C Serial Data Format
          2. 24.1.2.2.2  HS I2C Data Validity
          3. 24.1.2.2.3  HS I2C Start and Stop Conditions
          4. 24.1.2.2.4  HS I2C Addressing
            1. 24.1.2.2.4.1 Data Transfer Formats in F/S Mode
            2. 24.1.2.2.4.2 Data Transfer Format in HS Mode
          5. 24.1.2.2.5  HS I2C Master Transmitter
          6. 24.1.2.2.6  HS I2C Master Receiver
          7. 24.1.2.2.7  HS I2C Slave Transmitter
          8. 24.1.2.2.8  HS I2C Slave Receiver
          9. 24.1.2.2.9  HS I2C Bus Arbitration
          10. 24.1.2.2.10 HS I2C Clock Generation and Synchronization
      3. 24.1.3 HS I2C Integration
      4. 24.1.4 HS I2C Functional Description
        1. 24.1.4.1  HS I2C Block Diagram
        2. 24.1.4.2  HS I2C Clocks
          1. 24.1.4.2.1 HS I2C Clocking
          2. 24.1.4.2.2 HS I2C Automatic Blocking of the I2C Clock Feature
        3. 24.1.4.3  HS I2C Software Reset
        4. 24.1.4.4  HS I2C Power Management
        5. 24.1.4.5  HS I2C Interrupt Requests
        6. 24.1.4.6  HS I2C DMA Requests
        7. 24.1.4.7  HS I2C Programmable Multislave Channel Feature
        8. 24.1.4.8  HS I2C FIFO Management
          1. 24.1.4.8.1 HS I2C FIFO Interrupt Mode
          2. 24.1.4.8.2 HS I2C FIFO Polling Mode
          3. 24.1.4.8.3 HS I2C FIFO DMA Mode
          4. 24.1.4.8.4 HS I2C Draining Feature
        9. 24.1.4.9  HS I2C Noise Filter
        10. 24.1.4.10 HS I2C System Test Mode
      5. 24.1.5 HS I2C Programming Guide
        1. 24.1.5.1 HS I2C Low-Level Programming Models
          1. 24.1.5.1.1 HS I2C Programming Model
            1. 24.1.5.1.1.1 Main Program
              1. 24.1.5.1.1.1.1 Configure the Module Before Enabling the I2C Controller
              2. 24.1.5.1.1.1.2 Initialize the I2C Controller
              3. 24.1.5.1.1.1.3 Configure Slave Address and the Data Control Register
              4. 24.1.5.1.1.1.4 Initiate a Transfer
              5. 24.1.5.1.1.1.5 Receive Data
              6. 24.1.5.1.1.1.6 Transmit Data
            2. 24.1.5.1.1.2 Interrupt Subroutine Sequence
            3. 24.1.5.1.1.3 Programming Flow-Diagrams
      6. 24.1.6 HS I2C Register Manual
        1. 24.1.6.1 HS I2C Instance Summary
        2. 24.1.6.2 HS I2C Registers
          1. 24.1.6.2.1 HS I2C Register Summary
          2. 24.1.6.2.2 HS I2C Register Description
    2. 24.2  HDQ/1-Wire
      1. 24.2.1 HDQ1W Overview
      2. 24.2.2 HDQ1W Environment
        1. 24.2.2.1 HDQ1W Functional Modes
        2. 24.2.2.2 HDQ and 1-Wire (SDQ) Protocols
          1. 24.2.2.2.1 HDQ Protocol Initialization (Default)
          2. 24.2.2.2.2 1-Wire (SDQ) Protocol Initialization
          3. 24.2.2.2.3 Communication Sequence (HDQ and 1-Wire Protocols)
      3. 24.2.3 HDQ1W Integration
      4. 24.2.4 HDQ1W Functional Description
        1. 24.2.4.1 HDQ1W Block Diagram
        2. 24.2.4.2 HDQ1W Clocking Configuration
          1. 24.2.4.2.1 HDQ1W Clocks
        3. 24.2.4.3 HDQ1W Hardware and Software Reset
        4. 24.2.4.4 HDQ1W Power Management
          1. 24.2.4.4.1 Auto-Idle Mode
          2. 24.2.4.4.2 Power-Down Mode
          3. 24.2.4.4.3 3242
        5. 24.2.4.5 HDQ Interrupt Requests
        6. 24.2.4.6 HDQ Mode (Default)
          1. 24.2.4.6.1 HDQ Mode Features
          2. 24.2.4.6.2 Description
          3. 24.2.4.6.3 Single-Bit Mode
          4. 24.2.4.6.4 Interrupt Conditions
        7. 24.2.4.7 1-Wire Mode
          1. 24.2.4.7.1 1-Wire Mode Features
          2. 24.2.4.7.2 Description
          3. 24.2.4.7.3 1-Wire Single-Bit Mode Operation
          4. 24.2.4.7.4 Interrupt Conditions
          5. 24.2.4.7.5 Status Flags
        8. 24.2.4.8 BITFSM Delay
      5. 24.2.5 HDQ1W Low-Level Programming Model
        1. 24.2.5.1 Global Initialization
          1. 24.2.5.1.1 Surrounding Modules Global Initialization
          2. 24.2.5.1.2 HDQ1W Module Global Initialization
        2. 24.2.5.2 HDQ Operational Modes Configuration
          1. 24.2.5.2.1 Main Sequence - HDQ Write Operation Mode
          2. 24.2.5.2.2 Main Sequence - HDQ Read Operation Mode
            1. 24.2.5.2.2.1 Sub-sequence - Initialize HDQ Slave
        3. 24.2.5.3 1-Wire Operational Modes Configuration
          1. 24.2.5.3.1 Main Sequence - 1-Wire Write Operation Mode
          2. 24.2.5.3.2 Main Sequence - 1-Wire Read Operation Mode
          3. 24.2.5.3.3 Sub-sequence - Initialize 1-Wire Slave
      6. 24.2.6 HDQ1W Register Manual
        1. 24.2.6.1 HDQ1W Instance Summary
        2. 24.2.6.2 HDQ1W Registers
          1. 24.2.6.2.1 HDQ1W Register Summary
          2. 24.2.6.2.2 HDQ1W Register Description
    3. 24.3  UART/IrDA/CIR
      1. 24.3.1 UART/IrDA/CIR Overview
        1. 24.3.1.1 UART Features
        2. 24.3.1.2 IrDA Features
        3. 24.3.1.3 CIR Features
      2. 24.3.2 UART/IrDA/CIR Environment
        1. 24.3.2.1 UART Interface
          1. 24.3.2.1.1 System Using UART Communication With Hardware Handshake
          2. 24.3.2.1.2 UART Interface Description
          3. 24.3.2.1.3 UART Protocol and Data Format
        2. 24.3.2.2 IrDA Functional Interfaces
          1. 24.3.2.2.1 System Using IrDA Communication Protocol
          2. 24.3.2.2.2 IrDA Interface Description
          3. 24.3.2.2.3 IrDA Protocol and Data Format
            1. 24.3.2.2.3.1 SIR Mode
              1. 24.3.2.2.3.1.1 Frame Format
              2. 24.3.2.2.3.1.2 Asynchronous Transparency
              3. 24.3.2.2.3.1.3 Abort Sequence
              4. 24.3.2.2.3.1.4 Pulse Shaping
              5. 24.3.2.2.3.1.5 Encoder
              6. 24.3.2.2.3.1.6 Decoder
              7. 24.3.2.2.3.1.7 IR Address Checking
            2. 24.3.2.2.3.2 SIR Free-Format Mode
            3. 24.3.2.2.3.3 MIR Mode
              1. 24.3.2.2.3.3.1 MIR Encoder/Decoder
              2. 24.3.2.2.3.3.2 SIP Generation
            4. 24.3.2.2.3.4 FIR Mode
        3. 24.3.2.3 CIR Functional Interfaces
          1. 24.3.2.3.1 System Using CIR Communication Protocol With Remote Control
          2. 24.3.2.3.2 CIR Interface Description
          3. 24.3.2.3.3 CIR Protocol and Data Format
            1. 24.3.2.3.3.1 Carrier Modulation
            2. 24.3.2.3.3.2 Pulse Duty Cycle
            3. 24.3.2.3.3.3 Consumer IR Encoding/Decoding
      3. 24.3.3 UART/IrDA/CIR Integration
        1. 24.3.3.1 3308
      4. 24.3.4 UART/IrDA/CIR Functional Description
        1. 24.3.4.1 Block Diagram
        2. 24.3.4.2 Clock Configuration
        3. 24.3.4.3 Software Reset
        4. 24.3.4.4 Power Management
          1. 24.3.4.4.1 UART Mode Power Management
            1. 24.3.4.4.1.1 Module Power Saving
            2. 24.3.4.4.1.2 System Power Saving
          2. 24.3.4.4.2 IrDA Mode Power Management (UART3 Only)
            1. 24.3.4.4.2.1 Module Power Saving
            2. 24.3.4.4.2.2 System Power Saving
          3. 24.3.4.4.3 CIR Mode Power Management (UART3 Only)
            1. 24.3.4.4.3.1 Module Power Saving
            2. 24.3.4.4.3.2 System Power Saving
          4. 24.3.4.4.4 Local Power Management
        5. 24.3.4.5 Interrupt Requests
          1. 24.3.4.5.1 UART Mode Interrupt Management
            1. 24.3.4.5.1.1 UART Interrupts
            2. 24.3.4.5.1.2 Wake-Up Interrupt
          2. 24.3.4.5.2 IrDA Mode Interrupt Management
            1. 24.3.4.5.2.1 IrDA Interrupts
            2. 24.3.4.5.2.2 Wake-Up Interrupts
          3. 24.3.4.5.3 CIR Mode Interrupt Management
            1. 24.3.4.5.3.1 CIR Interrupts
            2. 24.3.4.5.3.2 Wake-Up Interrupts
        6. 24.3.4.6 FIFO Management
          1. 24.3.4.6.1 FIFO Trigger
            1. 24.3.4.6.1.1 Transmit FIFO Trigger
            2. 24.3.4.6.1.2 Receive FIFO Trigger
          2. 24.3.4.6.2 FIFO Interrupt Mode
          3. 24.3.4.6.3 FIFO Polled Mode Operation
          4. 24.3.4.6.4 FIFO DMA Mode Operation
            1. 24.3.4.6.4.1 DMA sequence to disable TX DMA
            2. 24.3.4.6.4.2 DMA Transfers (DMA Mode 1, 2, or 3)
            3. 24.3.4.6.4.3 DMA Transmission
            4. 24.3.4.6.4.4 DMA Reception
        7. 24.3.4.7 Mode Selection
          1. 24.3.4.7.1 Register Access Modes
            1. 24.3.4.7.1.1 Operational Mode and Configuration Modes
            2. 24.3.4.7.1.2 Register Access Submode
            3. 24.3.4.7.1.3 Registers Available for the Register Access Modes
          2. 24.3.4.7.2 UART/IrDA (SIR, MIR, FIR)/CIR Mode Selection
            1. 24.3.4.7.2.1 Registers Available for the UART Function
            2. 24.3.4.7.2.2 Registers Available for the IrDA Function (UART3 Only)
            3. 24.3.4.7.2.3 Registers Available for the CIR Function (UART3 Only)
        8. 24.3.4.8 Protocol Formatting
          1. 24.3.4.8.1 UART Mode
            1. 24.3.4.8.1.1 UART Clock Generation: Baud Rate Generation
            2. 24.3.4.8.1.2 Choosing the Appropriate Divisor Value
            3. 24.3.4.8.1.3 UART Data Formatting
              1. 24.3.4.8.1.3.1 Frame Formatting
              2. 24.3.4.8.1.3.2 Hardware Flow Control
              3. 24.3.4.8.1.3.3 Software Flow Control
                1. 24.3.4.8.1.3.3.1 Receive (RX)
                2. 24.3.4.8.1.3.3.2 Transmit (TX)
              4. 24.3.4.8.1.3.4 Autobauding Modes
              5. 24.3.4.8.1.3.5 Error Detection
              6. 24.3.4.8.1.3.6 Overrun During Receive
              7. 24.3.4.8.1.3.7 Time-Out and Break Conditions
                1. 24.3.4.8.1.3.7.1 Time-Out Counter
                2. 24.3.4.8.1.3.7.2 Break Condition
          2. 24.3.4.8.2 IrDA Mode (UART3 Only)
            1. 24.3.4.8.2.1 IrDA Clock Generation: Baud Generator
            2. 24.3.4.8.2.2 Choosing the Appropriate Divisor Value
            3. 24.3.4.8.2.3 IrDA Data Formatting
              1. 24.3.4.8.2.3.1 IR RX Polarity Control
              2. 24.3.4.8.2.3.2 IrDA Reception Control
              3. 24.3.4.8.2.3.3 IR Address Checking
              4. 24.3.4.8.2.3.4 Frame Closing
              5. 24.3.4.8.2.3.5 Store and Controlled Transmission
              6. 24.3.4.8.2.3.6 Error Detection
              7. 24.3.4.8.2.3.7 Underrun During Transmission
              8. 24.3.4.8.2.3.8 Overrun During Receive
              9. 24.3.4.8.2.3.9 Status FIFO
            4. 24.3.4.8.2.4 SIR Mode Data Formatting
              1. 24.3.4.8.2.4.1 Abort Sequence
              2. 24.3.4.8.2.4.2 Pulse Shaping
              3. 24.3.4.8.2.4.3 SIR Free Format Programming
            5. 24.3.4.8.2.5 MIR and FIR Mode Data Formatting
          3. 24.3.4.8.3 CIR Mode (UART3 Only)
            1. 24.3.4.8.3.1 CIR Mode Clock Generation
            2. 24.3.4.8.3.2 CIR Data Formatting
              1. 24.3.4.8.3.2.1 IR RX Polarity Control
              2. 24.3.4.8.3.2.2 CIR Transmission
      5. 24.3.5 UART/IrDA/CIR Basic Programming Model
        1. 24.3.5.1 Global Initialization
          1. 24.3.5.1.1 Surrounding Modules Global Initialization
          2. 24.3.5.1.2 UART/IrDA/CIR Module Global Initialization
        2. 24.3.5.2 Mode selection
        3. 24.3.5.3 Submode selection
        4. 24.3.5.4 Load FIFO trigger and DMA mode settings
          1. 24.3.5.4.1 DMA mode Settings
          2. 24.3.5.4.2 FIFO Trigger Settings
        5. 24.3.5.5 Protocol, Baud rate and interrupt settings
          1. 24.3.5.5.1 Baud rate settings
          2. 24.3.5.5.2 Interrupt settings
          3. 24.3.5.5.3 Protocol settings
          4. 24.3.5.5.4 UART/IrDA(SIR/MIR/FIR)/CIR
        6. 24.3.5.6 Hardware and Software Flow Control Configuration
          1. 24.3.5.6.1 Hardware Flow Control Configuration
          2. 24.3.5.6.2 Software Flow Control Configuration
        7. 24.3.5.7 IrDA Programming Model (UART3 Only)
          1. 24.3.5.7.1 SIR mode
            1. 24.3.5.7.1.1 Receive
            2. 24.3.5.7.1.2 Transmit
          2. 24.3.5.7.2 MIR mode
            1. 24.3.5.7.2.1 Receive
            2. 24.3.5.7.2.2 Transmit
          3. 24.3.5.7.3 FIR mode
            1. 24.3.5.7.3.1 Receive
            2. 24.3.5.7.3.2 Transmit
      6. 24.3.6 UART/IrDA/CIR Register Manual
        1. 24.3.6.1 UART/IrDA/CIR Instance Summary
        2. 24.3.6.2 UART/IrDA/CIR Registers
          1. 24.3.6.2.1 UART/IrDA/CIR Register Summary
          2. 24.3.6.2.2 UART/IrDA/CIR Register Description
    4. 24.4  Multichannel Serial Peripheral Interface
      1. 24.4.1 McSPI Overview
      2. 24.4.2 McSPI Environment
        1. 24.4.2.1 Basic McSPI Pins for Master Mode
        2. 24.4.2.2 Basic McSPI Pins for Slave Mode
        3. 24.4.2.3 Multichannel SPI Protocol and Data Format
          1. 24.4.2.3.1 Transfer Format
        4. 24.4.2.4 SPI in Master Mode
        5. 24.4.2.5 SPI in Slave Mode
      3. 24.4.3 McSPI Integration
      4. 24.4.4 McSPI Functional Description
        1. 24.4.4.1 McSPI Block Diagram
        2. 24.4.4.2 Reset
        3. 24.4.4.3 Master Mode
          1. 24.4.4.3.1 Master Mode Features
          2. 24.4.4.3.2 Master Transmit-and-Receive Mode (Full Duplex)
          3. 24.4.4.3.3 Master Transmit-Only Mode (Half Duplex)
          4. 24.4.4.3.4 Master Receive-Only Mode (Half Duplex)
          5. 24.4.4.3.5 Single-Channel Master Mode
            1. 24.4.4.3.5.1 Programming Tips When Switching to Another Channel
            2. 24.4.4.3.5.2 Force SPIEN[x] Mode
            3. 24.4.4.3.5.3 Turbo Mode
          6. 24.4.4.3.6 Start-Bit Mode
          7. 24.4.4.3.7 Chip-Select Timing Control
          8. 24.4.4.3.8 Programmable SPI Clock
            1. 24.4.4.3.8.1 Clock Ratio Granularity
        4. 24.4.4.4 Slave Mode
          1. 24.4.4.4.1 Dedicated Resources
          2. 24.4.4.4.2 Slave Transmit-and-Receive Mode
          3. 24.4.4.4.3 Slave Transmit-Only Mode
          4. 24.4.4.4.4 Slave Receive-Only Mode
        5. 24.4.4.5 3-Pin or 4-Pin Mode
        6. 24.4.4.6 FIFO Buffer Management
          1. 24.4.4.6.1 Buffer Almost Full
          2. 24.4.4.6.2 Buffer Almost Empty
          3. 24.4.4.6.3 End of Transfer Management
        7. 24.4.4.7 Interrupts
          1. 24.4.4.7.1 Interrupt Events in Master Mode
            1. 24.4.4.7.1.1 TXx_EMPTY
            2. 24.4.4.7.1.2 TXx_UNDERFLOW
            3. 24.4.4.7.1.3 RXx_ FULL
            4. 24.4.4.7.1.4 End Of Word Count
          2. 24.4.4.7.2 Interrupt Events in Slave Mode
            1. 24.4.4.7.2.1 TXx_EMPTY
            2. 24.4.4.7.2.2 TXx_UNDERFLOW
            3. 24.4.4.7.2.3 RXx_FULL
            4. 24.4.4.7.2.4 RX0_OVERFLOW
            5. 24.4.4.7.2.5 End Of Word Count
          3. 24.4.4.7.3 Interrupt-Driven Operation
          4. 24.4.4.7.4 Polling
        8. 24.4.4.8 DMA Requests
        9. 24.4.4.9 Power Saving Management
          1. 24.4.4.9.1 Normal Mode
          2. 24.4.4.9.2 Idle Mode
            1. 24.4.4.9.2.1 Wake-Up Event in Smart-Idle Mode
            2. 24.4.4.9.2.2 Transitions From Smart-Idle Mode to Normal Mode
            3. 24.4.4.9.2.3 Force-Idle Mode
      5. 24.4.5 McSPI Programming Guide
        1. 24.4.5.1 Global Initialization
          1. 24.4.5.1.1 Surrounding Modules Global Initialization
          2. 24.4.5.1.2 McSPI Global Initialization
            1. 24.4.5.1.2.1 Main Sequence – McSPI Global Initialization
        2. 24.4.5.2 Operational Mode Configuration
          1. 24.4.5.2.1 McSPI Operational Modes
            1. 24.4.5.2.1.1 Common Transfer Sequence
            2. 24.4.5.2.1.2 End of Transfer Sequences
            3. 24.4.5.2.1.3 Transmit-and-Receive (Master and Slave)
            4. 24.4.5.2.1.4 Transmit-Only (Master and Slave)
              1. 24.4.5.2.1.4.1 Based on Interrupt Requests
              2. 24.4.5.2.1.4.2 Based on DMA Write Requests
            5. 24.4.5.2.1.5 Master Normal Receive-Only
              1. 24.4.5.2.1.5.1 Based on Interrupt Requests
              2. 24.4.5.2.1.5.2 Based on DMA Read Requests
            6. 24.4.5.2.1.6 Master Turbo Receive-Only
              1. 24.4.5.2.1.6.1 Based on Interrupt Requests
              2. 24.4.5.2.1.6.2 Based on DMA Read Requests
            7. 24.4.5.2.1.7 Slave Receive-Only
            8. 24.4.5.2.1.8 Transfer Procedures With FIFO
              1. 24.4.5.2.1.8.1 Common Transfer Sequence in FIFO Mode
              2. 24.4.5.2.1.8.2 End of Transfer Sequences in FIFO Mode
              3. 24.4.5.2.1.8.3 Transmit-and-Receive With Word Count
              4. 24.4.5.2.1.8.4 Transmit-and-Receive Without Word Count
              5. 24.4.5.2.1.8.5 Transmit-Only
              6. 24.4.5.2.1.8.6 Receive-Only With Word Count
              7. 24.4.5.2.1.8.7 Receive-Only Without Word Count
        3. 24.4.5.3 Common Transfer Procedures Without FIFO – Polling Method
          1. 24.4.5.3.1 Receive-Only Procedure – Polling Method
          2. 24.4.5.3.2 Receive-Only Procedure – Interrupt Method
          3. 24.4.5.3.3 Transmit-Only Procedure – Polling Method
          4. 24.4.5.3.4 Transmit-and-Receive Procedure – Polling Method
      6. 24.4.6 McSPI Register Manual
        1. 24.4.6.1 McSPI Instance Summary
        2. 24.4.6.2 McSPI Registers
          1. 24.4.6.2.1 McSPI Register Summary
          2. 24.4.6.2.2 McSPI Register Description
    5. 24.5  Quad Serial Peripheral Interface
      1. 24.5.1 Quad Serial Peripheral Interface Overview
      2. 24.5.2 QSPI Environment
      3. 24.5.3 QSPI Integration
      4. 24.5.4 QSPI Functional Description
        1. 24.5.4.1 QSPI Block Diagram
          1. 24.5.4.1.1 SFI Register Control
          2. 24.5.4.1.2 SFI Translator
          3. 24.5.4.1.3 SPI Control Interface
          4. 24.5.4.1.4 SPI Clock Generator
          5. 24.5.4.1.5 SPI Control State-Machine
          6. 24.5.4.1.6 SPI Data Shifter
        2. 24.5.4.2 QSPI Clock Configuration
        3. 24.5.4.3 QSPI Interrupt Requests
        4. 24.5.4.4 QSPI Memory Regions
      5. 24.5.5 QSPI Register Manual
        1. 24.5.5.1 QSPI Instance Summary
        2. 24.5.5.2 QSPI registers
          1. 24.5.5.2.1 QSPI Register Summary
          2. 24.5.5.2.2 QSPI Register Description
    6. 24.6  Multichannel Audio Serial Port
      1. 24.6.1 McASP Overview
      2. 24.6.2 McASP Environment
        1. 24.6.2.1 McASP Signals
        2. 24.6.2.2 Protocols and Data Formats
          1. 24.6.2.2.1 Protocols Supported
          2. 24.6.2.2.2 Definition of Terms
          3. 24.6.2.2.3 TDM Format
          4. 24.6.2.2.4 I2S Format
          5. 24.6.2.2.5 S/PDIF Coding Format
            1. 24.6.2.2.5.1 Biphase-Mark Code
            2. 24.6.2.2.5.2 S/PDIF Subframe Format
            3. 24.6.2.2.5.3 Frame Format
      3. 24.6.3 McASP Integration
      4. 24.6.4 McASP Functional Description
        1. 24.6.4.1  McASP Block Diagram
        2. 24.6.4.2  McASP Clock and Frame-Sync Configurations
          1. 24.6.4.2.1 McASP Transmit Clock
          2. 24.6.4.2.2 McASP Receive Clock
          3. 24.6.4.2.3 Frame-Sync Generator
          4. 24.6.4.2.4 Synchronous and Asynchronous Transmit and Receive Operations
        3. 24.6.4.3  Serializers
        4. 24.6.4.4  Format Units
          1. 24.6.4.4.1 Transmit Format Unit
            1. 24.6.4.4.1.1 TDM Mode Transmission Data Alignment Settings
            2. 24.6.4.4.1.2 DIT Mode Transmission Data Alignment Settings
          2. 24.6.4.4.2 Receive Format Unit
            1. 24.6.4.4.2.1 TDM Mode Reception Data Alignment Settings
        5. 24.6.4.5  State-Machines
        6. 24.6.4.6  TDM Sequencers
        7. 24.6.4.7  McASP Software Reset
        8. 24.6.4.8  McASP Power Management
        9. 24.6.4.9  Transfer Modes
          1. 24.6.4.9.1 Burst Transfer Mode
          2. 24.6.4.9.2 Time-Division Multiplexed (TDM) Transfer Mode
            1. 24.6.4.9.2.1 TDM Time Slots Generation and Processing
            2. 24.6.4.9.2.2 Special 384-Slot TDM Mode for Connection to External DIR
          3. 24.6.4.9.3 DIT Transfer Mode
            1. 24.6.4.9.3.1 Transmit DIT Encoding
            2. 24.6.4.9.3.2 Transmit DIT Clock and Frame-Sync Generation
            3. 24.6.4.9.3.3 DIT Channel Status and User Data Register Files
        10. 24.6.4.10 Data Transmission and Reception
          1. 24.6.4.10.1 Data Ready Status and Event/Interrupt Generation
            1. 24.6.4.10.1.1 Transmit Data Ready
            2. 24.6.4.10.1.2 Receive Data Ready
            3. 24.6.4.10.1.3 Transfers Through the Data Port (DATA)
            4. 24.6.4.10.1.4 Transfers Through the Configuration Bus (CFG)
            5. 24.6.4.10.1.5 Using a Device CPU for McASP Servicing
            6. 24.6.4.10.1.6 Using the DMA for McASP Servicing
        11. 24.6.4.11 McASP Audio FIFO (AFIFO)
          1. 24.6.4.11.1 AFIFO Data Transmission
            1. 24.6.4.11.1.1 Transmit DMA Event Pacer
          2. 24.6.4.11.2 AFIFO Data Reception
            1. 24.6.4.11.2.1 Receive DMA Event Pacer
          3. 24.6.4.11.3 Arbitration Between Transmit and Receive DMA Requests
        12. 24.6.4.12 McASP Events and Interrupt Requests
          1. 24.6.4.12.1 Transmit Data Ready Event and Interrupt
          2. 24.6.4.12.2 Receive Data Ready Event and Interrupt
          3. 24.6.4.12.3 Error Interrupt
          4. 24.6.4.12.4 Multiple Interrupts
        13. 24.6.4.13 DMA Requests
        14. 24.6.4.14 Loopback Modes
          1. 24.6.4.14.1 Loopback Mode Configurations
        15. 24.6.4.15 Error Reporting
          1. 24.6.4.15.1 Buffer Underrun Error -Transmitter
          2. 24.6.4.15.2 Buffer Overrun Error-Receiver
          3. 24.6.4.15.3 DATA Port Error - Transmitter
          4. 24.6.4.15.4 DATA Port Error - Receiver
          5. 24.6.4.15.5 Unexpected Frame Sync Error
          6. 24.6.4.15.6 Clock Failure Detection
            1. 24.6.4.15.6.1 Clock Failure Check Startup
            2. 24.6.4.15.6.2 Transmit Clock Failure Check and Recovery
            3. 24.6.4.15.6.3 Receive Clock Failure Check and Recovery
      5. 24.6.5 McASP Low-Level Programming Model
        1. 24.6.5.1 Global Initialization
          1. 24.6.5.1.1 Surrounding Modules Global Initialization
          2. 24.6.5.1.2 McASP Global Initialization
            1. 24.6.5.1.2.1 Main Sequence – McASP Global Initialization for DIT-Transmission
              1. 24.6.5.1.2.1.1 Subsequence – Transmit Format Unit Configuration for DIT-Transmission
              2. 24.6.5.1.2.1.2 Subsequence – Transmit Frame Synchronization Generator Configuration for DIT-Transmission
              3. 24.6.5.1.2.1.3 Subsequence – Transmit Clock Generator Configuration for DIT-Transmission
              4. 24.6.5.1.2.1.4 Subsequence - McASP Pins Functional Configuration
              5. 24.6.5.1.2.1.5 Subsequence – DIT-specific Subframe Fields Configuration
            2. 24.6.5.1.2.2 Main Sequence – McASP Global Initialization for TDM-Reception
              1. 24.6.5.1.2.2.1 Subsequence – Receive Format Unit Configuration in TDM Mode
              2. 24.6.5.1.2.2.2 Subsequence – Receive Frame Synchronization Generator Configuration in TDM Mode
              3. 24.6.5.1.2.2.3 Subsequence – Receive Clock Generator Configuration
              4. 24.6.5.1.2.2.4 Subsequence—McASP Receiver Pins Functional Configuration
            3. 24.6.5.1.2.3 Main Sequence – McASP Global Initialization for TDM -Transmission
              1. 24.6.5.1.2.3.1 Subsequence – Transmit Format Unit Configuration in TDM Mode
              2. 24.6.5.1.2.3.2 Subsequence – Transmit Frame Synchronization Generator Configuration in TDM Mode
              3. 24.6.5.1.2.3.3 Subsequence – Transmit Clock Generator Configuration for TDM Cases
              4. 24.6.5.1.2.3.4 Subsequence—McASP Transmit Pins Functional Configuration
        2. 24.6.5.2 Operational Modes Configuration
          1. 24.6.5.2.1 McASP Transmission Modes
            1. 24.6.5.2.1.1 Main Sequence – McASP DIT- /TDM- Polling Transmission Method
            2. 24.6.5.2.1.2 Main Sequence – McASP DIT- /TDM - Interrupt Transmission Method
            3. 24.6.5.2.1.3 Main Sequence –McASP DIT- /TDM - Mode DMA Transmission Method
          2. 24.6.5.2.2 McASP Reception Modes
            1. 24.6.5.2.2.1 Main Sequence – McASP Polling Reception Method
            2. 24.6.5.2.2.2 Main Sequence – McASP TDM - Interrupt Reception Method
            3. 24.6.5.2.2.3 Main Sequence – McASP TDM - Mode DMA Reception Method
          3. 24.6.5.2.3 McASP Event Servicing
            1. 24.6.5.2.3.1 McASP DIT-/TDM- Transmit Interrupt Events Servicing
            2. 24.6.5.2.3.2 McASP TDM- Receive Interrupt Events Servicing
            3. 24.6.5.2.3.3 3645
            4. 24.6.5.2.3.4 Subsequence – McASP DIT-/TDM -Modes Transmit Error Handling
            5. 24.6.5.2.3.5 Subsequence – McASP Receive Error Handling
      6. 24.6.6 McASP Register Manual
        1. 24.6.6.1 McASP Instance Summary
        2. 24.6.6.2 McASP Registers
          1. 24.6.6.2.1 MCASP_CFG Register Summary
          2. 24.6.6.2.2 MCASP_CFG Register Description
          3. 24.6.6.2.3 MCASP_AFIFO Register Summary
          4. 24.6.6.2.4 MCASP_AFIFO Register Description
          5. 24.6.6.2.5 MCASP_DAT Register Summary
          6. 24.6.6.2.6 MCASP_DAT Register Description
    7. 24.7  SuperSpeed USB DRD
      1. 24.7.1 SuperSpeed USB DRD Subsystem Overview
        1. 24.7.1.1 Main Features
      2. 24.7.2 SuperSpeed USB DRD Subsystem Environment
        1. 24.7.2.1 SuperSpeed USB DRD Subsystem I/O Interfaces
        2. 24.7.2.2 SuperSpeed USB Subsystem Application
          1. 24.7.2.2.1 USB3.0 DRD Application
          2. 24.7.2.2.2 USB2.0 DRD Internal PHY
          3. 24.7.2.2.3 USB2.0 DRD External PHY
          4. 24.7.2.2.4 3666
          5. 24.7.2.2.5 Host Mode
          6. 24.7.2.2.6 Device Mode
      3. 24.7.3 SuperSpeed USB Subsystem Integration
    8. 24.8  SATA Controller
      1. 24.8.1 SATA Controller Overview
        1. 24.8.1.1 SATA Controller
          1. 24.8.1.1.1 AHCI Mode Overview
          2. 24.8.1.1.2 Native Command Queuing
          3. 24.8.1.1.3 SATA Transport Layer Functionalities
          4. 24.8.1.1.4 SATA Link Layer Functionalities
        2. 24.8.1.2 SATA Controller Features
      2. 24.8.2 SATA Controller Environment
      3. 24.8.3 SATA Controller Integration
      4. 24.8.4 SATA Controller Functional Description
        1. 24.8.4.1  SATA Controller Block Diagram
        2. 24.8.4.2  SATA Controller Link Layer Protocol and Data Format
          1. 24.8.4.2.1 SATA 8b/10b Parallel Encoding/Decoding
          2. 24.8.4.2.2 SATA Stream Dword Components
          3. 24.8.4.2.3 Scrambling/Descrambling Processing
        3. 24.8.4.3  Resets
          1. 24.8.4.3.1 Hardware Reset
          2. 24.8.4.3.2 Software Initiated Resets
            1. 24.8.4.3.2.1 Software Reset
            2. 24.8.4.3.2.2 Port Reset
            3. 24.8.4.3.2.3 HBA Reset
        4. 24.8.4.4  Power Management
          1. 24.8.4.4.1 SATA Specific Power Management
            1. 24.8.4.4.1.1 PARTIAL Power Mode
            2. 24.8.4.4.1.2 Slumber Power Mode
            3. 24.8.4.4.1.3 Software Control over Low Power States
            4. 24.8.4.4.1.4 Aggressive Power Management
          2. 24.8.4.4.2 Master Standby and Slave Idle Management Protocols
          3. 24.8.4.4.3 Clock Gating Synchronization
          4. 24.8.4.4.4 3700
        5. 24.8.4.5  Interrupt Requests
          1. 24.8.4.5.1 Interrupt Generation
          2. 24.8.4.5.2 Levels of Interrupt Control
          3. 24.8.4.5.3 Interrupt Events Description
            1. 24.8.4.5.3.1  Task File Error Status
            2. 24.8.4.5.3.2  Host Bus Fatal Error
            3. 24.8.4.5.3.3  Interface Fatal Error Status
            4. 24.8.4.5.3.4  Interface Non-Fatal Error Status
            5. 24.8.4.5.3.5  Overflow Status
            6. 24.8.4.5.3.6  Incorrect Port Multiplier Status
            7. 24.8.4.5.3.7  PHYReady Change Status
            8. 24.8.4.5.3.8  Port Connect Change Status
            9. 24.8.4.5.3.9  Descriptor Processed
            10. 24.8.4.5.3.10 Unknown FIS Interrupt
            11. 24.8.4.5.3.11 Set Device Bits Interrupt
            12. 24.8.4.5.3.12 DMA Setup FIS Interrupt
            13. 24.8.4.5.3.13 PIO Setup FIS Interrupt
            14. 24.8.4.5.3.14 Device to Host Register FIS Interrupt
          4. 24.8.4.5.4 Interrupt Condition Control
          5. 24.8.4.5.5 Command Completion Coalescing Interrupts
            1. 24.8.4.5.5.1 CCC Interrupt Based on Expired Timeout Value
            2. 24.8.4.5.5.2 CCC Interrupt Based on Completion Count
        6. 24.8.4.6  System Memory FIS Descriptors
          1. 24.8.4.6.1 Command List Structure Basics
          2. 24.8.4.6.2 Supported Types of Commands
          3. 24.8.4.6.3 Received FIS Structures
          4. 24.8.4.6.4 FIS Descriptors Summary
        7. 24.8.4.7  Transport Layer FIS-Based Interactions
          1. 24.8.4.7.1 Software Processing of the Port Command List
          2. 24.8.4.7.2 Handling the Received FIS Descriptors
        8. 24.8.4.8  DMA Port Configuration
        9. 24.8.4.9  Port Multiplier Operation
          1. 24.8.4.9.1 Command-Based Switching Mode
            1. 24.8.4.9.1.1 Port Multiplier NCQ and Non-NCQ Commands Generation
          2. 24.8.4.9.2 Port Multiplier Enumeration
        10. 24.8.4.10 Activity LED Generation Functionality
        11. 24.8.4.11 Supported Types of SATA Transfers
          1. 24.8.4.11.1 Supported Higher Level Protocols
        12. 24.8.4.12 SATA Controller AHCI Hardware Register Interface
      5. 24.8.5 SATA Controller Low Level Programming Model
        1. 24.8.5.1 Global Initialization
          1. 24.8.5.1.1 Surrounding Modules Global Initialization
          2. 24.8.5.1.2 SATA Controller Global Initialization
            1. 24.8.5.1.2.1 Main Sequence SATA Controller Global Initialization
            2. 24.8.5.1.2.2 SubSequence – Firmware Capability Writes
          3. 24.8.5.1.3 Issue Command - Main Sequence
          4. 24.8.5.1.4 Receive FIS—Main Sequence
      6. 24.8.6 SATA Controller Register Manual
        1. 24.8.6.1 SATA Controller Instance Summary
        2. 24.8.6.2 DWC_ahsata Registers
          1. 24.8.6.2.1 DWC_ahsata Register Summary
          2. 24.8.6.2.2 DWC_ahsata Register Description
        3. 24.8.6.3 SATAMAC_wrapper Registers
          1. 24.8.6.3.1 SATAMAC_wrapper Register Summary
          2. 24.8.6.3.2 SATAMAC_wrapper Register Description
    9. 24.9  PCIe Controller
      1. 24.9.1 PCIe Controller Subsystem Overview
        1. 24.9.1.1 PCIe Controllers Key Features
      2. 24.9.2 PCIe Controller Environment
      3. 24.9.3 PCIe Controllers Integration
      4. 24.9.4 PCIe SS Controller Functional Description
        1. 24.9.4.1 PCIe Controller Functional Block Diagram
        2. 24.9.4.2 PCIe Traffics
        3. 24.9.4.3 PCIe Controller Ports on L3_MAIN Interconnect
          1. 24.9.4.3.1 PCIe Controller Master Port
            1. 24.9.4.3.1.1 PCIe Controller Master Port to MMU Routing
          2. 24.9.4.3.2 PCIe Controller Slave Port
          3. 24.9.4.3.3 3768
        4. 24.9.4.4 PCIe Controller Reset Management
          1. 24.9.4.4.1 PCIe Reset Types and Stickiness
          2. 24.9.4.4.2 PCIe Reset Conditions
            1. 24.9.4.4.2.1 PCIe Main Reset
              1. 24.9.4.4.2.1.1 PCIe Subsystem Cold Main Reset Source
              2. 24.9.4.4.2.1.2 PCIe Subsystem Warm Main Reset Sources
            2. 24.9.4.4.2.2 PCIe Standard Specific Resets to the PCIe Core Logic
        5. 24.9.4.5 PCIe Controller Power Management
          1. 24.9.4.5.1 PCIe Protocol Power Management
            1. 24.9.4.5.1.1 PCIe Device/function power state (D-state)
            2. 24.9.4.5.1.2 PCIe Controller PIPE Powerstate (Powerdown Control)
          2. 24.9.4.5.2 PCIE Controller Clocks Management
            1. 24.9.4.5.2.1 PCIe Clock Domains
            2. 24.9.4.5.2.2 PCIe Controller Idle/Standby Clock Management Interfaces
              1. 24.9.4.5.2.2.1 PCIe Controller Master Standby Behavior
              2. 24.9.4.5.2.2.2 PCIe Controller Slave Idle/Disconnect Behavior
                1. 24.9.4.5.2.2.2.1 PCIe Controller Idle Sequence During D3cold/L3 State
        6. 24.9.4.6 PCIe Controller Interrupt Requests
          1. 24.9.4.6.1 PCIe Controller Main Hardware Management
            1. 24.9.4.6.1.1 PCIe Management Interrupt Events
            2. 24.9.4.6.1.2 PCIe Error Interrupt Events
            3. 24.9.4.6.1.3 Summary of PCIe Controller Main Hardware Interrupt Events
          2. 24.9.4.6.2 PCIe Controller Legacy and MSI Virtual Interrupts Management
            1. 24.9.4.6.2.1 Legacy PCI Interrupts (INTx)
              1. 24.9.4.6.2.1.1 Legacy PCI Interrupt Events Overview
              2. 24.9.4.6.2.1.2 Legacy PCI Interrupt Transmission (EP mode only)
              3. 24.9.4.6.2.1.3 Legacy PCI Interrupt Reception (RC mode only)
            2. 24.9.4.6.2.2 PCIe Controller Message Signaled Interrupts (MSI)
              1. 24.9.4.6.2.2.1 PCIe Specific MSI Interrupt Event Overview
              2. 24.9.4.6.2.2.2 PCIe Controller MSI Transmission Methods (EP mode)
                1. 24.9.4.6.2.2.2.1 PCIe Controller MSI transmission, hardware method
                2. 24.9.4.6.2.2.2.2 PCIe Controller MSI transmission, software method
              3. 24.9.4.6.2.2.3 PCIe Controller MSI Reception (RC mode)
          3. 24.9.4.6.3 PCIe Controller MSI Hardware Interrupt Events
        7. 24.9.4.7 PCIe Controller Address Spaces and Address Translation
        8. 24.9.4.8 PCIe Traffic Requesting and Responding
          1. 24.9.4.8.1 PCIe Memory-type (Mem) Traffic Management
            1. 24.9.4.8.1.1 PCIe Memory Requesting
            2. 24.9.4.8.1.2 PCIe Memory Responding
          2. 24.9.4.8.2 PCIe Configuration Type (Cfg) Traffic Management
            1. 24.9.4.8.2.1 RC Self-configuration (RC Only)
            2. 24.9.4.8.2.2 Configuration Requests over PCIe (RC Only)
            3. 24.9.4.8.2.3 Configuration Responding over PCIe (EP Only)
          3. 24.9.4.8.3 PCIe I/O-type (IO) traffic management
            1. 24.9.4.8.3.1 PCIe I/O requesting (RC only)
            2. 24.9.4.8.3.2 PCIe IO BAR initialization before enumeration (EP only)
            3. 24.9.4.8.3.3 PCIe I/O responding (PCI legacy EP only)
          4. 24.9.4.8.4 PCIe Message-type (Msg) traffic management
        9. 24.9.4.9 PCIe Programming Register Interface
          1. 24.9.4.9.1 PCIe Register Access
          2. 24.9.4.9.2 Double Mapping of the PCIe Local Control Registers
          3. 24.9.4.9.3 Base Address Registers (BAR) Initialization
      5. 24.9.5 PCIe Controller Low Level Programming Model
        1. 24.9.5.1 Surrounding Modules Global Initialization
        2. 24.9.5.2 Main Sequence of PCIe Controllers Initalization
      6. 24.9.6 PCIe Standard Registers vs PCIe Subsystem Hardware Registers Mapping
      7. 24.9.7 PCIe Controller Register Manual
        1. 24.9.7.1 PCIe Controller Instance Summary
        2. 24.9.7.2 PCIe_SS_EP_CFG_PCIe Registers
          1. 24.9.7.2.1 PCIe_SS_EP_CFG_PCIe Register Summary
          2. 24.9.7.2.2 PCIe_SS_EP_CFG_PCIe Register Description
          3. 24.9.7.2.3 3830
        3. 24.9.7.3 PCIe_SS_EP_CFG_DBICS Registers
          1. 24.9.7.3.1 PCIe_SS_EP_CFG_DBICS Register Summary
          2. 24.9.7.3.2 PCIe_SS_EP_CFG_DBICS Register Description
        4. 24.9.7.4 PCIe_SS_RC_CFG_DBICS Registers
          1. 24.9.7.4.1 PCIe_SS_RC_CFG_DBICS Register Summary
          2. 24.9.7.4.2 PCIe_SS_RC_CFG_DBICS Register Description
        5. 24.9.7.5 PCIe_SS_PL_CONF Registers
          1. 24.9.7.5.1 PCIe_SS_PL_CONF Register Summary
          2. 24.9.7.5.2 PCIe_SS_PL_CONF Register Description
        6. 24.9.7.6 PCIe_SS_EP_CFG_DBICS2 Registers
          1. 24.9.7.6.1 PCIe_SS_EP_CFG_DBICS2 Register Summary
          2. 24.9.7.6.2 PCIe_SS_EP_CFG_DBICS2 Register Description
        7. 24.9.7.7 PCIe_SS_RC_CFG_DBICS2 Registers
          1. 24.9.7.7.1 PCIe_SS_RC_CFG_DBICS2 Register Summary
          2. 24.9.7.7.2 PCIe_SS_RC_CFG_DBICS2 Register Description
        8. 24.9.7.8 PCIe_SS_TI_CONF Registers
          1. 24.9.7.8.1 PCIe_SS_TI_CONF Register Summary
          2. 24.9.7.8.2 PCIe_SS_TI_CONF Register Description
    10. 24.10 DCAN
      1. 24.10.1 DCAN Overview
        1. 24.10.1.1 Features
      2. 24.10.2 DCAN Environment
        1. 24.10.2.1 CAN Network Basics
      3. 24.10.3 DCAN Integration
      4. 24.10.4 DCAN Functional Description
        1. 24.10.4.1  Module Clocking Requirements
        2. 24.10.4.2  Interrupt Functionality
          1. 24.10.4.2.1 Message Object Interrupts
          2. 24.10.4.2.2 Status Change Interrupts
          3. 24.10.4.2.3 Error Interrupts
        3. 24.10.4.3  DMA Functionality
        4. 24.10.4.4  Local Power-Down Mode
          1. 24.10.4.4.1 Entering Local Power-Down Mode
          2. 24.10.4.4.2 Wakeup From Local Power Down
        5. 24.10.4.5  Parity Check Mechanism
          1. 24.10.4.5.1 Behavior on Parity Error
          2. 24.10.4.5.2 Parity Testing
        6. 24.10.4.6  Debug/Suspend Mode
        7. 24.10.4.7  Configuration of Message Objects Description
          1. 24.10.4.7.1 Configuration of a Transmit Object for Data Frames
          2. 24.10.4.7.2 Configuration of a Transmit Object for Remote Frames
          3. 24.10.4.7.3 Configuration of a Single Receive Object for Data Frames
          4. 24.10.4.7.4 Configuration of a Single Receive Object for Remote Frames
          5. 24.10.4.7.5 Configuration of a FIFO Buffer
        8. 24.10.4.8  Message Handling
          1. 24.10.4.8.1  Message Handler Overview
          2. 24.10.4.8.2  Receive/Transmit Priority
          3. 24.10.4.8.3  Transmission of Messages in Event Driven CAN Communication
          4. 24.10.4.8.4  Updating a Transmit Object
          5. 24.10.4.8.5  Changing a Transmit Object
          6. 24.10.4.8.6  Acceptance Filtering of Received Messages
          7. 24.10.4.8.7  Reception of Data Frames
          8. 24.10.4.8.8  Reception of Remote Frames
          9. 24.10.4.8.9  Reading Received Messages
          10. 24.10.4.8.10 Requesting New Data for a Receive Object
          11. 24.10.4.8.11 Storing Received Messages in FIFO Buffers
          12. 24.10.4.8.12 Reading From a FIFO Buffer
        9. 24.10.4.9  CAN Bit Timing
          1. 24.10.4.9.1 Bit Time and Bit Rate
            1. 24.10.4.9.1.1 Synchronization Segment
            2. 24.10.4.9.1.2 Propagation Time Segment
            3. 24.10.4.9.1.3 Phase Buffer Segments and Synchronization
            4. 24.10.4.9.1.4 Oscillator Tolerance Range
          2. 24.10.4.9.2 DCAN Bit Timing Registers
            1. 24.10.4.9.2.1 Calculation of the Bit Timing Parameters
            2. 24.10.4.9.2.2 Example for Bit Timing Calculation
        10. 24.10.4.10 Message Interface Register Sets
          1. 24.10.4.10.1 Message Interface Register Sets 1 and 2
          2. 24.10.4.10.2 IF3 Register Set
        11. 24.10.4.11 Message RAM
          1. 24.10.4.11.1 Structure of Message Objects
          2. 24.10.4.11.2 Addressing Message Objects in RAM
          3. 24.10.4.11.3 Message RAM Representation in Debug/Suspend Mode
          4. 24.10.4.11.4 Message RAM Representation in Direct Access Mode
        12. 24.10.4.12 CAN Operation
          1. 24.10.4.12.1 CAN Module Initialization
            1. 24.10.4.12.1.1 Configuration of CAN Bit Timing
            2. 24.10.4.12.1.2 Configuration of Message Objects
            3. 24.10.4.12.1.3 DCAN RAM Hardware Initialization
          2. 24.10.4.12.2 CAN Message Transfer (Normal Operation)
            1. 24.10.4.12.2.1 Automatic Retransmission
            2. 24.10.4.12.2.2 Auto-Bus-On
          3. 24.10.4.12.3 Test Modes
            1. 24.10.4.12.3.1 Silent Mode
            2. 24.10.4.12.3.2 Loopback Mode
            3. 24.10.4.12.3.3 External Loopback Mode
            4. 24.10.4.12.3.4 Loopback Mode Combined With Silent Mode
            5. 24.10.4.12.3.5 Software Control of CAN_TX Pin
        13. 24.10.4.13 GPIO Support
      5. 24.10.5 DCAN Register Manual
        1. 24.10.5.1 DCAN Instance Summary
        2. 24.10.5.2 DCAN Registers
          1. 24.10.5.2.1 DCAN Register Summary
          2. 24.10.5.2.2 DCAN Register Description
    11. 24.11 Gigabit Ethernet Switch (GMAC_SW)
      1. 24.11.1 GMAC_SW Overview
        1. 24.11.1.1 Features
        2. 24.11.1.2 3928
      2. 24.11.2 GMAC_SW Environment
        1. 24.11.2.1 G/MII Interface
        2. 24.11.2.2 RMII Interface
        3. 24.11.2.3 RGMII Interface
      3. 24.11.3 GMAC_SW Integration
      4. 24.11.4 GMAC_SW Functional Description
        1. 24.11.4.1  Functional Block Diagram
        2. 24.11.4.2  GMAC_SW Ports
          1. 24.11.4.2.1 Interface Mode Selection
        3. 24.11.4.3  Clocking
          1. 24.11.4.3.1 Subsystem Clocking
          2. 24.11.4.3.2 Interface Clocking
            1. 24.11.4.3.2.1 G/MII Interface Clocking
            2. 24.11.4.3.2.2 RGMII Interface Clocking
            3. 24.11.4.3.2.3 RMII Interface Clocking
            4. 24.11.4.3.2.4 MDIO Clocking
        4. 24.11.4.4  Software IDLE
        5. 24.11.4.5  Interrupt Functionality
          1. 24.11.4.5.1 Receive Packet Completion Pulse Interrupt (RX_PULSE)
          2. 24.11.4.5.2 Transmit Packet Completion Pulse Interrupt (TX_PULSE)
          3. 24.11.4.5.3 Receive Threshold Pulse Interrupt (RX_THRESH_PULSE)
          4. 24.11.4.5.4 Miscellaneous Pulse Interrupt (MISC_PULSE)
            1. 24.11.4.5.4.1 EVNT_PEND( CPTS_PEND) Interrupt
            2. 24.11.4.5.4.2 Statistics Interrupt
            3. 24.11.4.5.4.3 Host Error interrupt
            4. 24.11.4.5.4.4 MDIO Interrupts
          5. 24.11.4.5.5 Interrupt Pacing
        6. 24.11.4.6  Reset Isolation
          1. 24.11.4.6.1 Reset Isolation Functional Description
        7. 24.11.4.7  Software Reset
        8. 24.11.4.8  CPSW_3G
          1. 24.11.4.8.1  CPDMA RX and TX Interfaces
            1. 24.11.4.8.1.1 Functional Operation
            2. 24.11.4.8.1.2 Receive DMA Interface
              1. 24.11.4.8.1.2.1 Receive DMA Host Configuration
              2. 24.11.4.8.1.2.2 Receive Channel Teardown
            3. 24.11.4.8.1.3 Transmit DMA Interface
              1. 24.11.4.8.1.3.1 Transmit DMA Host Configuration
              2. 24.11.4.8.1.3.2 Transmit Channel Teardown
            4. 24.11.4.8.1.4 Transmit Rate Limiting
            5. 24.11.4.8.1.5 Command IDLE
          2. 24.11.4.8.2  Address Lookup Engine (ALE)
            1. 24.11.4.8.2.1 Address Table Entry
              1. 24.11.4.8.2.1.1 Free Table Entry
              2. 24.11.4.8.2.1.2 Multicast Address Table Entry
              3. 24.11.4.8.2.1.3 VLAN/Multicast Address Table Entry
              4. 24.11.4.8.2.1.4 Unicast Address Table Entry
              5. 24.11.4.8.2.1.5 OUI Unicast Address Table Entry
              6. 24.11.4.8.2.1.6 VLAN/Unicast Address Table Entry
              7. 24.11.4.8.2.1.7 VLAN Table Entry
            2. 24.11.4.8.2.2 Packet Forwarding Processes
            3. 24.11.4.8.2.3 Learning Process
            4. 24.11.4.8.2.4 VLAN Aware Mode
            5. 24.11.4.8.2.5 VLAN Unaware Mode
          3. 24.11.4.8.3  Packet Priority Handling
          4. 24.11.4.8.4  FIFO Memory Control
          5. 24.11.4.8.5  FIFO Transmit Queue Control
            1. 24.11.4.8.5.1 Normal Priority Mode
            2. 24.11.4.8.5.2 Dual MAC Mode
            3. 24.11.4.8.5.3 Rate Limit Mode
          6. 24.11.4.8.6  Audio Video Bridging
            1. 24.11.4.8.6.1 IEEE 802.1AS: Timing and Synchronization for Time-Sensitive Applications in Bridged Local Area Networks (Precision Time Protocol (PTP))
              1. 24.11.4.8.6.1.1 IEEE 1722: "Layer 2 Transport Protocol for Time-Sensitive Streams"
              2. 24.11.4.8.6.1.2 IEEE 1733: Extends RTCP for RTP Streaming over AVB-supported Networks
            2. 24.11.4.8.6.2 IEEE 802.1Qav: "Virtual Bridged Local Area Networks: Forwarding and Queuing for Time-Sensitive Streams"
              1. 24.11.4.8.6.2.1 Configuring the Device for 802.1Qav Operation:
          7. 24.11.4.8.7  Ethernet MAC Sliver (CPGMAC_SL)
            1. 24.11.4.8.7.1 G/MII Media Independent Interface
              1. 24.11.4.8.7.1.1 Data Reception
                1. 24.11.4.8.7.1.1.1 Receive Control
                2. 24.11.4.8.7.1.1.2 Receive Inter-Frame Interval
              2. 24.11.4.8.7.1.2 Data Transmission
                1. 24.11.4.8.7.1.2.1 Transmit Control
                2. 24.11.4.8.7.1.2.2 CRC Insertion
                3. 24.11.4.8.7.1.2.3 MTXER
                4. 24.11.4.8.7.1.2.4 Adaptive Performance Optimization (APO)
                5. 24.11.4.8.7.1.2.5 Inter-Packet-Gap Enforcement
                6. 24.11.4.8.7.1.2.6 Back Off
                7. 24.11.4.8.7.1.2.7 Programmable Transmit Inter-Packet Gap
                8. 24.11.4.8.7.1.2.8 Speed, Duplex and Pause Frame Support Negotiation
            2. 24.11.4.8.7.2 RMII Interface
              1. 24.11.4.8.7.2.1 Features
              2. 24.11.4.8.7.2.2 RMII Receive (RX)
              3. 24.11.4.8.7.2.3 RMII Transmit (TX)
            3. 24.11.4.8.7.3 RGMII Interface
              1. 24.11.4.8.7.3.1 RGMII Features
              2. 24.11.4.8.7.3.2 RGMII Receive (RX)
              3. 24.11.4.8.7.3.3 In-Band Mode of Operation
              4. 24.11.4.8.7.3.4 Forced Mode of Operation
              5. 24.11.4.8.7.3.5 RGMII Transmit (TX)
            4. 24.11.4.8.7.4 Frame Classification
          8. 24.11.4.8.8  Embedded Memories
          9. 24.11.4.8.9  Flow Control
            1. 24.11.4.8.9.1 CPPI Port Flow Control
            2. 24.11.4.8.9.2 Ethernet Port Flow Control
              1. 24.11.4.8.9.2.1 Receive Flow Control
                1. 24.11.4.8.9.2.1.1 Collision Based Receive Buffer Flow Control
                2. 24.11.4.8.9.2.1.2 IEEE 802.3X Based Receive Flow Control
              2. 24.11.4.8.9.2.2 Transmit Flow Control
          10. 24.11.4.8.10 Short Gap
          11. 24.11.4.8.11 Switch Latency
          12. 24.11.4.8.12 Emulation Control
          13. 24.11.4.8.13 FIFO Loopback
          14. 24.11.4.8.14 Device Level Ring (DLR) Support
          15. 24.11.4.8.15 Energy Efficient Ethernet Support (802.3az)
          16. 24.11.4.8.16 CPSW_3G Network Statistics
            1. 24.11.4.8.16.1 4035
        9. 24.11.4.9  Static Packet Filter (SPF)
          1. 24.11.4.9.1 SPF Overview
          2. 24.11.4.9.2 SPF Functional Description
            1. 24.11.4.9.2.1 SPF Block Diagram
            2. 24.11.4.9.2.2 Interrupts
            3. 24.11.4.9.2.3 Protocol Header Extractor
            4. 24.11.4.9.2.4 Programmable Rule Engine
              1. 24.11.4.9.2.4.1 Internal Registers
              2. 24.11.4.9.2.4.2 Packet Buffer
            5. 24.11.4.9.2.5 Intrusion Event Logger
            6. 24.11.4.9.2.6 Rate Limiter
            7. 24.11.4.9.2.7 Rule Engine Instruction Set Architecture
              1. 24.11.4.9.2.7.1 Instruction Format
              2. 24.11.4.9.2.7.2 Operand Field
              3. 24.11.4.9.2.7.3 Arithmetic/Logical Function Field
              4. 24.11.4.9.2.7.4 Operation Field
          3. 24.11.4.9.3 Programming Guide
            1. 24.11.4.9.3.1 Initialization Routine
            2. 24.11.4.9.3.2 Interrupt Service Routine
            3. 24.11.4.9.3.3 Rule Engine Example Program
        10. 24.11.4.10 Common Platform Time Sync (CPTS)
          1. 24.11.4.10.1 CPTS Architecture
          2. 24.11.4.10.2 CPTS Initialization
          3. 24.11.4.10.3 Time Stamp Value
          4. 24.11.4.10.4 Event FIFO
          5. 24.11.4.10.5 Time Sync Events
            1. 24.11.4.10.5.1 Time Stamp Push Event
            2. 24.11.4.10.5.2 Time Stamp Counter Rollover Event
            3. 24.11.4.10.5.3 Time Stamp Counter Half-rollover Event
            4. 24.11.4.10.5.4 Hardware Time Stamp Push Event
            5. 24.11.4.10.5.5 Ethernet Port Events
          6. 24.11.4.10.6 CPTS Interrupt Handling
        11. 24.11.4.11 CPPI Buffer Descriptors
          1. 24.11.4.11.1 TX Buffer Descriptors
            1. 24.11.4.11.1.1 CPPI TX Data Word 0
            2. 24.11.4.11.1.2 CPPI TX Data Word 1
            3. 24.11.4.11.1.3 CPPI TX Data Word 2
            4. 24.11.4.11.1.4 CPPI TX Data Word 3
          2. 24.11.4.11.2 RX Buffer Descriptors
            1. 24.11.4.11.2.1 CPPI RX Data Word 0
            2. 24.11.4.11.2.2 CPPI RX Data Word 1
            3. 24.11.4.11.2.3 CPPI RX Data Word 2
            4. 24.11.4.11.2.4 CPPI RX Data Word 3
        12. 24.11.4.12 MDIO
          1. 24.11.4.12.1 MDIO Frame Formats
          2. 24.11.4.12.2 MDIO Functional Description
      5. 24.11.5 GMAC_SW Programming Guide
        1. 24.11.5.1 Transmit Operation
        2. 24.11.5.2 Receive Operation
        3. 24.11.5.3 MDIO Software Interface
          1. 24.11.5.3.1 Initializing the MDIO Module
          2. 24.11.5.3.2 Writing Data To a PHY Register
          3. 24.11.5.3.3 Reading Data From a PHY Register
        4. 24.11.5.4 Initialization and Configuration of CPSW
      6. 24.11.6 GMAC_SW Register Manual
        1. 24.11.6.1  GMAC_SW Instance Summary
        2. 24.11.6.2  SS Registers
          1. 24.11.6.2.1 SS Register Summary
          2. 24.11.6.2.2 SS Register Description
        3. 24.11.6.3  PORT Registers
          1. 24.11.6.3.1 PORT Register Summary
          2. 24.11.6.3.2 PORT Register Description
        4. 24.11.6.4  CPDMA registers
          1. 24.11.6.4.1 CPDMA Register Summary
          2. 24.11.6.4.2 CPDMA Register Description
        5. 24.11.6.5  STATS Registers
          1. 24.11.6.5.1 STATS Register Summary
          2. 24.11.6.5.2 STATS Register Description
        6. 24.11.6.6  STATERAM Registers
          1. 24.11.6.6.1 STATERAM Register Summary
          2. 24.11.6.6.2 STATERAM Register Description
        7. 24.11.6.7  CPTS registers
          1. 24.11.6.7.1 CPTS Register Summary
          2. 24.11.6.7.2 CPTS Register Description
        8. 24.11.6.8  ALE registers
          1. 24.11.6.8.1 ALE Register Summary
          2. 24.11.6.8.2 ALE Register Description
        9. 24.11.6.9  SL registers
          1. 24.11.6.9.1 SL Register Summary
          2. 24.11.6.9.2 SL Register Description
        10. 24.11.6.10 MDIO registers
          1. 24.11.6.10.1 MDIO Register Summary
          2. 24.11.6.10.2 MDIO Register Description
        11. 24.11.6.11 WR registers
          1. 24.11.6.11.1 WR Register Summary
          2. 24.11.6.11.2 WR Register Description
        12. 24.11.6.12 SPF Registers
          1. 24.11.6.12.1 SPF Register Summary
          2. 24.11.6.12.2 SPF Register Description
    12. 24.12 Media Local Bus (MLB)
      1. 24.12.1 MLB Overview
      2. 24.12.2 MLB Environment
        1. 24.12.2.1 MLB IO Cell Controls
      3. 24.12.3 MLB Integration
      4. 24.12.4 MLB Functional Description
        1. 24.12.4.1 Block Diagram
          1. 24.12.4.1.1 MediaLB Core Block
          2. 24.12.4.1.2 Routing Fabric Block
          3. 24.12.4.1.3 Data Buffer RAM
          4. 24.12.4.1.4 Channel Table RAM
            1. 24.12.4.1.4.1 Channel Allocation Table
            2. 24.12.4.1.4.2 Channel Descriptor Table
          5. 24.12.4.1.5 DMA Block
            1. 24.12.4.1.5.1 Synchronous Channel Descriptor
            2. 24.12.4.1.5.2 Isochronous Channel Descriptors
            3. 24.12.4.1.5.3 Asynchronous and Control Channel Descriptors
              1. 24.12.4.1.5.3.1 Single-Packet Mode
              2. 24.12.4.1.5.3.2 Multiple-Packet Mode
        2. 24.12.4.2 Software and Data Flow for MLBSS
          1. 24.12.4.2.1 Data Flow For Receive Channels
          2. 24.12.4.2.2 Data Flow for Transmit Channels
        3. 24.12.4.3 MLB Priority On The L3_MAIN Interconnect
      5. 24.12.5 MLB Programming Guide
        1. 24.12.5.1 Global Initialization
          1. 24.12.5.1.1 Surrounding Modules Global Initialization
          2. 24.12.5.1.2 MLBSS Global Initialization
            1. 24.12.5.1.2.1 Channel Initialization
        2. 24.12.5.2 MLBSS Operational Modes Configuration
          1. 24.12.5.2.1 Channel Servicing
          2. 24.12.5.2.2 Channel Table RAM Access
      6. 24.12.6 MLB Register Manual
        1. 24.12.6.1 MLB Instance Summary
        2. 24.12.6.2 MLB registers
          1. 24.12.6.2.1 MLB Register Summary
          2. 24.12.6.2.2 MLB Register Description
  27. 25eMMC/SD/SDIO
    1. 25.1 eMMC/SD/SDIO Overview
      1. 25.1.1 eMMC/SD/SDIO Features
    2. 25.2 eMMC/SD/SDIO Environment
      1. 25.2.1 eMMC/SD/SDIO Functional Modes
        1. 25.2.1.1 eMMC/SD/SDIO Connected to an eMMC, SD, or SDIO Card
      2. 25.2.2 Protocol and Data Format
        1. 25.2.2.1 Protocol
        2. 25.2.2.2 Data Format
    3. 25.3 eMMC/SD/SDIO Integration
    4. 25.4 eMMC/SD/SDIO Functional Description
      1. 25.4.1  Block Diagram
      2. 25.4.2  Resets
        1. 25.4.2.1 Hardware Reset
        2. 25.4.2.2 Software Reset
      3. 25.4.3  Power Management
      4. 25.4.4  Interrupt Requests
        1. 25.4.4.1 Interrupt-Driven Operation
        2. 25.4.4.2 Polling
        3. 25.4.4.3 Asynchronous Interrupt
      5. 25.4.5  DMA Modes
        1. 25.4.5.1 Master DMA Operations
          1. 25.4.5.1.1 Descriptor Table Description
          2. 25.4.5.1.2 Requirements for Descriptors
            1. 25.4.5.1.2.1 Data Length
            2. 25.4.5.1.2.2 Supported Features
            3. 25.4.5.1.2.3 Error Generation
          3. 25.4.5.1.3 Advanced DMA Description
        2. 25.4.5.2 Slave DMA Operations
          1. 25.4.5.2.1 DMA Receive Mode
          2. 25.4.5.2.2 DMA Transmit Mode
      6. 25.4.6  Mode Selection
      7. 25.4.7  Buffer Management
        1. 25.4.7.1 Data Buffer
          1. 25.4.7.1.1 Memory Size, Block Length, and Buffer-Management Relationship
          2. 25.4.7.1.2 Data Buffer Status
      8. 25.4.8  Transfer Process
        1. 25.4.8.1 Different Types of Commands
        2. 25.4.8.2 Different Types of Responses
      9. 25.4.9  Transfer or Command Status and Errors Reporting
        1. 25.4.9.1 Busy Time-Out for R1b, R5b Response Type
        2. 25.4.9.2 Busy Time-Out After Write CRC Status
        3. 25.4.9.3 Write CRC Status Time-Out
        4. 25.4.9.4 Read Data Time-Out
        5. 25.4.9.5 Boot Acknowledge Time-Out
      10. 25.4.10 Auto Command 12 Timings
        1. 25.4.10.1 Auto CMD12 Timings During Write Transfer
        2. 25.4.10.2 Auto CMD12 Timings During Read Transfer
      11. 25.4.11 Transfer Stop
      12. 25.4.12 Output Signals Generation
        1. 25.4.12.1 Generation on Falling Edge of MMC Clock
        2. 25.4.12.2 Generation on Rising Edge of MMC Clock
      13. 25.4.13 Sampling Clock Tuning
      14. 25.4.14 Card Boot Mode Management
        1. 25.4.14.1 Boot Mode Using CMD0
        2. 25.4.14.2 Boot Mode With CMD Line Tied to 0
      15. 25.4.15 MMC CE-ATA Command Completion Disable Management
      16. 25.4.16 Test Registers
      17. 25.4.17 eMMC/SD/SDIO Hardware Status Features
    5. 25.5 eMMC/SD/SDIO Programming Guide
      1. 25.5.1 Low-Level Programming Models
        1. 25.5.1.1 Global Initialization
          1. 25.5.1.1.1 Surrounding Modules Global Initialization
          2. 25.5.1.1.2 eMMC/SD/SDIO Host Controller Initialization Flow
            1. 25.5.1.1.2.1 Enable Interface and Functional Clock for MMC Controller
            2. 25.5.1.1.2.2 MMCHS Soft Reset Flow
            3. 25.5.1.1.2.3 Set MMCHS Default Capabilities
            4. 25.5.1.1.2.4 Wake-Up Configuration
            5. 25.5.1.1.2.5 MMC Host and Bus Configuration
        2. 25.5.1.2 Operational Modes Configuration
          1. 25.5.1.2.1 Basic Operations for eMMC/SD/SDIO Host Controller
            1. 25.5.1.2.1.1 Card Detection, Identification, and Selection
              1. 25.5.1.2.1.1.1 CMD Line Reset Procedure
            2. 25.5.1.2.1.2 Read/Write Transfer Flow in DMA Mode With Interrupt
              1. 25.5.1.2.1.2.1 DATA Lines Reset Procedure
            3. 25.5.1.2.1.3 Read/Write Transfer Flow in DMA Mode With Polling
            4. 25.5.1.2.1.4 Read/Write Transfer Flow Without DMA With Polling
            5. 25.5.1.2.1.5 Read/Write Transfer Flow in CE-ATA Mode
            6. 25.5.1.2.1.6 Suspend-Resume Flow
              1. 25.5.1.2.1.6.1 Suspend Flow
              2. 25.5.1.2.1.6.2 Resume Flow
            7. 25.5.1.2.1.7 Basic Operations – Steps Detailed
              1. 25.5.1.2.1.7.1 Command Transfer Flow
              2. 25.5.1.2.1.7.2 MMCHS Clock Frequency Change
              3. 25.5.1.2.1.7.3 Bus Width Selection
          2. 25.5.1.2.2 Bus Voltage Selection
          3. 25.5.1.2.3 Boot Mode Configuration
            1. 25.5.1.2.3.1 Boot Using CMD0
            2. 25.5.1.2.3.2 Boot With CMD Line Tied to 0
          4. 25.5.1.2.4 SDR104/HS200 DLL Tuning Procedure
    6. 25.6 eMMC/SD/SDIO Register Manual
      1. 25.6.1 eMMC/SD/SDIO Instance Summary
      2. 25.6.2 eMMC/SD/SDIO Registers
        1. 25.6.2.1 eMMC/SD/SDIO Register Summary
        2. 25.6.2.2 eMMC/SD/SDIO Register Description
  28. 26Shared PHY Component Subsystem
    1. 26.1 SATA PHY Subsystem
      1. 26.1.1 SATA PHY Subsystem Overview
      2. 26.1.2 SATA PHY Subsystem Environment
        1. 26.1.2.1 SATA PHY I/O Signals
      3. 26.1.3 SATA PHY Subsystem Integration
      4. 26.1.4 SATA PHY Subsystem Functional Description
        1. 26.1.4.1 SATA PLL Controller L4 Interface Adapter Functional Description
        2. 26.1.4.2 SATA PHY Serializer and Deserializer Functional Descriptions
          1. 26.1.4.2.1 SATA PHY Reset
          2. 26.1.4.2.2 SATA_PHY Clocking
            1. 26.1.4.2.2.1 SATA_PHY Input Clocks
            2. 26.1.4.2.2.2 SATA_PHY Output Clocks
          3. 26.1.4.2.3 SATA_PHY Power Management
            1. 26.1.4.2.3.1 SATA_PHY Power-Up/-Down Sequences
            2. 26.1.4.2.3.2 SATA_PHY Low-Power Modes
          4. 26.1.4.2.4 SATA_PHY Hardware Requests
        3. 26.1.4.3 SATA Clock Generator Subsystem Functional Description
          1. 26.1.4.3.1 SATA DPLL Clock Generator Overview
          2. 26.1.4.3.2 SATA DPLL Clock Generator Reset
          3. 26.1.4.3.3 SATA DPLL Low-Power Modes
          4. 26.1.4.3.4 SATA DPLL Clocks Configuration
            1. 26.1.4.3.4.1 SATA DPLL Input Clock Control
            2. 26.1.4.3.4.2 SATA DPLL Output Clock Configuration
              1. 26.1.4.3.4.2.1 SATA DPLL Output Clock Gating
          5. 26.1.4.3.5 SATA DPLL Subsystem Architecture
          6. 26.1.4.3.6 SATA DPLL Clock Generator Modes and State Transitions
            1. 26.1.4.3.6.1 SATA Clock Generator Power Up
            2. 26.1.4.3.6.2 SATA DPLL Sequences
            3. 26.1.4.3.6.3 SATA DPLL Locked Mode
            4. 26.1.4.3.6.4 SATA DPLL Idle-Bypass Mode
            5. 26.1.4.3.6.5 SATA DPLL MN-Bypass Mode
            6. 26.1.4.3.6.6 SATA DPLL Error Conditions
          7. 26.1.4.3.7 SATA PLL Controller Functions
            1. 26.1.4.3.7.1 SATA PLL Controller Register Access
            2. 26.1.4.3.7.2 SATA DPLL Clock Programming Sequence
            3. 26.1.4.3.7.3 SATA DPLL Recommended Values
      5. 26.1.5 SATA PHY Subsystem Low-Level Programming Model
    2. 26.2 USB3_PHY Subsystem
      1. 26.2.1 USB3_PHY Subsystem Overview
      2. 26.2.2 USB3_PHY Subsystem Environment
        1. 26.2.2.1 USB3_PHY I/O Signals
      3. 26.2.3 USB3_PHY Subsystem Integration
      4. 26.2.4 USB3_PHY Subsystem Functional Description
        1. 26.2.4.1 Super-Speed USB PLL Controller L4 Interface Adapter Functional Description
        2. 26.2.4.2 USB3_PHY Serializer and Deserializer Functional Descriptions
          1. 26.2.4.2.1 USB3_PHY Module Resets
            1. 26.2.4.2.1.1 Hardware Reset
            2. 26.2.4.2.1.2 Software Reset
          2. 26.2.4.2.2 USB3_PHY Subsystem Clocking
            1. 26.2.4.2.2.1 USB3_PHY Subsystem Input Clocks
            2. 26.2.4.2.2.2 USB3_PHY Subsystem Output Clocks
          3. 26.2.4.2.3 USB3_PHY Power Management
            1. 26.2.4.2.3.1 USB3_PHY Power-Up/-Down Sequences
            2. 26.2.4.2.3.2 USB3_PHY Low-Power Modes
            3. 26.2.4.2.3.3 Clock Gating
          4. 26.2.4.2.4 USB3_PHY Hardware Requests
        3. 26.2.4.3 USB3_PHY Clock Generator Subsystem Functional Description
          1. 26.2.4.3.1 USB3_PHY DPLL Clock Generator Overview
          2. 26.2.4.3.2 USB3_PHY DPLL Clock Generator Reset
          3. 26.2.4.3.3 USB3_PHY DPLL Low-Power Modes
          4. 26.2.4.3.4 USB3_PHY DPLL Clocks Configuration
            1. 26.2.4.3.4.1 USB3_PHY DPLL Input Clock Control
            2. 26.2.4.3.4.2 USB3_PHY DPLL Output Clock Configuration
              1. 26.2.4.3.4.2.1 USB3_PHY DPLL Output Clock Gating
          5. 26.2.4.3.5 USB3_PHY DPLL Subsystem Architecture
          6. 26.2.4.3.6 USB3_PHY DPLL Clock Generator Modes and State Transitions
            1. 26.2.4.3.6.1 USB3_PHY Clock Generator Power Up
            2. 26.2.4.3.6.2 USB3_PHY DPLL Sequences
            3. 26.2.4.3.6.3 USB3_PHY DPLL Locked Mode
            4. 26.2.4.3.6.4 USB3_PHY DPLL Idle-Bypass Mode
            5. 26.2.4.3.6.5 USB3_PHY DPLL MN-Bypass Mode
            6. 26.2.4.3.6.6 USB3_PHY DPLL Error Conditions
          7. 26.2.4.3.7 USB3_PHY PLL Controller Functions
            1. 26.2.4.3.7.1 USB3_PHY PLL Controller Register Access
            2. 26.2.4.3.7.2 4331
            3. 26.2.4.3.7.3 USB3_PHY DPLL Clock Programming Sequence
            4. 26.2.4.3.7.4 USB3_PHY DPLL Recommended Values
      5. 26.2.5 USB3_PHY Subsystem Low-Level Programming Model
    3. 26.3 USB3 PHY and SATA PHY Register Manual
      1. 26.3.1 USB3 PHY and SATA PHY Instance Summary
      2. 26.3.2 USB3_PHY_RX Registers
        1. 26.3.2.1 USB3_PHY_RX Register Summary
        2. 26.3.2.2 USB3_PHY_RX Register Description
      3. 26.3.3 USB3_PHY_TX Registers
        1. 26.3.3.1 USB3_PHY_TX Register Summary
        2. 26.3.3.2 USB3_PHY_TX Register Description
      4. 26.3.4 SATA_PHY_RX Registers
        1. 26.3.4.1 SATA_PHY_RX Register Summary
        2. 26.3.4.2 SATA_PHY_RX Register Description
      5. 26.3.5 SATA_PHY_TX Registers
        1. 26.3.5.1 SATA_PHY_TX Register Summary
        2. 26.3.5.2 SATA_PHY_TX Register Description
      6. 26.3.6 DPLLCTRL Registers
        1. 26.3.6.1 DPLLCTRL Register Summary
        2. 26.3.6.2 DPLLCTRL Register Description
    4. 26.4 PCIe PHY Subsystem
      1. 26.4.1 PCIe PHY Subsystem Overview
        1. 26.4.1.1 PCIe PHY Subsystem Key Features
      2. 26.4.2 PCIe PHY Subsystem Environment
        1. 26.4.2.1 PCIe PHY I/O Signals
      3. 26.4.3 PCIe Shared PHY Subsystem Integration
      4. 26.4.4 PCIe PHY Subsystem Functional Description
        1. 26.4.4.1 PCIe PHY Subsystem Block Diagram
        2. 26.4.4.2 OCP2SCP Functional Description
          1. 26.4.4.2.1 OCP2SCP Reset
            1. 26.4.4.2.1.1 Hardware Reset
            2. 26.4.4.2.1.2 Software Reset
          2. 26.4.4.2.2 OCP2SCP Power Management
            1. 26.4.4.2.2.1 Idle Mode
            2. 26.4.4.2.2.2 Clock Gating
          3. 26.4.4.2.3 OCP2SCP Timing Registers
        3. 26.4.4.3 PCIe PHY Serializer and Deserializer Functional Descriptions
          1. 26.4.4.3.1 PCIe PHY Module Resets
            1. 26.4.4.3.1.1 Hardware Reset
            2. 26.4.4.3.1.2 Software Reset
          2. 26.4.4.3.2 PCIe PHY Subsystem Clocking
            1. 26.4.4.3.2.1 PCIe PHY Subsystem Input Clocks
            2. 26.4.4.3.2.2 PCIe PHY Subsystem Output Clocks
          3. 26.4.4.3.3 PCIe PHY Power Management
            1. 26.4.4.3.3.1 PCIe PHY Power-Up/-Down Sequences
            2. 26.4.4.3.3.2 PCIe PHY Low-Power Modes
            3. 26.4.4.3.3.3 Clock Gating
          4. 26.4.4.3.4 PCIe PHY Hardware Requests
        4. 26.4.4.4 PCIe PHY Clock Generator Subsystem Functional Description
          1. 26.4.4.4.1 PCIe PHY DPLL Clock Generator
            1. 26.4.4.4.1.1 PCIe PHY DPLL Clock Generator Overview
            2. 26.4.4.4.1.2 PCIe PHY DPLL Clock Generator Reset
            3. 26.4.4.4.1.3 PCIe PHY DPLL Low-Power Modes
            4. 26.4.4.4.1.4 PCIe PHY DPLL Clocks Configuration
              1. 26.4.4.4.1.4.1 PCIe PHY DPLL Input Clock Control
              2. 26.4.4.4.1.4.2 PCIe PHY DPLL Output Clock Configuration
                1. 26.4.4.4.1.4.2.1 PCIe PHY DPLL Output Clock Gating
            5. 26.4.4.4.1.5 PCIe PHY DPLL Subsystem Architecture
            6. 26.4.4.4.1.6 PCIe PHY DPLL Clock Generator Modes and State Transitions
              1. 26.4.4.4.1.6.1 PCIe PHY Clock Generator Power Up
              2. 26.4.4.4.1.6.2 PCIe PHY DPLL Sequences
              3. 26.4.4.4.1.6.3 PCIe PHY DPLL Locked Mode
              4. 26.4.4.4.1.6.4 PCIe PHY DPLL Idle-Bypass Mode
              5. 26.4.4.4.1.6.5 PCIe PHY DPLL Low Power Stop Mode
              6. 26.4.4.4.1.6.6 PCIe PHY DPLL Clock Programming Sequence
              7. 26.4.4.4.1.6.7 PCIe PHY DPLL Recommended Values
          2. 26.4.4.4.2 PCIe PHY APLL Clock Generator
            1. 26.4.4.4.2.1 PCIe PHY APLL Clock Generator Overview
            2. 26.4.4.4.2.2 PCIe PHY APLL Clock Generator Reset
            3. 26.4.4.4.2.3 PCIe PHY APLL Low-Power Mode
            4. 26.4.4.4.2.4 PCIe PHY APLL Clocks Configuration
              1. 26.4.4.4.2.4.1 PCIe PHY APLL Input Clock Control
              2. 26.4.4.4.2.4.2 PCIe PHY APLL Output Clock Configuration
                1. 26.4.4.4.2.4.2.1 PCIe PHY APLL Output Clock Gating
            5. 26.4.4.4.2.5 PCIe PHY APLL Subsystem Architecture
            6. 26.4.4.4.2.6 PCIe PHY APLL Clock Generator Modes and State Transitions
              1. 26.4.4.4.2.6.1 PCIe PHY APLL Clock Generator Power Up
              2. 26.4.4.4.2.6.2 PCIe PHY APLL Sequences
              3. 26.4.4.4.2.6.3 PCIe PHY APLL Locked Mode
          3. 26.4.4.4.3 ACSPCIE reference clock buffer
      5. 26.4.5 PCIePHY Subsystem Low-Level Programming Model
      6. 26.4.6 PCIe PHY Subsystem Register Manual
        1. 26.4.6.1 PCIe PHY Instance Summary
          1. 26.4.6.1.1 PCIe_PHY_RX Registers
            1. 26.4.6.1.1.1 PCIe_PHY_RX Register Summary
            2. 26.4.6.1.1.2 PCIe_PHY_RX Register Description
          2. 26.4.6.1.2 PCIe_PHY_TX Registers
            1. 26.4.6.1.2.1 PCIe_PHY_TX Register Summary
            2. 26.4.6.1.2.2 PCIe_PHY_TX Register Description
          3. 26.4.6.1.3 OCP2SCP Registers
            1. 26.4.6.1.3.1 OCP2SCP Register Summary
            2. 26.4.6.1.3.2 OCP2SCP Register Description
  29. 27General-Purpose Interface
    1. 27.1 General-Purpose Interface Overview
    2. 27.2 General-Purpose Interface Environment
      1. 27.2.1 General-Purpose Interface as a Keyboard Interface
      2. 27.2.2 General-Purpose Interface Signals
    3. 27.3 General-Purpose Interface Integration
    4. 27.4 General-Purpose Interface Functional Description
      1. 27.4.1 General-Purpose Interface Block Diagram
      2. 27.4.2 General-Purpose Interface Interrupt and Wake-Up Features
        1. 27.4.2.1 Synchronous Path: Interrupt Request Generation
        2. 27.4.2.2 Asynchronous Path: Wake-Up Request Generation
        3. 27.4.2.3 Wake-Up Event Conditions During Transition To/From IDLE State
        4. 27.4.2.4 Interrupt (or Wake-Up) Line Release
      3. 27.4.3 General-Purpose Interface Clock Configuration
        1. 27.4.3.1 Clocking
      4. 27.4.4 General-Purpose Interface Hardware and Software Reset
      5. 27.4.5 General-Purpose Interface Power Management
        1. 27.4.5.1 Power Domain
        2. 27.4.5.2 Power Management
          1. 27.4.5.2.1 Idle Scheme
          2. 27.4.5.2.2 Operating Modes
          3. 27.4.5.2.3 System Power Management and Wakeup
          4. 27.4.5.2.4 Module Power Saving
      6. 27.4.6 General-Purpose Interface Interrupt and Wake-Up Requests
        1. 27.4.6.1 Interrupt Requests Generation
        2. 27.4.6.2 Wake-Up Requests Generation
      7. 27.4.7 General-Purpose Interface Channels Description
      8. 27.4.8 General-Purpose Interface Data Input/Output Capabilities
      9. 27.4.9 General-Purpose Interface Set-and-Clear Protocol
        1. 27.4.9.1 Description
        2. 27.4.9.2 Clear Instruction
          1. 27.4.9.2.1 Clear Register Addresses
          2. 27.4.9.2.2 Clear Instruction Example
        3. 27.4.9.3 Set Instruction
          1. 27.4.9.3.1 Set Register Addresses
          2. 27.4.9.3.2 Set Instruction Example
    5. 27.5 General-Purpose Interface Programming Guide
      1. 27.5.1 General-Purpose Interface Low-Level Programming Models
        1. 27.5.1.1 Global Initialization
          1. 27.5.1.1.1 Surrounding Modules Global Initialization
          2. 27.5.1.1.2 General-Purpose Interface Module Global Initialization
        2. 27.5.1.2 General-Purpose Interface Operational Modes Configuration
          1. 27.5.1.2.1 General-Purpose Interface Read Input Register
          2. 27.5.1.2.2 General-Purpose Interface Set Bit Function
          3. 27.5.1.2.3 General-Purpose Interface Clear Bit Function
    6. 27.6 General-Purpose Interface Register Manual
      1. 27.6.1 General-Purpose Interface Instance Summary
      2. 27.6.2 General-Purpose Interface Registers
        1. 27.6.2.1 General-Purpose Interface Register Summary
        2. 27.6.2.2 General-Purpose Interface Register Description
  30. 28Keyboard Controller
    1. 28.1 Keyboard Controller Overview
    2. 28.2 Keyboard Controller Environment
      1. 28.2.1 Keyboard Controller Functions/Modes
      2. 28.2.2 Keyboard Controller Signals
      3. 28.2.3 Protocols and Data Formats
    3. 28.3 Keyboard Controller Integration
    4. 28.4 Keyboard Controller Functional Description
      1. 28.4.1 Keyboard Controller Block Diagram
      2. 28.4.2 Keyboard Controller Software Reset
      3. 28.4.3 Keyboard Controller Power Management
      4. 28.4.4 Keyboard Controller Interrupt Requests
      5. 28.4.5 Keyboard Controller Software Mode
      6. 28.4.6 Keyboard Controller Hardware Decoding Modes
        1. 28.4.6.1 Functional Modes
        2. 28.4.6.2 Keyboard Controller Timer
        3. 28.4.6.3 State-Machine Status
        4. 28.4.6.4 Keyboard Controller Interrupt Generation
          1. 28.4.6.4.1 Interrupt-Generation Scheme
          2. 28.4.6.4.2 Keyboard Buffer and Missed Events (Overrun Feature)
      7. 28.4.7 Keyboard Controller Key Coding Registers
      8. 28.4.8 Keyboard Controller Register Access
        1. 28.4.8.1 Write Registers Access
        2. 28.4.8.2 Read Registers Access
    5. 28.5 Keyboard Controller Programming Guide
      1. 28.5.1 Keyboard Controller Low-Level Programming Models
        1. 28.5.1.1 Global Initialization
          1. 28.5.1.1.1 Surrounding Modules Global Initialization
          2. 28.5.1.1.2 Keyboard Controller Global Initialization
            1. 28.5.1.1.2.1 Main Sequence – Keyboard Controller Global Initialization
        2. 28.5.1.2 Operational Modes Configuration
          1. 28.5.1.2.1 Keyboard Controller in Hardware Decoding Mode (Default Mode)
            1. 28.5.1.2.1.1 Main Sequence – Keyboard Controller Hardware Mode
          2. 28.5.1.2.2 Keyboard Controller Software Scanning Mode
            1. 28.5.1.2.2.1 Main Sequence – Keyboard Controller Software Mode
          3. 28.5.1.2.3 Using the Timer
          4. 28.5.1.2.4 State-Machine Status Register
        3. 28.5.1.3 Keyboard Controller Events Servicing
    6. 28.6 Keyboard Controller Register Manual
      1. 28.6.1 Keyboard Controller Instance Summary
      2. 28.6.2 Keyboard Controller Registers
        1. 28.6.2.1 Keyboard Controller Register Summary
        2. 28.6.2.2 Keyboard Controller Register Description
  31. 29Pulse-Width Modulation Subsystem
    1. 29.1 PWM Subsystem Resources
      1. 29.1.1 PWMSS Overview
        1. 29.1.1.1 PWMSS Key Features
        2. 29.1.1.2 PWMSS Unsupported Fetaures
      2. 29.1.2 PWMSS Environment
        1. 29.1.2.1 PWMSS I/O Interface
      3. 29.1.3 PWMSS Integration
        1. 29.1.3.1 PWMSS Module Interfaces Implementation
          1. 29.1.3.1.1 Device Specific PWMSS Features
          2. 29.1.3.1.2 Daisy-Chain Connectivity between PWMSS Modules
          3. 29.1.3.1.3 eHRPWM Modules Time Base Clock Gating
      4. 29.1.4 PWMSS Subsystem Power, Reset and Clock Configuration
        1. 29.1.4.1 PWMSS Local Clock Management
        2. 29.1.4.2 PWMSS Modules Local Clock Gating
        3. 29.1.4.3 PWMSS Software Reset
      5. 29.1.5 PWMSS_CFG Register Manual
        1. 29.1.5.1 PWMSS_CFG Instance Summary
        2. 29.1.5.2 PWMSS_CFG Registers
          1. 29.1.5.2.1 PWMSS_CFG Register Summary
          2. 29.1.5.2.2 PWMSS_CFG Register Description
    2. 29.2 Enhanced PWM (ePWM) Module
    3. 29.3 Enhanced Capture (eCAP) Module
    4. 29.4 Enhanced Quadrature Encoder Pulse (eQEP) Module
  32. 30Viterbi-Decoder Coprocessor
    1. 30.1 VCP Overview
      1. 30.1.1 VCP Features
    2. 30.2 VCP Integration
    3. 30.3 VCP Functional Description
      1. 30.3.1  VCP Block Diagram
      2. 30.3.2  VCP Internal Interfaces
        1. 30.3.2.1 VCP Power Management
          1. 30.3.2.1.1 Idle Mode
        2. 30.3.2.2 VCP Clocks
        3. 30.3.2.3 VCP Resets
        4. 30.3.2.4 Interrupt Requests
        5. 30.3.2.5 EDMA Requests
      3. 30.3.3  Functional Overview
        1. 30.3.3.1 Theoretical Basics of the Convolutional Code.
        2. 30.3.3.2 4556
      4. 30.3.4  VCP Architecture
        1. 30.3.4.1 Sliding Windows Processing
          1. 30.3.4.1.1 Tailed Traceback Mode
          2. 30.3.4.1.2 Mixed Traceback Mode
          3. 30.3.4.1.3 Convergent Traceback Mode
          4. 30.3.4.1.4 F, R, and C Limitations
          5. 30.3.4.1.5 Yamamoto Parameters
          6. 30.3.4.1.6 Input FIFO (Branch Metrics)
          7. 30.3.4.1.7 Output FIFO (Decisions)
      5. 30.3.5  VCP Input Data
        1. 30.3.5.1 Branch Metrics Calculations
      6. 30.3.6  Soft Input Dynamic Ranges
      7. 30.3.7  VCP Memory Sleep Mode
      8. 30.3.8  Decision Data
      9. 30.3.9  Endianness
        1. 30.3.9.1 Branch Metrics
          1. 30.3.9.1.1 Hard Decisions
          2. 30.3.9.1.2 Soft Decisions
      10. 30.3.10 VCP Output Parameters
      11. 30.3.11 Event Generation
        1. 30.3.11.1 VCPnXEVT Generation
        2. 30.3.11.2 VCPnREVT Generation
      12. 30.3.12 Operational Modes
        1. 30.3.12.1 Debugging Features
      13. 30.3.13 Errors and Status
    4. 30.4 VCP Modules Programming Guide
      1. 30.4.1 EDMA Resources
        1. 30.4.1.1 VCP1 and VCP2 Dedicated EDMA Resources
        2. 30.4.1.2 Special VCP EDMA Programming Considerations
          1. 30.4.1.2.1 Input Configuration Parameters Transfer
          2. 30.4.1.2.2 Branch Metrics Transfer
          3. 30.4.1.2.3 Decisions Transfer
          4. 30.4.1.2.4 Hard-Decisions Mode
          5. 30.4.1.2.5 Soft-Decisions Mode
          6. 30.4.1.2.6 Output Parameters Transfer
      2. 30.4.2 Input Configuration Words
    5. 30.5 VCP Register Manual
      1. 30.5.1 VCP1 and VCP2 Instance Summary
      2. 30.5.2 VCP Registers
        1. 30.5.2.1 VCP Register Summary
        2. 30.5.2.2 VCP1 and VCP2 Data Registers Description
        3. 30.5.2.3 VCP1 and VCP2 Configuration Registers Description
  33. 31Audio Tracking Logic
    1. 31.1 ATL Overview
    2. 31.2 ATL Environment
      1. 31.2.1 ATL Functions
      2. 31.2.2 ATL Signals Descriptions
    3. 31.3 ATL Integration
      1. 31.3.1 ATL Distribution on Interconnects
      2. 31.3.2 ATL Regions Allocations
    4. 31.4 ATL Functional Description
      1. 31.4.1 Block Diagram
      2. 31.4.2 Source Signal Control
      3. 31.4.3 ATL Clock and Reset Configuration
    5. 31.5 ATL Register Manual
      1. 31.5.1 ATL Instance Summary
      2. 31.5.2 ATL Register Summary
      3. 31.5.3 ATL Register Description
  34. 32Initialization
    1. 32.1 Initialization Overview
      1. 32.1.1 Terminology
      2. 32.1.2 Initialization Process
    2. 32.2 Preinitialization
      1. 32.2.1 Power Requirements
      2. 32.2.2 Interaction With the PMIC Companion
      3. 32.2.3 Clock, Reset, and Control
        1. 32.2.3.1 Overview
        2. 32.2.3.2 Clocking Scheme
        3. 32.2.3.3 Reset Configuration
          1. 32.2.3.3.1 ON/OFF Interconnect and Power-On-Reset
          2. 32.2.3.3.2 Warm Reset
          3. 32.2.3.3.3 Peripheral Reset by GPIO
          4. 32.2.3.3.4 Warm Reset Impact on GPIOs
        4. 32.2.3.4 PMIC Control
        5. 32.2.3.5 PMIC Request Signals
      4. 32.2.4 Sysboot Configuration
        1. 32.2.4.1 GPMC Configuration for XIP/NAND
        2. 32.2.4.2 System Clock Speed Selection
        3. 32.2.4.3 QSPI Redundant SBL Images Offset
        4. 32.2.4.4 Booting Device Order Selection
        5. 32.2.4.5 4637
        6. 32.2.4.6 Boot Peripheral Pin Multiplexing
    3. 32.3 Device Initialization by ROM Code
      1. 32.3.1 Booting Overview
        1. 32.3.1.1 Booting Types
        2. 32.3.1.2 ROM Code Architecture
      2. 32.3.2 Memory Maps
        1. 32.3.2.1 ROM Memory Map
        2. 32.3.2.2 RAM Memory Map
      3. 32.3.3 Overall Booting Sequence
      4. 32.3.4 Startup and Configuration
        1. 32.3.4.1 Startup
        2. 32.3.4.2 Control Module Configuration
        3. 32.3.4.3 PRCM Module Mode Configuration
        4. 32.3.4.4 Clocking Configuration
        5. 32.3.4.5 Booting Device List Setup
      5. 32.3.5 Peripheral Booting
        1. 32.3.5.1 Description
        2. 32.3.5.2 Initialization Phase for UART Boot
        3. 32.3.5.3 Initialization Phase for USB Boot
          1. 32.3.5.3.1 Initialization Procedure
          2. 32.3.5.3.2 SATA Peripheral Device Flashing over USB Interface
          3. 32.3.5.3.3 USB Driver Descriptors
          4. 32.3.5.3.4 4660
          5. 32.3.5.3.5 USB Customized Vendor and Product IDs
          6. 32.3.5.3.6 USB Driver Functionality
      6. 32.3.6 Fast External Booting
        1. 32.3.6.1 Overview
        2. 32.3.6.2 Fast External Booting Procedure
      7. 32.3.7 Memory Booting
        1. 32.3.7.1 Overview
        2. 32.3.7.2 Non-XIP Memory
        3. 32.3.7.3 XIP Memory
          1. 32.3.7.3.1 GPMC Initialization
        4. 32.3.7.4 NAND
          1. 32.3.7.4.1 Initialization and NAND Detection
          2. 32.3.7.4.2 NAND Read Sector Procedure
        5. 32.3.7.5 SPI/QSPI Flash Devices
        6. 32.3.7.6 eMMC Memories and SD Cards
          1. 32.3.7.6.1 eMMC Memories
            1. 32.3.7.6.1.1 System Conditions and Limitations
            2. 32.3.7.6.1.2 eMMC Memory Connection
          2. 32.3.7.6.2 SD Cards
            1. 32.3.7.6.2.1 System Conditions and Limitations
            2. 32.3.7.6.2.2 SD Card Connection
            3. 32.3.7.6.2.3 Booting Procedure
            4. 32.3.7.6.2.4 eMMC Partitions Handling in Alternative Boot Operation Mode
              1. 32.3.7.6.2.4.1 eMMC Devices Preflashing
              2. 32.3.7.6.2.4.2 eMMC Device State After ROM Code Execution
              3. 32.3.7.6.2.4.3 Consideration on device Global Warm Reset
              4. 32.3.7.6.2.4.4 Booting Image Size
              5. 32.3.7.6.2.4.5 Booting Image Layout
          3. 32.3.7.6.3 Initialization and Detection
          4. 32.3.7.6.4 Read Sector Procedure
          5. 32.3.7.6.5 File System Handling
            1. 32.3.7.6.5.1 MBR and FAT File System
        7. 32.3.7.7 SATA Device Boot Operation
          1. 32.3.7.7.1 SATA Booting Overview
          2. 32.3.7.7.2 SATA Power-Up Initialization Sequence
          3. 32.3.7.7.3 System Conditions and Limitations for SATA Boot
          4. 32.3.7.7.4 SATA Read Sector Procedure in FAT Mode
      8. 32.3.8 Image Format
        1. 32.3.8.1 Overview
        2. 32.3.8.2 Configuration Header
          1. 32.3.8.2.1 CHSETTINGS Item
          2. 32.3.8.2.2 CHFLASH Item
          3. 32.3.8.2.3 CHMMCSD Item
          4. 32.3.8.2.4 CHQSPI Item
        3. 32.3.8.3 GP Header
        4. 32.3.8.4 Image Execution
      9. 32.3.9 Tracing
    4. 32.4 Services for HLOS Support
      1. 32.4.1 Hypervisor
      2. 32.4.2 Caches Maintenance
      3. 32.4.3 CP15 Registers
      4. 32.4.4 Wakeup Generator
      5. 32.4.5 Arm Timer
  35. 33On-Chip Debug Support
    1. 33.1  Introduction
      1. 33.1.1 Key Features
    2. 33.2  Debug Interfaces
      1. 33.2.1 IEEE1149.1
      2. 33.2.2 Debug (Trace) Port
      3. 33.2.3 Trace Connector and Board Layout Considerations
    3. 33.3  Debugger Connection
      1. 33.3.1 ICEPick Module
      2. 33.3.2 ICEPick Boot Modes
        1. 33.3.2.1 Default Boot Mode
        2. 33.3.2.2 Wait-In-Reset
      3. 33.3.3 Dynamic TAP Insertion
        1. 33.3.3.1 ICEPick Secondary TAPs
    4. 33.4  Primary Debug Support
      1. 33.4.1 Processor Native Debug Support
        1. 33.4.1.1 Cortex-A15 Processor
        2. 33.4.1.2 Cortex-M4 Processor
        3. 33.4.1.3 DSP C66x
        4. 33.4.1.4 IVA Arm968
        5. 33.4.1.5 ARP32
        6. 33.4.1.6 4735
      2. 33.4.2 Cross-Triggering
        1. 33.4.2.1 SoC-Level Cross-Triggering
        2. 33.4.2.2 Cross-Triggering With External Device
      3. 33.4.3 Suspend
        1. 33.4.3.1 Debug Aware Peripherals and Host Processors
    5. 33.5  Real-Time Debug
      1. 33.5.1 Real-Time Debug Events
        1. 33.5.1.1 Emulation Interrupts
    6. 33.6  Power, Reset, and Clock Management Debug Support
      1. 33.6.1 Power and Clock Management
        1. 33.6.1.1 Power and Clock Control Override From Debugger
          1. 33.6.1.1.1 Debugger Directives
            1. 33.6.1.1.1.1 FORCEACTIVE Debugger Directive
            2. 33.6.1.1.1.2 INHIBITSLEEP Debugger Directive
          2. 33.6.1.1.2 Intrusive Debug Model
        2. 33.6.1.2 Debug Across Power Transition
          1. 33.6.1.2.1 Nonintrusive Debug Model
          2. 33.6.1.2.2 Debug Context Save and Restore
            1. 33.6.1.2.2.1 Debug Context Save
            2. 33.6.1.2.2.2 Debug Context Restore
      2. 33.6.2 Reset Management
        1. 33.6.2.1 Debugger Directives
          1. 33.6.2.1.1 Assert Reset
          2. 33.6.2.1.2 Block Reset
          3. 33.6.2.1.3 Wait-In-Reset
    7. 33.7  Performance Monitoring
      1. 33.7.1 MPU Subsystem Performance Monitoring
        1. 33.7.1.1 Performance Monitoring Unit
        2. 33.7.1.2 L2 Cache Controller
      2. 33.7.2 IPU Subsystem Performance Monitoring
        1. 33.7.2.1 Subsystem Counter Timer Module
        2. 33.7.2.2 Cache Events
      3. 33.7.3 DSP Subsystem Performance Monitoring
        1. 33.7.3.1 Advanced Event Triggering
      4. 33.7.4 EVE Subsystem Performance Monitoring
        1. 33.7.4.1 EVE Subsystem Counter Timer Module
        2. 33.7.4.2 EVE Subsystem SCTM Events
    8. 33.8  MPU Memory Adaptor (MPU_MA) Watchpoint
    9. 33.9  Processor Trace
      1. 33.9.1 Cortex-A15 Processor Trace
      2. 33.9.2 DSP Processor Trace
      3. 33.9.3 Trace Export
        1. 33.9.3.1 Trace Exported to External Trace Receiver
        2. 33.9.3.2 Trace Captured Into On-Chip Trace Buffer
        3. 33.9.3.3 Trace Exported Through USB
    10. 33.10 System Instrumentation
      1. 33.10.1  MIPI STM (CT_STM)
      2. 33.10.2  System Trace Export
        1. 33.10.2.1 CT_STM ATB Export
        2. 33.10.2.2 Trace Streams Interleaving
      3. 33.10.3  Software Instrumentation
        1. 33.10.3.1 MPU Software Instrumentation
        2. 33.10.3.2 SoC Software Instrumentation
      4. 33.10.4  OCP Watchpoint
        1. 33.10.4.1 OCP Target Traffic Monitoring
        2. 33.10.4.2 Messages Triggered from System Events
        3. 33.10.4.3 DMA Transfer Profiling
      5. 33.10.5  IVA Pipeline
      6. 33.10.6  EVE SMSET
      7. 33.10.7  L3 NOC Statistics Collector
        1. 33.10.7.1 L3 Target Load Monitoring
        2. 33.10.7.2 L3 Master Latency Monitoring
          1. 33.10.7.2.1  SC_LAT0 Configuration
          2. 33.10.7.2.2  SC_LAT1 Configuration
          3. 33.10.7.2.3  SC_LAT2 Configuration
          4. 33.10.7.2.4  SC_LAT3 Configuration
          5. 33.10.7.2.5  SC_LAT4 Configuration
          6. 33.10.7.2.6  SC_LAT5 Configuration
          7. 33.10.7.2.7  SC_LAT6 Configuration
          8. 33.10.7.2.8  SC_LAT7 Configuration
          9. 33.10.7.2.9  SC_LAT8 Configuration
          10. 33.10.7.2.10 Statistics Collector Alarm Mode
          11. 33.10.7.2.11 Statistics Collector Suspend Mode
      8. 33.10.8  PM Instrumentation
      9. 33.10.9  CM Instrumentation
      10. 33.10.10 Master-ID Encoding
        1. 33.10.10.1 Software Masters
        2. 33.10.10.2 Hardware Masters
    11. 33.11 Concurrent Debug Modes
    12. 33.12 DRM Register Manual
      1. 33.12.1 DRM Instance Summary
      2. 33.12.2 DRM Registers
        1. 33.12.2.1 DRM Register Summary
        2. 33.12.2.2 DRM Register Description
  36. 34Glossary
  37. 35Revision History
UART/IrDA/CIR Register Description
Table 24-143 UART_THR
Address Offset0x0000 0000
Physical Address0x4806 A000
0x4806 C000
0x4802 0000
0x4806 E000
0x4806 6000
0x4806 8000
0x4842 0000
0x4842 2000
0x4842 4000
0x4AE2 B000
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionThe transmitter section consists of the transmit holding register (THR) and the transmit shift register. The THR is a 64-byte FIFO. The local host (LH) writes data to the THR. The data is placed in the transmit shift register where it is shifted out serially on the TX output. If the FIFO is disabled, location 0 of the FIFO stores the data.
TypeW
313029282726252423222120191817161514131211109876543210
RESERVEDTHR
BitsField NameDescriptionTypeReset
31:8RESERVEDWrite has no effect.W0x000000
7:0THRTransmit holding registerW0x-
Table 24-144 UART_RHR
Address Offset0x0000 0000
Physical Address0x4806 A000
0x4806 C000
0x4802 0000
0x4806 E000
0x4806 6000
0x4806 8000
0x4842 0000
0x4842 2000
0x4842 4000
0x4AE2 B000
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionThe receiver section consists of the receiver holding register (RHR) and the receiver shift register. The RHR is a 64-byte FIFO. The receiver shift register receives serial data from RX input. The data is converted to parallel data and moved to the RHR. If the FIFO is disabled, location 0 of the FIFO stores the single data character. Note: If an overflow occurs, the data in the RHR is not overwritten.
TypeR
313029282726252423222120191817161514131211109876543210
RESERVEDRHR
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0R0x000000
7:0RHRReceive holding registerR0x-
Table 24-145 UART_DLL
Address Offset0x0000 0000
Physical Address0x4806 A000
0x4806 C000
0x4802 0000
0x4806 E000
0x4806 6000
0x4806 8000
0x4842 0000
0x4842 2000
0x4842 4000
0x4AE2 B000
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionThis register, with UART_DLH, stores the 14-bit divisor for generation of the baud clock in the baud rate generator. DLH stores the most-significant part of the divisor. DLL stores the least-significant part of the divisor.
TypeRW
313029282726252423222120191817161514131211109876543210
RESERVEDCLOCK_LSB
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0. Write has no effect.RW0x000000
7:0CLOCK_LSBStores the 8-bit LSB divisor valueRW0x00
Table 24-146 UART_IER
Address Offset0x0000 0004
Physical Address0x4806 A004
0x4806 C004
0x4802 0004
0x4806 E004
0x4806 6004
0x4806 8004
0x4842 0004
0x4842 2004
0x4842 4004
0x4AE2 B004
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionInterrupt enable register
TypeRW
313029282726252423222120191817161514131211109876543210
RESERVEDCTS_ITRTS_ITXOFF_ITSLEEP_MODEMODEM_STS_ITLINE_STS_ITTHR_ITRHR_IT
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0. Write has no effect.RW0x000000
7CTS_ITRW0
0x0: Disables the CTS* interrupt
0x1: Enables the CTS* interrupt
6RTS_ITRW0
0x0: Disables the RTS* interrupt
0x1: Enables the RTS* interrupt
5XOFF_ITRW0
0x0: Disables the XOFF interrupt
0x1: Enables the XOFF interrupt
4SLEEP_MODERW0
0x0: Disables sleep mode
0x1: Enables sleep mode (stop baud rate clock when the module is inactive)
3MODEM_STS_ITRW0
0x0: Disables the modem status register interrupt
0x1: Enables the modem status register interrupt
2LINE_STS_ITRW0
0x0: Disables the receiver line status interrupt
0x1: Enables the receiver line status interrupt
1THR_ITRW0
0x0: Disables the THR interrupt
0x1: Enables the THR interrupt
0RHR_ITRW0
0x0: Disables the RHR interrupt and time-out interrupt
0x1: Enables the RHR interrupt and time-out interrupt
Table 24-147 UART_IER_IRDA
Address Offset0x0000 0004
Physical Address0x4806 A004
0x4806 C004
0x4802 0004
0x4806 E004
0x4806 6004
0x4806 8004
0x4842 0004
0x4842 2004
0x4842 4004
0x4AE2 B004
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionThere are 8 types of interrupt in these modes, received EOF, LSR interrupt, TX status, status FIFO interrupt, RX overrun, last byte in RX FIFO, THR interrupt and RHR interrupt and they can be enabled/disabled individually.
Note: The TX_STATUS_IT interrupt reflects two possible conditions. The UART_MDR2[0] should be read to determine the status in the event of this interrupt.
TypeRW
313029282726252423222120191817161514131211109876543210
RESERVEDEOF_ITLINE_STS_ITTX_STATUS_ITSTS_FIFO_TRIG_ITRX_OVERRUN_ITLAST_RX_BYTE_ITTHR_ITRHR_IT
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0. Write has no effect.RW0x000000
7EOF_ITRW0
0x0: Disables the received EOF interrupt
0x1: Enables the received EOF interrupt
6LINE_STS_ITRW0
0x0: Disables the receiver line status interrupt
0x1: Enables the receiver line status interrupt
5TX_STATUS_ITRW0
0x0: Disables the TX status interrupt
0x1: Enables the TX status interrupt
4STS_FIFO_TRIG_ITRW0
0x0: Disables status FIFO trigger level interrupt
0x1: Enables status FIFO trigger level interrupt
3RX_OVERRUN_ITRW0
0x0: Disables the RX overrun interrupt
0x1: Enables the RX overrun interrupt
2LAST_RX_BYTE_ITRW0
0x0: Disables the last byte of frame in RX FIFO interrupt
0x1: Enables the last byte of frame in RX FIFO interrupt
1THR_ITRW0
0x0: Disables the THR interrupt
0x1: Enables the THR interrupt
0RHR_ITRW0
0x0: Disables the RHR interrupt and time-out interrupt
0x1: Enables the RHR interrupt and time-out interrupt
Table 24-148 UART_IER_CIR
Address Offset0x0000 0004
Physical Address0x4806 A004
0x4806 C004
0x4802 0004
0x4806 E004
0x4806 6004
0x4806 8004
0x4842 0004
0x4842 2004
0x4842 4004
0x4AE2 B004
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionThere are 6 types of interrupt in these modes, TX status, status FIFO interrupt, RX overrun, last byte in RX FIFO, THR interrupt and RHR interrupt and they can be enabled/disabled individually.
Notes: The RX_STOP_IT interrupt is generated based on the value set in the BOF Length register (UART_EBLR). In IR-CIR mode, contrary to the IR-IRDA mode, the TX_STATUS_IT has only one meaning corresponding to the case UART_MDR2[0] = 0.
TypeRW
313029282726252423222120191817161514131211109876543210
RESERVEDRESERVEDTX_STATUS_ITRESERVEDRX_OVERRUN_ITRX_STOP_ITTHR_ITRHR_IT
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0. Write has no effect.RW0x000000
7:6RESERVEDNot used in CIR modeRW0x0
5TX_STATUS_ITRW0
0x0: Disables the TX status interrupt
0x1: Enables the TX status interrupt
4RESERVEDNot used in CIR modeRW0
3RX_OVERRUN_ITRW0
0x0: Disables the RX overrun interrupt
0x1: Enables the RX overrun interrupt
2RX_STOP_ITRW0
0x0: Disables the receive stop interrupt
0x1: Enables the receive stop interrupt
1THR_ITRW0
0x0: Disables the THR interrupt
0x1: Enables the THR interrupt
0RHR_ITRW0
0x0: Disables the RHR interrupt
0x1: Enables the RHR interrupt
Table 24-149 UART_DLH
Address Offset0x0000 0004
Physical Address0x4806 A004
0x4806 C004
0x4802 0004
0x4806 E004
0x4806 6004
0x4806 8004
0x4842 0004
0x4842 2004
0x4842 4004
0x4AE2 B004
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionThis register, with UART_DLL, stores the 14-bit divisor for generating the baud clock in the baud rate generator. DLH stores the most-significant part of the divisor. DLL stores the least-significant part of the divisor.
TypeRW
313029282726252423222120191817161514131211109876543210
RESERVEDRESERVEDCLOCK_MSB
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0. Write has no effect.RW0x000000
7:6RESERVEDRead returns 0. Write has no effect.RW0x0
5:0CLOCK_MSBStores the 6-bit MSB divisor valueRW0x00
Table 24-150 UART_IIR
Address Offset0x0000 0008
Physical Address0x4806 A008
0x4806 C008
0x4802 0008
0x4806 E008
0x4806 6008
0x4806 8008
0x4842 0008
0x4842 2008
0x4842 4008
0x4AE2 B008
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionInterrupt identification register.
The IIR is a read-only register that provides the source of the interrupt in a prioritized manner.
TypeR
313029282726252423222120191817161514131211109876543210
RESERVEDFCR_MIRRORIT_TYPEIT_PENDING
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0. Write has no effect.R0x000000
7:6FCR_MIRRORMirror the contents of UART_FCR[0] on both bits.R0x0
5:1IT_TYPERead 0x0: Modem interrupt. Priority = 4R0x00
Read 0x1: THR interrupt. Priority = 3
Read 0x2: RHR interrupt. Priority = 2
Read 0x3: Receiver line status error. Priority = 3
Read 0x6: Rx time-out. Priority = 2
Read 0x8: XOFF/special character. Priority = 5
Read 0x10: CTS, RTS, DSR change state from active (low) to inactive (high) Priority = 6
0IT_PENDINGRead 0x0: An interrupt is pending.R1
Read 0x1: No interrupt is pending.
Table 24-151 UART_IIR_IRDA
Address Offset0x0000 0008
Physical Address0x4806 A008
0x4806 C008
0x4802 0008
0x4806 E008
0x4806 6008
0x4806 8008
0x4842 0008
0x4842 2008
0x4842 4008
0x4AE2 B008
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionThe interrupt line is activated whenever one of the 8 interrupts is active.
TypeR
313029282726252423222120191817161514131211109876543210
RESERVEDEOF_ITLINE_STS_ITTX_STATUS_ITSTS_FIFO_ITRX_OE_ITRX_FIFO_LAST_BYTE_ITTHR_ITRHR_IT
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0. Write has no effect.R0x000000
7EOF_ITR0
Read 0x0: Receive EOF interrupt inactive
Read 0x1: Received EOF interrupt active
6LINE_STS_ITR0
Read 0x0: Receiver line status interrupt inactive
Read 0x1: Receiver line status interrupt active
5TX_STATUS_ITR0
Read 0x0: TX status interrupt inactive
Read 0x1: TX status interrupt active
4STS_FIFO_ITR0
Read 0x0: Status FIFO trigger level interrupt inactive
Read 0x1: Status FIFO trigger level interrupt active
3RX_OE_ITR0
Read 0x0: RX overrun interrupt inactive
Read 0x1: RX overrun interrupt active
2RX_FIFO_LAST_BYTE_ITR0
Read 0x0: Last byte of frame in RX FIFO interrupt inactive
Read 0x1: Last byte of frame in RX FIFO interrupt active
1THR_ITR0
Read 0x0: THR interrupt inactive
Read 0x1: THR interrupt active
0RHR_ITR1
Read 0x0: RHR interrupt inactive
Read 0x1: RHR interrupt active
Table 24-152 UART_IIR_CIR
Address Offset0x0000 0008
Physical Address0x4806 A008
0x4806 C008
0x4802 0008
0x4806 E008
0x4806 6008
0x4806 8008
0x4842 0008
0x4842 2008
0x4842 4008
0x4AE2 B008
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionThe interrupt line is activated whenever one of the 6 interrupts is active.
TypeR
313029282726252423222120191817161514131211109876543210
RESERVEDRESERVEDTX_STATUS_ITRESERVEDRX_OE_ITRX_STOP_ITTHR_ITRHR_IT
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0. Write has no effect.R0x000000
7:6RESERVEDNot used in CIR modeR0x0
5TX_STATUS_ITRead 0x0: TX status interrupt inactiveR0
Read 0x1: TX status interrupt active
4RESERVEDNot used in CIR modeR0
3RX_OE_ITRead 0x0: RX overrun interrupt inactiveR0
Read 0x1: RX overrun interrupt active
2RX_STOP_ITRead 0x0: Receive stop interrupt inactiveR0
Read 0x1: Receive stop interrupt active
1THR_ITRead 0x0: THR interrupt inactiveR0
Read 0x1: THR interrupt active
0RHR_ITRead 0x0: RHR interrupt inactiveR0
Read 0x1: RHR interrupt active
Table 24-153 UART_FCR
Address Offset0x0000 0008
Physical Address0x4806 A008
0x4806 C008
0x4802 0008
0x4806 E008
0x4806 6008
0x4806 8008
0x4842 0008
0x4842 2008
0x4842 4008
0x4AE2 B008
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionFIFO control register
Notes: Bits 4 and 5 can only be written to when UART_EFR[4] = 1. Bits 0 and 3 can be changed only when the baud clock is not running (DLL and DLH set to 0). See Table 24-99 for UART_FCR[5:4] setting restriction when UART_SCR[6] = 1. See Table 24-100 for UART_FCR[7:6] setting restriction when UART_SCR[7] = 1.
TypeW
313029282726252423222120191817161514131211109876543210
RESERVEDRX_FIFO_TRIGTX_FIFO_TRIGDMA_MODETX_FIFO_CLEARRX_FIFO_CLEARFIFO_EN
BitsField NameDescriptionTypeReset
31:8RESERVEDWrite has no effect.W0x000000
7:6RX_FIFO_TRIGSets the trigger level for the RX FIFO:
If UART_SCR[7] = 0 and UART_TLR[7:4] = 0000:
00: 8 characters
01: 16 characters
10: 56 characters
11: 60 characters
If UART_SCR[7] = 0 and UART_TLR[7:4] != 0000, RX_FIFO_TRIG is not considered. If UART_SCR[7] = 1, RX_FIFO_TRIG is 2 LSBs of the trigger level (1-63 on 6 bits) with the granularity 1.
W0x0
5:4TX_FIFO_TRIGSets the trigger level for the TX FIFO:
If UART_SCR[6] = 0 and UART_TLR[3:0] = 0000: 00: 8 spaces
01: 16 spaces
10: 32 spaces
11: 56 spaces
If UART_SCR[6] = 0 and UART_TLR[3:0] != 0000, TX_FIFO_TRIG is not considered. If UART_SCR[6] = 1, TX_FIFO_TRIG is 2 LSBs of the trigger level (1-63 on 6 bits) with the granularity 1
W0x0
3DMA_MODEThis register is considered if UART_SCR[0] = 0.W0
Write 0x0: DMA_MODE 0 (No DMA)
Write 0x1: DMA_MODE 1 (UART_nDMA_REQ[0] in TX (UARTi_DREQ_TX), UART_nDMA_REQ[1] in RX (UARTi_DREQ_RX))
2TX_FIFO_CLEARW0
Write 0x0: No change
Write 0x1: Clears the TX FIFO and resets its counter logic to 0. Returns to 0 after clearing FIFO.
1RX_FIFO_CLEARW0
Write 0x0: No change
Write 0x1: Clears the RX FIFO and resets its counter logic to 0. Returns to 0 after clearing FIFO.
0FIFO_ENW0
Write 0x0: Disables the transmit and RX FIFOs. The transmit and receive holding registers are 1-byte FIFOs.
Write 0x1: Enables the transmit and RX FIFOs. The transmit and receive holding registers are 64-byte FIFOs.
Table 24-154 UART_EFR
Address Offset0x0000 0008
Physical Address0x4806 A008
0x4806 C008
0x4802 0008
0x4806 E008
0x4806 6008
0x4806 8008
0x4842 0008
0x4842 2008
0x4842 4008
0x4AE2 B008
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionEnhanced feature register
This register enables or disables enhanced features. Most of the enhanced functions apply only to UART modes, but UART_EFR[4] enables write accesses to UART_FCR[5:4], the TX trigger level, which is also used in IrDA modes.
TypeRW
313029282726252423222120191817161514131211109876543210
RESERVEDAUTO_CTS_ENAUTO_RTS_ENSPECIAL_CHAR_DETECTENHANCED_ENSW_FLOW_CONTROL
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0. Write has no effect.RW0x000000
7AUTO_CTS_ENAuto-CTS enable bitRW0
0x0: Normal operation
0x1: Auto-CTS flow control is enabled. Transmission is halted when the CTS* pin is high (inactive).
6AUTO_RTS_ENAuto-RTS enable bitRW0
0x0: Normal operation
0x1: Auto-RTS flow control is enabled. RTS* pin goes high (inactive) when the RX FIFO HALT trigger level, UART_TCR[3:0], is reached, and goes low (active) when the RX FIFO RESTORE transmission trigger level is reached.
5SPECIAL_CHAR_DETECTRW0
0x0: Normal operation
0x1: Special character detect enable. Received data is compared with XOFF2 data. If a match occurs, the received data is transferred to the RX FIFO and the UART_IIR[4] bit is set to 1 to indicate that a special character was detected.
4ENHANCED_ENEnhanced functions write enable bitRW0
0x0: Disables writing to IER bits 4-7, UART_FCR bits 4-5, and UART_MCR bits 5-7.
0x1: Enables writing to IER bits 4-7, UART_FCR bits 4-5, and UART_MCR bits 5-7.
3:0SW_FLOW_CONTROLCombinations of software flow control can be selected by programming bit 3 - bit 0. See Table 24-113.RW0x0
Table 24-155 UART_LCR
Address Offset0x0000 000C
Physical Address0x4806 A00C
0x4806 C00C
0x4802 000C
0x4806 E00C
0x4806 600C
0x4806 800C
0x4842 000C
0x4842 200C
0x4842 400C
0x4AE2 B00C
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionLine control register
LCR[6:0] define transmission and reception parameters. Note: When LCR[6] is set to 1, the TX line is forced to 0 and remains in this state as long as LCR[6] = 1.
TypeRW
313029282726252423222120191817161514131211109876543210
RESERVEDDIV_ENBREAK_ENPARITY_TYPE2PARITY_TYPE1PARITY_ENNB_STOPCHAR_LENGTH
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0. Write has no effect.RW0x000000
7DIV_ENRW0
0x0: Normal operating condition
0x1: Divisor latch enable. Allows access to UART_DLL, UART_DLH, and other registers (see Table 24-101).
6BREAK_ENBreak control bitRW0
0x0: Normal operating condition
0x1: Forces the transmitter output to go low to alert the communication terminal
5PARITY_TYPE2Selects the forced parity format (if UART_LCR[3] = 1). If UART_LCR[5] = 1 and UART_LCR[4] = 0, the parity bit is forced to 1 in the transmitted and received data. If UART_LCR[5] = 1 and UART_LCR[4] = 1, the parity bit is forced to 0 in the transmitted and received data.RW0
UART_LCR[3] UART_LCR[4] UART_LCR[5]Parity
0N/AN/ANo parity
100Odd parity
110Even parity
101Forced 1
111Forced 0
4PARITY_TYPE1RW0
0x0: Odd parity is generated (if UART_LCR[3] = 1).
0x1: Even parity is generated (if UART_LCR[3] = 1).
3PARITY_EN0x0: No parityRW0
0x1: A parity bit is generated during transmission and the receiver checks for received parity.
2NB_STOPSpecifies the number of stop-bitsRW0
0x0: 1 stop-bit (word length = 5, 6, 7, 8)
0x1: 1.5 stop-bits (word length = 5) 2 stop-bits (word length = 6, 7, 8)
1:0CHAR_LENGTHSpecifies the word length to be transmitted or receivedRW0x0
0x0: 5 bits
0x1: 6 bits
0x2: 7 bits
0x3: 8 bits
Table 24-156 UART_XON1_ADDR1
Address Offset0x0000 0010
Physical Address0x4806 A010
0x4806 C010
0x4802 0010
0x4806 E010
0x4806 6010
0x4806 8010
0x4842 0010
0x4842 2010
0x4842 4010
0x4AE2 B010
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionUART mode: XON1 character, IrDA mode: ADDR1 address
TypeRW
313029282726252423222120191817161514131211109876543210
RESERVEDXON_WORD1
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0. Write has no effect.RW0x000000
7:0XON_WORD1Stores the 8-bit XON1 character in UART modes and ADDR1 address 1 for IrDA modesRW0x00
Table 24-157 UART_MCR
Address Offset0x0000 0010
Physical Address0x4806 A010
0x4806 C010
0x4802 0010
0x4806 E010
0x4806 6010
0x4806 8010
0x4842 0010
0x4842 2010
0x4842 4010
0x4AE2 B010
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionModem control register
MCR[3:0] controls the interface with the modem, data set, or peripheral device that emulates the modem.
TypeRW
313029282726252423222120191817161514131211109876543210
RESERVEDRESERVEDTCR_TLRXON_ENLOOPBACK_ENCD_STS_CHRI_STS_CHRTSDTR
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0. Write has no effect.RW0x000000
7RESERVEDRead returns 0. Write has no effect.RW0
6TCR_TLR0x0: No actionRW0
0x1: Enables access to the UART_TCR and UART_TLR registers
5XON_EN0x0: Disable XON any function.RW0
0x1: Enable XON any function.
4LOOPBACK_EN0x0: Normal operating modeRW0
0x1: Enable local loopback mode (internal). In this mode, the MCR[3:0] signals are looped back into the UART_MSR[7:4] bit field. The transmit output is looped back to the receive input internally.
3CD_STS_CH0x0: In loopback, forces DCD* input high and IRQ outputs to inactive stateRW0
0x1: In loopback, forces DCD* input low and IRQ outputs to inactive state
2RI_STS_CH0x0: In loopback, forces RI* input highRW0
0x1: In loopback, forces RI* input low
1RTSIn loopback, controls the UART_MSR[4] bit. If auto-RTS is enabled, the RTS* output is controlled by hardware flow control.RW0
0x0: Force RTS* output to inactive (high).
0x1: Force RTS* output to active (low).
0DTR0x0: Force DTR* output to inactive (high).RW0
0x1: Force DTR* output to active (low).
Table 24-158 UART_LSR
Address Offset0x0000 0014
Physical Address0x4806 A014
0x4806 C014
0x4802 0014
0x4806 E014
0x4806 6014
0x4806 8014
0x4842 0014
0x4842 2014
0x4842 4014
0x4AE2 B014
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionLine status register
TypeR
313029282726252423222120191817161514131211109876543210
RESERVEDRX_FIFO_STSTX_SR_ETX_FIFO_ERX_BIRX_FERX_PERX_OERX_FIFO_E
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0.R0x000000
7RX_FIFO_STSRead 0x0: Normal operationR0
Read 0x1: At least one parity error, framing error, or break indication in the RX FIFO. Bit 7 is cleared when no more errors are present in the RX FIFO.
6TX_SR_ERead 0x0: Transmitter hold (TX FIFO) and shift registers are not empty.R1
Read 0x1: Transmitter hold (TX FIFO) and shift registers are empty.
5TX_FIFO_ERead 0x0: Transmit hold register (TX FIFO) is not empty.R1
Read 0x1: Transmit hold register (TX FIFO) is empty. The transmission is not necessarily complete.
4RX_BIRead 0x0: No break conditionR0
Read 0x1: A break was detected while the data from the RX FIFO was received (for example, RX input was low for one character + 1 bit time frame).
3RX_FERead 0x0: No framing error in data RX FIFOR0
Read 0x1: Framing error occurred in data from RX FIFO (received data did not have a valid stop-bit).
2RX_PERead 0x0: No parity error in data from RX FIFOR0
Read 0x1: Parity error in data from RX FIFO
1RX_OERead 0x0: No overrun errorR0
Read 0x1: Overrun error occurred. Set when the character in the receive shift register is not transferred to the RX FIFO. This occurs only when the RX FIFO is full.
0RX_FIFO_ERead 0x0: No data in the RX FIFOR0
Read 0x1: At least one data character in the RX FIFO
Table 24-159 UART_LSR_IRDA
Address Offset0x0000 0014
Physical Address0x4806 A014
0x4806 C014
0x4802 0014
0x4806 E014
0x4806 6014
0x4806 8014
0x4842 0014
0x4842 2014
0x4842 4014
0x4AE2 B014
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionWhen the LSR is read, LSR[4:2] reflect the error bits [FL, CRC, ABORT] of the frame at the top of the STATUS FIFO (next frame status to be read).
TypeR
313029282726252423222120191817161514131211109876543210
RESERVEDTHR_EMPTYSTS_FIFO_FULLRX_LAST_BYTEFRAME_TOO_LONGABORTCRCSTS_FIFO_ERX_FIFO_E
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0.R0x000000
7THR_EMPTYRead 0x0: Transmit holding register (TX FIFO) is not empty.R1
Read 0x1: Transmit hold register (TX FIFO) is empty. The transmission is not necessarily complete.
6STS_FIFO_FULLRead 0x0: Status FIFO not fullR0
Read 0x1: Status FIFO full
5RX_LAST_BYTERead 0x0: The RX FIFO (RHR) does not contain the last byte of the frame to be read.R0
Read 0x1: The RX FIFO (RHR) contains the last byte of the frame to be read. This bit is set only when the last byte of a frame is available to be read. It determines the frame boundary. It is cleared on a single read of the LSR register. See the note below.
4FRAME_TOO_LONGRead 0x0: No frame-too-long error in frameR0
Read 0x1: Frame-too-long error in the frame at the top of the STATUS FIFO, (next character to be read). This bit is set to 1 when a frame exceeding the maximum length (set by RXFLH and RXFLL registers) is received. When this error is detected, current frame reception is terminated. Reception is stopped until the next START flag is detected.
3ABORTRead 0x0: No abort pattern error in frameR0
Read 0x1: Abort pattern is received. SIR and MIR: Abort pattern FIR: Illegal symbol
2CRCRead 0x0: No CRC error in frameR0
Read 0x1: CRC error in the frame at the top of the STATUS FIFO (next character to be read)
1STS_FIFO_ERead 0x0: Status FIFO not emptyR1
Read 0x1: Status FIFO empty
0RX_FIFO_ERead 0x0: No data in the RX FIFOR1
Read 0x1: At least one data character in the RX FIFO
Table 24-160 UART_LSR_CIR
Address Offset0x0000 0014
Physical Address0x4806 A014
0x4806 C014
0x4802 0014
0x4806 E014
0x4806 6014
0x4806 8014
0x4842 0014
0x4842 2014
0x4842 4014
0x4AE2 B014
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionLine status register in CIR mode
TypeR
313029282726252423222120191817161514131211109876543210
RESERVEDTHR_EMPTYRESERVEDRX_STOPRESERVEDRX_FIFO_E
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0.R0x000000
7THR_EMPTYRead 0x0: Transmit holding register (TX FIFO) is not empty.R1
Read 0x1: Transmit hold register (TX FIFO) is empty. The transmission is not necessarily complete.
6RESERVEDNot used in CIR modeR0
5RX_STOPThe RX_STOP is generated based on the value set in the BOF Length register (UART_EBLR). It is cleared on a single read of the UART_LSR register.R0
Read 0x0: Reception is ongoing or waiting for a new frame.
Read 0x1: Reception is complete.
4:1RESERVEDNot used in CIR modeR0x0
0RX_FIFO_ERead 0x0: At least one data character in the RX FIFOR1
Read 0x1: No data in the RX FIFO
Table 24-161 UART_XON2_ADDR2
Address Offset0x0000 0014
Physical Address0x4806 A014
0x4806 C014
0x4802 0014
0x4806 E014
0x4806 6014
0x4806 8014
0x4842 0014
0x4842 2014
0x4842 4014
0x4AE2 B014
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionStores the 8-bit XON2 character in UART moldes and ADDR2 address 2 for IrDA modes
TypeRW
313029282726252423222120191817161514131211109876543210
RESERVEDXON_WORD2
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0. Write has no effect.RW0x000000
7:0XON_WORD2Stores the 8-bit XON2 character in UART modes and ADDR2 address 2 for IrDA modesRW0x00
Table 24-162 UART_TCR
Address Offset0x0000 0018
Physical Address0x4806 A018
0x4806 C018
0x4802 0018
0x4806 E018
0x4806 6018
0x4806 8018
0x4842 0018
0x4842 2018
0x4842 4018
0x4AE2 B018
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionTransmission control register
This register stores the RX FIFO threshold levels to start/stop transmission during hardware/software flow control. Notes: Trigger levels from 0 to 60 bytes are available with a granularity of 4. (Trigger level = 4 x [4-bit register value]) The programmer must ensure that UART_TCR[3:0] > UART_TCR[7:4] when auto-RTS or software flow control is enabled to avoid a mis-operation of the device. In FIFO interrupt mode with flow control, the programmer must ensure that the trigger level to halt transmission is greater than or equal to the RX FIFO trigger level (UART_TLR[7:4] or UART_FCR[7:6]); otherwise, FIFO operation stalls. In FIFO DMA mode with flow control, this concept does not exist because a DMA request is sent each time a byte is received.
TypeRW
313029282726252423222120191817161514131211109876543210
RESERVEDRX_FIFO_TRIG_STARTRX_FIFO_TRIG_HALT
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0. Write has no effect.RW0x000000
7:4RX_FIFO_TRIG_STARTRX FIFO trigger level to RESTORE transmission (0 - 60)RW0x0
3:0RX_FIFO_TRIG_HALTRX FIFO trigger level to HALT transmission (0 - 60)RW0xF
Table 24-163 UART_XOFF1
Address Offset0x0000 0018
Physical Address0x4806 A018
0x4806 C018
0x4802 0018
0x4806 E018
0x4806 6018
0x4806 8018
0x4842 0018
0x4842 2018
0x4842 4018
0x4AE2 B018
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionUART mode XOFF1 character
TypeRW
313029282726252423222120191817161514131211109876543210
RESERVEDXOFF_WORD1
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0. Write has no effect.RW0x000000
7:0XOFF_WORD1Stores the 8-bit XOFF1 character used in UART modesRW0x00
Table 24-164 UART_MSR
Address Offset0x0000 0018
Physical Address0x4806 A018
0x4806 C018
0x4802 0018
0x4806 E018
0x4806 6018
0x4806 8018
0x4842 0018
0x4842 2018
0x4842 4018
0x4AE2 B018
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionModem status register. UART mode only.
This register provides information about the current state of the control lines from the modem, data set, or peripheral device to the LH. It also indicates when a control input from the modem changes state.
TypeR
313029282726252423222120191817161514131211109876543210
RESERVEDNCD_STSNRI_STSNDSR_STSNCTS_STSDCD_STSRI_STSDSR_STSCTS_STS
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0.R0x000000
7NCD_STSThis bit is the complement of the DCD* input. In loopback mode, it is equivalent to UART_MCR[3].R-
6NRI_STSThis bit is the complement of the RI* input. In loopback mode, it is equivalent to UART_MCR[2].R-
5NDSR_STSThis bit is the complement of the DSR* input. In loopback mode, it is equivalent to UART_MCR[0].R-
4NCTS_STSThis bit is the complement of the CTS* input. In loopback mode, it is equivalent to UART_MCR[1].R-
3DCD_STSIndicates that DCD* input (or UART_MCR[3] in loopback) changed. Cleared on a read.R0
2RI_STSIndicates that RI* input (or UART_MCR[2] in loopback) changed state from low to high. Cleared on a read.R0
1DSR_STSR0
Read 0x1: Indicates that DSR* input (or UART_MCR[0] in loopback) changed state. Cleared on a read.
0CTS_STSR0
Read 0x1: Indicates that CTS* input (or UART_MCR[1] in loopback) changed state. Cleared on a read.
Table 24-165 UART_SPR
Address Offset0x0000 001C
Physical Address0x4806 A01C
0x4806 C01C
0x4802 001C
0x4806 E01C
0x4806 601C
0x4806 801C
0x4842 001C
0x4842 201C
0x4842 401C
0x4AE2 B01C
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionScratchpad register
This read/write register does not control the module. It is a scratchpad register to be used by the programmer to hold temporary data.
TypeRW
313029282726252423222120191817161514131211109876543210
RESERVEDSPR_WORD
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0. Write has no effect.RW0x000000
7:0SPR_WORDScratchpad registerRW0x00
Table 24-166 UART_TLR
Address Offset0x0000 001C
Physical Address0x4806 A01C
0x4806 C01C
0x4802 001C
0x4806 E01C
0x4806 601C
0x4806 801C
0x4842 001C
0x4842 201C
0x4842 401C
0x4AE2 B01C
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionTrigger level register
This register stores the programmable transmit and RX FIFO trigger levels for DMA and IRQ generation.
TypeRW
313029282726252423222120191817161514131211109876543210
RESERVEDRX_FIFO_TRIG_DMATX_FIFO_TRIG_DMA
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0. Write has no effect.RW0x000000
7:4RX_FIFO_TRIG_DMAReceive FIFO trigger levelRW0x0
3:0TX_FIFO_TRIG_DMATransmit FIFO trigger levelRW0x0
Table 24-167 UART_XOFF2
Address Offset0x0000 001C
Physical Address0x4806 A01C
0x4806 C01C
0x4802 001C
0x4806 E01C
0x4806 601C
0x4806 801C
0x4842 001C
0x4842 201C
0x4842 401C
0x4AE2 B01C
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionUART mode XOFF2 character
TypeRW
313029282726252423222120191817161514131211109876543210
RESERVEDXOFF_WORD2
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0. Write has no effect.RW0x000000
7:0XOFF_WORD2Stores the 8-bit XOFF2 character used in UART modes.RW0x00
Table 24-168 UART_MDR1
Address Offset0x0000 0020
Physical Address0x4806 A020
0x4806 C020
0x4802 0020
0x4806 E020
0x4806 6020
0x4806 8020
0x4842 0020
0x4842 2020
0x4842 4020
0x4AE2 B020
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionMode definition register 1
The mode of operation can be programmed by writing to MDR1[2:0] and therefore the MDR1 must be programmed on startup after configuration of the configuration registers (UART_DLL, UART_DLH, and UART_LCR). The value of MDR1[2:0] must not be changed again during normal operation. Note: If the module is disabled by setting the MODE_SELECT field to 111, interrupt requests can still be generated unless disabled through the interrupt enable register (UART_IER). In this case, UART mode interrupts are visible. Reading the interrupt identification register (UART_IIR) shows UART mode interrupt flags.
TypeRW
313029282726252423222120191817161514131211109876543210
RESERVEDFRAME_END_MODESIP_MODESCTSET_TXIRIR_SLEEPMODE_SELECT
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0. Write has no effect.RW0x000000
7FRAME_END_MODEIrDA mode onlyRW0
0x0: Frame-length method
0x1: Set EOT bit method
6SIP_MODEMIR/FIR modes onlyRW0
0x0: Manual SIP mode: SIP is generated with the control of UART_ACREG[3].
0x1: Automatic SIP mode: SIP is generated after each transmission.
5SCTStore and control the transmission.RW0
0x0: Starts the infrared transmission when a value is written to UART_THR
0x1: Starts the infrared transmission with the control of UART_ACREG[2].
Note: Before starting any transmission, there must be no reception ongoing.
4SET_TXIRUsed to configure the infrared transceiverRW0
0x0:
a) No action if UART_MDR2[7] = 0
b) TXIR pin output is forced low if UART_MDR2[7] = 1.
0x1: IRTX pin output is forced high (not dependent on UART_MDR2[7] value).
3IR_SLEEP0x0: IrDA/CIR sleep mode disabledRW0
0x1: IrDA/CIR sleep mode enabled
2:0MODE_SELECT0x0: UART 16x modeRW0x7
0x1: SIR mode
0x2: UART 16x auto-baud
0x3: UART 13x mode
0x4: MIR mode
0x5: FIR mode
0x6: CIR mode
0x7: Disable (default state)
Table 24-169 UART_MDR2
Address Offset0x0000 0024
Physical Address0x4806 A024
0x4806 C024
0x4802 0024
0x4806 E024
0x4806 6024
0x4806 8024
0x4842 0024
0x4842 2024
0x4842 4024
0x4AE2 B024
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionMode definition register 2
IR-IrDA and IR-CIR modes only. UART_MDR2[0] describes the status of the interrupt in UART_IIR[5]. The IRTX_UNDERRUN bit should be read after an UART_IIR[5] TX_STATUS_IT interrupt. The bits [2:1] of this register set the trigger level for the frame status FIFO (8 entries) and must be programmed before the mode is programmed in UART_MDR1[2:0].
Note: The UART_MDR2[6] gives the flexibility to invert the RX pin in the UART to ensure that the protocol at the input of the transceiver module has the same polarity at module level. By default, the RX pin is inverted because most transceivers invert the IR receive pin.
TypeRW
313029282726252423222120191817161514131211109876543210
RESERVEDSET_TXIR_ALTIRRXINVERTCIR_PULSE_MODEUART_PULSESTS_FIFO_TRIGIRTX_UNDERRUN
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0. Write has no effect.RW0x000000
7SET_TXIR_ALTProvide alternate function for UART_MDR1[4] (SET_TXIR).R0
0x0: Normal mode
0x1: Alternate mode for SET_TXIR
6IRRXINVERTIR mode only (IrDA and CIR). Invert RX pin in the module before the voting or sampling system logic of the infrared block. This does not affect the RX path in UART modem modes.RW0
0x0: Inversion is performed.
0x1: No inversion is performed.
5:4CIR_PULSE_MODECIR pulse modulation definition. Defines high level of the pulse width associated with a digit:RW0x0
0x0: Pulse width of 3 from 12 cycles
0x1: Pulse width of 4 from 12 cycles
0x2: Pulse width of 5 from 12 cycles
0x3: Pulse width of 6 from 12 cycles
3UART_PULSEUART mode only. Allows pulse shaping in UART mode.RW0
0x0: Normal UART mode
0x1: UART mode with a pulse shaping
2:1STS_FIFO_TRIGIR-IrDA mode only. Frame status FIFO threshold select:RW0x0
0x0: 1 entry
0x1: 4 entries
0x2: 7 entries
0x3: 8 entries
0IRTX_UNDERRUNIrDA transmission status interrupt. When the UART_IIR[5] interrupt occurs, the meaning of the interrupt is:R0
Read 0x0: The last bit of the frame transmitted successfully without error.
Read 0x1: An underrun occurred. The last bit of the frame was transmitted but with an underrun error. The bit is reset to 0 when the UART_RESUME register is read.
Table 24-170 UART_SFLSR
Address Offset0x0000 0028
Physical Address0x4806 A028
0x4806 C028
0x4802 0028
0x4806 E028
0x4806 6028
0x4806 8028
0x4842 0028
0x4842 2028
0x4842 4028
0x4AE2 B028
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionStatus FIFO line status register
IrDA modes only. Reading this register effectively reads frame status information from the status FIFO (this register does not physically exist). Reading this register increments the status FIFO read pointer (UART_SFREGL and UART_SFREGH must be read first).
TypeR
313029282726252423222120191817161514131211109876543210
RESERVEDRESERVEDOE_ERRORFRAME_TOO_LONG_ERRORABORT_DETECTCRC_ERRORRESERVED
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0.R0x000000
7:5RESERVEDRead returns 0.R0x0
4OE_ERRORRead 0x1: Overrun error in RX FIFO when frame at top of RX FIFO was received
Note: Top of RX FIFO = Next frame to be read from RX FIFO
R-
3FRAME_TOO_LONG_ERRORRead 0x1: Frame-length too long error in frame at top of RX FIFOR-
2ABORT_DETECTRead 0x1: Abort pattern detected in frame at top of RX FIFOR-
1CRC_ERRORRead 0x1: CRC error in frame at top of RX FIFOR-
0RESERVEDR0
Table 24-171 UART_TXFLL
Address Offset0x0000 0028
Physical Address0x4806 A028
0x4806 C028
0x4802 0028
0x4806 E028
0x4806 6028
0x4806 8028
0x4842 0028
0x4842 2028
0x4842 4028
0x4AE2 B028
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionTransmit frame length register low
IrDA modes only. The UART_TXFLL and UART_TXFLH registers hold the 13-bit transmit frame length (expressed in bytes). UART_TXFLL holds the LSBs and UART_TXFLH holds the MSBs. The frame length value is used if the frame length method of frame closing is used.
TypeW
313029282726252423222120191817161514131211109876543210
RESERVEDTXFLL
BitsField NameDescriptionTypeReset
31:8RESERVEDWrite has no effect.W0x000000
7:0TXFLLLSB register used to specify the frame lengthW0x00
Table 24-172 UART_RESUME
Address Offset0x0000 002C
Physical Address0x4806 A02C
0x4806 C02C
0x4802 002C
0x4806 E02C
0x4806 602C
0x4806 802C
0x4842 002C
0x4842 202C
0x4842 402C
0x4AE2 B02C
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionIR-IrDA and IR-CIR modes only. This register is used to clear internal flags, which halt transmission/reception when an underrun/overrun error occurs. Reading this register resumes the halted operation. This register does not physically exist and reads always as 0x00.
TypeR
313029282726252423222120191817161514131211109876543210
RESERVEDRESUME
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0.R0x000000
7:0RESUMEDummy read to restart the TX or RXR0x00
Table 24-173 UART_TXFLH
Address Offset0x0000 002C
Physical Address0x4806 A02C
0x4806 C02C
0x4802 002C
0x4806 E02C
0x4806 602C
0x4806 802C
0x4842 002C
0x4842 202C
0x4842 402C
0x4AE2 B02C
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionTransmit frame length register high
IrDA modes only. The UART_TXFLL and UART_TXFLH registers hold the 13-bit transmit frame length (expressed in bytes). UART_TXFLL holds the LSBs and UART_TXFLH holds the MSBs. The frame length value is used if the frame length method of frame closing is used.
TypeW
313029282726252423222120191817161514131211109876543210
RESERVEDRESERVEDTXFLH
BitsField NameDescriptionTypeReset
31:8RESERVEDWrite has no effect.W0x000000
7:5RESERVEDWrite has no effect.W0x0
4:0TXFLHMSB register used to specify the frame lengthW0x00
Table 24-174 UART_SFREGL
Address Offset0x0000 0030
Physical Address0x4806 A030
0x4806 C030
0x4802 0030
0x4806 E030
0x4806 6030
0x4806 8030
0x4842 0030
0x4842 2030
0x4842 4030
0x4AE2 B030
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionStatus FIFO register low
IrDA modes only. The frame lengths of received frames are written into the status FIFO. This information can be read by reading the UART_SFREGL and UART_SFREGH registers (these registers do not physically exist). The LSBs are read from UART_SFREGL and the MSBs are read from UART_SFREGH. Reading these registers does not alter the status FIFO read pointer. These registers should be read before the pointer is incremented by reading the UART_SFLSR register.
TypeR
313029282726252423222120191817161514131211109876543210
RESERVEDSFREGL
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0.R0x000000
7:0SFREGLLSB part of the frame lengthR0x-
Table 24-175 UART_RXFLL
Address Offset0x0000 0030
Physical Address0x4806 A030
0x4806 C030
0x4802 0030
0x4806 E030
0x4806 6030
0x4806 8030
0x4842 0030
0x4842 2030
0x4842 4030
0x4AE2 B030
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionReceived frame length register low
IrDA modes only. The UART_RXFLL and UART_RXFLH registers hold the 12-bit receive maximum frame length. UART_RXFLL holds the LSBs and UART_RXFLH holds the MSBs. If the intended maximum receive frame length is n bytes, program the UART_RXFLL and UART_RXFLH registers to be n + 3 in SIR or MIR modes and n + 6 in FIR mode (+3 and +6 are the result of frame format with CRC and stop flag; 2 bytes are associated with the FIR stop flag).
TypeW
313029282726252423222120191817161514131211109876543210
RESERVEDRXFLL
BitsField NameDescriptionTypeReset
31:8RESERVEDWrite has no effect.W0x000000
7:0RXFLLLSB register used to specify the frame length in receptionW0x00
Table 24-176 UART_SFREGH
Address Offset0x0000 0034
Physical Address0x4806 A034
0x4806 C034
0x4802 0034
0x4806 E034
0x4806 6034
0x4806 8034
0x4842 0034
0x4842 2034
0x4842 4034
0x4AE2 B034
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionStatus FIFO register high
IrDA modes only. The frame lengths of received frames are written into the status FIFO. This information can be read by reading the UART_SFREGL and UART_SFREGH registers (these registers do not physically exist). The LSBs are read from UART_SFREGL and the MSBs are read from UART_SFREGH. Reading these registers does not alter the status FIFO read pointer. These registers should be read before the pointer is incremented by reading the UART_SFLSR register.
TypeR
313029282726252423222120191817161514131211109876543210
RESERVEDRESERVEDSFREGH
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0.R0x000000
7:4RESERVEDRead returns 0.R0x0
3:0SFREGHMSB part of the frame lengthR0x-
Table 24-177 UART_RXFLH
Address Offset0x0000 0034
Physical Address0x4806 A034
0x4806 C034
0x4802 0034
0x4806 E034
0x4806 6034
0x4806 8034
0x4842 0034
0x4842 2034
0x4842 4034
0x4AE2 B034
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionReceived frame length register high
IrDA modes only. The UART_RXFLL and UART_RXFLH registers hold the 12-bit receive maximum frame length. UART_RXFLL holds the LSBs and UART_RXFLH holds the MSBs. If the intended maximum receive frame length is n bytes, program the UART_RXFLL and UART_RXFLH to be n + 3 in SIR or MIR modes and n + 6 in FIR mode (+3 and +6 are the result of frame format with CRC and stop flag; 2 bytes are associated with the FIR stop flag).
TypeW
313029282726252423222120191817161514131211109876543210
RESERVEDRESERVEDRXFLH
BitsField NameDescriptionTypeReset
31:8RESERVEDWrite has no effect.W0x000000
7:4RESERVEDWrite has no effect.W0x0
3:0RXFLHMSB register used to specify the frame length in receptionW0x0
Table 24-178 UART_BLR
Address Offset0x0000 0038
Physical Address0x4806 A038
0x4806 C038
0x4802 0038
0x4806 E038
0x4806 6038
0x4806 8038
0x4842 0038
0x4842 2038
0x4842 4038
0x4AE2 B038
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionBOF control register
IrDA modes only. The UART_BLR[6] bit selects whether 0xC0 or 0xFF start patterns are to be used, when multiple start flags are required in SIR mode. If only one start flag is required, this is always 0xC0. If n start flags are required, (-1) 0xC0 or (-1) 0xFF flags are sent, followed by a single 0xC0 flag (immediately preceding the first data byte).
TypeRW
313029282726252423222120191817161514131211109876543210
RESERVEDSTS_FIFO_RESETXBOF_TYPERESERVED
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0. Write has no effect.RW0x000000
7STS_FIFO_RESETStatus FIFO reset. This bit is self-clearing.RW0
6XBOF_TYPESIR xBOF selectRW1
0x0: 0xFF
0x1: 0xC0
5:0RESERVEDRead returns 0.R0x00
Table 24-179 UART_UASR
Address Offset0x0000 0038
Physical Address0x4806 A038
0x4806 C038
0x4802 0038
0x4806 E038
0x4806 6038
0x4806 8038
0x4842 0038
0x4842 2038
0x4842 4038
0x4AE2 B038
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionUART autobauding status register
UART autobauding mode only. This status register returns the speed, the number of bits by characters, and the type of the parity in UART autobauding mode. In autobauding mode, the input frequency of the UART modem must be fixed to 48 MHz. Any other module clock frequency results in incorrect baud rate recognition.
Note: When the UART is in autobauding mode, this register, instead of the UART_LCR, UART_DLL, and UART_DLH registers, is used to set up transmission according to the characteristics of the previous reception.
To reset the autobauding hardware (to start a new AT detection), set UART_MDR1[2:0] to 111 (reset value), then set UART_MDR1[2:1] to 010 (UART in autobaud mode).
To set the UART to standard mode (no autobaud), set UART_MDR1[2:1] to 000.
TypeR
313029282726252423222120191817161514131211109876543210
RESERVEDPARITY_TYPEBIT_BY_CHARSPEED
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0.R0x000000
7:6PARITY_TYPERead 0x0: No parity identifiedR0x0
Read 0x1: Parity space
Read 0x2: Even parity
Read 0x3: Odd parity
5BIT_BY_CHARRead 0x0: 7-bit character identifiedR0
Read 0x1: 8-bit character identified
4:0SPEEDUsed to report the speed identifiedR0x00
Read 0x0: No speed identified
Read 0x1: 115,200 baud
Read 0x2: 57,600 baud
Read 0x3: 38,400 baud
Read 0x4: 28,800 baud
Read 0x5: 19,200 baud
Read 0x6: 14,400 baud
Read 0x7: 9,600 baud
Read 0x8: 4,800 baud
Read 0x9: 2,400 baud
Read 0xA: 1,200 baud
Table 24-180 UART_ACREG
Address Offset0x0000 003C
Physical Address0x4806 A03C
0x4806 C03C
0x4802 003C
0x4806 E03C
0x4806 603C
0x4806 803C
0x4842 003C
0x4842 203C
0x4842 403C
0x4AE2 B03C
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionAuxiliary control register. IR-IrDA and IR-CIR modes only.
TypeRW
313029282726252423222120191817161514131211109876543210
RESERVEDPULSE_TYPESD_MODDIS_IR_RXDIS_TX_UNDERRUNSEND_SIPSCTX_ENABORT_ENEOT_EN
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0. Write has no effect.RW0x000000
7PULSE_TYPESIR pulse width selectRW0
0x0: 3/16 of baud-rate pulse width
0x1: 1.6 µs
6SD_MODPrimary output used to configure transceivers. Connected to the SD/MODE input pin of IrDA transceivers.RW0
0x0: SD pin is set to high.
0x1: SD pin is set to low.
5DIS_IR_RX0x0: Normal operation (RX input automatically disabled during transmit but enabled outside of transmit operation)RW0
0x1: Disables RX input (permanent state - independent of transmit)
4DIS_TX_UNDERRUNIt is recommended to disable TX FIFO underrun capability by masking corresponding underrun interrupt. When disabling underrun by setting UART_ACREG[4] = 1, garbage data is sent over TX line.RW0
0x0: Long stop-bits cannot be transmitted; TX underrun is enabled.
0x1: Long stop-bits can be transmitted; TX underrun is disabled.
3SEND_SIPMIR/FIR modes only. Send serial infrared interaction pulse (SIP). If this bit is set during an MIR/FIR transmission, the SIP is sent at the end of it. This bit is cleared automatically at the end of the SIP transmission.RW0
0x0: No action
0x1: Send SIP pulse.
2SCTX_ENStore and controlled TX start. When UART_MDR1[5] = 1 and the LH writes 1 to this bit, the TX state-machine starts frame transmission. This bit is self-clearing.RW0
1ABORT_ENFrame abort. The LH can intentionally abort transmission of a frame by writing 1 to this bit. Neither the end flag nor the CRC bits are appended to the frame. If TX FIFO is not empty and UART_MDR1[5] = 1, UART IrDA starts a new transfer with data of the previous frame when the abort frame is sent. Therefore, TX FIFO must be reset before sending an abort frame.RW0
0EOT_ENEOT (end of transmission) bit. The LH writes 1 to this bit just before it writes the last byte to the TX FIFO in set-EOT bit frame closing method. This bit is cleared automatically when the LH writes to the THR (TX FIFO).RW0
Table 24-181 UART_SCR
Address Offset0x0000 0040
Physical Address0x4806 A040
0x4806 C040
0x4802 0040
0x4806 E040
0x4806 6040
0x4806 8040
0x4842 0040
0x4842 2040
0x4842 4040
0x4AE2 B040
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionSupplementary control register
Note: Bit 4 enables the wake-up interrupt, but this interrupt is not mapped into the UART_IIR register. Therefore, when an interrupt occurs and there is no interrupt pending in the UART_IIR register, the UART_SSR[1] bit must be checked. To clear the wake-up interrupt, bit UART_SCR[4] must be reset to 0.
TypeRW
313029282726252423222120191817161514131211109876543210
RESERVEDRX_TRIG_GRANU1TX_TRIG_GRANU1DSR_ITRX_CTS_DSR_WAKE_UP_ENABLETX_EMPTY_CTL_ITDMA_MODE_2DMA_MODE_CTL
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0. Write has no effect.RW0x000000
7RX_TRIG_GRANU10x0: Disables the granularity of 1 for trigger RX levelRW0
0x1: Enables the granularity of 1 for trigger RX level
6TX_TRIG_GRANU10x0: Disables the granularity of 1 for trigger TX levelRW0
0x1: Enables the granularity of 1 for trigger TX level
5DSR_IT0x0: Disables DSR* interruptRW0
0x1: Enables DSR* interrupt
4RX_CTS_DSR_WAKE_UP_ENABLE0x0: Disables the wake-up interrupt and clears SSR[1]RW0
0x1: Waits for a falling edge of pins RX, CTS*, or DSR* to generate an interrupt
3TX_EMPTY_CTL_IT0x0: Normal mode for THR interrupt (see
UART mode interrupts table)
RW0
0x1: The THR interrupt is generated when TX FIFO and TX shift register are empty.
2:1DMA_MODE_2Used to specify the DMA mode valid if the UART_SCR[0] bit = 1RW0x0
0x0: DMA mode 0 (no DMA)
0x1: DMA mode 1 (UART_nDMA_REQ[0] in TX, UART_nDMA_REQ[1] in RX)
0x2: DMA mode 2 (UART_nDMA_REQ[0] in RX)
0x3: DMA mode 3 (UART_nDMA_REQ[0] in TX)
0DMA_MODE_CTL0x0: The DMA_MODE is set with UART_FCR[3].RW0
0x1: The DMA_MODE is set with UART_SCR[2:1].
Table 24-182 UART_SSR
Address Offset0x0000 0044
Physical Address0x4806 A044
0x4806 C044
0x4802 0044
0x4806 E044
0x4806 6044
0x4806 8044
0x4842 0044
0x4842 2044
0x4842 4044
0x4AE2 B044
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionSupplementary status register
Note: Bit 1 is reset only when UART_SCR[4] is reset to 0.
TypeRW
313029282726252423222120191817161514131211109876543210
RESERVEDRESERVEDDMA_COUNTER_RSTRX_CTS_DSR_WAKE_UP_STSTX_FIFO_FULL
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0.R0x000000
7:3RESERVEDRead returns 0.R0x00
2DMA_COUNTER_RST0x0: The DMA counter will not be reset if the corresponding FIFO is reset (through UART_FCR[1] or UART_FCR[2]).RW1
0x1: The DMA counter will be reset if corresponding FIFO is reset (through UART_FCR[1] or UART_FCR[2]).
1RX_CTS_DSR_WAKE_UP_STSRead 0x0: No falling edge event on RX, CTS*, and DSR*R0
Read 0x1: A falling edge occurred on RX, CTS*, or DSR*.
0TX_FIFO_FULLRead 0x0: TX FIFO is not full.R0
Read 0x1: TX FIFO is full.
Table 24-183 UART_EBLR
Address Offset0x0000 0048
Physical Address0x4806 A048
0x4806 C048
0x4802 0048
0x4806 E048
0x4806 6048
0x4806 8048
0x4842 0048
0x4842 2048
0x4842 4048
0x4AE2 B048
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionBOF length register
IR-IrDA and IR-CIR modes only. In IR-IrDA SIR operation, this register specifies the number of BOF + xBOFs to transmit. Value set into this register must account for the BOF character; therefore, to send only one BOF with no XBOF, this register must be set to 1. To send one BOF with N XBOF, this register must be set to N + 1. The value 0 sends 1 BOF plus 255 XBOF. In IR-IrDA MIR mode, this register specifies the number of additional start flags (MIR protocol mandates a minimum of 2 start flags). In IR-CIR mode, this register specifies the number of consecutive 0s to be received before generating the RX_STOP interrupt (UART_IIR[2]). All received 0s are stored in the RX FIFO. When the register is set to 0, this feature is deactivated and always in reception state, which can be disabled by setting the UART_ACREG[5] to 1.
Note: If the RX_STOP interrupt occurs before a byte boundary, the remaining bits of the last byte are filled with 0s and passed into the RX FIFO.
TypeRW
313029282726252423222120191817161514131211109876543210
RESERVEDEBLR
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0. Write has no effect.RW0x000000
7:0EBLRIR-IrDA mode: This register allows definition of up to 176 xBOFs, the maximum required by IrDA specification.RW0x00
IR-CIR mode: This register specifies the number of consecutive 0s to be received before generating the RX_STOP interrupt (UART_IIR[2]).
0x00: Feature disabled
0x01: Generate RX_STOP interrupt after receiving one zero bit.
...
0xFF: Generate RX_STOP interrupt after receiving 255 zero bits.
Table 24-184 UART_MVR
Address Offset0x0000 0050
Physical Address0x4806 A050
0x4806 C050
0x4802 0050
0x4806 E050
0x4806 6050
0x4806 8050
0x4842 0050
0x4842 2050
0x4842 4050
0x4AE2 B050
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionModule version register
The reset value is fixed by hardware and corresponds to the RTL revision of this module. A reset has no effect on the value returned.
TypeR
313029282726252423222120191817161514131211109876543210
REV
BitsField NameDescriptionTypeReset
31:0REVRevision numberR0x--
TI internal data
Table 24-185 UART_SYSC
Address Offset0x0000 0054
Physical Address0x4806 A054
0x4806 C054
0x4802 0054
0x4806 E054
0x4806 6054
0x4806 8054
0x4842 0054
0x4842 2054
0x4842 4054
0x4AE2 B054
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionSystem configuration register
The AUTOIDLE bit controls a power-saving technique to reduce the logic power consumption of the open-core protocol (OCP) interface. When the feature is enabled, the clock is gated off until an OCP command for this device is detected. When the software reset bit is set high, it causes a full device reset.
TypeRW
313029282726252423222120191817161514131211109876543210
RESERVEDRESERVEDIDLEMODEENAWAKEUPSOFTRESETAUTOIDLE
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0. Write has no effect.RW0x000000
7:5RESERVEDRead returns 0.R0x0
4:3IDLEMODEPower management req/ack control ref:
OCP Design Guidelines Version 1.1
RW0x0
0x0: Force-idle: Idle request is acknowledged unconditionally.
0x1: No-idle: Idle request is never acknowledged.
0x2: Smart-idle: Idle request is acknowledged based in module internal activity.
0x3: Smart-idle Wake-up: Acknowledgement to an idle request is given based in the internal activity of the module. The module is allowed to generate wake-up request.
2ENAWAKEUPWake-up feature controlRW0
0x0: Wakeup is disabled.
0x1: Wake-up capability is enabled.
1SOFTRESETSoftware reset. Set this bit to 1 to trigger a module reset. This bit is automatically reset by the hardware. Read returns 0.RW0
0x0: Normal mode
0x1: The module is reset.
0AUTOIDLEInternal OCP clock gating strategyRW0
0x0: Clock is running.
0x1: Automatic OCP clock gating strategy is applied, based on OCP interface activity
Table 24-186 UART_SYSS
Address Offset0x0000 0058
Physical Address0x4806 A058
0x4806 C058
0x4802 0058
0x4806 E058
0x4806 6058
0x4806 8058
0x4842 0058
0x4842 2058
0x4842 4058
0x4AE2 B058
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionSystem status register
TypeR
313029282726252423222120191817161514131211109876543210
RESERVEDRESERVEDRESETDONE
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0.R0x000000
7:1RESERVEDRead returns 0.R0x00
0RESETDONEInternal reset monitoringR0
Read 0x0: Internal module reset is ongoing.
Read 0x1: Reset complete
Table 24-187 UART_WER
Address Offset0x0000 005C
Physical Address0x4806 A05C
0x4806 C05C
0x4802 005C
0x4806 E05C
0x4806 605C
0x4806 805C
0x4842 005C
0x4842 205C
0x4842 405C
0x4AE2 B05C
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionWake-up enable register
The UART wake-up enable register is used to mask and unmask a UART event that would subsequently notify the system. An event is any activity in the logic that could cause an interrupt and/or an activity that would require the system to wake up. Even if the wakeup is disabled for certain events, if these events are also an interrupt to the UART, the UART registers the interrupt.
TypeRW
313029282726252423222120191817161514131211109876543210
RESERVEDTX_WAKEUP_ENEVENT_6_RECEIVER_LINE_STATUS_INTERRUPTEVENT_5_RHR_INTERRUPTEVENT_4_RX_ACTIVITYEVENT_3_DCD_CD_ACTIVITYEVENT_2_RI_ACTIVITYEVENT_1_DSR_ACTIVITYEVENT_0_CTS_ACTIVITY
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0. Write has no effect.RW0x000000
7TX_WAKEUP_EN0x0: Event is not allowed to wake up the system.RW1
0x1: Event can wake up the system: it can be THR_IT or TX_DMA request and/or TX_STATUS_IT.
6EVENT_6_RECEIVER_LINE_STATUS_INTERRUPT0x0: Event is not allowed to wake up the system.RW1
0x1: Event can wake up the system.
5EVENT_5_RHR_INTERRUPT0x0: Event is not allowed to wake up the system.RW1
0x1: Event can wake up the system.
4EVENT_4_RX_ACTIVITY0x0: Event is not allowed to wake up the system.RW1
0x1: Event can wake up the system.
3EVENT_3_DCD_CD_ACTIVITY0x0: Event is not allowed to wake up the systemRW1
0x1: Event can wake up the system
2EVENT_2_RI_ACTIVITY0x0: Event is not allowed to wake up the system.RW1
0x1: Event can wake up the system.
1EVENT_1_DSR_ACTIVITY0x0: Event is not allowed to wake up the system.RW1
0x1: Event can wake up the system.
0EVENT_0_CTS_ACTIVITY0x0: Event is not allowed to wake up the system.RW1
0x1: Event can wake up the system.
Table 24-188 UART_CFPS
Address Offset0x0000 0060
Physical Address0x4806 A060
0x4806 C060
0x4802 0060
0x4806 E060
0x4806 6060
0x4806 8060
0x4842 0060
0x4842 2060
0x4842 4060
0x4AE2 B060
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionCarrier frequency prescaler
Because the consumer IR works at modulation rates of 30 to 56.8 kHz, the 48-MHz clock must be prescaled before the clock can drive the IR logic. This register sets the divisor rate to give a range to accommodate the remote-control requirements in baud multiples of 12x. The value of the CFPS at reset is 0105 decimal, which equals 38.1 kHz output from starting conditions. The 48-MHz carrier is prescaled by the CFPS, which is then divided by the 12x baud multiple.
TypeRW
313029282726252423222120191817161514131211109876543210
RESERVEDCFPS
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0. Write has no effect.RW0x000000
7:0CFPSSystem clock frequency prescaler at (12x multiple). Examples for CFPS values:RW0x69
Target Freq (kHz)CFPS (decimal)Actual Freq (kHz)
3013330.08
32.7512232.79
3611136.04
36.710936.69
38*10538.1
4010040
56.87057.14
*configured at reset to this value
Note: CFPS = 0 is not supported.
Table 24-189 UART_RXFIFO_LVL
Address Offset0x0000 0064
Physical Address0x4806 A064
0x4806 C064
0x4802 0064
0x4806 E064
0x4806 6064
0x4806 8064
0x4842 0064
0x4842 2064
0x4842 4064
0x4AE2 B064
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionLevel of the RX FIFO
TypeR
313029282726252423222120191817161514131211109876543210
RESERVEDRXFIFO_LVL
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0.R0x000000
7:0RXFIFO_LVLShows the number of received bytes in the RX FIFOR0x00
Table 24-190 UART_TXFIFO_LVL
Address Offset0x0000 0068
Physical Address0x4806 A068
0x4806 C068
0x4802 0068
0x4806 E068
0x4806 6068
0x4806 8068
0x4842 0068
0x4842 2068
0x4842 4068
0x4AE2 B068
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionLevel of the TX FIFO
TypeR
313029282726252423222120191817161514131211109876543210
RESERVEDTXFIFO_LVL
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0.R0x000000
7:0TXFIFO_LVLShows the number of written bytes in the TX FIFOR0x00
Table 24-191 UART_IER2
Address Offset0x0000 006C
Physical Address0x4806 A06C
0x4806 C06C
0x4802 006C
0x4806 E06C
0x4806 606C
0x4806 806C
0x4842 006C
0x4842 206C
0x4842 406C
0x4AE2 B06C
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionEnables RX/TX FIFOs empty corresponding interrupts
TypeRW
313029282726252423222120191817161514131211109876543210
RESERVEDEN_TXFIFO_EMPTYEN_RXFIFO_EMPTY
BitsField NameDescriptionTypeReset
31:2RESERVEDRead returns 0. Write has no effect.RW0x0000 0000
1EN_TXFIFO_EMPTYEnables TX FIFO empty corresponding interruptRW0
0x0: Disables EN_TXFIFO_EMPTY interrupt
0x1: Enables EN_TXFIFO_EMPTY interrupt
0EN_RXFIFO_EMPTYEnables RX FIFO empty corresponding interruptRW0
0x0: Disables EN_RXFIFO_EMPTY interrupt
0x1: Enables EN_RXFIFO_EMPTY interrupt
Table 24-192 UART_ISR2
Address Offset0x0000 0070
Physical Address0x4806 A070
0x4806 C070
0x4802 0070
0x4806 E070
0x4806 6070
0x4806 8070
0x4842 0070
0x4842 2070
0x4842 4070
0x4AE2 B070
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionStatus of RX/TX FIFOs empty corresponding interrupts
TypeRW
313029282726252423222120191817161514131211109876543210
RESERVEDTXFIFO_EMPTY_STSRXFIFO_EMPTY_STS
BitsField NameDescriptionTypeReset
31:2RESERVEDRead returns 0. Write has no effect.RW0x0000 0000
1TXFIFO_EMPTY_STSUsed to generate interrupt if the TX_FIFO is empty (software flow control)RW1
0x0: TXFIFO_EMPTY interrupt not pending.
0x1: TXFIFO_EMPTY interrupt pending.
0RXFIFO_EMPTY_STSUsed to generate interrupt if the RX_FIFO is empty (software flow control)RW1
0x0: RXFIFO_EMPTY interrupt not pending.
0x1: RXFIFO_EMPTY interrupt pending.
Table 24-193 UART_FREQ_SEL
Address Offset0x0000 0074
Physical Address0x4806 A074
0x4806 C074
0x4802 0074
0x4806 E074
0x4806 6074
0x4806 8074
0x4842 0074
0x4842 2074
0x4842 4074
0x4AE2 B074
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionSample per bit selector
TypeRW
313029282726252423222120191817161514131211109876543210
RESERVEDFREQ_SEL
BitsField NameDescriptionTypeReset
31:8RESERVEDRead returns 0. Write has no effect.RW0x0000 0000
7:0FREQ_SELSets the sample per bit if nondefault frequency is used. UART_MDR3[1] must be set to 1 after this value is set. Must be equal to or higher than 6.RW0x1A
Table 24-194 UART_MDR3
Address Offset0x0000 0080
Physical Address0x4806 A080
0x4806 C080
0x4802 0080
0x4806 E080
0x4806 6080
0x4806 8080
0x4842 0080
0x4842 2080
0x4842 4080
0x4AE2 B080
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionMode definition register 3
TypeRW
313029282726252423222120191817161514131211109876543210
RESERVEDSET_DMA_TX_THRESHOLDNONDEFAULT_FREQDISABLE_CIR_RX_DEMOD
BitsField NameDescriptionTypeReset
31:3RESERVEDRead returns 0. Write has no effect.RW0x0000 0000
2SET_DMA_TX_THRESHOLDEnable to set different TXDMA threshold in UART_TX_DMA_THRESHOLD register.RW0
1NONDEFAULT_FREQUsed to enable the NONDEFAULT fclk frequencies.RW0
0x0: Disables using NONDEFAULT fclk frequencies.
0x1: Enables using NONDEFAULT fclk frequencies (set UART_FREQ_SEL and UART_DLH/UART_DLL).
0DISABLE_CIR_RX_DEMODUsed to enable CIR RX demodulation.RW0
0x0: Enables CIR RX demodulation.
0x1: Disables CIR RX demodulation.
Table 24-195 UART_TX_DMA_THRESHOLD
Address Offset0x0000 0084
Physical Address0x4806 A084
0x4806 C084
0x4802 0084
0x4806 E084
0x4806 6084
0x4806 8084
0x4842 0084
0x4842 2084
0x4842 4084
0x4AE2 B084
InstanceUART1
UART2
UART3
UART4
UART5
UART6
UART7
UART8
UART9
UART10
DescriptionUse to manually set the TX DMA threshold level.
UART_MDR3[2] SET_TX_DMA_THRESHOLD must be 1 and
must be value + tx_trigger_level = 64 (TX FIFO size).
If not, 64-tx_trigger_level will be used without modifying
the value of this register.
TypeRW
313029282726252423222120191817161514131211109876543210
RESERVEDTX_DMA_THRESHOLD
BitsField NameDescriptionTypeReset
31:6RESERVEDReservedRW0x0000000
5:0TX_DMA_THRESHOLDUsed to manually set the TX DMA threshold levelRW0x00