GDDR6 Controller IIP

• Supports GDDR6 protocol standard JESD250, JESD250A, JESD250B with version 3.11, JESD250C and JESD250D specification
• Compliant with DFI-version 4.0 or 5.0, 5.1 Specification
• Supports all the GDDR6 commands as per the specs
• Supports up to 16 AXI ports with data width up to 512 bits
• Supports controllable outstanding transactions for AXI write and read channels
• Supports in port arbitration and multi port arbitration
• Supports user programmable page policy
• Closed page policy
• Open page policy
• Supports high clock speeds in ASIC and FPGA
• Supports low latency for write and read path
• Supports reordering of transactions for higher performance
• Supports 2 separate independent channels with point-to-point interface for data, address and command
• Supports Double Data Rate (DDR) or Quad Data Rate (QDR) data
• Supports Pseudo channel mode operation
• Supports up to 32GB device density
• Supports the following device types
• X8
• X16
• Supports Programmable READ/WRITE latency
• Supports Bank grouping and 16 internal banks per channel
• Supports Data bus inversion (DBI) & Command Address bus inversion (CABI)
• Supports Read/Write data transmission integrity secured by cyclic redundancy check
• Supports Input/output PLL/DLL on/off mode
• Supports READ/WRITE EDC on/off mode
• Supports WRITE Data mask function (single/double byte mask)
• Supports Programmable EDC hold pattern for CDR
• Supports Programmable CRC READ/WRITE latency
• Supports Low Power modes
• Supports Refresh Management (RFM)
• Supports Auto refresh & self-refresh modes
• Supports On-die termination operation
• Supports Vendor ID1 and ID2 for identification
• Supports COMMAND ADDRESS, WCK2CK,READ/WRITE Training mode’s
• Supports IEEE.1149.1 boundary scan operation
• Supports programmable clock frequency of operation
• Supports power down features
• Supports input clock stop and frequency change
• Fully synthesizable
• Static synchronous design
• Positive edge clocking and no internal tri-states
• Scan test ready
• Simple host interfaces enable straightforward integration with microcontrollers and application processors

CORE: Core module interconnects all the sub-modules in the GDDR6 Controller IP. Ports of core module are the top level ports for the GDDR6 Controller IP.

ARBITER: Arbiter module implements arbitration for multi-channel and between same channels write and read. This module will get inputs from SoC data interface and process to write data FIFO, Read data FIFO and Command FIFO.

WRITE DATA FIFO: Write data fifo stores the write data in write operation which is coming from soc data interface.

READ DATA FIFO: Read data fifo stores the read data in read operation which is coming from dfi interface.

COMMAND FIFO: Command fifo stores the write/read commands or address related information.

GDDR6 CONTROLLER FSM:

This block consists of several sub modules listed below:

COMMAND FIFO PROCESSOR: Command fifo processor reads the command fifo data, decodes command fifo data and issues commands to FSM. Also pushes length to read response fifo which will be used in read operation.

ATIMER: Activate timer module is used to implement timers for maximum active time of a particular bank. For every write and read related operations the bank must be activate before processing those commands. This module gets bank and activate information from the FSM module and maximum bank activate time is decided by refresh requirement, configured from csr module. Based on this, It will close the activated banks.

FSM: GDDR6 Controller FSM starts to process once the commands are received from Command FIFO processor and CSR Modules. Based on the received commands, the GDDR6 Controller FSM process Activate, Write, Read, Mode Register operations.

The functionalities of the GDDR6 Controller FSM module include:

• Initialization Process
• Handling Memory Read/Write/Mask write
• Handling Mode Register Read/Write
• Activate and Precharge operations
• Self-Refresh and Power Down Modes
• Refresh Operations

COMMAND DRIVER: Command driver block gets chip and address from FSM module, this block also implements latency logic. Once latencies are satisfied cs and address will be driven to DFI. Command driver block generates write enable to data driver, read enable to data receiver in respective operations.

DATA DRIVER: Data driver module gets write enable and encoded write command value information from the command driver module. The data driver module collects data from the Write data FIFO. This module gets latency information from the CSR module. Once latency is satisfied, this module drives write data to dfi write data interface.

DATA RECEIVER: Data receiver module gets read enable and encoded read command value information from the command driver module. This module gets latency information from the CSR module. Once latency is satisfied, this module drives read enable after data latency the module samples read data from dfi read data interface when corresponding valid is high. Once entire burst of the data are sampled the data are sent to the Read data FIFO.

CSR: CSR Module has all the mode registers and timer configuration registers. The contents of the registers are decoded and assigned to its respective output ports based on its functionality. The registers can get its data from both the internal and external system interface.

• Single Site license for regional development teams.
• Multi-Site license for global corporate deployments.
• Single Design license for specific project cost-efficiency.
• Unlimited Design license for high-volume product roadmaps.

• Complete Verilog/VHDL/SystemC Source Code.
• UVM-compliant verification environment with a comprehensive test suite.
• Production-ready synthesis, Lint, and CDC scripts.
• IP-XACT RDL generated address maps.
• Standard-compliant firmware and Linux/C driver packages.
• Detailed documentation: User Guides, Release Notes, and ISO 26262 Safety Manual (SAM)/FMEDA.