草榴社区

草榴社区 1.6T Ethernet MAC IP

The 草榴社区 1.6T Ethernet MAC IP implements the functions required by the IEEE 802.3-2018 specification to communicate over Ethernet providing a simple frame-based interface to the system and a standardized interface to the PCS (Physical Control Block).

The 草榴社区 IP is split into four 400Gbps channels which can be configured via software-controllable registers to operate together to support higher data rates. The MAC supports the following data-rates:

  • 400 Gbps with up to four independent ports active simultaneously
  • 800 Gbps with up to two 800 Gbps ports or one 800 Gbps and two 400Gbps ports active simultaneously
  • 1600 Gbps as a single port

The application interface is a FIFO-based interface with four channels capable of transferring up to 4x512-bits of frame data per clock cycle and per direction. The PCS interface consists of four channels 320-bit wide each, encoded according to IEEE 802.3 Clause 117 (400GMII) and clock-synchronous to the corresponding PCS interfaces. The rate is controlled via per-channel PCS-driven data-enable signals for both transmit and receive directions.

The 草榴社区 1.6T Ethernet MAC IP seamlessly interoperates with 草榴社区 1.6T Ethernet PCS IP and 草榴社区 224G Ethernet PHY IP to provide a complete Ethernet MAC, PCS and PHY solution for 1.6T systems.

草榴社区 1.6T Ethernet MAC IP

 

Highlights
Features
  • Supports all required features of the IEEE 802.3 specification
  • Supports IEEE-managed objects, IETF MIB-II and RMON for management applications
  • Application interface includes the 草榴社区 native interface 512-bit or 1024bit FIFO for more than 200G operation
  • Integration tested with 草榴社区 1.6T Ethernet PCS IP and 224G Ethernet PHY IP
  • Supports IEEE 1588 applications
  • Full MAC layer and reconciliation sublayer implementation compliant with the IEEE 802.3 specification.
  • Up to four individual ports supporting full-duplex operation at 400Gbps, 800Gbps and 1600Gbps, with a maximum combined data-rate of 1600Gbps.
  • IEEE 802.3 Clause 117 compliant 400GMII PCS interface with optional PCS-driven data-rate control.
  • FIFO-based transmit application interface with simple level-based backpressure or accurate credit-based utilization.
  • FIFO-based receive application interface with system backpressure support for fatal events resulting in immediate discard of received frames without compromising the interface.
  • Protocol errors-resistant transmit application interface providing graceful recovery if a system error results in errors that compromise frame delimitation or causing the transmit buffer to overflow.
  • Support for optional ECC or parity errors indication in both transmit and receive buffers (memories) that results in frame erroring.
  • Fault detection and response as specified in Clause 81 of IEEE 802.3, supporting Local Faults, Remote Faults and Link Interrupt ordered set decoding and generation.
  • Provision for Clause 78 of IEEE 802.3 (Energy Efficient Ethernet, amendment IEEE 802.3az) support and Low Power Idle (LPI) generation and detection.
  • Transmit and receive per-frame statistics compliant with IEEE 802.3 and RFC 2819 and RFC 3635.
  • Per-frame transmit and receive timestamp capture.
  • Preamble, SFD and other framing characters insertion for transmitted frames, and check and removal deletion for received frames.
  • IPG (Inter-Packet Gap) adjustment for rate compensation when using MACSEC engines.
  • Frame FCS field checking and optional removal for received frames using CRC-32.
  • Padding insertion for frames that are less than 64-bytes as transmitted from the application interface to the 草榴社区 1.6T MAC IP.
  • Optional Link Pause (IEEE 802.3 Annex 31B) and Priority Flow Control (IEEE 802.3 Annex 31D) frame generation and decoding with internal timers and programmable “Xoff” time duration.
  • Optional support for frame modifications to support 1-step operation as defined in IEEE 802.3AS and IEEE 1588.
  • Optional asynchronous system interface for easy decoupling of the MAC+PCS clock domain to the application clock-domain.
  • Optional application-generated frame preamble and SFD for transmitted frames, and forwarding of frame’s preamble and SFD to the application for received frames.
  • Generic host interface allowing direct access to all configuration and status registers.