Abstract: Methods and apparatuses relating to hardware processors with multiple interconnected dies are described. In one embodiment, a hardware processor includes a plurality of physically separate dies, and an interconnect to electrically couple the plurality of physically separate dies together. In another embodiment, a method to create a hardware processor includes providing a plurality of physically separate dies, and electrically coupling the plurality of physically separate dies together with an interconnect.

Abstract: An interface adapter to identify a first ready signal from a first link layer-to-physical layer (LL-PHY) interface of a first communication protocol indicating readiness of a physical layer of the first protocol to accept link layer data. The interface adapter generates a second ready signal compatible with a second LL-PHY interface of a second communication protocol to cause link layer data to be sent from a link layer of the second communication protocol according to a predefined delay. A third ready signal is generated compatible with the first LL-PHY interface to indicate to the physical layer of the first communication protocol that the link layer data is to be sent. The interface adapter uses a shift register to cause the link layer data to be passed to the physical layer according to the predefined delay.

Abstract: A supersequence is sent to another device to indicate a transition from a partial width link state to another active link state. The supersequence is to be sent over one or more lanes of a link and is to include at least a portion of a start of data sequence (SDS) to include a predefined sequence and a byte number value. The byte number value is to indicate a number of bytes measured from a preceding control interval.

Abstract: An exit pattern is sent to initiate exit from a partial width state, where only a portion of the available lanes of a link are used to transmit data and the remaining lanes are idle. The exit pattern is sent on the idle lanes, the exit pattern including an electrical ordered set (EOS), one or more fast training sequences (FTS), a start of data sequence (SDS), and a partial fast training sequence (FTSp). The SDS includes a byte number field to indicate a number of a bytes measured from a previous control interval of the link, and an end of the SDS is sent to coincide with a clean flit boundary on the active lanes. The partial width state is exited based on the exit pattern and data is sent on all available lanes following the exit from the partial width state.

Abstract: A signal is received, a boundary of which is to be sent in alignment with a sync counter value. A nominal latency of a link is determined based on the sync counter value. Additional latency is applied to the signal to increase the nominal latency to a target latency for the link.

Abstract: A supersequence is sent to another device to indicate a transition from a partial width link state to another active link state. The supersequence is to be sent over one or more lanes of a link and is to include at least a portion of a start of data sequence (SDS) to include a predefined sequence and a byte number value. The byte number value is to indicate a number of bytes measured from a preceding control interval.