NXP Semiconductors KE1xF Series, Справочное руководство

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Chapter 10
Crossbar Integrity Checker (XBIC)
10.1 Chip-specific XBIC information
This chip has one instance of the XBIC module.
10.1.1 XBIC master and slave assignments
The XBIC identifies each XBAR master and slave in terms of the master or slave's
physical port number. See the "Physical master port" assignments in Table 9-1 and the
"Slave port" assignments in Table 9-2 .
10.1.2 Unimplemented MCR and ESR fields
10.2 Overview
Sample Reference Manual
Chapter 9
Crossbar Switch (XBAR)
9.1 Chip-specific XBAR information
This chip has one instance of the XBAR module.
9.1.1 XBAR master and slave assignments
The following table lists the XBAR physical port numbers and logical IDs for all master
ports on this SoC.
• Each port number matches the default priority assigned to the corresponding physical
master port. This default priority equals the reset value of the priority field for each
master port in the PRS n registers.
• A priority value of 0 is the highest priority. There is no "disabled" value for the
priority.
• A Nexus_3 module and core data bus share the same physical master port for each
core.
The logical master ID corresponds to the logical address provided by the master module
and is unique for each module. The logical master IDs are used by the bus masters
connected to the XBAR. The Nexus master is identified by setting the MSB in the 4-bit
field that supplies the master ID number.
Table 9-1. XBAR master ports and logical master IDs
Module Physical master port Logical master ID Comment
Core0 instruction 0 0
Core0 data 1 0
Nexus_3_0 8 Nexus_3_0 arbitrates with Core0 data for XBAR port 1
Core1 instruction 2 1
Core1 data 3 1
Nexus_3_1 9 Nexus_3_1 arbitrates with Core1 data for XBAR port 3
Table continues on the next page...
Sample Reference Manual
The Crossbar Integrity Checker (XBIC) verifies the integrity of the crossbar transfers.
For forward signals (master to slave), it is done by verifying the integrity of the attribute
information using an 8-bit Error Detection Code (EDC). The EDC detects any single- or
double-bit errors in the attribute information and signals the Fault Collection and Control
Unit (FCCU) when an error is detected. For feedback signals (slave to master), it is done
by comparing the consistency of the signals during the AHB dataphase.There are three
signals from slave to master, hready, hresp0, and hresp2. If any of the master signals is
different from the slave signals during dataphase, the error will be reported in the Error
Status Register.
On this chip, the MCR[SE5] and ESR[DPSE5] fields are not implemented. In XBIC
Module Control Register (XBIC_MCR) and XBIC Error Status Register (XBIC_ESR) ,
these fields are reserved.
EXAMPLE
Figure 1-3. Example: chip-specific information that refers to a different chapter
1.4 Register descriptions
Module chapters present register information in:
• Memory maps including:
• Addresses
• The name and acronym/abbreviation of each register
• The width of each register (in bits)
• Each register's reset value
• The page number on which each register is described
• Register figures
• Field-description tables
• Associated text
The register figures show the field structure using the conventions in the following figure.
Register descriptions
Kinetis KE1xF Sub-Family Reference Manual, Rev. 4, 06/2019
50 NXP Semiconductors