PXN20RM Datasheet, PDF(422/1376 Page) Freescale Semiconductor, Inc – PXN20 Microcontroller

English

English German Russian Spanish Italian Polish Chinese Japanese Korean French Portuguese	Language :

PXN20RM Datasheet, PDF (422/1376 Pages) Freescale Semiconductor, Inc – PXN20 Microcontroller

◁

Semaphores

Table 15-6. SEMA4_RSTGT Field Descriptions

Field

Description

RSTNSM

Reset Notification Finite State Machine. The reset state machine is maintained in a 2-bit, three-state

implementation, defined as:

00 Idle, waiting for the first data pattern write.

01 Waiting for the second data pattern write.

10 The two-write sequence has completed. Generate the specified notification reset(s). After the reset is

performed, this machine returns to the idle (waiting for first data pattern write) state.

11 This state encoding is never used and therefore reserved.

Reads of the SEMA4_RSTNTF register return the encoded state machine value. Note the RSTNSM = 0b10 state

is valid for a single machine cycle only, so it is impossible for a read to return this value.

RSTNMS

Reset Notification Bus Master. This 3-bit read-only field records the logical number of the bus master performing

the notification reset function. The reset function requires that the two consecutive writes to this register be

initiated by the same bus master to succeed. This field is updated each time a write to this register occurs.

Master

e200z6

e200z0

eDMA

â

FEC

MLB

FlexRAY

â

Master ID

0

1

2

3

4

5

6

7

RSTNTN

RSTNDP

Reset Notification Number. This 8-bit field specifies the specific IRQ notification state machine to be reset. This

field is updated by the second write.

If RSTNTN < 64, then reset the single IRQ notification machine defined by RSTNTN, else reset all the

notifications.

Reset Notification Data Pattern. This write-only field is accessed with the specified data patterns on the two

consecutive writes to enable the notification reset mechanism. For the first write, RSTNDP = 0x47 while the

second write requires RSTNDP = 0xb8.

15.4 Functional Description

Multi-processor systems require a function that can be used to safely and easily provide a locking

mechanism that is then used by system software to control access to shared data structures, shared

hardware resources, and etc. These gating mechanisms are used by the software to serialize (and

synchronize) writes to shared data and/or resources to prevent race conditions and preserve memory

coherency between processes and processors.

For example, if processor X enters a section of code where shared data values are to be updated or read

coherently, it must first acquire a semaphore. This locks, or closes, a software gate. After the gate has been

locked, a properly architected software system does not allow other processes (or processors) to execute

the same code segment or modify the shared data structure protected by the gate, that is, other

15-10

PXN20 Microcontroller Reference Manual, Rev. 1

Freescale Semiconductor

▷