Multiprocessor Support

Multiprocessor Support

The MVME166 dual-port RAM feature makes the shared RAM available to remote processors as well as to the local processor. This can be done by either of the following two methods. Either method can be enabled/disabled by the ENV command as its Remote Start Switch Method (refer to Appendix A).

3

Multiprocessor Control Register (MPCR) Method

A remote processor can initiate program execution in the local MVME166 dual-port RAM by issuing a remote GO command using the Multiprocessor Control Register (MPCR). The MPCR, located at shared RAM location of $800 offset from the base address the debugger loads it at, contains one of two longwords used to control communication between processors. The MPCR contents are organized as follows:

$800

*

N/A N/A N/A (MPCR)

The status codes stored in the MPCR are of two types:

Status returned (from the monitor)

Status set (by the bus master)

The status codes that may be returned from the monitor are:

HEX

0

(HEX 00)

--

Wait. Initialization not yet complete.

ASCII

E

(HEX 45)

--

Code pointed to by the MPAR address is executing.

ASCII

P

(HEX 50)

--

Program Flash Memory. The MPAR is set to the

 

 

 

 

address of the Flash memory program control packet.

ASCII

R

(HEX 52)

--

Ready. The firmware monitor is watching for a change.

You can only program Flash memory by the MPCR method. Refer to the

.PFLASH system call in the Debugging Package for Motorola 68K CISC CPUs User’s Manual for a description of the Flash memory program control packet structure.

The status codes that may be set by the bus master are:

ASCII

G

(HEX 47)

--

Use Go Direct (GD) logic specifying the MPAR address.

ASCII

B

(HEX 42)

--

Install breakpoints using the Go (G) logic.

MVME166IG/D2

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Motorola MVME166IG/D2 manual Multiprocessor Support, Multiprocessor Control Register Mpcr Method

MVME166IG/D2 specifications

The Motorola MVME166IG/D2 is a pioneering embedded computer designed for high-performance applications in industrial and telecom sectors. This versatile computing platform is based on the PowerPC architecture, which ensures efficient processing capabilities and transfer of data, making it suitable for a wide range of applications, including real-time control, data acquisition, and system monitoring.

One of the main features of the MVME166IG/D2 is its powerful processor. The system is equipped with a PowerPC 603e processor, which offers a remarkable performance rate with a clock speed of up to 250 MHz. This high-speed processing capability allows for rapid data handling and processing, which is critical for demanding applications in real-time environments.

The MVME166IG/D2 also stands out due to its modular design. It supports multiple expansion slots that make it adaptable for different user needs. The system can accommodate additional cards or memory modules, allowing for increased versatility and capability in various operational scenarios.

In terms of connectivity, this embedded computer includes multiple communication interfaces such as Ethernet and serial ports, which facilitate seamless data transfer and communication within larger systems. This connectivity is crucial for integrating the device into existing industrial networks or for connecting with sensors and other equipment.

Another noteworthy characteristic of the MVME166IG/D2 is its robust build quality, which is essential for operation in challenging environments. The device is designed to endure high levels of shock and vibration, making it suitable for deployment in applications such as transportation or heavy machinery.

Additionally, the MVME166IG/D2 offers a range of software support which includes various real-time operating systems. This compatibility allows developers to choose the OS that best fits their application's requirements, enhancing the overall utility of the system.

In summary, the Motorola MVME166IG/D2 is a powerful, flexible embedded computing solution that excels in performance, modularity, and reliability. Its advanced features and durable design make it an ideal choice for industries that require precision, speed, and robustness in their computing solutions.