MicroBlaze Processor Reference Guide
55
UG081 (v14.7)
Virtual-Memory Management
Virtual-Memory Management
Programs running on MicroBlaze use effective addresses to access a flat 4 GB address space. The
processor can interpret this address space in one of two ways, depending on the translation mode:
•
In real mode, effective addresses are used to directly access physical memory
•
In virtual mode, effective addresses are translated into physical addresses by the virtual-
memory management hardware in the processor
Virtual mode provides system software with the ability to relocate programs and data anywhere in
the physical address space. System software can move inactive programs and data out of physical
memory when space is required by active programs and data.
Relocation can make it appear to a program that more memory exists than is actually implemented
by the system. This frees the programmer from working within the limits imposed by the amount of
physical memory present in a system. Programmers do not need to know which physical-memory
addresses are assigned to other software processes and hardware devices. The addresses visible to
programs are translated into the appropriate physical addresses by the processor.
Virtual mode provides greater control over memory protection. Blocks of memory as small as 1 KB
can be individually protected from unauthorized access. Protection and relocation enable system
software to support multitasking. This capability gives the appearance of simultaneous or near-
simultaneous execution of multiple programs.
In MicroBlaze, virtual mode is implemented by the memory-management unit (MMU), available
when
C_USE_MMU
is set to 3 (Virtual) and
C_AREA_OPTIMIZED
is set to 0. The MMU controls
effective-address to physical-address mapping and supports memory protection. Using these
capabilities, system software can implement demand-paged virtual memory and other memory
management schemes.
The MicroBlaze MMU implementation is based upon PowerPC™ 405. For details, see the
PowerPC Processor Reference Guide (UG011)
document.
The MMU features are summarized as follows:
•
Translates effective addresses into physical addresses
•
Controls page-level access during address translation
•
Provides additional virtual-mode protection control through the use of zones
•
Provides independent control over instruction-address and data-address translation and
protection
•
Supports eight page sizes: 1 kB, 4 kB, 16 kB, 64 kB, 256 kB, 1 MB, 4 MB, and 16 MB. Any
combination of page sizes can be used by system software
•
Software controls the page-replacement strategy
Real Mode
The processor references memory when it fetches an instruction and when it accesses data with a
load or store instruction. Programs reference memory locations using a 32-bit effective address
calculated by the processor. When real mode is enabled, the physical address is identical to the
effective address and the processor uses it to access physical memory. After a processor reset, the
processor operates in real mode. Real mode can also be enabled by clearing the VM bit in the MSR.
Physical-memory data accesses (loads and stores) are performed in real mode using the effective
address. Real mode does not provide system software with virtual address translation, but the full
memory access-protection is available, implemented when
C_USE_MMU
> 1 (User Mode) and
C_AREA_OPTIMIZED
= 0. Implementation of a real-mode memory manager is more
Содержание MicroBlaze
Страница 1: ...MicroBlaze Processor Reference Guide Embedded Development Kit EDK 14 7 UG081 v14 7...
Страница 4: ...MicroBlaze Processor Reference Guide www xilinx com UG081 v14 7...
Страница 8: ...8 www xilinx com MicroBlaze Processor Reference Guide UG081 v14 7 Chapter 1 Introduction Send Feedback...
Страница 262: ...262 www xilinx com MicroBlaze Processor Reference Guide UG081 v14 7 Send Feedback...