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The write buffer and fill buffer support a drain operation, such that before the next
instruction executes, all Intel XScale processor data requests to external memory have
completed. See
Writes to a region marked non-cacheable/non-bufferable (page attributes C, B, and X
all 0) will cause execution to stall until the write completes.
If software is running in a privileged mode, it can explicitly drain all buffered writes. For
details on this operation, see the description of Drain Write Buffer in
Functions" on page
3.5
Configuration
This section describes the System Control Coprocessor (CP15) and coprocessor 14
(CP14). CP15 configures the MMU, caches, buffers and other system attributes. Where
possible, the definition of CP15 follows the definition of the Intel
products. CP14 contains the performance monitor registers, clock and power
management registers and the debug registers.
CP15 is accessed through MRC and MCR coprocessor instructions and allowed only in
privileged mode. Any access to CP15 in user mode or with LDC or STC coprocessor
instructions will cause an undefined instruction exception.
All CP14 registers can be accessed through MRC and MCR coprocessor instructions.
LDC and STC coprocessor instructions can only access the clock and power
management registers, and the debug registers. The performance monitoring registers
can't be accessed by LDC and STC because CRm != 0x0. Access to all registers is
allowed only in privileged mode. Any access to CP14 in user mode will cause an
undefined instruction exception.
Coprocessors, CP15 and CP14, on the Intel XScale processor do not support access via
CDP, MRRC, or MCRR instructions. An attempt to access these coprocessors with
these instructions will result in an Undefined Instruction exception.
Many of the MCR commands available in CP15 modify hardware state sometime after
execution. A software sequence is available for those wishing to determine when this
update occurs and can be found in
Like certain other Intel
includes an extra level of virtual address translation in the form of a PID (Process ID)
register and associated logic. For a detailed description of this facility, see
Process ID" on page
when interacting with CP15, some addresses are modified by the PID and others are
not.
An address that has yet to be modified by the PID ("PIDified") is known as a virtual
address (VA). An address that has been through the PID logic, but not translated into a
physical address, is a modified virtual address (MVA). Non-privileged code always deals
with VAs, while privileged code that programs CP15 occasionally needs to use MVAs.
The format of MRC and MCR is shown in
cp_num is defined for CP15, CP14 and CP0 on the Intel XScale processor. CP0 supports
instructions specific for DSP and is described in
Unless otherwise noted, unused bits in coprocessor registers have unpredictable values
when read. For compatibility with future implementations, software should not rely on
the values in those bits.
®
®
Intel
IXP45X and Intel
IXP46X Product Line of Network Processors
Developer's Manual
96
®
®
IXP45X and Intel
IXP46X Product Line of Network Processors—Intel XScale
Table 20, "Cache Functions" on page 104
103.
®
StrongARM
106. Privileged code needs to be aware of this facility because,
"Additions to CP15 Functionality" on page
*
architecture products, the Intel XScale processor
Table
9.
"Programming Model" on page 167
®
Processor
for the exact command.
"Register 7: Cache
®
*
StrongARM
176.
"Register 13:
August 2006
Order Number: 306262-004US
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