arduino-esp32/tools/sdk/include/esp32/xtensa/cacheasm.h
Me No Dev a59eafbc9d
Update IDF to aaf1239 (#1539)
* fix sdmmc config

* Fix warnings in EEPROM

from @Curclamas

* remove leftover TAG in EEPROM

* Initial add of @stickbreaker i2c

* Add log_n

* fix warnings when log is off

* i2c code clean up and reorganization

* add flags to interrupt allocator

* fix sdmmc config

* Fix warnings in EEPROM

from @Curclamas

* remove leftover TAG in EEPROM

* fix errors with latest IDF

* fix debug optimization (#1365)

incorrect optimization for debugging tick markers.

* Fix some missing BT header

* Change BTSerial log calls

* Update BLE lib

* Arduino-ESP32 release management scripted (#1515)

* Calculate an absolute path for a custom partitions table (#1452)

* * Arduino-ESP32 release management scripted
(ready-to-merge)

* * secure env for espressif/arduino-esp32

* * build tests enabled
* gitter webhook enabled

* * gitter room link fixed
* better comment

* * filepaths fixed

* BT Serial adjustments

* * don't run sketch builds & tests for tagged builds

* Return false from WiFi.hostByName() if hostname is not resolved

* Free BT Memory when BT is not used

* WIFI_MODE_NULL is not supported anymore

* Select some key examples to build with PlatformIO to save some time

* Update BLE lib

* Fixed BLE lib

* Major WiFi overhaul

- auto reconnect on connection loss now works
- moved to event groups
- some code clean up and procedure optimizations
- new methods to get a more elaborate system ststus

* Add cmake tests to travis

* Add initial AsyncUDP

* Add NetBIOS lib and fix CMake includes

* Add Initial WebServer

* Fix WebServer and examples

* travis not quiting on build fail

* Try different travis build

* Update IDF to aaf1239

* Fix WPS Example

* fix script permission and add some fail tests to sketch builder

* Add missing space in WiFiClient::write(Stream &stream)
2018-06-27 09:01:06 +02:00

963 lines
28 KiB
C

/*
* xtensa/cacheasm.h -- assembler-specific cache related definitions
* that depend on CORE configuration
*
* This file is logically part of xtensa/coreasm.h ,
* but is kept separate for modularity / compilation-performance.
*/
/*
* Copyright (c) 2001-2014 Cadence Design Systems, Inc.
*
* Permission is hereby granted, free of charge, to any person obtaining
* a copy of this software and associated documentation files (the
* "Software"), to deal in the Software without restriction, including
* without limitation the rights to use, copy, modify, merge, publish,
* distribute, sublicense, and/or sell copies of the Software, and to
* permit persons to whom the Software is furnished to do so, subject to
* the following conditions:
*
* The above copyright notice and this permission notice shall be included
* in all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
* IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY
* CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT,
* TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE
* SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#ifndef XTENSA_CACHEASM_H
#define XTENSA_CACHEASM_H
#include <xtensa/coreasm.h>
#include <xtensa/corebits.h>
#include <xtensa/xtensa-xer.h>
#include <xtensa/xtensa-versions.h>
/*
* This header file defines assembler macros of the form:
* <x>cache_<func>
* where <x> is 'i' or 'd' for instruction and data caches,
* and <func> indicates the function of the macro.
*
* The following functions <func> are defined,
* and apply only to the specified cache (I or D):
*
* reset
* Resets the cache.
*
* sync
* Makes sure any previous cache instructions have been completed;
* ie. makes sure any previous cache control operations
* have had full effect and been synchronized to memory.
* Eg. any invalidate completed [so as not to generate a hit],
* any writebacks or other pipelined writes written to memory, etc.
*
* invalidate_line (single cache line)
* invalidate_region (specified memory range)
* invalidate_all (entire cache)
* Invalidates all cache entries that cache
* data from the specified memory range.
* NOTE: locked entries are not invalidated.
*
* writeback_line (single cache line)
* writeback_region (specified memory range)
* writeback_all (entire cache)
* Writes back to memory all dirty cache entries
* that cache data from the specified memory range,
* and marks these entries as clean.
* NOTE: on some future implementations, this might
* also invalidate.
* NOTE: locked entries are written back, but never invalidated.
* NOTE: instruction caches never implement writeback.
*
* writeback_inv_line (single cache line)
* writeback_inv_region (specified memory range)
* writeback_inv_all (entire cache)
* Writes back to memory all dirty cache entries
* that cache data from the specified memory range,
* and invalidates these entries (including all clean
* cache entries that cache data from that range).
* NOTE: locked entries are written back but not invalidated.
* NOTE: instruction caches never implement writeback.
*
* lock_line (single cache line)
* lock_region (specified memory range)
* Prefetch and lock the specified memory range into cache.
* NOTE: if any part of the specified memory range cannot
* be locked, a Load/Store Error (for dcache) or Instruction
* Fetch Error (for icache) exception occurs. These macros don't
* do anything special (yet anyway) to handle this situation.
*
* unlock_line (single cache line)
* unlock_region (specified memory range)
* unlock_all (entire cache)
* Unlock cache entries that cache the specified memory range.
* Entries not already locked are unaffected.
*
* coherence_on
* coherence_off
* Turn off and on cache coherence
*
*/
/*************************** GENERIC -- ALL CACHES ***************************/
/*
* The following macros assume the following cache size/parameter limits
* in the current Xtensa core implementation:
* cache size: 1024 bytes minimum
* line size: 16 - 64 bytes
* way count: 1 - 4
*
* Minimum entries per way (ie. per associativity) = 1024 / 64 / 4 = 4
* Hence the assumption that each loop can execute four cache instructions.
*
* Correspondingly, the offset range of instructions is assumed able to cover
* four lines, ie. offsets {0,1,2,3} * line_size are assumed valid for
* both hit and indexed cache instructions. Ie. these offsets are all
* valid: 0, 16, 32, 48, 64, 96, 128, 192 (for line sizes 16, 32, 64).
* This is true of all original cache instructions
* (dhi, ihi, dhwb, dhwbi, dii, iii) which have offsets
* of 0 to 1020 in multiples of 4 (ie. 8 bits shifted by 2).
* This is also true of subsequent cache instructions
* (dhu, ihu, diu, iiu, diwb, diwbi, dpfl, ipfl) which have offsets
* of 0 to 240 in multiples of 16 (ie. 4 bits shifted by 4).
*
* (Maximum cache size, currently 32k, doesn't affect the following macros.
* Cache ways > MMU min page size cause aliasing but that's another matter.)
*/
/*
* Macro to apply an 'indexed' cache instruction to the entire cache.
*
* Parameters:
* cainst instruction/ that takes an address register parameter
* and an offset parameter (in range 0 .. 3*linesize).
* size size of cache in bytes
* linesize size of cache line in bytes (always power-of-2)
* assoc_or1 number of associativities (ways/sets) in cache
* if all sets affected by cainst,
* or 1 if only one set (or not all sets) of the cache
* is affected by cainst (eg. DIWB or DIWBI [not yet ISA defined]).
* aa, ab unique address registers (temporaries).
* awb set to other than a0 if wb type of instruction
* loopokay 1 allows use of zero-overhead loops, 0 does not
* immrange range (max value) of cainst's immediate offset parameter, in bytes
* (NOTE: macro assumes immrange allows power-of-2 number of lines)
*/
.macro cache_index_all cainst, size, linesize, assoc_or1, aa, ab, loopokay, maxofs, awb=a0
// Number of indices in cache (lines per way):
.set .Lindices, (\size / (\linesize * \assoc_or1))
// Number of indices processed per loop iteration (max 4):
.set .Lperloop, .Lindices
.ifgt .Lperloop - 4
.set .Lperloop, 4
.endif
// Also limit instructions per loop if cache line size exceeds immediate range:
.set .Lmaxperloop, (\maxofs / \linesize) + 1
.ifgt .Lperloop - .Lmaxperloop
.set .Lperloop, .Lmaxperloop
.endif
// Avoid addi of 128 which takes two instructions (addmi,addi):
.ifeq .Lperloop*\linesize - 128
.ifgt .Lperloop - 1
.set .Lperloop, .Lperloop / 2
.endif
.endif
// \size byte cache, \linesize byte lines, \assoc_or1 way(s) affected by each \cainst.
// XCHAL_ERRATUM_497 - don't execute using loop, to reduce the amount of added code
.ifne (\loopokay & XCHAL_HAVE_LOOPS && !XCHAL_ERRATUM_497)
movi \aa, .Lindices / .Lperloop // number of loop iterations
// Possible improvement: need only loop if \aa > 1 ;
// however \aa == 1 is highly unlikely.
movi \ab, 0 // to iterate over cache
loop \aa, .Lend_cachex\@
.set .Li, 0 ; .rept .Lperloop
\cainst \ab, .Li*\linesize
.set .Li, .Li+1 ; .endr
addi \ab, \ab, .Lperloop*\linesize // move to next line
.Lend_cachex\@:
.else
movi \aa, (\size / \assoc_or1)
// Possible improvement: need only loop if \aa > 1 ;
// however \aa == 1 is highly unlikely.
movi \ab, 0 // to iterate over cache
.ifne ((\awb !=a0) & XCHAL_ERRATUM_497) // don't use awb if set to a0
movi \awb, 0
.endif
.Lstart_cachex\@:
.set .Li, 0 ; .rept .Lperloop
\cainst \ab, .Li*\linesize
.set .Li, .Li+1 ; .endr
.ifne ((\awb !=a0) & XCHAL_ERRATUM_497) // do memw after 8 cainst wb instructions
addi \awb, \awb, .Lperloop
blti \awb, 8, .Lstart_memw\@
memw
movi \awb, 0
.Lstart_memw\@:
.endif
addi \ab, \ab, .Lperloop*\linesize // move to next line
bltu \ab, \aa, .Lstart_cachex\@
.endif
.endm
/*
* Macro to apply a 'hit' cache instruction to a memory region,
* ie. to any cache entries that cache a specified portion (region) of memory.
* Takes care of the unaligned cases, ie. may apply to one
* more cache line than $asize / lineSize if $aaddr is not aligned.
*
*
* Parameters are:
* cainst instruction/macro that takes an address register parameter
* and an offset parameter (currently always zero)
* and generates a cache instruction (eg. "dhi", "dhwb", "ihi", etc.)
* linesize_log2 log2(size of cache line in bytes)
* addr register containing start address of region (clobbered)
* asize register containing size of the region in bytes (clobbered)
* askew unique register used as temporary
* awb unique register used as temporary for erratum 497.
*
* Note: A possible optimization to this macro is to apply the operation
* to the entire cache if the region exceeds the size of the cache
* by some empirically determined amount or factor. Some experimentation
* is required to determine the appropriate factors, which also need
* to be tunable if required.
*/
.macro cache_hit_region cainst, linesize_log2, addr, asize, askew, awb=a0
// Make \asize the number of iterations:
extui \askew, \addr, 0, \linesize_log2 // get unalignment amount of \addr
add \asize, \asize, \askew // ... and add it to \asize
addi \asize, \asize, (1 << \linesize_log2) - 1 // round up!
srli \asize, \asize, \linesize_log2
// Iterate over region:
.ifne ((\awb !=a0) & XCHAL_ERRATUM_497) // don't use awb if set to a0
movi \awb, 0
.endif
floopnez \asize, cacheh\@
\cainst \addr, 0
.ifne ((\awb !=a0) & XCHAL_ERRATUM_497) // do memw after 8 cainst wb instructions
addi \awb, \awb, 1
blti \awb, 8, .Lstart_memw\@
memw
movi \awb, 0
.Lstart_memw\@:
.endif
addi \addr, \addr, (1 << \linesize_log2) // move to next line
floopend \asize, cacheh\@
.endm
/*************************** INSTRUCTION CACHE ***************************/
/*
* Reset/initialize the instruction cache by simply invalidating it:
* (need to unlock first also, if cache locking implemented):
*
* Parameters:
* aa, ab unique address registers (temporaries)
*/
.macro icache_reset aa, ab, loopokay=0
icache_unlock_all \aa, \ab, \loopokay
icache_invalidate_all \aa, \ab, \loopokay
.endm
/*
* Synchronize after an instruction cache operation,
* to be sure everything is in sync with memory as to be
* expected following any previous instruction cache control operations.
*
* Even if a config doesn't have caches, an isync is still needed
* when instructions in any memory are modified, whether by a loader
* or self-modifying code. Therefore, this macro always produces
* an isync, whether or not an icache is present.
*
* Parameters are:
* ar an address register (temporary) (currently unused, but may be used in future)
*/
.macro icache_sync ar
isync
.endm
/*
* Invalidate a single line of the instruction cache.
* Parameters are:
* ar address register that contains (virtual) address to invalidate
* (may get clobbered in a future implementation, but not currently)
* offset (optional) offset to add to \ar to compute effective address to invalidate
* (note: some number of lsbits are ignored)
*/
.macro icache_invalidate_line ar, offset
#if XCHAL_ICACHE_SIZE > 0
ihi \ar, \offset // invalidate icache line
icache_sync \ar
#endif
.endm
/*
* Invalidate instruction cache entries that cache a specified portion of memory.
* Parameters are:
* astart start address (register gets clobbered)
* asize size of the region in bytes (register gets clobbered)
* ac unique register used as temporary
*/
.macro icache_invalidate_region astart, asize, ac
#if XCHAL_ICACHE_SIZE > 0
// Instruction cache region invalidation:
cache_hit_region ihi, XCHAL_ICACHE_LINEWIDTH, \astart, \asize, \ac
icache_sync \ac
// End of instruction cache region invalidation
#endif
.endm
/*
* Invalidate entire instruction cache.
*
* Parameters:
* aa, ab unique address registers (temporaries)
*/
.macro icache_invalidate_all aa, ab, loopokay=1
#if XCHAL_ICACHE_SIZE > 0
// Instruction cache invalidation:
cache_index_all iii, XCHAL_ICACHE_SIZE, XCHAL_ICACHE_LINESIZE, XCHAL_ICACHE_WAYS, \aa, \ab, \loopokay, 1020
icache_sync \aa
// End of instruction cache invalidation
#endif
.endm
/*
* Lock (prefetch & lock) a single line of the instruction cache.
*
* Parameters are:
* ar address register that contains (virtual) address to lock
* (may get clobbered in a future implementation, but not currently)
* offset offset to add to \ar to compute effective address to lock
* (note: some number of lsbits are ignored)
*/
.macro icache_lock_line ar, offset
#if XCHAL_ICACHE_SIZE > 0 && XCHAL_ICACHE_LINE_LOCKABLE
ipfl \ar, \offset /* prefetch and lock icache line */
icache_sync \ar
#endif
.endm
/*
* Lock (prefetch & lock) a specified portion of memory into the instruction cache.
* Parameters are:
* astart start address (register gets clobbered)
* asize size of the region in bytes (register gets clobbered)
* ac unique register used as temporary
*/
.macro icache_lock_region astart, asize, ac
#if XCHAL_ICACHE_SIZE > 0 && XCHAL_ICACHE_LINE_LOCKABLE
// Instruction cache region lock:
cache_hit_region ipfl, XCHAL_ICACHE_LINEWIDTH, \astart, \asize, \ac
icache_sync \ac
// End of instruction cache region lock
#endif
.endm
/*
* Unlock a single line of the instruction cache.
*
* Parameters are:
* ar address register that contains (virtual) address to unlock
* (may get clobbered in a future implementation, but not currently)
* offset offset to add to \ar to compute effective address to unlock
* (note: some number of lsbits are ignored)
*/
.macro icache_unlock_line ar, offset
#if XCHAL_ICACHE_SIZE > 0 && XCHAL_ICACHE_LINE_LOCKABLE
ihu \ar, \offset /* unlock icache line */
icache_sync \ar
#endif
.endm
/*
* Unlock a specified portion of memory from the instruction cache.
* Parameters are:
* astart start address (register gets clobbered)
* asize size of the region in bytes (register gets clobbered)
* ac unique register used as temporary
*/
.macro icache_unlock_region astart, asize, ac
#if XCHAL_ICACHE_SIZE > 0 && XCHAL_ICACHE_LINE_LOCKABLE
// Instruction cache region unlock:
cache_hit_region ihu, XCHAL_ICACHE_LINEWIDTH, \astart, \asize, \ac
icache_sync \ac
// End of instruction cache region unlock
#endif
.endm
/*
* Unlock entire instruction cache.
*
* Parameters:
* aa, ab unique address registers (temporaries)
*/
.macro icache_unlock_all aa, ab, loopokay=1
#if XCHAL_ICACHE_SIZE > 0 && XCHAL_ICACHE_LINE_LOCKABLE
// Instruction cache unlock:
cache_index_all iiu, XCHAL_ICACHE_SIZE, XCHAL_ICACHE_LINESIZE, 1, \aa, \ab, \loopokay, 240
icache_sync \aa
// End of instruction cache unlock
#endif
.endm
/*************************** DATA CACHE ***************************/
/*
* Reset/initialize the data cache by simply invalidating it
* (need to unlock first also, if cache locking implemented):
*
* Parameters:
* aa, ab unique address registers (temporaries)
*/
.macro dcache_reset aa, ab, loopokay=0
dcache_unlock_all \aa, \ab, \loopokay
dcache_invalidate_all \aa, \ab, \loopokay
.endm
/*
* Synchronize after a data cache operation,
* to be sure everything is in sync with memory as to be
* expected following any previous data cache control operations.
*
* Parameters are:
* ar an address register (temporary) (currently unused, but may be used in future)
*/
.macro dcache_sync ar, wbtype=0
#if XCHAL_DCACHE_SIZE > 0
// No synchronization is needed.
// (memw may be desired e.g. after writeback operation to help ensure subsequent
// external accesses are seen to follow that writeback, however that's outside
// the scope of this macro)
//dsync
.ifne (\wbtype & XCHAL_ERRATUM_497)
memw
.endif
#endif
.endm
/*
* Turn on cache coherence.
*
* WARNING: for RE-201x.x and later hardware, any interrupt that tries
* to change MEMCTL will see its changes dropped if the interrupt comes
* in the middle of this routine. If this might be an issue, call this
* routine with interrupts disabled.
*
* Parameters are:
* ar,at two scratch address registers (both clobbered)
*/
.macro cache_coherence_on ar at
#if XCHAL_DCACHE_IS_COHERENT
# if XCHAL_HW_MIN_VERSION >= XTENSA_HWVERSION_RE_2012_0
/* Have MEMCTL. Enable snoop responses. */
rsr.memctl \ar
movi \at, MEMCTL_SNOOP_EN
or \ar, \ar, \at
wsr.memctl \ar
# elif XCHAL_HAVE_EXTERN_REGS && XCHAL_HAVE_MX
/* Opt into coherence for MX (for backward compatibility / testing). */
movi \ar, 1
movi \at, XER_CCON
wer \ar, \at
extw
# endif
#endif
.endm
/*
* Turn off cache coherence.
*
* NOTE: this is generally preceded by emptying the cache;
* see xthal_cache_coherence_optout() in hal/coherence.c for details.
*
* WARNING: for RE-201x.x and later hardware, any interrupt that tries
* to change MEMCTL will see its changes dropped if the interrupt comes
* in the middle of this routine. If this might be an issue, call this
* routine with interrupts disabled.
*
* Parameters are:
* ar,at two scratch address registers (both clobbered)
*/
.macro cache_coherence_off ar at
#if XCHAL_DCACHE_IS_COHERENT
# if XCHAL_HW_MIN_VERSION >= XTENSA_HWVERSION_RE_2012_0
/* Have MEMCTL. Disable snoop responses. */
rsr.memctl \ar
movi \at, ~MEMCTL_SNOOP_EN
and \ar, \ar, \at
wsr.memctl \ar
# elif XCHAL_HAVE_EXTERN_REGS && XCHAL_HAVE_MX
/* Opt out of coherence, for MX (for backward compatibility / testing). */
extw
movi \at, 0
movi \ar, XER_CCON
wer \at, \ar
extw
# endif
#endif
.endm
/*
* Synchronize after a data store operation,
* to be sure the stored data is completely off the processor
* (and assuming there is no buffering outside the processor,
* that the data is in memory). This may be required to
* ensure that the processor's write buffers are emptied.
* A MEMW followed by a read guarantees this, by definition.
* We also try to make sure the read itself completes.
*
* Parameters are:
* ar an address register (temporary)
*/
.macro write_sync ar
memw // ensure previous memory accesses are complete prior to subsequent memory accesses
l32i \ar, sp, 0 // completing this read ensures any previous write has completed, because of MEMW
//slot
add \ar, \ar, \ar // use the result of the read to help ensure the read completes (in future architectures)
.endm
/*
* Invalidate a single line of the data cache.
* Parameters are:
* ar address register that contains (virtual) address to invalidate
* (may get clobbered in a future implementation, but not currently)
* offset (optional) offset to add to \ar to compute effective address to invalidate
* (note: some number of lsbits are ignored)
*/
.macro dcache_invalidate_line ar, offset
#if XCHAL_DCACHE_SIZE > 0
dhi \ar, \offset
dcache_sync \ar
#endif
.endm
/*
* Invalidate data cache entries that cache a specified portion of memory.
* Parameters are:
* astart start address (register gets clobbered)
* asize size of the region in bytes (register gets clobbered)
* ac unique register used as temporary
*/
.macro dcache_invalidate_region astart, asize, ac
#if XCHAL_DCACHE_SIZE > 0
// Data cache region invalidation:
cache_hit_region dhi, XCHAL_DCACHE_LINEWIDTH, \astart, \asize, \ac
dcache_sync \ac
// End of data cache region invalidation
#endif
.endm
/*
* Invalidate entire data cache.
*
* Parameters:
* aa, ab unique address registers (temporaries)
*/
.macro dcache_invalidate_all aa, ab, loopokay=1
#if XCHAL_DCACHE_SIZE > 0
// Data cache invalidation:
cache_index_all dii, XCHAL_DCACHE_SIZE, XCHAL_DCACHE_LINESIZE, XCHAL_DCACHE_WAYS, \aa, \ab, \loopokay, 1020
dcache_sync \aa
// End of data cache invalidation
#endif
.endm
/*
* Writeback a single line of the data cache.
* Parameters are:
* ar address register that contains (virtual) address to writeback
* (may get clobbered in a future implementation, but not currently)
* offset offset to add to \ar to compute effective address to writeback
* (note: some number of lsbits are ignored)
*/
.macro dcache_writeback_line ar, offset
#if XCHAL_DCACHE_SIZE > 0 && XCHAL_DCACHE_IS_WRITEBACK
dhwb \ar, \offset
dcache_sync \ar, wbtype=1
#endif
.endm
/*
* Writeback dirty data cache entries that cache a specified portion of memory.
* Parameters are:
* astart start address (register gets clobbered)
* asize size of the region in bytes (register gets clobbered)
* ac unique register used as temporary
*/
.macro dcache_writeback_region astart, asize, ac, awb
#if XCHAL_DCACHE_SIZE > 0 && XCHAL_DCACHE_IS_WRITEBACK
// Data cache region writeback:
cache_hit_region dhwb, XCHAL_DCACHE_LINEWIDTH, \astart, \asize, \ac, \awb
dcache_sync \ac, wbtype=1
// End of data cache region writeback
#endif
.endm
/*
* Writeback entire data cache.
* Parameters:
* aa, ab unique address registers (temporaries)
*/
.macro dcache_writeback_all aa, ab, awb, loopokay=1
#if XCHAL_DCACHE_SIZE > 0 && XCHAL_DCACHE_IS_WRITEBACK
// Data cache writeback:
cache_index_all diwb, XCHAL_DCACHE_SIZE, XCHAL_DCACHE_LINESIZE, 1, \aa, \ab, \loopokay, 240, \awb,
dcache_sync \aa, wbtype=1
// End of data cache writeback
#endif
.endm
/*
* Writeback and invalidate a single line of the data cache.
* Parameters are:
* ar address register that contains (virtual) address to writeback and invalidate
* (may get clobbered in a future implementation, but not currently)
* offset offset to add to \ar to compute effective address to writeback and invalidate
* (note: some number of lsbits are ignored)
*/
.macro dcache_writeback_inv_line ar, offset
#if XCHAL_DCACHE_SIZE > 0
dhwbi \ar, \offset /* writeback and invalidate dcache line */
dcache_sync \ar, wbtype=1
#endif
.endm
/*
* Writeback and invalidate data cache entries that cache a specified portion of memory.
* Parameters are:
* astart start address (register gets clobbered)
* asize size of the region in bytes (register gets clobbered)
* ac unique register used as temporary
*/
.macro dcache_writeback_inv_region astart, asize, ac, awb
#if XCHAL_DCACHE_SIZE > 0
// Data cache region writeback and invalidate:
cache_hit_region dhwbi, XCHAL_DCACHE_LINEWIDTH, \astart, \asize, \ac, \awb
dcache_sync \ac, wbtype=1
// End of data cache region writeback and invalidate
#endif
.endm
/*
* Writeback and invalidate entire data cache.
* Parameters:
* aa, ab unique address registers (temporaries)
*/
.macro dcache_writeback_inv_all aa, ab, awb, loopokay=1
#if XCHAL_DCACHE_SIZE > 0
// Data cache writeback and invalidate:
#if XCHAL_DCACHE_IS_WRITEBACK
cache_index_all diwbi, XCHAL_DCACHE_SIZE, XCHAL_DCACHE_LINESIZE, 1, \aa, \ab, \loopokay, 240, \awb
dcache_sync \aa, wbtype=1
#else /*writeback*/
// Data cache does not support writeback, so just invalidate: */
dcache_invalidate_all \aa, \ab, \loopokay
#endif /*writeback*/
// End of data cache writeback and invalidate
#endif
.endm
/*
* Lock (prefetch & lock) a single line of the data cache.
*
* Parameters are:
* ar address register that contains (virtual) address to lock
* (may get clobbered in a future implementation, but not currently)
* offset offset to add to \ar to compute effective address to lock
* (note: some number of lsbits are ignored)
*/
.macro dcache_lock_line ar, offset
#if XCHAL_DCACHE_SIZE > 0 && XCHAL_DCACHE_LINE_LOCKABLE
dpfl \ar, \offset /* prefetch and lock dcache line */
dcache_sync \ar
#endif
.endm
/*
* Lock (prefetch & lock) a specified portion of memory into the data cache.
* Parameters are:
* astart start address (register gets clobbered)
* asize size of the region in bytes (register gets clobbered)
* ac unique register used as temporary
*/
.macro dcache_lock_region astart, asize, ac
#if XCHAL_DCACHE_SIZE > 0 && XCHAL_DCACHE_LINE_LOCKABLE
// Data cache region lock:
cache_hit_region dpfl, XCHAL_DCACHE_LINEWIDTH, \astart, \asize, \ac
dcache_sync \ac
// End of data cache region lock
#endif
.endm
/*
* Unlock a single line of the data cache.
*
* Parameters are:
* ar address register that contains (virtual) address to unlock
* (may get clobbered in a future implementation, but not currently)
* offset offset to add to \ar to compute effective address to unlock
* (note: some number of lsbits are ignored)
*/
.macro dcache_unlock_line ar, offset
#if XCHAL_DCACHE_SIZE > 0 && XCHAL_DCACHE_LINE_LOCKABLE
dhu \ar, \offset /* unlock dcache line */
dcache_sync \ar
#endif
.endm
/*
* Unlock a specified portion of memory from the data cache.
* Parameters are:
* astart start address (register gets clobbered)
* asize size of the region in bytes (register gets clobbered)
* ac unique register used as temporary
*/
.macro dcache_unlock_region astart, asize, ac
#if XCHAL_DCACHE_SIZE > 0 && XCHAL_DCACHE_LINE_LOCKABLE
// Data cache region unlock:
cache_hit_region dhu, XCHAL_DCACHE_LINEWIDTH, \astart, \asize, \ac
dcache_sync \ac
// End of data cache region unlock
#endif
.endm
/*
* Unlock entire data cache.
*
* Parameters:
* aa, ab unique address registers (temporaries)
*/
.macro dcache_unlock_all aa, ab, loopokay=1
#if XCHAL_DCACHE_SIZE > 0 && XCHAL_DCACHE_LINE_LOCKABLE
// Data cache unlock:
cache_index_all diu, XCHAL_DCACHE_SIZE, XCHAL_DCACHE_LINESIZE, 1, \aa, \ab, \loopokay, 240
dcache_sync \aa
// End of data cache unlock
#endif
.endm
/*
* Get the number of enabled icache ways. Note that this may
* be different from the value read from the MEMCTL register.
*
* Parameters:
* aa address register where value is returned
*/
.macro icache_get_ways aa
#if XCHAL_ICACHE_SIZE > 0
#if XCHAL_HAVE_ICACHE_DYN_WAYS
// Read from MEMCTL and shift/mask
rsr \aa, MEMCTL
extui \aa, \aa, MEMCTL_ICWU_SHIFT, MEMCTL_ICWU_BITS
blti \aa, XCHAL_ICACHE_WAYS, .Licgw
movi \aa, XCHAL_ICACHE_WAYS
.Licgw:
#else
// All ways are always enabled
movi \aa, XCHAL_ICACHE_WAYS
#endif
#else
// No icache
movi \aa, 0
#endif
.endm
/*
* Set the number of enabled icache ways.
*
* Parameters:
* aa address register specifying number of ways (trashed)
* ab,ac address register for scratch use (trashed)
*/
.macro icache_set_ways aa, ab, ac
#if XCHAL_ICACHE_SIZE > 0
#if XCHAL_HAVE_ICACHE_DYN_WAYS
movi \ac, MEMCTL_ICWU_CLR_MASK // set up to clear bits 18-22
rsr \ab, MEMCTL
and \ab, \ab, \ac
movi \ac, MEMCTL_INV_EN // set bit 23
slli \aa, \aa, MEMCTL_ICWU_SHIFT // move to right spot
or \ab, \ab, \aa
or \ab, \ab, \ac
wsr \ab, MEMCTL
isync
#else
// All ways are always enabled
#endif
#else
// No icache
#endif
.endm
/*
* Get the number of enabled dcache ways. Note that this may
* be different from the value read from the MEMCTL register.
*
* Parameters:
* aa address register where value is returned
*/
.macro dcache_get_ways aa
#if XCHAL_DCACHE_SIZE > 0
#if XCHAL_HAVE_DCACHE_DYN_WAYS
// Read from MEMCTL and shift/mask
rsr \aa, MEMCTL
extui \aa, \aa, MEMCTL_DCWU_SHIFT, MEMCTL_DCWU_BITS
blti \aa, XCHAL_DCACHE_WAYS, .Ldcgw
movi \aa, XCHAL_DCACHE_WAYS
.Ldcgw:
#else
// All ways are always enabled
movi \aa, XCHAL_DCACHE_WAYS
#endif
#else
// No dcache
movi \aa, 0
#endif
.endm
/*
* Set the number of enabled dcache ways.
*
* Parameters:
* aa address register specifying number of ways (trashed)
* ab,ac address register for scratch use (trashed)
*/
.macro dcache_set_ways aa, ab, ac
#if (XCHAL_DCACHE_SIZE > 0) && XCHAL_HAVE_DCACHE_DYN_WAYS
movi \ac, MEMCTL_DCWA_CLR_MASK // set up to clear bits 13-17
rsr \ab, MEMCTL
and \ab, \ab, \ac // clear ways allocatable
slli \ac, \aa, MEMCTL_DCWA_SHIFT
or \ab, \ab, \ac // set ways allocatable
wsr \ab, MEMCTL
#if XCHAL_DCACHE_IS_WRITEBACK
// Check if the way count is increasing or decreasing
extui \ac, \ab, MEMCTL_DCWU_SHIFT, MEMCTL_DCWU_BITS // bits 8-12 - ways in use
bge \aa, \ac, .Ldsw3 // equal or increasing
slli \ab, \aa, XCHAL_DCACHE_LINEWIDTH + XCHAL_DCACHE_SETWIDTH // start way number
slli \ac, \ac, XCHAL_DCACHE_LINEWIDTH + XCHAL_DCACHE_SETWIDTH // end way number
.Ldsw1:
diwbui.p \ab // auto-increments ab
bge \ab, \ac, .Ldsw2
beqz \ab, .Ldsw2
j .Ldsw1
.Ldsw2:
rsr \ab, MEMCTL
#endif
.Ldsw3:
// No dirty data to write back, just set the new number of ways
movi \ac, MEMCTL_DCWU_CLR_MASK // set up to clear bits 8-12
and \ab, \ab, \ac // clear ways in use
movi \ac, MEMCTL_INV_EN
or \ab, \ab, \ac // set bit 23
slli \aa, \aa, MEMCTL_DCWU_SHIFT
or \ab, \ab, \aa // set ways in use
wsr \ab, MEMCTL
#else
// No dcache or no way disable support
#endif
.endm
#endif /*XTENSA_CACHEASM_H*/