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https://github.com/autc04/Retro68.git
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439 lines
12 KiB
C
439 lines
12 KiB
C
/* Copyright (C) 2008-2017 Free Software Foundation, Inc.
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This file is part of GCC.
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GCC is free software; you can redistribute it and/or modify it under
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the terms of the GNU General Public License as published by the Free
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Software Foundation; either version 3, or (at your option) any later
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version.
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GCC is distributed in the hope that it will be useful, but WITHOUT ANY
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WARRANTY; without even the implied warranty of MERCHANTABILITY or
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FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
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for more details.
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Under Section 7 of GPL version 3, you are granted additional
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permissions described in the GCC Runtime Library Exception, version
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3.1, as published by the Free Software Foundation.
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You should have received a copy of the GNU General Public License and
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a copy of the GCC Runtime Library Exception along with this program;
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see the files COPYING3 and COPYING.RUNTIME respectively. If not, see
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<http://www.gnu.org/licenses/>. */
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#include <spu_mfcio.h>
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#include <spu_internals.h>
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#include <spu_intrinsics.h>
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#include <spu_cache.h>
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extern unsigned long long __ea_local_store;
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extern char __cache_tag_array_size;
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#define LINE_SIZE 128
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#define TAG_MASK (LINE_SIZE - 1)
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#define WAYS 4
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#define SET_MASK ((int) &__cache_tag_array_size - LINE_SIZE)
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#define CACHE_LINES ((int) &__cache_tag_array_size / \
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sizeof (struct __cache_tag_array) * WAYS)
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struct __cache_tag_array
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{
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unsigned int tag_lo[WAYS];
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unsigned int tag_hi[WAYS];
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void *base[WAYS];
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int reserved[WAYS];
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vector unsigned short dirty_bits[WAYS];
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};
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extern struct __cache_tag_array __cache_tag_array[];
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extern char __cache[];
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/* In order to make the code seem a little cleaner, and to avoid having
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64/32 bit ifdefs all over the place, we use macros. */
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#ifdef __EA64__
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typedef unsigned long long addr;
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#define CHECK_TAG(_entry, _way, _tag) \
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((_entry)->tag_lo[(_way)] == ((_tag) & 0xFFFFFFFF) \
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&& (_entry)->tag_hi[(_way)] == ((_tag) >> 32))
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#define GET_TAG(_entry, _way) \
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((unsigned long long)(_entry)->tag_hi[(_way)] << 32 \
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| (unsigned long long)(_entry)->tag_lo[(_way)])
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#define SET_TAG(_entry, _way, _tag) \
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(_entry)->tag_lo[(_way)] = (_tag) & 0xFFFFFFFF; \
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(_entry)->tag_hi[(_way)] = (_tag) >> 32
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#else /*__EA32__*/
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typedef unsigned long addr;
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#define CHECK_TAG(_entry, _way, _tag) \
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((_entry)->tag_lo[(_way)] == (_tag))
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#define GET_TAG(_entry, _way) \
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((_entry)->tag_lo[(_way)])
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#define SET_TAG(_entry, _way, _tag) \
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(_entry)->tag_lo[(_way)] = (_tag)
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#endif
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/* In GET_ENTRY, we cast away the high 32 bits,
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as the tag is only in the low 32. */
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#define GET_ENTRY(_addr) \
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((struct __cache_tag_array *) \
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si_to_uint (si_a (si_and (si_from_uint ((unsigned int) (addr) (_addr)), \
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si_from_uint (SET_MASK)), \
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si_from_uint ((unsigned int) __cache_tag_array))))
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#define GET_CACHE_LINE(_addr, _way) \
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((void *) (__cache + ((_addr) & SET_MASK) * WAYS) + ((_way) * LINE_SIZE));
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#define CHECK_DIRTY(_vec) (si_to_uint (si_orx ((qword) (_vec))))
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#define SET_EMPTY(_entry, _way) ((_entry)->tag_lo[(_way)] = 1)
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#define CHECK_EMPTY(_entry, _way) ((_entry)->tag_lo[(_way)] == 1)
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#define LS_FLAG 0x80000000
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#define SET_IS_LS(_entry, _way) ((_entry)->reserved[(_way)] |= LS_FLAG)
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#define CHECK_IS_LS(_entry, _way) ((_entry)->reserved[(_way)] & LS_FLAG)
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#define GET_LRU(_entry, _way) ((_entry)->reserved[(_way)] & ~LS_FLAG)
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static int dma_tag = 32;
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static void
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__cache_evict_entry (struct __cache_tag_array *entry, int way)
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{
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addr tag = GET_TAG (entry, way);
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if (CHECK_DIRTY (entry->dirty_bits[way]) && !CHECK_IS_LS (entry, way))
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{
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#ifdef NONATOMIC
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/* Non-atomic writes. */
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unsigned int oldmask, mach_stat;
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char *line = ((void *) 0);
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/* Enter critical section. */
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mach_stat = spu_readch (SPU_RdMachStat);
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spu_idisable ();
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/* Issue DMA request. */
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line = GET_CACHE_LINE (entry->tag_lo[way], way);
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mfc_put (line, tag, LINE_SIZE, dma_tag, 0, 0);
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/* Wait for DMA completion. */
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oldmask = mfc_read_tag_mask ();
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mfc_write_tag_mask (1 << dma_tag);
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mfc_read_tag_status_all ();
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mfc_write_tag_mask (oldmask);
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/* Leave critical section. */
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if (__builtin_expect (mach_stat & 1, 0))
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spu_ienable ();
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#else
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/* Allocate a buffer large enough that we know it has 128 bytes
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that are 128 byte aligned (for DMA). */
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char buffer[LINE_SIZE + 127];
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qword *buf_ptr = (qword *) (((unsigned int) (buffer) + 127) & ~127);
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qword *line = GET_CACHE_LINE (entry->tag_lo[way], way);
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qword bits;
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unsigned int mach_stat;
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/* Enter critical section. */
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mach_stat = spu_readch (SPU_RdMachStat);
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spu_idisable ();
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do
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{
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/* We atomically read the current memory into a buffer
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modify the dirty bytes in the buffer, and write it
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back. If writeback fails, loop and try again. */
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mfc_getllar (buf_ptr, tag, 0, 0);
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mfc_read_atomic_status ();
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/* The method we're using to write 16 dirty bytes into
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the buffer at a time uses fsmb which in turn uses
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the least significant 16 bits of word 0, so we
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load the bits and rotate so that the first bit of
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the bitmap is in the first bit that fsmb will use. */
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bits = (qword) entry->dirty_bits[way];
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bits = si_rotqbyi (bits, -2);
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/* Si_fsmb creates the mask of dirty bytes.
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Use selb to nab the appropriate bits. */
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buf_ptr[0] = si_selb (buf_ptr[0], line[0], si_fsmb (bits));
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/* Rotate to next 16 byte section of cache. */
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bits = si_rotqbyi (bits, 2);
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buf_ptr[1] = si_selb (buf_ptr[1], line[1], si_fsmb (bits));
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bits = si_rotqbyi (bits, 2);
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buf_ptr[2] = si_selb (buf_ptr[2], line[2], si_fsmb (bits));
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bits = si_rotqbyi (bits, 2);
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buf_ptr[3] = si_selb (buf_ptr[3], line[3], si_fsmb (bits));
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bits = si_rotqbyi (bits, 2);
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buf_ptr[4] = si_selb (buf_ptr[4], line[4], si_fsmb (bits));
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bits = si_rotqbyi (bits, 2);
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buf_ptr[5] = si_selb (buf_ptr[5], line[5], si_fsmb (bits));
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bits = si_rotqbyi (bits, 2);
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buf_ptr[6] = si_selb (buf_ptr[6], line[6], si_fsmb (bits));
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bits = si_rotqbyi (bits, 2);
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buf_ptr[7] = si_selb (buf_ptr[7], line[7], si_fsmb (bits));
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bits = si_rotqbyi (bits, 2);
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mfc_putllc (buf_ptr, tag, 0, 0);
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}
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while (mfc_read_atomic_status ());
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/* Leave critical section. */
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if (__builtin_expect (mach_stat & 1, 0))
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spu_ienable ();
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#endif
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}
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/* In any case, marking the lo tag with 1 which denotes empty. */
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SET_EMPTY (entry, way);
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entry->dirty_bits[way] = (vector unsigned short) si_from_uint (0);
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}
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void
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__cache_evict (__ea void *ea)
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{
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addr tag = (addr) ea & ~TAG_MASK;
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struct __cache_tag_array *entry = GET_ENTRY (ea);
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int i = 0;
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/* Cycles through all the possible ways an address could be at
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and evicts the way if found. */
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for (i = 0; i < WAYS; i++)
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if (CHECK_TAG (entry, i, tag))
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__cache_evict_entry (entry, i);
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}
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static void *
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__cache_fill (int way, addr tag)
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{
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unsigned int oldmask, mach_stat;
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char *line = ((void *) 0);
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/* Reserve our DMA tag. */
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if (dma_tag == 32)
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dma_tag = mfc_tag_reserve ();
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/* Enter critical section. */
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mach_stat = spu_readch (SPU_RdMachStat);
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spu_idisable ();
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/* Issue DMA request. */
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line = GET_CACHE_LINE (tag, way);
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mfc_get (line, tag, LINE_SIZE, dma_tag, 0, 0);
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/* Wait for DMA completion. */
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oldmask = mfc_read_tag_mask ();
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mfc_write_tag_mask (1 << dma_tag);
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mfc_read_tag_status_all ();
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mfc_write_tag_mask (oldmask);
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/* Leave critical section. */
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if (__builtin_expect (mach_stat & 1, 0))
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spu_ienable ();
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return (void *) line;
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}
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static void
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__cache_miss (__ea void *ea, struct __cache_tag_array *entry, int way)
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{
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addr tag = (addr) ea & ~TAG_MASK;
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unsigned int lru = 0;
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int i = 0;
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int idx = 0;
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/* If way > 4, then there are no empty slots, so we must evict
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the least recently used entry. */
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if (way >= 4)
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{
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for (i = 0; i < WAYS; i++)
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{
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if (GET_LRU (entry, i) > lru)
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{
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lru = GET_LRU (entry, i);
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idx = i;
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}
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}
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__cache_evict_entry (entry, idx);
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way = idx;
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}
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/* Set the empty entry's tag and fill it's cache line. */
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SET_TAG (entry, way, tag);
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entry->reserved[way] = 0;
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/* Check if the address is just an effective address within the
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SPU's local store. */
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/* Because the LS is not 256k aligned, we can't do a nice and mask
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here to compare, so we must check the whole range. */
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if ((addr) ea >= (addr) __ea_local_store
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&& (addr) ea < (addr) (__ea_local_store + 0x40000))
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{
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SET_IS_LS (entry, way);
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entry->base[way] =
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(void *) ((unsigned int) ((addr) ea -
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(addr) __ea_local_store) & ~0x7f);
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}
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else
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{
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entry->base[way] = __cache_fill (way, tag);
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}
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}
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void *
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__cache_fetch_dirty (__ea void *ea, int n_bytes_dirty)
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{
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#ifdef __EA64__
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unsigned int tag_hi;
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qword etag_hi;
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#endif
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unsigned int tag_lo;
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struct __cache_tag_array *entry;
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qword etag_lo;
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qword equal;
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qword bit_mask;
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qword way;
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/* This first chunk, we merely fill the pointer and tag. */
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entry = GET_ENTRY (ea);
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#ifndef __EA64__
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tag_lo =
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si_to_uint (si_andc
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(si_shufb
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(si_from_uint ((addr) ea), si_from_uint (0),
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si_from_uint (0x00010203)), si_from_uint (TAG_MASK)));
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#else
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tag_lo =
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si_to_uint (si_andc
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(si_shufb
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(si_from_ullong ((addr) ea), si_from_uint (0),
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si_from_uint (0x04050607)), si_from_uint (TAG_MASK)));
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tag_hi =
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si_to_uint (si_shufb
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(si_from_ullong ((addr) ea), si_from_uint (0),
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si_from_uint (0x00010203)));
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#endif
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/* Increment LRU in reserved bytes. */
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si_stqd (si_ai (si_lqd (si_from_ptr (entry), 48), 1),
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si_from_ptr (entry), 48);
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missreturn:
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/* Check if the entry's lo_tag is equal to the address' lo_tag. */
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etag_lo = si_lqd (si_from_ptr (entry), 0);
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equal = si_ceq (etag_lo, si_from_uint (tag_lo));
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#ifdef __EA64__
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/* And the high tag too. */
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etag_hi = si_lqd (si_from_ptr (entry), 16);
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equal = si_and (equal, (si_ceq (etag_hi, si_from_uint (tag_hi))));
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#endif
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if ((si_to_uint (si_orx (equal)) == 0))
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goto misshandler;
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if (n_bytes_dirty)
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{
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/* way = 0x40,0x50,0x60,0x70 for each way, which is also the
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offset of the appropriate dirty bits. */
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way = si_shli (si_clz (si_gbb (equal)), 2);
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/* To create the bit_mask, we set it to all 1s (uint -1), then we
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shift it over (128 - n_bytes_dirty) times. */
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bit_mask = si_from_uint (-1);
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bit_mask =
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si_shlqby (bit_mask, si_from_uint ((LINE_SIZE - n_bytes_dirty) / 8));
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bit_mask =
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si_shlqbi (bit_mask, si_from_uint ((LINE_SIZE - n_bytes_dirty) % 8));
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/* Rotate it around to the correct offset. */
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bit_mask =
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si_rotqby (bit_mask,
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si_from_uint (-1 * ((addr) ea & TAG_MASK) / 8));
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bit_mask =
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si_rotqbi (bit_mask,
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si_from_uint (-1 * ((addr) ea & TAG_MASK) % 8));
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/* Update the dirty bits. */
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si_stqx (si_or (si_lqx (si_from_ptr (entry), way), bit_mask),
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si_from_ptr (entry), way);
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};
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/* We've definitely found the right entry, set LRU (reserved) to 0
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maintaining the LS flag (MSB). */
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si_stqd (si_andc
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(si_lqd (si_from_ptr (entry), 48),
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si_and (equal, si_from_uint (~(LS_FLAG)))),
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si_from_ptr (entry), 48);
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return (void *)
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si_to_uint (si_a
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(si_orx
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(si_and (si_lqd (si_from_ptr (entry), 32), equal)),
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si_from_uint (((unsigned int) (addr) ea) & TAG_MASK)));
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misshandler:
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equal = si_ceqi (etag_lo, 1);
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__cache_miss (ea, entry, (si_to_uint (si_clz (si_gbb (equal))) - 16) >> 2);
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goto missreturn;
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}
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void *
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__cache_fetch (__ea void *ea)
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{
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return __cache_fetch_dirty (ea, 0);
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}
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void
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__cache_touch (__ea void *ea __attribute__ ((unused)))
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{
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/* NO-OP for now. */
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}
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void __cache_flush (void) __attribute__ ((destructor));
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void
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__cache_flush (void)
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{
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struct __cache_tag_array *entry = __cache_tag_array;
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unsigned int i;
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int j;
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/* Cycle through each cache entry and evict all used ways. */
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for (i = 0; i < CACHE_LINES / WAYS; i++)
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{
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for (j = 0; j < WAYS; j++)
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if (!CHECK_EMPTY (entry, j))
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__cache_evict_entry (entry, j);
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entry++;
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}
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}
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