mirror of
https://github.com/CTCaer/RetroArch.git
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450 lines
13 KiB
C
450 lines
13 KiB
C
/* RetroArch - A frontend for libretro.
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* Copyright (C) 2010-2014 - Hans-Kristian Arntzen
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* Copyright (C) 2014 - Alfred Agrell
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*
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* RetroArch is free software: you can redistribute it and/or modify it under the terms
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* of the GNU General Public License as published by the Free Software Found-
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* ation, either version 3 of the License, or (at your option) any later version.
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*
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* RetroArch is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
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* without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR
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* PURPOSE. See the GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License along with RetroArch.
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* If not, see <http://www.gnu.org/licenses/>.
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*/
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#define __STDC_LIMIT_MACROS
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#include "rewind.h"
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#include "performance.h"
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#include <stdlib.h>
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#include <stdint.h>
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#include <string.h>
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#ifndef UINT16_MAX
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#define UINT16_MAX 0xffff
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#endif
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#ifndef UINT32_MAX
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#define UINT32_MAX 0xffffffffu
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#endif
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#undef CPU_X86
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#if defined(__x86_64__) || defined(__i386__) || defined(__i486__) || defined(__i686__)
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#define CPU_X86
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#endif
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// Other arches SIGBUS (usually) on unaligned accesses.
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#ifndef CPU_X86
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#define NO_UNALIGNED_MEM
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#endif
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// Format per frame:
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// size nextstart;
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// repeat {
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// uint16 numchanged; // everything is counted in units of uint16
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// if (numchanged) {
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// uint16 numunchanged; // skip these before handling numchanged
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// uint16[numchanged] changeddata;
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// }
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// else
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// {
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// uint32 numunchanged;
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// if (!numunchanged) break;
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// }
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// }
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// size thisstart;
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//
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// The start offsets point to 'nextstart' of any given compressed frame.
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// Each uint16 is stored native endian; anything that claims any other endianness refers to the endianness of this specific item.
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// The uint32 is stored little endian.
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// Each size value is stored native endian if alignment is not enforced; if it is, they're little endian.
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// The start of the buffer contains a size pointing to the end of the buffer; the end points to its start.
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// Wrapping is handled by returning to the start of the buffer if the compressed data could potentially hit the edge;
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// if the compressed data could potentially overwrite the tail pointer, the tail retreats until it can no longer collide.
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// This means that on average, ~2 * maxcompsize is unused at any given moment.
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// These are called very few constant times per frame, keep it as simple as possible.
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static inline void write_size_t(void *ptr, size_t val)
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{
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memcpy(ptr, &val, sizeof(val));
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}
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static inline size_t read_size_t(const void *ptr)
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{
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size_t ret;
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memcpy(&ret, ptr, sizeof(ret));
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return ret;
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}
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struct state_manager
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{
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uint8_t *data;
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size_t capacity;
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uint8_t *head; // Reading and writing is done here.
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uint8_t *tail; // If head comes close to this, discard a frame.
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uint8_t *thisblock;
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uint8_t *nextblock;
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size_t blocksize; // This one is runded up from reset::blocksize.
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size_t maxcompsize; // size_t + (blocksize + 131071) / 131072 * (blocksize + u16 + u16) + u16 + u32 + size_t (yes, the math is a bit ugly).
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unsigned entries;
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bool thisblock_valid;
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};
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state_manager_t *state_manager_new(size_t state_size, size_t buffer_size)
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{
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state_manager_t *state = (state_manager_t*)calloc(1, sizeof(*state));
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if (!state)
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return NULL;
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size_t newblocksize = ((state_size - 1) | (sizeof(uint16_t) - 1)) + 1;
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state->blocksize = newblocksize;
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const int maxcblkcover = UINT16_MAX * sizeof(uint16_t);
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const int maxcblks = (state->blocksize + maxcblkcover - 1) / maxcblkcover;
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state->maxcompsize = state->blocksize + maxcblks * sizeof(uint16_t) * 2 + sizeof(uint16_t) + sizeof(uint32_t) + sizeof(size_t) * 2;
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state->data = (uint8_t*)malloc(buffer_size);
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state->thisblock = (uint8_t*)calloc(state->blocksize + sizeof(uint16_t) * 4 + 16, 1);
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state->nextblock = (uint8_t*)calloc(state->blocksize + sizeof(uint16_t) * 4 + 16, 1);
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if (!state->data || !state->thisblock || !state->nextblock)
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goto error;
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// Force in a different byte at the end, so we don't need to check bounds in the innermost loop (it's expensive).
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// There is also a large amount of data that's the same, to stop the other scan
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// There is also some padding at the end. This is so we don't read outside the buffer end if we're reading in large blocks;
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// it doesn't make any difference to us, but sacrificing 16 bytes to get Valgrind happy is worth it.
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*(uint16_t*)(state->thisblock + state->blocksize + sizeof(uint16_t) * 3) = 0xFFFF;
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*(uint16_t*)(state->nextblock + state->blocksize + sizeof(uint16_t) * 3) = 0x0000;
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state->capacity = buffer_size;
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state->head = state->data + sizeof(size_t);
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state->tail = state->data + sizeof(size_t);
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return state;
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error:
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state_manager_free(state);
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return NULL;
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}
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void state_manager_free(state_manager_t *state)
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{
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free(state->data);
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free(state->thisblock);
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free(state->nextblock);
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free(state);
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}
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bool state_manager_pop(state_manager_t *state, const void **data)
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{
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*data = NULL;
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if (state->thisblock_valid)
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{
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state->thisblock_valid = false;
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state->entries--;
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*data = state->thisblock;
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return true;
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}
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if (state->head == state->tail)
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return false;
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size_t start = read_size_t(state->head - sizeof(size_t));
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state->head = state->data + start;
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const uint8_t *compressed = state->data + start + sizeof(size_t);
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uint8_t *out = state->thisblock;
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// Begin decompression code
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// out is the last pushed (or returned) state
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const uint16_t *compressed16 = (const uint16_t*)compressed;
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uint16_t *out16 = (uint16_t*)out;
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for (;;)
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{
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uint16_t i;
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uint16_t numchanged = *(compressed16++);
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if (numchanged)
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{
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out16 += *compressed16++;
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// We could do memcpy, but it seems that memcpy has a constant-per-call overhead that actually shows up.
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// Our average size in here seems to be 8 or something.
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// Therefore, we do something with lower overhead.
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for (i = 0; i < numchanged; i++)
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out16[i] = compressed16[i];
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compressed16 += numchanged;
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out16 += numchanged;
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}
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else
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{
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uint32_t numunchanged = compressed16[0] | (compressed16[1] << 16);
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if (!numunchanged)
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break;
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compressed16 += 2;
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out16 += numunchanged;
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}
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}
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// End decompression code
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state->entries--;
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*data = state->thisblock;
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return true;
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}
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void state_manager_push_where(state_manager_t *state, void **data)
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{
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// We need to ensure we have an uncompressed copy of the last pushed state, or we could
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// end up applying a 'patch' to wrong savestate, and that'd blow up rather quickly.
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if (!state->thisblock_valid)
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{
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const void *ignored;
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if (state_manager_pop(state, &ignored))
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{
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state->thisblock_valid = true;
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state->entries++;
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}
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}
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*data = state->nextblock;
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}
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#if __SSE2__
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#if defined(__GNUC__)
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static inline int compat_ctz(unsigned x)
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{
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return __builtin_ctz(x);
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}
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#else
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// Only checks at nibble granularity, because that's what we need.
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static inline int compat_ctz(unsigned x)
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{
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if (x & 0x000f)
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return 0;
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if (x & 0x00f0)
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return 4;
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if (x & 0x0f00)
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return 8;
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if (x & 0xf000)
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return 12;
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return 16;
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}
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#endif
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#include <emmintrin.h>
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// There's no equivalent in libc, you'd think so ... std::mismatch exists, but it's not optimized at all. :(
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static inline size_t find_change(const uint16_t *a, const uint16_t *b)
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{
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const __m128i *a128 = (const __m128i*)a;
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const __m128i *b128 = (const __m128i*)b;
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for (;;)
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{
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__m128i v0 = _mm_loadu_si128(a128);
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__m128i v1 = _mm_loadu_si128(b128);
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__m128i c = _mm_cmpeq_epi32(v0, v1);
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uint32_t mask = _mm_movemask_epi8(c);
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if (mask != 0xffff) // Something has changed, figure out where.
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{
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size_t ret = (((uint8_t*)a128 - (uint8_t*)a) | (compat_ctz(~mask))) >> 1;
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return ret | (a[ret] == b[ret]);
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}
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a128++;
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b128++;
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}
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}
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#else
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static inline size_t find_change(const uint16_t *a, const uint16_t *b)
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{
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const uint16_t *a_org = a;
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#ifdef NO_UNALIGNED_MEM
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while (((uintptr_t)a & (sizeof(size_t) - 1)) && *a == *b)
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{
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a++;
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b++;
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}
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if (*a == *b)
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#endif
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{
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const size_t *a_big = (const size_t*)a;
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const size_t *b_big = (const size_t*)b;
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while (*a_big == *b_big)
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{
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a_big++;
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b_big++;
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}
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a = (const uint16_t*)a_big;
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b = (const uint16_t*)b_big;
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while (*a == *b)
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{
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a++;
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b++;
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}
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}
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return a - a_org;
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}
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#endif
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static inline size_t find_same(const uint16_t *a, const uint16_t *b)
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{
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const uint16_t *a_org = a;
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#ifdef NO_UNALIGNED_MEM
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if (((uintptr_t)a & (sizeof(uint32_t) - 1)) && *a != *b)
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{
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a++;
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b++;
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}
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if (*a != *b)
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#endif
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{
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// With this, it's random whether two consecutive identical words are caught.
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// Luckily, compression rate is the same for both cases, and three is always caught.
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// (We prefer to miss two-word blocks, anyways; fewer iterations of the outer loop, as well as in the decompressor.)
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const uint32_t *a_big = (const uint32_t*)a;
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const uint32_t *b_big = (const uint32_t*)b;
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while (*a_big != *b_big)
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{
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a_big++;
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b_big++;
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}
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a = (const uint16_t*)a_big;
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b = (const uint16_t*)b_big;
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if (a != a_org && a[-1] == b[-1])
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{
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a--;
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b--;
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}
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}
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return a - a_org;
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}
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void state_manager_push_do(state_manager_t *state)
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{
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if (state->thisblock_valid)
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{
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if (state->capacity < sizeof(size_t) + state->maxcompsize)
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return;
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recheckcapacity:;
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size_t headpos = state->head - state->data;
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size_t tailpos = state->tail - state->data;
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size_t remaining = (tailpos + state->capacity - sizeof(size_t) - headpos - 1) % state->capacity + 1;
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if (remaining <= state->maxcompsize)
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{
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state->tail = state->data + read_size_t(state->tail);
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state->entries--;
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goto recheckcapacity;
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}
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RARCH_PERFORMANCE_INIT(gen_deltas);
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RARCH_PERFORMANCE_START(gen_deltas);
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const uint8_t *oldb = state->thisblock;
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const uint8_t *newb = state->nextblock;
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uint8_t *compressed = state->head + sizeof(size_t);
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// Begin compression code; 'compressed' will point to the end of the compressed data (excluding the prev pointer).
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const uint16_t *old16 = (const uint16_t*)oldb;
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const uint16_t *new16 = (const uint16_t*)newb;
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uint16_t *compressed16 = (uint16_t*)compressed;
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size_t num16s = state->blocksize / sizeof(uint16_t);
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while (num16s)
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{
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size_t i;
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size_t skip = find_change(old16, new16);
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if (skip >= num16s)
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break;
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old16 += skip;
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new16 += skip;
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num16s -= skip;
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if (skip > UINT16_MAX)
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{
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if (skip > UINT32_MAX)
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{
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// This will make it scan the entire thing again, but it only hits on 8GB unchanged
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// data anyways, and if you're doing that, you've got bigger problems.
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skip = UINT32_MAX;
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}
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*compressed16++ = 0;
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*compressed16++ = skip;
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*compressed16++ = skip >> 16;
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skip = 0;
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continue;
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}
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size_t changed = find_same(old16, new16);
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if (changed > UINT16_MAX)
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changed = UINT16_MAX;
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*compressed16++ = changed;
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*compressed16++ = skip;
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for (i = 0; i < changed; i++)
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compressed16[i] = old16[i];
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old16 += changed;
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new16 += changed;
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num16s -= changed;
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compressed16 += changed;
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}
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compressed16[0] = 0;
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compressed16[1] = 0;
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compressed16[2] = 0;
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compressed = (uint8_t*)(compressed16 + 3);
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// End compression code.
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if (compressed - state->data + state->maxcompsize > state->capacity)
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{
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compressed = state->data;
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if (state->tail == state->data + sizeof(size_t))
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state->tail = state->data + read_size_t(state->tail);
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}
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write_size_t(compressed, state->head-state->data);
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compressed += sizeof(size_t);
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write_size_t(state->head, compressed-state->data);
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state->head = compressed;
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RARCH_PERFORMANCE_STOP(gen_deltas);
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}
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else
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state->thisblock_valid = true;
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uint8_t *swap = state->thisblock;
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state->thisblock = state->nextblock;
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state->nextblock = swap;
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state->entries++;
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return;
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}
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void state_manager_capacity(state_manager_t *state, unsigned *entries, size_t *bytes, bool *full)
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{
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size_t headpos = state->head - state->data;
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size_t tailpos = state->tail - state->data;
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size_t remaining = (tailpos + state->capacity - sizeof(size_t) - headpos - 1) % state->capacity + 1;
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if (entries)
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*entries = state->entries;
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if (bytes)
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*bytes = state->capacity-remaining;
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if (full)
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*full = remaining <= state->maxcompsize * 2;
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}
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