src/buffer.c@ed75dc1db503
src/buffer.c
Fri, 23 May 2025 12:44:24 +0200
- author
- Mike Becker <universe@uap-core.de>
- date
- Fri, 23 May 2025 12:44:24 +0200
- changeset 1327
- ed75dc1db503
- parent 1319
- aa1f580f8f59
- permissions
- -rw-r--r--
make test-compile depend on both static and shared
the shared lib is not needed for the tests,
but when run with coverage, gcov will be confused
when outdated line information is available from
a previous shared build
/* * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS HEADER. * * Copyright 2021 Mike Becker, Olaf Wintermann All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. */ #include "cx/buffer.h" #include <stdio.h> #include <string.h> #include <errno.h> #ifdef _WIN32 #include <Windows.h> #include <sysinfoapi.h> static unsigned long system_page_size() { static unsigned long ps = 0; if (ps == 0) { SYSTEM_INFO sysinfo; GetSystemInfo(&sysinfo); ps = sysinfo.dwPageSize; } return ps; } #define SYSTEM_PAGE_SIZE system_page_size() #else #include <unistd.h> #define SYSTEM_PAGE_SIZE sysconf(_SC_PAGESIZE) #endif static int buffer_copy_on_write(CxBuffer* buffer) { if (0 == (buffer->flags & CX_BUFFER_COPY_ON_WRITE)) return 0; void *newspace = cxMalloc(buffer->allocator, buffer->capacity); if (NULL == newspace) return -1; memcpy(newspace, buffer->space, buffer->size); buffer->space = newspace; buffer->flags &= ~CX_BUFFER_COPY_ON_WRITE; buffer->flags |= CX_BUFFER_FREE_CONTENTS; return 0; } int cxBufferInit( CxBuffer *buffer, void *space, size_t capacity, const CxAllocator *allocator, int flags ) { if (allocator == NULL) { allocator = cxDefaultAllocator; } if (flags & CX_BUFFER_COPY_ON_EXTEND) { flags |= CX_BUFFER_AUTO_EXTEND; } buffer->allocator = allocator; buffer->flags = flags; if (!space) { buffer->bytes = cxMalloc(allocator, capacity); if (buffer->bytes == NULL) { return -1; // LCOV_EXCL_LINE } buffer->flags |= CX_BUFFER_FREE_CONTENTS; } else { buffer->bytes = space; } buffer->capacity = capacity; buffer->size = 0; buffer->pos = 0; buffer->flush = NULL; return 0; } int cxBufferEnableFlushing( CxBuffer *buffer, CxBufferFlushConfig config ) { buffer->flush = cxMallocDefault(sizeof(CxBufferFlushConfig)); if (buffer->flush == NULL) return -1; // LCOV_EXCL_LINE memcpy(buffer->flush, &config, sizeof(CxBufferFlushConfig)); return 0; } void cxBufferDestroy(CxBuffer *buffer) { if (buffer->flags & CX_BUFFER_FREE_CONTENTS) { cxFree(buffer->allocator, buffer->bytes); } cxFreeDefault(buffer->flush); memset(buffer, 0, sizeof(CxBuffer)); } CxBuffer *cxBufferCreate( void *space, size_t capacity, const CxAllocator *allocator, int flags ) { if (allocator == NULL) { allocator = cxDefaultAllocator; } CxBuffer *buf = cxMalloc(allocator, sizeof(CxBuffer)); if (buf == NULL) return NULL; if (0 == cxBufferInit(buf, space, capacity, allocator, flags)) { return buf; } else { // LCOV_EXCL_START cxFree(allocator, buf); return NULL; // LCOV_EXCL_STOP } } void cxBufferFree(CxBuffer *buffer) { if (buffer == NULL) return; const CxAllocator *allocator = buffer->allocator; cxBufferDestroy(buffer); cxFree(allocator, buffer); } int cxBufferSeek( CxBuffer *buffer, off_t offset, int whence ) { size_t npos; switch (whence) { case SEEK_CUR: npos = buffer->pos; break; case SEEK_END: npos = buffer->size; break; case SEEK_SET: npos = 0; break; default: errno = EINVAL; return -1; } size_t opos = npos; npos += offset; if ((offset > 0 && npos < opos) || (offset < 0 && npos > opos)) { // to be compliant with fseek() specification // we return EINVAL on underflow errno = EINVAL; return -1; } if (npos > buffer->size) { // not compliant with fseek() specification // but this is the better behavior for CxBuffer errno = EINVAL; return -1; } else { buffer->pos = npos; return 0; } } void cxBufferClear(CxBuffer *buffer) { if (0 == (buffer->flags & CX_BUFFER_COPY_ON_WRITE)) { memset(buffer->bytes, 0, buffer->size); } buffer->size = 0; buffer->pos = 0; } void cxBufferReset(CxBuffer *buffer) { buffer->size = 0; buffer->pos = 0; } bool cxBufferEof(const CxBuffer *buffer) { return buffer->pos >= buffer->size; } int cxBufferMinimumCapacity( CxBuffer *buffer, size_t newcap ) { if (newcap <= buffer->capacity) { return 0; } unsigned long pagesize = SYSTEM_PAGE_SIZE; // if page size is larger than 64 KB - for some reason - truncate to 64 KB if (pagesize > 65536) pagesize = 65536; if (newcap < pagesize) { // when smaller as one page, map to the next power of two newcap--; newcap |= newcap >> 1; newcap |= newcap >> 2; newcap |= newcap >> 4; // last operation only needed for pages larger 4096 bytes // but if/else would be more expensive than just doing this newcap |= newcap >> 8; newcap++; } else { // otherwise, map to a multiple of the page size newcap -= newcap % pagesize; newcap += pagesize; // note: if newcap is already page aligned, // this gives a full additional page (which is good) } const int force_copy_flags = CX_BUFFER_COPY_ON_WRITE | CX_BUFFER_COPY_ON_EXTEND; if (buffer->flags & force_copy_flags) { void *newspace = cxMalloc(buffer->allocator, newcap); if (NULL == newspace) return -1; memcpy(newspace, buffer->space, buffer->size); buffer->space = newspace; buffer->capacity = newcap; buffer->flags &= ~force_copy_flags; buffer->flags |= CX_BUFFER_FREE_CONTENTS; return 0; } else if (cxReallocate(buffer->allocator, (void **) &buffer->bytes, newcap) == 0) { buffer->capacity = newcap; return 0; } else { return -1; // LCOV_EXCL_LINE } } void cxBufferShrink( CxBuffer *buffer, size_t reserve ) { // Ensure buffer is in a reallocatable state const int force_copy_flags = CX_BUFFER_COPY_ON_WRITE | CX_BUFFER_COPY_ON_EXTEND; if (buffer->flags & force_copy_flags) { // do nothing when we are not allowed to reallocate return; } // calculate new capacity size_t newCapacity = buffer->size + reserve; // If new capacity is smaller than current capacity, resize the buffer if (newCapacity < buffer->capacity) { if (0 == cxReallocate(buffer->allocator, &buffer->bytes, newCapacity)) { buffer->capacity = newCapacity; } } } static size_t cx_buffer_flush_helper( const CxBuffer *buffer, const unsigned char *src, size_t size, size_t nitems ) { // flush data from an arbitrary source // does not need to be the buffer's contents size_t max_items = buffer->flush->blksize / size; size_t fblocks = 0; size_t flushed_total = 0; while (nitems > 0 && fblocks < buffer->flush->blkmax) { fblocks++; size_t items = nitems > max_items ? max_items : nitems; size_t flushed = buffer->flush->wfunc( src, size, items, buffer->flush->target); if (flushed > 0) { flushed_total += flushed; src += flushed * size; nitems -= flushed; } else { // if no bytes can be flushed out anymore, we give up break; } } return flushed_total; } static size_t cx_buffer_flush_impl(CxBuffer *buffer, size_t size) { // flush the current contents of the buffer unsigned char *space = buffer->bytes; size_t remaining = buffer->pos / size; size_t flushed_total = cx_buffer_flush_helper( buffer, space, size, remaining); // shift the buffer left after flushing // IMPORTANT: up to this point, copy on write must have been // performed already, because we can't do error handling here cxBufferShiftLeft(buffer, flushed_total*size); return flushed_total; } size_t cxBufferFlush(CxBuffer *buffer) { if (buffer_copy_on_write(buffer)) return 0; return cx_buffer_flush_impl(buffer, 1); } size_t cxBufferWrite( const void *ptr, size_t size, size_t nitems, CxBuffer *buffer ) { // optimize for easy case if (size == 1 && (buffer->capacity - buffer->pos) >= nitems) { if (buffer_copy_on_write(buffer)) return 0; memcpy(buffer->bytes + buffer->pos, ptr, nitems); buffer->pos += nitems; if (buffer->pos > buffer->size) { buffer->size = buffer->pos; } return nitems; } size_t len, total_flushed = 0; cx_buffer_write_retry: if (cx_szmul(size, nitems, &len)) { errno = EOVERFLOW; return total_flushed; } if (buffer->pos > SIZE_MAX - len) { errno = EOVERFLOW; return total_flushed; } size_t required = buffer->pos + len; bool perform_flush = false; if (required > buffer->capacity) { if (buffer->flags & CX_BUFFER_AUTO_EXTEND) { if (buffer->flush != NULL && required > buffer->flush->threshold) { perform_flush = true; } else { if (cxBufferMinimumCapacity(buffer, required)) { return total_flushed; // LCOV_EXCL_LINE } } } else { if (buffer->flush != NULL) { perform_flush = true; } else { // truncate data, if we can neither extend nor flush len = buffer->capacity - buffer->pos; if (size > 1) { len -= len % size; } nitems = len / size; } } } // check here and not above because of possible truncation if (len == 0) { return total_flushed; } // check if we need to copy if (buffer_copy_on_write(buffer)) return 0; // perform the operation if (perform_flush) { size_t items_flushed; if (buffer->pos == 0) { // if we don't have data in the buffer, but are instructed // to flush, it means that we are supposed to relay the data items_flushed = cx_buffer_flush_helper(buffer, ptr, size, nitems); if (items_flushed == 0) { // we needed to relay data, but could not flush anything // i.e. we have to give up to avoid endless trying return 0; } nitems -= items_flushed; total_flushed += items_flushed; if (nitems > 0) { ptr = ((unsigned char*)ptr) + items_flushed * size; goto cx_buffer_write_retry; } return total_flushed; } else { items_flushed = cx_buffer_flush_impl(buffer, size); if (items_flushed == 0) { // flush target is full, let's try to truncate size_t remaining_space; if (buffer->flags & CX_BUFFER_AUTO_EXTEND) { remaining_space = buffer->flush->threshold > buffer->pos ? buffer->flush->threshold - buffer->pos : 0; } else { remaining_space = buffer->capacity > buffer->pos ? buffer->capacity - buffer->pos : 0; } nitems = remaining_space / size; if (nitems == 0) { return total_flushed; } } goto cx_buffer_write_retry; } } else { memcpy(buffer->bytes + buffer->pos, ptr, len); buffer->pos += len; if (buffer->pos > buffer->size) { buffer->size = buffer->pos; } return total_flushed + nitems; } } size_t cxBufferAppend( const void *ptr, size_t size, size_t nitems, CxBuffer *buffer ) { size_t pos = buffer->pos; size_t append_pos = buffer->size; buffer->pos = append_pos; size_t written = cxBufferWrite(ptr, size, nitems, buffer); // the buffer might have been flushed // we must compute a possible delta for the position // expected: pos = append_pos + written // -> if this is not the case, there is a delta size_t delta = append_pos + written*size - buffer->pos; if (delta > pos) { buffer->pos = 0; } else { buffer->pos = pos - delta; } return written; } int cxBufferPut( CxBuffer *buffer, int c ) { c &= 0xFF; unsigned char const ch = c; if (cxBufferWrite(&ch, 1, 1, buffer) == 1) { return c; } else { return EOF; } } int cxBufferTerminate(CxBuffer *buffer) { if (0 == cxBufferPut(buffer, 0)) { buffer->size = buffer->pos - 1; return 0; } else { return -1; } } size_t cxBufferPutString( CxBuffer *buffer, const char *str ) { return cxBufferWrite(str, 1, strlen(str), buffer); } size_t cxBufferRead( void *ptr, size_t size, size_t nitems, CxBuffer *buffer ) { size_t len; if (cx_szmul(size, nitems, &len)) { errno = EOVERFLOW; return 0; } if (buffer->pos + len > buffer->size) { len = buffer->size - buffer->pos; if (size > 1) len -= len % size; } if (len <= 0) { return len; } memcpy(ptr, buffer->bytes + buffer->pos, len); buffer->pos += len; return len / size; } int cxBufferGet(CxBuffer *buffer) { if (cxBufferEof(buffer)) { return EOF; } else { int c = buffer->bytes[buffer->pos]; buffer->pos++; return c; } } int cxBufferShiftLeft( CxBuffer *buffer, size_t shift ) { if (shift >= buffer->size) { buffer->pos = buffer->size = 0; } else { if (buffer_copy_on_write(buffer)) return -1; memmove(buffer->bytes, buffer->bytes + shift, buffer->size - shift); buffer->size -= shift; if (buffer->pos >= shift) { buffer->pos -= shift; } else { buffer->pos = 0; } } return 0; } int cxBufferShiftRight( CxBuffer *buffer, size_t shift ) { if (buffer->size > SIZE_MAX - shift) { errno = EOVERFLOW; return -1; } size_t req_capacity = buffer->size + shift; size_t movebytes; // auto extend buffer, if required and enabled if (buffer->capacity < req_capacity) { if (buffer->flags & CX_BUFFER_AUTO_EXTEND) { if (cxBufferMinimumCapacity(buffer, req_capacity)) { return -1; // LCOV_EXCL_LINE } movebytes = buffer->size; } else { movebytes = buffer->capacity - shift; } } else { movebytes = buffer->size; } if (movebytes > 0) { if (buffer_copy_on_write(buffer)) return -1; memmove(buffer->bytes + shift, buffer->bytes, movebytes); buffer->size = shift + movebytes; } buffer->pos += shift; if (buffer->pos > buffer->size) { buffer->pos = buffer->size; } return 0; } int cxBufferShift( CxBuffer *buffer, off_t shift ) { if (shift < 0) { return cxBufferShiftLeft(buffer, (size_t) (-shift)); } else if (shift > 0) { return cxBufferShiftRight(buffer, (size_t) shift); } else { return 0; } }
