5be84f59e8
git-svn-id: svn+ssh://svn.corp.yahoo.com/yahoo/yrl/labs/pnuts/code/logstore@2451 8dad8b1f-cf64-0410-95b6-bcf113ffbcfe
405 lines
12 KiB
C++
405 lines
12 KiB
C++
#include "logstore.h"
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#include "datapage.h"
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#include "regionAllocator.h"
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#include <stasis/page.h>
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static const int DATA_PAGE = USER_DEFINED_PAGE(1);
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#define MAX_PAGE_COUNT 1000 // ~ 4MB
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BEGIN_C_DECLS
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static void dataPageFsck(Page* p) {
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int32_t is_last_page = *stasis_page_int32_cptr_from_start(p, 0);
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assert(is_last_page == 0 || is_last_page == 1 || is_last_page == 2);
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}
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static void dataPageLoaded(Page* p) {
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dataPageFsck(p);
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}
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static void dataPageFlushed(Page* p) {
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*stasis_page_lsn_ptr(p) = p->LSN;
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dataPageFsck(p);
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}
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static int notSupported(int xid, Page * p) { return 0; }
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END_C_DECLS
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template <class TUPLE>
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void DataPage<TUPLE>::register_stasis_page_impl() {
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static page_impl pi = {
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DATA_PAGE,
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1,
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0, //slottedRead,
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0, //slottedWrite,
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0,// readDone
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0,// writeDone
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0,//slottedGetType,
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0,//slottedSetType,
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0,//slottedGetLength,
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0,//slottedFirst,
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0,//slottedNext,
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0,//slottedLast,
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notSupported, // is block supported
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stasis_block_first_default_impl,
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stasis_block_next_default_impl,
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stasis_block_done_default_impl,
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0,//slottedFreespace,
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0,//slottedCompact,
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0,//slottedCompactSlotIDs,
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0,//slottedPreRalloc,
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0,//slottedPostRalloc,
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0,//slottedSpliceSlot,
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0,//slottedFree,
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0,//XXX page_impl_dereference_identity,
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dataPageLoaded, //dataPageLoaded,
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dataPageFlushed, //dataPageFlushed,
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0,//slottedCleanup
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};
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stasis_page_impl_register(pi);
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}
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template <class TUPLE>
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DataPage<TUPLE>::DataPage(int xid, RegionAllocator * alloc, pageid_t pid): // XXX Hack!! The read-only constructor signature is too close to the other's
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xid_(xid),
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page_count_(1), // will be opportunistically incremented as we scan the datapage.
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initial_page_count_(-1), // used by append.
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alloc_(alloc), // read-only, and we don't free data pages one at a time.
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first_page_(pid),
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write_offset_(-1)
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{
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assert(pid!=0);
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Page *p = alloc_ ? alloc_->load_page(xid, first_page_) : loadPage(xid, first_page_);
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if(!(*is_another_page_ptr(p) == 0 || *is_another_page_ptr(p) == 2)) {
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printf("Page %lld is not the start of a datapage\n", first_page_); fflush(stdout);
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abort();
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}
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assert(*is_another_page_ptr(p) == 0 || *is_another_page_ptr(p) == 2); // would be 1 for page in the middle of a datapage
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releasePage(p);
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}
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template <class TUPLE>
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DataPage<TUPLE>::DataPage(int xid, pageid_t page_count, RegionAllocator *alloc) :
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xid_(xid),
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page_count_(1),
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initial_page_count_(page_count),
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alloc_(alloc),
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first_page_(alloc_->alloc_extent(xid_, page_count_)),
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write_offset_(0)
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{
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DEBUG("Datapage page count: %lld pid = %lld\n", (long long int)initial_page_count_, (long long int)first_page_);
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assert(page_count_ >= 1);
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initialize();
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}
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template<class TUPLE>
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void DataPage<TUPLE>::initialize() {
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initialize_page(first_page_);
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}
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template<class TUPLE>
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void DataPage<TUPLE>::initialize_page(pageid_t pageid) {
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//load the first page
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Page *p;
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#ifdef CHECK_FOR_SCRIBBLING
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p = alloc_ ? alloc->load_page(xid_, pageid) : loadPage(xid_, pageid);
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if(*stasis_page_type_ptr(p) == DATA_PAGE) {
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printf("Collision on page %lld\n", (long long)pageid); fflush(stdout);
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assert(*stasis_page_type_ptr(p) != DATA_PAGE);
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}
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#else
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p = loadUninitializedPage(xid_, pageid);
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#endif
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DEBUG("\t\t\t\t\t\t->%lld\n", pageid);
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//initialize header
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p->pageType = DATA_PAGE;
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//clear page (arranges for null-padding) XXX null pad more carefully and use sentinel value instead?
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memset(p->memAddr, 0, PAGE_SIZE);
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//we're the last page for now.
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*is_another_page_ptr(p) = 0;
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//write 0 to first data size
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*length_at_offset_ptr(p, calc_chunk_from_offset(write_offset_).slot) = 0;
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//set the page dirty
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stasis_page_lsn_write(xid_, p, alloc_->get_lsn(xid_));
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releasePage(p);
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}
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template <class TUPLE>
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size_t DataPage<TUPLE>::write_bytes(const byte * buf, ssize_t remaining, Page ** latch_p) {
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if(latch_p) { *latch_p = NULL; }
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recordid chunk = calc_chunk_from_offset(write_offset_);
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if(chunk.size > remaining) {
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chunk.size = remaining;
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}
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if(chunk.page >= first_page_ + page_count_) {
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chunk.size = 0; // no space (should not happen)
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} else {
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Page *p = alloc_ ? alloc_->load_page(xid_, chunk.page) : loadPage(xid_, chunk.page);
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assert(chunk.size);
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memcpy(data_at_offset_ptr(p, chunk.slot), buf, chunk.size);
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stasis_page_lsn_write(xid_, p, alloc_->get_lsn(xid_));
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if(latch_p && !*latch_p) {
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writelock(p->rwlatch,0);
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*latch_p = p;
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} else {
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releasePage(p);
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}
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write_offset_ += chunk.size;
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}
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return chunk.size;
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}
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template <class TUPLE>
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size_t DataPage<TUPLE>::read_bytes(byte * buf, off_t offset, ssize_t remaining) {
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recordid chunk = calc_chunk_from_offset(offset);
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if(chunk.size > remaining) {
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chunk.size = remaining;
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}
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if(chunk.page >= first_page_ + page_count_) {
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chunk.size = 0; // eof
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} else {
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Page *p = alloc_ ? alloc_->load_page(xid_, chunk.page) : loadPage(xid_, chunk.page);
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if(p->pageType != DATA_PAGE) {
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fprintf(stderr, "Page type %d, id %lld lsn %lld\n", (int)p->pageType, (long long)p->id, (long long)p->LSN);
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assert(p->pageType == DATA_PAGE);
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}
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if((chunk.page + 1 == page_count_ + first_page_)
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&& (*is_another_page_ptr(p))) {
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page_count_++;
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}
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memcpy(buf, data_at_offset_ptr(p, chunk.slot), chunk.size);
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releasePage(p);
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}
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return chunk.size;
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}
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template <class TUPLE>
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bool DataPage<TUPLE>::initialize_next_page() {
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recordid rid = calc_chunk_from_offset(write_offset_);
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assert(rid.slot == 0);
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DEBUG("\t\t%lld\n", (long long)rid.page);
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if(rid.page >= first_page_ + page_count_) {
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assert(rid.page == first_page_ + page_count_);
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if(alloc_->grow_extent(1)) {
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page_count_++;
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} else {
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return false; // The region is full
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}
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} else {
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abort();
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}
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Page *p = alloc_ ? alloc_->load_page(xid_, rid.page-1) : loadPage(xid_, rid.page-1);
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*is_another_page_ptr(p) = (rid.page-1 == first_page_) ? 2 : 1;
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stasis_page_lsn_write(xid_, p, alloc_->get_lsn(xid_));
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releasePage(p);
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initialize_page(rid.page);
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return true;
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}
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template<class TUPLE>
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Page * DataPage<TUPLE>::write_data_and_latch(const byte * buf, size_t len, bool init_next, bool latch) {
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bool first = true;
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Page * p = 0;
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while(1) {
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assert(len > 0);
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// if(latch) {
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// if(first) { assert(!p); } else { assert(p); }
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// } else {
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// assert(!p);
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// }
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size_t written;
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if(latch && first ) {
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written = write_bytes(buf, len, &p);
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} else {
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written = write_bytes(buf, len);
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}
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if(written == 0) {
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assert(!p);
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return 0; // fail
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}
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if(written == len) {
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if(latch) {
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return p;
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} else {
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// assert(!p);
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return (Page*)1;
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}
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}
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if(len > PAGE_SIZE && ! first) {
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assert(written > 4000);
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}
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buf += written;
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len -= written;
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if(init_next) {
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if(!initialize_next_page()) {
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if(p) {
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// assert(latch);
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unlock(p->rwlatch);
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releasePage(p);
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}
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return 0; // fail
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}
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}
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first = false;
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}
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}
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template <class TUPLE>
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bool DataPage<TUPLE>::write_data(const byte * buf, size_t len, bool init_next) {
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return 0 != write_data_and_latch(buf, len, init_next, false);
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}
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template <class TUPLE>
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bool DataPage<TUPLE>::read_data(byte * buf, off_t offset, size_t len) {
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while(1) {
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assert(len > 0);
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size_t read_count = read_bytes(buf, offset, len);
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if(read_count == 0) {
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return false; // fail
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}
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if(read_count == len) {
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return true; // success
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}
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buf += read_count;
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offset += read_count;
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len -= read_count;
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}
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}
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template <class TUPLE>
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bool DataPage<TUPLE>::append(TUPLE const * dat)
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{
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// First, decide if we should append to this datapage, based on whether appending will waste more or less space than starting a new datapage
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bool accept_tuple;
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len_t tup_len = dat->byte_length();
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// Decsion tree
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if(write_offset_ > (initial_page_count_ * PAGE_SIZE)) {
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// we already exceeded the page budget
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if(write_offset_ > (2 * initial_page_count_ * PAGE_SIZE)) {
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// ... by a lot. Reject regardless.
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accept_tuple = false;
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} else {
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// ... by a little bit. Accept tuple if it fits on this page.
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accept_tuple = (((write_offset_-1) & ~(PAGE_SIZE-1)) == (((write_offset_ + tup_len)-1) & ~(PAGE_SIZE-1)));
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}
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} else {
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if(write_offset_ + tup_len < (initial_page_count_ * PAGE_SIZE)) {
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// tuple fits. contractually obligated to accept it.
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accept_tuple = true;
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} else if(write_offset_ == 0) {
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// datapage is emptry. contractually obligated to accept tuple.
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accept_tuple = true;
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} else {
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if(tup_len > initial_page_count_ * PAGE_SIZE) {
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// this is a "big tuple"
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len_t reject_padding = PAGE_SIZE - (write_offset_ & (PAGE_SIZE-1));
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len_t accept_padding = PAGE_SIZE - ((write_offset_ + tup_len) & (PAGE_SIZE-1));
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accept_tuple = accept_padding < reject_padding;
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} else {
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// this is a "small tuple"; only exceed budget if doing so leads to < 33% overhead for this data.
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len_t accept_padding = PAGE_SIZE - (write_offset_ & (PAGE_SIZE-1));
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accept_tuple = (3*accept_padding) < tup_len;
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}
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}
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}
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if(!accept_tuple) {
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DEBUG("offset %lld closing datapage\n", write_offset_);
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return false;
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}
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DEBUG("offset %lld continuing datapage\n", write_offset_);
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byte * buf = dat->to_bytes(); // TODO could be more efficient; this does a malloc and memcpy. The alternative couples us more strongly to datapage, but simplifies datapage.
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len_t dat_len = dat->byte_length();
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Page * p = write_data_and_latch((const byte*)&dat_len, sizeof(dat_len));
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bool succ = false;
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if(p) {
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succ = write_data(buf, dat_len);
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unlock(p->rwlatch);
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releasePage(p);
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}
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free(buf);
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return succ;
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}
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template <class TUPLE>
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bool DataPage<TUPLE>::recordRead(const typename TUPLE::key_t key, size_t keySize, TUPLE ** buf)
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{
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iterator itr(this, NULL);
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int match = -1;
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while((*buf=itr.getnext()) != 0)
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{
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match = TUPLE::compare((*buf)->strippedkey(), (*buf)->strippedkeylen(), key, keySize);
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if(match<0) //keep searching
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{
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datatuple::freetuple(*buf);
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*buf=0;
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}
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else if(match==0) //found
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{
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return true;
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}
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else // match > 0, then does not exist
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{
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datatuple::freetuple(*buf);
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*buf = 0;
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break;
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}
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}
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return false;
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}
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///////////////////////////////////////////////////////////////
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//RECORD ITERATOR
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///////////////////////////////////////////////////////////////
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template <class TUPLE>
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TUPLE* DataPage<TUPLE>::iterator::getnext()
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{
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len_t len;
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bool succ;
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if(dp == NULL) { return NULL; }
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// XXX hack: read latch the page that the record will live on.
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// This should be handled by a read_data_in_latch function, or something...
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Page * p = loadPage(dp->xid_, dp->calc_chunk_from_offset(read_offset_).page);
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readlock(p->rwlatch, 0);
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succ = dp->read_data((byte*)&len, read_offset_, sizeof(len));
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if((!succ) || (len == 0)) {
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unlock(p->rwlatch);
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releasePage(p);
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return NULL;
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}
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read_offset_ += sizeof(len);
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byte * buf = (byte*)malloc(len);
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succ = dp->read_data(buf, read_offset_, len);
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// release hacky latch
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unlock(p->rwlatch);
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releasePage(p);
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if(!succ) { read_offset_ -= sizeof(len); free(buf); return NULL; }
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read_offset_ += len;
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TUPLE *ret = TUPLE::from_bytes(buf);
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free(buf);
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return ret;
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}
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template class DataPage<datatuple>;
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