// The MIT License // // Copyright (C) 2011 by Joseph Wayne Norton // // Permission is hereby granted, free of charge, to any person obtaining a copy // of this software and associated documentation files (the "Software"), to deal // in the Software without restriction, including without limitation the rights // to use, copy, modify, merge, publish, distribute, sublicense, and/or sell // copies of the Software, and to permit persons to whom the Software is // furnished to do so, subject to the following conditions: // // The above copyright notice and this permission notice shall be included in // all copies or substantial portions of the Software. // // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR // IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, // FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE // AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER // LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, // OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN // THE SOFTWARE. #include "lets_drv.h" #include "lets_drv_lib.h" #include #if 0 #define GOTOBADARG { fprintf(stderr, "GOTOBADARG %s:%d\n", __FILE__, __LINE__); goto badarg; } #else #define GOTOBADARG { goto badarg; } #endif #define LETS_BADARG 0x00 #define LETS_TRUE 0x01 #define LETS_FALSE 0x02 #define LETS_END_OF_TABLE 0x03 #define LETS_BINARY 0x04 #define LETS_OPEN6 0x00 // same as OPEN #define LETS_DESTROY6 0x01 // same as DESTROY #define LETS_REPAIR6 0x02 // same as REPAIR #define LETS_DELETE1 0x03 #define LETS_DELETE2 0x04 #define LETS_DELETE_ALL_OBJECTS1 0x05 #define LETS_FIRST1 0x06 #define LETS_FIRST_ITER1 0x07 #define LETS_INFO_MEMORY1 0x08 #define LETS_INFO_SIZE1 0x09 #define LETS_INSERT2 0x0A #define LETS_INSERT3 0x0B #define LETS_INSERT_NEW2 0x0C #define LETS_INSERT_NEW3 0x0D #define LETS_LAST1 0x0E #define LETS_LAST_ITER1 0x0F #define LETS_LOOKUP2 0x10 #define LETS_MEMBER2 0x11 #define LETS_NEXT2 0x12 #define LETS_NEXT_ITER2 0x13 #define LETS_PREV2 0x14 #define LETS_PREV_ITER2 0x15 // DrvData typedef struct { ErlDrvPort port; lets_impl impl; } DrvData; struct DrvAsync { DrvData* drvdata; ErlDrvTermData caller; int command; // outputs ErlDrvBinary* binary; int reply; // inputs leveldb::WriteBatch batch; DrvAsync(DrvData* d, ErlDrvTermData c, int cmd) : drvdata(d), caller(c), command(cmd), binary(NULL), reply(LETS_TRUE) { } DrvAsync(DrvData* d, ErlDrvTermData c, int cmd, const char* key, int keylen) : drvdata(d), caller(c), command(cmd), binary(NULL), reply(LETS_TRUE) { binary = driver_alloc_binary(keylen); assert(binary); memcpy(binary->orig_bytes, key, binary->orig_size); } ~DrvAsync() { if (binary) { driver_free_binary(binary); } } void put(const char* key, int keylen, const char* blob, int bloblen) { leveldb::Slice skey(key, keylen); leveldb::Slice sblob(blob, bloblen); batch.Put(skey, sblob); } void del(const char* key, int keylen) { leveldb::Slice skey(key, keylen); batch.Delete(skey); } }; static void lets_output_create6(const char op, DrvData* d, char* buf, int len, int* index, int items); static void lets_async_create6(void* async_data); static void lets_output_open6(DrvData* d, char* buf, int len, int* index, int items); static void lets_output_destroy6(DrvData* d, char* buf, int len, int* index, int items); static void lets_output_repair6(DrvData* d, char* buf, int len, int* index, int items); static void lets_output_insert2(DrvData* d, char* buf, int len, int* index, int items); static void lets_async_insert2(void* async_data); static void lets_output_insert3(DrvData* d, char* buf, int len, int* index, int items); static void lets_async_insert3(void* async_data); // static void lets_output_insert_new2(DrvData* d, char* buf, int len, int* index, int items); // static void lets_async_insert_new2(void* async_data); // static void lets_output_insert_new3(DrvData* d, char* buf, int len, int* index, int items); // static void lets_async_insert_new3(void* async_data); static void lets_output_delete1(DrvData* d, char* buf, int len, int* index, int items); static void lets_async_delete1(void* async_data); static void lets_output_delete2(DrvData* d, char* buf, int len, int* index, int items); static void lets_async_delete2(void* async_data); // static void lets_output_delete_all_objects1(DrvData* d, char* buf, int len, int* index, int items); // static void lets_async_delete_all_objects1(void* async_data); static void lets_output_lookup2(DrvData* d, char* buf, int len, int* index, int items); static void lets_async_lookup2(void* async_data); static void lets_output_member2(DrvData* d, char* buf, int len, int* index, int items); static void lets_async_member2(void* async_data); static void lets_output_first1(DrvData* d, char* buf, int len, int* index, int items); static void lets_async_first1(void* async_data); static void lets_output_first_iter1(DrvData* d, char* buf, int len, int* index, int items); static void lets_async_first_iter1(void* async_data); static void lets_output_last1(DrvData* d, char* buf, int len, int* index, int items); static void lets_async_last1(void* async_data); static void lets_output_last_iter1(DrvData* d, char* buf, int len, int* index, int items); static void lets_async_last_iter1(void* async_data); static void lets_output_next2(DrvData* d, char* buf, int len, int* index, int items); static void lets_async_next2(void* async_data); static void lets_output_next_iter2(DrvData* d, char* buf, int len, int* index, int items); static void lets_async_next_iter2(void* async_data); static void lets_output_prev2(DrvData* d, char* buf, int len, int* index, int items); static void lets_async_prev2(void* async_data); static void lets_output_prev_iter2(DrvData* d, char* buf, int len, int* index, int items); static void lets_async_prev_iter2(void* async_data); // static void lets_output_info_memory1(DrvData* d, char* buf, int len, int* index, int items); // static void lets_async_info_memory1(void* async_data); // static void lets_output_info_size1(DrvData* d, char* buf, int len, int* index, int items); // static void lets_async_info_size1(void* async_data); static void driver_send_int(DrvData* d, const int i, ErlDrvTermData caller=0) { ErlDrvTermData spec[] = { ERL_DRV_PORT, driver_mk_port(d->port), ERL_DRV_INT, i, ERL_DRV_TUPLE, 2, }; if (!caller) { caller = driver_caller(d->port); } driver_send_term(d->port, caller, spec, sizeof(spec) / sizeof(spec[0])); } static void driver_send_binary(DrvData* d, ErlDrvBinary* bin, ErlDrvTermData caller=0) { ErlDrvTermData spec[] = { ERL_DRV_PORT, driver_mk_port(d->port), ERL_DRV_INT, LETS_BINARY, ERL_DRV_BINARY, (ErlDrvTermData) bin, bin->orig_size, 0, ERL_DRV_TUPLE, 3, }; if (!caller) { caller = driver_caller(d->port); } driver_send_term(d->port, caller, spec, sizeof(spec) / sizeof(spec[0])); } static void driver_send_buf(DrvData* d, const char *buf, const ErlDrvUInt len, ErlDrvTermData caller=0) { ErlDrvTermData spec[] = { ERL_DRV_PORT, driver_mk_port(d->port), ERL_DRV_INT, LETS_BINARY, ERL_DRV_BUF2BINARY, (ErlDrvTermData) buf, len, ERL_DRV_TUPLE, 3, }; if (!caller) { caller = driver_caller(d->port); } driver_send_term(d->port, caller, spec, sizeof(spec) / sizeof(spec[0])); } // // Callbacks // static ErlDrvEntry drv_driver_entry = { drv_init, drv_start, drv_stop, drv_output, NULL, NULL, (char*) "lets_drv", NULL, NULL, NULL, NULL, NULL, drv_ready_async, NULL, NULL, NULL, ERL_DRV_EXTENDED_MARKER, ERL_DRV_EXTENDED_MAJOR_VERSION, ERL_DRV_EXTENDED_MINOR_VERSION, ERL_DRV_FLAG_USE_PORT_LOCKING, NULL, NULL, NULL }; DRIVER_INIT (lets_drv) // must match name in driver_entry { return &drv_driver_entry; } int drv_init() { if (!lets_drv_lib_init()) { return -1; } return 0; } ErlDrvData drv_start(ErlDrvPort port, char* command) { DrvData* d; if (port == NULL) { return ERL_DRV_ERROR_GENERAL; } if ((d = (DrvData*) driver_alloc(sizeof(DrvData))) == NULL) { errno = ENOMEM; return ERL_DRV_ERROR_ERRNO; } else { memset(d, 0, sizeof(DrvData)); } // port d->port = port; return (ErlDrvData) d; } void drv_stop(ErlDrvData handle) { DrvData* d = (DrvData*) handle; // alive d->impl.alive = 0; // db delete d->impl.db; // db_block_cache delete d->impl.db_block_cache; // name delete d->impl.name; driver_free(handle); } void drv_output(ErlDrvData handle, char* buf, int len) { DrvData* d = (DrvData*) handle; int ng, index, version, items; char command; #if 0 { int term_type, size_needed; index = 0; ng = ei_decode_version(buf, &index, &version); if (ng) GOTOBADARG; ng = ei_get_type(buf, &index, &term_type, &size_needed); if (ng) GOTOBADARG; fprintf(stderr, "DEBUG %c %d: ", term_type, (int) size_needed); index = 0; ng = ei_decode_version(buf, &index, &version); if (ng) GOTOBADARG; ei_print_term(stderr, buf, &index); fprintf(stderr, "\n"); } #endif index = 0; ng = ei_decode_version(buf, &index, &version); if (ng) GOTOBADARG; ng = ei_decode_tuple_header(buf, &index, &items); if (ng) GOTOBADARG; ng = (items < 1); if (ng) GOTOBADARG; ng = ei_decode_char(buf, &index, &command); if (ng) GOTOBADARG; items--; switch (command) { case LETS_OPEN6: ng = (items != 6); if (ng) GOTOBADARG; lets_output_open6(d, buf, len, &index, items); break; case LETS_DESTROY6: ng = (items != 6); if (ng) GOTOBADARG; lets_output_destroy6(d, buf, len, &index, items); break; case LETS_REPAIR6: ng = (items != 6); if (ng) GOTOBADARG; lets_output_repair6(d, buf, len, &index, items); break; case LETS_INSERT2: ng = (items != 1 || !d->impl.alive); if (ng) GOTOBADARG; lets_output_insert2(d, buf, len, &index, items); break; case LETS_INSERT3: ng = (items != 2 || !d->impl.alive); if (ng) GOTOBADARG; lets_output_insert3(d, buf, len, &index, items); break; case LETS_INSERT_NEW2: ng = (items != 1 || !d->impl.alive); if (ng) GOTOBADARG; GOTOBADARG; break; case LETS_INSERT_NEW3: ng = (items != 2 || !d->impl.alive); if (ng) GOTOBADARG; GOTOBADARG; break; case LETS_DELETE1: ng = (items != 0 || !d->impl.alive); if (ng) GOTOBADARG; lets_output_delete1(d, buf, len, &index, items); break; case LETS_DELETE2: ng = (items != 1 || !d->impl.alive); if (ng) GOTOBADARG; lets_output_delete2(d, buf, len, &index, items); break; case LETS_DELETE_ALL_OBJECTS1: ng = (items != 0 || !d->impl.alive); if (ng) GOTOBADARG; GOTOBADARG; break; case LETS_LOOKUP2: ng = (items != 1 || !d->impl.alive); if (ng) GOTOBADARG; lets_output_lookup2(d, buf, len, &index, items); break; case LETS_MEMBER2: ng = (items != 1 || !d->impl.alive); if (ng) GOTOBADARG; lets_output_member2(d, buf, len, &index, items); break; case LETS_FIRST1: ng = (items != 0 || !d->impl.alive); if (ng) GOTOBADARG; lets_output_first1(d, buf, len, &index, items); break; case LETS_FIRST_ITER1: ng = (items != 0 || !d->impl.alive); if (ng) GOTOBADARG; lets_output_first_iter1(d, buf, len, &index, items); break; case LETS_LAST1: ng = (items != 0 || !d->impl.alive); if (ng) GOTOBADARG; lets_output_last1(d, buf, len, &index, items); break; case LETS_LAST_ITER1: ng = (items != 0 || !d->impl.alive); if (ng) GOTOBADARG; lets_output_last_iter1(d, buf, len, &index, items); break; case LETS_NEXT2: ng = (items != 1 || !d->impl.alive); if (ng) GOTOBADARG; lets_output_next2(d, buf, len, &index, items); break; case LETS_NEXT_ITER2: ng = (items != 1 || !d->impl.alive); if (ng) GOTOBADARG; lets_output_next_iter2(d, buf, len, &index, items); break; case LETS_PREV2: ng = (items != 1 || !d->impl.alive); if (ng) GOTOBADARG; lets_output_prev2(d, buf, len, &index, items); break; case LETS_PREV_ITER2: ng = (items != 1 || !d->impl.alive); if (ng) GOTOBADARG; lets_output_prev_iter2(d, buf, len, &index, items); break; case LETS_INFO_MEMORY1: ng = (items != 0 || !d->impl.alive); if (ng) GOTOBADARG; GOTOBADARG; break; case LETS_INFO_SIZE1: ng = (items != 0 || !d->impl.alive); if (ng) GOTOBADARG; GOTOBADARG; break; default: GOTOBADARG; } return; badarg: driver_send_int(d, LETS_BADARG); return; } void drv_ready_async(ErlDrvData handle, ErlDrvThreadData async_data) { DrvData* d = (DrvData*) handle; DrvAsync* a = (DrvAsync*) async_data; assert(a != NULL); switch (a->reply) { case LETS_BADARG: driver_send_int(d, LETS_BADARG, a->caller); break; case LETS_TRUE: driver_send_int(d, LETS_TRUE, a->caller); break; case LETS_FALSE: driver_send_int(d, LETS_FALSE, a->caller); break; case LETS_END_OF_TABLE: driver_send_int(d, LETS_END_OF_TABLE, a->caller); break; case LETS_BINARY: driver_send_binary(d, a->binary, a->caller); break; default: driver_send_int(d, LETS_BADARG, a->caller); } delete a; } void drv_async_free(void* async_data) { DrvAsync* a = (DrvAsync*) async_data; delete a; } // // Commands // static void lets_output_create6(const char op, DrvData* d, char* buf, int len, int* index, int items) { DrvAsync* drv_async = NULL; char type; char privacy; char *name; long namelen; char* options; int options_len; char* read_options; int read_options_len; char* write_options; int write_options_len; int ng, term_type, size_needed; if (!ei_inspect_atom(buf, index, (char*) "set")) { type = SET; } else if (!ei_inspect_atom(buf, index, (char*) "ordered_set")) { type = ORDERED_SET; } else { GOTOBADARG; } if (!ei_inspect_atom(buf, index, (char*) "private")) { privacy = PRIVATE; } else if (!ei_inspect_atom(buf, index, (char*) "protected")) { privacy = PROTECTED; } else if (!ei_inspect_atom(buf, index, (char*) "public")) { privacy = PUBLIC; } else { GOTOBADARG; } ng = ei_inspect_binary(buf, index, (void**) &name, &namelen); if (ng) GOTOBADARG; if (!namelen) GOTOBADARG; ng = ei_get_type(buf, index, &term_type, &size_needed); if (ng) GOTOBADARG; if (!(term_type == ERL_LIST_EXT || term_type == ERL_NIL_EXT)) GOTOBADARG; options = buf + *index; options_len = size_needed; ng = ei_skip_term(buf, index); if (ng) GOTOBADARG; ng = ei_get_type(buf, index, &term_type, &size_needed); if (ng) GOTOBADARG; if (!(term_type == ERL_LIST_EXT || term_type == ERL_NIL_EXT)) GOTOBADARG; read_options = buf + *index; read_options_len = size_needed; ng = ei_skip_term(buf, index); if (ng) GOTOBADARG; ng = ei_get_type(buf, index, &term_type, &size_needed); if (ng) GOTOBADARG; if (!(term_type == ERL_LIST_EXT || term_type == ERL_NIL_EXT)) GOTOBADARG; write_options = buf + *index; write_options_len = size_needed; ng = ei_skip_term(buf, index); if (ng) GOTOBADARG; if (!lets_init(d->impl, type, privacy, name, namelen)) { GOTOBADARG; } if (!lets_parse_options(d->impl, options, options_len)) { GOTOBADARG; } if (!lets_parse_read_options(d->impl, read_options, read_options_len)) { GOTOBADARG; } if (!lets_parse_write_options(d->impl, write_options, write_options_len)) { GOTOBADARG; } if (d->impl.async) { drv_async = new DrvAsync(d, driver_caller(d->port), op); if (!drv_async) { GOTOBADARG; } driver_async(d->port, NULL, lets_async_create6, drv_async, drv_async_free); } else { if (!lets_create(d->impl, op)) { GOTOBADARG; } driver_send_int(d, LETS_TRUE); } return; badarg: if (drv_async) { delete drv_async; } driver_send_int(d, LETS_BADARG); return; } static void lets_async_create6(void* async_data) { DrvAsync* a = (DrvAsync*) async_data; assert(a != NULL); DrvData* d = a->drvdata; if (!lets_create(d->impl, a->command)) { a->reply = LETS_BADARG; } else { a->reply = LETS_TRUE; } } static void lets_output_open6(DrvData* d, char* buf, int len, int* index, int items) { lets_output_create6(OPEN, d, buf, len, index, items); } static void lets_output_destroy6(DrvData* d, char* buf, int len, int* index, int items) { lets_output_create6(DESTROY, d, buf, len, index, items); } static void lets_output_repair6(DrvData* d, char* buf, int len, int* index, int items) { lets_output_create6(REPAIR, d, buf, len, index, items); } static void lets_output_insert2(DrvData* d, char* buf, int len, int* index, int items) { DrvAsync* drv_async = NULL; int ng, arity; char *key; long keylen; char *blob; long bloblen; leveldb::WriteBatch batch; leveldb::Status status; ng = ei_decode_list_header(buf, index, &items); if (ng) GOTOBADARG; if (!items) { driver_send_int(d, LETS_TRUE); return; } if (d->impl.async) { drv_async = new DrvAsync(d, driver_caller(d->port), LETS_INSERT2); if (!drv_async) { GOTOBADARG; } } while (items) { ng = ei_decode_tuple_header(buf, index, &arity); if (ng) GOTOBADARG; ng = (arity != 2); if (ng) GOTOBADARG; ng = ei_inspect_binary(buf, index, (void**) &key, &keylen); if (ng) GOTOBADARG; ng = ei_inspect_binary(buf, index, (void**) &blob, &bloblen); if (ng) GOTOBADARG; if (drv_async) { drv_async->put((const char*) key, keylen, (const char*) blob, bloblen); } else { leveldb::Slice skey((const char*) key, keylen); leveldb::Slice sblob((const char*) blob, bloblen); batch.Put(skey, sblob); } items--; } ng = ei_decode_list_header(buf, index, &items); if (ng) GOTOBADARG; ng = (items != 0); if (ng) GOTOBADARG; if (drv_async) { driver_async(d->port, NULL, lets_async_insert2, drv_async, drv_async_free); } else { status = d->impl.db->Write(d->impl.db_write_options, &batch); if (!status.ok()) { GOTOBADARG; } driver_send_int(d, LETS_TRUE); } return; badarg: if (drv_async) { delete drv_async; } driver_send_int(d, LETS_BADARG); return; } static void lets_async_insert2(void* async_data) { DrvAsync* a = (DrvAsync*) async_data; assert(a != NULL); DrvData* d = a->drvdata; leveldb::Status status = d->impl.db->Write(d->impl.db_write_options, &(a->batch)); if (!status.ok()) { a->reply = LETS_BADARG; } else { a->reply = LETS_TRUE; } } static void lets_output_insert3(DrvData* d, char* buf, int len, int* index, int items) { DrvAsync* drv_async = NULL; int ng; char *key; long keylen; char *blob; long bloblen; leveldb::WriteBatch batch; leveldb::Status status; ng = ei_inspect_binary(buf, index, (void**) &key, &keylen); if (ng) GOTOBADARG; ng = ei_inspect_binary(buf, index, (void**) &blob, &bloblen); if (ng) GOTOBADARG; if (d->impl.async) { drv_async = new DrvAsync(d, driver_caller(d->port), LETS_INSERT3); if (!drv_async) { GOTOBADARG; } drv_async->put((const char*) key, keylen, (const char*) blob, bloblen); } else { leveldb::Slice skey((const char*) key, keylen); leveldb::Slice sblob((const char*) blob, bloblen); batch.Put(skey, sblob); } if (drv_async) { driver_async(d->port, NULL, lets_async_insert3, drv_async, drv_async_free); } else { status = d->impl.db->Write(d->impl.db_write_options, &batch); if (!status.ok()) { GOTOBADARG; } driver_send_int(d, LETS_TRUE); } return; badarg: if (drv_async) { delete drv_async; } driver_send_int(d, LETS_BADARG); return; } static void lets_async_insert3(void* async_data) { DrvAsync* a = (DrvAsync*) async_data; assert(a != NULL); DrvData* d = a->drvdata; leveldb::Status status = d->impl.db->Write(d->impl.db_write_options, &(a->batch)); if (!status.ok()) { a->reply = LETS_BADARG; } else { a->reply = LETS_TRUE; } } static void lets_output_delete1(DrvData* d, char* buf, int len, int* index, int items) { DrvAsync* drv_async = NULL; leveldb::WriteOptions db_write_options; leveldb::WriteBatch batch; leveldb::Status status; // alive d->impl.alive = 0; if (d->impl.async) { drv_async = new DrvAsync(d, driver_caller(d->port), LETS_DELETE1); if (!drv_async) { GOTOBADARG; } driver_async(d->port, NULL, lets_async_delete1, drv_async, drv_async_free); } else { db_write_options.sync = true; status = d->impl.db->Write(db_write_options, &batch); if (!status.ok()) { GOTOBADARG; } // @TBD This is quite risky ... need to re-consider. // delete d->impl.db; // d->impl.db = NULL; driver_send_int(d, LETS_TRUE); } return; badarg: if (drv_async) { delete drv_async; } driver_send_int(d, LETS_BADARG); return; } static void lets_async_delete1(void* async_data) { DrvAsync* a = (DrvAsync*) async_data; assert(a != NULL); DrvData* d = a->drvdata; leveldb::WriteOptions db_write_options; leveldb::WriteBatch batch; db_write_options.sync = true; leveldb::Status status = d->impl.db->Write(d->impl.db_write_options, &batch); if (!status.ok()) { a->reply = LETS_BADARG; } else { // @TBD This is quite risky ... need to re-consider. // delete d->impl.db; // d->impl.db = NULL; a->reply = LETS_TRUE; } } static void lets_output_delete2(DrvData* d, char* buf, int len, int* index, int items) { DrvAsync* drv_async = NULL; int ng; char *key; long keylen; leveldb::WriteBatch batch; leveldb::Status status; ng = ei_inspect_binary(buf, index, (void**) &key, &keylen); if (ng) GOTOBADARG; if (d->impl.async) { drv_async = new DrvAsync(d, driver_caller(d->port), LETS_INSERT2); if (!drv_async) { GOTOBADARG; } drv_async->del((const char*) key, keylen); } else { leveldb::Slice skey((const char*) key, keylen); batch.Delete(skey); } if (drv_async) { driver_async(d->port, NULL, lets_async_delete2, drv_async, drv_async_free); } else { status = d->impl.db->Write(d->impl.db_write_options, &batch); if (!status.ok()) { GOTOBADARG; } driver_send_int(d, LETS_TRUE); } return; badarg: if (drv_async) { delete drv_async; } driver_send_int(d, LETS_BADARG); return; } static void lets_async_delete2(void* async_data) { DrvAsync* a = (DrvAsync*) async_data; assert(a != NULL); DrvData* d = a->drvdata; leveldb::Status status = d->impl.db->Write(d->impl.db_write_options, &(a->batch)); if (!status.ok()) { a->reply = LETS_BADARG; } else { a->reply = LETS_TRUE; } } static void lets_output_lookup2(DrvData* d, char* buf, int len, int* index, int items) { DrvAsync* drv_async = NULL; int ng; char *key; long keylen; ng = ei_inspect_binary(buf, index, (void**) &key, &keylen); if (ng) GOTOBADARG; if (d->impl.async) { drv_async = new DrvAsync(d, driver_caller(d->port), LETS_LOOKUP2, (const char*) key, keylen); if (!drv_async) { GOTOBADARG; } driver_async(d->port, NULL, lets_async_lookup2, drv_async, drv_async_free); } else { leveldb::Iterator* it = d->impl.db->NewIterator(d->impl.db_read_options); if (!it) { GOTOBADARG; } leveldb::Slice skey((const char*) key, keylen); it->Seek(skey); if (!it->Valid() || it->key().compare(skey) != 0) { driver_send_int(d, LETS_END_OF_TABLE); delete it; return; } driver_send_buf(d, it->value().data(), it->value().size()); delete it; } return; badarg: if (drv_async) { delete drv_async; } driver_send_int(d, LETS_BADARG); return; } static void lets_async_lookup2(void* async_data) { DrvAsync* a = (DrvAsync*) async_data; assert(a != NULL); DrvData* d = a->drvdata; leveldb::Iterator* it = d->impl.db->NewIterator(d->impl.db_read_options); if (!it) { a->reply = LETS_BADARG; return; } leveldb::Slice skey((const char*) a->binary->orig_bytes, a->binary->orig_size); it->Seek(skey); if (!it->Valid() || it->key().compare(skey) != 0) { a->reply = LETS_END_OF_TABLE; delete it; return; } ErlDrvBinary* binary = driver_realloc_binary(a->binary, it->value().size()); if (binary) { memcpy(binary->orig_bytes, it->value().data(), binary->orig_size); a->binary = binary; a->reply = LETS_BINARY; } else { a->reply = LETS_BADARG; } delete it; } static void lets_output_member2(DrvData* d, char* buf, int len, int* index, int items) { DrvAsync* drv_async = NULL; int ng; char *key; long keylen; ng = ei_inspect_binary(buf, index, (void**) &key, &keylen); if (ng) GOTOBADARG; if (d->impl.async) { drv_async = new DrvAsync(d, driver_caller(d->port), LETS_MEMBER2, (const char*) key, keylen); if (!drv_async) { GOTOBADARG; } driver_async(d->port, NULL, lets_async_member2, drv_async, drv_async_free); } else { leveldb::Iterator* it = d->impl.db->NewIterator(d->impl.db_read_options); if (!it) { GOTOBADARG; } leveldb::Slice skey((const char*) key, keylen); it->Seek(skey); if (!it->Valid() || it->key().compare(skey) != 0) { driver_send_int(d, LETS_FALSE); delete it; return; } driver_send_int(d, LETS_TRUE); delete it; } return; badarg: if (drv_async) { delete drv_async; } driver_send_int(d, LETS_BADARG); return; } static void lets_async_member2(void* async_data) { DrvAsync* a = (DrvAsync*) async_data; assert(a != NULL); DrvData* d = a->drvdata; leveldb::Iterator* it = d->impl.db->NewIterator(d->impl.db_read_options); if (!it) { a->reply = LETS_BADARG; return; } leveldb::Slice skey((const char*) a->binary->orig_bytes, a->binary->orig_size); it->Seek(skey); if (!it->Valid() || it->key().compare(skey) != 0) { a->reply = LETS_FALSE; delete it; return; } a->reply = LETS_TRUE; delete it; } static void lets_output_first1(DrvData* d, char* buf, int len, int* index, int items) { DrvAsync* drv_async = NULL; if (d->impl.async) { drv_async = new DrvAsync(d, driver_caller(d->port), LETS_FIRST1); if (!drv_async) { GOTOBADARG; } driver_async(d->port, NULL, lets_async_first1, drv_async, drv_async_free); } else { leveldb::Iterator* it = d->impl.db->NewIterator(d->impl.db_read_options); if (!it) { GOTOBADARG; } it->SeekToFirst(); if (!it->Valid()) { driver_send_int(d, LETS_END_OF_TABLE); delete it; return; } driver_send_buf(d, it->key().data(), it->key().size()); delete it; } return; badarg: if (drv_async) { delete drv_async; } driver_send_int(d, LETS_BADARG); return; } static void lets_async_first1(void* async_data) { DrvAsync* a = (DrvAsync*) async_data; assert(a != NULL); DrvData* d = a->drvdata; leveldb::Iterator* it = d->impl.db->NewIterator(d->impl.db_read_options); if (!it) { a->reply = LETS_BADARG; return; } it->SeekToFirst(); if (!it->Valid()) { a->reply = LETS_END_OF_TABLE; delete it; return; } ErlDrvBinary* binary = driver_alloc_binary(it->key().size()); if (binary) { memcpy(binary->orig_bytes, it->key().data(), binary->orig_size); a->binary = binary; a->reply = LETS_BINARY; } else { a->reply = LETS_BADARG; } delete it; } static void lets_output_first_iter1(DrvData* d, char* buf, int len, int* index, int items) { DrvAsync* drv_async = NULL; if (d->impl.async) { drv_async = new DrvAsync(d, driver_caller(d->port), LETS_FIRST_ITER1); if (!drv_async) { GOTOBADARG; } driver_async(d->port, NULL, lets_async_first_iter1, drv_async, drv_async_free); } else { leveldb::Iterator* it = d->impl.db->NewIterator(d->impl.db_read_options); if (!it) { GOTOBADARG; } it->SeekToFirst(); if (!it->Valid()) { driver_send_int(d, LETS_END_OF_TABLE); delete it; return; } driver_send_buf(d, it->value().data(), it->value().size()); delete it; } return; badarg: if (drv_async) { delete drv_async; } driver_send_int(d, LETS_BADARG); return; } static void lets_async_first_iter1(void* async_data) { DrvAsync* a = (DrvAsync*) async_data; assert(a != NULL); DrvData* d = a->drvdata; leveldb::Iterator* it = d->impl.db->NewIterator(d->impl.db_read_options); if (!it) { a->reply = LETS_BADARG; return; } it->SeekToFirst(); if (!it->Valid()) { a->reply = LETS_END_OF_TABLE; delete it; return; } ErlDrvBinary* binary = driver_alloc_binary(it->value().size()); if (binary) { memcpy(binary->orig_bytes, it->value().data(), binary->orig_size); a->binary = binary; a->reply = LETS_BINARY; } else { a->reply = LETS_BADARG; } delete it; } static void lets_output_last1(DrvData* d, char* buf, int len, int* index, int items) { DrvAsync* drv_async = NULL; if (d->impl.async) { drv_async = new DrvAsync(d, driver_caller(d->port), LETS_LAST1); if (!drv_async) { GOTOBADARG; } driver_async(d->port, NULL, lets_async_last1, drv_async, drv_async_free); } else { leveldb::Iterator* it = d->impl.db->NewIterator(d->impl.db_read_options); if (!it) { GOTOBADARG; } it->SeekToLast(); if (!it->Valid()) { driver_send_int(d, LETS_END_OF_TABLE); delete it; return; } driver_send_buf(d, it->key().data(), it->key().size()); delete it; } return; badarg: if (drv_async) { delete drv_async; } driver_send_int(d, LETS_BADARG); return; } static void lets_async_last1(void* async_data) { DrvAsync* a = (DrvAsync*) async_data; assert(a != NULL); DrvData* d = a->drvdata; leveldb::Iterator* it = d->impl.db->NewIterator(d->impl.db_read_options); if (!it) { a->reply = LETS_BADARG; return; } it->SeekToLast(); if (!it->Valid()) { a->reply = LETS_END_OF_TABLE; delete it; return; } ErlDrvBinary* binary = driver_alloc_binary(it->key().size()); if (binary) { memcpy(binary->orig_bytes, it->key().data(), binary->orig_size); a->binary = binary; a->reply = LETS_BINARY; } else { a->reply = LETS_BADARG; } delete it; } static void lets_output_last_iter1(DrvData* d, char* buf, int len, int* index, int items) { DrvAsync* drv_async = NULL; if (d->impl.async) { drv_async = new DrvAsync(d, driver_caller(d->port), LETS_LAST_ITER1); if (!drv_async) { GOTOBADARG; } driver_async(d->port, NULL, lets_async_last_iter1, drv_async, drv_async_free); } else { leveldb::Iterator* it = d->impl.db->NewIterator(d->impl.db_read_options); if (!it) { GOTOBADARG; } it->SeekToLast(); if (!it->Valid()) { driver_send_int(d, LETS_END_OF_TABLE); delete it; return; } driver_send_buf(d, it->value().data(), it->value().size()); delete it; } return; badarg: if (drv_async) { delete drv_async; } driver_send_int(d, LETS_BADARG); return; } static void lets_async_last_iter1(void* async_data) { DrvAsync* a = (DrvAsync*) async_data; assert(a != NULL); DrvData* d = a->drvdata; leveldb::Iterator* it = d->impl.db->NewIterator(d->impl.db_read_options); if (!it) { a->reply = LETS_BADARG; return; } it->SeekToLast(); if (!it->Valid()) { a->reply = LETS_END_OF_TABLE; delete it; return; } ErlDrvBinary* binary = driver_alloc_binary(it->value().size()); if (binary) { memcpy(binary->orig_bytes, it->value().data(), binary->orig_size); a->binary = binary; a->reply = LETS_BINARY; } else { a->reply = LETS_BADARG; } delete it; } static void lets_output_next2(DrvData* d, char* buf, int len, int* index, int items) { DrvAsync* drv_async = NULL; int ng; char *key; long keylen; ng = ei_inspect_binary(buf, index, (void**) &key, &keylen); if (ng) GOTOBADARG; if (d->impl.async) { drv_async = new DrvAsync(d, driver_caller(d->port), LETS_NEXT2, (const char*) key, keylen); if (!drv_async) { GOTOBADARG; } driver_async(d->port, NULL, lets_async_next2, drv_async, drv_async_free); } else { leveldb::Iterator* it = d->impl.db->NewIterator(d->impl.db_read_options); if (!it) { GOTOBADARG; } leveldb::Slice skey((const char*) key, keylen); it->Seek(skey); if (!it->Valid()) { driver_send_int(d, LETS_END_OF_TABLE); delete it; return; } if (it->key().compare(skey) == 0) { it->Next(); if (!it->Valid()) { driver_send_int(d, LETS_END_OF_TABLE); delete it; return; } } driver_send_buf(d, it->key().data(), it->key().size()); delete it; } return; badarg: if (drv_async) { delete drv_async; } driver_send_int(d, LETS_BADARG); } static void lets_async_next2(void* async_data) { DrvAsync* a = (DrvAsync*) async_data; assert(a != NULL); DrvData* d = a->drvdata; leveldb::Iterator* it = d->impl.db->NewIterator(d->impl.db_read_options); if (!it) { a->reply = LETS_BADARG; return; } leveldb::Slice skey((const char*) a->binary->orig_bytes, a->binary->orig_size); it->Seek(skey); if (!it->Valid()) { a->reply = LETS_END_OF_TABLE; delete it; return; } if (it->key().compare(skey) == 0) { it->Next(); if (!it->Valid()) { a->reply = LETS_END_OF_TABLE; delete it; return; } } ErlDrvBinary* binary = driver_realloc_binary(a->binary, it->key().size()); if (binary) { memcpy(binary->orig_bytes, it->key().data(), binary->orig_size); a->binary = binary; a->reply = LETS_BINARY; } else { a->reply = LETS_BADARG; } delete it; } static void lets_output_next_iter2(DrvData* d, char* buf, int len, int* index, int items) { DrvAsync* drv_async = NULL; int ng; char *key; long keylen; ng = ei_inspect_binary(buf, index, (void**) &key, &keylen); if (ng) GOTOBADARG; if (d->impl.async) { drv_async = new DrvAsync(d, driver_caller(d->port), LETS_NEXT_ITER2, (const char*) key, keylen); if (!drv_async) { GOTOBADARG; } driver_async(d->port, NULL, lets_async_next_iter2, drv_async, drv_async_free); } else { leveldb::Iterator* it = d->impl.db->NewIterator(d->impl.db_read_options); if (!it) { GOTOBADARG; } leveldb::Slice skey((const char*) key, keylen); it->Seek(skey); if (!it->Valid()) { driver_send_int(d, LETS_END_OF_TABLE); delete it; return; } if (it->key().compare(skey) == 0) { it->Next(); if (!it->Valid()) { driver_send_int(d, LETS_END_OF_TABLE); delete it; return; } } driver_send_buf(d, it->value().data(), it->value().size()); delete it; } return; badarg: if (drv_async) { delete drv_async; } driver_send_int(d, LETS_BADARG); } static void lets_async_next_iter2(void* async_data) { DrvAsync* a = (DrvAsync*) async_data; assert(a != NULL); DrvData* d = a->drvdata; leveldb::Iterator* it = d->impl.db->NewIterator(d->impl.db_read_options); if (!it) { a->reply = LETS_BADARG; return; } leveldb::Slice skey((const char*) a->binary->orig_bytes, a->binary->orig_size); it->Seek(skey); if (!it->Valid()) { a->reply = LETS_END_OF_TABLE; delete it; return; } if (it->key().compare(skey) == 0) { it->Next(); if (!it->Valid()) { a->reply = LETS_END_OF_TABLE; delete it; return; } } ErlDrvBinary* binary = driver_realloc_binary(a->binary, it->value().size()); if (binary) { memcpy(binary->orig_bytes, it->value().data(), binary->orig_size); a->binary = binary; a->reply = LETS_BINARY; } else { a->reply = LETS_BADARG; } delete it; } static void lets_output_prev2(DrvData* d, char* buf, int len, int* index, int items) { DrvAsync* drv_async = NULL; int ng; char *key; long keylen; ng = ei_inspect_binary(buf, index, (void**) &key, &keylen); if (ng) GOTOBADARG; if (d->impl.async) { drv_async = new DrvAsync(d, driver_caller(d->port), LETS_PREV2, (const char*) key, keylen); if (!drv_async) { GOTOBADARG; } driver_async(d->port, NULL, lets_async_prev2, drv_async, drv_async_free); } else { leveldb::Iterator* it = d->impl.db->NewIterator(d->impl.db_read_options); if (!it) { GOTOBADARG; } leveldb::Slice skey((const char*) key, keylen); it->Seek(skey); if (!it->Valid()) { it->SeekToLast(); } else { it->Prev(); } if (!it->Valid()) { driver_send_int(d, LETS_END_OF_TABLE); delete it; return; } driver_send_buf(d, it->key().data(), it->key().size()); delete it; } return; badarg: if (drv_async) { delete drv_async; } driver_send_int(d, LETS_BADARG); } static void lets_async_prev2(void* async_data) { DrvAsync* a = (DrvAsync*) async_data; assert(a != NULL); DrvData* d = a->drvdata; leveldb::Iterator* it = d->impl.db->NewIterator(d->impl.db_read_options); if (!it) { a->reply = LETS_BADARG; return; } leveldb::Slice skey((const char*) a->binary->orig_bytes, a->binary->orig_size); it->Seek(skey); if (!it->Valid()) { it->SeekToLast(); } else { it->Prev(); } if (!it->Valid()) { a->reply = LETS_END_OF_TABLE; delete it; return; } ErlDrvBinary* binary = driver_realloc_binary(a->binary, it->key().size()); if (binary) { memcpy(binary->orig_bytes, it->key().data(), binary->orig_size); a->binary = binary; a->reply = LETS_BINARY; } else { a->reply = LETS_BADARG; } delete it; } static void lets_output_prev_iter2(DrvData* d, char* buf, int len, int* index, int items) { DrvAsync* drv_async = NULL; int ng; char *key; long keylen; ng = ei_inspect_binary(buf, index, (void**) &key, &keylen); if (ng) GOTOBADARG; if (d->impl.async) { drv_async = new DrvAsync(d, driver_caller(d->port), LETS_PREV_ITER2, (const char*) key, keylen); if (!drv_async) { GOTOBADARG; } driver_async(d->port, NULL, lets_async_prev_iter2, drv_async, drv_async_free); } else { leveldb::Iterator* it = d->impl.db->NewIterator(d->impl.db_read_options); if (!it) { GOTOBADARG; } leveldb::Slice skey((const char*) key, keylen); it->Seek(skey); if (!it->Valid()) { it->SeekToLast(); } else { it->Prev(); } if (!it->Valid()) { driver_send_int(d, LETS_END_OF_TABLE); delete it; return; } driver_send_buf(d, it->value().data(), it->value().size()); delete it; } return; badarg: if (drv_async) { delete drv_async; } driver_send_int(d, LETS_BADARG); } static void lets_async_prev_iter2(void* async_data) { DrvAsync* a = (DrvAsync*) async_data; assert(a != NULL); DrvData* d = a->drvdata; leveldb::Iterator* it = d->impl.db->NewIterator(d->impl.db_read_options); if (!it) { a->reply = LETS_BADARG; return; } leveldb::Slice skey((const char*) a->binary->orig_bytes, a->binary->orig_size); it->Seek(skey); if (!it->Valid()) { it->SeekToLast(); } else { it->Prev(); } if (!it->Valid()) { a->reply = LETS_END_OF_TABLE; delete it; return; } ErlDrvBinary* binary = driver_realloc_binary(a->binary, it->value().size()); if (binary) { memcpy(binary->orig_bytes, it->value().data(), binary->orig_size); a->binary = binary; a->reply = LETS_BINARY; } else { a->reply = LETS_BADARG; } delete it; }