#include "ssb.db.h"
#include "log.h"
#include "mem.h"
#include "ssb.h"
#include "trace.h"
#include "util.js.h"
#include "ow-crypt.h"
#include "sodium/crypto_hash_sha256.h"
#include "sodium/crypto_sign.h"
#include "sodium/crypto_sign_ed25519.h"
#include "sodium/randombytes.h"
#include "sqlite3.h"
#include "uv.h"
#include <stdlib.h>
#include <string.h>
#include <time.h>
#include <unistd.h>
typedef struct _message_store_t message_store_t;
static void _tf_ssb_db_store_message_after_work(tf_ssb_t* ssb, int status, void* user_data);
static int _tf_ssb_db_try_exec(sqlite3* db, const char* statement)
{
char* error = NULL;
int result = sqlite3_exec(db, statement, NULL, NULL, &error);
if (result != SQLITE_OK)
{
tf_printf("Error running '%s': %s.\n", statement, error ? error : sqlite3_errmsg(db));
}
return result;
}
static void _tf_ssb_db_exec(sqlite3* db, const char* statement)
{
char* error = NULL;
int result = sqlite3_exec(db, statement, NULL, NULL, &error);
if (result != SQLITE_OK)
{
tf_printf("Error running '%s': %s.\n", statement, error ? error : sqlite3_errmsg(db));
abort();
}
}
static bool _tf_ssb_db_has_rows(sqlite3* db, const char* query)
{
bool found = false;
sqlite3_stmt* statement = NULL;
if (sqlite3_prepare(db, query, -1, &statement, NULL) == SQLITE_OK)
{
int result = SQLITE_OK;
while ((result = sqlite3_step(statement)) == SQLITE_ROW)
{
found = true;
}
if (result != SQLITE_DONE)
{
tf_printf("%s\n", sqlite3_errmsg(db));
abort();
}
sqlite3_finalize(statement);
}
else
{
tf_printf("%s\n", sqlite3_errmsg(db));
abort();
}
return found;
}
static void _tf_ssb_db_init_internal(sqlite3* db)
{
sqlite3_extended_result_codes(db, 1);
_tf_ssb_db_exec(db, "PRAGMA journal_mode = WAL");
_tf_ssb_db_exec(db, "PRAGMA synchronous = NORMAL");
}
void tf_ssb_db_init_reader(sqlite3* db)
{
_tf_ssb_db_init_internal(db);
}
void tf_ssb_db_init(tf_ssb_t* ssb)
{
sqlite3* db = tf_ssb_acquire_db_writer(ssb);
_tf_ssb_db_init_internal(db);
sqlite3_stmt* statement = NULL;
int auto_vacuum = 0;
if (sqlite3_prepare(db, "PRAGMA auto_vacuum", -1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_step(statement) == SQLITE_ROW)
{
auto_vacuum = sqlite3_column_int(statement, 0);
}
sqlite3_finalize(statement);
}
if (auto_vacuum != 1 /* FULL */)
{
tf_printf("Enabling auto-vacuum and performing full vacuum.\n");
_tf_ssb_db_exec(db, "PRAGMA auto_vacuum = FULL");
_tf_ssb_db_exec(db, "VACUUM main");
tf_printf("All clean.\n");
}
_tf_ssb_db_exec(db,
"CREATE TABLE IF NOT EXISTS messages ("
" author TEXT,"
" id TEXT PRIMARY KEY,"
" sequence INTEGER,"
" timestamp REAL,"
" previous TEXT,"
" hash TEXT,"
" content BLOB,"
" signature TEXT,"
" flags INTEGER,"
" UNIQUE(author, sequence)"
")");
if (!_tf_ssb_db_has_rows(db, "PRAGMA table_list('messages_stats')"))
{
_tf_ssb_db_exec(db, "BEGIN TRANSACTION");
_tf_ssb_db_exec(db,
"CREATE TABLE IF NOT EXISTS messages_stats ("
" author TEXT PRIMARY KEY,"
" max_sequence INTEGER,"
" max_timestamp REAL"
")");
_tf_ssb_db_exec(
db, "INSERT OR REPLACE INTO messages_stats (author, max_sequence, max_timestamp) SELECT author, MAX(sequence), MAX(timestamp) FROM messages GROUP BY author");
_tf_ssb_db_exec(db, "COMMIT TRANSACTION");
}
_tf_ssb_db_exec(db,
"CREATE TRIGGER IF NOT EXISTS messages_ai_stats AFTER INSERT ON messages BEGIN INSERT INTO messages_stats(author, max_sequence, max_timestamp) VALUES (new.author, "
"new.sequence, new.timestamp) ON CONFLICT DO UPDATE SET max_sequence = MAX(max_sequence, excluded.max_sequence), max_timestamp = MAX(max_timestamp, "
"excluded.max_timestamp); END");
_tf_ssb_db_exec(db,
"CREATE TRIGGER IF NOT EXISTS messages_ad_stats AFTER DELETE ON messages BEGIN UPDATE messages_stats SET max_sequence = (SELECT MAX(messages.sequence) FROM messages WHERE "
"messages.author = old.author), max_timestamp = (SELECT MAX(messages.timestamp) FROM messages WHERE messages.author = old.author); END");
if (_tf_ssb_db_has_rows(db, "SELECT name FROM pragma_table_info('messages') WHERE name = 'content' AND type == 'TEXT'"))
{
tf_printf("converting to JSONB\n");
_tf_ssb_db_exec(db, "DROP TRIGGER IF EXISTS messages_ai_refs");
_tf_ssb_db_exec(db, "DROP TRIGGER IF EXISTS messages_ad_refs");
_tf_ssb_db_exec(db, "DROP TRIGGER IF EXISTS messages_ai");
_tf_ssb_db_exec(db, "DROP TRIGGER IF EXISTS messages_ad");
_tf_ssb_db_exec(db, "DROP TABLE IF EXISTS messages_fts");
_tf_ssb_db_exec(db, "BEGIN TRANSACTION");
_tf_ssb_db_exec(db, "ALTER TABLE messages ADD COLUMN contentb BLOB");
_tf_ssb_db_exec(db, "UPDATE messages SET contentb = jsonb(content)");
_tf_ssb_db_exec(db, "ALTER TABLE messages DROP COLUMN content");
_tf_ssb_db_exec(db, "ALTER TABLE messages RENAME COLUMN contentb TO content");
_tf_ssb_db_exec(db, "COMMIT TRANSACTION");
}
if (_tf_ssb_db_has_rows(db, "SELECT name FROM pragma_table_info('messages') WHERE name = 'sequence_before_author'"))
{
tf_printf("Renaming sequence_before_author -> flags.\n");
_tf_ssb_db_exec(db, "ALTER TABLE messages RENAME COLUMN sequence_before_author TO flags");
}
_tf_ssb_db_exec(db, "CREATE INDEX IF NOT EXISTS messages_author_id_index ON messages (author, id)");
_tf_ssb_db_exec(db, "CREATE INDEX IF NOT EXISTS messages_author_sequence_index ON messages (author, sequence)");
_tf_ssb_db_exec(db, "CREATE INDEX IF NOT EXISTS messages_author_timestamp_index ON messages (author, timestamp)");
_tf_ssb_db_exec(db, "CREATE INDEX IF NOT EXISTS messages_timestamp_index ON messages (timestamp)");
_tf_ssb_db_exec(db, "CREATE INDEX IF NOT EXISTS messages_type_timestamp_index ON messages (content ->> 'type', timestamp)");
_tf_ssb_db_exec(db, "CREATE INDEX IF NOT EXISTS messages_size_by_author_index ON messages (author, length(content))");
_tf_ssb_db_exec(db, "CREATE INDEX IF NOT EXISTS messages_type_author_channel_index ON messages (content ->> 'type', author, content ->> 'channel');");
_tf_ssb_db_exec(db,
"CREATE TABLE IF NOT EXISTS blobs ("
" id TEXT PRIMARY KEY,"
" content BLOB,"
" created INTEGER"
")");
_tf_ssb_db_exec(db, "DROP TABLE IF EXISTS blob_wants");
_tf_ssb_db_exec(db,
"CREATE TABLE IF NOT EXISTS properties ("
" id TEXT,"
" key TEXT,"
" value TEXT,"
" UNIQUE(id, key)"
")");
_tf_ssb_db_exec(db,
"CREATE TABLE IF NOT EXISTS connections ("
" host TEXT,"
" port INTEGER,"
" key TEXT,"
" last_attempt INTEGER,"
" last_success INTEGER,"
" UNIQUE(host, port, key)"
")");
_tf_ssb_db_exec(db,
"CREATE TABLE IF NOT EXISTS identities ("
" user TEXT,"
" public_key TEXT UNIQUE,"
" private_key TEXT UNIQUE"
")");
_tf_ssb_db_exec(db, "CREATE INDEX IF NOT EXISTS identities_user ON identities (user, public_key)");
_tf_ssb_db_exec(db, "DELETE FROM identities WHERE user = ':auth'");
_tf_ssb_db_exec(db,
"CREATE TABLE IF NOT EXISTS invites ("
" invite_public_key TEXT PRIMARY KEY,"
" account TEXT,"
" use_count INTEGER,"
" expires INTEGER"
")");
bool populate_fts = false;
if (!_tf_ssb_db_has_rows(db, "PRAGMA table_list('messages_fts')"))
{
_tf_ssb_db_exec(db, "CREATE VIRTUAL TABLE IF NOT EXISTS messages_fts USING fts5(content, content=messages, content_rowid=rowid)");
populate_fts = true;
}
if (!populate_fts && /* HACK */ false)
{
tf_printf("Checking FTS5 integrity...\n");
if (sqlite3_exec(db, "INSERT INTO messages_fts(messages_fts, rank) VALUES ('integrity-check', 0)", NULL, NULL, NULL) == SQLITE_CORRUPT_VTAB)
{
populate_fts = true;
}
tf_printf("Done.\n");
}
if (populate_fts)
{
tf_printf("Populating full-text search...\n");
_tf_ssb_db_exec(db, "INSERT INTO messages_fts (rowid, content) SELECT rowid, json(content) FROM messages");
tf_printf("Done.\n");
}
_tf_ssb_db_exec(
db, "CREATE TRIGGER IF NOT EXISTS messages_ai AFTER INSERT ON messages BEGIN INSERT INTO messages_fts(rowid, content) VALUES (new.rowid, json(new.content)); END");
_tf_ssb_db_exec(db,
"CREATE TRIGGER IF NOT EXISTS messages_ad AFTER DELETE ON messages BEGIN INSERT INTO messages_fts(messages_fts, rowid, content) VALUES ('delete', old.rowid, "
"old.content); END");
if (!_tf_ssb_db_has_rows(db, "PRAGMA table_list('messages_refs')"))
{
_tf_ssb_db_exec(db, "BEGIN TRANSACTION");
_tf_ssb_db_exec(db,
"CREATE TABLE IF NOT EXISTS messages_refs ("
" message TEXT, "
" ref TEXT, "
" UNIQUE(message, ref)"
")");
tf_printf("Populating messages_refs...\n");
_tf_ssb_db_exec(db,
"INSERT INTO messages_refs(message, ref) "
"SELECT messages.id, j.value FROM messages, json_tree(messages.content) as j WHERE "
"j.value LIKE '&%.sha256' OR "
"j.value LIKE '%%%.sha256' OR "
"j.value LIKE '@%.ed25519' "
"ON CONFLICT DO NOTHING");
_tf_ssb_db_exec(db, "COMMIT TRANSACTION");
tf_printf("Done.\n");
}
_tf_ssb_db_exec(db, "DROP TRIGGER IF EXISTS messages_ai_refs");
_tf_ssb_db_exec(db,
"CREATE TRIGGER IF NOT EXISTS messages_ai_refs AFTER INSERT ON messages BEGIN "
"INSERT INTO messages_refs(message, ref) "
"SELECT DISTINCT new.id, j.value FROM json_tree(new.content) as j WHERE "
"j.value LIKE '&%.sha256' OR "
"j.value LIKE '%%%.sha256' OR "
"j.value LIKE '@%.ed25519' "
"ON CONFLICT DO NOTHING; END");
_tf_ssb_db_exec(db, "DROP TRIGGER IF EXISTS messages_ad_refs");
_tf_ssb_db_exec(db, "CREATE TRIGGER IF NOT EXISTS messages_ad_refs AFTER DELETE ON messages BEGIN DELETE FROM messages_refs WHERE messages_refs.message = old.id; END");
_tf_ssb_db_exec(db, "CREATE INDEX IF NOT EXISTS messages_refs_message_idx ON messages_refs (message)");
_tf_ssb_db_exec(db, "CREATE INDEX IF NOT EXISTS messages_refs_ref_idx ON messages_refs (ref)");
if (!_tf_ssb_db_has_rows(db, "PRAGMA table_list('blobs_refs')"))
{
_tf_ssb_db_exec(db, "BEGIN TRANSACTION");
_tf_ssb_db_exec(db,
"CREATE TABLE IF NOT EXISTS blobs_refs ("
" blob TEXT, "
" ref TEXT, "
" UNIQUE(blob, ref)"
")");
tf_printf("Populating blobs_refs...\n");
_tf_ssb_db_exec(db,
"INSERT INTO blobs_refs(blob, ref) "
"SELECT blobs.id, j.value FROM blobs, json_tree(blobs.content) as j WHERE "
"json_valid(blobs.content) AND j.value LIKE '&%.sha256' "
"ON CONFLICT DO NOTHING");
_tf_ssb_db_exec(db, "COMMIT TRANSACTION");
tf_printf("Done.\n");
}
_tf_ssb_db_exec(db, "DROP TRIGGER IF EXISTS blobs_ai_refs");
_tf_ssb_db_exec(db,
"CREATE TRIGGER IF NOT EXISTS blobs_ai_refs AFTER INSERT ON blobs BEGIN "
"INSERT INTO blobs_refs(blob, ref) "
"SELECT DISTINCT new.id, j.value FROM json_tree(new.content) as j WHERE "
"json_valid(new.content) AND j.value LIKE '&%.sha256' "
"ON CONFLICT DO NOTHING; END");
_tf_ssb_db_exec(db, "DROP TRIGGER IF EXISTS blobs_ad_refs");
_tf_ssb_db_exec(db, "CREATE TRIGGER IF NOT EXISTS blobs_ad_refs AFTER DELETE ON blobs BEGIN DELETE FROM blobs_refs WHERE blobs_refs.blob = old.id; END");
_tf_ssb_db_exec(db, "CREATE INDEX IF NOT EXISTS blobs_refs_blob_idx ON blobs_refs (blob)");
_tf_ssb_db_exec(db, "CREATE INDEX IF NOT EXISTS blobs_refs_ref_idx ON blobs_refs (ref)");
_tf_ssb_db_exec(db, "DROP VIEW IF EXISTS blob_wants_view");
_tf_ssb_db_exec(db,
"CREATE VIEW IF NOT EXISTS blob_wants_view (source, id, timestamp) AS "
" WITH RECURSIVE "
" wanted1 AS ( "
" SELECT messages_refs.message AS source, messages_refs.ref AS id, messages.timestamp AS timestamp "
" FROM messages_refs "
" JOIN messages ON messages.id = messages_refs.message "
" UNION "
" SELECT messages_refs.message AS source, messages_refs.ref AS id, unixepoch() * 1000 AS timestamp "
" FROM messages_refs "
" JOIN messages ON messages.id = messages_refs.message "
" WHERE messages.content ->> 'type' = 'about' "
" ), "
" wanted(source, id, timestamp) AS ( "
" SELECT wanted1.source AS source, wanted1.id AS id, wanted1.timestamp AS timestamp FROM wanted1 "
" UNION "
" SELECT wanted.source AS source, br.ref AS id, wanted.timestamp AS timestamp FROM wanted JOIN blobs_refs br ON br.blob = wanted.id "
" ) "
" SELECT wanted.source, wanted.id, wanted.timestamp FROM wanted "
" LEFT OUTER JOIN blobs ON wanted.id = blobs.id "
" WHERE blobs.id IS NULL "
" AND LENGTH(wanted.id) = 52 "
" AND wanted.id LIKE '&%.sha256'");
if (!_tf_ssb_db_has_rows(db, "PRAGMA table_list('blob_wants_cache')"))
{
tf_printf("Populating blob_wants_cache...\n");
_tf_ssb_db_exec(db, "BEGIN TRANSACTION");
_tf_ssb_db_exec(db, "CREATE TABLE IF NOT EXISTS blob_wants_cache (source TEXT, id TEXT, timestamp REAL, UNIQUE(source, id))");
_tf_ssb_db_exec(
db, "INSERT INTO blob_wants_cache SELECT * FROM blob_wants_view WHERE true ON CONFLICT(source, id) DO UPDATE SET timestamp = MAX(timestamp, excluded.timestamp)");
_tf_ssb_db_exec(db, "COMMIT TRANSACTION");
tf_printf("Done.\n");
}
_tf_ssb_db_exec(db, "CREATE INDEX IF NOT EXISTS blob_wants_cache_id_idx ON blob_wants_cache (id)");
_tf_ssb_db_exec(db, "CREATE INDEX IF NOT EXISTS blob_wants_cache_timestamp_id_idx ON blob_wants_cache (timestamp, id)");
_tf_ssb_db_exec(db,
"CREATE TRIGGER IF NOT EXISTS messages_ai_blob_wants_cache AFTER INSERT ON messages_refs BEGIN "
"INSERT INTO blob_wants_cache (source, id, timestamp) "
"SELECT messages.id, new.ref, messages.timestamp FROM messages WHERE messages.id = new.message AND "
"LENGTH(new.ref) = 52 AND new.ref LIKE '&%.sha256' "
"ON CONFLICT (source, id) DO NOTHING; END");
_tf_ssb_db_exec(db, "DROP TRIGGER IF EXISTS blobs_refs_ai_blob_wants_cache");
_tf_ssb_db_exec(db,
"CREATE TRIGGER IF NOT EXISTS blobs_refs_ai_blob_wants_cache AFTER INSERT ON blobs_refs BEGIN "
"INSERT INTO blob_wants_cache (source, id, timestamp) "
"SELECT messages.id, new.ref, messages.timestamp FROM messages "
"JOIN blob_wants_cache bwc ON bwc.source = messages.id AND bwc.id = new.blob "
"ON CONFLICT (source, id) DO NOTHING; END");
_tf_ssb_db_exec(db,
"CREATE TRIGGER IF NOT EXISTS messages_ad_blob_wants_cache AFTER DELETE ON messages BEGIN "
"DELETE FROM blob_wants_cache WHERE blob_wants_cache.source = old.id; END");
_tf_ssb_db_exec(db, "DROP TRIGGER IF EXISTS blobs_ai_blob_wants_cache");
_tf_ssb_db_exec(db,
"CREATE TRIGGER IF NOT EXISTS blobs_ai_blob_wants_cache AFTER INSERT ON blobs BEGIN "
"DELETE FROM blob_wants_cache WHERE blob_wants_cache.id = new.id; END");
bool need_add_flags = true;
bool need_convert_timestamp_to_real = false;
if (sqlite3_prepare(db, "PRAGMA table_info(messages)", -1, &statement, NULL) == SQLITE_OK)
{
int result = SQLITE_OK;
while ((result = sqlite3_step(statement)) == SQLITE_ROW)
{
const char* name = (const char*)sqlite3_column_text(statement, 1);
const char* type = (const char*)sqlite3_column_text(statement, 2);
if (name && type && strcmp(name, "timestamp") == 0 && strcmp(type, "INTEGER") == 0)
{
need_convert_timestamp_to_real = true;
}
if (name && strcmp(name, "flags") == 0)
{
need_add_flags = false;
}
}
sqlite3_finalize(statement);
}
if (need_convert_timestamp_to_real)
{
tf_printf("Converting timestamp column from INTEGER to REAL.\n");
_tf_ssb_db_exec(db, "BEGIN TRANSACTION");
_tf_ssb_db_exec(db, "DROP INDEX IF EXISTS messages_author_timestamp_index");
_tf_ssb_db_exec(db, "ALTER TABLE messages ADD COLUMN timestamp_real REAL");
_tf_ssb_db_exec(db, "UPDATE messages SET timestamp_real = timestamp");
_tf_ssb_db_exec(db, "ALTER TABLE messages DROP COLUMN timestamp");
_tf_ssb_db_exec(db, "ALTER TABLE messages RENAME COLUMN timestamp_real TO timestamp");
_tf_ssb_db_exec(db, "CREATE INDEX IF NOT EXISTS messages_author_timestamp_index ON messages (author, timestamp)");
_tf_ssb_db_exec(db, "COMMIT TRANSACTION");
}
if (need_add_flags)
{
tf_printf("Adding flags column.\n");
_tf_ssb_db_exec(db, "ALTER TABLE messages ADD COLUMN flags INTEGER");
}
tf_ssb_release_db_writer(ssb, db);
}
static bool _tf_ssb_db_previous_message_exists(sqlite3* db, const char* author, int64_t sequence, const char* previous, bool* out_id_mismatch)
{
bool exists = false;
if (sequence == 1)
{
exists = true;
}
else
{
sqlite3_stmt* statement;
if (sqlite3_prepare(db, "SELECT COUNT(*), id != ?3 AS is_mismatch FROM messages WHERE author = ?1 AND sequence = ?2", -1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, author, -1, NULL) == SQLITE_OK && sqlite3_bind_int64(statement, 2, sequence - 1) == SQLITE_OK &&
sqlite3_bind_text(statement, 3, previous, -1, NULL) == SQLITE_OK && sqlite3_step(statement) == SQLITE_ROW)
{
exists = sqlite3_column_int(statement, 0) != 0;
*out_id_mismatch = sqlite3_column_int(statement, 1) != 0;
}
sqlite3_finalize(statement);
}
}
return exists;
}
static int64_t _tf_ssb_db_store_message_raw(sqlite3* db, const char* id, const char* previous, const char* author, int64_t sequence, double timestamp, const char* content,
size_t content_len, const char* signature, int flags)
{
int64_t last_row_id = -1;
bool id_mismatch = false;
if (_tf_ssb_db_previous_message_exists(db, author, sequence, previous, &id_mismatch))
{
const char* query = "INSERT INTO messages (id, previous, author, sequence, timestamp, content, hash, signature, flags) VALUES (?, ?, ?, ?, ?, jsonb(?), "
"?, ?, ?) ON CONFLICT DO NOTHING";
sqlite3_stmt* statement;
if (sqlite3_prepare(db, query, -1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, id, -1, NULL) == SQLITE_OK &&
(previous ? sqlite3_bind_text(statement, 2, previous, -1, NULL) : sqlite3_bind_null(statement, 2)) == SQLITE_OK &&
sqlite3_bind_text(statement, 3, author, -1, NULL) == SQLITE_OK && sqlite3_bind_int64(statement, 4, sequence) == SQLITE_OK &&
sqlite3_bind_double(statement, 5, timestamp) == SQLITE_OK && sqlite3_bind_text(statement, 6, content, content_len, NULL) == SQLITE_OK &&
sqlite3_bind_text(statement, 7, "sha256", 6, NULL) == SQLITE_OK && sqlite3_bind_text(statement, 8, signature, -1, NULL) == SQLITE_OK &&
sqlite3_bind_int(statement, 9, flags) == SQLITE_OK)
{
int r = sqlite3_step(statement);
if (r != SQLITE_DONE)
{
tf_printf("_tf_ssb_db_store_message_raw: %s\n", sqlite3_errmsg(db));
}
if (r == SQLITE_DONE && sqlite3_changes(db) != 0)
{
last_row_id = sqlite3_last_insert_rowid(db);
}
}
else
{
tf_printf("bind failed\n");
}
sqlite3_finalize(statement);
}
else
{
tf_printf("%s: prepare failed: %s\n", __FUNCTION__, sqlite3_errmsg(db));
}
}
else if (id_mismatch)
{
/*
** Only warn if we find a previous message with the wrong ID.
** If a feed is forked, we would otherwise warn on every
** message when trying to receive what we don't have, and
** that's not helping anybody.
*/
tf_printf("%p: Previous message doesn't exist for author=%s sequence=%" PRId64 " previous=%s.\n", db, author, sequence, previous);
}
return last_row_id;
}
static char* _tf_ssb_db_get_message_blob_wants(tf_ssb_t* ssb, int64_t rowid)
{
sqlite3* db = tf_ssb_acquire_db_reader(ssb);
sqlite3_stmt* statement;
char* result = NULL;
size_t size = 0;
if (sqlite3_prepare(db,
"SELECT DISTINCT json.value FROM messages, json_tree(messages.content) AS json LEFT OUTER JOIN blobs ON json.value = blobs.id WHERE messages.rowid = ?1 AND "
"json.value LIKE '&%%.sha256' AND length(json.value) = ?2 AND blobs.content IS NULL",
-1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_int64(statement, 1, rowid) == SQLITE_OK && sqlite3_bind_int(statement, 2, k_blob_id_len - 1) == SQLITE_OK)
{
int r = SQLITE_OK;
while ((r = sqlite3_step(statement)) == SQLITE_ROW)
{
int id_size = sqlite3_column_bytes(statement, 0);
const uint8_t* id = sqlite3_column_text(statement, 0);
result = tf_resize_vec(result, size + id_size + 1);
memcpy(result + size, id, id_size + 1);
size += id_size + 1;
}
if (r != SQLITE_DONE)
{
tf_printf("%s\n", sqlite3_errmsg(db));
}
}
else
{
tf_printf("bind failed: %s\n", sqlite3_errmsg(db));
}
sqlite3_finalize(statement);
}
else
{
tf_printf("%s: prepare failed: %s\n", __FUNCTION__, sqlite3_errmsg(db));
}
result = tf_realloc(result, size + 1);
result[size] = '\0';
tf_ssb_release_db_reader(ssb, db);
return result;
}
typedef struct _message_store_t
{
char id[k_id_base64_len];
char signature[512];
int flags;
char previous[k_id_base64_len];
char author[k_id_base64_len];
int64_t sequence;
double timestamp;
const char* content;
size_t length;
bool out_stored;
char* out_blob_wants;
tf_ssb_db_store_message_callback_t* callback;
void* user_data;
message_store_t* next;
} message_store_t;
static void _tf_ssb_db_store_message_work(tf_ssb_t* ssb, void* user_data)
{
message_store_t* store = user_data;
sqlite3* db = tf_ssb_acquire_db_writer(ssb);
bool in_transaction = _tf_ssb_db_try_exec(db, "BEGIN TRANSACTION") == SQLITE_OK;
while (store)
{
int64_t last_row_id = _tf_ssb_db_store_message_raw(db, store->id, *store->previous ? store->previous : NULL, store->author, store->sequence, store->timestamp,
store->content, store->length, store->signature, store->flags);
if (last_row_id != -1)
{
store->out_stored = true;
store->out_blob_wants = _tf_ssb_db_get_message_blob_wants(ssb, last_row_id);
}
store = store->next;
}
if (in_transaction)
{
if (_tf_ssb_db_try_exec(db, "COMMIT TRANSACTION") != SQLITE_OK)
{
store = user_data;
while (store)
{
store->out_stored = false;
store = store->next;
}
}
}
tf_ssb_release_db_writer(ssb, db);
}
static void _wake_up_queue(tf_ssb_t* ssb, tf_ssb_store_queue_t* queue)
{
if (!queue->running)
{
message_store_t* stores = queue->head;
queue->head = NULL;
queue->tail = NULL;
if (stores)
{
queue->running = true;
tf_ssb_run_work(ssb, _tf_ssb_db_store_message_work, _tf_ssb_db_store_message_after_work, stores);
}
}
}
static void _tf_ssb_db_store_message_after_work(tf_ssb_t* ssb, int status, void* user_data)
{
message_store_t* store = user_data;
tf_trace_t* trace = tf_ssb_get_trace(ssb);
message_store_t* last_stored = NULL;
while (store)
{
if (store->out_stored)
{
last_stored = store;
}
if (store->out_blob_wants)
{
tf_trace_begin(trace, "notify_blob_wants_added");
for (char* p = store->out_blob_wants; *p; p = p + strlen(p))
{
tf_ssb_notify_blob_want_added(ssb, p);
}
tf_free(store->out_blob_wants);
tf_trace_end(trace);
}
if (store->callback)
{
store->callback(store->id, store->out_stored, store->user_data);
}
store = store->next;
}
if (last_stored)
{
tf_trace_begin(trace, "notify_message_added");
JSContext* context = tf_ssb_get_context(ssb);
JSValue formatted = tf_ssb_format_message(context, last_stored->previous, last_stored->author, last_stored->sequence, last_stored->timestamp, "sha256",
last_stored->content, last_stored->signature, last_stored->flags);
JSValue message = JS_NewObject(context);
JS_SetPropertyStr(context, message, "key", JS_NewString(context, last_stored->id));
JS_SetPropertyStr(context, message, "value", formatted);
char timestamp_string[256];
snprintf(timestamp_string, sizeof(timestamp_string), "%f", last_stored->timestamp);
JS_SetPropertyStr(context, message, "timestamp", JS_NewString(context, timestamp_string));
tf_ssb_notify_message_added(ssb, last_stored->author, last_stored->sequence, last_stored->id, message);
JS_FreeValue(context, message);
tf_trace_end(trace);
}
JSContext* context = tf_ssb_get_context(ssb);
store = user_data;
while (store)
{
JS_FreeCString(context, store->content);
message_store_t* last = store;
store = store->next;
tf_free(last);
}
tf_ssb_store_queue_t* queue = tf_ssb_get_store_queue(ssb);
queue->running = false;
_wake_up_queue(ssb, queue);
}
void tf_ssb_db_store_message(
tf_ssb_t* ssb, JSContext* context, const char* id, JSValue val, const char* signature, int flags, tf_ssb_db_store_message_callback_t* callback, void* user_data)
{
JSValue previousval = JS_GetPropertyStr(context, val, "previous");
const char* previous = JS_IsNull(previousval) ? NULL : JS_ToCString(context, previousval);
JS_FreeValue(context, previousval);
JSValue authorval = JS_GetPropertyStr(context, val, "author");
const char* author = JS_ToCString(context, authorval);
JS_FreeValue(context, authorval);
int64_t sequence = -1;
JSValue sequenceval = JS_GetPropertyStr(context, val, "sequence");
JS_ToInt64(context, &sequence, sequenceval);
JS_FreeValue(context, sequenceval);
double timestamp = -1.0;
JSValue timestampval = JS_GetPropertyStr(context, val, "timestamp");
JS_ToFloat64(context, ×tamp, timestampval);
JS_FreeValue(context, timestampval);
JSValue contentval = JS_GetPropertyStr(context, val, "content");
JSValue content = JS_JSONStringify(context, contentval, JS_NULL, JS_NULL);
size_t content_len;
const char* contentstr = JS_ToCStringLen(context, &content_len, content);
JS_FreeValue(context, content);
JS_FreeValue(context, contentval);
message_store_t* store = tf_malloc(sizeof(message_store_t));
*store = (message_store_t) {
.sequence = sequence,
.timestamp = timestamp,
.content = contentstr,
.length = content_len,
.flags = flags,
.callback = callback,
.user_data = user_data,
};
snprintf(store->id, sizeof(store->id), "%s", id);
snprintf(store->previous, sizeof(store->previous), "%s", previous ? previous : "");
snprintf(store->author, sizeof(store->author), "%s", author);
snprintf(store->signature, sizeof(store->signature), "%s", signature);
JS_FreeCString(context, author);
JS_FreeCString(context, previous);
tf_ssb_store_queue_t* queue = tf_ssb_get_store_queue(ssb);
if (queue->tail)
{
message_store_t* tail = queue->tail;
tail->next = store;
queue->tail = store;
}
else
{
queue->head = store;
queue->tail = store;
}
_wake_up_queue(ssb, queue);
}
bool tf_ssb_db_message_content_get(tf_ssb_t* ssb, const char* id, uint8_t** out_blob, size_t* out_size)
{
bool result = false;
sqlite3_stmt* statement;
sqlite3* db = tf_ssb_acquire_db_reader(ssb);
const char* query = "SELECT json(content) FROM messages WHERE id = ?";
if (sqlite3_prepare(db, query, -1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, id, -1, NULL) == SQLITE_OK && sqlite3_step(statement) == SQLITE_ROW)
{
const uint8_t* blob = sqlite3_column_blob(statement, 0);
int size = sqlite3_column_bytes(statement, 0);
if (out_blob)
{
*out_blob = tf_malloc(size + 1);
memcpy(*out_blob, blob, size);
(*out_blob)[size] = '\0';
}
if (out_size)
{
*out_size = size;
}
result = true;
}
sqlite3_finalize(statement);
}
tf_ssb_release_db_reader(ssb, db);
return result;
}
bool tf_ssb_db_blob_has(sqlite3* db, const char* id)
{
bool result = false;
sqlite3_stmt* statement;
const char* query = "SELECT COUNT(*) FROM blobs WHERE id = ?1";
if (sqlite3_prepare(db, query, -1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, id, -1, NULL) == SQLITE_OK && sqlite3_step(statement) == SQLITE_ROW)
{
result = sqlite3_column_int64(statement, 0) != 0;
}
sqlite3_finalize(statement);
}
return result;
}
bool tf_ssb_db_blob_get(tf_ssb_t* ssb, const char* id, uint8_t** out_blob, size_t* out_size)
{
bool result = false;
sqlite3_stmt* statement;
sqlite3* db = tf_ssb_acquire_db_reader(ssb);
const char* query = "SELECT content FROM blobs WHERE id = ?1";
if (sqlite3_prepare(db, query, -1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, id, -1, NULL) == SQLITE_OK && sqlite3_step(statement) == SQLITE_ROW)
{
const uint8_t* blob = sqlite3_column_blob(statement, 0);
int size = sqlite3_column_bytes(statement, 0);
if (out_blob)
{
*out_blob = tf_malloc(size + 1);
if (size)
{
memcpy(*out_blob, blob, size);
}
(*out_blob)[size] = '\0';
}
if (out_size)
{
*out_size = size;
}
result = true;
}
sqlite3_finalize(statement);
}
tf_ssb_release_db_reader(ssb, db);
return result;
}
typedef struct _blob_get_async_t
{
tf_ssb_t* ssb;
char id[k_blob_id_len];
tf_ssb_db_blob_get_callback_t* callback;
void* user_data;
bool out_found;
uint8_t* out_data;
size_t out_size;
} blob_get_async_t;
static void _tf_ssb_db_blob_get_async_work(tf_ssb_t* ssb, void* user_data)
{
blob_get_async_t* async = user_data;
async->out_found = tf_ssb_db_blob_get(ssb, async->id, &async->out_data, &async->out_size);
}
static void _tf_ssb_db_blob_get_async_after_work(tf_ssb_t* ssb, int status, void* user_data)
{
blob_get_async_t* async = user_data;
async->callback(async->out_found, async->out_data, async->out_size, async->user_data);
tf_free(async->out_data);
tf_free(async);
}
void tf_ssb_db_blob_get_async(tf_ssb_t* ssb, const char* id, tf_ssb_db_blob_get_callback_t* callback, void* user_data)
{
blob_get_async_t* async = tf_malloc(sizeof(blob_get_async_t));
*async = (blob_get_async_t) {
.ssb = ssb,
.callback = callback,
.user_data = user_data,
};
snprintf(async->id, sizeof(async->id), "%s", id);
tf_ssb_run_work(ssb, _tf_ssb_db_blob_get_async_work, _tf_ssb_db_blob_get_async_after_work, async);
}
typedef struct _blob_store_work_t
{
const uint8_t* blob;
size_t size;
char id[k_blob_id_len];
bool is_new;
tf_ssb_db_blob_store_callback_t* callback;
void* user_data;
} blob_store_work_t;
static void _tf_ssb_db_blob_store_work(tf_ssb_t* ssb, void* user_data)
{
blob_store_work_t* blob_work = user_data;
if (!tf_ssb_is_shutting_down(ssb))
{
tf_ssb_db_blob_store(ssb, blob_work->blob, blob_work->size, blob_work->id, sizeof(blob_work->id), &blob_work->is_new);
}
}
static void _tf_ssb_db_blob_store_after_work(tf_ssb_t* ssb, int status, void* user_data)
{
blob_store_work_t* blob_work = user_data;
if (status == 0 && *blob_work->id)
{
tf_ssb_notify_blob_stored(ssb, blob_work->id);
}
if (status != 0)
{
tf_printf("tf_ssb_db_blob_store_async -> uv_queue_work failed asynchronously: %s\n", uv_strerror(status));
}
if (blob_work->callback)
{
blob_work->callback(status == 0 ? blob_work->id : NULL, blob_work->is_new, blob_work->user_data);
}
tf_free(blob_work);
}
void tf_ssb_db_blob_store_async(tf_ssb_t* ssb, const uint8_t* blob, size_t size, tf_ssb_db_blob_store_callback_t* callback, void* user_data)
{
blob_store_work_t* work = tf_malloc(sizeof(blob_store_work_t));
*work = (blob_store_work_t) {
.blob = blob,
.size = size,
.callback = callback,
.user_data = user_data,
};
tf_ssb_run_work(ssb, _tf_ssb_db_blob_store_work, _tf_ssb_db_blob_store_after_work, work);
}
bool tf_ssb_db_blob_store(tf_ssb_t* ssb, const uint8_t* blob, size_t size, char* out_id, size_t out_id_size, bool* out_new)
{
bool result = false;
uint8_t hash[crypto_hash_sha256_BYTES];
crypto_hash_sha256(hash, blob, size);
char hash64[256];
tf_base64_encode(hash, sizeof(hash), hash64, sizeof(hash64));
char id[512];
snprintf(id, sizeof(id), "&%s.sha256", hash64);
int rows = 0;
sqlite3* db = tf_ssb_acquire_db_writer(ssb);
sqlite3_stmt* statement;
if (sqlite3_prepare(db, "INSERT INTO blobs (id, content, created) VALUES (?1, ?2, CAST(strftime('%s') AS INTEGER)) ON CONFLICT DO NOTHING", -1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, id, -1, NULL) == SQLITE_OK && sqlite3_bind_blob(statement, 2, blob, size, NULL) == SQLITE_OK)
{
result = sqlite3_step(statement) == SQLITE_DONE;
rows = sqlite3_changes(db);
}
else
{
tf_printf("bind failed: %s\n", sqlite3_errmsg(db));
}
sqlite3_finalize(statement);
}
else
{
tf_printf("%s: prepare failed: %s\n", __FUNCTION__, sqlite3_errmsg(db));
}
tf_ssb_release_db_writer(ssb, db);
if (result && out_id)
{
snprintf(out_id, out_id_size, "%s", id);
}
if (out_new)
{
*out_new = rows != 0;
}
return result;
}
bool tf_ssb_db_get_message_by_author_and_sequence(tf_ssb_t* ssb, const char* author, int64_t sequence, char* out_message_id, size_t out_message_id_size, char* out_previous,
size_t out_previous_size, double* out_timestamp, char** out_content, char* out_hash, size_t out_hash_size, char* out_signature, size_t out_signature_size, int* out_flags)
{
bool found = false;
sqlite3_stmt* statement;
const char* query = "SELECT id, previous, timestamp, json(content), hash, signature, flags FROM messages WHERE author = ?1 AND sequence = ?2";
sqlite3* db = tf_ssb_acquire_db_reader(ssb);
if (sqlite3_prepare(db, query, -1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, author, -1, NULL) == SQLITE_OK && sqlite3_bind_int64(statement, 2, sequence) == SQLITE_OK && sqlite3_step(statement) == SQLITE_ROW)
{
if (out_message_id)
{
snprintf(out_message_id, out_message_id_size, "%s", (const char*)sqlite3_column_text(statement, 0));
}
if (out_previous)
{
if (sqlite3_column_type(statement, 1) == SQLITE_NULL)
{
if (out_previous_size)
{
*out_previous = '\0';
}
}
else
{
snprintf(out_previous, out_previous_size, "%s", (const char*)sqlite3_column_text(statement, 1));
}
}
if (out_timestamp)
{
*out_timestamp = sqlite3_column_double(statement, 2);
}
if (out_content)
{
*out_content = tf_strdup((const char*)sqlite3_column_text(statement, 3));
}
if (out_hash)
{
snprintf(out_hash, out_hash_size, "%s", (const char*)sqlite3_column_text(statement, 4));
}
if (out_signature)
{
snprintf(out_signature, out_signature_size, "%s", (const char*)sqlite3_column_text(statement, 5));
}
if (out_flags)
{
*out_flags = sqlite3_column_int(statement, 6);
}
found = true;
}
sqlite3_finalize(statement);
}
else
{
tf_printf("%s: prepare failed: %s\n", __FUNCTION__, sqlite3_errmsg(db));
}
tf_ssb_release_db_reader(ssb, db);
return found;
}
bool tf_ssb_db_get_latest_message_by_author(tf_ssb_t* ssb, const char* author, int64_t* out_sequence, char* out_message_id, size_t out_message_id_size)
{
bool found = false;
sqlite3_stmt* statement;
sqlite3* db = tf_ssb_acquire_db_reader(ssb);
if (out_message_id)
{
const char* query = "SELECT id, sequence FROM messages WHERE author = ?1 ORDER BY sequence DESC LIMIT 1";
if (sqlite3_prepare(db, query, -1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, author, -1, NULL) == SQLITE_OK && sqlite3_step(statement) == SQLITE_ROW)
{
if (out_sequence)
{
*out_sequence = sqlite3_column_int64(statement, 1);
}
if (out_message_id)
{
strncpy(out_message_id, (const char*)sqlite3_column_text(statement, 0), out_message_id_size - 1);
}
found = true;
}
sqlite3_finalize(statement);
}
else
{
tf_printf("%s: prepare failed: %s\n", __FUNCTION__, sqlite3_errmsg(db));
}
}
else
{
const char* query = "SELECT max_sequence FROM messages_stats WHERE author = ?1";
if (sqlite3_prepare(db, query, -1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, author, -1, NULL) == SQLITE_OK && sqlite3_step(statement) == SQLITE_ROW)
{
if (out_sequence)
{
*out_sequence = sqlite3_column_int64(statement, 0);
}
found = true;
}
sqlite3_finalize(statement);
}
else
{
tf_printf("%s: prepare failed: %s\n", __FUNCTION__, sqlite3_errmsg(db));
}
}
tf_ssb_release_db_reader(ssb, db);
return found;
}
static JSValue _tf_ssb_sqlite_bind_json(JSContext* context, sqlite3* db, sqlite3_stmt* statement, JSValue binds)
{
if (JS_IsUndefined(binds))
{
return JS_UNDEFINED;
}
if (!JS_IsArray(context, binds))
{
return JS_ThrowTypeError(context, "Expected bind parameters to be an array.");
}
JSValue result = JS_UNDEFINED;
int32_t length = tf_util_get_length(context, binds);
for (int i = 0; i < length && JS_IsUndefined(result); i++)
{
JSValue value = JS_GetPropertyUint32(context, binds, i);
if (JS_IsNumber(value))
{
int64_t number = 0;
JS_ToInt64(context, &number, value);
if (sqlite3_bind_int64(statement, i + 1, number) != SQLITE_OK)
{
result = JS_ThrowInternalError(context, "Failed to bind: %s.", sqlite3_errmsg(db));
}
}
else if (JS_IsBool(value))
{
if (sqlite3_bind_int(statement, i + 1, JS_ToBool(context, value) ? 1 : 0) != SQLITE_OK)
{
result = JS_ThrowInternalError(context, "Failed to bind: %s.", sqlite3_errmsg(db));
}
}
else if (JS_IsNull(value))
{
if (sqlite3_bind_null(statement, i + 1) != SQLITE_OK)
{
result = JS_ThrowInternalError(context, "Failed to bind: %s.", sqlite3_errmsg(db));
}
}
else
{
size_t str_len = 0;
const char* str = JS_ToCStringLen(context, &str_len, value);
if (str)
{
if (sqlite3_bind_text(statement, i + 1, str, str_len, SQLITE_TRANSIENT) != SQLITE_OK)
{
result = JS_ThrowInternalError(context, "Failed to bind: %s.", sqlite3_errmsg(db));
}
JS_FreeCString(context, str);
}
else
{
result = JS_ThrowInternalError(context, "Could not convert bind argument %d to string.", i);
}
}
JS_FreeValue(context, value);
}
return result;
}
static JSValue _tf_ssb_sqlite_row_to_json(JSContext* context, sqlite3_stmt* row)
{
JSValue result = JS_NewObject(context);
for (int i = 0; i < sqlite3_column_count(row); i++)
{
const char* name = sqlite3_column_name(row, i);
switch (sqlite3_column_type(row, i))
{
case SQLITE_INTEGER:
JS_SetPropertyStr(context, result, name, JS_NewInt64(context, sqlite3_column_int64(row, i)));
break;
case SQLITE_FLOAT:
JS_SetPropertyStr(context, result, name, JS_NewFloat64(context, sqlite3_column_double(row, i)));
break;
case SQLITE_TEXT:
JS_SetPropertyStr(context, result, name, JS_NewStringLen(context, (const char*)sqlite3_column_text(row, i), sqlite3_column_bytes(row, i)));
break;
case SQLITE_BLOB:
JS_SetPropertyStr(context, result, name, JS_NewArrayBufferCopy(context, sqlite3_column_blob(row, i), sqlite3_column_bytes(row, i)));
break;
case SQLITE_NULL:
JS_SetPropertyStr(context, result, name, JS_NULL);
break;
}
}
return result;
}
int tf_ssb_sqlite_authorizer(void* user_data, int action_code, const char* arg0, const char* arg1, const char* arg2, const char* arg3)
{
int result = SQLITE_DENY;
switch (action_code)
{
case SQLITE_SELECT:
case SQLITE_FUNCTION:
result = SQLITE_OK;
break;
case SQLITE_READ:
result = (strcmp(arg0, "blob_wants_cache") == 0 || strcmp(arg0, "blob_wants_view") == 0 || strcmp(arg0, "json_each") == 0 || strcmp(arg0, "json_tree") == 0 ||
strcmp(arg0, "messages") == 0 || strcmp(arg0, "messages_stats") == 0 || strcmp(arg0, "messages_fts") == 0 || strcmp(arg0, "messages_fts_idx") == 0 ||
strcmp(arg0, "messages_fts_config") == 0 || strcmp(arg0, "messages_refs") == 0 || strcmp(arg0, "messages_refs_message_idx") == 0 ||
strcmp(arg0, "messages_refs_ref_idx") == 0 || strcmp(arg0, "sqlite_master") == 0 || false)
? SQLITE_OK
: SQLITE_DENY;
break;
case SQLITE_PRAGMA:
result = strcmp(arg0, "data_version") == 0 ? SQLITE_OK : SQLITE_DENY;
break;
case SQLITE_UPDATE:
result = strcmp(arg0, "sqlite_master") == 0 ? SQLITE_OK : SQLITE_DENY;
break;
}
if (result != SQLITE_OK)
{
tf_printf("Denying sqlite access to %d %s %s %s %s\n", action_code, arg0, arg1, arg2, arg3);
fflush(stdout);
}
return result;
}
JSValue tf_ssb_db_visit_query(tf_ssb_t* ssb, const char* query, const JSValue binds, void (*callback)(JSValue row, void* user_data), void* user_data)
{
JSValue result = JS_UNDEFINED;
sqlite3* db = tf_ssb_acquire_db_reader_restricted(ssb);
JSContext* context = tf_ssb_get_context(ssb);
sqlite3_stmt* statement;
if (sqlite3_prepare(db, query, -1, &statement, NULL) == SQLITE_OK)
{
JSValue bind_result = _tf_ssb_sqlite_bind_json(context, db, statement, binds);
if (JS_IsUndefined(bind_result))
{
int r = SQLITE_OK;
while ((r = sqlite3_step(statement)) == SQLITE_ROW)
{
JSValue row = _tf_ssb_sqlite_row_to_json(context, statement);
tf_trace_t* trace = tf_ssb_get_trace(ssb);
tf_trace_begin(trace, "callback");
callback(row, user_data);
tf_trace_end(trace);
JS_FreeValue(context, row);
}
if (r != SQLITE_DONE)
{
result = JS_ThrowInternalError(context, "SQL Error %s: running \"%s\".", sqlite3_errmsg(db), query);
}
}
else
{
result = bind_result;
}
sqlite3_finalize(statement);
}
else
{
result = JS_ThrowInternalError(context, "SQL Error %s: preparing \"%s\".", sqlite3_errmsg(db), query);
}
tf_ssb_release_db_reader(ssb, db);
return result;
}
JSValue tf_ssb_format_message(
JSContext* context, const char* previous, const char* author, int64_t sequence, double timestamp, const char* hash, const char* content, const char* signature, int flags)
{
JSValue value = JS_NewObject(context);
JS_SetPropertyStr(context, value, "previous", (previous && *previous) ? JS_NewString(context, previous) : JS_NULL);
if (flags & k_tf_ssb_message_flag_sequence_before_author)
{
JS_SetPropertyStr(context, value, "sequence", JS_NewInt64(context, sequence));
JS_SetPropertyStr(context, value, "author", JS_NewString(context, author));
}
else
{
JS_SetPropertyStr(context, value, "author", JS_NewString(context, author));
JS_SetPropertyStr(context, value, "sequence", JS_NewInt64(context, sequence));
}
JS_SetPropertyStr(context, value, "timestamp", JS_NewFloat64(context, timestamp));
JS_SetPropertyStr(context, value, "hash", JS_NewString(context, hash));
JS_SetPropertyStr(context, value, "content", JS_ParseJSON(context, content, strlen(content), NULL));
JS_SetPropertyStr(context, value, "signature", JS_NewString(context, signature));
return value;
}
int tf_ssb_db_identity_get_count_for_user(tf_ssb_t* ssb, const char* user)
{
int count = 0;
sqlite3* db = tf_ssb_acquire_db_reader(ssb);
sqlite3_stmt* statement = NULL;
if (sqlite3_prepare(db, "SELECT COUNT(*) FROM identities WHERE user = ?", -1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, user, -1, NULL) == SQLITE_OK)
{
if (sqlite3_step(statement) == SQLITE_ROW)
{
count = sqlite3_column_int(statement, 0);
}
}
sqlite3_finalize(statement);
}
tf_ssb_release_db_reader(ssb, db);
return count;
}
bool tf_ssb_db_identity_create(tf_ssb_t* ssb, const char* user, uint8_t* out_public_key, uint8_t* out_private_key)
{
int count = tf_ssb_db_identity_get_count_for_user(ssb, user);
if (count < 16)
{
char public[512];
char private[512];
tf_ssb_generate_keys_buffer(public, sizeof(public), private, sizeof(private));
if (tf_ssb_db_identity_add(ssb, user, public, private))
{
if (out_public_key)
{
tf_ssb_id_str_to_bin(out_public_key, public);
}
if (out_private_key)
{
tf_ssb_id_str_to_bin(out_private_key, private);
/* HACK: tf_ssb_id_str_to_bin only produces 32 bytes even though the full private key is 32 + 32. */
tf_ssb_id_str_to_bin(out_private_key + crypto_sign_PUBLICKEYBYTES, public);
}
return true;
}
}
return false;
}
bool tf_ssb_db_identity_add(tf_ssb_t* ssb, const char* user, const char* public_key, const char* private_key)
{
bool added = false;
sqlite3* db = tf_ssb_acquire_db_writer(ssb);
sqlite3_stmt* statement = NULL;
if (sqlite3_prepare(db, "INSERT INTO identities (user, public_key, private_key) VALUES (?, ?, ?) ON CONFLICT DO NOTHING", -1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, user, -1, NULL) == SQLITE_OK && sqlite3_bind_text(statement, 2, public_key, -1, NULL) == SQLITE_OK &&
sqlite3_bind_text(statement, 3, private_key, -1, NULL) == SQLITE_OK)
{
added = sqlite3_step(statement) == SQLITE_DONE && sqlite3_changes(db) != 0;
if (!added)
{
tf_printf("Unable to add identity: %s.\n", sqlite3_errmsg(db));
}
}
sqlite3_finalize(statement);
}
tf_ssb_release_db_writer(ssb, db);
return added;
}
bool tf_ssb_db_identity_delete(tf_ssb_t* ssb, const char* user, const char* public_key)
{
bool removed = false;
sqlite3* db = tf_ssb_acquire_db_writer(ssb);
sqlite3_stmt* statement = NULL;
tf_printf("deleting [%s] [%s]\n", user, public_key);
if (sqlite3_prepare(db, "DELETE FROM identities WHERE user = ? AND public_key = ?", -1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, user, -1, NULL) == SQLITE_OK && sqlite3_bind_text(statement, 2, public_key, -1, NULL) == SQLITE_OK)
{
removed = sqlite3_step(statement) == SQLITE_DONE && sqlite3_changes(db) != 0;
if (!removed)
{
tf_printf("Unable to delete identity: %s.\n", sqlite3_errmsg(db));
}
}
sqlite3_finalize(statement);
}
tf_ssb_release_db_writer(ssb, db);
return removed;
}
void tf_ssb_db_identity_visit(tf_ssb_t* ssb, const char* user, void (*callback)(const char* identity, void* user_data), void* user_data)
{
sqlite3* db = tf_ssb_acquire_db_reader(ssb);
sqlite3_stmt* statement = NULL;
if (sqlite3_prepare(db, "SELECT public_key FROM identities WHERE user = ? ORDER BY public_key", -1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, user, -1, NULL) == SQLITE_OK)
{
while (sqlite3_step(statement) == SQLITE_ROW)
{
callback((const char*)sqlite3_column_text(statement, 0), user_data);
}
}
sqlite3_finalize(statement);
}
tf_ssb_release_db_reader(ssb, db);
}
void tf_ssb_db_identity_visit_all(tf_ssb_t* ssb, void (*callback)(const char* identity, void* user_data), void* user_data)
{
sqlite3* db = tf_ssb_acquire_db_reader(ssb);
sqlite3_stmt* statement = NULL;
if (sqlite3_prepare(db, "SELECT public_key FROM identities ORDER BY public_key", -1, &statement, NULL) == SQLITE_OK)
{
while (sqlite3_step(statement) == SQLITE_ROW)
{
callback((const char*)sqlite3_column_text(statement, 0), user_data);
}
sqlite3_finalize(statement);
}
tf_ssb_release_db_reader(ssb, db);
}
bool tf_ssb_db_identity_get_private_key(tf_ssb_t* ssb, const char* user, const char* public_key, uint8_t* out_private_key, size_t private_key_size)
{
bool success = false;
if (out_private_key)
{
memset(out_private_key, 0, private_key_size);
}
sqlite3* db = tf_ssb_acquire_db_reader(ssb);
sqlite3_stmt* statement = NULL;
if (sqlite3_prepare(db, "SELECT private_key FROM identities WHERE user = ? AND public_key = ?", -1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, user, -1, NULL) == SQLITE_OK &&
sqlite3_bind_text(statement, 2, (public_key && *public_key == '@') ? public_key + 1 : public_key, -1, NULL) == SQLITE_OK)
{
if (sqlite3_step(statement) == SQLITE_ROW)
{
const char* key = (const char*)sqlite3_column_text(statement, 0);
if (out_private_key && private_key_size)
{
int r = tf_base64_decode(key, sqlite3_column_bytes(statement, 0) - strlen(".ed25519"), out_private_key, private_key_size);
success = r > 0;
}
else
{
success = true;
}
}
}
else
{
tf_printf("Bind failed: %s.\n", sqlite3_errmsg(db));
}
sqlite3_finalize(statement);
}
else
{
tf_printf("Prepare failed: %s.\n", sqlite3_errmsg(db));
}
tf_ssb_release_db_reader(ssb, db);
return success;
}
typedef struct _following_t following_t;
typedef struct _following_t
{
char id[k_id_base64_len];
following_t** following;
following_t** blocking;
int following_count;
int blocking_count;
int depth;
int ref_count;
int block_ref_count;
bool populated;
} following_t;
static int _following_compare(const void* a, const void* b)
{
const char* ida = a;
const following_t* const* followingb = b;
return strcmp(ida, (*followingb)->id);
}
static bool _has_following_entry(const char* id, following_t** list, int count)
{
return count ? bsearch(id, list, count, sizeof(following_t*), _following_compare) != NULL : false;
}
static bool _add_following_entry(following_t*** list, int* count, following_t* add)
{
int index = tf_util_insert_index(add->id, *list, *count, sizeof(following_t*), _following_compare);
if (index >= *count || strcmp(add->id, (*list)[index]->id) != 0)
{
*list = tf_resize_vec(*list, sizeof(**list) * (*count + 1));
if (*count - index)
{
memmove(*list + index + 1, *list + index, sizeof(following_t*) * (*count - index));
}
(*list)[index] = add;
(*count)++;
return true;
}
return false;
}
static bool _remove_following_entry(following_t*** list, int* count, following_t* remove)
{
int index = tf_util_insert_index(remove->id, *list, *count, sizeof(following_t*), _following_compare);
if (index < *count && strcmp(remove->id, (*list)[index]->id) == 0)
{
if (*count - index > 1)
{
memmove(*list + index, *list + index + 1, sizeof(following_t*) * (*count - index - 1));
}
*list = tf_resize_vec(*list, sizeof(**list) * (*count - 1));
(*count)--;
return true;
}
return false;
}
typedef struct _block_node_t block_node_t;
typedef struct _block_node_t
{
following_t* entry;
block_node_t* parent;
} block_node_t;
static bool _is_blocked_by_active_blocks(const char* id, const block_node_t* blocks)
{
for (const block_node_t* b = blocks; b; b = b->parent)
{
if (_has_following_entry(id, b->entry->blocking, b->entry->blocking_count))
{
return true;
}
}
return false;
}
static following_t* _make_following_node(const char* id, following_t*** following, int* following_count, block_node_t* blocks, bool include_blocks)
{
if (!include_blocks && _is_blocked_by_active_blocks(id, blocks))
{
return NULL;
}
int index = tf_util_insert_index(id, *following, *following_count, sizeof(following_t*), _following_compare);
following_t* entry = NULL;
if (index < *following_count && strcmp(id, (*following)[index]->id) == 0)
{
entry = (*following)[index];
}
else
{
*following = tf_resize_vec(*following, sizeof(*following) * (*following_count + 1));
if (*following_count - index)
{
memmove(*following + index + 1, *following + index, sizeof(following_t*) * (*following_count - index));
}
entry = tf_malloc(sizeof(following_t));
(*following)[index] = entry;
(*following_count)++;
memset(entry, 0, sizeof(*entry));
entry->depth = INT_MAX;
snprintf(entry->id, sizeof(entry->id), "%s", id);
}
return entry;
}
static void _populate_follows_and_blocks(tf_ssb_t* ssb, following_t* entry, following_t*** following, int* following_count, block_node_t* active_blocks, bool include_blocks)
{
sqlite3* db = tf_ssb_acquire_db_reader(ssb);
sqlite3_stmt* statement = NULL;
if (sqlite3_prepare(db,
"SELECT content ->> '$.contact' AS contact, content ->> '$.following', content ->> '$.blocking' "
"FROM messages "
"WHERE contact IS NOT NULL AND author = ? AND content ->> '$.type' = 'contact' "
"ORDER BY sequence",
-1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, entry->id, -1, NULL) == SQLITE_OK)
{
while (sqlite3_step(statement) == SQLITE_ROW)
{
const char* contact = (const char*)sqlite3_column_text(statement, 0);
if (sqlite3_column_type(statement, 1) != SQLITE_NULL)
{
bool is_following = sqlite3_column_int(statement, 1) != 0;
following_t* next = _make_following_node(contact, following, following_count, active_blocks, include_blocks);
if (next)
{
if (is_following)
{
if (_add_following_entry(&entry->following, &entry->following_count, next))
{
next->ref_count++;
}
}
else
{
if (_remove_following_entry(&entry->following, &entry->following_count, next))
{
next->ref_count--;
}
}
}
}
if (sqlite3_column_type(statement, 2) != SQLITE_NULL)
{
bool is_blocking = sqlite3_column_int(statement, 2) != 0;
following_t* next = _make_following_node(contact, following, following_count, active_blocks, include_blocks);
if (next)
{
if (is_blocking)
{
if (_add_following_entry(&entry->blocking, &entry->blocking_count, next))
{
next->block_ref_count++;
}
}
else
{
if (_remove_following_entry(&entry->blocking, &entry->blocking_count, next))
{
next->block_ref_count--;
}
}
}
}
}
}
sqlite3_finalize(statement);
}
tf_ssb_release_db_reader(ssb, db);
}
static void _get_following(
tf_ssb_t* ssb, following_t* entry, following_t*** following, int* following_count, int depth, int max_depth, block_node_t* active_blocks, bool include_blocks)
{
int old_depth = entry->depth;
entry->depth = tf_min(depth, entry->depth);
if (depth < max_depth && depth < old_depth)
{
if (!_is_blocked_by_active_blocks(entry->id, active_blocks))
{
if (!entry->populated)
{
entry->populated = true;
_populate_follows_and_blocks(ssb, entry, following, following_count, active_blocks, include_blocks);
}
block_node_t blocks = { .entry = entry, .parent = active_blocks };
for (int i = 0; i < entry->following_count; i++)
{
_get_following(ssb, entry->following[i], following, following_count, depth + 1, max_depth, &blocks, include_blocks);
}
}
}
}
tf_ssb_following_t* tf_ssb_db_following_deep(tf_ssb_t* ssb, const char** ids, int count, int depth, bool include_blocks)
{
following_t** following = NULL;
int following_count = 0;
for (int i = 0; i < count; i++)
{
following_t* entry = _make_following_node(ids[i], &following, &following_count, NULL, include_blocks);
_get_following(ssb, entry, &following, &following_count, 0, depth, NULL, include_blocks);
entry->ref_count++;
}
int actual_following_count = 0;
for (int i = 0; i < following_count; i++)
{
if (following[i]->ref_count > 0 || include_blocks)
{
actual_following_count++;
}
}
tf_ssb_following_t* result = tf_malloc(sizeof(tf_ssb_following_t) * (actual_following_count + 1));
memset(result, 0, sizeof(tf_ssb_following_t) * (actual_following_count + 1));
int write_index = 0;
for (int i = 0; i < following_count; i++)
{
if (following[i]->ref_count > 0 || include_blocks)
{
snprintf(result[write_index].id, sizeof(result[write_index].id), "%s", following[i]->id);
result[write_index].following_count = following[i]->following_count;
result[write_index].blocking_count = following[i]->blocking_count;
result[write_index].followed_by_count = following[i]->ref_count;
result[write_index].blocked_by_count = following[i]->block_ref_count;
result[write_index].depth = following[i]->depth;
write_index++;
}
}
for (int i = 0; i < following_count; i++)
{
tf_free(following[i]->following);
tf_free(following[i]->blocking);
tf_free(following[i]);
}
tf_free(following);
return result;
}
const char** tf_ssb_db_following_deep_ids(tf_ssb_t* ssb, const char** ids, int count, int depth)
{
following_t** following = NULL;
int following_count = 0;
for (int i = 0; i < count; i++)
{
following_t* entry = _make_following_node(ids[i], &following, &following_count, NULL, false);
_get_following(ssb, entry, &following, &following_count, 0, depth, NULL, false);
entry->ref_count++;
}
int actual_following_count = 0;
for (int i = 0; i < following_count; i++)
{
if (following[i]->ref_count > 0)
{
actual_following_count++;
}
}
char** result = tf_malloc(sizeof(char*) * (actual_following_count + 1) + k_id_base64_len * actual_following_count);
char* result_ids = (char*)result + sizeof(char*) * (actual_following_count + 1);
int write_index = 0;
for (int i = 0; i < following_count; i++)
{
if (following[i]->ref_count > 0)
{
result[write_index] = result_ids + k_id_base64_len * write_index;
snprintf(result[write_index], k_id_base64_len, "%s", following[i]->id);
write_index++;
}
}
result[actual_following_count] = NULL;
for (int i = 0; i < following_count; i++)
{
tf_free(following[i]->following);
tf_free(following[i]->blocking);
tf_free(following[i]);
}
tf_free(following);
return (const char**)result;
}
typedef struct _identities_t
{
const char** ids;
int count;
} identities_t;
static void _add_identity(const char* identity, void* user_data)
{
identities_t* identities = user_data;
char full_id[k_id_base64_len];
snprintf(full_id, sizeof(full_id), "@%s", identity);
identities->ids = tf_resize_vec(identities->ids, sizeof(const char*) * (identities->count + 1));
identities->ids[identities->count++] = tf_strdup(full_id);
}
const char** tf_ssb_db_get_all_visible_identities(tf_ssb_t* ssb, int depth)
{
identities_t identities = { 0 };
tf_ssb_db_identity_visit_all(ssb, _add_identity, &identities);
const char** following = tf_ssb_db_following_deep_ids(ssb, identities.ids, identities.count, depth);
for (int i = 0; i < identities.count; i++)
{
tf_free((void*)identities.ids[i]);
}
tf_free(identities.ids);
return following;
}
JSValue tf_ssb_db_get_message_by_id(tf_ssb_t* ssb, const char* id, bool is_keys)
{
JSValue result = JS_UNDEFINED;
JSContext* context = tf_ssb_get_context(ssb);
sqlite3* db = tf_ssb_acquire_db_reader(ssb);
sqlite3_stmt* statement;
if (sqlite3_prepare(db, "SELECT previous, author, id, sequence, timestamp, hash, json(content), signature, flags FROM messages WHERE id = ?", -1, &statement, NULL) ==
SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, id, -1, NULL) == SQLITE_OK)
{
if (sqlite3_step(statement) == SQLITE_ROW)
{
JSValue message = JS_UNDEFINED;
JSValue formatted = tf_ssb_format_message(context, (const char*)sqlite3_column_text(statement, 0), (const char*)sqlite3_column_text(statement, 1),
sqlite3_column_int64(statement, 3), sqlite3_column_double(statement, 4), (const char*)sqlite3_column_text(statement, 5),
(const char*)sqlite3_column_text(statement, 6), (const char*)sqlite3_column_text(statement, 7), sqlite3_column_int(statement, 8));
if (is_keys)
{
message = JS_NewObject(context);
JS_SetPropertyStr(context, message, "key", JS_NewString(context, (const char*)sqlite3_column_text(statement, 2)));
JS_SetPropertyStr(context, message, "value", formatted);
JS_SetPropertyStr(context, message, "timestamp", JS_NewString(context, (const char*)sqlite3_column_text(statement, 4)));
}
else
{
message = formatted;
}
result = message;
}
}
sqlite3_finalize(statement);
}
tf_ssb_release_db_reader(ssb, db);
return result;
}
tf_ssb_db_stored_connection_t* tf_ssb_db_get_stored_connections(tf_ssb_t* ssb, int* out_count)
{
sqlite3* db = tf_ssb_acquire_db_reader(ssb);
tf_ssb_db_stored_connection_t* result = NULL;
int count = 0;
sqlite3_stmt* statement;
if (sqlite3_prepare(db, "SELECT host, port, key FROM connections ORDER BY host, port, key", -1, &statement, NULL) == SQLITE_OK)
{
while (sqlite3_step(statement) == SQLITE_ROW)
{
result = tf_resize_vec(result, sizeof(tf_ssb_db_stored_connection_t) * (count + 1));
result[count] = (tf_ssb_db_stored_connection_t) {
.port = sqlite3_column_int(statement, 1),
};
snprintf(result[count].address, sizeof(result[count].address), "%s", (const char*)sqlite3_column_text(statement, 0));
snprintf(result[count].pubkey, sizeof(result[count].pubkey), "%s", (const char*)sqlite3_column_text(statement, 2));
count++;
}
sqlite3_finalize(statement);
}
tf_ssb_release_db_reader(ssb, db);
*out_count = count;
return result;
}
void tf_ssb_db_forget_stored_connection(tf_ssb_t* ssb, const char* address, int port, const char* pubkey)
{
sqlite3* db = tf_ssb_acquire_db_writer(ssb);
sqlite3_stmt* statement;
if (sqlite3_prepare(db, "DELETE FROM connections WHERE host = ? AND port = ? AND key = ?", -1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, address, -1, NULL) != SQLITE_OK || sqlite3_bind_int(statement, 2, port) != SQLITE_OK ||
sqlite3_bind_text(statement, 3, pubkey, -1, NULL) != SQLITE_OK || sqlite3_step(statement) != SQLITE_DONE)
{
tf_printf("Delete stored connection: %s.\n", sqlite3_errmsg(db));
}
sqlite3_finalize(statement);
}
tf_ssb_release_db_writer(ssb, db);
}
bool tf_ssb_db_get_account_password_hash(tf_ssb_t* ssb, const char* name, char* out_password, size_t password_size)
{
bool result = false;
sqlite3* db = tf_ssb_acquire_db_reader(ssb);
sqlite3_stmt* statement = NULL;
if (sqlite3_prepare(db, "SELECT value ->> '$.password' FROM properties WHERE id = 'auth' AND key = 'user:' || ?", -1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, name, -1, NULL) == SQLITE_OK)
{
if (sqlite3_step(statement) == SQLITE_ROW)
{
snprintf(out_password, password_size, "%s", (const char*)sqlite3_column_text(statement, 0));
result = true;
}
}
sqlite3_finalize(statement);
}
tf_ssb_release_db_reader(ssb, db);
return result;
}
bool tf_ssb_db_set_account_password(uv_loop_t* loop, sqlite3* db, JSContext* context, const char* name, const char* password)
{
bool result = false;
static const int k_salt_length = 12;
char buffer[16];
size_t bytes = uv_random(loop, &(uv_random_t) { 0 }, buffer, sizeof(buffer), 0, NULL) == 0 ? sizeof(buffer) : 0;
char output[7 + 22 + 1];
char* salt = crypt_gensalt_rn("$2b$", k_salt_length, buffer, bytes, output, sizeof(output));
char hash_output[7 + 22 + 31 + 1];
char* hash = crypt_rn(password, salt, hash_output, sizeof(hash_output));
JSValue user_entry = JS_NewObject(context);
JS_SetPropertyStr(context, user_entry, "password", JS_NewString(context, hash));
JSValue user_json = JS_JSONStringify(context, user_entry, JS_NULL, JS_NULL);
size_t user_length = 0;
const char* user_string = JS_ToCStringLen(context, &user_length, user_json);
sqlite3_stmt* statement = NULL;
if (sqlite3_prepare(db, "INSERT OR REPLACE INTO properties (id, key, value) VALUES ('auth', 'user:' || ?, ?)", -1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, name, -1, NULL) == SQLITE_OK && sqlite3_bind_text(statement, 2, user_string, user_length, NULL) == SQLITE_OK)
{
result = sqlite3_step(statement) == SQLITE_DONE;
}
sqlite3_finalize(statement);
}
JS_FreeCString(context, user_string);
JS_FreeValue(context, user_json);
JS_FreeValue(context, user_entry);
return result;
}
bool tf_ssb_db_register_account(uv_loop_t* loop, sqlite3* db, JSContext* context, const char* name, const char* password)
{
bool result = false;
JSValue users_array = JS_UNDEFINED;
bool registration_allowed = true;
tf_ssb_db_get_global_setting_bool(db, "account_registration", ®istration_allowed);
if (registration_allowed)
{
sqlite3_stmt* statement = NULL;
if (sqlite3_prepare(db, "SELECT value FROM properties WHERE id = 'auth' AND key = 'users'", -1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_step(statement) == SQLITE_ROW)
{
users_array = JS_ParseJSON(context, (const char*)sqlite3_column_text(statement, 0), sqlite3_column_bytes(statement, 0), NULL);
}
sqlite3_finalize(statement);
}
if (JS_IsUndefined(users_array))
{
users_array = JS_NewArray(context);
}
int length = tf_util_get_length(context, users_array);
JS_SetPropertyUint32(context, users_array, length, JS_NewString(context, name));
JSValue json = JS_JSONStringify(context, users_array, JS_NULL, JS_NULL);
JS_FreeValue(context, users_array);
size_t value_length = 0;
const char* value = JS_ToCStringLen(context, &value_length, json);
if (sqlite3_prepare(db, "INSERT OR REPLACE INTO properties (id, key, value) VALUES ('auth', 'users', ?)", -1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, value, value_length, NULL) == SQLITE_OK)
{
result = sqlite3_step(statement) == SQLITE_DONE;
}
sqlite3_finalize(statement);
}
JS_FreeCString(context, value);
JS_FreeValue(context, json);
}
result = result && tf_ssb_db_set_account_password(loop, db, context, name, password);
return result;
}
const char* tf_ssb_db_get_property(tf_ssb_t* ssb, const char* id, const char* key)
{
char* result = NULL;
sqlite3* db = tf_ssb_acquire_db_reader(ssb);
sqlite3_stmt* statement = NULL;
if (sqlite3_prepare(db, "SELECT value FROM properties WHERE id = ? AND key = ?", -1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, id, -1, NULL) == SQLITE_OK && sqlite3_bind_text(statement, 2, key, -1, NULL) == SQLITE_OK)
{
if (sqlite3_step(statement) == SQLITE_ROW)
{
size_t length = sqlite3_column_bytes(statement, 0);
result = tf_malloc(length + 1);
memcpy(result, sqlite3_column_text(statement, 0), length);
result[length] = '\0';
}
}
sqlite3_finalize(statement);
}
tf_ssb_release_db_reader(ssb, db);
return result;
}
bool tf_ssb_db_set_property(tf_ssb_t* ssb, const char* id, const char* key, const char* value)
{
bool result = false;
sqlite3* db = tf_ssb_acquire_db_writer(ssb);
sqlite3_stmt* statement = NULL;
if (sqlite3_prepare(db, "INSERT OR REPLACE INTO properties (id, key, value) VALUES (?, ?, ?)", -1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, id, -1, NULL) == SQLITE_OK && sqlite3_bind_text(statement, 2, key, -1, NULL) == SQLITE_OK &&
sqlite3_bind_text(statement, 3, value, -1, NULL) == SQLITE_OK)
{
result = sqlite3_step(statement) == SQLITE_DONE;
}
sqlite3_finalize(statement);
}
tf_ssb_release_db_writer(ssb, db);
return result;
}
bool tf_ssb_db_remove_property(tf_ssb_t* ssb, const char* id, const char* key)
{
bool result = false;
sqlite3* db = tf_ssb_acquire_db_writer(ssb);
sqlite3_stmt* statement = NULL;
if (sqlite3_prepare(db, "DELETE FROM properties WHERE id = ? AND key = ?", -1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, id, -1, NULL) == SQLITE_OK && sqlite3_bind_text(statement, 2, key, -1, NULL) == SQLITE_OK)
{
result = sqlite3_step(statement) == SQLITE_DONE && sqlite3_changes(db) != 0;
}
sqlite3_finalize(statement);
}
tf_ssb_release_db_writer(ssb, db);
return result;
}
bool tf_ssb_db_remove_value_from_array_property(tf_ssb_t* ssb, const char* id, const char* key, const char* value)
{
bool result = false;
sqlite3* db = tf_ssb_acquire_db_writer(ssb);
sqlite3_stmt* statement = NULL;
if (sqlite3_prepare(db,
"UPDATE properties SET value = json_remove(properties.value, entry.fullkey) FROM json_each(properties.value) AS entry WHERE properties.id = ? AND properties.key = ? "
"AND entry.value = ?",
-1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, id, -1, NULL) == SQLITE_OK && sqlite3_bind_text(statement, 2, key, -1, NULL) == SQLITE_OK &&
sqlite3_bind_text(statement, 3, value, -1, NULL) == SQLITE_OK)
{
result = sqlite3_step(statement) == SQLITE_DONE && sqlite3_changes(db) != 0;
}
sqlite3_finalize(statement);
}
tf_ssb_release_db_writer(ssb, db);
return result;
}
bool tf_ssb_db_add_value_to_array_property(tf_ssb_t* ssb, const char* id, const char* key, const char* value)
{
bool result = false;
sqlite3* db = tf_ssb_acquire_db_writer(ssb);
sqlite3_stmt* statement = NULL;
if (sqlite3_prepare(db,
"INSERT INTO properties (id, key, value) VALUES (?1, ?2, json_array(?3)) ON CONFLICT DO UPDATE SET value = json_insert(properties.value, '$[#]', ?3) WHERE "
"properties.id = ?1 AND properties.key = ?2 AND NOT EXISTS (SELECT 1 FROM json_each(properties.value) AS entry WHERE entry.value = ?3)",
-1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, id, -1, NULL) == SQLITE_OK && sqlite3_bind_text(statement, 2, key, -1, NULL) == SQLITE_OK &&
sqlite3_bind_text(statement, 3, value, -1, NULL) == SQLITE_OK)
{
result = sqlite3_step(statement) == SQLITE_DONE && sqlite3_changes(db) != 0;
}
sqlite3_finalize(statement);
}
tf_ssb_release_db_writer(ssb, db);
return result;
}
bool tf_ssb_db_identity_get_active(sqlite3* db, const char* user, const char* package_owner, const char* package_name, char* out_identity, size_t out_identity_size)
{
sqlite3_stmt* statement = NULL;
bool found = false;
if (sqlite3_prepare(db, "SELECT value FROM properties WHERE id = ? AND key = 'id:' || ? || ':' || ?", -1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, user, -1, NULL) == SQLITE_OK && sqlite3_bind_text(statement, 2, package_owner, -1, NULL) == SQLITE_OK &&
sqlite3_bind_text(statement, 3, package_name, -1, NULL) == SQLITE_OK && sqlite3_step(statement) == SQLITE_ROW)
{
snprintf(out_identity, out_identity_size, "%s", (const char*)sqlite3_column_text(statement, 0));
found = true;
}
sqlite3_finalize(statement);
}
return found;
}
typedef struct _resolve_index_t
{
const char* host;
const char* path;
void (*callback)(const char* path, void* user_data);
void* user_data;
} resolve_index_t;
static void _tf_ssb_db_resolve_index_work(tf_ssb_t* ssb, void* user_data)
{
resolve_index_t* request = user_data;
sqlite3* db = tf_ssb_acquire_db_reader(ssb);
sqlite3_stmt* statement;
if (sqlite3_prepare(db, "SELECT json_extract(value, '$.index_map') FROM properties WHERE id = 'core' AND key = 'settings'", -1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_step(statement) == SQLITE_ROW)
{
const char* index_map = (const char*)sqlite3_column_text(statement, 0);
const char* start = index_map;
while (start)
{
const char* end = strchr(start, '\n');
const char* equals = strchr(start, '=');
if (equals && strncasecmp(request->host, start, equals - start) == 0)
{
size_t value_length = end && equals < end ? (size_t)(end - (equals + 1)) : strlen(equals + 1);
char* path = tf_malloc(value_length + 1);
memcpy(path, equals + 1, value_length);
path[value_length] = '\0';
request->path = path;
break;
}
start = end ? end + 1 : NULL;
}
}
sqlite3_finalize(statement);
}
else
{
tf_printf("prepare failed: %s\n", sqlite3_errmsg(db));
}
if (!request->path)
{
if (sqlite3_prepare(db, "SELECT json_extract(value, '$.index') FROM properties WHERE id = 'core' AND key = 'settings'", -1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_step(statement) == SQLITE_ROW)
{
request->path = tf_strdup((const char*)sqlite3_column_text(statement, 0));
}
sqlite3_finalize(statement);
}
else
{
tf_printf("prepare failed: %s\n", sqlite3_errmsg(db));
}
}
tf_ssb_release_db_reader(ssb, db);
if (!request->path)
{
/* From default global settings. */
request->path = tf_strdup("/~core/ssb/");
}
}
static void _tf_ssb_db_resolve_index_after_work(tf_ssb_t* ssb, int status, void* user_data)
{
resolve_index_t* request = user_data;
request->callback(request->path, request->user_data);
tf_free((void*)request->host);
tf_free((void*)request->path);
tf_free(request);
}
void tf_ssb_db_resolve_index_async(tf_ssb_t* ssb, const char* host, void (*callback)(const char* path, void* user_data), void* user_data)
{
resolve_index_t* request = tf_malloc(sizeof(resolve_index_t));
*request = (resolve_index_t) {
.host = tf_strdup(host),
.callback = callback,
.user_data = user_data,
};
tf_ssb_run_work(ssb, _tf_ssb_db_resolve_index_work, _tf_ssb_db_resolve_index_after_work, request);
}
bool tf_ssb_db_verify(tf_ssb_t* ssb, const char* id)
{
JSContext* context = tf_ssb_get_context(ssb);
bool verified = true;
int64_t sequence = -1;
if (tf_ssb_db_get_latest_message_by_author(ssb, id, &sequence, NULL, 0))
{
for (int64_t i = 1; i <= sequence; i++)
{
char message_id[k_id_base64_len];
char previous[256];
double timestamp;
char* content = NULL;
char hash[32];
char signature[256];
int flags = 0;
if (tf_ssb_db_get_message_by_author_and_sequence(
ssb, id, i, message_id, sizeof(message_id), previous, sizeof(previous), ×tamp, &content, hash, sizeof(hash), signature, sizeof(signature), &flags))
{
JSValue message = tf_ssb_format_message(context, previous, id, i, timestamp, hash, content, signature, flags);
char calculated_id[k_id_base64_len];
char extracted_signature[256];
int calculated_flags = 0;
if (!tf_ssb_verify_and_strip_signature(context, message, calculated_id, sizeof(calculated_id), extracted_signature, sizeof(extracted_signature), &calculated_flags))
{
tf_printf("author=%s sequence=%" PRId64 " verify failed.\n", id, i);
verified = false;
}
if (calculated_flags != flags)
{
tf_printf("author=%s sequence=%" PRId64 " flag mismatch %d => %d.\n", id, i, flags, calculated_flags);
verified = false;
}
if (strcmp(message_id, calculated_id))
{
tf_printf("author=%s sequence=%" PRId64 " id mismatch %s => %s.\n", id, i, message_id, calculated_id);
verified = false;
}
JS_FreeValue(context, message);
tf_free(content);
if (!verified)
{
break;
}
}
else
{
tf_printf("Unable to find message with sequence=%" PRId64 " for author=%s.", i, id);
verified = false;
break;
}
}
}
else
{
tf_printf("Unable to get latest message for author '%s'.\n", id);
verified = false;
}
return verified;
}
bool tf_ssb_db_user_has_permission(tf_ssb_t* ssb, sqlite3* db, const char* id, const char* permission)
{
bool has_permission = false;
sqlite3* reader = db ? db : tf_ssb_acquire_db_reader(ssb);
sqlite3_stmt* statement = NULL;
if (sqlite3_prepare(reader,
"SELECT COUNT(*) FROM properties, json_each(properties.value -> 'permissions' -> ?) AS permission WHERE properties.id = 'core' AND properties.key = 'settings' AND "
"permission.value = ?",
-1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, id, -1, NULL) == SQLITE_OK && sqlite3_bind_text(statement, 2, permission, -1, NULL) == SQLITE_OK &&
sqlite3_step(statement) == SQLITE_ROW)
{
has_permission = sqlite3_column_int64(statement, 0) > 0;
}
sqlite3_finalize(statement);
}
if (reader != db)
{
tf_ssb_release_db_reader(ssb, reader);
}
return has_permission;
}
bool tf_ssb_db_get_global_setting_bool(sqlite3* db, const char* name, bool* out_value)
{
bool result = false;
sqlite3_stmt* statement;
if (sqlite3_prepare(db, "SELECT json_extract(value, '$.' || ?) FROM properties WHERE id = 'core' AND key = 'settings'", -1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, name, -1, NULL) == SQLITE_OK)
{
if (sqlite3_step(statement) == SQLITE_ROW && sqlite3_column_type(statement, 0) != SQLITE_NULL)
{
*out_value = sqlite3_column_int(statement, 0) != 0;
result = true;
}
}
sqlite3_finalize(statement);
}
else
{
tf_printf("prepare failed: %s\n", sqlite3_errmsg(db));
}
if (!result)
{
*out_value = tf_util_get_default_global_setting_bool(name);
}
return result;
}
bool tf_ssb_db_get_global_setting_int64(sqlite3* db, const char* name, int64_t* out_value)
{
bool result = false;
sqlite3_stmt* statement;
if (sqlite3_prepare(db, "SELECT json_extract(value, '$.' || ?) FROM properties WHERE id = 'core' AND key = 'settings'", -1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, name, -1, NULL) == SQLITE_OK)
{
if (sqlite3_step(statement) == SQLITE_ROW && sqlite3_column_type(statement, 0) != SQLITE_NULL)
{
*out_value = sqlite3_column_int64(statement, 0);
result = true;
}
}
sqlite3_finalize(statement);
}
else
{
tf_printf("prepare failed: %s\n", sqlite3_errmsg(db));
}
if (!result)
{
*out_value = tf_util_get_default_global_setting_int(name);
}
return result;
}
bool tf_ssb_db_get_global_setting_string(sqlite3* db, const char* name, char* out_value, size_t size)
{
bool result = false;
sqlite3_stmt* statement;
if (sqlite3_prepare(db, "SELECT json_extract(value, '$.' || ?) FROM properties WHERE id = 'core' AND key = 'settings'", -1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, name, -1, NULL) == SQLITE_OK)
{
if (sqlite3_step(statement) == SQLITE_ROW && sqlite3_column_type(statement, 0) != SQLITE_NULL)
{
snprintf(out_value, size, "%s", sqlite3_column_text(statement, 0));
result = true;
}
}
sqlite3_finalize(statement);
}
else
{
tf_printf("prepare failed: %s\n", sqlite3_errmsg(db));
}
if (!result)
{
snprintf(out_value, size, "%s", tf_util_get_default_global_setting_string(name));
}
return result;
}
bool tf_ssb_db_set_global_setting_from_string(sqlite3* db, const char* name, char* value)
{
tf_setting_kind_t kind = tf_util_get_global_setting_kind(name);
if (kind == k_kind_unknown)
{
return false;
}
bool result = false;
sqlite3_stmt* statement;
if (sqlite3_prepare(db,
"INSERT INTO properties (id, key, value) VALUES ('core', 'settings', json_object(?1, ?2)) ON CONFLICT DO UPDATE SET value = json_set(value, '$.' || ?1, ?2)", -1,
&statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, name, -1, NULL) == SQLITE_OK)
{
bool bound = false;
switch (kind)
{
case k_kind_bool:
bound = sqlite3_bind_int(statement, 2, value && (strcmp(value, "true") == 0 || atoi(value))) == SQLITE_OK;
break;
case k_kind_int:
bound = sqlite3_bind_int(statement, 2, atoi(value)) == SQLITE_OK;
break;
case k_kind_string:
bound = sqlite3_bind_text(statement, 2, value, -1, NULL) == SQLITE_OK;
break;
case k_kind_unknown:
break;
}
if (bound && sqlite3_step(statement) == SQLITE_DONE)
{
result = sqlite3_changes(db) != 0;
}
}
sqlite3_finalize(statement);
}
else
{
tf_printf("prepare failed: %s\n", sqlite3_errmsg(db));
}
return result;
}
const char* tf_ssb_db_get_profile(sqlite3* db, const char* id)
{
const char* result = NULL;
sqlite3_stmt* statement;
if (sqlite3_prepare(db,
"SELECT json(json_group_object(key, value)) FROM (SELECT fields.key, RANK() OVER (PARTITION BY fields.key ORDER BY messages.sequence DESC) AS rank, fields.value FROM "
"messages, json_each(messages.content) AS fields WHERE messages.author = ? AND messages.content ->> '$.type' = 'about' AND messages.content ->> '$.about' = "
"messages.author AND NOT fields.key IN ('about', 'type')) WHERE rank = 1",
-1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, id, -1, NULL) == SQLITE_OK)
{
if (sqlite3_step(statement) == SQLITE_ROW)
{
result = tf_strdup((const char*)sqlite3_column_text(statement, 0));
}
}
sqlite3_finalize(statement);
}
else
{
tf_printf("prepare failed: %s\n", sqlite3_errmsg(db));
}
return result;
}
const char* tf_ssb_db_get_profile_name(sqlite3* db, const char* id)
{
const char* result = NULL;
sqlite3_stmt* statement;
if (sqlite3_prepare(db,
"SELECT name FROM (SELECT messages.author, RANK() OVER (PARTITION BY messages.author ORDER BY messages.sequence DESC) AS author_rank, "
"messages.content ->> 'name' AS name FROM messages WHERE messages.author = ? "
"AND messages.content ->> '$.type' = 'about' AND content ->> 'about' = messages.author AND name IS NOT NULL) "
"WHERE author_rank = 1",
-1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, id, -1, NULL) == SQLITE_OK)
{
if (sqlite3_step(statement) == SQLITE_ROW)
{
result = tf_strdup((const char*)sqlite3_column_text(statement, 0));
}
}
sqlite3_finalize(statement);
}
else
{
tf_printf("prepare failed: %s\n", sqlite3_errmsg(db));
}
return result;
}
static void _tf_ssb_db_invite_cleanup(sqlite3* db)
{
sqlite3_stmt* statement;
if (sqlite3_prepare(db, "DELETE FROM invites WHERE use_count = 0 OR (expires > 0 AND expires < ?)", -1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_int64(statement, 1, (int64_t)time(NULL)) == SQLITE_OK)
{
if (sqlite3_step(statement) == SQLITE_DONE)
{
if (sqlite3_changes(db))
{
char buffer[2] = { 0 };
size_t buffer_size = sizeof(buffer);
bool verbose = uv_os_getenv("TF_SSB_VERBOSE", buffer, &buffer_size) == 0 && strcmp(buffer, "1") == 0;
if (verbose)
{
tf_printf("Cleaned up %d used/expired invites.\n", sqlite3_changes(db));
}
}
}
else
{
tf_printf("Invite cleanup failed: %s\n", sqlite3_errmsg(db));
}
}
sqlite3_finalize(statement);
}
else
{
tf_printf("prepare failed: %s\n", sqlite3_errmsg(db));
}
}
bool tf_ssb_db_generate_invite(sqlite3* db, const char* id, const char* host, int port, int use_count, int expires_seconds, char* out_invite, size_t size)
{
if (use_count < -1 || use_count == 0)
{
return false;
}
uint8_t public_key[crypto_sign_ed25519_PUBLICKEYBYTES] = { 0 };
uint8_t secret_key[crypto_sign_ed25519_SECRETKEYBYTES] = { 0 };
uint8_t seed[crypto_sign_ed25519_SEEDBYTES] = { 0 };
randombytes_buf(seed, sizeof(seed));
crypto_sign_ed25519_seed_keypair(public_key, secret_key, seed);
char public[k_id_base64_len];
tf_ssb_id_bin_to_str(public, sizeof(public), public_key);
char seed_b64[64];
tf_base64_encode(seed, sizeof(seed), seed_b64, sizeof(seed_b64));
bool inserted = false;
sqlite3_stmt* statement;
if (sqlite3_prepare(db, "INSERT INTO invites (invite_public_key, account, use_count, expires) VALUES (?, ?, ?, ?)", -1, &statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, public, -1, NULL) == SQLITE_OK && sqlite3_bind_text(statement, 2, id, -1, NULL) == SQLITE_OK &&
sqlite3_bind_int(statement, 3, use_count) == SQLITE_OK &&
sqlite3_bind_int64(statement, 4, (expires_seconds > 0 ? (int64_t)time(NULL) : 0) + expires_seconds) == SQLITE_OK)
{
inserted = sqlite3_step(statement) == SQLITE_DONE;
}
sqlite3_finalize(statement);
}
_tf_ssb_db_invite_cleanup(db);
snprintf(out_invite, size, "%s:%d:%s~%s", host, port, id, seed_b64);
return inserted;
}
bool tf_ssb_db_use_invite(sqlite3* db, const char* id)
{
bool used = false;
sqlite3_stmt* statement;
if (sqlite3_prepare(db, "UPDATE invites SET use_count = use_count - 1 WHERE invite_public_key = ? AND (expires < 0 OR expires >= ?) AND (use_count > 0 OR use_count = -1)", -1,
&statement, NULL) == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, id, -1, NULL) == SQLITE_OK && sqlite3_bind_int64(statement, 2, (int64_t)time(NULL)) == SQLITE_OK)
{
used = sqlite3_step(statement) == SQLITE_DONE && sqlite3_changes(db) > 0;
}
sqlite3_finalize(statement);
}
_tf_ssb_db_invite_cleanup(db);
return used;
}
bool tf_ssb_db_has_invite(sqlite3* db, const char* id)
{
bool has = false;
sqlite3_stmt* statement;
if (sqlite3_prepare(db, "SELECT COUNT(*) FROM invites WHERE invite_public_key = ? AND (expires < 0 OR expires >= ?) AND (use_count > 0 OR use_count = -1)", -1, &statement,
NULL) == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, id, -1, NULL) == SQLITE_OK && sqlite3_bind_int64(statement, 2, (int64_t)time(NULL)) == SQLITE_OK)
{
has = sqlite3_step(statement) == SQLITE_ROW && sqlite3_column_int(statement, 0) > 0;
}
sqlite3_finalize(statement);
}
return has;
}
static void _tf_ssb_db_get_identity_info_visit(const char* identity, void* user_data)
{
tf_ssb_identity_info_t* info = user_data;
info->identity = tf_resize_vec(info->identity, (info->count + 1) * sizeof(char*));
info->name = tf_resize_vec(info->name, (info->count + 1) * sizeof(char*));
char buffer[k_id_base64_len];
snprintf(buffer, sizeof(buffer), "@%s", identity);
info->identity[info->count] = tf_strdup(buffer);
info->name[info->count] = NULL;
info->count++;
}
tf_ssb_identity_info_t* tf_ssb_db_get_identity_info(tf_ssb_t* ssb, const char* user, const char* package_owner, const char* package_name)
{
tf_ssb_identity_info_t* info = tf_malloc(sizeof(tf_ssb_identity_info_t));
*info = (tf_ssb_identity_info_t) { 0 };
char id[k_id_base64_len] = "";
if (tf_ssb_db_user_has_permission(ssb, NULL, user, "administration"))
{
if (tf_ssb_whoami(ssb, id, sizeof(id)))
{
_tf_ssb_db_get_identity_info_visit(*id == '@' ? id + 1 : id, info);
}
}
tf_ssb_db_identity_visit(ssb, user, _tf_ssb_db_get_identity_info_visit, info);
sqlite3* db = tf_ssb_acquire_db_reader(ssb);
sqlite3_stmt* statement = NULL;
int result = sqlite3_prepare(db,
"SELECT author, name FROM ( "
" SELECT "
" messages.author, "
" RANK() OVER (PARTITION BY messages.author ORDER BY messages.sequence DESC) AS author_rank, "
" messages.content ->> 'name' AS name "
" FROM messages "
" JOIN identities ON messages.author = ('@' || identities.public_key) "
" WHERE "
" (identities.user = ? OR identities.public_key = ?) AND "
" messages.content ->> '$.type' = 'about' AND "
" content ->> 'about' = messages.author AND name IS NOT NULL) "
"WHERE author_rank = 1 ",
-1, &statement, NULL);
if (result == SQLITE_OK)
{
if (sqlite3_bind_text(statement, 1, user, -1, NULL) == SQLITE_OK && sqlite3_bind_text(statement, 2, *id == '@' ? id + 1 : id, -1, NULL) == SQLITE_OK)
{
int r = SQLITE_OK;
while ((r = sqlite3_step(statement)) == SQLITE_ROW)
{
const char* identity = (const char*)sqlite3_column_text(statement, 0);
const char* name = (const char*)sqlite3_column_text(statement, 1);
for (int i = 0; i < info->count; i++)
{
if (!info->name[i] && strcmp(info->identity[i], identity) == 0)
{
info->name[i] = tf_strdup(name);
break;
}
}
}
}
sqlite3_finalize(statement);
}
else
{
tf_printf("prepare failed: %s.\n", sqlite3_errmsg(db));
}
tf_ssb_db_identity_get_active(db, user, package_owner, package_name, info->active_identity, sizeof(info->active_identity));
if (!*info->active_identity && info->count)
{
snprintf(info->active_identity, sizeof(info->active_identity), "%s", info->identity[0]);
}
tf_ssb_release_db_reader(ssb, db);
size_t size = sizeof(tf_ssb_identity_info_t) + sizeof(char*) * info->count * 2;
for (int i = 0; i < info->count; i++)
{
size += strlen(info->identity[i]) + 1;
size += info->name[i] ? strlen(info->name[i]) + 1 : 0;
}
tf_ssb_identity_info_t* copy = tf_malloc(size);
*copy = *info;
copy->identity = (const char**)(copy + 1);
copy->name = (const char**)(copy + 1) + copy->count;
char* p = (char*)((const char**)(copy + 1) + copy->count * 2);
for (int i = 0; i < info->count; i++)
{
size_t length = strlen(info->identity[i]);
memcpy(p, info->identity[i], length + 1);
copy->identity[i] = p;
p += length + 1;
tf_free((void*)info->identity[i]);
if (info->name[i])
{
length = strlen(info->name[i]);
memcpy(p, info->name[i], length + 1);
copy->name[i] = p;
p += length + 1;
tf_free((void*)info->name[i]);
}
else
{
copy->name[i] = NULL;
}
}
tf_free(info->name);
tf_free(info->identity);
tf_free(info);
return copy;
}