// Copyright (c) 2014-2019, The Monero Project
//
// All rights reserved.
//
// Redistribution and use in source and binary forms, with or without modification, are
// permitted provided that the following conditions are met:
//
// 1. Redistributions of source code must retain the above copyright notice, this list of
// conditions and the following disclaimer.
//
// 2. Redistributions in binary form must reproduce the above copyright notice, this list
// of conditions and the following disclaimer in the documentation and/or other
// materials provided with the distribution.
//
// 3. Neither the name of the copyright holder nor the names of its contributors may be
// used to endorse or promote products derived from this software without specific
// prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY
// EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
// MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL
// THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
// PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
// INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT,
// STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF
// THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
//
// Parts of this file are originally copyright (c) 2012-2013 The Cryptonote developers
# include "string_tools.h"
# include "common/password.h"
# include "common/scoped_message_writer.h"
Pruning
The blockchain prunes seven eighths of prunable tx data.
This saves about two thirds of the blockchain size, while
keeping the node useful as a sync source for an eighth
of the blockchain.
No other data is currently pruned.
There are three ways to prune a blockchain:
- run monerod with --prune-blockchain
- run "prune_blockchain" in the monerod console
- run the monero-blockchain-prune utility
The first two will prune in place. Due to how LMDB works, this
will not reduce the blockchain size on disk. Instead, it will
mark parts of the file as free, so that future data will use
that free space, causing the file to not grow until free space
grows scarce.
The third way will create a second database, a pruned copy of
the original one. Since this is a new file, this one will be
smaller than the original one.
Once the database is pruned, it will stay pruned as it syncs.
That is, there is no need to use --prune-blockchain again, etc.
6 years ago
# include "common/pruning.h"
# include "daemon/rpc_command_executor.h"
# include "rpc/core_rpc_server_commands_defs.h"
# include "cryptonote_core/cryptonote_core.h"
# include "cryptonote_basic/hardfork.h"
# include <boost/format.hpp>
# include <ctime>
# include <string>
Change logging to easylogging++
This replaces the epee and data_loggers logging systems with
a single one, and also adds filename:line and explicit severity
levels. Categories may be defined, and logging severity set
by category (or set of categories). epee style 0-4 log level
maps to a sensible severity configuration. Log files now also
rotate when reaching 100 MB.
To select which logs to output, use the MONERO_LOGS environment
variable, with a comma separated list of categories (globs are
supported), with their requested severity level after a colon.
If a log matches more than one such setting, the last one in
the configuration string applies. A few examples:
This one is (mostly) silent, only outputting fatal errors:
MONERO_LOGS=*:FATAL
This one is very verbose:
MONERO_LOGS=*:TRACE
This one is totally silent (logwise):
MONERO_LOGS=""
This one outputs all errors and warnings, except for the
"verify" category, which prints just fatal errors (the verify
category is used for logs about incoming transactions and
blocks, and it is expected that some/many will fail to verify,
hence we don't want the spam):
MONERO_LOGS=*:WARNING,verify:FATAL
Log levels are, in decreasing order of priority:
FATAL, ERROR, WARNING, INFO, DEBUG, TRACE
Subcategories may be added using prefixes and globs. This
example will output net.p2p logs at the TRACE level, but all
other net* logs only at INFO:
MONERO_LOGS=*:ERROR,net*:INFO,net.p2p:TRACE
Logs which are intended for the user (which Monero was using
a lot through epee, but really isn't a nice way to go things)
should use the "global" category. There are a few helper macros
for using this category, eg: MGINFO("this shows up by default")
or MGINFO_RED("this is red"), to try to keep a similar look
and feel for now.
Existing epee log macros still exist, and map to the new log
levels, but since they're used as a "user facing" UI element
as much as a logging system, they often don't map well to log
severities (ie, a log level 0 log may be an error, or may be
something we want the user to see, such as an important info).
In those cases, I tried to use the new macros. In other cases,
I left the existing macros in. When modifying logs, it is
probably best to switch to the new macros with explicit levels.
The --log-level options and set_log commands now also accept
category settings, in addition to the epee style log levels.
7 years ago
# undef MONERO_DEFAULT_LOG_CATEGORY
# define MONERO_DEFAULT_LOG_CATEGORY "daemon"
namespace daemonize {
namespace {
const char * get_address_type_name ( epee : : net_utils : : address_type address_type )
{
switch ( address_type )
{
default :
case epee : : net_utils : : address_type : : invalid : return " invalid " ;
case epee : : net_utils : : address_type : : ipv4 : return " IPv4 " ;
case epee : : net_utils : : address_type : : ipv6 : return " IPv6 " ;
case epee : : net_utils : : address_type : : i2p : return " I2P " ;
case epee : : net_utils : : address_type : : tor : return " Tor " ;
}
}
void print_peer ( std : : string const & prefix , cryptonote : : peer const & peer )
{
time_t now ;
time ( & now ) ;
time_t last_seen = static_cast < time_t > ( peer . last_seen ) ;
std : : string id_str ;
std : : string port_str ;
std : : string elapsed = epee : : misc_utils : : get_time_interval_string ( now - last_seen ) ;
std : : string ip_str = epee : : string_tools : : get_ip_string_from_int32 ( peer . ip ) ;
std : : stringstream peer_id_str ;
peer_id_str < < std : : hex < < std : : setw ( 16 ) < < peer . id ;
peer_id_str > > id_str ;
epee : : string_tools : : xtype_to_string ( peer . port , port_str ) ;
std : : string addr_str = ip_str + " : " + port_str ;
std : : string rpc_port = peer . rpc_port ? std : : to_string ( peer . rpc_port ) : " - " ;
Pruning
The blockchain prunes seven eighths of prunable tx data.
This saves about two thirds of the blockchain size, while
keeping the node useful as a sync source for an eighth
of the blockchain.
No other data is currently pruned.
There are three ways to prune a blockchain:
- run monerod with --prune-blockchain
- run "prune_blockchain" in the monerod console
- run the monero-blockchain-prune utility
The first two will prune in place. Due to how LMDB works, this
will not reduce the blockchain size on disk. Instead, it will
mark parts of the file as free, so that future data will use
that free space, causing the file to not grow until free space
grows scarce.
The third way will create a second database, a pruned copy of
the original one. Since this is a new file, this one will be
smaller than the original one.
Once the database is pruned, it will stay pruned as it syncs.
That is, there is no need to use --prune-blockchain again, etc.
6 years ago
std : : string pruning_seed = epee : : string_tools : : to_string_hex ( peer . pruning_seed ) ;
tools : : msg_writer ( ) < < boost : : format ( " %-10s %-25s %-25s %-5s %-4s %s " ) % prefix % id_str % addr_str % rpc_port % pruning_seed % elapsed ;
}
void print_block_header ( cryptonote : : block_header_response const & header )
{
tools : : success_msg_writer ( )
< < " timestamp: " < < boost : : lexical_cast < std : : string > ( header . timestamp ) < < " ( " < < tools : : get_human_readable_timestamp ( header . timestamp ) < < " ) " < < std : : endl
< < " previous hash: " < < header . prev_hash < < std : : endl
< < " nonce: " < < boost : : lexical_cast < std : : string > ( header . nonce ) < < std : : endl
< < " is orphan: " < < header . orphan_status < < std : : endl
< < " height: " < < boost : : lexical_cast < std : : string > ( header . height ) < < std : : endl
< < " depth: " < < boost : : lexical_cast < std : : string > ( header . depth ) < < std : : endl
< < " hash: " < < header . hash < < std : : endl
< < " difficulty: " < < boost : : lexical_cast < std : : string > ( header . difficulty ) < < std : : endl
< < " POW hash: " < < header . pow_hash < < std : : endl
< < " block size: " < < header . block_size < < std : : endl
< < " block weight: " < < header . block_weight < < std : : endl
ArticMine's new block weight algorithm
This curbs runaway growth while still allowing substantial
spikes in block weight
Original specification from ArticMine:
here is the scaling proposal
Define: LongTermBlockWeight
Before fork:
LongTermBlockWeight = BlockWeight
At or after fork:
LongTermBlockWeight = min(BlockWeight, 1.4*LongTermEffectiveMedianBlockWeight)
Note: To avoid possible consensus issues over rounding the LongTermBlockWeight for a given block should be calculated to the nearest byte, and stored as a integer in the block itself. The stored LongTermBlockWeight is then used for future calculations of the LongTermEffectiveMedianBlockWeight and not recalculated each time.
Define: LongTermEffectiveMedianBlockWeight
LongTermEffectiveMedianBlockWeight = max(300000, MedianOverPrevious100000Blocks(LongTermBlockWeight))
Change Definition of EffectiveMedianBlockWeight
From (current definition)
EffectiveMedianBlockWeight = max(300000, MedianOverPrevious100Blocks(BlockWeight))
To (proposed definition)
EffectiveMedianBlockWeight = min(max(300000, MedianOverPrevious100Blocks(BlockWeight)), 50*LongTermEffectiveMedianBlockWeight)
Notes:
1) There are no other changes to the existing penalty formula, median calculation, fees etc.
2) There is the requirement to store the LongTermBlockWeight of a block unencrypted in the block itself. This is to avoid possible consensus issues over rounding and also to prevent the calculations from becoming unwieldy as we move away from the fork.
3) When the EffectiveMedianBlockWeight cap is reached it is still possible to mine blocks up to 2x the EffectiveMedianBlockWeight by paying the corresponding penalty.
Note: the long term block weight is stored in the database, but not in the actual block itself,
since it requires recalculating anyway for verification.
5 years ago
< < " long term weight: " < < header . long_term_weight < < std : : endl
< < " num txes: " < < header . num_txes < < std : : endl
< < " reward: " < < cryptonote : : print_money ( header . reward ) ;
}
std : : string get_human_time_ago ( time_t t , time_t now )
{
if ( t = = now )
return " now " ;
time_t dt = t > now ? t - now : now - t ;
std : : string s ;
if ( dt < 90 )
s = boost : : lexical_cast < std : : string > ( dt ) + " seconds " ;
else if ( dt < 90 * 60 )
s = boost : : lexical_cast < std : : string > ( dt / 60 ) + " minutes " ;
else if ( dt < 36 * 3600 )
s = boost : : lexical_cast < std : : string > ( dt / 3600 ) + " hours " ;
else
s = boost : : lexical_cast < std : : string > ( dt / ( 3600 * 24 ) ) + " days " ;
return s + " " + ( t > now ? " in the future " : " ago " ) ;
}
std : : string get_time_hms ( time_t t )
{
unsigned int hours , minutes , seconds ;
char buffer [ 24 ] ;
hours = t / 3600 ;
t % = 3600 ;
minutes = t / 60 ;
t % = 60 ;
seconds = t ;
snprintf ( buffer , sizeof ( buffer ) , " %02u:%02u:%02u " , hours , minutes , seconds ) ;
return std : : string ( buffer ) ;
}
std : : string make_error ( const std : : string & base , const std : : string & status )
{
if ( status = = CORE_RPC_STATUS_OK )
return base ;
return base + " -- " + status ;
}
}
t_rpc_command_executor : : t_rpc_command_executor (
uint32_t ip
, uint16_t port
, const boost : : optional < tools : : login > & login
, const epee : : net_utils : : ssl_options_t & ssl_options
, bool is_rpc
, cryptonote : : core_rpc_server * rpc_server
)
: m_rpc_client ( NULL ) , m_rpc_server ( rpc_server )
{
if ( is_rpc )
{
boost : : optional < epee : : net_utils : : http : : login > http_login { } ;
if ( login )
http_login . emplace ( login - > username , login - > password . password ( ) ) ;
m_rpc_client = new tools : : t_rpc_client ( ip , port , std : : move ( http_login ) , ssl_options ) ;
}
else
{
if ( rpc_server = = NULL )
{
throw std : : runtime_error ( " If not calling commands via RPC, rpc_server pointer must be non-null " ) ;
}
}
m_is_rpc = is_rpc ;
}
t_rpc_command_executor : : ~ t_rpc_command_executor ( )
{
if ( m_rpc_client ! = NULL )
{
delete m_rpc_client ;
}
}
bool t_rpc_command_executor : : print_peer_list ( bool white , bool gray , size_t limit ) {
cryptonote : : COMMAND_RPC_GET_PEER_LIST : : request req ;
cryptonote : : COMMAND_RPC_GET_PEER_LIST : : response res ;
std : : string failure_message = " Couldn't retrieve peer list " ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > rpc_request ( req , res , " /get_peer_list " , failure_message . c_str ( ) ) )
{
return false ;
}
}
else
{
if ( ! m_rpc_server - > on_get_peer_list ( req , res ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < failure_message ;
return false ;
}
}
if ( white )
{
auto peer = res . white_list . cbegin ( ) ;
const auto end = limit ? peer + std : : min ( limit , res . white_list . size ( ) ) : res . white_list . cend ( ) ;
for ( ; peer ! = end ; + + peer )
{
print_peer ( " white " , * peer ) ;
}
}
if ( gray )
{
auto peer = res . gray_list . cbegin ( ) ;
const auto end = limit ? peer + std : : min ( limit , res . gray_list . size ( ) ) : res . gray_list . cend ( ) ;
for ( ; peer ! = end ; + + peer )
{
print_peer ( " gray " , * peer ) ;
}
}
return true ;
}
bool t_rpc_command_executor : : print_peer_list_stats ( ) {
cryptonote : : COMMAND_RPC_GET_PEER_LIST : : request req ;
cryptonote : : COMMAND_RPC_GET_PEER_LIST : : response res ;
std : : string failure_message = " Couldn't retrieve peer list " ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > rpc_request ( req , res , " /get_peer_list " , failure_message . c_str ( ) ) )
{
return false ;
}
}
else
{
if ( ! m_rpc_server - > on_get_peer_list ( req , res ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < failure_message ;
return false ;
}
}
tools : : msg_writer ( )
< < " White list size: " < < res . white_list . size ( ) < < " / " < < P2P_LOCAL_WHITE_PEERLIST_LIMIT < < " ( " < < res . white_list . size ( ) * 100.0 / P2P_LOCAL_WHITE_PEERLIST_LIMIT < < " %) " < < std : : endl
< < " Gray list size: " < < res . gray_list . size ( ) < < " / " < < P2P_LOCAL_GRAY_PEERLIST_LIMIT < < " ( " < < res . gray_list . size ( ) * 100.0 / P2P_LOCAL_GRAY_PEERLIST_LIMIT < < " %) " ;
return true ;
}
bool t_rpc_command_executor : : save_blockchain ( ) {
cryptonote : : COMMAND_RPC_SAVE_BC : : request req ;
cryptonote : : COMMAND_RPC_SAVE_BC : : response res ;
std : : string fail_message = " Couldn't save blockchain " ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > rpc_request ( req , res , " /save_bc " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_save_bc ( req , res ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
return true ;
}
}
tools : : success_msg_writer ( ) < < " Blockchain saved " ;
return true ;
}
bool t_rpc_command_executor : : show_hash_rate ( ) {
cryptonote : : COMMAND_RPC_SET_LOG_HASH_RATE : : request req ;
cryptonote : : COMMAND_RPC_SET_LOG_HASH_RATE : : response res ;
req . visible = true ;
std : : string fail_message = " Unsuccessful " ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > rpc_request ( req , res , " /set_log_hash_rate " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_set_log_hash_rate ( req , res ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
}
}
tools : : success_msg_writer ( ) < < " Hash rate logging is on " ;
return true ;
}
bool t_rpc_command_executor : : hide_hash_rate ( ) {
cryptonote : : COMMAND_RPC_SET_LOG_HASH_RATE : : request req ;
cryptonote : : COMMAND_RPC_SET_LOG_HASH_RATE : : response res ;
req . visible = false ;
std : : string fail_message = " Unsuccessful " ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > rpc_request ( req , res , " /set_log_hash_rate " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_set_log_hash_rate ( req , res ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
return true ;
}
}
tools : : success_msg_writer ( ) < < " Hash rate logging is off " ;
return true ;
}
bool t_rpc_command_executor : : show_difficulty ( ) {
cryptonote : : COMMAND_RPC_GET_INFO : : request req ;
cryptonote : : COMMAND_RPC_GET_INFO : : response res ;
std : : string fail_message = " Problem fetching info " ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > rpc_request ( req , res , " /getinfo " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_get_info ( req , res ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message . c_str ( ) , res . status ) ;
return true ;
}
}
tools : : success_msg_writer ( ) < < " BH: " < < res . height
< < " , TH: " < < res . top_block_hash
< < " , DIFF: " < < res . difficulty
< < " , CUM_DIFF: " < < res . cumulative_difficulty
< < " , HR: " < < res . difficulty / res . target < < " H/s " ;
return true ;
}
static std : : string get_mining_speed ( uint64_t hr )
{
if ( hr > 1e9 ) return ( boost : : format ( " %.2f GH/s " ) % ( hr / 1e9 ) ) . str ( ) ;
if ( hr > 1e6 ) return ( boost : : format ( " %.2f MH/s " ) % ( hr / 1e6 ) ) . str ( ) ;
if ( hr > 1e3 ) return ( boost : : format ( " %.2f kH/s " ) % ( hr / 1e3 ) ) . str ( ) ;
return ( boost : : format ( " %.0f H/s " ) % hr ) . str ( ) ;
}
static std : : string get_fork_extra_info ( uint64_t t , uint64_t now , uint64_t block_time )
{
uint64_t blocks_per_day = 86400 / block_time ;
if ( t = = now )
return " (forking now) " ;
if ( t > now )
{
uint64_t dblocks = t - now ;
if ( dblocks < = 30 )
return ( boost : : format ( " (next fork in %u blocks) " ) % ( unsigned ) dblocks ) . str ( ) ;
if ( dblocks < = blocks_per_day / 2 )
return ( boost : : format ( " (next fork in %.1f hours) " ) % ( dblocks / ( float ) ( blocks_per_day / 24 ) ) ) . str ( ) ;
if ( dblocks < = blocks_per_day * 30 )
return ( boost : : format ( " (next fork in %.1f days) " ) % ( dblocks / ( float ) blocks_per_day ) ) . str ( ) ;
return " " ;
}
return " " ;
}
static float get_sync_percentage ( uint64_t height , uint64_t target_height )
{
target_height = target_height ? target_height < height ? height : target_height : height ;
float pc = 100.0f * height / target_height ;
if ( height < target_height & & pc > 99.9f )
return 99.9f ; // to avoid 100% when not fully synced
return pc ;
}
static float get_sync_percentage ( const cryptonote : : COMMAND_RPC_GET_INFO : : response & ires )
{
return get_sync_percentage ( ires . height , ires . target_height ) ;
}
bool t_rpc_command_executor : : show_status ( ) {
cryptonote : : COMMAND_RPC_GET_INFO : : request ireq ;
cryptonote : : COMMAND_RPC_GET_INFO : : response ires ;
cryptonote : : COMMAND_RPC_HARD_FORK_INFO : : request hfreq ;
cryptonote : : COMMAND_RPC_HARD_FORK_INFO : : response hfres ;
cryptonote : : COMMAND_RPC_MINING_STATUS : : request mreq ;
cryptonote : : COMMAND_RPC_MINING_STATUS : : response mres ;
epee : : json_rpc : : error error_resp ;
bool has_mining_info = true ;
std : : string fail_message = " Problem fetching info " ;
hfreq . version = 0 ;
bool mining_busy = false ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > rpc_request ( ireq , ires , " /getinfo " , fail_message . c_str ( ) ) )
{
return true ;
}
if ( ! m_rpc_client - > json_rpc_request ( hfreq , hfres , " hard_fork_info " , fail_message . c_str ( ) ) )
{
return true ;
}
// mining info is only available non unrestricted RPC mode
has_mining_info = m_rpc_client - > rpc_request ( mreq , mres , " /mining_status " , fail_message . c_str ( ) ) ;
}
else
{
if ( ! m_rpc_server - > on_get_info ( ireq , ires ) | | ires . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , ires . status ) ;
return true ;
}
if ( ! m_rpc_server - > on_hard_fork_info ( hfreq , hfres , error_resp ) | | hfres . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , hfres . status ) ;
return true ;
}
if ( ! m_rpc_server - > on_mining_status ( mreq , mres ) )
{
tools : : fail_msg_writer ( ) < < fail_message . c_str ( ) ;
return true ;
}
if ( mres . status = = CORE_RPC_STATUS_BUSY )
{
mining_busy = true ;
}
else if ( mres . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , mres . status ) ;
return true ;
}
}
std : : time_t uptime = std : : time ( nullptr ) - ires . start_time ;
uint64_t net_height = ires . target_height > ires . height ? ires . target_height : ires . height ;
std : : string bootstrap_msg ;
if ( ires . was_bootstrap_ever_used )
{
bootstrap_msg = " , bootstrapping from " + ires . bootstrap_daemon_address ;
if ( ires . untrusted )
{
bootstrap_msg + = ( boost : : format ( " , local height: %llu (%.1f%%) " ) % ires . height_without_bootstrap % get_sync_percentage ( ires . height_without_bootstrap , net_height ) ) . str ( ) ;
}
else
{
bootstrap_msg + = " was used before " ;
}
}
std : : stringstream str ;
str < < boost : : format ( " Height: %llu/%llu (%.1f%%) on %s%s, %s, net hash %s, v%u%s, %s, %u(out)+%u(in) connections " )
% ( unsigned long long ) ires . height
% ( unsigned long long ) net_height
% get_sync_percentage ( ires )
% ( ires . testnet ? " testnet " : ires . stagenet ? " stagenet " : " mainnet " )
% bootstrap_msg
% ( ! has_mining_info ? " mining info unavailable " : mining_busy ? " syncing " : mres . active ? ( ( mres . is_background_mining_enabled ? " smart " : " " ) + std : : string ( " mining at " ) + get_mining_speed ( mres . speed ) ) : " not mining " )
% get_mining_speed ( ires . difficulty / ires . target )
% ( unsigned ) hfres . version
% get_fork_extra_info ( hfres . earliest_height , net_height , ires . target )
% ( hfres . state = = cryptonote : : HardFork : : Ready ? " up to date " : hfres . state = = cryptonote : : HardFork : : UpdateNeeded ? " update needed " : " out of date, likely forked " )
% ( unsigned ) ires . outgoing_connections_count
% ( unsigned ) ires . incoming_connections_count
;
// restricted RPC does not disclose start time
if ( ires . start_time )
{
str < < boost : : format ( " , uptime %ud %uh %um %us " )
% ( unsigned int ) floor ( uptime / 60.0 / 60.0 / 24.0 )
% ( unsigned int ) floor ( fmod ( ( uptime / 60.0 / 60.0 ) , 24.0 ) )
% ( unsigned int ) floor ( fmod ( ( uptime / 60.0 ) , 60.0 ) )
% ( unsigned int ) fmod ( uptime , 60.0 )
;
}
tools : : success_msg_writer ( ) < < str . str ( ) ;
return true ;
}
bool t_rpc_command_executor : : mining_status ( ) {
cryptonote : : COMMAND_RPC_MINING_STATUS : : request mreq ;
cryptonote : : COMMAND_RPC_MINING_STATUS : : response mres ;
epee : : json_rpc : : error error_resp ;
bool has_mining_info = true ;
std : : string fail_message = " Problem fetching info " ;
bool mining_busy = false ;
if ( m_is_rpc )
{
// mining info is only available non unrestricted RPC mode
has_mining_info = m_rpc_client - > rpc_request ( mreq , mres , " /mining_status " , fail_message . c_str ( ) ) ;
}
else
{
if ( ! m_rpc_server - > on_mining_status ( mreq , mres ) )
{
tools : : fail_msg_writer ( ) < < fail_message . c_str ( ) ;
return true ;
}
if ( mres . status = = CORE_RPC_STATUS_BUSY )
{
mining_busy = true ;
}
else if ( mres . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , mres . status ) ;
return true ;
}
}
if ( ! has_mining_info )
{
tools : : fail_msg_writer ( ) < < " Mining info unavailable " ;
return true ;
}
if ( mining_busy | | ! mres . active )
{
tools : : msg_writer ( ) < < " Not currently mining " ;
}
else
{
tools : : msg_writer ( ) < < " Mining at " < < get_mining_speed ( mres . speed ) < < " with " < < mres . threads_count < < " threads " ;
}
if ( mres . active | | mres . is_background_mining_enabled )
{
tools : : msg_writer ( ) < < " PoW algorithm: " < < mres . pow_algorithm ;
tools : : msg_writer ( ) < < " Mining address: " < < mres . address ;
}
if ( mres . is_background_mining_enabled )
{
tools : : msg_writer ( ) < < " Smart mining enabled: " ;
tools : : msg_writer ( ) < < " Target: " < < ( unsigned ) mres . bg_target < < " % CPU " ;
tools : : msg_writer ( ) < < " Idle threshold: " < < ( unsigned ) mres . bg_idle_threshold < < " % CPU " ;
tools : : msg_writer ( ) < < " Min idle time: " < < ( unsigned ) mres . bg_min_idle_seconds < < " seconds " ;
tools : : msg_writer ( ) < < " Ignore battery: " < < ( mres . bg_ignore_battery ? " yes " : " no " ) ;
}
if ( ! mining_busy & & mres . active & & mres . speed > 0 & & mres . block_target > 0 & & mres . difficulty > 0 )
{
double ratio = mres . speed * mres . block_target / ( double ) mres . difficulty ;
uint64_t daily = 86400ull / mres . block_target * mres . block_reward * ratio ;
uint64_t monthly = 86400ull / mres . block_target * 30.5 * mres . block_reward * ratio ;
uint64_t yearly = 86400ull / mres . block_target * 356 * mres . block_reward * ratio ;
tools : : msg_writer ( ) < < " Possible reward: " < < cryptonote : : print_money ( monthly ) < < " WOW monthly, " < < cryptonote : : print_money ( yearly ) < < " WOW yearly " ;
}
return true ;
}
bool t_rpc_command_executor : : print_connections ( ) {
cryptonote : : COMMAND_RPC_GET_CONNECTIONS : : request req ;
cryptonote : : COMMAND_RPC_GET_CONNECTIONS : : response res ;
epee : : json_rpc : : error error_resp ;
std : : string fail_message = " Unsuccessful " ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > json_rpc_request ( req , res , " get_connections " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_get_connections ( req , res , error_resp ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
return true ;
}
}
tools : : msg_writer ( ) < < std : : setw ( 30 ) < < std : : left < < " Remote Host "
< < std : : setw ( 8 ) < < " Type "
epee: add SSL support
RPC connections now have optional tranparent SSL.
An optional private key and certificate file can be passed,
using the --{rpc,daemon}-ssl-private-key and
--{rpc,daemon}-ssl-certificate options. Those have as
argument a path to a PEM format private private key and
certificate, respectively.
If not given, a temporary self signed certificate will be used.
SSL can be enabled or disabled using --{rpc}-ssl, which
accepts autodetect (default), disabled or enabled.
Access can be restricted to particular certificates using the
--rpc-ssl-allowed-certificates, which takes a list of
paths to PEM encoded certificates. This can allow a wallet to
connect to only the daemon they think they're connected to,
by forcing SSL and listing the paths to the known good
certificates.
To generate long term certificates:
openssl genrsa -out /tmp/KEY 4096
openssl req -new -key /tmp/KEY -out /tmp/REQ
openssl x509 -req -days 999999 -sha256 -in /tmp/REQ -signkey /tmp/KEY -out /tmp/CERT
/tmp/KEY is the private key, and /tmp/CERT is the certificate,
both in PEM format. /tmp/REQ can be removed. Adjust the last
command to set expiration date, etc, as needed. It doesn't
make a whole lot of sense for monero anyway, since most servers
will run with one time temporary self signed certificates anyway.
SSL support is transparent, so all communication is done on the
existing ports, with SSL autodetection. This means you can start
using an SSL daemon now, but you should not enforce SSL yet or
nothing will talk to you.
6 years ago
< < std : : setw ( 6 ) < < " SSL "
< < std : : setw ( 20 ) < < " Peer id "
< < std : : setw ( 20 ) < < " Support Flags "
< < std : : setw ( 30 ) < < " Recv/Sent (inactive,sec) "
< < std : : setw ( 25 ) < < " State "
< < std : : setw ( 20 ) < < " Livetime(sec) "
< < std : : setw ( 12 ) < < " Down (kB/s) "
< < std : : setw ( 14 ) < < " Down(now) "
< < std : : setw ( 10 ) < < " Up (kB/s) "
< < std : : setw ( 13 ) < < " Up(now) "
< < std : : endl ;
for ( auto & info : res . connections )
{
std : : string address = info . incoming ? " INC " : " OUT " ;
address + = info . ip + " : " + info . port ;
//std::string in_out = info.incoming ? "INC " : "OUT ";
tools : : msg_writer ( )
//<< std::setw(30) << std::left << in_out
< < std : : setw ( 30 ) < < std : : left < < address
< < std : : setw ( 8 ) < < ( get_address_type_name ( ( epee : : net_utils : : address_type ) info . address_type ) )
epee: add SSL support
RPC connections now have optional tranparent SSL.
An optional private key and certificate file can be passed,
using the --{rpc,daemon}-ssl-private-key and
--{rpc,daemon}-ssl-certificate options. Those have as
argument a path to a PEM format private private key and
certificate, respectively.
If not given, a temporary self signed certificate will be used.
SSL can be enabled or disabled using --{rpc}-ssl, which
accepts autodetect (default), disabled or enabled.
Access can be restricted to particular certificates using the
--rpc-ssl-allowed-certificates, which takes a list of
paths to PEM encoded certificates. This can allow a wallet to
connect to only the daemon they think they're connected to,
by forcing SSL and listing the paths to the known good
certificates.
To generate long term certificates:
openssl genrsa -out /tmp/KEY 4096
openssl req -new -key /tmp/KEY -out /tmp/REQ
openssl x509 -req -days 999999 -sha256 -in /tmp/REQ -signkey /tmp/KEY -out /tmp/CERT
/tmp/KEY is the private key, and /tmp/CERT is the certificate,
both in PEM format. /tmp/REQ can be removed. Adjust the last
command to set expiration date, etc, as needed. It doesn't
make a whole lot of sense for monero anyway, since most servers
will run with one time temporary self signed certificates anyway.
SSL support is transparent, so all communication is done on the
existing ports, with SSL autodetection. This means you can start
using an SSL daemon now, but you should not enforce SSL yet or
nothing will talk to you.
6 years ago
< < std : : setw ( 6 ) < < ( info . ssl ? " yes " : " no " )
< < std : : setw ( 20 ) < < epee : : string_tools : : pad_string ( info . peer_id , 16 , ' 0 ' , true )
< < std : : setw ( 20 ) < < info . support_flags
< < std : : setw ( 30 ) < < std : : to_string ( info . recv_count ) + " ( " + std : : to_string ( info . recv_idle_time ) + " )/ " + std : : to_string ( info . send_count ) + " ( " + std : : to_string ( info . send_idle_time ) + " ) "
< < std : : setw ( 25 ) < < info . state
< < std : : setw ( 20 ) < < info . live_time
< < std : : setw ( 12 ) < < info . avg_download
< < std : : setw ( 14 ) < < info . current_download
< < std : : setw ( 10 ) < < info . avg_upload
< < std : : setw ( 13 ) < < info . current_upload
< < std : : left < < ( info . localhost ? " [LOCALHOST] " : " " )
< < std : : left < < ( info . local_ip ? " [LAN] " : " " ) ;
//tools::msg_writer() << boost::format("%-25s peer_id: %-25s %s") % address % info.peer_id % in_out;
}
return true ;
}
bool t_rpc_command_executor : : print_net_stats ( )
{
cryptonote : : COMMAND_RPC_GET_NET_STATS : : request net_stats_req ;
cryptonote : : COMMAND_RPC_GET_NET_STATS : : response net_stats_res ;
cryptonote : : COMMAND_RPC_GET_LIMIT : : request limit_req ;
cryptonote : : COMMAND_RPC_GET_LIMIT : : response limit_res ;
std : : string fail_message = " Unsuccessful " ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > json_rpc_request ( net_stats_req , net_stats_res , " get_net_stats " , fail_message . c_str ( ) ) )
{
return true ;
}
if ( ! m_rpc_client - > json_rpc_request ( limit_req , limit_res , " get_limit " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_get_net_stats ( net_stats_req , net_stats_res ) | | net_stats_res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , net_stats_res . status ) ;
return true ;
}
if ( ! m_rpc_server - > on_get_limit ( limit_req , limit_res ) | | limit_res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , limit_res . status ) ;
return true ;
}
}
uint64_t seconds = ( uint64_t ) time ( NULL ) - net_stats_res . start_time ;
uint64_t average = seconds > 0 ? net_stats_res . total_bytes_in / seconds : 0 ;
uint64_t limit = limit_res . limit_down * 1024 ; // convert to bytes, as limits are always kB/s
double percent = ( double ) average / ( double ) limit * 100.0 ;
tools : : success_msg_writer ( ) < < boost : : format ( " Received %u bytes (%s) in %u packets, average %s/s = %.2f%% of the limit of %s/s " )
% net_stats_res . total_bytes_in
% tools : : get_human_readable_bytes ( net_stats_res . total_bytes_in )
% net_stats_res . total_packets_in
% tools : : get_human_readable_bytes ( average )
% percent
% tools : : get_human_readable_bytes ( limit ) ;
average = seconds > 0 ? net_stats_res . total_bytes_out / seconds : 0 ;
limit = limit_res . limit_up * 1024 ;
percent = ( double ) average / ( double ) limit * 100.0 ;
tools : : success_msg_writer ( ) < < boost : : format ( " Sent %u bytes (%s) in %u packets, average %s/s = %.2f%% of the limit of %s/s " )
% net_stats_res . total_bytes_out
% tools : : get_human_readable_bytes ( net_stats_res . total_bytes_out )
% net_stats_res . total_packets_out
% tools : : get_human_readable_bytes ( average )
% percent
% tools : : get_human_readable_bytes ( limit ) ;
return true ;
}
bool t_rpc_command_executor : : print_blockchain_info ( uint64_t start_block_index , uint64_t end_block_index ) {
cryptonote : : COMMAND_RPC_GET_BLOCK_HEADERS_RANGE : : request req ;
cryptonote : : COMMAND_RPC_GET_BLOCK_HEADERS_RANGE : : response res ;
epee : : json_rpc : : error error_resp ;
req . start_height = start_block_index ;
req . end_height = end_block_index ;
req . fill_pow_hash = false ;
std : : string fail_message = " Unsuccessful " ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > json_rpc_request ( req , res , " getblockheadersrange " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_get_block_headers_range ( req , res , error_resp ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
return true ;
}
}
bool first = true ;
for ( auto & header : res . headers )
{
if ( ! first )
tools : : msg_writer ( ) < < " " < < std : : endl ;
tools : : msg_writer ( )
< < " height: " < < header . height < < " , timestamp: " < < header . timestamp < < " ( " < < tools : : get_human_readable_timestamp ( header . timestamp ) < < " ) "
< < " , size: " < < header . block_size < < " , weight: " < < header . block_weight < < " (long term " < < header . long_term_weight < < " ), transactions: " < < header . num_txes < < std : : endl
< < " major version: " < < ( unsigned ) header . major_version < < " , minor version: " < < ( unsigned ) header . minor_version < < std : : endl
< < " block id: " < < header . hash < < " , previous block id: " < < header . prev_hash < < std : : endl
< < " difficulty: " < < header . difficulty < < " , nonce " < < header . nonce < < " , reward " < < cryptonote : : print_money ( header . reward ) < < std : : endl ;
first = false ;
}
return true ;
}
bool t_rpc_command_executor : : set_log_level ( int8_t level ) {
cryptonote : : COMMAND_RPC_SET_LOG_LEVEL : : request req ;
cryptonote : : COMMAND_RPC_SET_LOG_LEVEL : : response res ;
req . level = level ;
std : : string fail_message = " Unsuccessful " ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > rpc_request ( req , res , " /set_log_level " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_set_log_level ( req , res ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
return true ;
}
}
tools : : success_msg_writer ( ) < < " Log level is now " < < std : : to_string ( level ) ;
return true ;
}
Change logging to easylogging++
This replaces the epee and data_loggers logging systems with
a single one, and also adds filename:line and explicit severity
levels. Categories may be defined, and logging severity set
by category (or set of categories). epee style 0-4 log level
maps to a sensible severity configuration. Log files now also
rotate when reaching 100 MB.
To select which logs to output, use the MONERO_LOGS environment
variable, with a comma separated list of categories (globs are
supported), with their requested severity level after a colon.
If a log matches more than one such setting, the last one in
the configuration string applies. A few examples:
This one is (mostly) silent, only outputting fatal errors:
MONERO_LOGS=*:FATAL
This one is very verbose:
MONERO_LOGS=*:TRACE
This one is totally silent (logwise):
MONERO_LOGS=""
This one outputs all errors and warnings, except for the
"verify" category, which prints just fatal errors (the verify
category is used for logs about incoming transactions and
blocks, and it is expected that some/many will fail to verify,
hence we don't want the spam):
MONERO_LOGS=*:WARNING,verify:FATAL
Log levels are, in decreasing order of priority:
FATAL, ERROR, WARNING, INFO, DEBUG, TRACE
Subcategories may be added using prefixes and globs. This
example will output net.p2p logs at the TRACE level, but all
other net* logs only at INFO:
MONERO_LOGS=*:ERROR,net*:INFO,net.p2p:TRACE
Logs which are intended for the user (which Monero was using
a lot through epee, but really isn't a nice way to go things)
should use the "global" category. There are a few helper macros
for using this category, eg: MGINFO("this shows up by default")
or MGINFO_RED("this is red"), to try to keep a similar look
and feel for now.
Existing epee log macros still exist, and map to the new log
levels, but since they're used as a "user facing" UI element
as much as a logging system, they often don't map well to log
severities (ie, a log level 0 log may be an error, or may be
something we want the user to see, such as an important info).
In those cases, I tried to use the new macros. In other cases,
I left the existing macros in. When modifying logs, it is
probably best to switch to the new macros with explicit levels.
The --log-level options and set_log commands now also accept
category settings, in addition to the epee style log levels.
7 years ago
bool t_rpc_command_executor : : set_log_categories ( const std : : string & categories ) {
cryptonote : : COMMAND_RPC_SET_LOG_CATEGORIES : : request req ;
cryptonote : : COMMAND_RPC_SET_LOG_CATEGORIES : : response res ;
req . categories = categories ;
std : : string fail_message = " Unsuccessful " ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > rpc_request ( req , res , " /set_log_categories " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_set_log_categories ( req , res ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
Change logging to easylogging++
This replaces the epee and data_loggers logging systems with
a single one, and also adds filename:line and explicit severity
levels. Categories may be defined, and logging severity set
by category (or set of categories). epee style 0-4 log level
maps to a sensible severity configuration. Log files now also
rotate when reaching 100 MB.
To select which logs to output, use the MONERO_LOGS environment
variable, with a comma separated list of categories (globs are
supported), with their requested severity level after a colon.
If a log matches more than one such setting, the last one in
the configuration string applies. A few examples:
This one is (mostly) silent, only outputting fatal errors:
MONERO_LOGS=*:FATAL
This one is very verbose:
MONERO_LOGS=*:TRACE
This one is totally silent (logwise):
MONERO_LOGS=""
This one outputs all errors and warnings, except for the
"verify" category, which prints just fatal errors (the verify
category is used for logs about incoming transactions and
blocks, and it is expected that some/many will fail to verify,
hence we don't want the spam):
MONERO_LOGS=*:WARNING,verify:FATAL
Log levels are, in decreasing order of priority:
FATAL, ERROR, WARNING, INFO, DEBUG, TRACE
Subcategories may be added using prefixes and globs. This
example will output net.p2p logs at the TRACE level, but all
other net* logs only at INFO:
MONERO_LOGS=*:ERROR,net*:INFO,net.p2p:TRACE
Logs which are intended for the user (which Monero was using
a lot through epee, but really isn't a nice way to go things)
should use the "global" category. There are a few helper macros
for using this category, eg: MGINFO("this shows up by default")
or MGINFO_RED("this is red"), to try to keep a similar look
and feel for now.
Existing epee log macros still exist, and map to the new log
levels, but since they're used as a "user facing" UI element
as much as a logging system, they often don't map well to log
severities (ie, a log level 0 log may be an error, or may be
something we want the user to see, such as an important info).
In those cases, I tried to use the new macros. In other cases,
I left the existing macros in. When modifying logs, it is
probably best to switch to the new macros with explicit levels.
The --log-level options and set_log commands now also accept
category settings, in addition to the epee style log levels.
7 years ago
return true ;
}
}
tools : : success_msg_writer ( ) < < " Log categories are now " < < res . categories ;
Change logging to easylogging++
This replaces the epee and data_loggers logging systems with
a single one, and also adds filename:line and explicit severity
levels. Categories may be defined, and logging severity set
by category (or set of categories). epee style 0-4 log level
maps to a sensible severity configuration. Log files now also
rotate when reaching 100 MB.
To select which logs to output, use the MONERO_LOGS environment
variable, with a comma separated list of categories (globs are
supported), with their requested severity level after a colon.
If a log matches more than one such setting, the last one in
the configuration string applies. A few examples:
This one is (mostly) silent, only outputting fatal errors:
MONERO_LOGS=*:FATAL
This one is very verbose:
MONERO_LOGS=*:TRACE
This one is totally silent (logwise):
MONERO_LOGS=""
This one outputs all errors and warnings, except for the
"verify" category, which prints just fatal errors (the verify
category is used for logs about incoming transactions and
blocks, and it is expected that some/many will fail to verify,
hence we don't want the spam):
MONERO_LOGS=*:WARNING,verify:FATAL
Log levels are, in decreasing order of priority:
FATAL, ERROR, WARNING, INFO, DEBUG, TRACE
Subcategories may be added using prefixes and globs. This
example will output net.p2p logs at the TRACE level, but all
other net* logs only at INFO:
MONERO_LOGS=*:ERROR,net*:INFO,net.p2p:TRACE
Logs which are intended for the user (which Monero was using
a lot through epee, but really isn't a nice way to go things)
should use the "global" category. There are a few helper macros
for using this category, eg: MGINFO("this shows up by default")
or MGINFO_RED("this is red"), to try to keep a similar look
and feel for now.
Existing epee log macros still exist, and map to the new log
levels, but since they're used as a "user facing" UI element
as much as a logging system, they often don't map well to log
severities (ie, a log level 0 log may be an error, or may be
something we want the user to see, such as an important info).
In those cases, I tried to use the new macros. In other cases,
I left the existing macros in. When modifying logs, it is
probably best to switch to the new macros with explicit levels.
The --log-level options and set_log commands now also accept
category settings, in addition to the epee style log levels.
7 years ago
return true ;
}
bool t_rpc_command_executor : : print_height ( ) {
cryptonote : : COMMAND_RPC_GET_HEIGHT : : request req ;
cryptonote : : COMMAND_RPC_GET_HEIGHT : : response res ;
std : : string fail_message = " Unsuccessful " ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > rpc_request ( req , res , " /getheight " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_get_height ( req , res ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
return true ;
}
}
tools : : success_msg_writer ( ) < < boost : : lexical_cast < std : : string > ( res . height ) ;
return true ;
}
bool t_rpc_command_executor : : print_block_by_hash ( crypto : : hash block_hash , bool include_hex ) {
cryptonote : : COMMAND_RPC_GET_BLOCK : : request req ;
cryptonote : : COMMAND_RPC_GET_BLOCK : : response res ;
epee : : json_rpc : : error error_resp ;
req . hash = epee : : string_tools : : pod_to_hex ( block_hash ) ;
req . fill_pow_hash = true ;
std : : string fail_message = " Unsuccessful " ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > json_rpc_request ( req , res , " getblock " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_get_block ( req , res , error_resp ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
return true ;
}
}
if ( include_hex )
tools : : success_msg_writer ( ) < < res . blob < < std : : endl ;
print_block_header ( res . block_header ) ;
tools : : success_msg_writer ( ) < < res . json < < ENDL ;
return true ;
}
bool t_rpc_command_executor : : print_block_by_height ( uint64_t height , bool include_hex ) {
cryptonote : : COMMAND_RPC_GET_BLOCK : : request req ;
cryptonote : : COMMAND_RPC_GET_BLOCK : : response res ;
epee : : json_rpc : : error error_resp ;
req . height = height ;
req . fill_pow_hash = true ;
std : : string fail_message = " Unsuccessful " ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > json_rpc_request ( req , res , " getblock " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_get_block ( req , res , error_resp ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
return true ;
}
}
if ( include_hex )
tools : : success_msg_writer ( ) < < res . blob < < std : : endl ;
print_block_header ( res . block_header ) ;
tools : : success_msg_writer ( ) < < res . json < < ENDL ;
return true ;
}
bool t_rpc_command_executor : : print_transaction ( crypto : : hash transaction_hash ,
bool include_hex ,
bool include_json ) {
cryptonote : : COMMAND_RPC_GET_TRANSACTIONS : : request req ;
cryptonote : : COMMAND_RPC_GET_TRANSACTIONS : : response res ;
std : : string fail_message = " Problem fetching transaction " ;
req . txs_hashes . push_back ( epee : : string_tools : : pod_to_hex ( transaction_hash ) ) ;
req . decode_as_json = false ;
Pruning
The blockchain prunes seven eighths of prunable tx data.
This saves about two thirds of the blockchain size, while
keeping the node useful as a sync source for an eighth
of the blockchain.
No other data is currently pruned.
There are three ways to prune a blockchain:
- run monerod with --prune-blockchain
- run "prune_blockchain" in the monerod console
- run the monero-blockchain-prune utility
The first two will prune in place. Due to how LMDB works, this
will not reduce the blockchain size on disk. Instead, it will
mark parts of the file as free, so that future data will use
that free space, causing the file to not grow until free space
grows scarce.
The third way will create a second database, a pruned copy of
the original one. Since this is a new file, this one will be
smaller than the original one.
Once the database is pruned, it will stay pruned as it syncs.
That is, there is no need to use --prune-blockchain again, etc.
6 years ago
req . split = true ;
req . prune = false ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > rpc_request ( req , res , " /gettransactions " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_get_transactions ( req , res ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
return true ;
}
}
if ( 1 = = res . txs . size ( ) | | 1 = = res . txs_as_hex . size ( ) )
{
if ( 1 = = res . txs . size ( ) )
{
// only available for new style answers
if ( res . txs . front ( ) . in_pool )
tools : : success_msg_writer ( ) < < " Found in pool " ;
else
Pruning
The blockchain prunes seven eighths of prunable tx data.
This saves about two thirds of the blockchain size, while
keeping the node useful as a sync source for an eighth
of the blockchain.
No other data is currently pruned.
There are three ways to prune a blockchain:
- run monerod with --prune-blockchain
- run "prune_blockchain" in the monerod console
- run the monero-blockchain-prune utility
The first two will prune in place. Due to how LMDB works, this
will not reduce the blockchain size on disk. Instead, it will
mark parts of the file as free, so that future data will use
that free space, causing the file to not grow until free space
grows scarce.
The third way will create a second database, a pruned copy of
the original one. Since this is a new file, this one will be
smaller than the original one.
Once the database is pruned, it will stay pruned as it syncs.
That is, there is no need to use --prune-blockchain again, etc.
6 years ago
tools : : success_msg_writer ( ) < < " Found in blockchain at height " < < res . txs . front ( ) . block_height < < ( res . txs . front ( ) . prunable_as_hex . empty ( ) ? " (pruned) " : " " ) ;
}
const std : : string & as_hex = ( 1 = = res . txs . size ( ) ) ? res . txs . front ( ) . as_hex : res . txs_as_hex . front ( ) ;
Pruning
The blockchain prunes seven eighths of prunable tx data.
This saves about two thirds of the blockchain size, while
keeping the node useful as a sync source for an eighth
of the blockchain.
No other data is currently pruned.
There are three ways to prune a blockchain:
- run monerod with --prune-blockchain
- run "prune_blockchain" in the monerod console
- run the monero-blockchain-prune utility
The first two will prune in place. Due to how LMDB works, this
will not reduce the blockchain size on disk. Instead, it will
mark parts of the file as free, so that future data will use
that free space, causing the file to not grow until free space
grows scarce.
The third way will create a second database, a pruned copy of
the original one. Since this is a new file, this one will be
smaller than the original one.
Once the database is pruned, it will stay pruned as it syncs.
That is, there is no need to use --prune-blockchain again, etc.
6 years ago
const std : : string & pruned_as_hex = ( 1 = = res . txs . size ( ) ) ? res . txs . front ( ) . pruned_as_hex : " " ;
const std : : string & prunable_as_hex = ( 1 = = res . txs . size ( ) ) ? res . txs . front ( ) . prunable_as_hex : " " ;
// Print raw hex if requested
if ( include_hex )
Pruning
The blockchain prunes seven eighths of prunable tx data.
This saves about two thirds of the blockchain size, while
keeping the node useful as a sync source for an eighth
of the blockchain.
No other data is currently pruned.
There are three ways to prune a blockchain:
- run monerod with --prune-blockchain
- run "prune_blockchain" in the monerod console
- run the monero-blockchain-prune utility
The first two will prune in place. Due to how LMDB works, this
will not reduce the blockchain size on disk. Instead, it will
mark parts of the file as free, so that future data will use
that free space, causing the file to not grow until free space
grows scarce.
The third way will create a second database, a pruned copy of
the original one. Since this is a new file, this one will be
smaller than the original one.
Once the database is pruned, it will stay pruned as it syncs.
That is, there is no need to use --prune-blockchain again, etc.
6 years ago
{
if ( ! as_hex . empty ( ) )
{
tools : : success_msg_writer ( ) < < as_hex < < std : : endl ;
}
else
{
std : : string output = pruned_as_hex + prunable_as_hex ;
tools : : success_msg_writer ( ) < < output < < std : : endl ;
}
}
// Print json if requested
if ( include_json )
{
crypto : : hash tx_hash , tx_prefix_hash ;
cryptonote : : transaction tx ;
cryptonote : : blobdata blob ;
Pruning
The blockchain prunes seven eighths of prunable tx data.
This saves about two thirds of the blockchain size, while
keeping the node useful as a sync source for an eighth
of the blockchain.
No other data is currently pruned.
There are three ways to prune a blockchain:
- run monerod with --prune-blockchain
- run "prune_blockchain" in the monerod console
- run the monero-blockchain-prune utility
The first two will prune in place. Due to how LMDB works, this
will not reduce the blockchain size on disk. Instead, it will
mark parts of the file as free, so that future data will use
that free space, causing the file to not grow until free space
grows scarce.
The third way will create a second database, a pruned copy of
the original one. Since this is a new file, this one will be
smaller than the original one.
Once the database is pruned, it will stay pruned as it syncs.
That is, there is no need to use --prune-blockchain again, etc.
6 years ago
std : : string source = as_hex . empty ( ) ? pruned_as_hex + prunable_as_hex : as_hex ;
bool pruned = ! pruned_as_hex . empty ( ) & & prunable_as_hex . empty ( ) ;
if ( ! string_tools : : parse_hexstr_to_binbuff ( source , blob ) )
{
tools : : fail_msg_writer ( ) < < " Failed to parse tx to get json format " ;
}
else
{
Pruning
The blockchain prunes seven eighths of prunable tx data.
This saves about two thirds of the blockchain size, while
keeping the node useful as a sync source for an eighth
of the blockchain.
No other data is currently pruned.
There are three ways to prune a blockchain:
- run monerod with --prune-blockchain
- run "prune_blockchain" in the monerod console
- run the monero-blockchain-prune utility
The first two will prune in place. Due to how LMDB works, this
will not reduce the blockchain size on disk. Instead, it will
mark parts of the file as free, so that future data will use
that free space, causing the file to not grow until free space
grows scarce.
The third way will create a second database, a pruned copy of
the original one. Since this is a new file, this one will be
smaller than the original one.
Once the database is pruned, it will stay pruned as it syncs.
That is, there is no need to use --prune-blockchain again, etc.
6 years ago
bool ret ;
if ( pruned )
ret = cryptonote : : parse_and_validate_tx_base_from_blob ( blob , tx ) ;
else
ret = cryptonote : : parse_and_validate_tx_from_blob ( blob , tx ) ;
if ( ! ret )
{
tools : : fail_msg_writer ( ) < < " Failed to parse tx blob to get json format " ;
}
else
{
tools : : success_msg_writer ( ) < < cryptonote : : obj_to_json_str ( tx ) < < std : : endl ;
}
}
}
}
else
{
tools : : fail_msg_writer ( ) < < " Transaction wasn't found: " < < transaction_hash < < std : : endl ;
}
return true ;
}
bool t_rpc_command_executor : : is_key_image_spent ( const crypto : : key_image & ki ) {
cryptonote : : COMMAND_RPC_IS_KEY_IMAGE_SPENT : : request req ;
cryptonote : : COMMAND_RPC_IS_KEY_IMAGE_SPENT : : response res ;
std : : string fail_message = " Problem checking key image " ;
req . key_images . push_back ( epee : : string_tools : : pod_to_hex ( ki ) ) ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > rpc_request ( req , res , " /is_key_image_spent " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_is_key_image_spent ( req , res ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
return true ;
}
}
if ( 1 = = res . spent_status . size ( ) )
{
// first as hex
tools : : success_msg_writer ( ) < < ki < < " : " < < ( res . spent_status . front ( ) ? " spent " : " unspent " ) < < ( res . spent_status . front ( ) = = cryptonote : : COMMAND_RPC_IS_KEY_IMAGE_SPENT : : SPENT_IN_POOL ? " (in pool) " : " " ) ;
}
else
{
tools : : fail_msg_writer ( ) < < " key image status could not be determined " < < std : : endl ;
}
return true ;
}
bool t_rpc_command_executor : : print_transaction_pool_long ( ) {
cryptonote : : COMMAND_RPC_GET_TRANSACTION_POOL : : request req ;
cryptonote : : COMMAND_RPC_GET_TRANSACTION_POOL : : response res ;
std : : string fail_message = " Problem fetching transaction pool " ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > rpc_request ( req , res , " /get_transaction_pool " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_get_transaction_pool ( req , res ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
return true ;
}
}
if ( res . transactions . empty ( ) & & res . spent_key_images . empty ( ) )
{
tools : : msg_writer ( ) < < " Pool is empty " < < std : : endl ;
}
if ( ! res . transactions . empty ( ) )
{
const time_t now = time ( NULL ) ;
tools : : msg_writer ( ) < < " Transactions: " ;
for ( auto & tx_info : res . transactions )
{
tools : : msg_writer ( ) < < " id: " < < tx_info . id_hash < < std : : endl
< < tx_info . tx_json < < std : : endl
< < " blob_size: " < < tx_info . blob_size < < std : : endl
< < " weight: " < < tx_info . weight < < std : : endl
< < " fee: " < < cryptonote : : print_money ( tx_info . fee ) < < std : : endl
< < " fee/byte: " < < cryptonote : : print_money ( tx_info . fee / ( double ) tx_info . weight ) < < std : : endl
< < " receive_time: " < < tx_info . receive_time < < " ( " < < get_human_time_ago ( tx_info . receive_time , now ) < < " ) " < < std : : endl
< < " relayed: " < < [ & ] ( const cryptonote : : tx_info & tx_info ) - > std : : string { if ( ! tx_info . relayed ) return " no " ; return boost : : lexical_cast < std : : string > ( tx_info . last_relayed_time ) + " ( " + get_human_time_ago ( tx_info . last_relayed_time , now ) + " ) " ; } ( tx_info ) < < std : : endl
< < " do_not_relay: " < < ( tx_info . do_not_relay ? ' T ' : ' F ' ) < < std : : endl
< < " kept_by_block: " < < ( tx_info . kept_by_block ? ' T ' : ' F ' ) < < std : : endl
< < " double_spend_seen: " < < ( tx_info . double_spend_seen ? ' T ' : ' F ' ) < < std : : endl
< < " max_used_block_height: " < < tx_info . max_used_block_height < < std : : endl
< < " max_used_block_id: " < < tx_info . max_used_block_id_hash < < std : : endl
< < " last_failed_height: " < < tx_info . last_failed_height < < std : : endl
< < " last_failed_id: " < < tx_info . last_failed_id_hash < < std : : endl ;
}
if ( res . spent_key_images . empty ( ) )
{
tools : : msg_writer ( ) < < " WARNING: Inconsistent pool state - no spent key images " ;
}
}
if ( ! res . spent_key_images . empty ( ) )
{
tools : : msg_writer ( ) < < " " ; // one newline
tools : : msg_writer ( ) < < " Spent key images: " ;
for ( const cryptonote : : spent_key_image_info & kinfo : res . spent_key_images )
{
tools : : msg_writer ( ) < < " key image: " < < kinfo . id_hash ;
if ( kinfo . txs_hashes . size ( ) = = 1 )
{
tools : : msg_writer ( ) < < " tx: " < < kinfo . txs_hashes [ 0 ] ;
}
else if ( kinfo . txs_hashes . size ( ) = = 0 )
{
tools : : msg_writer ( ) < < " WARNING: spent key image has no txs associated " ;
}
else
{
tools : : msg_writer ( ) < < " NOTE: key image for multiple txs: " < < kinfo . txs_hashes . size ( ) ;
for ( const std : : string & tx_id : kinfo . txs_hashes )
{
tools : : msg_writer ( ) < < " tx: " < < tx_id ;
}
}
}
if ( res . transactions . empty ( ) )
{
tools : : msg_writer ( ) < < " WARNING: Inconsistent pool state - no transactions " ;
}
}
return true ;
}
bool t_rpc_command_executor : : print_transaction_pool_short ( ) {
cryptonote : : COMMAND_RPC_GET_TRANSACTION_POOL : : request req ;
cryptonote : : COMMAND_RPC_GET_TRANSACTION_POOL : : response res ;
std : : string fail_message = " Problem fetching transaction pool " ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > rpc_request ( req , res , " /get_transaction_pool " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_get_transaction_pool ( req , res ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
return true ;
}
}
if ( res . transactions . empty ( ) )
{
tools : : msg_writer ( ) < < " Pool is empty " < < std : : endl ;
}
else
{
const time_t now = time ( NULL ) ;
for ( auto & tx_info : res . transactions )
{
tools : : msg_writer ( ) < < " id: " < < tx_info . id_hash < < std : : endl
< < " blob_size: " < < tx_info . blob_size < < std : : endl
< < " weight: " < < tx_info . weight < < std : : endl
< < " fee: " < < cryptonote : : print_money ( tx_info . fee ) < < std : : endl
< < " fee/byte: " < < cryptonote : : print_money ( tx_info . fee / ( double ) tx_info . weight ) < < std : : endl
< < " receive_time: " < < tx_info . receive_time < < " ( " < < get_human_time_ago ( tx_info . receive_time , now ) < < " ) " < < std : : endl
< < " relayed: " < < [ & ] ( const cryptonote : : tx_info & tx_info ) - > std : : string { if ( ! tx_info . relayed ) return " no " ; return boost : : lexical_cast < std : : string > ( tx_info . last_relayed_time ) + " ( " + get_human_time_ago ( tx_info . last_relayed_time , now ) + " ) " ; } ( tx_info ) < < std : : endl
< < " do_not_relay: " < < ( tx_info . do_not_relay ? ' T ' : ' F ' ) < < std : : endl
< < " kept_by_block: " < < ( tx_info . kept_by_block ? ' T ' : ' F ' ) < < std : : endl
< < " double_spend_seen: " < < ( tx_info . double_spend_seen ? ' T ' : ' F ' ) < < std : : endl
< < " max_used_block_height: " < < tx_info . max_used_block_height < < std : : endl
< < " max_used_block_id: " < < tx_info . max_used_block_id_hash < < std : : endl
< < " last_failed_height: " < < tx_info . last_failed_height < < std : : endl
< < " last_failed_id: " < < tx_info . last_failed_id_hash < < std : : endl ;
}
}
return true ;
}
bool t_rpc_command_executor : : print_transaction_pool_stats ( ) {
cryptonote : : COMMAND_RPC_GET_TRANSACTION_POOL_STATS : : request req ;
cryptonote : : COMMAND_RPC_GET_TRANSACTION_POOL_STATS : : response res ;
cryptonote : : COMMAND_RPC_GET_INFO : : request ireq ;
cryptonote : : COMMAND_RPC_GET_INFO : : response ires ;
std : : string fail_message = " Problem fetching transaction pool stats " ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > rpc_request ( req , res , " /get_transaction_pool_stats " , fail_message . c_str ( ) ) )
{
return true ;
}
if ( ! m_rpc_client - > rpc_request ( ireq , ires , " /getinfo " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
res . pool_stats = { } ;
if ( ! m_rpc_server - > on_get_transaction_pool_stats ( req , res ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
return true ;
}
if ( ! m_rpc_server - > on_get_info ( ireq , ires ) | | ires . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , ires . status ) ;
return true ;
}
}
size_t n_transactions = res . pool_stats . txs_total ;
const uint64_t now = time ( NULL ) ;
size_t avg_bytes = n_transactions ? res . pool_stats . bytes_total / n_transactions : 0 ;
std : : string backlog_message ;
const uint64_t full_reward_zone = ires . block_weight_limit / 2 ;
if ( res . pool_stats . bytes_total < = full_reward_zone )
{
backlog_message = " no backlog " ;
}
else
{
uint64_t backlog = ( res . pool_stats . bytes_total + full_reward_zone - 1 ) / full_reward_zone ;
backlog_message = ( boost : : format ( " estimated %u block (%u minutes) backlog " ) % backlog % ( backlog * DIFFICULTY_TARGET_V2 / 60 ) ) . str ( ) ;
}
tools : : msg_writer ( ) < < n_transactions < < " tx(es), " < < res . pool_stats . bytes_total < < " bytes total (min " < < res . pool_stats . bytes_min < < " , max " < < res . pool_stats . bytes_max < < " , avg " < < avg_bytes < < " , median " < < res . pool_stats . bytes_med < < " ) " < < std : : endl
< < " fees " < < cryptonote : : print_money ( res . pool_stats . fee_total ) < < " (avg " < < cryptonote : : print_money ( n_transactions ? res . pool_stats . fee_total / n_transactions : 0 ) < < " per tx " < < " , " < < cryptonote : : print_money ( res . pool_stats . bytes_total ? res . pool_stats . fee_total / res . pool_stats . bytes_total : 0 ) < < " per byte) " < < std : : endl
< < res . pool_stats . num_double_spends < < " double spends, " < < res . pool_stats . num_not_relayed < < " not relayed, " < < res . pool_stats . num_failing < < " failing, " < < res . pool_stats . num_10m < < " older than 10 minutes (oldest " < < ( res . pool_stats . oldest = = 0 ? " - " : get_human_time_ago ( res . pool_stats . oldest , now ) ) < < " ), " < < backlog_message ;
if ( n_transactions > 1 & & res . pool_stats . histo . size ( ) )
{
std : : vector < uint64_t > times ;
uint64_t numer ;
size_t i , n = res . pool_stats . histo . size ( ) , denom ;
times . resize ( n ) ;
if ( res . pool_stats . histo_98pc )
{
numer = res . pool_stats . histo_98pc ;
denom = n - 1 ;
for ( i = 0 ; i < denom ; i + + )
times [ i ] = i * numer / denom ;
times [ i ] = now - res . pool_stats . oldest ;
} else
{
numer = now - res . pool_stats . oldest ;
denom = n ;
for ( i = 0 ; i < denom ; i + + )
times [ i ] = i * numer / denom ;
}
tools : : msg_writer ( ) < < " Age Txes Bytes " ;
for ( i = 0 ; i < n ; i + + )
{
tools : : msg_writer ( ) < < get_time_hms ( times [ i ] ) < < std : : setw ( 8 ) < < res . pool_stats . histo [ i ] . txs < < std : : setw ( 12 ) < < res . pool_stats . histo [ i ] . bytes ;
}
}
tools : : msg_writer ( ) ;
return true ;
}
bool t_rpc_command_executor : : start_mining ( cryptonote : : account_public_address address , uint64_t num_threads , cryptonote : : network_type nettype , bool do_background_mining , bool ignore_battery ) {
cryptonote : : COMMAND_RPC_START_MINING : : request req ;
cryptonote : : COMMAND_RPC_START_MINING : : response res ;
req . miner_address = cryptonote : : get_account_address_as_str ( nettype , false , address ) ;
req . threads_count = num_threads ;
req . do_background_mining = do_background_mining ;
req . ignore_battery = ignore_battery ;
std : : string fail_message = " Mining did not start " ;
if ( m_is_rpc )
{
if ( m_rpc_client - > rpc_request ( req , res , " /start_mining " , fail_message . c_str ( ) ) )
{
tools : : success_msg_writer ( ) < < " Mining started " ;
}
}
else
{
if ( ! m_rpc_server - > on_start_mining ( req , res ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
return true ;
}
}
return true ;
}
bool t_rpc_command_executor : : stop_mining ( ) {
cryptonote : : COMMAND_RPC_STOP_MINING : : request req ;
cryptonote : : COMMAND_RPC_STOP_MINING : : response res ;
std : : string fail_message = " Mining did not stop " ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > rpc_request ( req , res , " /stop_mining " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_stop_mining ( req , res ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
return true ;
}
}
tools : : success_msg_writer ( ) < < " Mining stopped " ;
return true ;
}
bool t_rpc_command_executor : : stop_daemon ( )
{
cryptonote : : COMMAND_RPC_STOP_DAEMON : : request req ;
cryptonote : : COMMAND_RPC_STOP_DAEMON : : response res ;
//# ifdef WIN32
// // Stop via service API
// // TODO - this is only temporary! Get rid of hard-coded constants!
// bool ok = windows::stop_service("BitMonero Daemon");
// ok = windows::uninstall_service("BitMonero Daemon");
// //bool ok = windows::stop_service(SERVICE_NAME);
// //ok = windows::uninstall_service(SERVICE_NAME);
// if (ok)
// {
// return true;
// }
//# endif
// Stop via RPC
std : : string fail_message = " Daemon did not stop " ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > rpc_request ( req , res , " /stop_daemon " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_stop_daemon ( req , res ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
return true ;
}
}
tools : : success_msg_writer ( ) < < " Stop signal sent " ;
return true ;
}
bool t_rpc_command_executor : : print_status ( )
{
if ( ! m_is_rpc )
{
tools : : success_msg_writer ( ) < < " print_status makes no sense in interactive mode " ;
return true ;
}
bool daemon_is_alive = m_rpc_client - > check_connection ( ) ;
if ( daemon_is_alive ) {
tools : : success_msg_writer ( ) < < " wownerod is running " ;
}
else {
tools : : fail_msg_writer ( ) < < " wownerod is NOT running " ;
}
return true ;
}
bool t_rpc_command_executor : : get_limit ( )
{
cryptonote : : COMMAND_RPC_GET_LIMIT : : request req ;
cryptonote : : COMMAND_RPC_GET_LIMIT : : response res ;
std : : string failure_message = " Couldn't get limit " ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > rpc_request ( req , res , " /get_limit " , failure_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_get_limit ( req , res ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( failure_message , res . status ) ;
return true ;
}
}
tools : : msg_writer ( ) < < " limit-down is " < < res . limit_down < < " kB/s " ;
tools : : msg_writer ( ) < < " limit-up is " < < res . limit_up < < " kB/s " ;
return true ;
}
bool t_rpc_command_executor : : set_limit ( int64_t limit_down , int64_t limit_up )
{
cryptonote : : COMMAND_RPC_SET_LIMIT : : request req ;
cryptonote : : COMMAND_RPC_SET_LIMIT : : response res ;
req . limit_down = limit_down ;
req . limit_up = limit_up ;
std : : string failure_message = " Couldn't set limit " ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > rpc_request ( req , res , " /set_limit " , failure_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_set_limit ( req , res ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( failure_message , res . status ) ;
return true ;
}
}
tools : : msg_writer ( ) < < " Set limit-down to " < < res . limit_down < < " kB/s " ;
tools : : msg_writer ( ) < < " Set limit-up to " < < res . limit_up < < " kB/s " ;
return true ;
}
bool t_rpc_command_executor : : get_limit_up ( )
{
cryptonote : : COMMAND_RPC_GET_LIMIT : : request req ;
cryptonote : : COMMAND_RPC_GET_LIMIT : : response res ;
std : : string failure_message = " Couldn't get limit " ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > rpc_request ( req , res , " /get_limit " , failure_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_get_limit ( req , res ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( failure_message , res . status ) ;
return true ;
}
}
tools : : msg_writer ( ) < < " limit-up is " < < res . limit_up < < " kB/s " ;
return true ;
}
bool t_rpc_command_executor : : get_limit_down ( )
{
cryptonote : : COMMAND_RPC_GET_LIMIT : : request req ;
cryptonote : : COMMAND_RPC_GET_LIMIT : : response res ;
std : : string failure_message = " Couldn't get limit " ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > rpc_request ( req , res , " /get_limit " , failure_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_get_limit ( req , res ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( failure_message , res . status ) ;
return true ;
}
}
tools : : msg_writer ( ) < < " limit-down is " < < res . limit_down < < " kB/s " ;
return true ;
}
bool t_rpc_command_executor : : out_peers ( uint64_t limit )
{
cryptonote : : COMMAND_RPC_OUT_PEERS : : request req ;
cryptonote : : COMMAND_RPC_OUT_PEERS : : response res ;
epee : : json_rpc : : error error_resp ;
req . out_peers = limit ;
std : : string fail_message = " Unsuccessful " ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > rpc_request ( req , res , " /out_peers " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_out_peers ( req , res ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
return true ;
}
}
tools : : msg_writer ( ) < < " Max number of out peers set to " < < limit < < std : : endl ;
return true ;
}
bool t_rpc_command_executor : : in_peers ( uint64_t limit )
{
cryptonote : : COMMAND_RPC_IN_PEERS : : request req ;
cryptonote : : COMMAND_RPC_IN_PEERS : : response res ;
epee : : json_rpc : : error error_resp ;
req . in_peers = limit ;
std : : string fail_message = " Unsuccessful " ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > rpc_request ( req , res , " /in_peers " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_in_peers ( req , res ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
return true ;
}
}
tools : : msg_writer ( ) < < " Max number of in peers set to " < < limit < < std : : endl ;
return true ;
}
bool t_rpc_command_executor : : start_save_graph ( )
{
cryptonote : : COMMAND_RPC_START_SAVE_GRAPH : : request req ;
cryptonote : : COMMAND_RPC_START_SAVE_GRAPH : : response res ;
std : : string fail_message = " Unsuccessful " ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > rpc_request ( req , res , " /start_save_graph " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_start_save_graph ( req , res ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
return true ;
}
}
tools : : success_msg_writer ( ) < < " Saving graph is now on " ;
return true ;
}
bool t_rpc_command_executor : : stop_save_graph ( )
{
cryptonote : : COMMAND_RPC_STOP_SAVE_GRAPH : : request req ;
cryptonote : : COMMAND_RPC_STOP_SAVE_GRAPH : : response res ;
std : : string fail_message = " Unsuccessful " ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > rpc_request ( req , res , " /stop_save_graph " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_stop_save_graph ( req , res ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
return true ;
}
}
tools : : success_msg_writer ( ) < < " Saving graph is now off " ;
return true ;
}
bool t_rpc_command_executor : : hard_fork_info ( uint8_t version )
{
cryptonote : : COMMAND_RPC_HARD_FORK_INFO : : request req ;
cryptonote : : COMMAND_RPC_HARD_FORK_INFO : : response res ;
std : : string fail_message = " Unsuccessful " ;
epee : : json_rpc : : error error_resp ;
req . version = version ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > json_rpc_request ( req , res , " hard_fork_info " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_hard_fork_info ( req , res , error_resp ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
return true ;
}
}
version = version > 0 ? version : res . voting ;
tools : : msg_writer ( ) < < " version " < < ( uint32_t ) version < < " " < < ( res . enabled ? " enabled " : " not enabled " ) < <
" , " < < res . votes < < " / " < < res . window < < " votes, threshold " < < res . threshold ;
tools : : msg_writer ( ) < < " current version " < < ( uint32_t ) res . version < < " , voting for version " < < ( uint32_t ) res . voting ;
return true ;
}
bool t_rpc_command_executor : : print_bans ( )
{
cryptonote : : COMMAND_RPC_GETBANS : : request req ;
cryptonote : : COMMAND_RPC_GETBANS : : response res ;
std : : string fail_message = " Unsuccessful " ;
epee : : json_rpc : : error error_resp ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > json_rpc_request ( req , res , " get_bans " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_get_bans ( req , res , error_resp ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
return true ;
}
}
for ( auto i = res . bans . begin ( ) ; i ! = res . bans . end ( ) ; + + i )
{
tools : : msg_writer ( ) < < epee : : string_tools : : get_ip_string_from_int32 ( i - > ip ) < < " banned for " < < i - > seconds < < " seconds " ;
}
return true ;
}
bool t_rpc_command_executor : : ban ( const std : : string & ip , time_t seconds )
{
cryptonote : : COMMAND_RPC_SETBANS : : request req ;
cryptonote : : COMMAND_RPC_SETBANS : : response res ;
std : : string fail_message = " Unsuccessful " ;
epee : : json_rpc : : error error_resp ;
cryptonote : : COMMAND_RPC_SETBANS : : ban ban ;
if ( ! epee : : string_tools : : get_ip_int32_from_string ( ban . ip , ip ) )
{
tools : : fail_msg_writer ( ) < < " Invalid IP " ;
return true ;
}
ban . ban = true ;
ban . seconds = seconds ;
req . bans . push_back ( ban ) ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > json_rpc_request ( req , res , " set_bans " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_set_bans ( req , res , error_resp ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
return true ;
}
}
return true ;
}
bool t_rpc_command_executor : : unban ( const std : : string & ip )
{
cryptonote : : COMMAND_RPC_SETBANS : : request req ;
cryptonote : : COMMAND_RPC_SETBANS : : response res ;
std : : string fail_message = " Unsuccessful " ;
epee : : json_rpc : : error error_resp ;
cryptonote : : COMMAND_RPC_SETBANS : : ban ban ;
if ( ! epee : : string_tools : : get_ip_int32_from_string ( ban . ip , ip ) )
{
tools : : fail_msg_writer ( ) < < " Invalid IP " ;
return true ;
}
ban . ban = false ;
ban . seconds = 0 ;
req . bans . push_back ( ban ) ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > json_rpc_request ( req , res , " set_bans " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_set_bans ( req , res , error_resp ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
return true ;
}
}
return true ;
}
bool t_rpc_command_executor : : flush_txpool ( const std : : string & txid )
{
cryptonote : : COMMAND_RPC_FLUSH_TRANSACTION_POOL : : request req ;
cryptonote : : COMMAND_RPC_FLUSH_TRANSACTION_POOL : : response res ;
std : : string fail_message = " Unsuccessful " ;
epee : : json_rpc : : error error_resp ;
if ( ! txid . empty ( ) )
req . txids . push_back ( txid ) ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > json_rpc_request ( req , res , " flush_txpool " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_flush_txpool ( req , res , error_resp ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
return true ;
}
}
tools : : success_msg_writer ( ) < < " Pool successfully flushed " ;
return true ;
}
bool t_rpc_command_executor : : output_histogram ( const std : : vector < uint64_t > & amounts , uint64_t min_count , uint64_t max_count )
{
cryptonote : : COMMAND_RPC_GET_OUTPUT_HISTOGRAM : : request req ;
cryptonote : : COMMAND_RPC_GET_OUTPUT_HISTOGRAM : : response res ;
std : : string fail_message = " Unsuccessful " ;
epee : : json_rpc : : error error_resp ;
req . amounts = amounts ;
req . min_count = min_count ;
req . max_count = max_count ;
req . unlocked = false ;
req . recent_cutoff = 0 ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > json_rpc_request ( req , res , " get_output_histogram " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_get_output_histogram ( req , res , error_resp ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
return true ;
}
}
std : : sort ( res . histogram . begin ( ) , res . histogram . end ( ) ,
[ ] ( const cryptonote : : COMMAND_RPC_GET_OUTPUT_HISTOGRAM : : entry & e1 , const cryptonote : : COMMAND_RPC_GET_OUTPUT_HISTOGRAM : : entry & e2 ) - > bool { return e1 . total_instances < e2 . total_instances ; } ) ;
for ( const auto & e : res . histogram )
{
tools : : msg_writer ( ) < < e . total_instances < < " " < < cryptonote : : print_money ( e . amount ) ;
}
return true ;
}
bool t_rpc_command_executor : : print_coinbase_tx_sum ( uint64_t height , uint64_t count )
{
cryptonote : : COMMAND_RPC_GET_COINBASE_TX_SUM : : request req ;
cryptonote : : COMMAND_RPC_GET_COINBASE_TX_SUM : : response res ;
epee : : json_rpc : : error error_resp ;
req . height = height ;
req . count = count ;
std : : string fail_message = " Unsuccessful " ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > json_rpc_request ( req , res , " get_coinbase_tx_sum " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_get_coinbase_tx_sum ( req , res , error_resp ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
return true ;
}
}
tools : : msg_writer ( ) < < " Sum of coinbase transactions between block heights [ "
< < height < < " , " < < ( height + count ) < < " ) is "
< < cryptonote : : print_money ( res . emission_amount + res . fee_amount ) < < " "
< < " consisting of " < < cryptonote : : print_money ( res . emission_amount )
< < " in emissions, and " < < cryptonote : : print_money ( res . fee_amount ) < < " in fees " ;
return true ;
}
bool t_rpc_command_executor : : alt_chain_info ( const std : : string & tip )
{
cryptonote : : COMMAND_RPC_GET_INFO : : request ireq ;
cryptonote : : COMMAND_RPC_GET_INFO : : response ires ;
cryptonote : : COMMAND_RPC_GET_ALTERNATE_CHAINS : : request req ;
cryptonote : : COMMAND_RPC_GET_ALTERNATE_CHAINS : : response res ;
epee : : json_rpc : : error error_resp ;
std : : string fail_message = " Unsuccessful " ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > rpc_request ( ireq , ires , " /getinfo " , fail_message . c_str ( ) ) )
{
return true ;
}
if ( ! m_rpc_client - > json_rpc_request ( req , res , " get_alternate_chains " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_get_info ( ireq , ires ) | | ires . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , ires . status ) ;
return true ;
}
if ( ! m_rpc_server - > on_get_alternate_chains ( req , res , error_resp ) )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
return true ;
}
}
if ( tip . empty ( ) )
{
tools : : msg_writer ( ) < < boost : : lexical_cast < std : : string > ( res . chains . size ( ) ) < < " alternate chains found: " ;
for ( const auto & chain : res . chains )
{
uint64_t start_height = ( chain . height - chain . length + 1 ) ;
tools : : msg_writer ( ) < < chain . length < < " blocks long, from height " < < start_height < < " ( " < < ( ires . height - start_height - 1 )
< < " deep), diff " < < chain . difficulty < < " : " < < chain . block_hash ;
}
}
else
{
const auto i = std : : find_if ( res . chains . begin ( ) , res . chains . end ( ) , [ & tip ] ( cryptonote : : COMMAND_RPC_GET_ALTERNATE_CHAINS : : chain_info & info ) { return info . block_hash = = tip ; } ) ;
if ( i ! = res . chains . end ( ) )
{
const auto & chain = * i ;
tools : : success_msg_writer ( ) < < " Found alternate chain with tip " < < tip ;
uint64_t start_height = ( chain . height - chain . length + 1 ) ;
tools : : msg_writer ( ) < < chain . length < < " blocks long, from height " < < start_height < < " ( " < < ( ires . height - start_height - 1 )
< < " deep), diff " < < chain . difficulty < < " : " ;
for ( const std : : string & block_id : chain . block_hashes )
tools : : msg_writer ( ) < < " " < < block_id ;
tools : : msg_writer ( ) < < " Chain parent on main chain: " < < chain . main_chain_parent_block ;
}
else
tools : : fail_msg_writer ( ) < < " Block hash " < < tip < < " is not the tip of any known alternate chain " ;
}
return true ;
}
bool t_rpc_command_executor : : print_blockchain_dynamic_stats ( uint64_t nblocks )
{
cryptonote : : COMMAND_RPC_GET_INFO : : request ireq ;
cryptonote : : COMMAND_RPC_GET_INFO : : response ires ;
cryptonote : : COMMAND_RPC_GET_BLOCK_HEADERS_RANGE : : request bhreq ;
cryptonote : : COMMAND_RPC_GET_BLOCK_HEADERS_RANGE : : response bhres ;
cryptonote : : COMMAND_RPC_GET_BASE_FEE_ESTIMATE : : request fereq ;
cryptonote : : COMMAND_RPC_GET_BASE_FEE_ESTIMATE : : response feres ;
cryptonote : : COMMAND_RPC_HARD_FORK_INFO : : request hfreq ;
cryptonote : : COMMAND_RPC_HARD_FORK_INFO : : response hfres ;
epee : : json_rpc : : error error_resp ;
std : : string fail_message = " Problem fetching info " ;
fereq . grace_blocks = 0 ;
hfreq . version = HF_VERSION_PER_BYTE_FEE ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > rpc_request ( ireq , ires , " /getinfo " , fail_message . c_str ( ) ) )
{
return true ;
}
if ( ! m_rpc_client - > json_rpc_request ( fereq , feres , " get_fee_estimate " , fail_message . c_str ( ) ) )
{
return true ;
}
if ( ! m_rpc_client - > json_rpc_request ( hfreq , hfres , " hard_fork_info " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_get_info ( ireq , ires ) | | ires . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , ires . status ) ;
return true ;
}
if ( ! m_rpc_server - > on_get_base_fee_estimate ( fereq , feres , error_resp ) | | feres . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , feres . status ) ;
return true ;
}
if ( ! m_rpc_server - > on_hard_fork_info ( hfreq , hfres , error_resp ) | | hfres . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , hfres . status ) ;
return true ;
}
}
tools : : msg_writer ( ) < < " Height: " < < ires . height < < " , diff " < < ires . difficulty < < " , cum. diff " < < ires . cumulative_difficulty
< < " , target " < < ires . target < < " sec " < < " , dyn fee " < < cryptonote : : print_money ( feres . fee ) < < " / " < < ( hfres . enabled ? " byte " : " kB " ) ;
if ( nblocks > 0 )
{
if ( nblocks > ires . height )
nblocks = ires . height ;
bhreq . start_height = ires . height - nblocks ;
bhreq . end_height = ires . height - 1 ;
bhreq . fill_pow_hash = false ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > json_rpc_request ( bhreq , bhres , " getblockheadersrange " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_get_block_headers_range ( bhreq , bhres , error_resp ) | | bhres . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , bhres . status ) ;
return true ;
}
}
double avgdiff = 0 ;
double avgnumtxes = 0 ;
double avgreward = 0 ;
std : : vector < uint64_t > weights ;
weights . reserve ( nblocks ) ;
uint64_t earliest = std : : numeric_limits < uint64_t > : : max ( ) , latest = 0 ;
std : : vector < unsigned > major_versions ( 256 , 0 ) , minor_versions ( 256 , 0 ) ;
for ( const auto & bhr : bhres . headers )
{
avgdiff + = bhr . difficulty ;
avgnumtxes + = bhr . num_txes ;
avgreward + = bhr . reward ;
weights . push_back ( bhr . block_weight ) ;
static_assert ( sizeof ( bhr . major_version ) = = 1 , " major_version expected to be uint8_t " ) ;
static_assert ( sizeof ( bhr . minor_version ) = = 1 , " major_version expected to be uint8_t " ) ;
major_versions [ ( unsigned ) bhr . major_version ] + + ;
minor_versions [ ( unsigned ) bhr . minor_version ] + + ;
earliest = std : : min ( earliest , bhr . timestamp ) ;
latest = std : : max ( latest , bhr . timestamp ) ;
}
avgdiff / = nblocks ;
avgnumtxes / = nblocks ;
avgreward / = nblocks ;
uint64_t median_block_weight = epee : : misc_utils : : median ( weights ) ;
tools : : msg_writer ( ) < < " Last " < < nblocks < < " : avg. diff " < < ( uint64_t ) avgdiff < < " , " < < ( latest - earliest ) / nblocks < < " avg sec/block, avg num txes " < < avgnumtxes
< < " , avg. reward " < < cryptonote : : print_money ( avgreward ) < < " , median block weight " < < median_block_weight ;
unsigned int max_major = 256 , max_minor = 256 ;
while ( max_major > 0 & & ! major_versions [ - - max_major ] ) ;
while ( max_minor > 0 & & ! minor_versions [ - - max_minor ] ) ;
std : : string s = " " ;
for ( unsigned n = 0 ; n < = max_major ; + + n )
if ( major_versions [ n ] )
s + = ( s . empty ( ) ? " " : " , " ) + boost : : lexical_cast < std : : string > ( major_versions [ n ] ) + std : : string ( " v " ) + boost : : lexical_cast < std : : string > ( n ) ;
tools : : msg_writer ( ) < < " Block versions: " < < s ;
s = " " ;
for ( unsigned n = 0 ; n < = max_minor ; + + n )
if ( minor_versions [ n ] )
s + = ( s . empty ( ) ? " " : " , " ) + boost : : lexical_cast < std : : string > ( minor_versions [ n ] ) + std : : string ( " v " ) + boost : : lexical_cast < std : : string > ( n ) ;
tools : : msg_writer ( ) < < " Voting for: " < < s ;
}
return true ;
}
bool t_rpc_command_executor : : update ( const std : : string & command )
{
cryptonote : : COMMAND_RPC_UPDATE : : request req ;
cryptonote : : COMMAND_RPC_UPDATE : : response res ;
epee : : json_rpc : : error error_resp ;
std : : string fail_message = " Problem fetching info " ;
req . command = command ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > rpc_request ( req , res , " /update " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_update ( req , res ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
return true ;
}
}
if ( ! res . update )
{
tools : : msg_writer ( ) < < " No update available " ;
return true ;
}
tools : : msg_writer ( ) < < " Update available: v " < < res . version < < " : " < < res . user_uri < < " , hash " < < res . hash ;
if ( command = = " check " )
return true ;
if ( ! res . path . empty ( ) )
tools : : msg_writer ( ) < < " Update downloaded to: " < < res . path ;
else
tools : : msg_writer ( ) < < " Update download failed: " < < res . status ;
if ( command = = " download " )
return true ;
tools : : msg_writer ( ) < < " 'update' not implemented yet " ;
return true ;
}
bool t_rpc_command_executor : : relay_tx ( const std : : string & txid )
{
cryptonote : : COMMAND_RPC_RELAY_TX : : request req ;
cryptonote : : COMMAND_RPC_RELAY_TX : : response res ;
std : : string fail_message = " Unsuccessful " ;
epee : : json_rpc : : error error_resp ;
req . txids . push_back ( txid ) ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > json_rpc_request ( req , res , " relay_tx " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_relay_tx ( req , res , error_resp ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
return true ;
}
}
tools : : success_msg_writer ( ) < < " Transaction successfully relayed " ;
return true ;
}
bool t_rpc_command_executor : : sync_info ( )
{
cryptonote : : COMMAND_RPC_SYNC_INFO : : request req ;
cryptonote : : COMMAND_RPC_SYNC_INFO : : response res ;
std : : string fail_message = " Unsuccessful " ;
epee : : json_rpc : : error error_resp ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > json_rpc_request ( req , res , " sync_info " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_sync_info ( req , res , error_resp ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
return true ;
}
}
uint64_t target = res . target_height < res . height ? res . height : res . target_height ;
tools : : success_msg_writer ( ) < < " Height: " < < res . height < < " , target: " < < target < < " ( " < < ( 100.0 * res . height / target ) < < " %) " ;
uint64_t current_download = 0 ;
for ( const auto & p : res . peers )
current_download + = p . info . current_download ;
tools : : success_msg_writer ( ) < < " Downloading at " < < current_download < < " kB/s " ;
Pruning
The blockchain prunes seven eighths of prunable tx data.
This saves about two thirds of the blockchain size, while
keeping the node useful as a sync source for an eighth
of the blockchain.
No other data is currently pruned.
There are three ways to prune a blockchain:
- run monerod with --prune-blockchain
- run "prune_blockchain" in the monerod console
- run the monero-blockchain-prune utility
The first two will prune in place. Due to how LMDB works, this
will not reduce the blockchain size on disk. Instead, it will
mark parts of the file as free, so that future data will use
that free space, causing the file to not grow until free space
grows scarce.
The third way will create a second database, a pruned copy of
the original one. Since this is a new file, this one will be
smaller than the original one.
Once the database is pruned, it will stay pruned as it syncs.
That is, there is no need to use --prune-blockchain again, etc.
6 years ago
if ( res . next_needed_pruning_seed )
tools : : success_msg_writer ( ) < < " Next needed pruning seed: " < < res . next_needed_pruning_seed ;
tools : : success_msg_writer ( ) < < std : : to_string ( res . peers . size ( ) ) < < " peers " ;
for ( const auto & p : res . peers )
{
std : : string address = epee : : string_tools : : pad_string ( p . info . address , 24 ) ;
uint64_t nblocks = 0 , size = 0 ;
for ( const auto & s : res . spans )
Pruning
The blockchain prunes seven eighths of prunable tx data.
This saves about two thirds of the blockchain size, while
keeping the node useful as a sync source for an eighth
of the blockchain.
No other data is currently pruned.
There are three ways to prune a blockchain:
- run monerod with --prune-blockchain
- run "prune_blockchain" in the monerod console
- run the monero-blockchain-prune utility
The first two will prune in place. Due to how LMDB works, this
will not reduce the blockchain size on disk. Instead, it will
mark parts of the file as free, so that future data will use
that free space, causing the file to not grow until free space
grows scarce.
The third way will create a second database, a pruned copy of
the original one. Since this is a new file, this one will be
smaller than the original one.
Once the database is pruned, it will stay pruned as it syncs.
That is, there is no need to use --prune-blockchain again, etc.
6 years ago
if ( s . connection_id = = p . info . connection_id )
nblocks + = s . nblocks , size + = s . size ;
Pruning
The blockchain prunes seven eighths of prunable tx data.
This saves about two thirds of the blockchain size, while
keeping the node useful as a sync source for an eighth
of the blockchain.
No other data is currently pruned.
There are three ways to prune a blockchain:
- run monerod with --prune-blockchain
- run "prune_blockchain" in the monerod console
- run the monero-blockchain-prune utility
The first two will prune in place. Due to how LMDB works, this
will not reduce the blockchain size on disk. Instead, it will
mark parts of the file as free, so that future data will use
that free space, causing the file to not grow until free space
grows scarce.
The third way will create a second database, a pruned copy of
the original one. Since this is a new file, this one will be
smaller than the original one.
Once the database is pruned, it will stay pruned as it syncs.
That is, there is no need to use --prune-blockchain again, etc.
6 years ago
tools : : success_msg_writer ( ) < < address < < " " < < epee : : string_tools : : pad_string ( p . info . peer_id , 16 , ' 0 ' , true ) < < " " < <
epee : : string_tools : : pad_string ( p . info . state , 16 ) < < " " < <
epee : : string_tools : : pad_string ( epee : : string_tools : : to_string_hex ( p . info . pruning_seed ) , 8 ) < < " " < < p . info . height < < " " < <
p . info . current_download < < " kB/s, " < < nblocks < < " blocks / " < < size / 1e6 < < " MB queued " ;
}
uint64_t total_size = 0 ;
for ( const auto & s : res . spans )
total_size + = s . size ;
tools : : success_msg_writer ( ) < < std : : to_string ( res . spans . size ( ) ) < < " spans, " < < total_size / 1e6 < < " MB " ;
Pruning
The blockchain prunes seven eighths of prunable tx data.
This saves about two thirds of the blockchain size, while
keeping the node useful as a sync source for an eighth
of the blockchain.
No other data is currently pruned.
There are three ways to prune a blockchain:
- run monerod with --prune-blockchain
- run "prune_blockchain" in the monerod console
- run the monero-blockchain-prune utility
The first two will prune in place. Due to how LMDB works, this
will not reduce the blockchain size on disk. Instead, it will
mark parts of the file as free, so that future data will use
that free space, causing the file to not grow until free space
grows scarce.
The third way will create a second database, a pruned copy of
the original one. Since this is a new file, this one will be
smaller than the original one.
Once the database is pruned, it will stay pruned as it syncs.
That is, there is no need to use --prune-blockchain again, etc.
6 years ago
tools : : success_msg_writer ( ) < < res . overview ;
for ( const auto & s : res . spans )
{
std : : string address = epee : : string_tools : : pad_string ( s . remote_address , 24 ) ;
Pruning
The blockchain prunes seven eighths of prunable tx data.
This saves about two thirds of the blockchain size, while
keeping the node useful as a sync source for an eighth
of the blockchain.
No other data is currently pruned.
There are three ways to prune a blockchain:
- run monerod with --prune-blockchain
- run "prune_blockchain" in the monerod console
- run the monero-blockchain-prune utility
The first two will prune in place. Due to how LMDB works, this
will not reduce the blockchain size on disk. Instead, it will
mark parts of the file as free, so that future data will use
that free space, causing the file to not grow until free space
grows scarce.
The third way will create a second database, a pruned copy of
the original one. Since this is a new file, this one will be
smaller than the original one.
Once the database is pruned, it will stay pruned as it syncs.
That is, there is no need to use --prune-blockchain again, etc.
6 years ago
std : : string pruning_seed = epee : : string_tools : : to_string_hex ( tools : : get_pruning_seed ( s . start_block_height , std : : numeric_limits < uint64_t > : : max ( ) , CRYPTONOTE_PRUNING_LOG_STRIPES ) ) ;
if ( s . size = = 0 )
{
Pruning
The blockchain prunes seven eighths of prunable tx data.
This saves about two thirds of the blockchain size, while
keeping the node useful as a sync source for an eighth
of the blockchain.
No other data is currently pruned.
There are three ways to prune a blockchain:
- run monerod with --prune-blockchain
- run "prune_blockchain" in the monerod console
- run the monero-blockchain-prune utility
The first two will prune in place. Due to how LMDB works, this
will not reduce the blockchain size on disk. Instead, it will
mark parts of the file as free, so that future data will use
that free space, causing the file to not grow until free space
grows scarce.
The third way will create a second database, a pruned copy of
the original one. Since this is a new file, this one will be
smaller than the original one.
Once the database is pruned, it will stay pruned as it syncs.
That is, there is no need to use --prune-blockchain again, etc.
6 years ago
tools : : success_msg_writer ( ) < < address < < " " < < s . nblocks < < " / " < < pruning_seed < < " ( " < < s . start_block_height < < " - " < < ( s . start_block_height + s . nblocks - 1 ) < < " ) - " ;
}
else
{
Pruning
The blockchain prunes seven eighths of prunable tx data.
This saves about two thirds of the blockchain size, while
keeping the node useful as a sync source for an eighth
of the blockchain.
No other data is currently pruned.
There are three ways to prune a blockchain:
- run monerod with --prune-blockchain
- run "prune_blockchain" in the monerod console
- run the monero-blockchain-prune utility
The first two will prune in place. Due to how LMDB works, this
will not reduce the blockchain size on disk. Instead, it will
mark parts of the file as free, so that future data will use
that free space, causing the file to not grow until free space
grows scarce.
The third way will create a second database, a pruned copy of
the original one. Since this is a new file, this one will be
smaller than the original one.
Once the database is pruned, it will stay pruned as it syncs.
That is, there is no need to use --prune-blockchain again, etc.
6 years ago
tools : : success_msg_writer ( ) < < address < < " " < < s . nblocks < < " / " < < pruning_seed < < " ( " < < s . start_block_height < < " - " < < ( s . start_block_height + s . nblocks - 1 ) < < " , " < < ( uint64_t ) ( s . size / 1e3 ) < < " kB) " < < ( unsigned ) ( s . rate / 1e3 ) < < " kB/s ( " < < s . speed / 100.0f < < " ) " ;
}
}
return true ;
}
bool t_rpc_command_executor : : pop_blocks ( uint64_t num_blocks )
{
cryptonote : : COMMAND_RPC_POP_BLOCKS : : request req ;
cryptonote : : COMMAND_RPC_POP_BLOCKS : : response res ;
std : : string fail_message = " pop_blocks failed " ;
req . nblocks = num_blocks ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > rpc_request ( req , res , " /pop_blocks " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_pop_blocks ( req , res ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
return true ;
}
}
tools : : success_msg_writer ( ) < < " new height: " < < res . height ;
return true ;
}
Pruning
The blockchain prunes seven eighths of prunable tx data.
This saves about two thirds of the blockchain size, while
keeping the node useful as a sync source for an eighth
of the blockchain.
No other data is currently pruned.
There are three ways to prune a blockchain:
- run monerod with --prune-blockchain
- run "prune_blockchain" in the monerod console
- run the monero-blockchain-prune utility
The first two will prune in place. Due to how LMDB works, this
will not reduce the blockchain size on disk. Instead, it will
mark parts of the file as free, so that future data will use
that free space, causing the file to not grow until free space
grows scarce.
The third way will create a second database, a pruned copy of
the original one. Since this is a new file, this one will be
smaller than the original one.
Once the database is pruned, it will stay pruned as it syncs.
That is, there is no need to use --prune-blockchain again, etc.
6 years ago
bool t_rpc_command_executor : : prune_blockchain ( )
{
cryptonote : : COMMAND_RPC_PRUNE_BLOCKCHAIN : : request req ;
cryptonote : : COMMAND_RPC_PRUNE_BLOCKCHAIN : : response res ;
std : : string fail_message = " Unsuccessful " ;
epee : : json_rpc : : error error_resp ;
req . check = false ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > json_rpc_request ( req , res , " prune_blockchain " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_prune_blockchain ( req , res , error_resp ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
return true ;
}
}
tools : : success_msg_writer ( ) < < " Blockchain pruned " ;
Pruning
The blockchain prunes seven eighths of prunable tx data.
This saves about two thirds of the blockchain size, while
keeping the node useful as a sync source for an eighth
of the blockchain.
No other data is currently pruned.
There are three ways to prune a blockchain:
- run monerod with --prune-blockchain
- run "prune_blockchain" in the monerod console
- run the monero-blockchain-prune utility
The first two will prune in place. Due to how LMDB works, this
will not reduce the blockchain size on disk. Instead, it will
mark parts of the file as free, so that future data will use
that free space, causing the file to not grow until free space
grows scarce.
The third way will create a second database, a pruned copy of
the original one. Since this is a new file, this one will be
smaller than the original one.
Once the database is pruned, it will stay pruned as it syncs.
That is, there is no need to use --prune-blockchain again, etc.
6 years ago
return true ;
}
bool t_rpc_command_executor : : check_blockchain_pruning ( )
{
cryptonote : : COMMAND_RPC_PRUNE_BLOCKCHAIN : : request req ;
cryptonote : : COMMAND_RPC_PRUNE_BLOCKCHAIN : : response res ;
std : : string fail_message = " Unsuccessful " ;
epee : : json_rpc : : error error_resp ;
req . check = true ;
if ( m_is_rpc )
{
if ( ! m_rpc_client - > json_rpc_request ( req , res , " prune_blockchain " , fail_message . c_str ( ) ) )
{
return true ;
}
}
else
{
if ( ! m_rpc_server - > on_prune_blockchain ( req , res , error_resp ) | | res . status ! = CORE_RPC_STATUS_OK )
{
tools : : fail_msg_writer ( ) < < make_error ( fail_message , res . status ) ;
return true ;
}
}
if ( res . pruning_seed )
{
tools : : success_msg_writer ( ) < < " Blockchain is pruned " ;
Pruning
The blockchain prunes seven eighths of prunable tx data.
This saves about two thirds of the blockchain size, while
keeping the node useful as a sync source for an eighth
of the blockchain.
No other data is currently pruned.
There are three ways to prune a blockchain:
- run monerod with --prune-blockchain
- run "prune_blockchain" in the monerod console
- run the monero-blockchain-prune utility
The first two will prune in place. Due to how LMDB works, this
will not reduce the blockchain size on disk. Instead, it will
mark parts of the file as free, so that future data will use
that free space, causing the file to not grow until free space
grows scarce.
The third way will create a second database, a pruned copy of
the original one. Since this is a new file, this one will be
smaller than the original one.
Once the database is pruned, it will stay pruned as it syncs.
That is, there is no need to use --prune-blockchain again, etc.
6 years ago
}
else
{
tools : : success_msg_writer ( ) < < " Blockchain is not pruned " ;
}
return true ;
}
} // namespace daemonize
