hush3/src/hush_globals.h

// Copyright 2016-2020 The Hush Developers
// Distributed under the GPLv3 software license, see the accompanying
// file COPYING or https://www.gnu.org/licenses/gpl-3.0.en.html
/******************************************************************************
 * Copyright © 2014-2019 The SuperNET Developers.                             *
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 * See the AUTHORS, DEVELOPER-AGREEMENT and LICENSE files at                  *
 * the top-level directory of this distribution for the individual copyright  *
 * holder information and the developer policies on copyright and licensing.  *
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 * SuperNET software, including this file may be copied, modified, propagated *
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#include "hush_defs.h"
void komodo_prefetch(FILE *fp);
uint32_t komodo_heightstamp(int32_t height);
void hush_stateupdate(int32_t height,uint8_t notarypubs[][33],uint8_t numnotaries,uint8_t notaryid,uint256 txhash,uint64_t voutmask,uint8_t numvouts,uint32_t *pvals,uint8_t numpvals,int32_t kheight,uint32_t ktime,uint64_t opretvalue,uint8_t *opretbuf,uint16_t opretlen,uint16_t vout,uint256 MoM,int32_t MoMdepth);
void komodo_init(int32_t height);
int32_t komodo_MoMdata(int32_t *notarized_htp,uint256 *MoMp,uint256 *kmdtxidp,int32_t nHeight,uint256 *MoMoMp,int32_t *MoMoMoffsetp,int32_t *MoMoMdepthp,int32_t *kmdstartip,int32_t *kmdendip);
int32_t komodo_notarizeddata(int32_t nHeight,uint256 *notarized_hashp,uint256 *notarized_desttxidp);
char *komodo_issuemethod(char *userpass,char *method,char *params,uint16_t port);
void komodo_init(int32_t height);
int32_t hush_chosennotary(int32_t *notaryidp,int32_t height,uint8_t *pubkey33,uint32_t timestamp);
int32_t komodo_isrealtime(int32_t *kmdheightp);
uint64_t komodo_paxtotal();
int32_t hush_longestchain();
uint64_t komodo_maxallowed(int32_t baseid);
int32_t komodo_bannedset(int32_t *indallvoutsp,uint256 *array,int32_t max);
int32_t komodo_checkvout(int32_t vout,int32_t k,int32_t indallvouts);
pthread_mutex_t komodo_mutex,staked_mutex;

#define KOMODO_ELECTION_GAP 2000    //((SMART_CHAIN_SYMBOL[0] == 0) ? 2000 : 100)
#define HUSH_SMART_CHAIN_MAXLEN 65

struct pax_transaction *PAX;
int32_t NUM_PRICES; uint32_t *PVALS;
struct knotaries_entry *Pubkeys;
struct hush_state KOMODO_STATES[34];

#define _COINBASE_MATURITY 100
int COINBASE_MATURITY = _COINBASE_MATURITY;//100;
unsigned int WITNESS_CACHE_SIZE = _COINBASE_MATURITY+10;
uint256 HUSH_EARLYTXID;

int32_t HUSH_MININGTHREADS = -1,IS_HUSH_NOTARY,USE_EXTERNAL_PUBKEY,KOMODO_CHOSEN_ONE,ASSETCHAINS_SEED,KOMODO_ON_DEMAND,KOMODO_EXTERNAL_NOTARIES,HUSH_PASSPORT_INITDONE,KOMODO_PAX,HUSH_EXCHANGEWALLET,HUSH_REWIND,HUSH_CONNECTING = -1,KOMODO_DEALERNODE,HUSH_EXTRASATOSHI,ASSETCHAINS_FOUNDERS,ASSETCHAINS_CBMATURITY,HUSH_NSPV;
int32_t HUSH_INSYNC,KOMODO_LASTMINED,prevKOMODO_LASTMINED,KOMODO_CCACTIVATE,JUMBLR_PAUSE = 1;
std::string NOTARY_PUBKEY,ASSETCHAINS_NOTARIES,ASSETCHAINS_OVERRIDE_PUBKEY,DONATION_PUBKEY,ASSETCHAINS_SCRIPTPUB,NOTARY_ADDRESS,ASSETCHAINS_SELFIMPORT,ASSETCHAINS_CCLIB;
uint8_t NOTARY_PUBKEY33[33],ASSETCHAINS_OVERRIDE_PUBKEY33[33],ASSETCHAINS_OVERRIDE_PUBKEYHASH[20],ASSETCHAINS_PUBLIC,ASSETCHAINS_PRIVATE,ASSETCHAINS_TXPOW,ASSETCHAINS_MARMARA;
int8_t ASSETCHAINS_ADAPTIVEPOW;
std::vector<uint8_t> Mineropret;
std::vector<std::string> vWhiteListAddress;
char NOTARYADDRS[64][64];
char NOTARY_ADDRESSES[NUM_HUSH_SEASONS][64][64];

char SMART_CHAIN_SYMBOL[HUSH_SMART_CHAIN_MAXLEN],ASSETCHAINS_USERPASS[4096];
uint16_t ASSETCHAINS_P2PPORT,ASSETCHAINS_RPCPORT,ASSETCHAINS_BEAMPORT,ASSETCHAINS_CODAPORT;
uint32_t ASSETCHAIN_INIT,ASSETCHAINS_CC,HUSH_STOPAT,HUSH_DPOWCONFS = 1,STAKING_MIN_DIFF;
uint32_t ASSETCHAINS_MAGIC = 2387029918;
int64_t ASSETCHAINS_GENESISTXVAL = 5000000000;

int64_t MAX_MONEY = 200000000 * 100000000LL;

// consensus variables for coinbase timelock control and timelock transaction support
// time locks are specified enough to enable their use initially to lock specific coinbase transactions for emission control
// to be verifiable, timelocks require additional data that enables them to be validated and their ownership and
// release time determined from the blockchain. to do this, every time locked output according to this
// spec will use an op_return with CLTV at front and anything after |OP_RETURN|PUSH of rest|OPRETTYPE_TIMELOCK|script|
#define _ASSETCHAINS_TIMELOCKOFF 0xffffffffffffffff
uint64_t ASSETCHAINS_TIMELOCKGTE = _ASSETCHAINS_TIMELOCKOFF;
uint64_t ASSETCHAINS_TIMEUNLOCKFROM = 0, ASSETCHAINS_TIMEUNLOCKTO = 0,ASSETCHAINS_CBOPRET=0;

uint64_t ASSETCHAINS_LASTERA = 1;
uint64_t ASSETCHAINS_ENDSUBSIDY[ASSETCHAINS_MAX_ERAS+1],ASSETCHAINS_REWARD[ASSETCHAINS_MAX_ERAS+1],ASSETCHAINS_HALVING[ASSETCHAINS_MAX_ERAS+1],ASSETCHAINS_DECAY[ASSETCHAINS_MAX_ERAS+1],ASSETCHAINS_NOTARY_PAY[ASSETCHAINS_MAX_ERAS+1],ASSETCHAINS_PEGSCCPARAMS[3];
uint8_t ASSETCHAINS_CCDISABLES[256];
std::vector<std::string> ASSETCHAINS_PRICES,ASSETCHAINS_STOCKS;

#define _ASSETCHAINS_EQUIHASH 0
uint32_t ASSETCHAINS_NUMALGOS = 3;
uint32_t ASSETCHAINS_EQUIHASH = _ASSETCHAINS_EQUIHASH;
const char *ASSETCHAINS_ALGORITHMS[] = {"equihash"};
uint64_t ASSETCHAINS_NONCEMASK[] = {0xffff};
uint32_t ASSETCHAINS_NONCESHIFT[] = {32};
uint32_t ASSETCHAINS_HASHESPERROUND[] = {1};
uint32_t ASSETCHAINS_ALGO = _ASSETCHAINS_EQUIHASH;
// min diff returned from GetNextWorkRequired needs to be added here for each algo, so they can work with ac_staked.
uint32_t ASSETCHAINS_MINDIFF[] = {537857807};
int32_t ASSETCHAINS_LWMAPOS = 0;        // percentage of blocks should be PoS
int32_t ASSETCHAINS_SAPLING = -1;
int32_t ASSETCHAINS_OVERWINTER = -1;
uint64_t KOMODO_INTERESTSUM,KOMODO_WALLETBALANCE;
int32_t ASSETCHAINS_STAKED;
uint64_t ASSETCHAINS_COMMISSION,ASSETCHAINS_SUPPLY = 10,ASSETCHAINS_FOUNDERS_REWARD;
uint32_t HUSH_INITDONE;
char KMDUSERPASS[8192+512+1],BTCUSERPASS[8192]; uint16_t KMD_PORT = 7771,BITCOIND_RPCPORT = 7771;
uint64_t PENDING_KOMODO_TX;
extern int32_t HUSH_LOADINGBLOCKS;
unsigned int MAX_BLOCK_SIGOPS = 20000;
int32_t HUSH_TESTNODE, HUSH_SNAPSHOT_INTERVAL;
CScript HUSH_EARLYTXID_SCRIPTPUB;
int32_t ASSETCHAINS_EARLYTXIDCONTRACT;
std::map <std::int8_t, int32_t> mapHeightEvalActivate;
struct komodo_kv *HUSH_KV;
pthread_mutex_t HUSH_KV_mutex,KOMODO_CC_mutex;

#define MAX_CURRENCIES 32
char CURRENCIES[][8] = { "USD", "EUR", "JPY", "GBP", "AUD", "CAD", "CHF", "NZD", // major currencies
    "CNY", "RUB", "MXN", "BRL", "INR", "HKD", "TRY", "ZAR", "PLN", "NOK", "SEK", "DKK", "CZK", "HUF", "ILS", "KRW", "MYR", "PHP", "RON", "SGD", "THB", "BGN", "IDR", "HRK",
    "KMD" };

int32_t komodo_baseid(char *origbase)
{
    int32_t i; char base[64];
    for (i=0; origbase[i]!=0&&i<sizeof(base); i++)
        base[i] = toupper((int32_t)(origbase[i] & 0xff));
    base[i] = 0;
    for (i=0; i<=MAX_CURRENCIES; i++)
        if ( strcmp(CURRENCIES[i],base) == 0 )
            return(i);
    //printf("illegal base.(%s) %s\n",origbase,base);
    return(-1);
}

#ifndef SATOSHIDEN
#define SATOSHIDEN ((uint64_t)100000000L)
#endif
uint64_t hush_current_supply(uint32_t nHeight)
{
    uint64_t cur_money;
    int32_t baseid;

    //if ( (baseid = komodo_baseid(SMART_CHAIN_SYMBOL)) >= 0 && baseid < 32 )
    //    cur_money = ASSETCHAINS_GENESISTXVAL + ASSETCHAINS_SUPPLY + nHeight * ASSETCHAINS_REWARD[0] / SATOSHIDEN;
    //else
    {
        // figure out max_money by adding up supply to a maximum of 10,000,000 blocks
        cur_money = (ASSETCHAINS_SUPPLY+1) * SATOSHIDEN + (ASSETCHAINS_MAGIC & 0xffffff) + ASSETCHAINS_GENESISTXVAL;
        if ( ASSETCHAINS_LASTERA == 0 && ASSETCHAINS_REWARD[0] == 0 )
        {
            cur_money += (nHeight * 10000);// / SATOSHIDEN;
        }
        else
        {
            for ( int j = 0; j <= ASSETCHAINS_LASTERA; j++ )
            {
                // if any condition means we have no more rewards, break
                if (j != 0 && (nHeight <= ASSETCHAINS_ENDSUBSIDY[j - 1] || (ASSETCHAINS_ENDSUBSIDY[j - 1] == 0 &&
                    (ASSETCHAINS_REWARD[j] == 0 && (j == ASSETCHAINS_LASTERA || ASSETCHAINS_DECAY[j] != SATOSHIDEN)))))
                    break;

                // add rewards from this era, up to nHeight
                int64_t reward = ASSETCHAINS_REWARD[j];
                
                //fprintf(stderr,"last.%d reward %llu period %llu\n",(int32_t)ASSETCHAINS_LASTERA,(long long)reward,(long long)ASSETCHAINS_HALVING[j]);
                if ( reward > 0 )
                {
                    uint64_t lastEnd = j == 0 ? 0 : ASSETCHAINS_ENDSUBSIDY[j - 1];
                    uint64_t curEnd = ASSETCHAINS_ENDSUBSIDY[j] == 0 ? nHeight : nHeight > ASSETCHAINS_ENDSUBSIDY[j] ? ASSETCHAINS_ENDSUBSIDY[j] : nHeight;
                    uint64_t period = ASSETCHAINS_HALVING[j];
                    if ( period == 0 )
                        period = 210000;
                    uint32_t nSteps = (curEnd - lastEnd) / period;
                    uint32_t modulo = (curEnd - lastEnd) % period;
                    uint64_t decay = ASSETCHAINS_DECAY[j];

                    //fprintf(stderr,"period.%llu cur_money %.8f += %.8f * %d\n",(long long)period,(double)cur_money/COIN,(double)reward/COIN,nHeight);
                    if ( ASSETCHAINS_HALVING[j] == 0 )
                    {
                        // no halving, straight multiply
                        cur_money += reward * (nHeight - 1);
                        //fprintf(stderr,"cur_money %.8f\n",(double)cur_money/COIN);
                    }
                    // if exactly SATOSHIDEN, linear decay to zero or to next era, same as:
                    // (next_era_reward + (starting reward - next_era_reward) / 2) * num_blocks
                    else if ( decay == SATOSHIDEN )
                    {
                        int64_t lowestSubsidy, subsidyDifference, stepDifference, stepTriangle;
                        int64_t denominator, modulo=1;
                        int32_t sign = 1;

                        if ( j == ASSETCHAINS_LASTERA )
                        {
                            subsidyDifference = reward;
                            lowestSubsidy = 0;
                        }
                        else
                        {
                            // Ex: -ac_eras=3 -ac_reward=0,384,24 -ac_end=1440,260640,0 -ac_halving=1,1440,2103840 -ac_decay 100000000,97750000,0
                            subsidyDifference = reward - ASSETCHAINS_REWARD[j + 1];
                            if (subsidyDifference < 0)
                            {
                                sign = -1;
                                subsidyDifference *= sign;
                                lowestSubsidy = reward;
                            }
                            else
                            {
                                lowestSubsidy = ASSETCHAINS_REWARD[j + 1];
                            }
                        }

                        // if we have not finished the current era, we need to caluclate a total as if we are at the end, with the current
                        // subsidy. we will calculate the total of a linear era as follows. Each item represents an area calculation:
                        // a) the rectangle from 0 to the lowest reward in the era * the number of blocks
                        // b) the rectangle of the remainder of blocks from the lowest point of the era to the highest point of the era if any remainder
                        // c) the minor triangle from the start of transition from the lowest point to the start of transition to the highest point
                        // d) one halving triangle (half area of one full step)
                        //
                        // we also need:
                        // e) number of steps = (n - erastart) / halving interval
                        //
                        // the total supply from era start up to height is:
                        // a + b + c + (d * e)

                        // calculate amount in one step's triangular protrusion over minor triangle's hypotenuse
                        denominator = nSteps * period;
                        if ( denominator == 0 )
                            denominator = 1;
                        // difference of one step vs. total
                        stepDifference = (period * subsidyDifference) / denominator;

                        // area == coin holding of one step triangle, protruding from minor triangle's hypotenuse
                        stepTriangle = (period * stepDifference) >> 1;

                        // sign is negative if slope is positive (start is less than end)
                        if (sign < 0)
                        {
                            // use steps minus one for our calculations, and add the potentially partial rectangle
                            // at the end
                            cur_money += stepTriangle * (nSteps - 1);
                            cur_money += stepTriangle * (nSteps - 1) * (nSteps - 1);

                            // difference times number of steps is height of rectangle above lowest subsidy
                            cur_money += modulo * stepDifference * nSteps;
                        }
                        else
                        {
                            // if negative slope, the minor triangle is the full number of steps, as the highest
                            // level step is full. lowest subsidy is just the lowest so far
                            lowestSubsidy = reward - (stepDifference * nSteps);

                            // add the step triangles, one per step
                            cur_money += stepTriangle * nSteps;

                            // add the minor triangle
                            cur_money += stepTriangle * nSteps * nSteps;
                        }

                        // add more for the base rectangle if lowest subsidy is not 0
                        cur_money += lowestSubsidy * (curEnd - lastEnd);
                    } else {
                        for ( int k = lastEnd; k < curEnd; k += period )
                        {
                            cur_money += period * reward;
                            // if zero, we do straight halving
                            reward = decay ? (reward * decay) / SATOSHIDEN : reward >> 1;
                        }
                        cur_money += modulo * reward;
                    }
                }
            }
        }
    }    
    if ( KOMODO_BIT63SET(cur_money) != 0 )
        return(KOMODO_MAXNVALUE);
    if ( ASSETCHAINS_COMMISSION != 0 ) {
        uint64_t newval = (cur_money + (cur_money/COIN * ASSETCHAINS_COMMISSION));
        if ( KOMODO_BIT63SET(newval) != 0 )
            return(KOMODO_MAXNVALUE);
        else if ( newval < cur_money ) // check for underflow
            return(KOMODO_MAXNVALUE);
        return(newval);
    }
    //fprintf(stderr,"cur_money %.8f\n",(double)cur_money/COIN);
    return(cur_money);
}