peerplays_migrated/libraries/chain/asset.cpp

/*
 * Copyright (c) 2015, Cryptonomex, Inc.
 * All rights reserved.
 *
 * This source code is provided for evaluation in private test networks only, until September 8, 2015. After this date, this license expires and
 * the code may not be used, modified or distributed for any purpose. Redistribution and use in source and binary forms, with or without modification,
 * are permitted until September 8, 2015, provided that the following conditions are met:
 *
 * 1. The code and/or derivative works are used only for private test networks consisting of no more than 10 P2P nodes.
 *
 * 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.
 */
#include <graphene/chain/asset.hpp>
#include <fc/uint128.hpp>
#include <boost/rational.hpp>

namespace graphene { namespace chain {
      bool operator < ( const asset& a, const asset& b )
      {
         return std::tie( a.asset_id, a.amount ) < std::tie( b.asset_id, b.amount);
      }
      bool operator <= ( const asset& a, const asset& b )
      {
         return std::tie( a.asset_id, a.amount ) <= std::tie( b.asset_id, b.amount);
      }
      bool operator < ( const price& a, const price& b )
      {
         if( a.base.asset_id < b.base.asset_id ) return true;
         if( a.base.asset_id > b.base.asset_id ) return false;
         if( a.quote.asset_id < b.quote.asset_id ) return true;
         if( a.quote.asset_id > b.quote.asset_id ) return false;
         auto amult = fc::uint128(b.quote.amount.value) * a.base.amount.value;
         auto bmult = fc::uint128(a.quote.amount.value) * b.base.amount.value;
         assert( (a.to_real() < b.to_real()) == (amult < bmult) );
         return amult < bmult;
      }
      bool operator <= ( const price& a, const price& b )
      {
         if( a.base.asset_id < b.base.asset_id ) return true;
         if( a.base.asset_id > b.base.asset_id ) return false;
         if( a.quote.asset_id < b.quote.asset_id ) return true;
         if( a.quote.asset_id > b.quote.asset_id ) return false;
         auto amult = fc::uint128(b.quote.amount.value) * a.base.amount.value;
         auto bmult = fc::uint128(a.quote.amount.value) * b.base.amount.value;
         assert( (a.to_real() <= b.to_real()) == (amult <= bmult) );
         return amult <= bmult;
      }
      bool operator == ( const price& a, const price& b )
      {
         if( a.base.asset_id < b.base.asset_id ) return true;
         if( a.base.asset_id > b.base.asset_id ) return false;
         if( a.quote.asset_id < b.quote.asset_id ) return true;
         if( a.quote.asset_id > b.quote.asset_id ) return false;
         auto amult = fc::uint128(a.quote.amount.value) * b.base.amount.value;
         auto bmult = fc::uint128(b.quote.amount.value) * a.base.amount.value;
         return amult == bmult;
      }
      bool operator != ( const price& a, const price& b )
      {
         return !(a==b);
      }

      bool operator >= ( const price& a, const price& b )
      {
         return !(a < b);
      }
      bool operator > ( const price& a, const price& b )
      {
         return !(a <= b);
      }

      asset operator * ( const asset& a, const price& b )
      {
         if( a.asset_id == b.base.asset_id )
         {
            FC_ASSERT( b.base.amount.value > 0 );
            auto result = (fc::uint128(a.amount.value) * b.quote.amount.value)/b.base.amount.value;
            FC_ASSERT( result <= GRAPHENE_MAX_SHARE_SUPPLY );
            return asset( result.to_uint64(), b.quote.asset_id );
         }
         else if( a.asset_id == b.quote.asset_id )
         {
            FC_ASSERT( b.quote.amount.value > 0 );
            auto result = (fc::uint128(a.amount.value) * b.base.amount.value)/b.quote.amount.value;
            FC_ASSERT( result <= GRAPHENE_MAX_SHARE_SUPPLY );
            return asset( result.to_uint64(), b.base.asset_id );
         }
         FC_ASSERT( !"invalid asset * price", "", ("asset",a)("price",b) );
      }

      price operator / ( const asset& base, const asset& quote )
      {
         FC_ASSERT( base.asset_id != quote.asset_id );
         return price{base,quote};
      }
      price price::max( asset_id_type base, asset_id_type quote ) { return asset( share_type(GRAPHENE_MAX_SHARE_SUPPLY), base ) / asset( share_type(1), quote); }
      price price::min( asset_id_type base, asset_id_type quote ) { return asset( 1, base ) / asset( GRAPHENE_MAX_SHARE_SUPPLY, quote); }
 
      /**
       *  The black swan price is defined as debt/collateral, we want to perform a margin call
       *  before debt == collateral.   Given a debt/collateral ratio of 1 USD / CORE and
       *  a maintenance collateral requirement of 2x we can define the call price to be
       *  2 USD / CORE.   
       *
       *  This method divides the collateral by the maintenance collateral ratio to derive
       *  a call price for the given black swan ratio.
       *
       *  There exists some cases where the debt and collateral values are so small that
       *  dividing by the collateral ratio will result in a 0 price or really poor 
       *  rounding errors.   No matter what the collateral part of the price ratio can
       *  never go to 0 and the debt can never go more than GRAPHENE_MAX_SHARE_SUPPLY
       *
       *  CR * DEBT/COLLAT or DEBT/(COLLAT/CR)
       */
      price price::call_price( const asset& debt, const asset& collateral, uint16_t collateral_ratio)
      { try {
         //wdump((debt)(collateral)(collateral_ratio));
         boost::rational<uint64_t> swan(debt.amount.value,collateral.amount.value); 
         boost::rational<uint64_t> ratio( collateral_ratio, GRAPHENE_COLLATERAL_RATIO_DENOM );
         auto cp = swan * ratio;
         return ~(asset( cp.numerator(), debt.asset_id ) / asset( cp.denominator(), collateral.asset_id ));
      } FC_CAPTURE_AND_RETHROW( (debt)(collateral)(collateral_ratio) ) }

      bool price::is_null() const { return *this == price(); }

      void price::validate() const
      { try {
         FC_ASSERT( base.amount > share_type(0) );
         FC_ASSERT( quote.amount > share_type(0) );
         FC_ASSERT( base.asset_id != quote.asset_id );
      } FC_CAPTURE_AND_RETHROW( (base)(quote) ) }

      void price_feed::validate() const
      { try {
         if( !settlement_price.is_null() )
            settlement_price.validate();
         FC_ASSERT( maximum_short_squeeze_ratio >= GRAPHENE_MIN_COLLATERAL_RATIO );
         FC_ASSERT( maximum_short_squeeze_ratio <= GRAPHENE_MAX_COLLATERAL_RATIO );
         FC_ASSERT( maintenance_collateral_ratio >= GRAPHENE_MIN_COLLATERAL_RATIO );
         FC_ASSERT( maintenance_collateral_ratio <= GRAPHENE_MAX_COLLATERAL_RATIO );
         //FC_ASSERT( maintenance_collateral_ratio >= maximum_short_squeeze_ratio );
      } FC_CAPTURE_AND_RETHROW( (*this) ) }

      price price_feed::max_short_squeeze_price()const
      {
         boost::rational<uint64_t> sp( settlement_price.base.amount.value, settlement_price.quote.amount.value ); //debt.amount.value,collateral.amount.value); 
         boost::rational<uint64_t> ratio( GRAPHENE_COLLATERAL_RATIO_DENOM, maximum_short_squeeze_ratio );
         auto cp = sp * ratio;
         return (asset( cp.numerator(), settlement_price.base.asset_id ) / asset( cp.denominator(), settlement_price.quote.asset_id ));
      }

} } // graphene::chain