// Copyright (c) 2018-2020 The Bitcoin Core developers
// Distributed under the MIT software license, see the accompanying
// file COPYING or http://www.opensource.org/licenses/mit-license.php.

#include <interfaces/chain.h>

#include <chain.h>
#include <chainparams.h>
#include <interfaces/handler.h>
#include <interfaces/wallet.h>
#include <net.h>
#include <net_processing.h>
#include <node/coin.h>
#include <node/context.h>
#include <node/transaction.h>
#include <node/ui_interface.h>
#include <policy/fees.h>
#include <policy/policy.h>
#include <policy/rbf.h>
#include <policy/settings.h>
#include <primitives/block.h>
#include <primitives/transaction.h>
#include <rpc/protocol.h>
#include <rpc/server.h>
#include <shutdown.h>
#include <sync.h>
#include <timedata.h>
#include <txmempool.h>
#include <uint256.h>
#include <univalue.h>
#include <util/system.h>
#include <validation.h>
#include <validationinterface.h>

#include <memory>
#include <utility>

namespace interfaces {
namespace {

bool FillBlock(const CBlockIndex* index, const FoundBlock& block, UniqueLock<RecursiveMutex>& lock)
{
    if (!index) return false;
    if (block.m_hash) *block.m_hash = index->GetBlockHash();
    if (block.m_height) *block.m_height = index->nHeight;
    if (block.m_time) *block.m_time = index->GetBlockTime();
    if (block.m_max_time) *block.m_max_time = index->GetBlockTimeMax();
    if (block.m_mtp_time) *block.m_mtp_time = index->GetMedianTimePast();
    if (block.m_data) {
        REVERSE_LOCK(lock);
        if (!ReadBlockFromDisk(*block.m_data, index, Params().GetConsensus())) block.m_data->SetNull();
    }
    return true;
}

class NotificationsProxy : public CValidationInterface
{
public:
    explicit NotificationsProxy(std::shared_ptr<Chain::Notifications> notifications)
        : m_notifications(std::move(notifications)) {}
    virtual ~NotificationsProxy() = default;
    void TransactionAddedToMempool(const CTransactionRef& tx, uint64_t mempool_sequence) override
    {
        m_notifications->transactionAddedToMempool(tx, mempool_sequence);
    }
    void TransactionRemovedFromMempool(const CTransactionRef& tx, MemPoolRemovalReason reason, uint64_t mempool_sequence) override
    {
        m_notifications->transactionRemovedFromMempool(tx, reason, mempool_sequence);
    }
    void BlockConnected(const std::shared_ptr<const CBlock>& block, const CBlockIndex* index) override
    {
        m_notifications->blockConnected(*block, index->nHeight);
    }
    void BlockDisconnected(const std::shared_ptr<const CBlock>& block, const CBlockIndex* index) override
    {
        m_notifications->blockDisconnected(*block, index->nHeight);
    }
    void UpdatedBlockTip(const CBlockIndex* index, const CBlockIndex* fork_index, bool is_ibd) override
    {
        m_notifications->updatedBlockTip();
    }
    void ChainStateFlushed(const CBlockLocator& locator) override { m_notifications->chainStateFlushed(locator); }
    std::shared_ptr<Chain::Notifications> m_notifications;
};

class NotificationsHandlerImpl : public Handler
{
public:
    explicit NotificationsHandlerImpl(std::shared_ptr<Chain::Notifications> notifications)
        : m_proxy(std::make_shared<NotificationsProxy>(std::move(notifications)))
    {
        RegisterSharedValidationInterface(m_proxy);
    }
    ~NotificationsHandlerImpl() override { disconnect(); }
    void disconnect() override
    {
        if (m_proxy) {
            UnregisterSharedValidationInterface(m_proxy);
            m_proxy.reset();
        }
    }
    std::shared_ptr<NotificationsProxy> m_proxy;
};

class RpcHandlerImpl : public Handler
{
public:
    explicit RpcHandlerImpl(const CRPCCommand& command) : m_command(command), m_wrapped_command(&command)
    {
        m_command.actor = [this](const JSONRPCRequest& request, UniValue& result, bool last_handler) {
            if (!m_wrapped_command) return false;
            try {
                return m_wrapped_command->actor(request, result, last_handler);
            } catch (const UniValue& e) {
                // If this is not the last handler and a wallet not found
                // exception was thrown, return false so the next handler can
                // try to handle the request. Otherwise, reraise the exception.
                if (!last_handler) {
                    const UniValue& code = e["code"];
                    if (code.isNum() && code.get_int() == RPC_WALLET_NOT_FOUND) {
                        return false;
                    }
                }
                throw;
            }
        };
        ::tableRPC.appendCommand(m_command.name, &m_command);
    }

    void disconnect() final
    {
        if (m_wrapped_command) {
            m_wrapped_command = nullptr;
            ::tableRPC.removeCommand(m_command.name, &m_command);
        }
    }

    ~RpcHandlerImpl() override { disconnect(); }

    CRPCCommand m_command;
    const CRPCCommand* m_wrapped_command;
};

class ChainImpl : public Chain
{
public:
    explicit ChainImpl(NodeContext& node) : m_node(node) {}
    Optional<int> getHeight() override
    {
        LOCK(::cs_main);
        int height = ::ChainActive().Height();
        if (height >= 0) {
            return height;
        }
        return nullopt;
    }
    Optional<int> getBlockHeight(const uint256& hash) override
    {
        LOCK(::cs_main);
        CBlockIndex* block = LookupBlockIndex(hash);
        if (block && ::ChainActive().Contains(block)) {
            return block->nHeight;
        }
        return nullopt;
    }
    uint256 getBlockHash(int height) override
    {
        LOCK(::cs_main);
        CBlockIndex* block = ::ChainActive()[height];
        assert(block);
        return block->GetBlockHash();
    }
    bool haveBlockOnDisk(int height) override
    {
        LOCK(cs_main);
        CBlockIndex* block = ::ChainActive()[height];
        return block && ((block->nStatus & BLOCK_HAVE_DATA) != 0) && block->nTx > 0;
    }
    Optional<int> findFirstBlockWithTimeAndHeight(int64_t time, int height, uint256* hash) override
    {
        LOCK(cs_main);
        CBlockIndex* block = ::ChainActive().FindEarliestAtLeast(time, height);
        if (block) {
            if (hash) *hash = block->GetBlockHash();
            return block->nHeight;
        }
        return nullopt;
    }
    CBlockLocator getTipLocator() override
    {
        LOCK(cs_main);
        return ::ChainActive().GetLocator();
    }
    bool checkFinalTx(const CTransaction& tx) override
    {
        LOCK(cs_main);
        return CheckFinalTx(tx);
    }
    Optional<int> findLocatorFork(const CBlockLocator& locator) override
    {
        LOCK(cs_main);
        if (CBlockIndex* fork = FindForkInGlobalIndex(::ChainActive(), locator)) {
            return fork->nHeight;
        }
        return nullopt;
    }
    bool findBlock(const uint256& hash, const FoundBlock& block) override
    {
        WAIT_LOCK(cs_main, lock);
        return FillBlock(LookupBlockIndex(hash), block, lock);
    }
    bool findFirstBlockWithTimeAndHeight(int64_t min_time, int min_height, const FoundBlock& block) override
    {
        WAIT_LOCK(cs_main, lock);
        return FillBlock(ChainActive().FindEarliestAtLeast(min_time, min_height), block, lock);
    }
    bool findNextBlock(const uint256& block_hash, int block_height, const FoundBlock& next, bool* reorg) override {
        WAIT_LOCK(cs_main, lock);
        CBlockIndex* block = ChainActive()[block_height];
        if (block && block->GetBlockHash() != block_hash) block = nullptr;
        if (reorg) *reorg = !block;
        return FillBlock(block ? ChainActive()[block_height + 1] : nullptr, next, lock);
    }
    bool findAncestorByHeight(const uint256& block_hash, int ancestor_height, const FoundBlock& ancestor_out) override
    {
        WAIT_LOCK(cs_main, lock);
        if (const CBlockIndex* block = LookupBlockIndex(block_hash)) {
            if (const CBlockIndex* ancestor = block->GetAncestor(ancestor_height)) {
                return FillBlock(ancestor, ancestor_out, lock);
            }
        }
        return FillBlock(nullptr, ancestor_out, lock);
    }
    bool findAncestorByHash(const uint256& block_hash, const uint256& ancestor_hash, const FoundBlock& ancestor_out) override
    {
        WAIT_LOCK(cs_main, lock);
        const CBlockIndex* block = LookupBlockIndex(block_hash);
        const CBlockIndex* ancestor = LookupBlockIndex(ancestor_hash);
        if (block && ancestor && block->GetAncestor(ancestor->nHeight) != ancestor) ancestor = nullptr;
        return FillBlock(ancestor, ancestor_out, lock);
    }
    bool findCommonAncestor(const uint256& block_hash1, const uint256& block_hash2, const FoundBlock& ancestor_out, const FoundBlock& block1_out, const FoundBlock& block2_out) override
    {
        WAIT_LOCK(cs_main, lock);
        const CBlockIndex* block1 = LookupBlockIndex(block_hash1);
        const CBlockIndex* block2 = LookupBlockIndex(block_hash2);
        const CBlockIndex* ancestor = block1 && block2 ? LastCommonAncestor(block1, block2) : nullptr;
        // Using & instead of && below to avoid short circuiting and leaving
        // output uninitialized.
        return FillBlock(ancestor, ancestor_out, lock) & FillBlock(block1, block1_out, lock) & FillBlock(block2, block2_out, lock);
    }
    void findCoins(std::map<COutPoint, Coin>& coins) override { return FindCoins(m_node, coins); }
    double guessVerificationProgress(const uint256& block_hash) override
    {
        LOCK(cs_main);
        return GuessVerificationProgress(Params().TxData(), LookupBlockIndex(block_hash));
    }
    bool hasBlocks(const uint256& block_hash, int min_height, Optional<int> max_height) override
    {
        // hasBlocks returns true if all ancestors of block_hash in specified
        // range have block data (are not pruned), false if any ancestors in
        // specified range are missing data.
        //
        // For simplicity and robustness, min_height and max_height are only
        // used to limit the range, and passing min_height that's too low or
        // max_height that's too high will not crash or change the result.
        LOCK(::cs_main);
        if (CBlockIndex* block = LookupBlockIndex(block_hash)) {
            if (max_height && block->nHeight >= *max_height) block = block->GetAncestor(*max_height);
            for (; block->nStatus & BLOCK_HAVE_DATA; block = block->pprev) {
                // Check pprev to not segfault if min_height is too low
                if (block->nHeight <= min_height || !block->pprev) return true;
            }
        }
        return false;
    }
    RBFTransactionState isRBFOptIn(const CTransaction& tx) override
    {
        if (!m_node.mempool) return IsRBFOptInEmptyMempool(tx);
        LOCK(m_node.mempool->cs);
        return IsRBFOptIn(tx, *m_node.mempool);
    }
    bool hasDescendantsInMempool(const uint256& txid) override
    {
        if (!m_node.mempool) return false;
        LOCK(m_node.mempool->cs);
        auto it = m_node.mempool->GetIter(txid);
        return it && (*it)->GetCountWithDescendants() > 1;
    }
    bool broadcastTransaction(const CTransactionRef& tx,
        const CAmount& max_tx_fee,
        bool relay,
        std::string& err_string) override
    {
        const TransactionError err = BroadcastTransaction(m_node, tx, err_string, max_tx_fee, relay, /*wait_callback*/ false);
        // Chain clients only care about failures to accept the tx to the mempool. Disregard non-mempool related failures.
        // Note: this will need to be updated if BroadcastTransactions() is updated to return other non-mempool failures
        // that Chain clients do not need to know about.
        return TransactionError::OK == err;
    }
    void getTransactionAncestry(const uint256& txid, size_t& ancestors, size_t& descendants) override
    {
        ancestors = descendants = 0;
        if (!m_node.mempool) return;
        m_node.mempool->GetTransactionAncestry(txid, ancestors, descendants);
    }
    void getPackageLimits(unsigned int& limit_ancestor_count, unsigned int& limit_descendant_count) override
    {
        limit_ancestor_count = gArgs.GetArg("-limitancestorcount", DEFAULT_ANCESTOR_LIMIT);
        limit_descendant_count = gArgs.GetArg("-limitdescendantcount", DEFAULT_DESCENDANT_LIMIT);
    }
    bool checkChainLimits(const CTransactionRef& tx) override
    {
        if (!m_node.mempool) return true;
        LockPoints lp;
        CTxMemPoolEntry entry(tx, 0, 0, 0, false, 0, lp);
        CTxMemPool::setEntries ancestors;
        auto limit_ancestor_count = gArgs.GetArg("-limitancestorcount", DEFAULT_ANCESTOR_LIMIT);
        auto limit_ancestor_size = gArgs.GetArg("-limitancestorsize", DEFAULT_ANCESTOR_SIZE_LIMIT) * 1000;
        auto limit_descendant_count = gArgs.GetArg("-limitdescendantcount", DEFAULT_DESCENDANT_LIMIT);
        auto limit_descendant_size = gArgs.GetArg("-limitdescendantsize", DEFAULT_DESCENDANT_SIZE_LIMIT) * 1000;
        std::string unused_error_string;
        LOCK(m_node.mempool->cs);
        return m_node.mempool->CalculateMemPoolAncestors(
            entry, ancestors, limit_ancestor_count, limit_ancestor_size,
            limit_descendant_count, limit_descendant_size, unused_error_string);
    }
    CFeeRate estimateSmartFee(int num_blocks, bool conservative, FeeCalculation* calc) override
    {
        return ::feeEstimator.estimateSmartFee(num_blocks, calc, conservative);
    }
    unsigned int estimateMaxBlocks() override
    {
        return ::feeEstimator.HighestTargetTracked(FeeEstimateHorizon::LONG_HALFLIFE);
    }
    CFeeRate mempoolMinFee() override
    {
        if (!m_node.mempool) return {};
        return m_node.mempool->GetMinFee(gArgs.GetArg("-maxmempool", DEFAULT_MAX_MEMPOOL_SIZE) * 1000000);
    }
    CFeeRate relayMinFee() override { return ::minRelayTxFee; }
    CFeeRate relayIncrementalFee() override { return ::incrementalRelayFee; }
    CFeeRate relayDustFee() override { return ::dustRelayFee; }
    bool havePruned() override
    {
        LOCK(cs_main);
        return ::fHavePruned;
    }
    bool isReadyToBroadcast() override { return !::fImporting && !::fReindex && !isInitialBlockDownload(); }
    bool isInitialBlockDownload() override { return ::ChainstateActive().IsInitialBlockDownload(); }
    bool shutdownRequested() override { return ShutdownRequested(); }
    int64_t getAdjustedTime() override { return GetAdjustedTime(); }
    void initMessage(const std::string& message) override { ::uiInterface.InitMessage(message); }
    void initWarning(const bilingual_str& message) override { InitWarning(message); }
    void initError(const bilingual_str& message) override { InitError(message); }
    void showProgress(const std::string& title, int progress, bool resume_possible) override
    {
        ::uiInterface.ShowProgress(title, progress, resume_possible);
    }
    std::unique_ptr<Handler> handleNotifications(std::shared_ptr<Notifications> notifications) override
    {
        return MakeUnique<NotificationsHandlerImpl>(std::move(notifications));
    }
    void waitForNotificationsIfTipChanged(const uint256& old_tip) override
    {
        if (!old_tip.IsNull()) {
            LOCK(::cs_main);
            if (old_tip == ::ChainActive().Tip()->GetBlockHash()) return;
        }
        SyncWithValidationInterfaceQueue();
    }
    std::unique_ptr<Handler> handleRpc(const CRPCCommand& command) override
    {
        return MakeUnique<RpcHandlerImpl>(command);
    }
    bool rpcEnableDeprecated(const std::string& method) override { return IsDeprecatedRPCEnabled(method); }
    void rpcRunLater(const std::string& name, std::function<void()> fn, int64_t seconds) override
    {
        RPCRunLater(name, std::move(fn), seconds);
    }
    int rpcSerializationFlags() override { return RPCSerializationFlags(); }
    util::SettingsValue getRwSetting(const std::string& name) override
    {
        util::SettingsValue result;
        gArgs.LockSettings([&](const util::Settings& settings) {
            if (const util::SettingsValue* value = util::FindKey(settings.rw_settings, name)) {
                result = *value;
            }
        });
        return result;
    }
    bool updateRwSetting(const std::string& name, const util::SettingsValue& value) override
    {
        gArgs.LockSettings([&](util::Settings& settings) {
            if (value.isNull()) {
                settings.rw_settings.erase(name);
            } else {
                settings.rw_settings[name] = value;
            }
        });
        return gArgs.WriteSettingsFile();
    }
    void requestMempoolTransactions(Notifications& notifications) override
    {
        if (!m_node.mempool) return;
        LOCK2(::cs_main, m_node.mempool->cs);
        for (const CTxMemPoolEntry& entry : m_node.mempool->mapTx) {
            notifications.transactionAddedToMempool(entry.GetSharedTx(), 0 /* mempool_sequence */);
        }
    }
    NodeContext& m_node;
};
} // namespace

std::unique_ptr<Chain> MakeChain(NodeContext& node) { return MakeUnique<ChainImpl>(node); }

} // namespace interfaces