bitcoin-test 0.1.16-alpha.0

crate::ix!();



//-------------------------------------------[.cpp/bitcoin/src/test/skiplist_tests.cpp]

pub const SKIPLIST_LENGTH: usize = 300000;

#[cfg(test)]
#[fixture(BasicTestingSetup)]
pub mod skiplist_tests {

    #[test] fn skiplist_test() {
        todo!();
        /*
        
            std::vector<CBlockIndex> vIndex(SKIPLIST_LENGTH);

            for (int i=0; i<SKIPLIST_LENGTH; i++) {
                vIndex[i].nHeight = i;
                vIndex[i].pprev = (i == 0) ? nullptr : &vIndex[i - 1];
                vIndex[i].BuildSkip();
            }

            for (int i=0; i<SKIPLIST_LENGTH; i++) {
                if (i > 0) {
                    BOOST_CHECK(vIndex[i].pskip == &vIndex[vIndex[i].pskip->nHeight]);
                    BOOST_CHECK(vIndex[i].pskip->nHeight < i);
                } else {
                    BOOST_CHECK(vIndex[i].pskip == nullptr);
                }
            }

            for (int i=0; i < 1000; i++) {
                int from = InsecureRandRange(SKIPLIST_LENGTH - 1);
                int to = InsecureRandRange(from + 1);

                BOOST_CHECK(vIndex[SKIPLIST_LENGTH - 1].GetAncestor(from) == &vIndex[from]);
                BOOST_CHECK(vIndex[from].GetAncestor(to) == &vIndex[to]);
                BOOST_CHECK(vIndex[from].GetAncestor(0) == vIndex.data());
            }

        */
    }

    #[test] fn getlocator_test() {
        todo!();
        /*
        
            // Build a main chain 100000 blocks long.
            std::vector<uint256> vHashMain(100000);
            std::vector<CBlockIndex> vBlocksMain(100000);
            for (unsigned int i=0; i<vBlocksMain.size(); i++) {
                vHashMain[i] = ArithToUint256(i); // Set the hash equal to the height, so we can quickly check the distances.
                vBlocksMain[i].nHeight = i;
                vBlocksMain[i].pprev = i ? &vBlocksMain[i - 1] : nullptr;
                vBlocksMain[i].phashBlock = &vHashMain[i];
                vBlocksMain[i].BuildSkip();
                BOOST_CHECK_EQUAL((int)UintToArith256(vBlocksMain[i].GetBlockHash()).GetLow64(), vBlocksMain[i].nHeight);
                BOOST_CHECK(vBlocksMain[i].pprev == nullptr || vBlocksMain[i].nHeight == vBlocksMain[i].pprev->nHeight + 1);
            }

            // Build a branch that splits off at block 49999, 50000 blocks long.
            std::vector<uint256> vHashSide(50000);
            std::vector<CBlockIndex> vBlocksSide(50000);
            for (unsigned int i=0; i<vBlocksSide.size(); i++) {
                vHashSide[i] = ArithToUint256(i + 50000 + (arith_uint256(1) << 128)); // Add 1<<128 to the hashes, so GetLow64() still returns the height.
                vBlocksSide[i].nHeight = i + 50000;
                vBlocksSide[i].pprev = i ? &vBlocksSide[i - 1] : (vBlocksMain.data()+49999);
                vBlocksSide[i].phashBlock = &vHashSide[i];
                vBlocksSide[i].BuildSkip();
                BOOST_CHECK_EQUAL((int)UintToArith256(vBlocksSide[i].GetBlockHash()).GetLow64(), vBlocksSide[i].nHeight);
                BOOST_CHECK(vBlocksSide[i].pprev == nullptr || vBlocksSide[i].nHeight == vBlocksSide[i].pprev->nHeight + 1);
            }

            // Build a CChain for the main branch.
            CChain chain;
            chain.SetTip(&vBlocksMain.back());

            // Test 100 random starting points for locators.
            for (int n=0; n<100; n++) {
                int r = InsecureRandRange(150000);
                CBlockIndex* tip = (r < 100000) ? &vBlocksMain[r] : &vBlocksSide[r - 100000];
                CBlockLocator locator = chain.GetLocator(tip);

                // The first result must be the block itself, the last one must be genesis.
                BOOST_CHECK(locator.vHave.front() == tip->GetBlockHash());
                BOOST_CHECK(locator.vHave.back() == vBlocksMain[0].GetBlockHash());

                // Entries 1 through 11 (inclusive) go back one step each.
                for (unsigned int i = 1; i < 12 && i < locator.vHave.size() - 1; i++) {
                    BOOST_CHECK_EQUAL(UintToArith256(locator.vHave[i]).GetLow64(), tip->nHeight - i);
                }

                // The further ones (excluding the last one) go back with exponential steps.
                unsigned int dist = 2;
                for (unsigned int i = 12; i < locator.vHave.size() - 1; i++) {
                    BOOST_CHECK_EQUAL(UintToArith256(locator.vHave[i - 1]).GetLow64() - UintToArith256(locator.vHave[i]).GetLow64(), dist);
                    dist *= 2;
                }
            }

        */
    }

    #[test] fn findearliestatleast_test() {
        todo!();
        /*
        
            std::vector<uint256> vHashMain(100000);
            std::vector<CBlockIndex> vBlocksMain(100000);
            for (unsigned int i=0; i<vBlocksMain.size(); i++) {
                vHashMain[i] = ArithToUint256(i); // Set the hash equal to the height
                vBlocksMain[i].nHeight = i;
                vBlocksMain[i].pprev = i ? &vBlocksMain[i - 1] : nullptr;
                vBlocksMain[i].phashBlock = &vHashMain[i];
                vBlocksMain[i].BuildSkip();
                if (i < 10) {
                    vBlocksMain[i].nTime = i;
                    vBlocksMain[i].nTimeMax = i;
                } else {
                    // randomly choose something in the range [MTP, MTP*2]
                    int64_t medianTimePast = vBlocksMain[i].GetMedianTimePast();
                    int r = InsecureRandRange(medianTimePast);
                    vBlocksMain[i].nTime = r + medianTimePast;
                    vBlocksMain[i].nTimeMax = std::max(vBlocksMain[i].nTime, vBlocksMain[i-1].nTimeMax);
                }
            }
            // Check that we set nTimeMax up correctly.
            unsigned int curTimeMax = 0;
            for (unsigned int i=0; i<vBlocksMain.size(); ++i) {
                curTimeMax = std::max(curTimeMax, vBlocksMain[i].nTime);
                BOOST_CHECK(curTimeMax == vBlocksMain[i].nTimeMax);
            }

            // Build a CChain for the main branch.
            CChain chain;
            chain.SetTip(&vBlocksMain.back());

            // Verify that FindEarliestAtLeast is correct.
            for (unsigned int i=0; i<10000; ++i) {
                // Pick a random element in vBlocksMain.
                int r = InsecureRandRange(vBlocksMain.size());
                int64_t test_time = vBlocksMain[r].nTime;
                CBlockIndex* ret = chain.FindEarliestAtLeast(test_time, 0);
                BOOST_CHECK(ret->nTimeMax >= test_time);
                BOOST_CHECK((ret->pprev==nullptr) || ret->pprev->nTimeMax < test_time);
                BOOST_CHECK(vBlocksMain[r].GetAncestor(ret->nHeight) == ret);
            }

        */
    }

    #[test] fn findearliestatleast_edge_test() {
        todo!();
        /*
        
            std::list<CBlockIndex> blocks;
            for (const unsigned int timeMax : {100, 100, 100, 200, 200, 200, 300, 300, 300}) {
                CBlockIndex* prev = blocks.empty() ? nullptr : &blocks.back();
                blocks.emplace_back();
                blocks.back().nHeight = prev ? prev->nHeight + 1 : 0;
                blocks.back().pprev = prev;
                blocks.back().BuildSkip();
                blocks.back().nTimeMax = timeMax;
            }

            CChain chain;
            chain.SetTip(&blocks.back());

            BOOST_CHECK_EQUAL(chain.FindEarliestAtLeast(50, 0)->nHeight, 0);
            BOOST_CHECK_EQUAL(chain.FindEarliestAtLeast(100, 0)->nHeight, 0);
            BOOST_CHECK_EQUAL(chain.FindEarliestAtLeast(150, 0)->nHeight, 3);
            BOOST_CHECK_EQUAL(chain.FindEarliestAtLeast(200, 0)->nHeight, 3);
            BOOST_CHECK_EQUAL(chain.FindEarliestAtLeast(250, 0)->nHeight, 6);
            BOOST_CHECK_EQUAL(chain.FindEarliestAtLeast(300, 0)->nHeight, 6);
            BOOST_CHECK(!chain.FindEarliestAtLeast(350, 0));

            BOOST_CHECK_EQUAL(chain.FindEarliestAtLeast(0, 0)->nHeight, 0);
            BOOST_CHECK_EQUAL(chain.FindEarliestAtLeast(-1, 0)->nHeight, 0);

            BOOST_CHECK_EQUAL(chain.FindEarliestAtLeast(std::numeric_limits<int64_t>::min(), 0)->nHeight, 0);
            BOOST_CHECK_EQUAL(chain.FindEarliestAtLeast(-int64_t(std::numeric_limits<unsigned int>::max()) - 1, 0)->nHeight, 0);
            BOOST_CHECK(!chain.FindEarliestAtLeast(std::numeric_limits<int64_t>::max(), 0));
            BOOST_CHECK(!chain.FindEarliestAtLeast(std::numeric_limits<unsigned int>::max(), 0));
            BOOST_CHECK(!chain.FindEarliestAtLeast(int64_t(std::numeric_limits<unsigned int>::max()) + 1, 0));

            BOOST_CHECK_EQUAL(chain.FindEarliestAtLeast(0, -1)->nHeight, 0);
            BOOST_CHECK_EQUAL(chain.FindEarliestAtLeast(0, 0)->nHeight, 0);
            BOOST_CHECK_EQUAL(chain.FindEarliestAtLeast(0, 3)->nHeight, 3);
            BOOST_CHECK_EQUAL(chain.FindEarliestAtLeast(0, 8)->nHeight, 8);
            BOOST_CHECK(!chain.FindEarliestAtLeast(0, 9));

            CBlockIndex* ret1 = chain.FindEarliestAtLeast(100, 2);
            BOOST_CHECK(ret1->nTimeMax >= 100 && ret1->nHeight == 2);
            BOOST_CHECK(!chain.FindEarliestAtLeast(300, 9));
            CBlockIndex* ret2 = chain.FindEarliestAtLeast(200, 4);
            BOOST_CHECK(ret2->nTimeMax >= 200 && ret2->nHeight == 4);

        */
    }
}