// Copyright (c) 2018 Kenton Varda and contributors
// Licensed under the MIT License:
//
// Permission is hereby granted, free of charge, to any person obtaining a copy
// of this software and associated documentation files (the "Software"), to deal
// in the Software without restriction, including without limitation the rights
// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
// copies of the Software, and to permit persons to whom the Software is
// furnished to do so, subject to the following conditions:
//
// The above copyright notice and this permission notice shall be included in
// all copies or substantial portions of the Software.
//
// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
// THE SOFTWARE.

#pragma once

#include "common.h"
#include "tuple.h"
#include "vector.h"
#include "function.h"

#if _MSC_VER
// Need _ReadWriteBarrier
#if _MSC_VER < 1910
#include <intrin.h>
#else
#include <intrin0.h>
#endif
#endif

#if KJ_DEBUG_TABLE_IMPL
#include "debug.h"
#define KJ_TABLE_IREQUIRE KJ_REQUIRE
#define KJ_TABLE_IASSERT KJ_ASSERT
#else
#define KJ_TABLE_IREQUIRE KJ_IREQUIRE
#define KJ_TABLE_IASSERT KJ_IASSERT
#endif

KJ_BEGIN_HEADER

namespace kj {

class String;

namespace _ {  // private

template <typename Row>
class TableMapping;
template <typename Row, typename Inner>
using TableIterable = MappedIterable<Inner, TableMapping<Row>>;
template <typename Row, typename Inner>
using TableIterator = MappedIterator<Inner, TableMapping<Row>>;

}  // namespace _ (private)

template <typename Row, typename... Indexes>
class Table {
  // A table with one or more indexes. This is the KJ alternative to map, set, unordered_map, and
  // unordered_set.
  //
  // Unlike a traditional map, which explicitly stores key/value pairs, a Table simply stores
  // "rows" of arbitrary type, and then lets the application specify how these should be indexed.
  // Rows could be indexed on a specific struct field, or they could be indexed based on a computed
  // property. An index could be hash-based or tree-based. Multiple indexes are supported, making
  // it easy to construct a "bimap".
  //
  // The table has deterministic iteration order based on the sequence of insertions and deletions.
  // In the case of only insertions, the iteration order is the order of insertion. If deletions
  // occur, then the current last row is moved to occupy the deleted slot. This determinism is
  // intended to be reliable for the purpose of testing, etc.
  //
  // Each index is a class that looks like:
  //
  //   class Index {
  //   public:
  //     void reserve(size_t size);
  //     // Called when Table::reserve() is called.
  //
  //     SearchParam& keyForRow(const Row& row) const;
  //     // Given a row, return a value appropriate to pass as SearchParams to the other functions.
  //
  //     // In all function calls below, `SearchPrams` refers to whatever parameters the index
  //     // supports for looking up a row in the table.
  //
  //     template <typename... SearchParams>
  //     kj::Maybe<size_t> insert(kj::ArrayPtr<const Row> table, size_t pos, SearchParams&&...);
  //     // Called to indicate that we're about to insert a new row which will match the given
  //     // search parameters, and will be located at the given position. If this index disallows
  //     //  duplicates and some other matching row already exists, then insert() returns the index
  //     // of that row without modifying the index. If the row does not exist, then insert()
  //     // updates the index to note that the new row is located at `pos`. Note that `table[pos]`
  //     // may not be valid yet at the time of this call; the index must go on the search params
  //     // alone.
  //     //
  //     // Insert may throw an exception, in which case the table will roll back insertion.
  //
  //     template <typename... SearchParams>
  //     void erase(kj::ArrayPtr<const Row> table, size_t pos, SearchParams&&...);
  //     // Called to indicate that the index must remove references to row number `pos`. The
  //     // index must not attempt to access table[pos] directly -- in fact, `pos` may be equal to
  //     // `table.size()`, i.e., may be out-of-bounds (this happens when rolling back a failed
  //     // insertion). Instead, the index can use the search params to search for the row -- they
  //     // will either be the same as the params passed to insert(), or will be a single value of
  //     // type `Row&`.
  //     //
  //     // erase() called immediately after a successful insert() must not throw an exception, as
  //     // it may be called during unwind.
  //
  //     template <typename... SearchParams>
  //     void move(kj::ArrayPtr<const Row> table, size_t oldPos, size_t newPos, SearchParams&&...);
  //     // Called when a row is about to be moved from `oldPos` to `newPos` in the table. The
  //     // index should update it to the new location. Neither `table[oldPos]` nor `table[newPos]`
  //     // is valid during the call -- use the search params to find the row. Before this call
  //     // `oldPos` is indexed and `newPos` is not -- after the call, the opposite is true.
  //     //
  //     // This should never throw; if it does the table may be corrupted.
  //
  //     class Iterator;  // Behaves like a C++ iterator over size_t values.
  //     class Iterable;  // Has begin() and end() methods returning iterators.
  //
  //     template <typename... SearchParams>
  //     Maybe<size_t> find(kj::ArrayPtr<const Row> table, SearchParams&&...) const;
  //     // Optional. Implements Table::find<Index>(...).
  //
  //     template <typename... SearchParams>
  //     Iterator seek(kj::ArrayPtr<const Row> table, SearchParams&&...) const;
  //     // Optional. Implements Table::seek<Index>() and Table::range<Index>(...).
  //
  //     Iterator begin() const;
  //     Iterator end() const;
  //     // Optional. Implements Table::ordered<Index>().
  //   };

public:
  Table();
  Table(Indexes&&... indexes);

  void reserve(size_t size);
  // Pre-allocates space for a table of the given size. Normally a Table grows by re-allocating
  // its backing array whenever more space is needed. Reserving in advance avoids redundantly
  // re-allocating as the table grows.

  size_t size() const;
  size_t capacity() const;

  void clear();

  Row* begin();
  Row* end();
  const Row* begin() const;
  const Row* end() const;

  Row& insert(Row&& row);
  Row& insert(const Row& row);
  // Inserts a new row. Throws an exception if this would violate the uniqueness constraints of any
  // of the indexes.

  template <typename Collection>
  void insertAll(Collection&& collection);
  template <typename Collection>
  void insertAll(Collection& collection);
  // Given an iterable collection of Rows, inserts all of them into this table. If the input is
  // an rvalue, the rows will be moved rather than copied.
  //
  // If an insertion throws (e.g. because it violates a uniqueness constraint of some index),
  // subsequent insertions do not occur, but previous insertions remain inserted.

  template <typename UpdateFunc>
  Row& upsert(Row&& row, UpdateFunc&& update);
  template <typename UpdateFunc>
  Row& upsert(const Row& row, UpdateFunc&& update);
  // Tries to insert a new row. However, if a duplicate already exists (according to some index),
  // then update(Row& existingRow, Row&& newRow) is called to modify the existing row.

  template <typename Index, typename... Params>
  kj::Maybe<Row&> find(Params&&... params);
  template <typename Index, typename... Params>
  kj::Maybe<const Row&> find(Params&&... params) const;
  // Using the given index, search for a matching row. What parameters are accepted depends on the
  // index. Not all indexes support this method -- "multimap" indexes may support only range().

  template <typename Index, typename... Params, typename Func>
  Row& findOrCreate(Params&&... params, Func&& createFunc);
  // Like find(), but if the row doesn't exist, call a function to create it. createFunc() must
  // return `Row` or something that implicitly converts to `Row`.
  //
  // NOTE: C++ doesn't actually properly support inferring types of a parameter pack at the
  //   beginning of an argument list, but we define a hack to support it below. Don't worry about
  //   it.

  template <typename Index, typename BeginKey, typename EndKey>
  auto range(BeginKey&& begin, EndKey&& end);
  template <typename Index, typename BeginKey, typename EndKey>
  auto range(BeginKey&& begin, EndKey&& end) const;
  // Using the given index, look up a range of values, returning an iterable. What parameters are
  // accepted depends on the index. Not all indexes support this method (in particular, unordered
  // indexes normally don't).

  template <typename Index>
  _::TableIterable<Row, Index&> ordered();
  template <typename Index>
  _::TableIterable<const Row, const Index&> ordered() const;
  // Returns an iterable over the whole table ordered using the given index. Not all indexes
  // support this method.

  template <typename Index, typename... Params>
  auto seek(Params&&... params);
  template <typename Index, typename... Params>
  auto seek(Params&&... params) const;
  // Takes same parameters as find(), but returns an iterator at the position where the search
  // key should go. That is, this returns an iterator that points to the matching entry or, if
  // there is no matching entry, points at the next entry after the key, in order. Or, if there
  // is no such entry, the returned iterator is the same as ordered().end().
  //
  // seek() is only supported by indexes that support ordered(). It returns the same kind of
  // iterator that ordered() uses.

  template <typename Index, typename... Params>
  bool eraseMatch(Params&&... params);
  // Erase the row that would be matched by `find<Index>(params)`. Returns true if there was a
  // match.

  template <typename Index, typename BeginKey, typename EndKey>
  size_t eraseRange(BeginKey&& begin, EndKey&& end);
  // Erase the row that would be matched by `range<Index>(params)`. Returns the number of
  // elements erased.

  void erase(Row& row);
  // Erase the given row.
  //
  // WARNING: This invalidates all iterators, so you can't iterate over rows and erase them this
  //   way. Use `eraseAll()` for that.

  Row release(Row& row);
  // Remove the given row from the table and return it in one operation.
  //
  // WARNING: This invalidates all iterators, so you can't iterate over rows and release them this
  //   way.

  template <typename Predicate, typename = decltype(instance<Predicate>()(instance<Row&>()))>
  size_t eraseAll(Predicate&& predicate);
  // Erase all rows for which predicate(row) returns true. This scans over the entire table.

  template <typename Collection, typename = decltype(instance<Collection>().begin()), bool = true>
  size_t eraseAll(Collection&& collection);
  // Erase all rows in the given iterable collection of rows. This carefully marks rows for
  // deletion in a first pass then deletes them in a second.

  template <size_t index = 0, typename... Params>
  kj::Maybe<Row&> find(Params&&... params);
  template <size_t index = 0, typename... Params>
  kj::Maybe<const Row&> find(Params&&... params) const;
  template <size_t index = 0, typename... Params, typename Func>
  Row& findOrCreate(Params&&... params, Func&& createFunc);
  template <size_t index = 0, typename BeginKey, typename EndKey>
  auto range(BeginKey&& begin, EndKey&& end);
  template <size_t index = 0, typename BeginKey, typename EndKey>
  auto range(BeginKey&& begin, EndKey&& end) const;
  template <size_t index = 0>
  _::TableIterable<Row, TypeOfIndex<index, Tuple<Indexes...>>&> ordered();
  template <size_t index = 0>
  _::TableIterable<const Row, const TypeOfIndex<index, Tuple<Indexes...>>&> ordered() const;
  template <size_t index = 0, typename... Params>
  auto seek(Params&&... params);
  template <size_t index = 0, typename... Params>
  auto seek(Params&&... params) const;
  template <size_t index = 0, typename... Params>
  bool eraseMatch(Params&&... params);
  template <size_t index = 0, typename BeginKey, typename EndKey>
  size_t eraseRange(BeginKey&& begin, EndKey&& end);
  // Methods which take an index type as a template parameter can also take an index number. This
  // is useful particularly when you have multiple indexes of the same type but different runtime
  // properties. Additionally, you can omit the template parameter altogether to use the first
  // index.

  template <size_t index = 0>
  void verify();
  // Checks the integrity of indexes, throwing an exception if there are any problems. This is
  // intended to be called within the unit test for an index.

  template <typename Index, typename First, typename... Rest>
  Row& findOrCreate(First&& first, Rest&&... rest);
  template <size_t index = 0, typename First, typename... Rest>
  Row& findOrCreate(First&& first, Rest&&... rest);
  // HACK: A parameter pack can only be inferred if it lives at the end of the argument list, so
  //   the findOrCreate() definitions from earlier won't actually work. These ones will, but we
  //   have to do some annoying things inside to regroup the arguments.

private:
  Vector<Row> rows;
  Tuple<Indexes...> indexes;

  template <size_t index = 0, bool final = (index >= sizeof...(Indexes))>
  class Impl;
  template <typename Func, typename... Params>
  class FindOrCreateImpl;

  template <typename ParamsTuple, typename... Params>
  struct FindOrCreateHack;

  void eraseImpl(size_t pos);
  template <typename Collection>
  size_t eraseAllImpl(Collection&& collection);
};

template <typename Callbacks>
class HashIndex;
// A Table index based on a hash table.
//
// This implementation:
// * Is based on linear probing, not chaining. It is important to use a high-quality hash function.
//   Use the KJ hashing library if possible.
// * Is limited to tables of 2^30 rows or less, mainly to allow for tighter packing with 32-bit
//   integers instead of 64-bit.
// * Caches hash codes so that each table row need only be hashed once, and never checks equality
//   unless hash codes have already been determined to be equal.
//
// The `Callbacks` type defines how to compute hash codes and equality. It should be defined like:
//
//   class Callbacks {
//   public:
//     // In this interface, `SearchParams...` means whatever parameters you want to support in
//     // a call to table.find(...). By overloading the calls to support various inputs, you can
//     // affect what table.find(...) accepts.
//
//     SearchParam& keyForRow(const Row& row);
//     // Given a row of the table, return the SearchParams that might be passed to the other
//     // methods to match this row.
//
//     bool matches(const Row&, SearchParams&&...) const;
//     // Returns true if the row on the left matches the search params on the right.
//
//     uint hashCode(SearchParams&&...) const;
//     // Computes the hash code of the given search params. Matching rows (as determined by
//     // matches()) must have the same hash code. Non-matching rows should have different hash
//     // codes, to the maximum extent possible. Non-matching rows with the same hash code hurt
//     // performance.
//   };
//
// If your `Callbacks` type has dynamic state, you may pass its constructor parameters as the
// constructor parameters to `HashIndex`.

template <typename Callbacks>
class TreeIndex;
// A Table index based on a B-tree.
//
// This allows sorted iteration over rows.
//
// The `Callbacks` type defines how to compare rows. It should be defined like:
//
//   class Callbacks {
//   public:
//     // In this interface, `SearchParams...` means whatever parameters you want to support in
//     // a call to table.find(...). By overloading the calls to support various inputs, you can
//     // affect what table.find(...) accepts.
//
//     SearchParam& keyForRow(const Row& row);
//     // Given a row of the table, return the SearchParams that might be passed to the other
//     // methods to match this row.
//
//     bool isBefore(const Row&, SearchParams&&...) const;
//     // Returns true if the row on the left comes before the search params on the right.
//
//     bool matches(const Row&, SearchParams&&...) const;
//     // Returns true if the row "matches" the search params.
//   };

// =======================================================================================
// inline implementation details

namespace _ {  // private

KJ_NORETURN(void throwDuplicateTableRow());

template <typename Dst, typename Src, typename = decltype(instance<Src>().size())>
inline void tryReserveSize(Dst& dst, Src&& src) { dst.reserve(dst.size() + src.size()); }
template <typename... Params>
inline void tryReserveSize(Params&&...) {}
// If `src` has a `.size()` method, call dst.reserve(dst.size() + src.size()).
// Otherwise, do nothing.

template <typename Row>
class TableMapping {
public:
  TableMapping(Row* table): table(table) {}
  Row& map(size_t i) const { return table[i]; }

private:
  Row* table;
};

template <typename Row>
class TableUnmapping {
public:
  TableUnmapping(Row* table): table(table) {}
  size_t map(Row& row) const { return &row - table; }
  size_t map(Row* row) const { return row - table; }

private:
  Row* table;
};

template <typename Iterator>
class IterRange {
public:
  inline IterRange(Iterator b, Iterator e): b(b), e(e) {}

  inline Iterator begin() const { return b; }
  inline Iterator end() const { return e; }
private:
  Iterator b;
  Iterator e;
};

template <typename Iterator>
inline IterRange<Decay<Iterator>> iterRange(Iterator b, Iterator e) {
  return { b, e };
}

}  // namespace _ (private)

template <typename Row, typename... Indexes>
template <size_t index>
class Table<Row, Indexes...>::Impl<index, false> {
public:
  static void reserve(Table<Row, Indexes...>& table, size_t size) {
    get<index>(table.indexes).reserve(size);
    Impl<index + 1>::reserve(table, size);
  }

  static void clear(Table<Row, Indexes...>& table) {
    get<index>(table.indexes).clear();
    Impl<index + 1>::clear(table);
  }

  static kj::Maybe<size_t> insert(Table<Row, Indexes...>& table, size_t pos, Row& row, uint skip) {
    if (skip == index) {
      return Impl<index + 1>::insert(table, pos, row, skip);
    }
    auto& indexObj = get<index>(table.indexes);
    KJ_IF_MAYBE(existing, indexObj.insert(table.rows.asPtr(), pos, indexObj.keyForRow(row))) {
      return *existing;
    }

    bool success = false;
    KJ_DEFER(if (!success) {
      indexObj.erase(table.rows.asPtr(), pos, indexObj.keyForRow(row));
    });
    auto result = Impl<index + 1>::insert(table, pos, row, skip);
    success = result == nullptr;
    return result;
  }

  static void erase(Table<Row, Indexes...>& table, size_t pos, Row& row) {
    auto& indexObj = get<index>(table.indexes);
    indexObj.erase(table.rows.asPtr(), pos, indexObj.keyForRow(row));
    Impl<index + 1>::erase(table, pos, row);
  }

  static void move(Table<Row, Indexes...>& table, size_t oldPos, size_t newPos, Row& row) {
    auto& indexObj = get<index>(table.indexes);
    indexObj.move(table.rows.asPtr(), oldPos, newPos, indexObj.keyForRow(row));
    Impl<index + 1>::move(table, oldPos, newPos, row);
  }
};

template <typename Row, typename... Indexes>
template <size_t index>
class Table<Row, Indexes...>::Impl<index, true> {
public:
  static void reserve(Table<Row, Indexes...>& table, size_t size) {}
  static void clear(Table<Row, Indexes...>& table) {}
  static kj::Maybe<size_t> insert(Table<Row, Indexes...>& table, size_t pos, Row& row, uint skip) {
    return nullptr;
  }
  static void erase(Table<Row, Indexes...>& table, size_t pos, Row& row) {}
  static void move(Table<Row, Indexes...>& table, size_t oldPos, size_t newPos, Row& row) {}
};

template <typename Row, typename... Indexes>
Table<Row, Indexes...>::Table() {}

template <typename Row, typename... Indexes>
Table<Row, Indexes...>::Table(Indexes&&... indexes)
    : indexes(tuple(kj::fwd<Indexes&&>(indexes)...)) {}

template <typename Row, typename... Indexes>
void Table<Row, Indexes...>::reserve(size_t size) {
  rows.reserve(size);
  Impl<>::reserve(*this, size);
}

template <typename Row, typename... Indexes>
size_t Table<Row, Indexes...>::size() const {
  return rows.size();
}
template <typename Row, typename... Indexes>
void Table<Row, Indexes...>::clear() {
  Impl<>::clear(*this);
  rows.clear();
}
template <typename Row, typename... Indexes>
size_t Table<Row, Indexes...>::capacity() const {
  return rows.capacity();
}

template <typename Row, typename... Indexes>
Row* Table<Row, Indexes...>::begin() {
  return rows.begin();
}
template <typename Row, typename... Indexes>
Row* Table<Row, Indexes...>::end() {
  return rows.end();
}
template <typename Row, typename... Indexes>
const Row* Table<Row, Indexes...>::begin() const {
  return rows.begin();
}
template <typename Row, typename... Indexes>
const Row* Table<Row, Indexes...>::end() const {
  return rows.end();
}

template <typename Row, typename... Indexes>
Row& Table<Row, Indexes...>::insert(Row&& row) {
  KJ_IF_MAYBE(existing, Impl<>::insert(*this, rows.size(), row, kj::maxValue)) {
    _::throwDuplicateTableRow();
  } else {
    return rows.add(kj::mv(row));
  }
}
template <typename Row, typename... Indexes>
Row& Table<Row, Indexes...>::insert(const Row& row) {
  return insert(kj::cp(row));
}

template <typename Row, typename... Indexes>
template <typename Collection>
void Table<Row, Indexes...>::insertAll(Collection&& collection) {
  _::tryReserveSize(*this, collection);
  for (auto& row: collection) {
    insert(kj::mv(row));
  }
}

template <typename Row, typename... Indexes>
template <typename Collection>
void Table<Row, Indexes...>::insertAll(Collection& collection) {
  _::tryReserveSize(*this, collection);
  for (auto& row: collection) {
    insert(row);
  }
}

template <typename Row, typename... Indexes>
template <typename UpdateFunc>
Row& Table<Row, Indexes...>::upsert(Row&& row, UpdateFunc&& update) {
  KJ_IF_MAYBE(existing, Impl<>::insert(*this, rows.size(), row, kj::maxValue)) {
    update(rows[*existing], kj::mv(row));
    return rows[*existing];
  } else {
    return rows.add(kj::mv(row));
  }
}
template <typename Row, typename... Indexes>
template <typename UpdateFunc>
Row& Table<Row, Indexes...>::upsert(const Row& row, UpdateFunc&& update) {
  return upsert(kj::cp(row), kj::fwd<UpdateFunc>(update));
}

template <typename Row, typename... Indexes>
template <typename Index, typename... Params>
kj::Maybe<Row&> Table<Row, Indexes...>::find(Params&&... params) {
  return find<indexOfType<Index, Tuple<Indexes...>>()>(kj::fwd<Params>(params)...);
}
template <typename Row, typename... Indexes>
template <size_t index, typename... Params>
kj::Maybe<Row&> Table<Row, Indexes...>::find(Params&&... params) {
  KJ_IF_MAYBE(pos, get<index>(indexes).find(rows.asPtr(), kj::fwd<Params>(params)...)) {
    return rows[*pos];
  } else {
    return nullptr;
  }
}
template <typename Row, typename... Indexes>
template <typename Index, typename... Params>
kj::Maybe<const Row&> Table<Row, Indexes...>::find(Params&&... params) const {
  return find<indexOfType<Index, Tuple<Indexes...>>()>(kj::fwd<Params>(params)...);
}
template <typename Row, typename... Indexes>
template <size_t index, typename... Params>
kj::Maybe<const Row&> Table<Row, Indexes...>::find(Params&&... params) const {
  KJ_IF_MAYBE(pos, get<index>(indexes).find(rows.asPtr(), kj::fwd<Params>(params)...)) {
    return rows[*pos];
  } else {
    return nullptr;
  }
}

template <typename Row, typename... Indexes>
template <typename Func, typename... Params>
class Table<Row, Indexes...>::FindOrCreateImpl {
public:
  template <size_t index>
  static Row& apply(Table<Row, Indexes...>& table, Params&&... params, Func&& createFunc) {
    auto pos = table.rows.size();
    KJ_IF_MAYBE(existing, get<index>(table.indexes).insert(table.rows.asPtr(), pos, params...)) {
      return table.rows[*existing];
    } else {
      bool success = false;
      KJ_DEFER({
        if (!success) {
          get<index>(table.indexes).erase(table.rows.asPtr(), pos, params...);
        }
      });
      auto& newRow = table.rows.add(createFunc());
      KJ_DEFER({
        if (!success) {
          table.rows.removeLast();
        }
      });
      if (Table<Row, Indexes...>::template Impl<>::insert(table, pos, newRow, index) == nullptr) {
        success = true;
      } else {
        _::throwDuplicateTableRow();
      }
      return newRow;
    }
  }
};

template <typename Row, typename... Indexes>
template <typename... T, typename U, typename V, typename... W>
struct Table<Row, Indexes...>::FindOrCreateHack<_::Tuple<T...>, U, V, W...>
    : public FindOrCreateHack<_::Tuple<T..., U>, V, W...> {};
template <typename Row, typename... Indexes>
template <typename... T, typename U>
struct Table<Row, Indexes...>::FindOrCreateHack<_::Tuple<T...>, U>
    : public FindOrCreateImpl<U, T...> {};
// This awful hack works around C++'s lack of support for parameter packs anywhere other than at
// the end of an argument list. We accumulate all of the types except for the last one into a
// Tuple, then forward to FindOrCreateImpl with the last parameter as the Func.

template <typename Row, typename... Indexes>
template <typename Index, typename First, typename... Rest>
Row& Table<Row, Indexes...>::findOrCreate(First&& first, Rest&&... rest) {
  return findOrCreate<indexOfType<Index, Tuple<Indexes...>>()>(
      kj::fwd<First>(first), kj::fwd<Rest>(rest)...);
}
template <typename Row, typename... Indexes>
template <size_t index, typename First, typename... Rest>
Row& Table<Row, Indexes...>::findOrCreate(First&& first, Rest&&... rest) {
  return FindOrCreateHack<_::Tuple<>, First, Rest...>::template apply<index>(
      *this, kj::fwd<First>(first), kj::fwd<Rest>(rest)...);
}

template <typename Row, typename... Indexes>
template <typename Index, typename BeginKey, typename EndKey>
auto Table<Row, Indexes...>::range(BeginKey&& begin, EndKey&& end) {
  return range<indexOfType<Index, Tuple<Indexes...>>()>(
      kj::fwd<BeginKey>(begin), kj::fwd<EndKey>(end));
}
template <typename Row, typename... Indexes>
template <size_t index, typename BeginKey, typename EndKey>
auto Table<Row, Indexes...>::range(BeginKey&& begin, EndKey&& end) {
  auto inner = _::iterRange(get<index>(indexes).seek(rows.asPtr(), kj::fwd<BeginKey>(begin)),
                            get<index>(indexes).seek(rows.asPtr(), kj::fwd<EndKey>(end)));
  return _::TableIterable<Row, decltype(inner)>(kj::mv(inner), rows.begin());
}
template <typename Row, typename... Indexes>
template <typename Index, typename BeginKey, typename EndKey>
auto Table<Row, Indexes...>::range(BeginKey&& begin, EndKey&& end) const {
  return range<indexOfType<Index, Tuple<Indexes...>>()>(
      kj::fwd<BeginKey>(begin), kj::fwd<EndKey>(end));
}
template <typename Row, typename... Indexes>
template <size_t index, typename BeginKey, typename EndKey>
auto Table<Row, Indexes...>::range(BeginKey&& begin, EndKey&& end) const {
  auto inner = _::iterRange(get<index>(indexes).seek(rows.asPtr(), kj::fwd<BeginKey>(begin)),
                            get<index>(indexes).seek(rows.asPtr(), kj::fwd<EndKey>(end)));
  return _::TableIterable<const Row, decltype(inner)>(kj::mv(inner), rows.begin());
}

template <typename Row, typename... Indexes>
template <typename Index>
_::TableIterable<Row, Index&> Table<Row, Indexes...>::ordered() {
  return ordered<indexOfType<Index, Tuple<Indexes...>>()>();
}
template <typename Row, typename... Indexes>
template <size_t index>
_::TableIterable<Row, TypeOfIndex<index, Tuple<Indexes...>>&> Table<Row, Indexes...>::ordered() {
  return { get<index>(indexes), rows.begin() };
}
template <typename Row, typename... Indexes>
template <typename Index>
_::TableIterable<const Row, const Index&> Table<Row, Indexes...>::ordered() const {
  return ordered<indexOfType<Index, Tuple<Indexes...>>()>();
}
template <typename Row, typename... Indexes>
template <size_t index>
_::TableIterable<const Row, const TypeOfIndex<index, Tuple<Indexes...>>&>
Table<Row, Indexes...>::ordered() const {
  return { get<index>(indexes), rows.begin() };
}

template <typename Row, typename... Indexes>
template <typename Index, typename... Params>
auto Table<Row, Indexes...>::seek(Params&&... params) {
  return seek<indexOfType<Index, Tuple<Indexes...>>()>(kj::fwd<Params>(params)...);
}
template <typename Row, typename... Indexes>
template <size_t index, typename... Params>
auto Table<Row, Indexes...>::seek(Params&&... params) {
  auto inner = get<index>(indexes).seek(rows.asPtr(), kj::fwd<Params>(params)...);
  return _::TableIterator<Row, decltype(inner)>(kj::mv(inner), rows.begin());
}
template <typename Row, typename... Indexes>
template <typename Index, typename... Params>
auto Table<Row, Indexes...>::seek(Params&&... params) const {
  return seek<indexOfType<Index, Tuple<Indexes...>>()>(kj::fwd<Params>(params)...);
}
template <typename Row, typename... Indexes>
template <size_t index, typename... Params>
auto Table<Row, Indexes...>::seek(Params&&... params) const {
  auto inner = get<index>(indexes).seek(rows.asPtr(), kj::fwd<Params>(params)...);
  return _::TableIterator<Row, decltype(inner)>(kj::mv(inner), rows.begin());
}

template <typename Row, typename... Indexes>
template <typename Index, typename... Params>
bool Table<Row, Indexes...>::eraseMatch(Params&&... params) {
  return eraseMatch<indexOfType<Index, Tuple<Indexes...>>()>(kj::fwd<Params>(params)...);
}
template <typename Row, typename... Indexes>
template <size_t index, typename... Params>
bool Table<Row, Indexes...>::eraseMatch(Params&&... params) {
  KJ_IF_MAYBE(pos, get<index>(indexes).find(rows.asPtr(), kj::fwd<Params>(params)...)) {
    eraseImpl(*pos);
    return true;
  } else {
    return false;
  }
}

template <typename Row, typename... Indexes>
template <typename Index, typename BeginKey, typename EndKey>
size_t Table<Row, Indexes...>::eraseRange(BeginKey&& begin, EndKey&& end) {
  return eraseRange<indexOfType<Index, Tuple<Indexes...>>()>(
      kj::fwd<BeginKey>(begin), kj::fwd<EndKey>(end));
}
template <typename Row, typename... Indexes>
template <size_t index, typename BeginKey, typename EndKey>
size_t Table<Row, Indexes...>::eraseRange(BeginKey&& begin, EndKey&& end) {
  auto inner = _::iterRange(get<index>(indexes).seek(rows.asPtr(), kj::fwd<BeginKey>(begin)),
                            get<index>(indexes).seek(rows.asPtr(), kj::fwd<EndKey>(end)));
  return eraseAllImpl(inner);
}

template <typename Row, typename... Indexes>
template <size_t index>
void Table<Row, Indexes...>::verify() {
  get<index>(indexes).verify(rows.asPtr());
}

template <typename Row, typename... Indexes>
void Table<Row, Indexes...>::erase(Row& row) {
  KJ_TABLE_IREQUIRE(&row >= rows.begin() && &row < rows.end(), "row is not a member of this table");
  eraseImpl(&row - rows.begin());
}
template <typename Row, typename... Indexes>
void Table<Row, Indexes...>::eraseImpl(size_t pos) {
  Impl<>::erase(*this, pos, rows[pos]);
  size_t back = rows.size() - 1;
  if (pos != back) {
    Impl<>::move(*this, back, pos, rows[back]);
    rows[pos] = kj::mv(rows[back]);
  }
  rows.removeLast();
}

template <typename Row, typename... Indexes>
Row Table<Row, Indexes...>::release(Row& row) {
  KJ_TABLE_IREQUIRE(&row >= rows.begin() && &row < rows.end(), "row is not a member of this table");
  size_t pos = &row - rows.begin();
  Impl<>::erase(*this, pos, row);
  Row result = kj::mv(row);
  size_t back = rows.size() - 1;
  if (pos != back) {
    Impl<>::move(*this, back, pos, rows[back]);
    row = kj::mv(rows[back]);
  }
  rows.removeLast();
  return result;
}

template <typename Row, typename... Indexes>
template <typename Predicate, typename>
size_t Table<Row, Indexes...>::eraseAll(Predicate&& predicate) {
  size_t count = 0;
  for (size_t i = 0; i < rows.size();) {
    if (predicate(rows[i])) {
      eraseImpl(i);
      ++count;
      // eraseImpl() replaces the erased row with the last row, so don't increment i here; repeat
      // with the same i.
    } else {
      ++i;
    }
  }
  return count;
}

template <typename Row, typename... Indexes>
template <typename Collection, typename, bool>
size_t Table<Row, Indexes...>::eraseAll(Collection&& collection) {
  return eraseAllImpl(MappedIterable<Collection&, _::TableUnmapping<Row>>(
      collection, rows.begin()));
}

template <typename Row, typename... Indexes>
template <typename Collection>
size_t Table<Row, Indexes...>::eraseAllImpl(Collection&& collection) {
  // We need to transform the collection of row numbers into a sequence of erasures, accounting
  // for the fact that each erasure re-positions the last row into its slot.
  Vector<size_t> erased;
  _::tryReserveSize(erased, collection);
  for (size_t pos: collection) {
    while (pos >= rows.size() - erased.size()) {
      // Oops, the next item to be erased is already scheduled to be moved to a different location
      // due to a previous erasure. Figure out where it will be at this point.
      size_t erasureNumber = rows.size() - pos - 1;
      pos = erased[erasureNumber];
    }
    erased.add(pos);
  }

  // Now we can execute the sequence of erasures.
  for (size_t pos: erased) {
    eraseImpl(pos);
  }

  return erased.size();
}

// -----------------------------------------------------------------------------
// Hash table index

namespace _ {  // private

void logHashTableInconsistency();

struct HashBucket {
  uint hash;
  uint value;

  HashBucket() = default;
  HashBucket(uint hash, uint pos)
      : hash(hash), value(pos + 2) {}

  inline bool isEmpty() const { return value == 0; }
  inline bool isErased() const { return value == 1; }
  inline bool isOccupied() const { return value >= 2; }
  template <typename Row>
  inline Row& getRow(ArrayPtr<Row> table) const { return table[getPos()]; }
  template <typename Row>
  inline const Row& getRow(ArrayPtr<const Row> table) const { return table[getPos()]; }
  inline bool isPos(uint pos) const { return pos + 2 == value; }
  inline uint getPos() const {
    KJ_TABLE_IASSERT(value >= 2);
    return value - 2;
  }
  inline void setEmpty() { value = 0; }
  inline void setErased() { value = 1; }
  inline void setPos(uint pos) { value = pos + 2; }
};

inline size_t probeHash(const kj::Array<HashBucket>& buckets, size_t i) {
  // TODO(perf): Is linear probing OK or should we do something fancier?
  if (++i == buckets.size()) {
    return 0;
  } else {
    return i;
  }
}

kj::Array<HashBucket> rehash(kj::ArrayPtr<const HashBucket> oldBuckets, size_t targetSize);

uint chooseBucket(uint hash, uint count);

}  // namespace _ (private)

template <typename Callbacks>
class HashIndex {
public:
  HashIndex() = default;
  template <typename... Params>
  HashIndex(Params&&... params): cb(kj::fwd<Params>(params)...) {}

  size_t capacity() {
    // This method is for testing.
    return buckets.size();
  }

  void reserve(size_t size) {
    if (buckets.size() < size * 2) {
      rehash(size);
    }
  }

  void clear() {
    erasedCount = 0;
    if (buckets.size() > 0) memset(buckets.begin(), 0, buckets.asBytes().size());
  }

  template <typename Row>
  decltype(auto) keyForRow(Row&& row) const {
    return cb.keyForRow(kj::fwd<Row>(row));
  }

  template <typename Row, typename... Params>
  kj::Maybe<size_t> insert(kj::ArrayPtr<Row> table, size_t pos, Params&&... params) {
    if (buckets.size() * 2 < (table.size() + 1 + erasedCount) * 3) {
      // Load factor is more than 2/3, let's rehash so that it's 1/3, i.e. double the buckets.
      // Note that rehashing also cleans up erased entries, so we may not actually be doubling if
      // there are a lot of erasures. Nevertheless, this gives us amortized constant time -- it
      // would take at least O(table.size()) more insertions (whether or not erasures occur)
      // before another rehash is needed.
      rehash((table.size() + 1) * 3);
    }

    uint hashCode = cb.hashCode(params...);
    Maybe<_::HashBucket&> erasedSlot;
    for (uint i = _::chooseBucket(hashCode, buckets.size());; i = _::probeHash(buckets, i)) {
      auto& bucket = buckets[i];
      if (bucket.isEmpty()) {
        // no duplicates found
        KJ_IF_MAYBE(s, erasedSlot) {
          --erasedCount;
          *s = { hashCode, uint(pos) };
        } else {
          bucket = { hashCode, uint(pos) };
        }
        return nullptr;
      } else if (bucket.isErased()) {
        // We can fill in the erased slot. However, we have to keep searching to make sure there
        // are no duplicates before we do that.
        if (erasedSlot == nullptr) {
          erasedSlot = bucket;
        }
      } else if (bucket.hash == hashCode &&
                 cb.matches(bucket.getRow(table), params...)) {
        // duplicate row
        return size_t(bucket.getPos());
      }
    }
  }

  template <typename Row, typename... Params>
  void erase(kj::ArrayPtr<Row> table, size_t pos, Params&&... params) {
    uint hashCode = cb.hashCode(params...);
    for (uint i = _::chooseBucket(hashCode, buckets.size());; i = _::probeHash(buckets, i)) {
      auto& bucket = buckets[i];
      if (bucket.isPos(pos)) {
        // found it
        ++erasedCount;
        bucket.setErased();
        return;
      } else if (bucket.isEmpty()) {
        // can't find the bucket, something is very wrong
        _::logHashTableInconsistency();
        return;
      }
    }
  }

  template <typename Row, typename... Params>
  void move(kj::ArrayPtr<Row> table, size_t oldPos, size_t newPos, Params&&... params) {
    uint hashCode = cb.hashCode(params...);
    for (uint i = _::chooseBucket(hashCode, buckets.size());; i = _::probeHash(buckets, i)) {
      auto& bucket = buckets[i];
      if (bucket.isPos(oldPos)) {
        // found it
        bucket.setPos(newPos);
        return;
      } else if (bucket.isEmpty()) {
        // can't find the bucket, something is very wrong
        _::logHashTableInconsistency();
        return;
      }
    }
  }

  template <typename Row, typename... Params>
  Maybe<size_t> find(kj::ArrayPtr<Row> table, Params&&... params) const {
    if (buckets.size() == 0) return nullptr;

    uint hashCode = cb.hashCode(params...);
    for (uint i = _::chooseBucket(hashCode, buckets.size());; i = _::probeHash(buckets, i)) {
      auto& bucket = buckets[i];
      if (bucket.isEmpty()) {
        // not found.
        return nullptr;
      } else if (bucket.isErased()) {
        // skip, keep searching
      } else if (bucket.hash == hashCode &&
                 cb.matches(bucket.getRow(table), params...)) {
        // found
        return size_t(bucket.getPos());
      }
    }
  }

  // No begin() nor end() because hash tables are not usefully ordered.

private:
  Callbacks cb;
  size_t erasedCount = 0;
  Array<_::HashBucket> buckets;

  void rehash(size_t targetSize) {
    buckets = _::rehash(buckets, targetSize);
    erasedCount = 0;
  }
};

// -----------------------------------------------------------------------------
// BTree index

namespace _ {  // private

KJ_ALWAYS_INLINE(void compilerBarrier());
void compilerBarrier() {
  // Make sure that reads occurring before this call cannot be re-ordered to happen after
  // writes that occur after this call. We need this in a couple places below to prevent C++
  // strict aliasing rules from breaking things.
#if _MSC_VER
  _ReadWriteBarrier();
#else
  __asm__ __volatile__("": : :"memory");
#endif
}

template <typename T>
inline void acopy(T* to, T* from, size_t size) { memcpy(to, from, size * sizeof(T)); }
template <typename T>
inline void amove(T* to, T* from, size_t size) { memmove(to, from, size * sizeof(T)); }
template <typename T>
inline void azero(T* ptr, size_t size) { memset(ptr, 0, size * sizeof(T)); }
// memcpy/memmove/memset variants that count size in elements, not bytes.
//
// TODO(cleanup): These are generally useful, put them somewhere.

class BTreeImpl {
public:
  class Iterator;
  class MaybeUint;
  struct NodeUnion;
  struct Leaf;
  struct Parent;
  struct Freelisted;

  class SearchKey {
    // Passed to methods that need to search the tree. This class allows most of the B-tree
    // implementation to be kept out of templates, avoiding code bloat, at the cost of some
    // performance trade-off. In order to lessen the performance cost of virtual calls, we design
    // this interface so that it only needs to be called once per tree node, rather than once per
    // comparison.

  public:
    virtual uint search(const Parent& parent) const = 0;
    virtual uint search(const Leaf& leaf) const = 0;
    // Binary search for the first key/row in the parent/leaf that is equal to or comes after the
    // search key.

    virtual bool isAfter(uint rowIndex) const = 0;
    // Returns true if the key comes after the value in the given row.
  };

  BTreeImpl();
  ~BTreeImpl() noexcept(false);

  KJ_DISALLOW_COPY(BTreeImpl);
  BTreeImpl(BTreeImpl&& other);
  BTreeImpl& operator=(BTreeImpl&& other);

  void logInconsistency() const;

  void reserve(size_t size);

  void clear();

  Iterator begin() const;
  Iterator end() const;

  Iterator search(const SearchKey& searchKey) const;
  // Find the "first" row (in sorted order) for which searchKey.isAfter(rowNumber) returns true.

  Iterator insert(const SearchKey& searchKey);
  // Like search() but ensures that there is room in the leaf node to insert a new row.

  void erase(uint row, const SearchKey& searchKey);
  // Erase the given row number from the tree. searchKey.isAfter() returns true for the given row
  // and all rows after it.

  void renumber(uint oldRow, uint newRow, const SearchKey& searchKey);
  // Renumber the given row from oldRow to newRow. searchKey.isAfter() returns true for oldRow and
  // all rows after it. (It will not be called on newRow.)

  void verify(size_t size, FunctionParam<bool(uint, uint)>);

private:
  NodeUnion* tree;        // allocated with aligned_alloc aligned to cache lines
  uint treeCapacity;
  uint height;            // height of *parent* tree -- does not include the leaf level
  uint freelistHead;
  uint freelistSize;
  uint beginLeaf;
  uint endLeaf;
  void growTree(uint minCapacity = 0);

  template <typename T>
  struct AllocResult;

  template <typename T>
  inline AllocResult<T> alloc();
  inline void free(uint pos);

  inline uint split(Parent& src, uint srcPos, Parent& dst, uint dstPos);
  inline uint split(Leaf& dst, uint dstPos, Leaf& src, uint srcPos);
  inline void merge(Parent& dst, uint dstPos, uint pivot, Parent& src);
  inline void merge(Leaf& dst, uint dstPos, uint pivot, Leaf& src);
  inline void move(Parent& dst, uint dstPos, Parent& src);
  inline void move(Leaf& dst, uint dstPos, Leaf& src);
  inline void rotateLeft(
      Parent& left, Parent& right, Parent& parent, uint indexInParent, MaybeUint*& fixup);
  inline void rotateLeft(
      Leaf& left, Leaf& right, Parent& parent, uint indexInParent, MaybeUint*& fixup);
  inline void rotateRight(Parent& left, Parent& right, Parent& parent, uint indexInParent);
  inline void rotateRight(Leaf& left, Leaf& right, Parent& parent, uint indexInParent);

  template <typename Node>
  inline Node& insertHelper(const SearchKey& searchKey,
      Node& node, Parent* parent, uint indexInParent, uint pos);

  template <typename Node>
  inline Node& eraseHelper(
      Node& node, Parent* parent, uint indexInParent, uint pos, MaybeUint*& fixup);

  size_t verifyNode(size_t size, FunctionParam<bool(uint, uint)>&,
                    uint pos, uint height, MaybeUint maxRow);

  static const NodeUnion EMPTY_NODE;
};

class BTreeImpl::MaybeUint {
  // A nullable uint, using the value zero to mean null and shifting all other values up by 1.
public:
  MaybeUint() = default;
  inline MaybeUint(uint i): i(i - 1) {}
  inline MaybeUint(decltype(nullptr)): i(0) {}

  inline bool operator==(decltype(nullptr)) const { return i == 0; }
  inline bool operator==(uint j) const { return i == j + 1; }
  inline bool operator==(const MaybeUint& other) const { return i == other.i; }
  inline bool operator!=(decltype(nullptr)) const { return i != 0; }
  inline bool operator!=(uint j) const { return i != j + 1; }
  inline bool operator!=(const MaybeUint& other) const { return i != other.i; }

  inline MaybeUint& operator=(decltype(nullptr)) { i = 0; return *this; }
  inline MaybeUint& operator=(uint j) { i = j + 1; return *this; }

  inline uint operator*() const { KJ_TABLE_IREQUIRE(i != 0); return i - 1; }

  template <typename Func>
  inline bool check(Func& func) const { return i != 0 && func(i - 1); }
  // Equivalent to *this != nullptr && func(**this)

  kj::String toString() const;

private:
  uint i;
};

struct BTreeImpl::Leaf {
  uint next;
  uint prev;
  // Pointers to next and previous nodes at the same level, used for fast iteration.

  static constexpr size_t NROWS = 14;
  MaybeUint rows[NROWS];
  // Pointers to table rows, offset by 1 so that 0 is an empty value.

  inline bool isFull() const;
  inline bool isMostlyFull() const;
  inline bool isHalfFull() const;

  inline void insert(uint i, uint newRow) {
    KJ_TABLE_IREQUIRE(rows[Leaf::NROWS - 1] == nullptr);  // check not full

    amove(rows + i + 1, rows + i, Leaf::NROWS - (i + 1));
    rows[i] = newRow;
  }

  inline void erase(uint i) {
    KJ_TABLE_IREQUIRE(rows[0] != nullptr);  // check not empty

    amove(rows + i, rows + i + 1, Leaf::NROWS - (i + 1));
    rows[Leaf::NROWS - 1] = nullptr;
  }

  inline uint size() const {
    static_assert(Leaf::NROWS == 14, "logic here needs updating");

    // Binary search for first empty element in `rows`, or return 14 if no empty elements. We do
    // this in a branch-free manner. Since there are 15 possible results (0 through 14, inclusive),
    // this isn't a perfectly balanced binary search. We carefully choose the split points so that
    // there's no way we'll try to dereference row[14] or later (which would be a buffer overflow).
    uint i = (rows[6] != nullptr) * 7;
    i += (rows[i + 3] != nullptr) * 4;
    i += (rows[i + 1] != nullptr) * 2;
    i += (rows[i    ] != nullptr);
    return i;
  }

  template <typename Func>
  inline uint binarySearch(Func& predicate) const {
    // Binary search to find first row for which predicate(row) is false.

    static_assert(Leaf::NROWS == 14, "logic here needs updating");

    // See comments in size().
    uint i = (rows[6].check(predicate)) * 7;
    i += (rows[i + 3].check(predicate)) * 4;
    i += (rows[i + 1].check(predicate)) * 2;
    if (i != 6) {  // don't redundantly check row 6
      i += (rows[i    ].check(predicate));
    }
    return i;
  }
};

struct BTreeImpl::Parent {
  uint unused;
  // Not used. May be arbitrarily non-zero due to overlap with Freelisted::nextOffset.

  static constexpr size_t NKEYS = 7;
  MaybeUint keys[NKEYS];
  // Pointers to table rows, offset by 1 so that 0 is an empty value.
  //
  // Each keys[i] specifies the table row which is the "last" row found under children[i].
  //
  // Note that `keys` has size 7 but `children` has size 8. `children[8]`'s "last row" is not
  // recorded here, because the Parent's Parent records it instead. (Or maybe the Parent's Parent's
  // Parent, if this Parent is `children[8]` of its own Parent. And so on.)

  static constexpr size_t NCHILDREN = NKEYS + 1;
  uint children[NCHILDREN];
  // Pointers to children. Not offset because the root is always at position 0, and a pointer
  // to the root would be nonsensical.

  inline bool isFull() const;
  inline bool isMostlyFull() const;
  inline bool isHalfFull() const;
  inline void initRoot(uint key, uint leftChild, uint rightChild);
  inline void insertAfter(uint i, uint splitKey, uint child);
  inline void eraseAfter(uint i);

  inline uint keyCount() const {
    static_assert(Parent::NKEYS == 7, "logic here needs updating");

    // Binary search for first empty element in `keys`, or return 7 if no empty elements. We do
    // this in a branch-free manner. Since there are 8 possible results (0 through 7, inclusive),
    // this is a perfectly balanced binary search.
    uint i = (keys[3] != nullptr) * 4;
    i += (keys[i + 1] != nullptr) * 2;
    i += (keys[i    ] != nullptr);
    return i;
  }

  template <typename Func>
  inline uint binarySearch(Func& predicate) const {
    // Binary search to find first key for which predicate(key) is false.

    static_assert(Parent::NKEYS == 7, "logic here needs updating");

    // See comments in size().
    uint i = (keys[3].check(predicate)) * 4;
    i += (keys[i + 1].check(predicate)) * 2;
    i += (keys[i    ].check(predicate));
    return i;
  }
};

struct BTreeImpl::Freelisted {
  int nextOffset;
  // The next node in the freelist is at: this + 1 + nextOffset
  //
  // Hence, newly-allocated space can initialize this to zero.

  uint zero[15];
  // Freelisted entries are always zero'd.
};

struct BTreeImpl::NodeUnion {
  union {
    Freelisted freelist;
    // If this node is in the freelist.

    Leaf leaf;
    // If this node is a leaf.

    Parent parent;
    // If this node is not a leaf.
  };

  inline operator Leaf&() { return leaf; }
  inline operator Parent&() { return parent; }
  inline operator const Leaf&() const { return leaf; }
  inline operator const Parent&() const { return parent; }
};

static_assert(sizeof(BTreeImpl::Parent) == 64,
    "BTreeImpl::Parent should be optimized to fit a cache line");
static_assert(sizeof(BTreeImpl::Leaf) == 64,
    "BTreeImpl::Leaf should be optimized to fit a cache line");
static_assert(sizeof(BTreeImpl::Freelisted) == 64,
    "BTreeImpl::Freelisted should be optimized to fit a cache line");
static_assert(sizeof(BTreeImpl::NodeUnion) == 64,
    "BTreeImpl::NodeUnion should be optimized to fit a cache line");

bool BTreeImpl::Leaf::isFull() const {
  return rows[Leaf::NROWS - 1] != nullptr;
}
bool BTreeImpl::Leaf::isMostlyFull() const {
  return rows[Leaf::NROWS / 2] != nullptr;
}
bool BTreeImpl::Leaf::isHalfFull() const {
  KJ_TABLE_IASSERT(rows[Leaf::NROWS / 2 - 1] != nullptr);
  return rows[Leaf::NROWS / 2] == nullptr;
}

bool BTreeImpl::Parent::isFull() const {
  return keys[Parent::NKEYS - 1] != nullptr;
}
bool BTreeImpl::Parent::isMostlyFull() const {
  return keys[Parent::NKEYS / 2] != nullptr;
}
bool BTreeImpl::Parent::isHalfFull() const {
  KJ_TABLE_IASSERT(keys[Parent::NKEYS / 2 - 1] != nullptr);
  return keys[Parent::NKEYS / 2] == nullptr;
}

class BTreeImpl::Iterator {
public:
  Iterator(const NodeUnion* tree, const Leaf* leaf, uint row)
      : tree(tree), leaf(leaf), row(row) {}

  size_t operator*() const {
    KJ_TABLE_IREQUIRE(row < Leaf::NROWS && leaf->rows[row] != nullptr,
        "tried to dereference end() iterator");
    return *leaf->rows[row];
  }

  inline Iterator& operator++() {
    KJ_TABLE_IREQUIRE(leaf->rows[row] != nullptr, "B-tree iterator overflow");
    ++row;
    if (row >= Leaf::NROWS || leaf->rows[row] == nullptr) {
      if (leaf->next == 0) {
        // at end; stay on current leaf
      } else {
        leaf = &tree[leaf->next].leaf;
        row = 0;
      }
    }
    return *this;
  }
  inline Iterator operator++(int) {
    Iterator other = *this;
    ++*this;
    return other;
  }

  inline Iterator& operator--() {
    if (row == 0) {
      KJ_TABLE_IREQUIRE(leaf->prev != 0, "B-tree iterator underflow");
      leaf = &tree[leaf->prev].leaf;
      row = leaf->size() - 1;
    } else {
      --row;
    }
    return *this;
  }
  inline Iterator operator--(int) {
    Iterator other = *this;
    --*this;
    return other;
  }

  inline bool operator==(const Iterator& other) const {
    return leaf == other.leaf && row == other.row;
  }
  inline bool operator!=(const Iterator& other) const {
    return leaf != other.leaf || row != other.row;
  }

  bool isEnd() {
    return row == Leaf::NROWS || leaf->rows[row] == nullptr;
  }

  void insert(BTreeImpl& impl, uint newRow) {
    KJ_TABLE_IASSERT(impl.tree == tree);
    const_cast<Leaf*>(leaf)->insert(row, newRow);
  }

  void erase(BTreeImpl& impl) {
    KJ_TABLE_IASSERT(impl.tree == tree);
    const_cast<Leaf*>(leaf)->erase(row);
  }

  void replace(BTreeImpl& impl, uint newRow) {
    KJ_TABLE_IASSERT(impl.tree == tree);
    const_cast<Leaf*>(leaf)->rows[row] = newRow;
  }

private:
  const NodeUnion* tree;
  const Leaf* leaf;
  uint row;
};

inline BTreeImpl::Iterator BTreeImpl::begin() const {
  return { tree, &tree[beginLeaf].leaf, 0 };
}
inline BTreeImpl::Iterator BTreeImpl::end() const {
  auto& leaf = tree[endLeaf].leaf;
  return { tree, &leaf, leaf.size() };
}

}  // namespace _ (private)

template <typename Callbacks>
class TreeIndex {
public:
  TreeIndex() = default;
  template <typename... Params>
  TreeIndex(Params&&... params): cb(kj::fwd<Params>(params)...) {}

  template <typename Row>
  void verify(kj::ArrayPtr<Row> table) {
    impl.verify(table.size(), [&](uint i, uint j) {
      return cb.isBefore(table[i], table[j]);
    });
  }

  inline void reserve(size_t size) { impl.reserve(size); }
  inline void clear() { impl.clear(); }
  inline auto begin() const { return impl.begin(); }
  inline auto end() const { return impl.end(); }

  template <typename Row>
  decltype(auto) keyForRow(Row&& row) const {
    return cb.keyForRow(kj::fwd<Row>(row));
  }

  template <typename Row, typename... Params>
  kj::Maybe<size_t> insert(kj::ArrayPtr<Row> table, size_t pos, Params&&... params) {
    auto iter = impl.insert(searchKey(table, params...));

    if (!iter.isEnd() && cb.matches(table[*iter], params...)) {
      return *iter;
    } else {
      iter.insert(impl, pos);
      return nullptr;
    }
  }

  template <typename Row, typename... Params>
  void erase(kj::ArrayPtr<Row> table, size_t pos, Params&&... params) {
    impl.erase(pos, searchKeyForErase(table, pos, params...));
  }

  template <typename Row, typename... Params>
  void move(kj::ArrayPtr<Row> table, size_t oldPos, size_t newPos, Params&&... params) {
    impl.renumber(oldPos, newPos, searchKey(table, params...));
  }

  template <typename Row, typename... Params>
  Maybe<size_t> find(kj::ArrayPtr<Row> table, Params&&... params) const {
    auto iter = impl.search(searchKey(table, params...));

    if (!iter.isEnd() && cb.matches(table[*iter], params...)) {
      return size_t(*iter);
    } else {
      return nullptr;
    }
  }

  template <typename Row, typename... Params>
  _::BTreeImpl::Iterator seek(kj::ArrayPtr<Row> table, Params&&... params) const {
    return impl.search(searchKey(table, params...));
  }

private:
  Callbacks cb;
  _::BTreeImpl impl;

  template <typename Predicate>
  class SearchKeyImpl: public _::BTreeImpl::SearchKey {
  public:
    SearchKeyImpl(Predicate&& predicate)
        : predicate(kj::mv(predicate)) {}

    uint search(const _::BTreeImpl::Parent& parent) const override {
      return parent.binarySearch(predicate);
    }
    uint search(const _::BTreeImpl::Leaf& leaf) const override {
      return leaf.binarySearch(predicate);
    }
    bool isAfter(uint rowIndex) const override {
      return predicate(rowIndex);
    }

  private:
    Predicate predicate;
  };

  template <typename Row, typename... Params>
  inline auto searchKey(kj::ArrayPtr<Row>& table, Params&... params) const {
    auto predicate = [&](uint i) { return cb.isBefore(table[i], params...); };
    return SearchKeyImpl<decltype(predicate)>(kj::mv(predicate));
  }

  template <typename Row, typename... Params>
  inline auto searchKeyForErase(kj::ArrayPtr<Row>& table, uint pos, Params&... params) const {
    // When erasing, the table entry for the erased row may already be invalid, so we must avoid
    // accessing it.
    auto predicate = [&,pos](uint i) {
      return i != pos && cb.isBefore(table[i], params...);
    };
    return SearchKeyImpl<decltype(predicate)>(kj::mv(predicate));
  }
};

// -----------------------------------------------------------------------------
// Insertion order index

class InsertionOrderIndex {
  // Table index which allows iterating over elements in order of insertion. This index cannot
  // be used for Table::find(), but can be used for Table::ordered().

  struct Link;
public:
  InsertionOrderIndex();
  InsertionOrderIndex(const InsertionOrderIndex&) = delete;
  InsertionOrderIndex& operator=(const InsertionOrderIndex&) = delete;
  InsertionOrderIndex(InsertionOrderIndex&& other);
  InsertionOrderIndex& operator=(InsertionOrderIndex&& other);
  ~InsertionOrderIndex() noexcept(false);

  class Iterator {
  public:
    Iterator(const Link* links, uint pos)
        : links(links), pos(pos) {}

    inline size_t operator*() const {
      KJ_TABLE_IREQUIRE(pos != 0, "can't dereference end() iterator");
      return pos - 1;
    };

    inline Iterator& operator++() {
      pos = links[pos].next;
      return *this;
    }
    inline Iterator operator++(int) {
      Iterator result = *this;
      ++*this;
      return result;
    }
    inline Iterator& operator--() {
      pos = links[pos].prev;
      return *this;
    }
    inline Iterator operator--(int) {
      Iterator result = *this;
      --*this;
      return result;
    }

    inline bool operator==(const Iterator& other) const {
      return pos == other.pos;
    }
    inline bool operator!=(const Iterator& other) const {
      return pos != other.pos;
    }

  private:
    const Link* links;
    uint pos;
  };

  template <typename Row>
  Row& keyForRow(Row& row) const { return row; }

  void reserve(size_t size);
  void clear();
  inline Iterator begin() const { return Iterator(links, links[0].next); }
  inline Iterator end() const { return Iterator(links, 0); }

  template <typename Row>
  kj::Maybe<size_t> insert(kj::ArrayPtr<Row> table, size_t pos, const Row& row) {
    return insertImpl(pos);
  }

  template <typename Row>
  void erase(kj::ArrayPtr<Row> table, size_t pos, const Row& row) {
    eraseImpl(pos);
  }

  template <typename Row>
  void move(kj::ArrayPtr<Row> table, size_t oldPos, size_t newPos, const Row& row) {
    return moveImpl(oldPos, newPos);
  }

private:
  struct Link {
    uint next;
    uint prev;
  };

  uint capacity;
  Link* links;
  // links[0] is special: links[0].next points to the first link, links[0].prev points to the last.
  // links[n+1] corresponds to row n.

  kj::Maybe<size_t> insertImpl(size_t pos);
  void eraseImpl(size_t pos);
  void moveImpl(size_t oldPos, size_t newPos);

  static const Link EMPTY_LINK;
};

} // namespace kj

KJ_END_HEADER