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authorVincent Ambo <mail@tazj.in>2020-07-15T07·20+0100
committerVincent Ambo <mail@tazj.in>2020-07-15T07·20+0100
commit7f19d641647ac4ef313ed88d6b5c140983ce5436 (patch)
tree31b66c81465293da5c093c5dde3e419758c0d6cc /immer/detail/hamts/node.hpp
Squashed 'third_party/immer/' content from commit ad3e3556d
git-subtree-dir: third_party/immer
git-subtree-split: ad3e3556d38bb75966dd24c61a774970a7c7957e
Diffstat (limited to 'immer/detail/hamts/node.hpp')
-rw-r--r--immer/detail/hamts/node.hpp717
1 files changed, 717 insertions, 0 deletions
diff --git a/immer/detail/hamts/node.hpp b/immer/detail/hamts/node.hpp
new file mode 100644
index 000000000000..216e82b7874f
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+++ b/immer/detail/hamts/node.hpp
@@ -0,0 +1,717 @@
+//
+// immer: immutable data structures for C++
+// Copyright (C) 2016, 2017, 2018 Juan Pedro Bolivar Puente
+//
+// This software is distributed under the Boost Software License, Version 1.0.
+// See accompanying file LICENSE or copy at http://boost.org/LICENSE_1_0.txt
+//
+
+#pragma once
+
+#include <immer/detail/combine_standard_layout.hpp>
+#include <immer/detail/hamts/bits.hpp>
+#include <immer/detail/util.hpp>
+
+#include <cassert>
+
+namespace immer {
+namespace detail {
+namespace hamts {
+
+template <typename T,
+          typename Hash,
+          typename Equal,
+          typename MemoryPolicy,
+          bits_t B>
+struct node
+{
+    using node_t = node;
+
+    using memory      = MemoryPolicy;
+    using heap_policy = typename memory::heap;
+    using heap        = typename heap_policy::type;
+    using transience  = typename memory::transience_t;
+    using refs_t      = typename memory::refcount;
+    using ownee_t     = typename transience::ownee;
+    using edit_t      = typename transience::edit;
+    using value_t     = T;
+    using bitmap_t    = typename get_bitmap_type<B>::type;
+
+    enum class kind_t
+    {
+        collision,
+        inner
+    };
+
+    struct collision_t
+    {
+        count_t count;
+        aligned_storage_for<T> buffer;
+    };
+
+    struct values_data_t
+    {
+        aligned_storage_for<T> buffer;
+    };
+
+    using values_t = combine_standard_layout_t<values_data_t, refs_t>;
+
+    struct inner_t
+    {
+        bitmap_t nodemap;
+        bitmap_t datamap;
+        values_t* values;
+        aligned_storage_for<node_t*> buffer;
+    };
+
+    union data_t
+    {
+        inner_t inner;
+        collision_t collision;
+    };
+
+    struct impl_data_t
+    {
+#if IMMER_TAGGED_NODE
+        kind_t kind;
+#endif
+        data_t data;
+    };
+
+    using impl_t = combine_standard_layout_t<impl_data_t, refs_t>;
+
+    impl_t impl;
+
+    constexpr static std::size_t sizeof_values_n(count_t count)
+    {
+        return std::max(sizeof(values_t),
+                        immer_offsetof(values_t, d.buffer) +
+                            sizeof(values_data_t::buffer) * count);
+    }
+
+    constexpr static std::size_t sizeof_collision_n(count_t count)
+    {
+        return immer_offsetof(impl_t, d.data.collision.buffer) +
+               sizeof(collision_t::buffer) * count;
+    }
+
+    constexpr static std::size_t sizeof_inner_n(count_t count)
+    {
+        return immer_offsetof(impl_t, d.data.inner.buffer) +
+               sizeof(inner_t::buffer) * count;
+    }
+
+#if IMMER_TAGGED_NODE
+    kind_t kind() const { return impl.d.kind; }
+#endif
+
+    auto values()
+    {
+        IMMER_ASSERT_TAGGED(kind() == kind_t::inner);
+        assert(impl.d.data.inner.values);
+        return (T*) &impl.d.data.inner.values->d.buffer;
+    }
+
+    auto values() const
+    {
+        IMMER_ASSERT_TAGGED(kind() == kind_t::inner);
+        assert(impl.d.data.inner.values);
+        return (const T*) &impl.d.data.inner.values->d.buffer;
+    }
+
+    auto children()
+    {
+        IMMER_ASSERT_TAGGED(kind() == kind_t::inner);
+        return (node_t**) &impl.d.data.inner.buffer;
+    }
+
+    auto children() const
+    {
+        IMMER_ASSERT_TAGGED(kind() == kind_t::inner);
+        return (const node_t* const*) &impl.d.data.inner.buffer;
+    }
+
+    auto datamap() const
+    {
+        IMMER_ASSERT_TAGGED(kind() == kind_t::inner);
+        return impl.d.data.inner.datamap;
+    }
+
+    auto nodemap() const
+    {
+        IMMER_ASSERT_TAGGED(kind() == kind_t::inner);
+        return impl.d.data.inner.nodemap;
+    }
+
+    auto collision_count() const
+    {
+        IMMER_ASSERT_TAGGED(kind() == kind_t::collision);
+        return impl.d.data.collision.count;
+    }
+
+    T* collisions()
+    {
+        IMMER_ASSERT_TAGGED(kind() == kind_t::collision);
+        return (T*) &impl.d.data.collision.buffer;
+    }
+
+    const T* collisions() const
+    {
+        IMMER_ASSERT_TAGGED(kind() == kind_t::collision);
+        return (const T*) &impl.d.data.collision.buffer;
+    }
+
+    static refs_t& refs(const values_t* x)
+    {
+        return auto_const_cast(get<refs_t>(*x));
+    }
+    static const ownee_t& ownee(const values_t* x) { return get<ownee_t>(*x); }
+    static ownee_t& ownee(values_t* x) { return get<ownee_t>(*x); }
+
+    static refs_t& refs(const node_t* x)
+    {
+        return auto_const_cast(get<refs_t>(x->impl));
+    }
+    static const ownee_t& ownee(const node_t* x)
+    {
+        return get<ownee_t>(x->impl);
+    }
+    static ownee_t& ownee(node_t* x) { return get<ownee_t>(x->impl); }
+
+    static node_t* make_inner_n(count_t n)
+    {
+        assert(n <= branches<B>);
+        auto m = heap::allocate(sizeof_inner_n(n));
+        auto p = new (m) node_t;
+#if IMMER_TAGGED_NODE
+        p->impl.d.kind = node_t::kind_t::inner;
+#endif
+        p->impl.d.data.inner.nodemap = 0;
+        p->impl.d.data.inner.datamap = 0;
+        p->impl.d.data.inner.values  = nullptr;
+        return p;
+    }
+
+    static node_t* make_inner_n(count_t n, values_t* values)
+    {
+        auto p = make_inner_n(n);
+        if (values) {
+            p->impl.d.data.inner.values = values;
+            refs(values).inc();
+        }
+        return p;
+    }
+
+    static node_t* make_inner_n(count_t n, count_t nv)
+    {
+        assert(nv <= branches<B>);
+        auto p = make_inner_n(n);
+        if (nv) {
+            try {
+                p->impl.d.data.inner.values =
+                    new (heap::allocate(sizeof_values_n(nv))) values_t{};
+            } catch (...) {
+                deallocate_inner(p, n);
+                throw;
+            }
+        }
+        return p;
+    }
+
+    static node_t* make_inner_n(count_t n, count_t idx, node_t* child)
+    {
+        assert(n >= 1);
+        auto p                       = make_inner_n(n);
+        p->impl.d.data.inner.nodemap = bitmap_t{1u} << idx;
+        p->children()[0]             = child;
+        return p;
+    }
+
+    static node_t* make_inner_n(count_t n, bitmap_t bitmap, T x)
+    {
+        auto p                       = make_inner_n(n, 1);
+        p->impl.d.data.inner.datamap = bitmap;
+        try {
+            new (p->values()) T{std::move(x)};
+        } catch (...) {
+            deallocate_inner(p, n, 1);
+            throw;
+        }
+        return p;
+    }
+
+    static node_t*
+    make_inner_n(count_t n, count_t idx1, T x1, count_t idx2, T x2)
+    {
+        assert(idx1 != idx2);
+        auto p = make_inner_n(n, 2);
+        p->impl.d.data.inner.datamap =
+            (bitmap_t{1u} << idx1) | (bitmap_t{1u} << idx2);
+        auto assign = [&](auto&& x1, auto&& x2) {
+            auto vp = p->values();
+            try {
+                new (vp) T{std::move(x1)};
+                try {
+                    new (vp + 1) T{std::move(x2)};
+                } catch (...) {
+                    vp->~T();
+                    throw;
+                }
+            } catch (...) {
+                deallocate_inner(p, n, 2);
+                throw;
+            }
+        };
+        if (idx1 < idx2)
+            assign(x1, x2);
+        else
+            assign(x2, x1);
+        return p;
+    }
+
+    static node_t* make_collision_n(count_t n)
+    {
+        auto m = heap::allocate(sizeof_collision_n(n));
+        auto p = new (m) node_t;
+#if IMMER_TAGGED_NODE
+        p->impl.d.kind = node_t::kind_t::collision;
+#endif
+        p->impl.d.data.collision.count = n;
+        return p;
+    }
+
+    static node_t* make_collision(T v1, T v2)
+    {
+        auto m = heap::allocate(sizeof_collision_n(2));
+        auto p = new (m) node_t;
+#if IMMER_TAGGED_NODE
+        p->impl.d.kind = node_t::kind_t::collision;
+#endif
+        p->impl.d.data.collision.count = 2;
+        auto cols                      = p->collisions();
+        try {
+            new (cols) T{std::move(v1)};
+            try {
+                new (cols + 1) T{std::move(v2)};
+            } catch (...) {
+                cols->~T();
+                throw;
+            }
+        } catch (...) {
+            deallocate_collision(p, 2);
+            throw;
+        }
+        return p;
+    }
+
+    static node_t* copy_collision_insert(node_t* src, T v)
+    {
+        IMMER_ASSERT_TAGGED(src->kind() == kind_t::collision);
+        auto n    = src->collision_count();
+        auto dst  = make_collision_n(n + 1);
+        auto srcp = src->collisions();
+        auto dstp = dst->collisions();
+        try {
+            new (dstp) T{std::move(v)};
+            try {
+                std::uninitialized_copy(srcp, srcp + n, dstp + 1);
+            } catch (...) {
+                dstp->~T();
+                throw;
+            }
+        } catch (...) {
+            deallocate_collision(dst, n + 1);
+            throw;
+        }
+        return dst;
+    }
+
+    static node_t* copy_collision_remove(node_t* src, T* v)
+    {
+        IMMER_ASSERT_TAGGED(src->kind() == kind_t::collision);
+        assert(src->collision_count() > 1);
+        auto n    = src->collision_count();
+        auto dst  = make_collision_n(n - 1);
+        auto srcp = src->collisions();
+        auto dstp = dst->collisions();
+        try {
+            dstp = std::uninitialized_copy(srcp, v, dstp);
+            try {
+                std::uninitialized_copy(v + 1, srcp + n, dstp);
+            } catch (...) {
+                destroy(dst->collisions(), dstp);
+                throw;
+            }
+        } catch (...) {
+            deallocate_collision(dst, n - 1);
+            throw;
+        }
+        return dst;
+    }
+
+    static node_t* copy_collision_replace(node_t* src, T* pos, T v)
+    {
+        IMMER_ASSERT_TAGGED(src->kind() == kind_t::collision);
+        auto n    = src->collision_count();
+        auto dst  = make_collision_n(n);
+        auto srcp = src->collisions();
+        auto dstp = dst->collisions();
+        assert(pos >= srcp && pos < srcp + n);
+        try {
+            new (dstp) T{std::move(v)};
+            try {
+                dstp = std::uninitialized_copy(srcp, pos, dstp + 1);
+                try {
+                    std::uninitialized_copy(pos + 1, srcp + n, dstp);
+                } catch (...) {
+                    destroy(dst->collisions(), dstp);
+                    throw;
+                }
+            } catch (...) {
+                dst->collisions()->~T();
+                throw;
+            }
+        } catch (...) {
+            deallocate_collision(dst, n);
+            throw;
+        }
+        return dst;
+    }
+
+    static node_t*
+    copy_inner_replace(node_t* src, count_t offset, node_t* child)
+    {
+        IMMER_ASSERT_TAGGED(src->kind() == kind_t::inner);
+        auto n    = popcount(src->nodemap());
+        auto dst  = make_inner_n(n, src->impl.d.data.inner.values);
+        auto srcp = src->children();
+        auto dstp = dst->children();
+        dst->impl.d.data.inner.datamap = src->datamap();
+        dst->impl.d.data.inner.nodemap = src->nodemap();
+        std::uninitialized_copy(srcp, srcp + n, dstp);
+        inc_nodes(srcp, n);
+        srcp[offset]->dec_unsafe();
+        dstp[offset] = child;
+        return dst;
+    }
+
+    static node_t* copy_inner_replace_value(node_t* src, count_t offset, T v)
+    {
+        IMMER_ASSERT_TAGGED(src->kind() == kind_t::inner);
+        assert(offset < popcount(src->datamap()));
+        auto n                         = popcount(src->nodemap());
+        auto nv                        = popcount(src->datamap());
+        auto dst                       = make_inner_n(n, nv);
+        dst->impl.d.data.inner.datamap = src->datamap();
+        dst->impl.d.data.inner.nodemap = src->nodemap();
+        try {
+            std::uninitialized_copy(
+                src->values(), src->values() + nv, dst->values());
+            try {
+                dst->values()[offset] = std::move(v);
+            } catch (...) {
+                destroy_n(dst->values(), nv);
+                throw;
+            }
+        } catch (...) {
+            deallocate_inner(dst, n, nv);
+            throw;
+        }
+        inc_nodes(src->children(), n);
+        std::uninitialized_copy(
+            src->children(), src->children() + n, dst->children());
+        return dst;
+    }
+
+    static node_t* copy_inner_replace_merged(node_t* src,
+                                             bitmap_t bit,
+                                             count_t voffset,
+                                             node_t* node)
+    {
+        IMMER_ASSERT_TAGGED(src->kind() == kind_t::inner);
+        assert(!(src->nodemap() & bit));
+        assert(src->datamap() & bit);
+        assert(voffset == popcount(src->datamap() & (bit - 1)));
+        auto n                         = popcount(src->nodemap());
+        auto nv                        = popcount(src->datamap());
+        auto dst                       = make_inner_n(n + 1, nv - 1);
+        auto noffset                   = popcount(src->nodemap() & (bit - 1));
+        dst->impl.d.data.inner.datamap = src->datamap() & ~bit;
+        dst->impl.d.data.inner.nodemap = src->nodemap() | bit;
+        if (nv > 1) {
+            try {
+                std::uninitialized_copy(
+                    src->values(), src->values() + voffset, dst->values());
+                try {
+                    std::uninitialized_copy(src->values() + voffset + 1,
+                                            src->values() + nv,
+                                            dst->values() + voffset);
+                } catch (...) {
+                    destroy_n(dst->values(), voffset);
+                    throw;
+                }
+            } catch (...) {
+                deallocate_inner(dst, n + 1, nv - 1);
+                throw;
+            }
+        }
+        inc_nodes(src->children(), n);
+        std::uninitialized_copy(
+            src->children(), src->children() + noffset, dst->children());
+        std::uninitialized_copy(src->children() + noffset,
+                                src->children() + n,
+                                dst->children() + noffset + 1);
+        dst->children()[noffset] = node;
+        return dst;
+    }
+
+    static node_t* copy_inner_replace_inline(node_t* src,
+                                             bitmap_t bit,
+                                             count_t noffset,
+                                             T value)
+    {
+        IMMER_ASSERT_TAGGED(src->kind() == kind_t::inner);
+        assert(!(src->datamap() & bit));
+        assert(src->nodemap() & bit);
+        assert(noffset == popcount(src->nodemap() & (bit - 1)));
+        auto n                         = popcount(src->nodemap());
+        auto nv                        = popcount(src->datamap());
+        auto dst                       = make_inner_n(n - 1, nv + 1);
+        auto voffset                   = popcount(src->datamap() & (bit - 1));
+        dst->impl.d.data.inner.nodemap = src->nodemap() & ~bit;
+        dst->impl.d.data.inner.datamap = src->datamap() | bit;
+        try {
+            if (nv)
+                std::uninitialized_copy(
+                    src->values(), src->values() + voffset, dst->values());
+            try {
+                new (dst->values() + voffset) T{std::move(value)};
+                try {
+                    if (nv)
+                        std::uninitialized_copy(src->values() + voffset,
+                                                src->values() + nv,
+                                                dst->values() + voffset + 1);
+                } catch (...) {
+                    dst->values()[voffset].~T();
+                    throw;
+                }
+            } catch (...) {
+                destroy_n(dst->values(), voffset);
+                throw;
+            }
+        } catch (...) {
+            deallocate_inner(dst, n - 1, nv + 1);
+            throw;
+        }
+        inc_nodes(src->children(), n);
+        src->children()[noffset]->dec_unsafe();
+        std::uninitialized_copy(
+            src->children(), src->children() + noffset, dst->children());
+        std::uninitialized_copy(src->children() + noffset + 1,
+                                src->children() + n,
+                                dst->children() + noffset);
+        return dst;
+    }
+
+    static node_t*
+    copy_inner_remove_value(node_t* src, bitmap_t bit, count_t voffset)
+    {
+        IMMER_ASSERT_TAGGED(src->kind() == kind_t::inner);
+        assert(!(src->nodemap() & bit));
+        assert(src->datamap() & bit);
+        assert(voffset == popcount(src->datamap() & (bit - 1)));
+        auto n                         = popcount(src->nodemap());
+        auto nv                        = popcount(src->datamap());
+        auto dst                       = make_inner_n(n, nv - 1);
+        dst->impl.d.data.inner.datamap = src->datamap() & ~bit;
+        dst->impl.d.data.inner.nodemap = src->nodemap();
+        if (nv > 1) {
+            try {
+                std::uninitialized_copy(
+                    src->values(), src->values() + voffset, dst->values());
+                try {
+                    std::uninitialized_copy(src->values() + voffset + 1,
+                                            src->values() + nv,
+                                            dst->values() + voffset);
+                } catch (...) {
+                    destroy_n(dst->values(), voffset);
+                    throw;
+                }
+            } catch (...) {
+                deallocate_inner(dst, n, nv - 1);
+                throw;
+            }
+        }
+        inc_nodes(src->children(), n);
+        std::uninitialized_copy(
+            src->children(), src->children() + n, dst->children());
+        return dst;
+    }
+
+    static node_t* copy_inner_insert_value(node_t* src, bitmap_t bit, T v)
+    {
+        IMMER_ASSERT_TAGGED(src->kind() == kind_t::inner);
+        auto n                         = popcount(src->nodemap());
+        auto nv                        = popcount(src->datamap());
+        auto offset                    = popcount(src->datamap() & (bit - 1));
+        auto dst                       = make_inner_n(n, nv + 1);
+        dst->impl.d.data.inner.datamap = src->datamap() | bit;
+        dst->impl.d.data.inner.nodemap = src->nodemap();
+        try {
+            if (nv)
+                std::uninitialized_copy(
+                    src->values(), src->values() + offset, dst->values());
+            try {
+                new (dst->values() + offset) T{std::move(v)};
+                try {
+                    if (nv)
+                        std::uninitialized_copy(src->values() + offset,
+                                                src->values() + nv,
+                                                dst->values() + offset + 1);
+                } catch (...) {
+                    dst->values()[offset].~T();
+                    throw;
+                }
+            } catch (...) {
+                destroy_n(dst->values(), offset);
+                throw;
+            }
+        } catch (...) {
+            deallocate_inner(dst, n, nv + 1);
+            throw;
+        }
+        inc_nodes(src->children(), n);
+        std::uninitialized_copy(
+            src->children(), src->children() + n, dst->children());
+        return dst;
+    }
+
+    static node_t*
+    make_merged(shift_t shift, T v1, hash_t hash1, T v2, hash_t hash2)
+    {
+        if (shift < max_shift<B>) {
+            auto idx1 = hash1 & (mask<B> << shift);
+            auto idx2 = hash2 & (mask<B> << shift);
+            if (idx1 == idx2) {
+                auto merged = make_merged(
+                    shift + B, std::move(v1), hash1, std::move(v2), hash2);
+                try {
+                    return make_inner_n(1, idx1 >> shift, merged);
+                } catch (...) {
+                    delete_deep_shift(merged, shift + B);
+                    throw;
+                }
+            } else {
+                return make_inner_n(0,
+                                    idx1 >> shift,
+                                    std::move(v1),
+                                    idx2 >> shift,
+                                    std::move(v2));
+            }
+        } else {
+            return make_collision(std::move(v1), std::move(v2));
+        }
+    }
+
+    node_t* inc()
+    {
+        refs(this).inc();
+        return this;
+    }
+
+    const node_t* inc() const
+    {
+        refs(this).inc();
+        return this;
+    }
+
+    bool dec() const { return refs(this).dec(); }
+    void dec_unsafe() const { refs(this).dec_unsafe(); }
+
+    static void inc_nodes(node_t** p, count_t n)
+    {
+        for (auto i = p, e = i + n; i != e; ++i)
+            refs(*i).inc();
+    }
+
+    static void delete_values(values_t* p, count_t n)
+    {
+        assert(p);
+        deallocate_values(p, n);
+    }
+
+    static void delete_inner(node_t* p)
+    {
+        assert(p);
+        IMMER_ASSERT_TAGGED(p->kind() == kind_t::inner);
+        auto vp = p->impl.d.data.inner.values;
+        if (vp && refs(vp).dec())
+            delete_values(vp, popcount(p->datamap()));
+        deallocate_inner(p, popcount(p->nodemap()));
+    }
+
+    static void delete_collision(node_t* p)
+    {
+        assert(p);
+        IMMER_ASSERT_TAGGED(p->kind() == kind_t::collision);
+        auto n = p->collision_count();
+        deallocate_collision(p, n);
+    }
+
+    static void delete_deep(node_t* p, shift_t s)
+    {
+        if (s == max_depth<B>)
+            delete_collision(p);
+        else {
+            auto fst = p->children();
+            auto lst = fst + popcount(p->nodemap());
+            for (; fst != lst; ++fst)
+                if ((*fst)->dec())
+                    delete_deep(*fst, s + 1);
+            delete_inner(p);
+        }
+    }
+
+    static void delete_deep_shift(node_t* p, shift_t s)
+    {
+        if (s == max_shift<B>)
+            delete_collision(p);
+        else {
+            auto fst = p->children();
+            auto lst = fst + popcount(p->nodemap());
+            for (; fst != lst; ++fst)
+                if ((*fst)->dec())
+                    delete_deep_shift(*fst, s + B);
+            delete_inner(p);
+        }
+    }
+
+    static void deallocate_values(values_t* p, count_t n)
+    {
+        destroy_n((T*) &p->d.buffer, n);
+        heap::deallocate(node_t::sizeof_values_n(n), p);
+    }
+
+    static void deallocate_collision(node_t* p, count_t n)
+    {
+        destroy_n(p->collisions(), n);
+        heap::deallocate(node_t::sizeof_collision_n(n), p);
+    }
+
+    static void deallocate_inner(node_t* p, count_t n)
+    {
+        heap::deallocate(node_t::sizeof_inner_n(n), p);
+    }
+
+    static void deallocate_inner(node_t* p, count_t n, count_t nv)
+    {
+        assert(nv);
+        heap::deallocate(node_t::sizeof_values_n(nv),
+                         p->impl.d.data.inner.values);
+        heap::deallocate(node_t::sizeof_inner_n(n), p);
+    }
+};
+
+} // namespace hamts
+} // namespace detail
+} // namespace immer