update check-structures-sanity (part 2 of 2)

2020-03-10 23:05:59 -05:00 · 2020-03-10 23:05:59 -05:00 · e2138a6cc2
parent e5de783c58
commit e2138a6cc2
5 changed files with 674 additions and 81 deletions
--- a/plugins/devel/check-structures-sanity/check-structures-sanity.h
+++ b/plugins/devel/check-structures-sanity/check-structures-sanity.h
@ -15,7 +15,7 @@ using namespace DFHack;
 #ifdef WIN32
 #define UNEXPECTED __debugbreak()
 #else
-#define UNEXPECTED __asm__ volatile ("int $0x03")
+#define UNEXPECTED __asm__ volatile ("int $0x03; nop")
 #endif
 #define PTR_ADD(ptr, offset) reinterpret_cast<const void *>(uintptr_t(ptr) + (offset))
@ -33,14 +33,20 @@ struct CheckedStructure
 {
    type_identity *identity;
    size_t count;
    enum_identity *eid;
    CheckedStructure();
    explicit CheckedStructure(type_identity *, size_t = 0);
    CheckedStructure(type_identity *, size_t, enum_identity *);
    CheckedStructure(const struct_field_info *);
    size_t full_size() const;
 };
 #define MIN_SIZE_FOR_SUGGEST 64
 extern std::map<size_t, std::vector<std::string>> known_types_by_size;
 void build_size_table();
 namespace
 {
    template<typename T, bool is_pointer = std::is_pointer<T>::value>
@ -59,7 +65,7 @@ class Checker
 {
    color_ostream & out;
    std::vector<t_memrange> mapped;
-    std::map<const void *, CheckedStructure> data;
+    std::map<const void *, std::pair<std::string, CheckedStructure>> data;
    std::deque<QueueItem> queue;
 public:
    size_t checked_count;
@ -72,11 +78,19 @@ public:
    bool failfast;
    Checker(color_ostream & out);
-    void queue_item(const QueueItem & item, const CheckedStructure & cs);
+    bool queue_item(const QueueItem & item, const CheckedStructure & cs);
    void queue_globals();
    bool process_queue();
-    bool is_valid_dereference(const QueueItem & item, const CheckedStructure & cs, bool quiet = false);
+    bool is_valid_dereference(const QueueItem & item, const CheckedStructure & cs, size_t size, bool quiet);
    inline bool is_valid_dereference(const QueueItem & item, const CheckedStructure & cs, bool quiet = false)
    {
        return is_valid_dereference(item, cs, cs.full_size(), quiet);
    }
    inline bool is_valid_dereference(const QueueItem & item, size_t size, bool quiet = false)
    {
        return is_valid_dereference(item, CheckedStructure(df::identity_traits<void *>::get()), size, quiet);
    }
    template<typename T>
    const T validate_and_dereference(const QueueItem & item, bool quiet = false)
    {
@ -87,8 +101,15 @@ public:
        return *reinterpret_cast<const T *>(item.ptr);
    }
    int64_t get_int_value(const QueueItem & item, type_identity *type, bool quiet = false);
    const char *get_vtable_name(const QueueItem & item, const CheckedStructure & cs, bool quiet = false);
    std::pair<const void *, size_t> validate_vector_size(const QueueItem & item, const CheckedStructure & cs, bool quiet = false);
    size_t get_allocated_size(const QueueItem & item);
 #ifndef WIN32
    // this function doesn't make sense on windows, where std::string is not pointer-sized.
    const std::string *validate_stl_string_pointer(const void *const*);
 #endif
    static const char *const *get_enum_item_key(enum_identity *identity, int64_t value);
 private:
    color_ostream & fail(int, const QueueItem &, const CheckedStructure &);
@ -106,12 +127,25 @@ private:
    void dispatch_class(const QueueItem &, const CheckedStructure &);
    void dispatch_buffer(const QueueItem &, const CheckedStructure &);
    void dispatch_stl_ptr_vector(const QueueItem &, const CheckedStructure &);
    void dispatch_tagged_union(const QueueItem &, const QueueItem &, const CheckedStructure &, const CheckedStructure &);
    void dispatch_tagged_union_vector(const QueueItem &, const QueueItem &, const CheckedStructure &, const CheckedStructure &);
    void dispatch_untagged_union(const QueueItem &, const CheckedStructure &);
-    void check_stl_vector(const QueueItem &, type_identity *);
+    void check_unknown_pointer(const QueueItem &);
    void check_stl_vector(const QueueItem &, type_identity *, type_identity *);
    void check_stl_string(const QueueItem &);
    friend struct CheckedStructure;
    static type_identity *wrap_in_pointer(type_identity *);
    static type_identity *wrap_in_stl_ptr_vector(type_identity *);
 };
-#define FAIL(message) (static_cast<color_ostream &>(fail(__LINE__, item, cs) << message) << COLOR_RESET << std::endl)
+#define FAIL(message) \
    do \
    { \
        auto & failstream = fail(__LINE__, item, cs); \
        failstream << message; \
        failstream << COLOR_RESET << std::endl; \
        if (failfast) \
            UNEXPECTED; \
    } \
    while (false)
--- a/plugins/devel/check-structures-sanity/dispatch.cpp
+++ b/plugins/devel/check-structures-sanity/dispatch.cpp
@ -25,19 +25,25 @@ color_ostream & Checker::fail(int line, const QueueItem & item, const CheckedStr
    out << COLOR_YELLOW;
    if (maxerrors && maxerrors != ~size_t(0))
        maxerrors--;
    if (failfast)
        UNEXPECTED;
    return out;
 }
-void Checker::queue_item(const QueueItem & item, const CheckedStructure & cs)
+bool Checker::queue_item(const QueueItem & item, const CheckedStructure & cs)
 {
-    if (data.count(item.ptr) && data.at(item.ptr).full_size() == cs.full_size())
+    if (data.count(item.ptr))
    {
        // already checked
-        // TODO: make sure types are equal
+        auto existing = data.at(item.ptr);
-        UNEXPECTED;
+        if (cs.identity != existing.second.identity)
-        return;
+        {
            if (cs.identity->type() == IDTYPE_CLASS && existing.second.identity->type() == IDTYPE_CLASS && get_vtable_name(item, cs, false) && static_cast<virtual_identity *>(cs.identity)->is_instance(static_cast<virtual_ptr>(const_cast<void *>(item.ptr))))
            {
                return false;
            }
            FAIL("TODO: handle merging structures: " << data.at(item.ptr).first << " overlaps " << item.path << " (same pointer)");
        }
        return false;
    }
    auto ptr_end = PTR_ADD(item.ptr, cs.full_size());
@ -46,10 +52,27 @@ void Checker::queue_item(const QueueItem & item, const CheckedStructure & cs)
    if (prev != data.cbegin())
    {
        prev--;
-        if (uintptr_t(prev->first) + prev->second.full_size() > uintptr_t(item.ptr))
+        if (uintptr_t(prev->first) + prev->second.second.full_size() > uintptr_t(item.ptr))
        {
            // placeholder algorithm
            if (auto sid = dynamic_cast<struct_identity *>(prev->second.second.identity))
            {
                auto offset = uintptr_t(item.ptr) - uintptr_t(prev->first);
                for (auto field = sid->getFields(); field->mode != struct_field_info::END; field++)
                {
                    if (field->offset == offset)
                    {
                        if (field->mode == struct_field_info::SUBSTRUCT && field->type == cs.identity)
                        {
                            return false;
                        }
                        UNEXPECTED;
                    }
                }
            }
            // TODO
-            UNEXPECTED;
+            FAIL("TODO: handle merging structures: " << prev->second.first << " overlaps " << item.path << " (backward)");
        }
    }
@ -58,12 +81,13 @@ void Checker::queue_item(const QueueItem & item, const CheckedStructure & cs)
    while (overlap != overlap_end)
    {
        // TODO
-        UNEXPECTED;
+        FAIL("TODO: handle merging structures: " << overlap->second.first << " overlaps " << item.path << " (forward)");
        overlap++;
    }
-    data[item.ptr] = cs;
+    data[item.ptr] = std::make_pair(item.path, cs);
    queue.push_back(item);
    return true;
 }
 void Checker::queue_globals()
@ -89,6 +113,12 @@ void Checker::queue_globals()
            continue;
        }
        if (!strcmp(field->name, "enabler"))
        {
            // don't care about libgraphics as we have the source code
            continue;
        }
        queue_item(item, cs);
    }
 }
@ -110,7 +140,7 @@ bool Checker::process_queue()
        return true;
    }
-    dispatch_item(item, cs->second);
+    dispatch_item(item, cs->second.second);
    return true;
 }
@ -194,7 +224,6 @@ void Checker::dispatch_single_item(const QueueItem & item, const CheckedStructur
            dispatch_stl_ptr_vector(item, cs);
            break;
        case IDTYPE_OPAQUE:
            UNEXPECTED;
            break;
        case IDTYPE_UNION:
            dispatch_untagged_union(item, cs);
@ -204,27 +233,78 @@ void Checker::dispatch_single_item(const QueueItem & item, const CheckedStructur
 void Checker::dispatch_primitive(const QueueItem & item, const CheckedStructure & cs)
 {
-    if (cs.identity->isConstructed())
+    if (cs.identity == df::identity_traits<std::string>::get())
    {
-        if (cs.identity == df::identity_traits<std::string>::get())
+        check_stl_string(item);
-        {
+    }
-            // TODO check std::string
+    else if (cs.identity == df::identity_traits<char *>::get())
-            UNEXPECTED;
+    {
-        }
+        // TODO check c strings
-        else
+        UNEXPECTED;
    }
    else if (cs.identity == df::identity_traits<bool>::get())
    {
        auto val = *reinterpret_cast<const uint8_t *>(item.ptr);
        if (val > 1 && val != 0xd2)
        {
-            UNEXPECTED;
+            FAIL("invalid value for bool: " << int(val));
        }
    }
-
+    else if (auto int_id = dynamic_cast<df::integer_identity_base *>(cs.identity))
-    // TODO: check primitives
+    {
-    UNEXPECTED;
+        // TODO check ints?
    }
    else if (auto float_id = dynamic_cast<df::float_identity_base *>(cs.identity))
    {
        // TODO check floats?
    }
    else
    {
        UNEXPECTED;
    }
 }
 void Checker::dispatch_pointer(const QueueItem & item, const CheckedStructure & cs)
 {
-    auto identity = static_cast<pointer_identity *>(cs.identity);
+    auto target_ptr = validate_and_dereference<const void *>(item);
-    // TODO: check pointer
+    if (!target_ptr)
-    UNEXPECTED;
+    {
        return;
    }
 #ifdef DFHACK64
    if (uintptr_t(target_ptr) == 0xd2d2d2d2d2d2d2d2)
 #else
    if (uintptr_t(target_ptr) == 0xd2d2d2d2)
 #endif
    {
        return;
    }
    QueueItem target_item(item.path, target_ptr);
    auto target = static_cast<pointer_identity *>(cs.identity)->getTarget();
    if (!target)
    {
        check_unknown_pointer(item);
        return;
    }
    // 256 is an arbitrarily chosen size threshold
    if (cs.count || target->byte_size() <= 256)
    {
        // target is small, or we are inside an array of pointers; handle now
        if (queue_item(target_item, CheckedStructure(target)))
        {
            // we insert it into the queue to make sure we're not stuck in a loop
            // get it back out of the queue to prevent the queue growing too big
            queue.pop_back();
            dispatch_item(target_item, CheckedStructure(target));
        }
    }
    else
    {
        // target is large and not part of an array; handle later
        queue_item(target_item, CheckedStructure(target));
    }
 }
 void Checker::dispatch_container(const QueueItem & item, const CheckedStructure & cs)
 {
@ -232,11 +312,7 @@ void Checker::dispatch_container(const QueueItem & item, const CheckedStructure
    auto base_container = identity->getFullName(nullptr);
    if (base_container == "vector<void>")
    {
-        if (identity->getIndexEnumType())
+        check_stl_vector(item, identity->getItemType(), identity->getIndexEnumType());
        {
            UNEXPECTED;
        }
        check_stl_vector(item, identity->getItemType());
    }
    else if (base_container == "deque<void>")
    {
@ -262,12 +338,10 @@ void Checker::dispatch_bit_container(const QueueItem & item, const CheckedStruct
    if (base_container == "BitArray<>")
    {
        // TODO: check DF bit array
        UNEXPECTED;
    }
    else if (base_container == "vector<bool>")
    {
        // TODO: check stl bit vector
        UNEXPECTED;
    }
    else
    {
@ -281,8 +355,66 @@ void Checker::dispatch_bitfield(const QueueItem & item, const CheckedStructure &
        return;
    }
-    // TODO: check bitfields
+    auto bitfield_type = static_cast<bitfield_identity *>(cs.identity);
-    UNEXPECTED;
+    uint64_t bitfield_value;
    switch (bitfield_type->byte_size())
    {
        case 1:
            bitfield_value = validate_and_dereference<uint8_t>(item);
            // don't check for uninitialized; too small to be sure
            break;
        case 2:
            bitfield_value = validate_and_dereference<uint16_t>(item);
            if (bitfield_value == 0xd2d2)
            {
                bitfield_value = 0;
            }
            break;
        case 4:
            bitfield_value = validate_and_dereference<uint32_t>(item);
            if (bitfield_value == 0xd2d2d2d2)
            {
                bitfield_value = 0;
            }
            break;
        case 8:
            bitfield_value = validate_and_dereference<uint64_t>(item);
            if (bitfield_value == 0xd2d2d2d2d2d2d2d2)
            {
                bitfield_value = 0;
            }
            break;
        default:
            UNEXPECTED;
            bitfield_value = 0;
            break;
    }
    auto num_bits = bitfield_type->getNumBits();
    auto bits = bitfield_type->getBits();
    for (int i = 0; i < 64; i++)
    {
        if (!(num_bits & 1))
        {
            bitfield_value >>= 1;
            continue;
        }
        bitfield_value >>= 1;
        if (i >= num_bits || !bits[i].size)
        {
            FAIL("bitfield bit " << i << " is out of range");
        }
        else if (unnamed && bits[i].size > 0 && !bits[i].name)
        {
            FAIL("bitfield bit " << i << " is unnamed");
        }
        else if (unnamed && !bits[i + bits[i].size].name)
        {
            FAIL("bitfield bit " << i << " (part of a field starting at bit " << (i + bits[i].size) << ") is unnamed");
        }
    }
 }
 void Checker::dispatch_enum(const QueueItem & item, const CheckedStructure & cs)
 {
@ -291,8 +423,31 @@ void Checker::dispatch_enum(const QueueItem & item, const CheckedStructure & cs)
        return;
    }
-    // TODO: check enums
+    auto enum_type = static_cast<enum_identity *>(cs.identity);
-    UNEXPECTED;
+    auto enum_value = get_int_value(item, enum_type->getBaseType());
    if (enum_type->byte_size() == 2 && uint16_t(enum_value) == 0xd2d2)
    {
        return;
    }
    else if (enum_type->byte_size() == 4 && uint32_t(enum_value) == 0xd2d2d2d2)
    {
        return;
    }
    else if (enum_type->byte_size() == 8 && uint64_t(enum_value) == 0xd2d2d2d2d2d2d2d2)
    {
        return;
    }
    auto enum_name = get_enum_item_key(enum_type, enum_value);
    if (!enum_name)
    {
        FAIL("enum value (" << enum_value << ") is out of range");
        return;
    }
    if (unnamed && !*enum_name)
    {
        FAIL("enum value (" << enum_value << ") is unnamed");
    }
 }
 void Checker::dispatch_struct(const QueueItem & item, const CheckedStructure & cs)
 {
@ -300,6 +455,11 @@ void Checker::dispatch_struct(const QueueItem & item, const CheckedStructure & c
    for (auto p = identity; p; p = p->getParent())
    {
        auto fields = p->getFields();
        if (!fields)
        {
            continue;
        }
        for (auto field = fields; field->mode != struct_field_info::END; field++)
        {
            dispatch_field(item, cs, fields, field);
@ -314,16 +474,28 @@ void Checker::dispatch_field(const QueueItem & item, const CheckedStructure & cs
        return;
    }
    auto field_ptr = PTR_ADD(item.ptr, field->offset);
    QueueItem field_item(item, field->name, field_ptr);
    CheckedStructure field_cs(field);
    auto tag_field = find_union_tag(fields, field);
    if (tag_field)
    {
-        UNEXPECTED;
+        auto tag_ptr = PTR_ADD(item.ptr, tag_field->offset);
        QueueItem tag_item(item, tag_field->name, tag_ptr);
        CheckedStructure tag_cs(tag_field);
        if (tag_cs.identity->isContainer())
        {
            dispatch_tagged_union_vector(field_item, tag_item, field_cs, tag_cs);
        }
        else
        {
            dispatch_tagged_union(field_item, tag_item, field_cs, tag_cs);
        }
        return;
    }
-    auto field_ptr = PTR_ADD(item.ptr, field->offset);
+    dispatch_item(field_item, field_cs);
    CheckedStructure field_cs(field);
    dispatch_item(QueueItem(item, field->name, field_ptr), field_cs);
 }
 void Checker::dispatch_class(const QueueItem & item, const CheckedStructure & cs)
 {
@ -336,40 +508,158 @@ void Checker::dispatch_class(const QueueItem & item, const CheckedStructure & cs
    auto base_identity = static_cast<virtual_identity *>(cs.identity);
    auto vptr = static_cast<virtual_ptr>(const_cast<void *>(item.ptr));
-    if (!base_identity->is_instance(vptr))
+    auto identity = virtual_identity::get(vptr);
    if (!identity)
    {
-        FAIL("expected subclass of " << base_identity->getFullName() << ", but got " << vtable_name);
+        FAIL("unidentified subclass of " << base_identity->getFullName() << ": " << vtable_name);
        return;
    }
    if (base_identity != identity && !base_identity->is_subclass(identity))
    {
        FAIL("expected subclass of " << base_identity->getFullName() << ", but got " << identity->getFullName());
        return;
    }
-    auto identity = virtual_identity::get(vptr);
+    if (data.count(item.ptr) && data.at(item.ptr).first == item.path)
    {
        // TODO: handle cases where this may overlap later data
        data.at(item.ptr).second.identity = identity;
    }
    dispatch_struct(QueueItem(item.path + "<" + identity->getFullName() + ">", item.ptr), CheckedStructure(identity));
 }
 void Checker::dispatch_buffer(const QueueItem & item, const CheckedStructure & cs)
 {
    auto identity = static_cast<container_identity *>(cs.identity);
    if (identity->getIndexEnumType())
    {
        UNEXPECTED;
    }
    auto item_identity = identity->getItemType();
-    dispatch_item(item, CheckedStructure(item_identity, identity->byte_size() / item_identity->byte_size()));
+    dispatch_item(item, CheckedStructure(item_identity, identity->byte_size() / item_identity->byte_size(), static_cast<enum_identity *>(identity->getIndexEnumType())));
 }
 void Checker::dispatch_stl_ptr_vector(const QueueItem & item, const CheckedStructure & cs)
 {
    auto identity = static_cast<container_identity *>(cs.identity);
-    if (identity->getIndexEnumType())
+    auto ptr_type = wrap_in_pointer(identity->getItemType());
    check_stl_vector(item, ptr_type, identity->getIndexEnumType());
 }
 void Checker::dispatch_tagged_union(const QueueItem & item, const QueueItem & tag_item, const CheckedStructure & cs, const CheckedStructure & tag_cs)
 {
    if (tag_cs.identity->type() != IDTYPE_ENUM || cs.identity->type() != IDTYPE_UNION)
    {
        UNEXPECTED;
        return;
    }
    auto tag_identity = static_cast<enum_identity *>(tag_cs.identity);
    auto tag_value = get_int_value(tag_item, tag_identity->getBaseType());
    auto tag_name = get_enum_item_key(tag_identity, tag_value);
    if (!tag_name)
    {
        FAIL("tagged union tag (accessed as " << tag_item.path << ") value (" << tag_value << ") not defined in enum " << tag_cs.identity->getFullName());
        return;
    }
    if (!*tag_name)
    {
        FAIL("tagged union tag (accessed as " << tag_item.path << ") value (" << tag_value << ") is unnamed");
        return;
    }
    auto union_type = static_cast<union_identity *>(cs.identity);
    for (auto field = union_type->getFields(); field->mode != struct_field_info::END; field++)
    {
        if (strcmp(field->name, *tag_name))
        {
            continue;
        }
        if (field->offset != 0)
        {
            UNEXPECTED;
        }
        dispatch_item(QueueItem(item, field->name, item.ptr), field);
        return;
    }
    auto union_data_ptr = reinterpret_cast<const uint8_t *>(item.ptr);
    uint8_t padding_byte = *union_data_ptr;
    if (padding_byte == 0x00 || padding_byte == 0xd2 || padding_byte == 0xff)
    {
        bool all_padding = true;
        for (size_t i = 0; i < union_type->byte_size(); i++)
        {
            if (union_data_ptr[i] != padding_byte)
            {
                all_padding = false;
                break;
            }
        }
        // don't ask for fields if it's all padding
        if (all_padding)
        {
            return;
        }
    }
    FAIL("tagged union missing " << *tag_name << " field to match tag (accessed as " << tag_item.path << ") value (" << tag_value << ")");
 }
 void Checker::dispatch_tagged_union_vector(const QueueItem & item, const QueueItem & tag_item, const CheckedStructure & cs, const CheckedStructure & tag_cs)
 {
    auto union_container_identity = static_cast<container_identity *>(cs.identity);
    CheckedStructure union_item_cs(union_container_identity->getItemType());
    if (union_container_identity->type() != IDTYPE_CONTAINER)
    {
        // assume pointer container
        union_item_cs.identity = wrap_in_pointer(union_item_cs.identity);
    }
    auto tag_container_identity = static_cast<container_identity *>(tag_cs.identity);
    auto tag_container_base = tag_container_identity->getFullName(nullptr);
    if (tag_container_base == "vector<void>")
    {
        auto vec_union = validate_vector_size(item, union_item_cs);
        CheckedStructure tag_item_cs(tag_container_identity->getItemType());
        auto vec_tag = validate_vector_size(tag_item, tag_item_cs);
        if (!vec_union.first || !vec_tag.first)
        {
            // invalid vectors (already warned)
            return;
        }
        if (!vec_union.second && !vec_tag.second)
        {
            // empty vectors
            return;
        }
        if (vec_union.second != vec_tag.second)
        {
            FAIL("tagged union vector is " << vec_union.second << " elements, but tag vector (accessed as " << tag_item.path << ") is " << vec_tag.second << " elements");
        }
        for (size_t i = 0; i < vec_union.second && i < vec_tag.second; i++)
        {
            dispatch_tagged_union(QueueItem(item, i, vec_union.first), QueueItem(tag_item, i, vec_tag.first), union_item_cs, tag_item_cs);
            vec_union.first = PTR_ADD(vec_union.first, union_item_cs.identity->byte_size());
            vec_tag.first = PTR_ADD(vec_tag.first, tag_item_cs.identity->byte_size());
        }
    }
    else if (tag_container_base == "vector<bool>")
    {
        // TODO
        UNEXPECTED;
    }
    else
    {
        UNEXPECTED;
    }
    auto ptr_type = wrap_in_pointer(identity->getItemType());
    check_stl_vector(item, ptr_type);
 }
 void Checker::dispatch_untagged_union(const QueueItem & item, const CheckedStructure & cs)
 {
    // special case for large_integer weirdness
    if (cs.identity == df::identity_traits<df::large_integer>::get())
    {
        // it's 16 bytes on 64-bit linux due to a messy header in libgraphics
        // but only the first 8 bytes are ever used
        dispatch_primitive(item, CheckedStructure(df::identity_traits<int64_t>::get()));
        return;
    }
@ -377,13 +667,141 @@ void Checker::dispatch_untagged_union(const QueueItem & item, const CheckedStruc
    UNEXPECTED;
 }
-void Checker::check_stl_vector(const QueueItem & item, type_identity *item_identity)
+void Checker::check_unknown_pointer(const QueueItem & item)
 {
    CheckedStructure cs(df::identity_traits<void *>::get());
    if (auto allocated_size = get_allocated_size(item))
    {
        FAIL("pointer to a block of " << allocated_size << " bytes of allocated memory");
        if (allocated_size >= MIN_SIZE_FOR_SUGGEST && known_types_by_size.count(allocated_size))
        {
            FAIL("known types of this size: " << join_strings(", ", known_types_by_size.at(allocated_size)));
        }
        // check recursively if it's the right size for a pointer
        // or if it starts with what might be a valid pointer
        if (allocated_size == sizeof(void *) || (allocated_size > sizeof(void *) && is_valid_dereference(item, cs, true)))
        {
            QueueItem ptr_item(item, "?ptr?", item.ptr);
            if (queue_item(ptr_item, cs))
            {
                queue.pop_back();
                dispatch_pointer(ptr_item, cs);
            }
        }
    }
 #ifndef WIN32
    else if (auto str = validate_stl_string_pointer(&item.ptr))
    {
        FAIL("untyped pointer is actually stl-string with value \"" << *str << "\" (length " << str->length() << ")");
    }
 #endif
    else if (auto vtable_name = get_vtable_name(QueueItem(item.path, &item.ptr), cs, true))
    {
        FAIL("pointer to a vtable: " << vtable_name);
    }
    else if (sizes)
    {
        //FAIL("pointer to memory with no size information");
    }
 }
 void Checker::check_stl_vector(const QueueItem & item, type_identity *item_identity, type_identity *eid)
 {
    auto vec_items = validate_vector_size(item, CheckedStructure(item_identity));
    // skip bad pointer vectors
    if (item.path.length() > 4 && item.path.substr(item.path.length() - 4) == ".bad" && item_identity->type() == IDTYPE_POINTER)
    {
        return;
    }
    if (vec_items.first && vec_items.second)
    {
        QueueItem items_item(item.path, vec_items.first);
-        CheckedStructure items_cs(item_identity, vec_items.second);
+        CheckedStructure items_cs(item_identity, vec_items.second, static_cast<enum_identity *>(eid));
        queue_item(items_item, items_cs);
    }
 }
 void Checker::check_stl_string(const QueueItem & item)
 {
    const static CheckedStructure cs(df::identity_traits<std::string>::get());
 #ifdef WIN32
    struct string_data
    {
        union
        {
            uintptr_t start;
            char local_data[16];
        };
        size_t length;
        size_t capacity;
    };
 #else
    struct string_data
    {
        struct string_data_inner
        {
            size_t length;
            size_t capacity;
            int32_t refcount;
        } *ptr;
    };
 #endif
    auto string = reinterpret_cast<const string_data *>(item.ptr);
 #ifdef WIN32
    bool is_local = string->capacity < 16;
    const char *start = is_local ? &string->local_data[0] : reinterpret_cast<const char *>(string->start);
    ptrdiff_t length = string->length;
    ptrdiff_t capacity = string->capacity;
 #else
    if (!is_valid_dereference(QueueItem(item, "?ptr?", string->ptr), 1))
    {
        // nullptr is NOT okay here
        FAIL("invalid string pointer " << stl_sprintf("%p", string->ptr));
        return;
    }
    if (!is_valid_dereference(QueueItem(item, "?hdr?", string->ptr - 1), sizeof(*string->ptr)))
    {
        return;
    }
    const char *start = reinterpret_cast<const char *>(string->ptr);
    ptrdiff_t length = (string->ptr - 1)->length;
    ptrdiff_t capacity = (string->ptr - 1)->capacity;
 #endif
    if (length < 0)
    {
        FAIL("string length is negative (" << length << ")");
    }
    else if (capacity < 0)
    {
        FAIL("string capacity is negative (" << capacity << ")");
    }
    else if (capacity < length)
    {
        FAIL("string capacity (" << capacity << ") is less than length (" << length << ")");
    }
 #ifndef WIN32
    const std::string empty_string;
    auto empty_string_data = reinterpret_cast<const string_data *>(&empty_string);
    if (sizes && string->ptr != empty_string_data->ptr)
    {
        size_t allocated_size = get_allocated_size(QueueItem(item, "?hdr?", string->ptr - 1));
        size_t expected_size = sizeof(*string->ptr) + capacity + 1;
        if (!allocated_size)
        {
            FAIL("pointer does not appear to be a string");
        }
        else if (allocated_size != expected_size)
        {
            FAIL("allocated string data size (" << allocated_size << ") does not match expected size (" << expected_size << ")");
        }
    }
 #endif
 }
--- a/plugins/devel/check-structures-sanity/main.cpp
+++ b/plugins/devel/check-structures-sanity/main.cpp
@ -26,6 +26,9 @@ DFhackCExport command_result plugin_init(color_ostream &, std::vector<PluginComm
        "by default, check-structures-sanity reports invalid pointers, vectors, strings, and vtables."
    ));
    known_types_by_size.clear();
    build_size_table();
    return CR_OK;
 }
--- a/plugins/devel/check-structures-sanity/types.cpp
+++ b/plugins/devel/check-structures-sanity/types.cpp
@ -20,7 +20,14 @@ CheckedStructure::CheckedStructure() :
 }
 CheckedStructure::CheckedStructure(type_identity *identity, size_t count) :
    identity(identity),
-    count(count)
+    count(count),
    eid(nullptr)
 {
 }
 CheckedStructure::CheckedStructure(type_identity *identity, size_t count, enum_identity *eid) :
    identity(identity),
    count(count),
    eid(eid)
 {
 }
 CheckedStructure::CheckedStructure(const struct_field_info *field) :
@ -31,24 +38,8 @@ CheckedStructure::CheckedStructure(const struct_field_info *field) :
        UNEXPECTED;
    }
    if (field->mode == struct_field_info::STATIC_ARRAY && field->eid)
    {
        UNEXPECTED;
    }
    else if (field->type && field->type->isContainer())
    {
        auto expected_eid = static_cast<container_identity *>(field->type)->getIndexEnumType();
        if (field->eid != expected_eid)
        {
            UNEXPECTED;
        }
    }
    else if (field->eid)
    {
        UNEXPECTED;
    }
    identity = field->type;
    eid = field->eid;
    switch (field->mode)
    {
        case struct_field_info::END:
@ -129,3 +120,15 @@ type_identity *Checker::wrap_in_pointer(type_identity *base)
 {
    RETURN_CACHED_WRAPPER(df::pointer_identity, base);
 }
 std::map<size_t, std::vector<std::string>> known_types_by_size;
 void build_size_table()
 {
    for (auto & ident : compound_identity::getTopScope())
    {
        if (ident->byte_size() >= MIN_SIZE_FOR_SUGGEST)
        {
            known_types_by_size[ident->byte_size()].push_back(ident->getFullName());
        }
    }
 }
--- a/plugins/devel/check-structures-sanity/validate.cpp
+++ b/plugins/devel/check-structures-sanity/validate.cpp
@ -1,9 +1,8 @@
 #include "check-structures-sanity.h"
-bool Checker::is_valid_dereference(const QueueItem & item, const CheckedStructure & cs, bool quiet)
+bool Checker::is_valid_dereference(const QueueItem & item, const CheckedStructure & cs, size_t size, bool quiet)
 {
    auto base = const_cast<void *>(item.ptr);
    auto size = cs.full_size();
    if (!base)
    {
        // cannot dereference null pointer, but not an error
@ -83,6 +82,47 @@ bool Checker::is_valid_dereference(const QueueItem & item, const CheckedStructur
 #undef FAIL_PTR
 }
 int64_t Checker::get_int_value(const QueueItem & item, type_identity *type, bool quiet)
 {
    if (type == df::identity_traits<int32_t>::get())
    {
        return validate_and_dereference<int32_t>(item, quiet);
    }
    else if (type == df::identity_traits<uint32_t>::get())
    {
        return validate_and_dereference<uint32_t>(item, quiet);
    }
    else if (type == df::identity_traits<int16_t>::get())
    {
        return validate_and_dereference<int16_t>(item, quiet);
    }
    else if (type == df::identity_traits<uint16_t>::get())
    {
        return validate_and_dereference<uint16_t>(item, quiet);
    }
    else if (type == df::identity_traits<int64_t>::get())
    {
        return validate_and_dereference<int64_t>(item, quiet);
    }
    else if (type == df::identity_traits<uint64_t>::get())
    {
        return int64_t(validate_and_dereference<uint64_t>(item, quiet));
    }
    else if (type == df::identity_traits<int8_t>::get())
    {
        return validate_and_dereference<int8_t>(item, quiet);
    }
    else if (type == df::identity_traits<uint8_t>::get())
    {
        return validate_and_dereference<uint8_t>(item, quiet);
    }
    else
    {
        UNEXPECTED;
        return 0;
    }
 }
 const char *Checker::get_vtable_name(const QueueItem & item, const CheckedStructure & cs, bool quiet)
 {
    auto vtable = validate_and_dereference<const void *const*>(QueueItem(item, "?vtable?", item.ptr), quiet);
@ -235,3 +275,98 @@ std::pair<const void *, size_t> Checker::validate_vector_size(const QueueItem &
    return local_ok ? std::make_pair(start_ptr, ulength / item_size) : std::make_pair(nullptr, 0);
 }
 size_t Checker::get_allocated_size(const QueueItem & item)
 {
    if (!sizes)
    {
        return 0;
    }
    uint32_t tag = *reinterpret_cast<const uint32_t *>(PTR_ADD(item.ptr, -8));
    if (tag == 0xdfdf4ac8)
    {
        return *reinterpret_cast<const size_t *>(PTR_ADD(item.ptr, -16));
    }
    return 0;
 }
 #ifndef WIN32
 const std::string *Checker::validate_stl_string_pointer(const void *const* base)
 {
    std::string empty_string;
    if (*base == *reinterpret_cast<void **>(&empty_string))
    {
        return reinterpret_cast<const std::string *>(base);
    }
    const struct string_data_inner
    {
        size_t length;
        size_t capacity;
        int32_t refcount;
    } *str_data = static_cast<const string_data_inner *>(*base) - 1;
    uint32_t tag = *reinterpret_cast<const uint32_t *>(PTR_ADD(str_data, -8));
    if (tag == 0xdfdf4ac8)
    {
        size_t allocated_size = *reinterpret_cast<const size_t *>(PTR_ADD(str_data, -16));
        size_t expected_size = sizeof(*str_data) + str_data->capacity + 1;
        if (allocated_size != expected_size)
        {
            return nullptr;
        }
    }
    else
    {
        return nullptr;
    }
    if (str_data->capacity < str_data->length)
    {
        return nullptr;
    }
    const char *ptr = reinterpret_cast<const char *>(*base);
    for (size_t i = 0; i < str_data->length; i++)
    {
        if (!*ptr++)
        {
            return nullptr;
        }
    }
    if (*ptr++)
    {
        return nullptr;
    }
    return reinterpret_cast<const std::string *>(base);
 }
 #endif
 const char *const *Checker::get_enum_item_key(enum_identity *identity, int64_t value)
 {
    size_t index;
    if (auto cplx = identity->getComplex())
    {
        auto it = cplx->value_index_map.find(value);
        if (it == cplx->value_index_map.cend())
        {
            return nullptr;
        }
        index = it->second;
    }
    else
    {
        if (value < identity->getFirstItem() || value > identity->getLastItem())
        {
            return nullptr;
        }
        index = value - identity->getFirstItem();
    }
    return &identity->getKeys()[index];
 }