//===-- llvm/CodeGen/DIEHash.cpp - Dwarf Hashing Framework ----------------===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file contains support for DWARF4 hashing of DIEs. // //===----------------------------------------------------------------------===// #define DEBUG_TYPE "dwarfdebug" #include "DIE.h" #include "DIEHash.h" #include "DwarfCompileUnit.h" #include "llvm/ADT/ArrayRef.h" #include "llvm/ADT/StringRef.h" #include "llvm/Support/Debug.h" #include "llvm/Support/Dwarf.h" #include "llvm/Support/Endian.h" #include "llvm/Support/MD5.h" #include "llvm/Support/raw_ostream.h" using namespace llvm; /// \brief Grabs the string in whichever attribute is passed in and returns /// a reference to it. static StringRef getDIEStringAttr(DIE *Die, uint16_t Attr) { const SmallVectorImpl &Values = Die->getValues(); const DIEAbbrev &Abbrevs = Die->getAbbrev(); // Iterate through all the attributes until we find the one we're // looking for, if we can't find it return an empty string. for (size_t i = 0; i < Values.size(); ++i) { if (Abbrevs.getData()[i].getAttribute() == Attr) { DIEValue *V = Values[i]; assert(isa(V) && "String requested. Not a string."); DIEString *S = cast(V); return S->getString(); } } return StringRef(""); } /// \brief Adds the string in \p Str to the hash. This also hashes /// a trailing NULL with the string. void DIEHash::addString(StringRef Str) { DEBUG(dbgs() << "Adding string " << Str << " to hash.\n"); Hash.update(Str); Hash.update(makeArrayRef((uint8_t)'\0')); } // FIXME: The LEB128 routines are copied and only slightly modified out of // LEB128.h. /// \brief Adds the unsigned in \p Value to the hash encoded as a ULEB128. void DIEHash::addULEB128(uint64_t Value) { DEBUG(dbgs() << "Adding ULEB128 " << Value << " to hash.\n"); do { uint8_t Byte = Value & 0x7f; Value >>= 7; if (Value != 0) Byte |= 0x80; // Mark this byte to show that more bytes will follow. Hash.update(Byte); } while (Value != 0); } /// \brief Including \p Parent adds the context of Parent to the hash.. void DIEHash::addParentContext(DIE *Parent) { DEBUG(dbgs() << "Adding parent context to hash...\n"); // [7.27.2] For each surrounding type or namespace beginning with the // outermost such construct... SmallVector Parents; while (Parent->getTag() != dwarf::DW_TAG_compile_unit) { Parents.push_back(Parent); Parent = Parent->getParent(); } // Reverse iterate over our list to go from the outermost construct to the // innermost. for (SmallVectorImpl::reverse_iterator I = Parents.rbegin(), E = Parents.rend(); I != E; ++I) { DIE *Die = *I; // ... Append the letter "C" to the sequence... addULEB128('C'); // ... Followed by the DWARF tag of the construct... addULEB128(Die->getTag()); // ... Then the name, taken from the DW_AT_name attribute. StringRef Name = getDIEStringAttr(Die, dwarf::DW_AT_name); DEBUG(dbgs() << "... adding context: " << Name << "\n"); if (!Name.empty()) addString(Name); } } // Collect all of the attributes for a particular DIE in single structure. void DIEHash::collectAttributes(DIE *Die, DIEAttrs &Attrs) { const SmallVectorImpl &Values = Die->getValues(); const DIEAbbrev &Abbrevs = Die->getAbbrev(); #define COLLECT_ATTR(NAME) \ Attrs.NAME.Val = Values[i]; \ Attrs.NAME.Desc = &Abbrevs.getData()[i]; for (size_t i = 0, e = Values.size(); i != e; ++i) { DEBUG(dbgs() << "Attribute: " << dwarf::AttributeString(Abbrevs.getData()[i].getAttribute()) << " added.\n"); switch (Abbrevs.getData()[i].getAttribute()) { case dwarf::DW_AT_name: COLLECT_ATTR(DW_AT_name); break; case dwarf::DW_AT_accessibility: COLLECT_ATTR(DW_AT_accessibility) break; case dwarf::DW_AT_address_class: COLLECT_ATTR(DW_AT_address_class) break; case dwarf::DW_AT_allocated: COLLECT_ATTR(DW_AT_allocated) break; case dwarf::DW_AT_artificial: COLLECT_ATTR(DW_AT_artificial) break; case dwarf::DW_AT_associated: COLLECT_ATTR(DW_AT_associated) break; case dwarf::DW_AT_binary_scale: COLLECT_ATTR(DW_AT_binary_scale) break; case dwarf::DW_AT_bit_offset: COLLECT_ATTR(DW_AT_bit_offset) break; case dwarf::DW_AT_bit_size: COLLECT_ATTR(DW_AT_bit_size) break; case dwarf::DW_AT_bit_stride: COLLECT_ATTR(DW_AT_bit_stride) break; case dwarf::DW_AT_byte_size: COLLECT_ATTR(DW_AT_byte_size) break; case dwarf::DW_AT_byte_stride: COLLECT_ATTR(DW_AT_byte_stride) break; case dwarf::DW_AT_const_expr: COLLECT_ATTR(DW_AT_const_expr) break; case dwarf::DW_AT_const_value: COLLECT_ATTR(DW_AT_const_value) break; case dwarf::DW_AT_containing_type: COLLECT_ATTR(DW_AT_containing_type) break; case dwarf::DW_AT_count: COLLECT_ATTR(DW_AT_count) break; case dwarf::DW_AT_data_bit_offset: COLLECT_ATTR(DW_AT_data_bit_offset) break; case dwarf::DW_AT_data_location: COLLECT_ATTR(DW_AT_data_location) break; case dwarf::DW_AT_data_member_location: COLLECT_ATTR(DW_AT_data_member_location) break; case dwarf::DW_AT_decimal_scale: COLLECT_ATTR(DW_AT_decimal_scale) break; case dwarf::DW_AT_decimal_sign: COLLECT_ATTR(DW_AT_decimal_sign) break; case dwarf::DW_AT_default_value: COLLECT_ATTR(DW_AT_default_value) break; case dwarf::DW_AT_digit_count: COLLECT_ATTR(DW_AT_digit_count) break; case dwarf::DW_AT_discr: COLLECT_ATTR(DW_AT_discr) break; case dwarf::DW_AT_discr_list: COLLECT_ATTR(DW_AT_discr_list) break; case dwarf::DW_AT_discr_value: COLLECT_ATTR(DW_AT_discr_value) break; case dwarf::DW_AT_encoding: COLLECT_ATTR(DW_AT_encoding) break; case dwarf::DW_AT_enum_class: COLLECT_ATTR(DW_AT_enum_class) break; case dwarf::DW_AT_endianity: COLLECT_ATTR(DW_AT_endianity) break; case dwarf::DW_AT_explicit: COLLECT_ATTR(DW_AT_explicit) break; case dwarf::DW_AT_is_optional: COLLECT_ATTR(DW_AT_is_optional) break; case dwarf::DW_AT_location: COLLECT_ATTR(DW_AT_location) break; case dwarf::DW_AT_lower_bound: COLLECT_ATTR(DW_AT_lower_bound) break; case dwarf::DW_AT_mutable: COLLECT_ATTR(DW_AT_mutable) break; case dwarf::DW_AT_ordering: COLLECT_ATTR(DW_AT_ordering) break; case dwarf::DW_AT_picture_string: COLLECT_ATTR(DW_AT_picture_string) break; case dwarf::DW_AT_prototyped: COLLECT_ATTR(DW_AT_prototyped) break; case dwarf::DW_AT_small: COLLECT_ATTR(DW_AT_small) break; case dwarf::DW_AT_segment: COLLECT_ATTR(DW_AT_segment) break; case dwarf::DW_AT_string_length: COLLECT_ATTR(DW_AT_string_length) break; case dwarf::DW_AT_threads_scaled: COLLECT_ATTR(DW_AT_threads_scaled) break; case dwarf::DW_AT_upper_bound: COLLECT_ATTR(DW_AT_upper_bound) break; case dwarf::DW_AT_use_location: COLLECT_ATTR(DW_AT_use_location) break; case dwarf::DW_AT_use_UTF8: COLLECT_ATTR(DW_AT_use_UTF8) break; case dwarf::DW_AT_variable_parameter: COLLECT_ATTR(DW_AT_variable_parameter) break; case dwarf::DW_AT_virtuality: COLLECT_ATTR(DW_AT_virtuality) break; case dwarf::DW_AT_visibility: COLLECT_ATTR(DW_AT_visibility) break; case dwarf::DW_AT_vtable_elem_location: COLLECT_ATTR(DW_AT_vtable_elem_location) break; default: break; } } } // Hash an individual attribute \param Attr based on the type of attribute and // the form. void DIEHash::hashAttribute(AttrEntry Attr) { const DIEValue *Value = Attr.Val; const DIEAbbrevData *Desc = Attr.Desc; // TODO: Add support for types. // Add the letter A to the hash. addULEB128('A'); // Then the attribute code and form. addULEB128(Desc->getAttribute()); addULEB128(Desc->getForm()); // TODO: Add support for additional forms. switch (Desc->getForm()) { // TODO: We'll want to add DW_FORM_string here if we start emitting them // again. case dwarf::DW_FORM_strp: addString(cast(Value)->getString()); break; case dwarf::DW_FORM_data1: case dwarf::DW_FORM_data2: case dwarf::DW_FORM_data4: case dwarf::DW_FORM_data8: case dwarf::DW_FORM_udata: addULEB128(cast(Value)->getValue()); break; } } // Go through the attributes from \param Attrs in the order specified in 7.27.4 // and hash them. void DIEHash::hashAttributes(const DIEAttrs &Attrs) { #define ADD_ATTR(ATTR) \ { \ if (ATTR.Val != 0) \ hashAttribute(ATTR); \ } ADD_ATTR(Attrs.DW_AT_name); ADD_ATTR(Attrs.DW_AT_accessibility); ADD_ATTR(Attrs.DW_AT_address_class); ADD_ATTR(Attrs.DW_AT_allocated); ADD_ATTR(Attrs.DW_AT_artificial); ADD_ATTR(Attrs.DW_AT_associated); ADD_ATTR(Attrs.DW_AT_binary_scale); ADD_ATTR(Attrs.DW_AT_bit_offset); ADD_ATTR(Attrs.DW_AT_bit_size); ADD_ATTR(Attrs.DW_AT_bit_stride); ADD_ATTR(Attrs.DW_AT_byte_size); ADD_ATTR(Attrs.DW_AT_byte_stride); ADD_ATTR(Attrs.DW_AT_const_expr); ADD_ATTR(Attrs.DW_AT_const_value); ADD_ATTR(Attrs.DW_AT_containing_type); ADD_ATTR(Attrs.DW_AT_count); ADD_ATTR(Attrs.DW_AT_data_bit_offset); ADD_ATTR(Attrs.DW_AT_data_location); ADD_ATTR(Attrs.DW_AT_data_member_location); ADD_ATTR(Attrs.DW_AT_decimal_scale); ADD_ATTR(Attrs.DW_AT_decimal_sign); ADD_ATTR(Attrs.DW_AT_default_value); ADD_ATTR(Attrs.DW_AT_digit_count); ADD_ATTR(Attrs.DW_AT_discr); ADD_ATTR(Attrs.DW_AT_discr_list); ADD_ATTR(Attrs.DW_AT_discr_value); ADD_ATTR(Attrs.DW_AT_encoding); ADD_ATTR(Attrs.DW_AT_enum_class); ADD_ATTR(Attrs.DW_AT_endianity); ADD_ATTR(Attrs.DW_AT_explicit); ADD_ATTR(Attrs.DW_AT_is_optional); ADD_ATTR(Attrs.DW_AT_location); ADD_ATTR(Attrs.DW_AT_lower_bound); ADD_ATTR(Attrs.DW_AT_mutable); ADD_ATTR(Attrs.DW_AT_ordering); ADD_ATTR(Attrs.DW_AT_picture_string); ADD_ATTR(Attrs.DW_AT_prototyped); ADD_ATTR(Attrs.DW_AT_small); ADD_ATTR(Attrs.DW_AT_segment); ADD_ATTR(Attrs.DW_AT_string_length); ADD_ATTR(Attrs.DW_AT_threads_scaled); ADD_ATTR(Attrs.DW_AT_upper_bound); ADD_ATTR(Attrs.DW_AT_use_location); ADD_ATTR(Attrs.DW_AT_use_UTF8); ADD_ATTR(Attrs.DW_AT_variable_parameter); ADD_ATTR(Attrs.DW_AT_virtuality); ADD_ATTR(Attrs.DW_AT_visibility); ADD_ATTR(Attrs.DW_AT_vtable_elem_location); // FIXME: Add the extended attributes. } // Add all of the attributes for \param Die to the hash. void DIEHash::addAttributes(DIE *Die) { DIEAttrs Attrs; memset(&Attrs, 0, sizeof(Attrs)); collectAttributes(Die, Attrs); hashAttributes(Attrs); } // Compute the hash of a DIE. This is based on the type signature computation // given in section 7.27 of the DWARF4 standard. It is the md5 hash of a // flattened description of the DIE. void DIEHash::computeHash(DIE *Die) { // Append the letter 'D', followed by the DWARF tag of the DIE. addULEB128('D'); addULEB128(Die->getTag()); // Add each of the attributes of the DIE. addAttributes(Die); // Then hash each of the children of the DIE. for (std::vector::const_iterator I = Die->getChildren().begin(), E = Die->getChildren().end(); I != E; ++I) computeHash(*I); } /// This is based on the type signature computation given in section 7.27 of the /// DWARF4 standard. It is the md5 hash of a flattened description of the DIE /// with the exception that we are hashing only the context and the name of the /// type. uint64_t DIEHash::computeDIEODRSignature(DIE *Die) { // Add the contexts to the hash. We won't be computing the ODR hash for // function local types so it's safe to use the generic context hashing // algorithm here. // FIXME: If we figure out how to account for linkage in some way we could // actually do this with a slight modification to the parent hash algorithm. DIE *Parent = Die->getParent(); if (Parent) addParentContext(Parent); // Add the current DIE information. // Add the DWARF tag of the DIE. addULEB128(Die->getTag()); // Add the name of the type to the hash. addString(getDIEStringAttr(Die, dwarf::DW_AT_name)); // Now get the result. MD5::MD5Result Result; Hash.final(Result); // ... take the least significant 8 bytes and return those. Our MD5 // implementation always returns its results in little endian, swap bytes // appropriately. return *reinterpret_cast(Result + 8); } /// This is based on the type signature computation given in section 7.27 of the /// DWARF4 standard. It is an md5 hash of the flattened description of the DIE /// with the inclusion of the full CU and all top level CU entities. // TODO: Initialize the type chain at 0 instead of 1 for CU signatures. uint64_t DIEHash::computeCUSignature(DIE *Die) { // Hash the DIE. computeHash(Die); // Now return the result. MD5::MD5Result Result; Hash.final(Result); // ... take the least significant 8 bytes and return those. Our MD5 // implementation always returns its results in little endian, swap bytes // appropriately. return *reinterpret_cast(Result + 8); } /// This is based on the type signature computation given in section 7.27 of the /// DWARF4 standard. It is an md5 hash of the flattened description of the DIE /// with the inclusion of additional forms not specifically called out in the /// standard. uint64_t DIEHash::computeTypeSignature(DIE *Die) { // Hash the DIE. computeHash(Die); // Now return the result. MD5::MD5Result Result; Hash.final(Result); // ... take the least significant 8 bytes and return those. Our MD5 // implementation always returns its results in little endian, swap bytes // appropriately. return *reinterpret_cast(Result + 8); }