// -*- mode: c++ -*- // Copyright (c) 2010 Google Inc. // All rights reserved. // // Redistribution and use in source and binary forms, with or without // modification, are permitted provided that the following conditions are // met: // // * Redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer. // * Redistributions in binary form must reproduce the above // copyright notice, this list of conditions and the following disclaimer // in the documentation and/or other materials provided with the // distribution. // * Neither the name of Google Inc. nor the names of its // contributors may be used to endorse or promote products derived from // this software without specific prior written permission. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. // stack_frame_cpu.h: CPU-specific StackFrame extensions. // // These types extend the StackFrame structure to carry CPU-specific register // state. They are defined in this header instead of stack_frame.h to // avoid the need to include minidump_format.h when only the generic // StackFrame type is needed. // // Author: Mark Mentovai #ifndef GOOGLE_BREAKPAD_PROCESSOR_STACK_FRAME_CPU_H__ #define GOOGLE_BREAKPAD_PROCESSOR_STACK_FRAME_CPU_H__ #include "google_breakpad/common/minidump_format.h" #include "google_breakpad/processor/stack_frame.h" namespace google_breakpad { struct WindowsFrameInfo; class CFIFrameInfo; struct StackFrameX86 : public StackFrame { // ContextValidity has one entry for each relevant hardware pointer // register (%eip and %esp) and one entry for each general-purpose // register. It's worthwhile having validity flags for caller-saves // registers: they are valid in the youngest frame, and such a frame // might save a callee-saves register in a caller-saves register, but // SimpleCFIWalker won't touch registers unless they're marked as valid. enum ContextValidity { CONTEXT_VALID_NONE = 0, CONTEXT_VALID_EIP = 1 << 0, CONTEXT_VALID_ESP = 1 << 1, CONTEXT_VALID_EBP = 1 << 2, CONTEXT_VALID_EAX = 1 << 3, CONTEXT_VALID_EBX = 1 << 4, CONTEXT_VALID_ECX = 1 << 5, CONTEXT_VALID_EDX = 1 << 6, CONTEXT_VALID_ESI = 1 << 7, CONTEXT_VALID_EDI = 1 << 8, CONTEXT_VALID_ALL = -1 }; StackFrameX86() : context(), context_validity(CONTEXT_VALID_NONE), windows_frame_info(NULL), cfi_frame_info(NULL) {} ~StackFrameX86(); // Overriden to return the return address as saved on the stack. virtual uint64_t ReturnAddress() const; // Register state. This is only fully valid for the topmost frame in a // stack. In other frames, the values of nonvolatile registers may be // present, given sufficient debugging information. Refer to // context_validity. MDRawContextX86 context; // context_validity is actually ContextValidity, but int is used because // the OR operator doesn't work well with enumerated types. This indicates // which fields in context are valid. int context_validity; // Any stack walking information we found describing this.instruction. // These may be NULL if there is no such information for that address. WindowsFrameInfo *windows_frame_info; CFIFrameInfo *cfi_frame_info; }; struct StackFramePPC : public StackFrame { // ContextValidity should eventually contain entries for the validity of // other nonvolatile (callee-save) registers as in // StackFrameX86::ContextValidity, but the ppc stackwalker doesn't currently // locate registers other than the ones listed here. enum ContextValidity { CONTEXT_VALID_NONE = 0, CONTEXT_VALID_SRR0 = 1 << 0, CONTEXT_VALID_GPR1 = 1 << 1, CONTEXT_VALID_ALL = -1 }; StackFramePPC() : context(), context_validity(CONTEXT_VALID_NONE) {} // Register state. This is only fully valid for the topmost frame in a // stack. In other frames, the values of nonvolatile registers may be // present, given sufficient debugging information. Refer to // context_validity. MDRawContextPPC context; // context_validity is actually ContextValidity, but int is used because // the OR operator doesn't work well with enumerated types. This indicates // which fields in context are valid. int context_validity; }; struct StackFramePPC64 : public StackFrame { // ContextValidity should eventually contain entries for the validity of // other nonvolatile (callee-save) registers as in // StackFrameX86::ContextValidity, but the ppc stackwalker doesn't currently // locate registers other than the ones listed here. enum ContextValidity { CONTEXT_VALID_NONE = 0, CONTEXT_VALID_SRR0 = 1 << 0, CONTEXT_VALID_GPR1 = 1 << 1, CONTEXT_VALID_ALL = -1 }; StackFramePPC64() : context(), context_validity(CONTEXT_VALID_NONE) {} // Register state. This is only fully valid for the topmost frame in a // stack. In other frames, the values of nonvolatile registers may be // present, given sufficient debugging information. Refer to // context_validity. MDRawContextPPC64 context; // context_validity is actually ContextValidity, but int is used because // the OR operator doesn't work well with enumerated types. This indicates // which fields in context are valid. int context_validity; }; struct StackFrameAMD64 : public StackFrame { // ContextValidity has one entry for each register that we might be able // to recover. enum ContextValidity { CONTEXT_VALID_NONE = 0, CONTEXT_VALID_RAX = 1 << 0, CONTEXT_VALID_RDX = 1 << 1, CONTEXT_VALID_RCX = 1 << 2, CONTEXT_VALID_RBX = 1 << 3, CONTEXT_VALID_RSI = 1 << 4, CONTEXT_VALID_RDI = 1 << 5, CONTEXT_VALID_RBP = 1 << 6, CONTEXT_VALID_RSP = 1 << 7, CONTEXT_VALID_R8 = 1 << 8, CONTEXT_VALID_R9 = 1 << 9, CONTEXT_VALID_R10 = 1 << 10, CONTEXT_VALID_R11 = 1 << 11, CONTEXT_VALID_R12 = 1 << 12, CONTEXT_VALID_R13 = 1 << 13, CONTEXT_VALID_R14 = 1 << 14, CONTEXT_VALID_R15 = 1 << 15, CONTEXT_VALID_RIP = 1 << 16, CONTEXT_VALID_ALL = -1 }; StackFrameAMD64() : context(), context_validity(CONTEXT_VALID_NONE) {} // Overriden to return the return address as saved on the stack. virtual uint64_t ReturnAddress() const; // Register state. This is only fully valid for the topmost frame in a // stack. In other frames, which registers are present depends on what // debugging information we had available. Refer to context_validity. MDRawContextAMD64 context; // For each register in context whose value has been recovered, we set // the corresponding CONTEXT_VALID_ bit in context_validity. // // context_validity's type should actually be ContextValidity, but // we use int instead because the bitwise inclusive or operator // yields an int when applied to enum values, and C++ doesn't // silently convert from ints to enums. int context_validity; }; struct StackFrameSPARC : public StackFrame { // to be confirmed enum ContextValidity { CONTEXT_VALID_NONE = 0, CONTEXT_VALID_PC = 1 << 0, CONTEXT_VALID_SP = 1 << 1, CONTEXT_VALID_FP = 1 << 2, CONTEXT_VALID_ALL = -1 }; StackFrameSPARC() : context(), context_validity(CONTEXT_VALID_NONE) {} // Register state. This is only fully valid for the topmost frame in a // stack. In other frames, the values of nonvolatile registers may be // present, given sufficient debugging information. Refer to // context_validity. MDRawContextSPARC context; // context_validity is actually ContextValidity, but int is used because // the OR operator doesn't work well with enumerated types. This indicates // which fields in context are valid. int context_validity; }; struct StackFrameARM : public StackFrame { // A flag for each register we might know. enum ContextValidity { CONTEXT_VALID_NONE = 0, CONTEXT_VALID_R0 = 1 << 0, CONTEXT_VALID_R1 = 1 << 1, CONTEXT_VALID_R2 = 1 << 2, CONTEXT_VALID_R3 = 1 << 3, CONTEXT_VALID_R4 = 1 << 4, CONTEXT_VALID_R5 = 1 << 5, CONTEXT_VALID_R6 = 1 << 6, CONTEXT_VALID_R7 = 1 << 7, CONTEXT_VALID_R8 = 1 << 8, CONTEXT_VALID_R9 = 1 << 9, CONTEXT_VALID_R10 = 1 << 10, CONTEXT_VALID_R11 = 1 << 11, CONTEXT_VALID_R12 = 1 << 12, CONTEXT_VALID_R13 = 1 << 13, CONTEXT_VALID_R14 = 1 << 14, CONTEXT_VALID_R15 = 1 << 15, CONTEXT_VALID_ALL = ~CONTEXT_VALID_NONE, // Aliases for registers with dedicated or conventional roles. CONTEXT_VALID_FP = CONTEXT_VALID_R11, CONTEXT_VALID_SP = CONTEXT_VALID_R13, CONTEXT_VALID_LR = CONTEXT_VALID_R14, CONTEXT_VALID_PC = CONTEXT_VALID_R15 }; StackFrameARM() : context(), context_validity(CONTEXT_VALID_NONE) {} // Return the ContextValidity flag for register rN. static ContextValidity RegisterValidFlag(int n) { return ContextValidity(1 << n); } // Register state. This is only fully valid for the topmost frame in a // stack. In other frames, the values of nonvolatile registers may be // present, given sufficient debugging information. Refer to // context_validity. MDRawContextARM context; // For each register in context whose value has been recovered, we set // the corresponding CONTEXT_VALID_ bit in context_validity. // // context_validity's type should actually be ContextValidity, but // we use int instead because the bitwise inclusive or operator // yields an int when applied to enum values, and C++ doesn't // silently convert from ints to enums. int context_validity; }; struct StackFrameARM64 : public StackFrame { // A flag for each register we might know. Note that we can't use an enum // here as there are 33 values to represent. static const uint64_t CONTEXT_VALID_NONE = 0; static const uint64_t CONTEXT_VALID_X0 = 1ULL << 0; static const uint64_t CONTEXT_VALID_X1 = 1ULL << 1; static const uint64_t CONTEXT_VALID_X2 = 1ULL << 2; static const uint64_t CONTEXT_VALID_X3 = 1ULL << 3; static const uint64_t CONTEXT_VALID_X4 = 1ULL << 4; static const uint64_t CONTEXT_VALID_X5 = 1ULL << 5; static const uint64_t CONTEXT_VALID_X6 = 1ULL << 6; static const uint64_t CONTEXT_VALID_X7 = 1ULL << 7; static const uint64_t CONTEXT_VALID_X8 = 1ULL << 8; static const uint64_t CONTEXT_VALID_X9 = 1ULL << 9; static const uint64_t CONTEXT_VALID_X10 = 1ULL << 10; static const uint64_t CONTEXT_VALID_X11 = 1ULL << 11; static const uint64_t CONTEXT_VALID_X12 = 1ULL << 12; static const uint64_t CONTEXT_VALID_X13 = 1ULL << 13; static const uint64_t CONTEXT_VALID_X14 = 1ULL << 14; static const uint64_t CONTEXT_VALID_X15 = 1ULL << 15; static const uint64_t CONTEXT_VALID_X16 = 1ULL << 16; static const uint64_t CONTEXT_VALID_X17 = 1ULL << 17; static const uint64_t CONTEXT_VALID_X18 = 1ULL << 18; static const uint64_t CONTEXT_VALID_X19 = 1ULL << 19; static const uint64_t CONTEXT_VALID_X20 = 1ULL << 20; static const uint64_t CONTEXT_VALID_X21 = 1ULL << 21; static const uint64_t CONTEXT_VALID_X22 = 1ULL << 22; static const uint64_t CONTEXT_VALID_X23 = 1ULL << 23; static const uint64_t CONTEXT_VALID_X24 = 1ULL << 24; static const uint64_t CONTEXT_VALID_X25 = 1ULL << 25; static const uint64_t CONTEXT_VALID_X26 = 1ULL << 26; static const uint64_t CONTEXT_VALID_X27 = 1ULL << 27; static const uint64_t CONTEXT_VALID_X28 = 1ULL << 28; static const uint64_t CONTEXT_VALID_X29 = 1ULL << 29; static const uint64_t CONTEXT_VALID_X30 = 1ULL << 30; static const uint64_t CONTEXT_VALID_X31 = 1ULL << 31; static const uint64_t CONTEXT_VALID_X32 = 1ULL << 32; static const uint64_t CONTEXT_VALID_ALL = ~CONTEXT_VALID_NONE; // Aliases for registers with dedicated or conventional roles. static const uint64_t CONTEXT_VALID_FP = CONTEXT_VALID_X29; static const uint64_t CONTEXT_VALID_LR = CONTEXT_VALID_X30; static const uint64_t CONTEXT_VALID_SP = CONTEXT_VALID_X31; static const uint64_t CONTEXT_VALID_PC = CONTEXT_VALID_X32; StackFrameARM64() : context(), context_validity(CONTEXT_VALID_NONE) {} // Return the validity flag for register xN. static uint64_t RegisterValidFlag(int n) { return 1ULL << n; } // Register state. This is only fully valid for the topmost frame in a // stack. In other frames, the values of nonvolatile registers may be // present, given sufficient debugging information. Refer to // context_validity. MDRawContextARM64 context; // For each register in context whose value has been recovered, we set // the corresponding CONTEXT_VALID_ bit in context_validity. uint64_t context_validity; }; struct StackFrameMIPS : public StackFrame { // MIPS callee save registers for o32 ABI (32bit registers) are: // 1. $s0-$s7, // 2. $sp, $fp // 3. $f20-$f31 // // The register structure is available at // http://en.wikipedia.org/wiki/MIPS_architecture#Compiler_register_usage #define INDEX_MIPS_REG_S0 MD_CONTEXT_MIPS_REG_S0 // 16 #define INDEX_MIPS_REG_S7 MD_CONTEXT_MIPS_REG_S7 // 23 #define INDEX_MIPS_REG_GP MD_CONTEXT_MIPS_REG_GP // 28 #define INDEX_MIPS_REG_RA MD_CONTEXT_MIPS_REG_RA // 31 #define INDEX_MIPS_REG_PC 34 #define SHIFT_MIPS_REG_S0 0 #define SHIFT_MIPS_REG_GP 8 #define SHIFT_MIPS_REG_PC 12 enum ContextValidity { CONTEXT_VALID_NONE = 0, CONTEXT_VALID_S0 = 1 << 0, // $16 CONTEXT_VALID_S1 = 1 << 1, // $17 CONTEXT_VALID_S2 = 1 << 2, // $18 CONTEXT_VALID_S3 = 1 << 3, // $19 CONTEXT_VALID_S4 = 1 << 4, // $20 CONTEXT_VALID_S5 = 1 << 5, // $21 CONTEXT_VALID_S6 = 1 << 6, // $22 CONTEXT_VALID_S7 = 1 << 7, // $23 // GP is not calee-save for o32 abi. CONTEXT_VALID_GP = 1 << 8, // $28 CONTEXT_VALID_SP = 1 << 9, // $29 CONTEXT_VALID_FP = 1 << 10, // $30 CONTEXT_VALID_RA = 1 << 11, // $31 CONTEXT_VALID_PC = 1 << 12, // $34 CONTEXT_VALID_ALL = ~CONTEXT_VALID_NONE }; // Return the ContextValidity flag for register rN. static ContextValidity RegisterValidFlag(int n) { if (n >= INDEX_MIPS_REG_S0 && n <= INDEX_MIPS_REG_S7) return ContextValidity(1 << (n - INDEX_MIPS_REG_S0 + SHIFT_MIPS_REG_S0)); else if (n >= INDEX_MIPS_REG_GP && n <= INDEX_MIPS_REG_RA) return ContextValidity(1 << (n - INDEX_MIPS_REG_GP + SHIFT_MIPS_REG_GP)); else if (n == INDEX_MIPS_REG_PC) return ContextValidity(1 << SHIFT_MIPS_REG_PC); return CONTEXT_VALID_NONE; } StackFrameMIPS() : context(), context_validity(CONTEXT_VALID_NONE) {} // Register state. This is only fully valid for the topmost frame in a // stack. In other frames, which registers are present depends on what // debugging information were available. Refer to 'context_validity' below. MDRawContextMIPS context; // For each register in context whose value has been recovered, // the corresponding CONTEXT_VALID_ bit in 'context_validity' is set. // // context_validity's type should actually be ContextValidity, but // type int is used instead because the bitwise inclusive or operator // yields an int when applied to enum values, and C++ doesn't // silently convert from ints to enums. int context_validity; }; } // namespace google_breakpad #endif // GOOGLE_BREAKPAD_PROCESSOR_STACK_FRAME_CPU_H__