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// Copyright 2015 Ted Mielczarek. See the COPYRIGHT
// file at the top-level directory of this distribution.
//! CPU contexts.
use num_traits::FromPrimitive;
use scroll::Pread;
use std::collections::HashSet;
use std::fmt;
use std::io;
use std::io::prelude::*;
use std::mem;
use tracing::warn;
use crate::iostuff::*;
use crate::{MinidumpMiscInfo, MinidumpSystemInfo};
use minidump_common::format as md;
use minidump_common::format::ContextFlagsCpu;
/// The CPU-specific context structure.
#[derive(Debug, Clone)]
#[cfg_attr(feature = "arbitrary_impls", derive(arbitrary::Arbitrary))]
pub enum MinidumpRawContext {
X86(md::CONTEXT_X86),
Ppc(md::CONTEXT_PPC),
Ppc64(md::CONTEXT_PPC64),
Amd64(md::CONTEXT_AMD64),
Sparc(md::CONTEXT_SPARC),
Arm(md::CONTEXT_ARM),
Arm64(md::CONTEXT_ARM64),
OldArm64(md::CONTEXT_ARM64_OLD),
Mips(md::CONTEXT_MIPS),
}
/// Generic over the specifics of a CPU context.
pub trait CpuContext {
/// The word size of general-purpose registers in the context.
type Register: fmt::LowerHex;
/// General purpose registers in this context type.
const REGISTERS: &'static [&'static str];
/// Gets whether the given register is valid
///
/// This is exposed so that the context can map aliases. For instance
/// "lr" and "x30" are aliases in ARM64.
fn register_is_valid(&self, reg: &str, valid: &MinidumpContextValidity) -> bool {
if let MinidumpContextValidity::Some(ref which) = *valid {
which.contains(reg)
} else {
self.memoize_register(reg).is_some()
}
}
/// Get a register value if it is valid.
///
/// Get the value of the register named `reg` from this CPU context
/// if `valid` indicates that it has a valid value, otherwise return
/// `None`.
fn get_register(&self, reg: &str, valid: &MinidumpContextValidity) -> Option<Self::Register> {
if self.register_is_valid(reg, valid) {
Some(self.get_register_always(reg))
} else {
None
}
}
/// Get a register value regardless of whether it is valid.
fn get_register_always(&self, reg: &str) -> Self::Register;
/// Set a register value, if that register name it exists.
///
/// Returns None if the register name isn't supported.
fn set_register(&mut self, reg: &str, val: Self::Register) -> Option<()>;
/// Gets a static version of the given register name, if possible.
///
/// Returns the default name of the register for register name aliases.
fn memoize_register(&self, reg: &str) -> Option<&'static str> {
default_memoize_register(Self::REGISTERS, reg)
}
/// Return a String containing the value of `reg` formatted to its natural width.
fn format_register(&self, reg: &str) -> String {
format!(
"0x{:01$x}",
self.get_register_always(reg),
mem::size_of::<Self::Register>() * 2
)
}
/// An iterator over all registers in this context.
///
/// This iterator yields registers and values regardless of whether the register is valid. To
/// get valid values, use [`valid_registers`](Self::valid_registers), instead.
fn registers(&self) -> CpuRegisters<'_, Self> {
self.valid_registers(&MinidumpContextValidity::All)
}
/// An iterator over valid registers in this context.
///
/// This iterator yields valid registers and their values.
fn valid_registers<'a>(&'a self, valid: &'a MinidumpContextValidity) -> CpuRegisters<'a, Self> {
let regs = match valid {
MinidumpContextValidity::All => CpuRegistersInner::Slice(Self::REGISTERS.iter()),
MinidumpContextValidity::Some(valid) => CpuRegistersInner::Set(valid.iter()),
};
CpuRegisters {
regs,
context: self,
}
}
/// Gets the name of the stack pointer register (for use with get_register/set_register).
fn stack_pointer_register_name(&self) -> &'static str;
/// Gets the name of the instruction pointer register (for use with get_register/set_register).
fn instruction_pointer_register_name(&self) -> &'static str;
}
/// Default implementation for `CpuContext::memoize_register`.
fn default_memoize_register(registers: &[&'static str], reg: &str) -> Option<&'static str> {
let idx = registers.iter().position(|val| *val == reg)?;
Some(registers[idx])
}
#[derive(Debug, Clone)]
enum CpuRegistersInner<'a> {
Slice(std::slice::Iter<'a, &'static str>),
Set(std::collections::hash_set::Iter<'a, &'static str>),
}
/// An iterator over registers and values in a [`CpuContext`].
///
/// Returned by [`CpuContext::registers`] and [`CpuContext::valid_registers`].
#[derive(Clone, Debug)]
pub struct CpuRegisters<'a, T: ?Sized> {
regs: CpuRegistersInner<'a>,
context: &'a T,
}
impl<'a, T> Iterator for CpuRegisters<'a, T>
where
T: CpuContext,
{
type Item = (&'static str, T::Register);
fn next(&mut self) -> Option<Self::Item> {
let reg = match &mut self.regs {
CpuRegistersInner::Slice(iter) => iter.next(),
CpuRegistersInner::Set(iter) => iter.next(),
}?;
Some((reg, self.context.get_register_always(reg)))
}
}
impl CpuContext for md::CONTEXT_X86 {
type Register = u32;
const REGISTERS: &'static [&'static str] = &[
"eip", "esp", "ebp", "ebx", "esi", "edi", "eax", "ecx", "edx", "eflags",
];
fn get_register_always(&self, reg: &str) -> u32 {
match reg {
"eip" => self.eip,
"esp" => self.esp,
"ebp" => self.ebp,
"ebx" => self.ebx,
"esi" => self.esi,
"edi" => self.edi,
"eax" => self.eax,
"ecx" => self.ecx,
"edx" => self.edx,
"eflags" => self.eflags,
_ => unreachable!("Invalid x86 register! {}", reg),
}
}
fn set_register(&mut self, reg: &str, val: Self::Register) -> Option<()> {
match reg {
"eip" => self.eip = val,
"esp" => self.esp = val,
"ebp" => self.ebp = val,
"ebx" => self.ebx = val,
"esi" => self.esi = val,
"edi" => self.edi = val,
"eax" => self.eax = val,
"ecx" => self.ecx = val,
"edx" => self.edx = val,
"eflags" => self.eflags = val,
_ => return None,
}
Some(())
}
fn stack_pointer_register_name(&self) -> &'static str {
"esp"
}
fn instruction_pointer_register_name(&self) -> &'static str {
"eip"
}
}
impl CpuContext for md::CONTEXT_AMD64 {
type Register = u64;
const REGISTERS: &'static [&'static str] = &[
"rax", "rdx", "rcx", "rbx", "rsi", "rdi", "rbp", "rsp", "r8", "r9", "r10", "r11", "r12",
"r13", "r14", "r15", "rip",
];
fn get_register_always(&self, reg: &str) -> u64 {
match reg {
"rax" => self.rax,
"rdx" => self.rdx,
"rcx" => self.rcx,
"rbx" => self.rbx,
"rsi" => self.rsi,
"rdi" => self.rdi,
"rbp" => self.rbp,
"rsp" => self.rsp,
"r8" => self.r8,
"r9" => self.r9,
"r10" => self.r10,
"r11" => self.r11,
"r12" => self.r12,
"r13" => self.r13,
"r14" => self.r14,
"r15" => self.r15,
"rip" => self.rip,
_ => unreachable!("Invalid x86-64 register! {}", reg),
}
}
fn set_register(&mut self, reg: &str, val: Self::Register) -> Option<()> {
match reg {
"rax" => self.rax = val,
"rdx" => self.rdx = val,
"rcx" => self.rcx = val,
"rbx" => self.rbx = val,
"rsi" => self.rsi = val,
"rdi" => self.rdi = val,
"rbp" => self.rbp = val,
"rsp" => self.rsp = val,
"r8" => self.r8 = val,
"r9" => self.r9 = val,
"r10" => self.r10 = val,
"r11" => self.r11 = val,
"r12" => self.r12 = val,
"r13" => self.r13 = val,
"r14" => self.r14 = val,
"r15" => self.r15 = val,
"rip" => self.rip = val,
_ => return None,
}
Some(())
}
fn stack_pointer_register_name(&self) -> &'static str {
"rsp"
}
fn instruction_pointer_register_name(&self) -> &'static str {
"rip"
}
}
impl CpuContext for md::CONTEXT_ARM {
type Register = u32;
const REGISTERS: &'static [&'static str] = &[
"r0", "r1", "r2", "r3", "r4", "r5", "r6", "r7", "r8", "r9", "r10", "r12", "fp", "sp", "lr",
"pc",
];
fn memoize_register(&self, reg: &str) -> Option<&'static str> {
match reg {
"r11" => Some("fp"),
"r13" => Some("sp"),
"r14" => Some("lr"),
"r15" => Some("pc"),
_ => default_memoize_register(Self::REGISTERS, reg),
}
}
fn register_is_valid(&self, reg: &str, valid: &MinidumpContextValidity) -> bool {
if let MinidumpContextValidity::Some(ref which) = valid {
match reg {
"r11" | "fp" => which.contains("r11") || which.contains("fp"),
"r13" | "sp" => which.contains("r13") || which.contains("sp"),
"r14" | "lr" => which.contains("r14") || which.contains("lr"),
"r15" | "pc" => which.contains("r15") || which.contains("pc"),
_ => which.contains(reg),
}
} else {
self.memoize_register(reg).is_some()
}
}
fn get_register_always(&self, reg: &str) -> u32 {
match reg {
"r0" => self.iregs[0],
"r1" => self.iregs[1],
"r2" => self.iregs[2],
"r3" => self.iregs[3],
"r4" => self.iregs[4],
"r5" => self.iregs[5],
"r6" => self.iregs[6],
"r7" => self.iregs[7],
"r8" => self.iregs[8],
"r9" => self.iregs[9],
"r10" => self.iregs[10],
"r11" => self.iregs[11],
"r12" => self.iregs[12],
"r13" => self.iregs[13],
"r14" => self.iregs[14],
"r15" => self.iregs[15],
"pc" => self.iregs[md::ArmRegisterNumbers::ProgramCounter as usize],
"lr" => self.iregs[md::ArmRegisterNumbers::LinkRegister as usize],
"fp" => self.iregs[md::ArmRegisterNumbers::FramePointer as usize],
"sp" => self.iregs[md::ArmRegisterNumbers::StackPointer as usize],
_ => unreachable!("Invalid arm register! {}", reg),
}
}
fn set_register(&mut self, reg: &str, val: Self::Register) -> Option<()> {
match reg {
"r0" => self.iregs[0] = val,
"r1" => self.iregs[1] = val,
"r2" => self.iregs[2] = val,
"r3" => self.iregs[3] = val,
"r4" => self.iregs[4] = val,
"r5" => self.iregs[5] = val,
"r6" => self.iregs[6] = val,
"r7" => self.iregs[7] = val,
"r8" => self.iregs[8] = val,
"r9" => self.iregs[9] = val,
"r10" => self.iregs[10] = val,
"r11" => self.iregs[11] = val,
"r12" => self.iregs[12] = val,
"r13" => self.iregs[13] = val,
"r14" => self.iregs[14] = val,
"r15" => self.iregs[15] = val,
"pc" => self.iregs[md::ArmRegisterNumbers::ProgramCounter as usize] = val,
"lr" => self.iregs[md::ArmRegisterNumbers::LinkRegister as usize] = val,
"fp" => self.iregs[md::ArmRegisterNumbers::FramePointer as usize] = val,
"sp" => self.iregs[md::ArmRegisterNumbers::StackPointer as usize] = val,
_ => return None,
}
Some(())
}
fn stack_pointer_register_name(&self) -> &'static str {
"sp"
}
fn instruction_pointer_register_name(&self) -> &'static str {
"pc"
}
}
impl CpuContext for md::CONTEXT_ARM64_OLD {
type Register = u64;
const REGISTERS: &'static [&'static str] = &[
"x0", "x1", "x2", "x3", "x4", "x5", "x6", "x7", "x8", "x9", "x10", "x11", "x12", "x13",
"x14", "x15", "x16", "x17", "x18", "x19", "x20", "x21", "x22", "x23", "x24", "x25", "x26",
"x27", "x28", "fp", "lr", "sp", "pc",
];
fn memoize_register(&self, reg: &str) -> Option<&'static str> {
match reg {
"x29" => Some("fp"),
"x30" => Some("lr"),
_ => default_memoize_register(Self::REGISTERS, reg),
}
}
fn register_is_valid(&self, reg: &str, valid: &MinidumpContextValidity) -> bool {
if let MinidumpContextValidity::Some(ref which) = valid {
match reg {
"x29" | "fp" => which.contains("x29") || which.contains("fp"),
"x30" | "lr" => which.contains("x30") || which.contains("lr"),
_ => which.contains(reg),
}
} else {
self.memoize_register(reg).is_some()
}
}
fn get_register_always(&self, reg: &str) -> u64 {
match reg {
"x0" => self.iregs[0],
"x1" => self.iregs[1],
"x2" => self.iregs[2],
"x3" => self.iregs[3],
"x4" => self.iregs[4],
"x5" => self.iregs[5],
"x6" => self.iregs[6],
"x7" => self.iregs[7],
"x8" => self.iregs[8],
"x9" => self.iregs[9],
"x10" => self.iregs[10],
"x11" => self.iregs[11],
"x12" => self.iregs[12],
"x13" => self.iregs[13],
"x14" => self.iregs[14],
"x15" => self.iregs[15],
"x16" => self.iregs[16],
"x17" => self.iregs[17],
"x18" => self.iregs[18],
"x19" => self.iregs[19],
"x20" => self.iregs[20],
"x21" => self.iregs[21],
"x22" => self.iregs[22],
"x23" => self.iregs[23],
"x24" => self.iregs[24],
"x25" => self.iregs[25],
"x26" => self.iregs[26],
"x27" => self.iregs[27],
"x28" => self.iregs[28],
"x29" => self.iregs[29],
"x30" => self.iregs[30],
"pc" => self.pc,
"sp" => self.sp,
"lr" => self.iregs[md::Arm64RegisterNumbers::LinkRegister as usize],
"fp" => self.iregs[md::Arm64RegisterNumbers::FramePointer as usize],
_ => unreachable!("Invalid aarch64 register! {}", reg),
}
}
fn set_register(&mut self, reg: &str, val: Self::Register) -> Option<()> {
match reg {
"x0" => self.iregs[0] = val,
"x1" => self.iregs[1] = val,
"x2" => self.iregs[2] = val,
"x3" => self.iregs[3] = val,
"x4" => self.iregs[4] = val,
"x5" => self.iregs[5] = val,
"x6" => self.iregs[6] = val,
"x7" => self.iregs[7] = val,
"x8" => self.iregs[8] = val,
"x9" => self.iregs[9] = val,
"x10" => self.iregs[10] = val,
"x11" => self.iregs[11] = val,
"x12" => self.iregs[12] = val,
"x13" => self.iregs[13] = val,
"x14" => self.iregs[14] = val,
"x15" => self.iregs[15] = val,
"x16" => self.iregs[16] = val,
"x17" => self.iregs[17] = val,
"x18" => self.iregs[18] = val,
"x19" => self.iregs[19] = val,
"x20" => self.iregs[20] = val,
"x21" => self.iregs[21] = val,
"x22" => self.iregs[22] = val,
"x23" => self.iregs[23] = val,
"x24" => self.iregs[24] = val,
"x25" => self.iregs[25] = val,
"x26" => self.iregs[26] = val,
"x27" => self.iregs[27] = val,
"x28" => self.iregs[28] = val,
"x29" => self.iregs[29] = val,
"x30" => self.iregs[30] = val,
"pc" => self.pc = val,
"sp" => self.sp = val,
"lr" => self.iregs[md::Arm64RegisterNumbers::LinkRegister as usize] = val,
"fp" => self.iregs[md::Arm64RegisterNumbers::FramePointer as usize] = val,
_ => return None,
}
Some(())
}
fn stack_pointer_register_name(&self) -> &'static str {
"sp"
}
fn instruction_pointer_register_name(&self) -> &'static str {
"pc"
}
}
impl CpuContext for md::CONTEXT_ARM64 {
type Register = u64;
const REGISTERS: &'static [&'static str] = &[
"x0", "x1", "x2", "x3", "x4", "x5", "x6", "x7", "x8", "x9", "x10", "x11", "x12", "x13",
"x14", "x15", "x16", "x17", "x18", "x19", "x20", "x21", "x22", "x23", "x24", "x25", "x26",
"x27", "x28", "fp", "lr", "sp", "pc",
];
fn memoize_register(&self, reg: &str) -> Option<&'static str> {
match reg {
"x29" => Some("fp"),
"x30" => Some("lr"),
_ => default_memoize_register(Self::REGISTERS, reg),
}
}
fn register_is_valid(&self, reg: &str, valid: &MinidumpContextValidity) -> bool {
if let MinidumpContextValidity::Some(ref which) = valid {
match reg {
"x29" | "fp" => which.contains("x29") || which.contains("fp"),
"x30" | "lr" => which.contains("x30") || which.contains("lr"),
_ => which.contains(reg),
}
} else {
self.memoize_register(reg).is_some()
}
}
fn get_register_always(&self, reg: &str) -> u64 {
match reg {
"x0" => self.iregs[0],
"x1" => self.iregs[1],
"x2" => self.iregs[2],
"x3" => self.iregs[3],
"x4" => self.iregs[4],
"x5" => self.iregs[5],
"x6" => self.iregs[6],
"x7" => self.iregs[7],
"x8" => self.iregs[8],
"x9" => self.iregs[9],
"x10" => self.iregs[10],
"x11" => self.iregs[11],
"x12" => self.iregs[12],
"x13" => self.iregs[13],
"x14" => self.iregs[14],
"x15" => self.iregs[15],
"x16" => self.iregs[16],
"x17" => self.iregs[17],
"x18" => self.iregs[18],
"x19" => self.iregs[19],
"x20" => self.iregs[20],
"x21" => self.iregs[21],
"x22" => self.iregs[22],
"x23" => self.iregs[23],
"x24" => self.iregs[24],
"x25" => self.iregs[25],
"x26" => self.iregs[26],
"x27" => self.iregs[27],
"x28" => self.iregs[28],
"x29" => self.iregs[29],
"x30" => self.iregs[30],
"pc" => self.pc,
"sp" => self.sp,
"lr" => self.iregs[md::Arm64RegisterNumbers::LinkRegister as usize],
"fp" => self.iregs[md::Arm64RegisterNumbers::FramePointer as usize],
_ => unreachable!("Invalid aarch64 register! {}", reg),
}
}
fn set_register(&mut self, reg: &str, val: Self::Register) -> Option<()> {
match reg {
"x0" => self.iregs[0] = val,
"x1" => self.iregs[1] = val,
"x2" => self.iregs[2] = val,
"x3" => self.iregs[3] = val,
"x4" => self.iregs[4] = val,
"x5" => self.iregs[5] = val,
"x6" => self.iregs[6] = val,
"x7" => self.iregs[7] = val,
"x8" => self.iregs[8] = val,
"x9" => self.iregs[9] = val,
"x10" => self.iregs[10] = val,
"x11" => self.iregs[11] = val,
"x12" => self.iregs[12] = val,
"x13" => self.iregs[13] = val,
"x14" => self.iregs[14] = val,
"x15" => self.iregs[15] = val,
"x16" => self.iregs[16] = val,
"x17" => self.iregs[17] = val,
"x18" => self.iregs[18] = val,
"x19" => self.iregs[19] = val,
"x20" => self.iregs[20] = val,
"x21" => self.iregs[21] = val,
"x22" => self.iregs[22] = val,
"x23" => self.iregs[23] = val,
"x24" => self.iregs[24] = val,
"x25" => self.iregs[25] = val,
"x26" => self.iregs[26] = val,
"x27" => self.iregs[27] = val,
"x28" => self.iregs[28] = val,
"x29" => self.iregs[29] = val,
"x30" => self.iregs[30] = val,
"pc" => self.pc = val,
"sp" => self.sp = val,
"lr" => self.iregs[md::Arm64RegisterNumbers::LinkRegister as usize] = val,
"fp" => self.iregs[md::Arm64RegisterNumbers::FramePointer as usize] = val,
_ => return None,
}
Some(())
}
fn stack_pointer_register_name(&self) -> &'static str {
"sp"
}
fn instruction_pointer_register_name(&self) -> &'static str {
"pc"
}
}
impl CpuContext for md::CONTEXT_PPC {
type Register = u32;
const REGISTERS: &'static [&'static str] = &[
"srr0", "srr1", "r0", "r1", "r2", "r3", "r4", "r5", "r6", "r7", "r8", "r9", "r10", "r11",
"r12", "r13", "r14", "r15", "r16", "r17", "r18", "r19", "r20", "r21", "r22", "r23", "r24",
"r25", "r26", "r27", "r28", "r29", "r30", "r31", "cr", "xer", "lr", "ctr", "mq", "vrsave",
];
fn get_register_always(&self, reg: &str) -> Self::Register {
match reg {
"srr0" => self.srr0,
"srr1" => self.srr1,
"r0" => self.gpr[0],
"r1" => self.gpr[1],
"r2" => self.gpr[2],
"r3" => self.gpr[3],
"r4" => self.gpr[4],
"r5" => self.gpr[5],
"r6" => self.gpr[6],
"r7" => self.gpr[7],
"r8" => self.gpr[8],
"r9" => self.gpr[9],
"r10" => self.gpr[10],
"r11" => self.gpr[11],
"r12" => self.gpr[12],
"r13" => self.gpr[13],
"r14" => self.gpr[14],
"r15" => self.gpr[15],
"r16" => self.gpr[16],
"r17" => self.gpr[17],
"r18" => self.gpr[18],
"r19" => self.gpr[19],
"r20" => self.gpr[20],
"r21" => self.gpr[21],
"r22" => self.gpr[22],
"r23" => self.gpr[23],
"r24" => self.gpr[24],
"r25" => self.gpr[25],
"r26" => self.gpr[26],
"r27" => self.gpr[27],
"r28" => self.gpr[28],
"r29" => self.gpr[29],
"r30" => self.gpr[30],
"r31" => self.gpr[31],
"cr" => self.cr,
"xer" => self.xer,
"lr" => self.lr,
"ctr" => self.ctr,
"mq" => self.mq,
"vrsave" => self.vrsave,
_ => unreachable!("Invalid ppc register! {}", reg),
}
}
fn set_register(&mut self, reg: &str, val: Self::Register) -> Option<()> {
match reg {
"srr0" => self.srr0 = val,
"srr1" => self.srr1 = val,
"r0" => self.gpr[0] = val,
"r1" => self.gpr[1] = val,
"r2" => self.gpr[2] = val,
"r3" => self.gpr[3] = val,
"r4" => self.gpr[4] = val,
"r5" => self.gpr[5] = val,
"r6" => self.gpr[6] = val,
"r7" => self.gpr[7] = val,
"r8" => self.gpr[8] = val,
"r9" => self.gpr[9] = val,
"r10" => self.gpr[10] = val,
"r11" => self.gpr[11] = val,
"r12" => self.gpr[12] = val,
"r13" => self.gpr[13] = val,
"r14" => self.gpr[14] = val,
"r15" => self.gpr[15] = val,
"r16" => self.gpr[16] = val,
"r17" => self.gpr[17] = val,
"r18" => self.gpr[18] = val,
"r19" => self.gpr[19] = val,
"r20" => self.gpr[20] = val,
"r21" => self.gpr[21] = val,
"r22" => self.gpr[22] = val,
"r23" => self.gpr[23] = val,
"r24" => self.gpr[24] = val,
"r25" => self.gpr[25] = val,
"r26" => self.gpr[26] = val,
"r27" => self.gpr[27] = val,
"r28" => self.gpr[28] = val,
"r29" => self.gpr[29] = val,
"r30" => self.gpr[30] = val,
"r31" => self.gpr[31] = val,
"cr" => self.cr = val,
"xer" => self.xer = val,
"lr" => self.lr = val,
"ctr" => self.ctr = val,
"mq" => self.mq = val,
"vrsave" => self.vrsave = val,
_ => return None,
}
Some(())
}
fn stack_pointer_register_name(&self) -> &'static str {
"r1"
}
fn instruction_pointer_register_name(&self) -> &'static str {
"srr0"
}
}
impl CpuContext for md::CONTEXT_PPC64 {
type Register = u64;
const REGISTERS: &'static [&'static str] = &[
"srr0", "srr1", "r0", "r1", "r2", "r3", "r4", "r5", "r6", "r7", "r8", "r9", "r10", "r11",
"r12", "r13", "r14", "r15", "r16", "r17", "r18", "r19", "r20", "r21", "r22", "r23", "r24",
"r25", "r26", "r27", "r28", "r29", "r30", "r31", "cr", "xer", "lr", "ctr", "vrsave",
];
fn get_register_always(&self, reg: &str) -> Self::Register {
match reg {
"srr0" => self.srr0,
"srr1" => self.srr1,
"r0" => self.gpr[0],
"r1" => self.gpr[1],
"r2" => self.gpr[2],
"r3" => self.gpr[3],
"r4" => self.gpr[4],
"r5" => self.gpr[5],
"r6" => self.gpr[6],
"r7" => self.gpr[7],
"r8" => self.gpr[8],
"r9" => self.gpr[9],
"r10" => self.gpr[10],
"r11" => self.gpr[11],
"r12" => self.gpr[12],
"r13" => self.gpr[13],
"r14" => self.gpr[14],
"r15" => self.gpr[15],
"r16" => self.gpr[16],
"r17" => self.gpr[17],
"r18" => self.gpr[18],
"r19" => self.gpr[19],
"r20" => self.gpr[20],
"r21" => self.gpr[21],
"r22" => self.gpr[22],
"r23" => self.gpr[23],
"r24" => self.gpr[24],
"r25" => self.gpr[25],
"r26" => self.gpr[26],
"r27" => self.gpr[27],
"r28" => self.gpr[28],
"r29" => self.gpr[29],
"r30" => self.gpr[30],
"r31" => self.gpr[31],
"cr" => self.cr,
"xer" => self.xer,
"lr" => self.lr,
"ctr" => self.ctr,
"vrsave" => self.vrsave,
_ => unreachable!("Invalid ppc64 register! {}", reg),
}
}
fn set_register(&mut self, reg: &str, val: Self::Register) -> Option<()> {
match reg {
"srr0" => self.srr0 = val,
"srr1" => self.srr1 = val,
"r0" => self.gpr[0] = val,
"r1" => self.gpr[1] = val,
"r2" => self.gpr[2] = val,
"r3" => self.gpr[3] = val,
"r4" => self.gpr[4] = val,
"r5" => self.gpr[5] = val,
"r6" => self.gpr[6] = val,
"r7" => self.gpr[7] = val,
"r8" => self.gpr[8] = val,
"r9" => self.gpr[9] = val,
"r10" => self.gpr[10] = val,
"r11" => self.gpr[11] = val,
"r12" => self.gpr[12] = val,
"r13" => self.gpr[13] = val,
"r14" => self.gpr[14] = val,
"r15" => self.gpr[15] = val,
"r16" => self.gpr[16] = val,
"r17" => self.gpr[17] = val,
"r18" => self.gpr[18] = val,
"r19" => self.gpr[19] = val,
"r20" => self.gpr[20] = val,
"r21" => self.gpr[21] = val,
"r22" => self.gpr[22] = val,
"r23" => self.gpr[23] = val,
"r24" => self.gpr[24] = val,
"r25" => self.gpr[25] = val,
"r26" => self.gpr[26] = val,
"r27" => self.gpr[27] = val,
"r28" => self.gpr[28] = val,
"r29" => self.gpr[29] = val,
"r30" => self.gpr[30] = val,
"r31" => self.gpr[31] = val,
"cr" => self.cr = val,
"xer" => self.xer = val,
"lr" => self.lr = val,
"ctr" => self.ctr = val,
"vrsave" => self.vrsave = val,
_ => return None,
}
Some(())
}
fn stack_pointer_register_name(&self) -> &'static str {
"r1"
}
fn instruction_pointer_register_name(&self) -> &'static str {
"srr0"
}
}
impl CpuContext for md::CONTEXT_MIPS {
type Register = u64;
const REGISTERS: &'static [&'static str] = &[
"gp", "sp", "fp", "ra", "pc", "s0", "s1", "s2", "s3", "s4", "s5", "s6", "s7",
];
fn get_register_always(&self, reg: &str) -> Self::Register {
match reg {
"gp" => self.iregs[md::MipsRegisterNumbers::GlobalPointer as usize],
"sp" => self.iregs[md::MipsRegisterNumbers::StackPointer as usize],
"fp" => self.iregs[md::MipsRegisterNumbers::FramePointer as usize],
"ra" => self.iregs[md::MipsRegisterNumbers::ReturnAddress as usize],
"pc" => self.epc,
"s0" => self.iregs[md::MipsRegisterNumbers::S0 as usize],
"s1" => self.iregs[md::MipsRegisterNumbers::S1 as usize],
"s2" => self.iregs[md::MipsRegisterNumbers::S2 as usize],
"s3" => self.iregs[md::MipsRegisterNumbers::S3 as usize],
"s4" => self.iregs[md::MipsRegisterNumbers::S4 as usize],
"s5" => self.iregs[md::MipsRegisterNumbers::S5 as usize],
"s6" => self.iregs[md::MipsRegisterNumbers::S6 as usize],
"s7" => self.iregs[md::MipsRegisterNumbers::S7 as usize],
_ => unreachable!("Invalid mips register! {}", reg),
}
}
fn set_register(&mut self, reg: &str, val: Self::Register) -> Option<()> {
match reg {
"gp" => self.iregs[md::MipsRegisterNumbers::GlobalPointer as usize] = val,
"sp" => self.iregs[md::MipsRegisterNumbers::StackPointer as usize] = val,
"fp" => self.iregs[md::MipsRegisterNumbers::FramePointer as usize] = val,
"ra" => self.iregs[md::MipsRegisterNumbers::ReturnAddress as usize] = val,
"pc" => self.epc = val,
"s0" => self.iregs[md::MipsRegisterNumbers::S0 as usize] = val,
"s1" => self.iregs[md::MipsRegisterNumbers::S1 as usize] = val,
"s2" => self.iregs[md::MipsRegisterNumbers::S2 as usize] = val,
"s3" => self.iregs[md::MipsRegisterNumbers::S3 as usize] = val,
"s4" => self.iregs[md::MipsRegisterNumbers::S4 as usize] = val,
"s5" => self.iregs[md::MipsRegisterNumbers::S5 as usize] = val,
"s6" => self.iregs[md::MipsRegisterNumbers::S6 as usize] = val,
"s7" => self.iregs[md::MipsRegisterNumbers::S7 as usize] = val,
_ => return None,
}
Some(())
}
fn stack_pointer_register_name(&self) -> &'static str {
"sp"
}
fn instruction_pointer_register_name(&self) -> &'static str {
"pc"
}
}
impl CpuContext for md::CONTEXT_SPARC {
type Register = u64;
const REGISTERS: &'static [&'static str] = &[
"g_r0", "g_r1", "g_r2", "g_r3", "g_r4", "g_r5", "g_r6", "g_r7", "g_r8", "g_r9", "g_r10",
"g_r11", "g_r12", "g_r13", "g_r14", "g_r15", "g_r16", "g_r17", "g_r18", "g_r19", "g_r20",
"g_r21", "g_r22", "g_r23", "g_r24", "g_r25", "g_r26", "g_r27", "g_r28", "g_r29", "g_r30",
"g_r31", "ccr", "pc", "npc", "y", "asi", "fprs",
];
fn get_register_always(&self, reg: &str) -> Self::Register {
match reg {
"g_r0" | "g0" => self.g_r[0],
"g_r1" | "g1" => self.g_r[1],
"g_r2" | "g2" => self.g_r[2],
"g_r3" | "g3" => self.g_r[3],
"g_r4" | "g4" => self.g_r[4],
"g_r5" | "g5" => self.g_r[5],
"g_r6" | "g6" => self.g_r[6],
"g_r7" | "g7" => self.g_r[7],
"g_r8" | "o0" => self.g_r[8],
"g_r9" | "o1" => self.g_r[9],
"g_r10" | "o2" => self.g_r[10],
"g_r11" | "o3" => self.g_r[11],
"g_r12" | "o4" => self.g_r[12],
"g_r13" | "o5" => self.g_r[13],
"g_r14" | "o6" => self.g_r[14],
"g_r15" | "o7" => self.g_r[15],
"g_r16" | "l0" => self.g_r[16],
"g_r17" | "l1" => self.g_r[17],
"g_r18" | "l2" => self.g_r[18],
"g_r19" | "l3" => self.g_r[19],
"g_r20" | "l4" => self.g_r[20],
"g_r21" | "l5" => self.g_r[21],
"g_r22" | "l6" => self.g_r[22],
"g_r23" | "l7" => self.g_r[23],
"g_r24" | "i0" => self.g_r[24],
"g_r25" | "i1" => self.g_r[25],
"g_r26" | "i2" => self.g_r[26],
"g_r27" | "i3" => self.g_r[27],
"g_r28" | "i4" => self.g_r[28],
"g_r29" | "i5" => self.g_r[29],
"g_r30" | "i6" => self.g_r[30],
"g_r31" | "i7" => self.g_r[31],
"ccr" => self.ccr,
"pc" => self.pc,
"npc" => self.npc,
"y" => self.y,
"asi" => self.asi,
"fprs" => self.fprs,
_ => unreachable!("Invalid sparc register! {}", reg),
}
}
fn set_register(&mut self, reg: &str, val: Self::Register) -> Option<()> {
match reg {
"g_r0" | "g0" => self.g_r[0] = val,
"g_r1" | "g1" => self.g_r[1] = val,
"g_r2" | "g2" => self.g_r[2] = val,
"g_r3" | "g3" => self.g_r[3] = val,
"g_r4" | "g4" => self.g_r[4] = val,
"g_r5" | "g5" => self.g_r[5] = val,
"g_r6" | "g6" => self.g_r[6] = val,
"g_r7" | "g7" => self.g_r[7] = val,
"g_r8" | "o0" => self.g_r[8] = val,
"g_r9" | "o1" => self.g_r[9] = val,
"g_r10" | "o2" => self.g_r[10] = val,
"g_r11" | "o3" => self.g_r[11] = val,
"g_r12" | "o4" => self.g_r[12] = val,
"g_r13" | "o5" => self.g_r[13] = val,
"g_r14" | "o6" => self.g_r[14] = val,
"g_r15" | "o7" => self.g_r[15] = val,
"g_r16" | "l0" => self.g_r[16] = val,
"g_r17" | "l1" => self.g_r[17] = val,
"g_r18" | "l2" => self.g_r[18] = val,
"g_r19" | "l3" => self.g_r[19] = val,
"g_r20" | "l4" => self.g_r[20] = val,
"g_r21" | "l5" => self.g_r[21] = val,
"g_r22" | "l6" => self.g_r[22] = val,
"g_r23" | "l7" => self.g_r[23] = val,
"g_r24" | "i0" => self.g_r[24] = val,
"g_r25" | "i1" => self.g_r[25] = val,
"g_r26" | "i2" => self.g_r[26] = val,
"g_r27" | "i3" => self.g_r[27] = val,
"g_r28" | "i4" => self.g_r[28] = val,
"g_r29" | "i5" => self.g_r[29] = val,
"g_r30" | "i6" => self.g_r[30] = val,
"g_r31" | "i7" => self.g_r[31] = val,
"ccr" => self.ccr = val,
"pc" => self.pc = val,
"npc" => self.npc = val,
"y" => self.y = val,
"asi" => self.asi = val,
"fprs" => self.fprs = val,
_ => return None,
}
Some(())
}
fn stack_pointer_register_name(&self) -> &'static str {
"g_r14" // alias out register o6
}
fn instruction_pointer_register_name(&self) -> &'static str {
"pc"
}
}
/// Information about which registers are valid in a `MinidumpContext`.
#[derive(Clone, Debug, PartialEq, Eq)]
pub enum MinidumpContextValidity {
// All registers are valid.
All,
// The registers in this set are valid.
Some(HashSet<&'static str>),
}
/// CPU context such as register states.
///
/// MinidumpContext carries a CPU-specific MDRawContext structure, which
/// contains CPU context such as register states. Each thread has its
/// own context, and the exception record, if present, also has its own
/// context. Note that if the exception record is present, the context it
/// refers to is probably what the user wants to use for the exception
/// thread, instead of that thread's own context. The exception thread's
/// context (as opposed to the exception record's context) will contain
/// context for the exception handler (which performs minidump generation),
/// and not the context that caused the exception (which is probably what the
/// user wants).
#[derive(Debug, Clone)]
pub struct MinidumpContext {
/// The raw CPU register state.
pub raw: MinidumpRawContext,
/// Which registers are valid in `raw`.
pub valid: MinidumpContextValidity,
}
/// Errors encountered while reading a `MinidumpContext`.
#[derive(Debug)]
pub enum ContextError {
/// Failed to read data.
ReadFailure,
/// Encountered an unknown CPU context.
UnknownCpuContext,
}
//======================================================
// Implementations
impl MinidumpContext {
/// Return a MinidumpContext given a `MinidumpRawContext`.
pub fn from_raw(raw: MinidumpRawContext) -> MinidumpContext {
MinidumpContext {
raw,
valid: MinidumpContextValidity::All,
}
}
/// Read a `MinidumpContext` from `bytes`.
pub fn read(
bytes: &[u8],
endian: scroll::Endian,
system_info: &MinidumpSystemInfo,
_misc: Option<&MinidumpMiscInfo>,
) -> Result<MinidumpContext, ContextError> {
use md::ProcessorArchitecture::*;
let mut offset = 0;
// Although every context contains `context_flags` which tell us what kind
// ok context we're handling, they aren't all in the same location, so we
// need to use SystemInfo to choose what kind of context to parse this as.
// We can then use the `context_flags` to validate our parse.
// We need to use the raw processor_architecture because system_info.cpu
// flattens away some key distinctions for this code.
match md::ProcessorArchitecture::from_u16(system_info.raw.processor_architecture) {
Some(PROCESSOR_ARCHITECTURE_INTEL) | Some(PROCESSOR_ARCHITECTURE_IA32_ON_WIN64) => {
// Not 100% sure IA32_ON_WIN64 is this format, but let's assume so?
let ctx: md::CONTEXT_X86 = bytes
.gread_with(&mut offset, endian)
.or(Err(ContextError::ReadFailure))?;
let flags = ContextFlagsCpu::from_flags(ctx.context_flags);
if flags == ContextFlagsCpu::CONTEXT_X86 {
if ctx.context_flags & md::CONTEXT_HAS_XSTATE != 0 {
// FIXME: uses MISC_INFO_5 to parse out extra sections here
warn!("Cpu context has extra XSTATE that is being ignored");
}
Ok(MinidumpContext::from_raw(MinidumpRawContext::X86(ctx)))
} else {
Err(ContextError::ReadFailure)
}
}
Some(PROCESSOR_ARCHITECTURE_AMD64) => {
let ctx: md::CONTEXT_AMD64 = bytes
.gread_with(&mut offset, endian)
.or(Err(ContextError::ReadFailure))?;
let flags = ContextFlagsCpu::from_flags(ctx.context_flags);
if flags == ContextFlagsCpu::CONTEXT_AMD64 {
if ctx.context_flags & md::CONTEXT_HAS_XSTATE != 0 {
// FIXME: uses MISC_INFO_5 to parse out extra sections here
warn!("Cpu context has extra XSTATE that is being ignored");
}
Ok(MinidumpContext::from_raw(MinidumpRawContext::Amd64(ctx)))
} else {
Err(ContextError::ReadFailure)
}
}
Some(PROCESSOR_ARCHITECTURE_PPC) => {
let ctx: md::CONTEXT_PPC = bytes
.gread_with(&mut offset, endian)
.or(Err(ContextError::ReadFailure))?;
let flags = ContextFlagsCpu::from_flags(ctx.context_flags);
if flags == ContextFlagsCpu::CONTEXT_PPC {
Ok(MinidumpContext::from_raw(MinidumpRawContext::Ppc(ctx)))
} else {
Err(ContextError::ReadFailure)
}
}
Some(PROCESSOR_ARCHITECTURE_PPC64) => {
let ctx: md::CONTEXT_PPC64 = bytes
.gread_with(&mut offset, endian)
.or(Err(ContextError::ReadFailure))?;
let flags = ContextFlagsCpu::from_flags(ctx.context_flags as u32);
if flags == ContextFlagsCpu::CONTEXT_PPC64 {
Ok(MinidumpContext::from_raw(MinidumpRawContext::Ppc64(ctx)))
} else {
Err(ContextError::ReadFailure)
}
}
Some(PROCESSOR_ARCHITECTURE_SPARC) => {
let ctx: md::CONTEXT_SPARC = bytes
.gread_with(&mut offset, endian)
.or(Err(ContextError::ReadFailure))?;
let flags = ContextFlagsCpu::from_flags(ctx.context_flags);
if flags == ContextFlagsCpu::CONTEXT_SPARC {
Ok(MinidumpContext::from_raw(MinidumpRawContext::Sparc(ctx)))
} else {
Err(ContextError::ReadFailure)
}
}
Some(PROCESSOR_ARCHITECTURE_ARM) => {
let ctx: md::CONTEXT_ARM = bytes
.gread_with(&mut offset, endian)
.or(Err(ContextError::ReadFailure))?;
let flags = ContextFlagsCpu::from_flags(ctx.context_flags);
if flags == ContextFlagsCpu::CONTEXT_ARM {
Ok(MinidumpContext::from_raw(MinidumpRawContext::Arm(ctx)))
} else {
Err(ContextError::ReadFailure)
}
}
Some(PROCESSOR_ARCHITECTURE_ARM64) => {
let ctx: md::CONTEXT_ARM64 = bytes
.gread_with(&mut offset, endian)
.or(Err(ContextError::ReadFailure))?;
let flags = ContextFlagsCpu::from_flags(ctx.context_flags);
if flags == ContextFlagsCpu::CONTEXT_ARM64 {
Ok(MinidumpContext::from_raw(MinidumpRawContext::Arm64(ctx)))
} else {
Err(ContextError::ReadFailure)
}
}
Some(PROCESSOR_ARCHITECTURE_ARM64_OLD) => {
let ctx: md::CONTEXT_ARM64_OLD = bytes
.gread_with(&mut offset, endian)
.or(Err(ContextError::ReadFailure))?;
let flags = ContextFlagsCpu::from_flags(ctx.context_flags as u32);
if flags == ContextFlagsCpu::CONTEXT_ARM64_OLD {
Ok(MinidumpContext::from_raw(MinidumpRawContext::OldArm64(ctx)))
} else {
Err(ContextError::ReadFailure)
}
}
Some(PROCESSOR_ARCHITECTURE_MIPS) => {
let ctx: md::CONTEXT_MIPS = bytes
.gread_with(&mut offset, endian)
.or(Err(ContextError::ReadFailure))?;
let flags = ContextFlagsCpu::from_flags(ctx.context_flags);
if flags == ContextFlagsCpu::CONTEXT_MIPS {
Ok(MinidumpContext::from_raw(MinidumpRawContext::Mips(ctx)))
} else {
Err(ContextError::ReadFailure)
}
}
_ => Err(ContextError::UnknownCpuContext),
}
}
pub fn get_instruction_pointer(&self) -> u64 {
match self.raw {
MinidumpRawContext::Amd64(ref ctx) => ctx.rip,
MinidumpRawContext::Arm(ref ctx) => {
ctx.iregs[md::ArmRegisterNumbers::ProgramCounter as usize] as u64
}
MinidumpRawContext::Arm64(ref ctx) => ctx.pc,
MinidumpRawContext::OldArm64(ref ctx) => ctx.pc,
MinidumpRawContext::Ppc(ref ctx) => ctx.srr0 as u64,
MinidumpRawContext::Ppc64(ref ctx) => ctx.srr0,
MinidumpRawContext::Sparc(ref ctx) => ctx.pc,
MinidumpRawContext::X86(ref ctx) => ctx.eip as u64,
MinidumpRawContext::Mips(ref ctx) => ctx.epc,
}
}
pub fn get_stack_pointer(&self) -> u64 {
match self.raw {
MinidumpRawContext::Amd64(ref ctx) => ctx.rsp,
MinidumpRawContext::Arm(ref ctx) => {
ctx.iregs[md::ArmRegisterNumbers::StackPointer as usize] as u64
}
MinidumpRawContext::Arm64(ref ctx) => ctx.sp,
MinidumpRawContext::OldArm64(ref ctx) => ctx.sp,
MinidumpRawContext::Ppc(ref ctx) => {
ctx.gpr[md::PpcRegisterNumbers::StackPointer as usize] as u64
}
MinidumpRawContext::Ppc64(ref ctx) => {
ctx.gpr[md::Ppc64RegisterNumbers::StackPointer as usize]
}
MinidumpRawContext::Sparc(ref ctx) => {
ctx.g_r[md::SparcRegisterNumbers::StackPointer as usize]
}
MinidumpRawContext::X86(ref ctx) => ctx.esp as u64,
MinidumpRawContext::Mips(ref ctx) => {
ctx.iregs[md::MipsRegisterNumbers::StackPointer as usize]
}
}
}
pub fn get_register_always(&self, reg: &str) -> u64 {
match self.raw {
MinidumpRawContext::Amd64(ref ctx) => ctx.get_register_always(reg),
MinidumpRawContext::Arm(ref ctx) => ctx.get_register_always(reg).into(),
MinidumpRawContext::Arm64(ref ctx) => ctx.get_register_always(reg),
MinidumpRawContext::OldArm64(ref ctx) => ctx.get_register_always(reg),
MinidumpRawContext::Ppc(ref ctx) => ctx.get_register_always(reg).into(),
MinidumpRawContext::Ppc64(ref ctx) => ctx.get_register_always(reg),
MinidumpRawContext::Sparc(ref ctx) => ctx.get_register_always(reg),
MinidumpRawContext::X86(ref ctx) => ctx.get_register_always(reg).into(),
MinidumpRawContext::Mips(ref ctx) => ctx.get_register_always(reg),
}
}
pub fn get_register(&self, reg: &str) -> Option<u64> {
let valid = match &self.raw {
MinidumpRawContext::X86(ctx) => ctx.register_is_valid(reg, &self.valid),
MinidumpRawContext::Ppc(ctx) => ctx.register_is_valid(reg, &self.valid),
MinidumpRawContext::Ppc64(ctx) => ctx.register_is_valid(reg, &self.valid),
MinidumpRawContext::Amd64(ctx) => ctx.register_is_valid(reg, &self.valid),
MinidumpRawContext::Sparc(ctx) => ctx.register_is_valid(reg, &self.valid),
MinidumpRawContext::Arm(ctx) => ctx.register_is_valid(reg, &self.valid),
MinidumpRawContext::Arm64(ctx) => ctx.register_is_valid(reg, &self.valid),
MinidumpRawContext::OldArm64(ctx) => ctx.register_is_valid(reg, &self.valid),
MinidumpRawContext::Mips(ctx) => ctx.register_is_valid(reg, &self.valid),
};
if valid {
Some(self.get_register_always(reg))
} else {
None
}
}
pub fn format_register(&self, reg: &str) -> String {
match self.raw {
MinidumpRawContext::Amd64(ref ctx) => ctx.format_register(reg),
MinidumpRawContext::Arm(ref ctx) => ctx.format_register(reg),
MinidumpRawContext::Arm64(ref ctx) => ctx.format_register(reg),
MinidumpRawContext::OldArm64(ref ctx) => ctx.format_register(reg),
MinidumpRawContext::Ppc(ref ctx) => ctx.format_register(reg),
MinidumpRawContext::Ppc64(ref ctx) => ctx.format_register(reg),
MinidumpRawContext::Sparc(ref ctx) => ctx.format_register(reg),
MinidumpRawContext::X86(ref ctx) => ctx.format_register(reg),
MinidumpRawContext::Mips(ref ctx) => ctx.format_register(reg),
}
}
pub fn general_purpose_registers(&self) -> &'static [&'static str] {
match self.raw {
MinidumpRawContext::Amd64(_) => md::CONTEXT_AMD64::REGISTERS,
MinidumpRawContext::Arm(_) => md::CONTEXT_ARM::REGISTERS,
MinidumpRawContext::Arm64(_) => md::CONTEXT_ARM64::REGISTERS,
MinidumpRawContext::OldArm64(_) => md::CONTEXT_ARM64::REGISTERS,
MinidumpRawContext::Ppc(_) => md::CONTEXT_PPC::REGISTERS,
MinidumpRawContext::Ppc64(_) => md::CONTEXT_PPC64::REGISTERS,
MinidumpRawContext::Sparc(_) => md::CONTEXT_SPARC::REGISTERS,
MinidumpRawContext::X86(_) => md::CONTEXT_X86::REGISTERS,
MinidumpRawContext::Mips(_) => md::CONTEXT_MIPS::REGISTERS,
}
}
pub fn registers(&self) -> impl Iterator<Item = (&'static str, u64)> + '_ {
self.general_purpose_registers()
.iter()
.map(move |&reg| (reg, self.get_register_always(reg)))
}
pub fn valid_registers(&self) -> impl Iterator<Item = (&'static str, u64)> + '_ {
// This is suboptimal in theory, as we could iterate over self.valid just like the original
// and faster `CpuRegisters` iterator does. However, this complicates code here, and the
// minimal gain in performance hasn't been worth the added complexity.
self.registers().filter(move |(reg, _)| match &self.raw {
MinidumpRawContext::X86(ctx) => ctx.register_is_valid(reg, &self.valid),
MinidumpRawContext::Ppc(ctx) => ctx.register_is_valid(reg, &self.valid),
MinidumpRawContext::Ppc64(ctx) => ctx.register_is_valid(reg, &self.valid),
MinidumpRawContext::Amd64(ctx) => ctx.register_is_valid(reg, &self.valid),
MinidumpRawContext::Sparc(ctx) => ctx.register_is_valid(reg, &self.valid),
MinidumpRawContext::Arm(ctx) => ctx.register_is_valid(reg, &self.valid),
MinidumpRawContext::Arm64(ctx) => ctx.register_is_valid(reg, &self.valid),
MinidumpRawContext::OldArm64(ctx) => ctx.register_is_valid(reg, &self.valid),
MinidumpRawContext::Mips(ctx) => ctx.register_is_valid(reg, &self.valid),
})
}
/// Get the size (in bytes) of general-purpose registers.
pub fn register_size(&self) -> usize {
fn get<T: CpuContext>(_: &T) -> usize {
std::mem::size_of::<T::Register>()
}
match &self.raw {
MinidumpRawContext::X86(ctx) => get(ctx),
MinidumpRawContext::Ppc(ctx) => get(ctx),
MinidumpRawContext::Ppc64(ctx) => get(ctx),
MinidumpRawContext::Amd64(ctx) => get(ctx),
MinidumpRawContext::Sparc(ctx) => get(ctx),
MinidumpRawContext::Arm(ctx) => get(ctx),
MinidumpRawContext::Arm64(ctx) => get(ctx),
MinidumpRawContext::OldArm64(ctx) => get(ctx),
MinidumpRawContext::Mips(ctx) => get(ctx),
}
}
/// Write a human-readable description of this `MinidumpContext` to `f`.
///
/// This is very verbose, it is the format used by `minidump_dump`.
pub fn print<T: Write>(&self, f: &mut T) -> io::Result<()> {
match self.raw {
MinidumpRawContext::X86(ref raw) => {
write!(
f,
r#"CONTEXT_X86
context_flags = {:#x}
dr0 = {:#x}
dr1 = {:#x}
dr2 = {:#x}
dr3 = {:#x}
dr6 = {:#x}
dr7 = {:#x}
float_save.control_word = {:#x}
float_save.status_word = {:#x}
float_save.tag_word = {:#x}
float_save.error_offset = {:#x}
float_save.error_selector = {:#x}
float_save.data_offset = {:#x}
float_save.data_selector = {:#x}
float_save.register_area[{:2}] = 0x"#,
raw.context_flags,
raw.dr0,
raw.dr1,
raw.dr2,
raw.dr3,
raw.dr6,
raw.dr7,
raw.float_save.control_word,
raw.float_save.status_word,
raw.float_save.tag_word,
raw.float_save.error_offset,
raw.float_save.error_selector,
raw.float_save.data_offset,
raw.float_save.data_selector,
raw.float_save.register_area.len(),
)?;
write_bytes(f, &raw.float_save.register_area)?;
writeln!(f)?;
write!(
f,
r#" float_save.cr0_npx_state = {:#x}
gs = {:#x}
fs = {:#x}
es = {:#x}
ds = {:#x}
edi = {:#x}
esi = {:#x}
ebx = {:#x}
edx = {:#x}
ecx = {:#x}
eax = {:#x}
ebp = {:#x}
eip = {:#x}
cs = {:#x}
eflags = {:#x}
esp = {:#x}
ss = {:#x}
extended_registers[{:3}] = 0x"#,
raw.float_save.cr0_npx_state,
raw.gs,
raw.fs,
raw.es,
raw.ds,
raw.edi,
raw.esi,
raw.ebx,
raw.edx,
raw.ecx,
raw.eax,
raw.ebp,
raw.eip,
raw.cs,
raw.eflags,
raw.esp,
raw.ss,
raw.extended_registers.len(),
)?;
write_bytes(f, &raw.extended_registers)?;
write!(f, "\n\n")?;
}
MinidumpRawContext::Ppc(_) => {
unimplemented!();
}
MinidumpRawContext::Ppc64(_) => {
unimplemented!();
}
MinidumpRawContext::Amd64(ref raw) => {
write!(
f,
r#"CONTEXT_AMD64
p1_home = {:#x}
p2_home = {:#x}
p3_home = {:#x}
p4_home = {:#x}
p5_home = {:#x}
p6_home = {:#x}
context_flags = {:#x}
mx_csr = {:#x}
cs = {:#x}
ds = {:#x}
es = {:#x}
fs = {:#x}
gs = {:#x}
ss = {:#x}
eflags = {:#x}
dr0 = {:#x}
dr1 = {:#x}
dr2 = {:#x}
dr3 = {:#x}
dr6 = {:#x}
dr7 = {:#x}
rax = {:#x}
rcx = {:#x}
rdx = {:#x}
rbx = {:#x}
rsp = {:#x}
rbp = {:#x}
rsi = {:#x}
rdi = {:#x}
r8 = {:#x}
r9 = {:#x}
r10 = {:#x}
r11 = {:#x}
r12 = {:#x}
r13 = {:#x}
r14 = {:#x}
r15 = {:#x}
rip = {:#x}
"#,
raw.p1_home,
raw.p2_home,
raw.p3_home,
raw.p4_home,
raw.p5_home,
raw.p6_home,
raw.context_flags,
raw.mx_csr,
raw.cs,
raw.ds,
raw.es,
raw.fs,
raw.gs,
raw.ss,
raw.eflags,
raw.dr0,
raw.dr1,
raw.dr2,
raw.dr3,
raw.dr6,
raw.dr7,
raw.rax,
raw.rcx,
raw.rdx,
raw.rbx,
raw.rsp,
raw.rbp,
raw.rsi,
raw.rdi,
raw.r8,
raw.r9,
raw.r10,
raw.r11,
raw.r12,
raw.r13,
raw.r14,
raw.r15,
raw.rip,
)?;
}
MinidumpRawContext::Sparc(_) => {
unimplemented!();
}
MinidumpRawContext::Arm(ref raw) => {
write!(
f,
r#"CONTEXT_ARM
context_flags = {:#x}
"#,
raw.context_flags
)?;
for (i, reg) in raw.iregs.iter().enumerate() {
writeln!(f, " iregs[{i:2}] = {reg:#x}")?;
}
write!(
f,
r#" cpsr = {:#x}
float_save.fpscr = {:#x}
"#,
raw.cpsr, raw.float_save.fpscr
)?;
for (i, reg) in raw.float_save.regs.iter().enumerate() {
writeln!(f, " float_save.regs[{i:2}] = {reg:#x}")?;
}
for (i, reg) in raw.float_save.extra.iter().enumerate() {
writeln!(f, " float_save.extra[{i:2}] = {reg:#x}")?;
}
}
MinidumpRawContext::Arm64(ref raw) => {
write!(
f,
r#"CONTEXT_ARM64
context_flags = {:#x}
"#,
raw.context_flags
)?;
for (i, reg) in raw.iregs[..29].iter().enumerate() {
writeln!(f, " x{i:<2} = {reg:#x}")?;
}
writeln!(f, " x29 (fp) = {:#x}", raw.iregs[29])?;
writeln!(f, " x30 (lr) = {:#x}", raw.iregs[30])?;
writeln!(f, " sp = {:#x}", raw.sp)?;
writeln!(f, " pc = {:#x}", raw.pc)?;
writeln!(f, " cpsr = {:#x}", raw.cpsr)?;
writeln!(f, " fpsr = {:#x}", raw.fpsr)?;
writeln!(f, " fpcr = {:#x}", raw.fpcr)?;
for (i, reg) in raw.float_regs.iter().enumerate() {
writeln!(f, " d{i:<2} = {reg:#x}")?;
}
for (i, reg) in raw.bcr.iter().enumerate() {
writeln!(f, " bcr[{i:2}] = {reg:#x}")?;
}
for (i, reg) in raw.bvr.iter().enumerate() {
writeln!(f, " bvr[{i:2}] = {reg:#x}")?;
}
for (i, reg) in raw.wcr.iter().enumerate() {
writeln!(f, " wcr[{i:2}] = {reg:#x}")?;
}
for (i, reg) in raw.wvr.iter().enumerate() {
writeln!(f, " wvr[{i:2}] = {reg:#x}")?;
}
}
MinidumpRawContext::OldArm64(ref raw) => {
write!(
f,
r#"CONTEXT_ARM64_OLD
context_flags = {:#x}
"#,
raw.context_flags
)?;
for (i, reg) in raw.iregs[..29].iter().enumerate() {
writeln!(f, " x{i:<2} = {reg:#x}")?;
}
writeln!(f, " x29 (fp) = {:#x}", raw.iregs[29])?;
writeln!(f, " x30 (lr) = {:#x}", raw.iregs[30])?;
writeln!(f, " sp = {:#x}", raw.sp)?;
writeln!(f, " pc = {:#x}", raw.pc)?;
writeln!(f, " cpsr = {:#x}", raw.cpsr)?;
writeln!(f, " fpsr = {:#x}", raw.fpsr)?;
writeln!(f, " fpcr = {:#x}", raw.fpcr)?;
for (i, reg) in raw.float_regs.iter().enumerate() {
writeln!(f, " d{i:<2} = {reg:#x}")?;
}
}
MinidumpRawContext::Mips(ref raw) => {
write!(
f,
r#"CONTEXT_MIPS
context_flags = {:#x}
"#,
raw.context_flags
)?;
use md::MipsRegisterNumbers;
const MIPS_REGS: &[MipsRegisterNumbers] = &[
MipsRegisterNumbers::S0,
MipsRegisterNumbers::S1,
MipsRegisterNumbers::S2,
MipsRegisterNumbers::S3,
MipsRegisterNumbers::S4,
MipsRegisterNumbers::S5,
MipsRegisterNumbers::S6,
MipsRegisterNumbers::S7,
MipsRegisterNumbers::GlobalPointer,
MipsRegisterNumbers::StackPointer,
MipsRegisterNumbers::FramePointer,
MipsRegisterNumbers::ReturnAddress,
];
for reg in MIPS_REGS {
writeln!(
f,
r#" {} = {:#x}"#,
reg.name(),
raw.iregs[*reg as usize]
)?;
}
}
}
Ok(())
}
}
#[cfg(test)]
mod tests {
use super::*;
#[test]
/// Smoke test for the default implementation of `memoize_register`.
fn test_memoize_amd64() {
let context = md::CONTEXT_AMD64::default();
assert_eq!(context.memoize_register("rip"), Some("rip"));
assert_eq!(context.memoize_register("foo"), None);
}
#[test]
/// Test ARM register aliases by example of `fp`.
fn test_memoize_arm_alias() {
let context = md::CONTEXT_ARM::default();
assert_eq!(context.memoize_register("r11"), Some("fp"));
assert_eq!(context.memoize_register("fp"), Some("fp"));
assert_eq!(context.memoize_register("foo"), None);
}
#[test]
/// Test ARM register aliases by example of `fp`.
fn test_memoize_arm64_alias() {
let context = md::CONTEXT_ARM64::default();
assert_eq!(context.memoize_register("x29"), Some("fp"));
assert_eq!(context.memoize_register("fp"), Some("fp"));
assert_eq!(context.memoize_register("foo"), None);
}
}