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157 lines
4.5 KiB
Go
157 lines
4.5 KiB
Go
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package proc
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import (
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"errors"
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"github.com/derekparker/delve/pkg/dwarf/op"
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)
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const cacheEnabled = true
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// MemoryReader is like io.ReaderAt, but the offset is a uintptr so that it
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// can address all of 64-bit memory.
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// Redundant with memoryReadWriter but more easily suited to working with
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// the standard io package.
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type MemoryReader interface {
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// ReadMemory is just like io.ReaderAt.ReadAt.
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ReadMemory(buf []byte, addr uintptr) (n int, err error)
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}
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// MemoryReadWriter is an interface for reading or writing to
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// the targets memory. This allows us to read from the actual
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// target memory or possibly a cache.
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type MemoryReadWriter interface {
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MemoryReader
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WriteMemory(addr uintptr, data []byte) (written int, err error)
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}
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type memCache struct {
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loaded bool
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cacheAddr uintptr
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cache []byte
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mem MemoryReadWriter
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}
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func (m *memCache) contains(addr uintptr, size int) bool {
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return addr >= m.cacheAddr && addr <= (m.cacheAddr+uintptr(len(m.cache)-size))
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}
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func (m *memCache) ReadMemory(data []byte, addr uintptr) (n int, err error) {
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if m.contains(addr, len(data)) {
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if !m.loaded {
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_, err := m.mem.ReadMemory(m.cache, m.cacheAddr)
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if err != nil {
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return 0, err
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}
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m.loaded = true
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}
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copy(data, m.cache[addr-m.cacheAddr:])
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return len(data), nil
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}
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return m.mem.ReadMemory(data, addr)
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}
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func (m *memCache) WriteMemory(addr uintptr, data []byte) (written int, err error) {
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return m.mem.WriteMemory(addr, data)
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}
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func cacheMemory(mem MemoryReadWriter, addr uintptr, size int) MemoryReadWriter {
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if !cacheEnabled {
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return mem
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}
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if size <= 0 {
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return mem
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}
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switch cacheMem := mem.(type) {
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case *memCache:
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if cacheMem.contains(addr, size) {
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return mem
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}
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case *compositeMemory:
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return mem
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}
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return &memCache{false, addr, make([]byte, size), mem}
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}
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// fakeAddress used by extractVarInfoFromEntry for variables that do not
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// have a memory address, we can't use 0 because a lot of code (likely
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// including client code) assumes that addr == 0 is nil
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const fakeAddress = 0xbeef0000
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// compositeMemory represents a chunk of memory that is stored in CPU
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// registers or non-contiguously.
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//
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// When optimizations are enabled the compiler will store some variables
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// into registers and sometimes it will also store structs non-contiguously
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// with some fields stored into CPU registers and other fields stored in
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// memory.
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type compositeMemory struct {
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realmem MemoryReadWriter
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regs op.DwarfRegisters
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pieces []op.Piece
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data []byte
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}
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func newCompositeMemory(mem MemoryReadWriter, regs op.DwarfRegisters, pieces []op.Piece) *compositeMemory {
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cmem := &compositeMemory{realmem: mem, regs: regs, pieces: pieces, data: []byte{}}
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for _, piece := range pieces {
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if piece.IsRegister {
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reg := regs.Bytes(piece.RegNum)
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sz := piece.Size
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if sz == 0 && len(pieces) == 1 {
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sz = len(reg)
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}
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cmem.data = append(cmem.data, reg[:sz]...)
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} else {
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buf := make([]byte, piece.Size)
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mem.ReadMemory(buf, uintptr(piece.Addr))
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cmem.data = append(cmem.data, buf...)
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}
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}
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return cmem
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}
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func (mem *compositeMemory) ReadMemory(data []byte, addr uintptr) (int, error) {
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addr -= fakeAddress
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if addr >= uintptr(len(mem.data)) || addr+uintptr(len(data)) > uintptr(len(mem.data)) {
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return 0, errors.New("read out of bounds")
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}
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copy(data, mem.data[addr:addr+uintptr(len(data))])
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return len(data), nil
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}
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func (mem *compositeMemory) WriteMemory(addr uintptr, data []byte) (int, error) {
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//TODO(aarzilli): implement
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return 0, errors.New("can't write composite memory")
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}
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// DereferenceMemory returns a MemoryReadWriter that can read and write the
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// memory pointed to by pointers in this memory.
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// Normally mem and mem.Dereference are the same object, they are different
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// only if this MemoryReadWriter is used to access memory outside of the
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// normal address space of the inferior process (such as data contained in
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// registers, or composite memory).
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func DereferenceMemory(mem MemoryReadWriter) MemoryReadWriter {
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switch mem := mem.(type) {
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case *compositeMemory:
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return mem.realmem
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}
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return mem
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}
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// bufferMemoryReadWriter is dummy a MemoryReadWriter backed by a []byte.
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type bufferMemoryReadWriter struct {
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buf []byte
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}
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func (mem *bufferMemoryReadWriter) ReadMemory(buf []byte, addr uintptr) (n int, err error) {
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copy(buf, mem.buf[addr-fakeAddress:][:len(buf)])
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return len(buf), nil
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}
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func (mem *bufferMemoryReadWriter) WriteMemory(addr uintptr, data []byte) (written int, err error) {
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copy(mem.buf[addr-fakeAddress:], data)
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return len(data), nil
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}
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