// Copyright (c) 2017, Google Inc. // // Permission to use, copy, modify, and/or distribute this software for any // purpose with or without fee is hereby granted, provided that the above // copyright notice and this permission notice appear in all copies. // // THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES // WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF // MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY // SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES // WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION // OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN // CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ // delocate performs several transformations of textual assembly code. See // FIPS.md in this directory for an overview. package main import ( "bufio" "bytes" "flag" "fmt" "os" "path/filepath" "strconv" "strings" "unicode/utf8" ) func main() { // The .a file, if given, is expected to be an archive of textual // assembly sources. That's odd, but CMake really wants to create // archive files so it's the only way that we can make it work. arInput := flag.String("a", "", "Path to a .a file containing assembly sources") outFile := flag.String("o", "", "Path to output assembly") asmFiles := flag.String("as", "", "Comma separated list of assembly inputs") flag.Parse() var lines []string var err error if len(*arInput) > 0 { if lines, err = arLines(lines, *arInput); err != nil { panic(err) } } asPaths := strings.Split(*asmFiles, ",") for i, path := range asPaths { if lines, err = asLines(lines, path, i); err != nil { panic(err) } } symbols := definedSymbols(lines) lines = transform(lines, symbols) out, err := os.OpenFile(*outFile, os.O_CREATE|os.O_TRUNC|os.O_WRONLY, 0644) if err != nil { panic(err) } defer out.Close() for _, line := range lines { out.WriteString(line) out.WriteString("\n") } } // isSymbolDef returns detects whether line contains a (non-local) symbol // definition. If so, it returns the symbol and true. Otherwise it returns "" // and false. func isSymbolDef(line string) (string, bool) { line = strings.TrimSpace(line) if len(line) > 0 && line[len(line)-1] == ':' && line[0] != '.' { symbol := line[:len(line)-1] if validSymbolName(symbol) { return symbol, true } } return "", false } // definedSymbols finds all (non-local) symbols from lines and returns a map // from symbol name to whether or not that symbol is global. func definedSymbols(lines []string) map[string]bool { globalSymbols := make(map[string]struct{}) symbols := make(map[string]bool) for _, line := range lines { if len(line) == 0 { continue } if symbol, ok := isSymbolDef(line); ok { _, isGlobal := globalSymbols[symbol] symbols[symbol] = isGlobal } parts := strings.Fields(strings.TrimSpace(line)) if parts[0] == ".globl" { globalSymbols[parts[1]] = struct{}{} } } return symbols } // transform performs a number of transformations on the given assembly code. // See FIPS.md in the current directory for an overview. func transform(lines []string, symbols map[string]bool) (ret []string) { ret = append(ret, ".text", "BORINGSSL_bcm_text_start:") // redirectors maps from out-call symbol name to the name of a // redirector function for that symbol. redirectors := make(map[string]string) // ia32capAddrNeeded is true iff OPENSSL_ia32cap_addr has been // referenced and thus needs to be emitted outside the module. ia32capAddrNeeded := false // extractedText contains lines that have been extracted from the // assembly and need to be moved outside of the module. (This is used // for the .init_array section that specifies constructors.) var extractedText []string extractingText := false // bssAccessorsNeeded contains the names of BSS symbols for which // accessor functions need to be emitted outside of the module. var bssAccessorsNeeded []string for lineNo, line := range lines { if strings.Contains(line, "OPENSSL_ia32cap_P(%rip)") { panic("reference to OPENSSL_ia32cap_P needs to be changed to indirect via OPENSSL_ia32cap_addr") } if strings.Contains(line, "OPENSSL_ia32cap_addr(%rip)") { ia32capAddrNeeded = true } parts := strings.Fields(strings.TrimSpace(line)) if len(parts) == 0 { ret = append(ret, line) continue } switch parts[0] { case "call", "callq", "jmp": target := parts[1] // indirect via register or local label if strings.HasPrefix(target, "*") || strings.HasPrefix(target, ".L") { ret = append(ret, line) continue } if isGlobal, ok := symbols[target]; ok { newTarget := target if isGlobal { newTarget = localTargetName(target) } ret = append(ret, fmt.Sprintf("\t%s %s", parts[0], newTarget)) continue } redirectorName := "bcm_redirector_" + target if strings.HasSuffix(target, "@PLT") { withoutPLT := target[:len(target)-4] if isGlobal, ok := symbols[withoutPLT]; ok { newTarget := withoutPLT if isGlobal { newTarget = localTargetName(withoutPLT) } ret = append(ret, fmt.Sprintf("\t%s %s", parts[0], newTarget)) continue } redirectorName = redirectorName[:len(redirectorName)-4] } ret = append(ret, fmt.Sprintf("\t%s %s", parts[0], redirectorName)) redirectors[redirectorName] = target continue case ".file": // Do not reorder .file directives. These define // numbered files which are referenced by other debug // directives which may not be reordered. ret = append(ret, line) continue case ".comm": p := strings.Split(parts[1], ",") name := p[0] bssAccessorsNeeded = append(bssAccessorsNeeded, name) symbols[accessorName(name)] = false ret = append(ret, line) case ".section": extractingText = false p := strings.Split(parts[1], ",") section := p[0] if section == ".rodata" || section == ".text.startup" || strings.HasPrefix(section, ".rodata.") { // Move .rodata to .text so it may be accessed // without a relocation. GCC with // -fmerge-constants will place strings into // separate sections, so we move all sections // named like .rodata. Also move .text.startup // so the self-test function is also in the // module. ret = append(ret, ".text # "+section) break } switch section { case ".data", ".data.rel.ro.local": panic(fmt.Sprintf("bad section %q on line %d", parts[1], lineNo+1)) case ".init_array": // init_array contains function pointers to // constructor functions. Since these must be // relocated, this section is moved to the end // of the file. extractedText = append(extractedText, line) extractingText = true default: ret = append(ret, line) } case ".text": extractingText = false fallthrough default: if extractingText { extractedText = append(extractedText, line) continue } if symbol, ok := isSymbolDef(line); ok { if isGlobal := symbols[symbol]; isGlobal { ret = append(ret, localTargetName(symbol)+":") } } if parts[0] == "leaq" { line = strings.Replace(line, "BORINGSSL_bcm_text_dummy_", "BORINGSSL_bcm_text_", -1) } ret = append(ret, line) } } ret = append(ret, "BORINGSSL_bcm_text_end:") // Emit redirector functions. Each is a single JMP instruction. for redirectorName, target := range redirectors { ret = append(ret, ".type "+redirectorName+", @function") ret = append(ret, redirectorName+":") ret = append(ret, "\tjmp "+target) } // Emit BSS accessor functions. Each is a single LEA followed by RET. for _, name := range bssAccessorsNeeded { funcName := accessorName(name) ret = append(ret, ".type "+funcName+", @function") ret = append(ret, funcName+":") ret = append(ret, "\tleaq "+name+"(%rip), %rax") ret = append(ret, "\tret") } // Emit an indirect reference to OPENSSL_ia32cap_P. if ia32capAddrNeeded { ret = append(ret, ".extern OPENSSL_ia32cap_P") ret = append(ret, ".type OPENSSL_ia32cap_addr,@object") ret = append(ret, ".size OPENSSL_ia32cap_addr,8") ret = append(ret, "OPENSSL_ia32cap_addr:") ret = append(ret, "\t.quad OPENSSL_ia32cap_P") } // Emit an array for storing the module hash. ret = append(ret, ".type BORINGSSL_bcm_text_hash,@object") ret = append(ret, ".size OPENSSL_ia32cap_addr,32") ret = append(ret, "BORINGSSL_bcm_text_hash:") for _, b := range uninitHashValue { ret = append(ret, ".byte 0x"+strconv.FormatUint(uint64(b), 16)) } ret = append(ret, extractedText...) return ret } // accessorName returns the name of the accessor function for a BSS symbol // named name. func accessorName(name string) string { return name + "_bss_get" } // localTargetName returns the name of the local target label for a global // symbol named name. func localTargetName(name string) string { return ".L" + name + "_local_target" } // asLines appends the contents of path to lines. Local symbols are renamed // using uniqueId to avoid collisions. func asLines(lines []string, path string, uniqueId int) ([]string, error) { basename := symbolRuneOrUnderscore(filepath.Base(path)) asFile, err := os.Open(path) if err != nil { return nil, err } defer asFile.Close() var contents []string // localSymbols maps from the symbol name used in the input, to a // unique symbol name. localSymbols := make(map[string]string) scanner := bufio.NewScanner(asFile) for scanner.Scan() { line := scanner.Text() trimmed := strings.TrimSpace(line) if strings.HasPrefix(trimmed, ".L") && strings.HasSuffix(trimmed, ":") { symbol := trimmed[:len(trimmed)-1] mappedSymbol := fmt.Sprintf(".L%s_%d_%s", basename, uniqueId, symbol[2:]) localSymbols[symbol] = mappedSymbol contents = append(contents, mappedSymbol+":") continue } contents = append(contents, scanner.Text()) } if err := scanner.Err(); err != nil { return nil, err } for _, line := range contents { for symbol, mappedSymbol := range localSymbols { for i := strings.Index(line, symbol); i >= 0; i = strings.Index(line[i:], symbol) { before := ' ' if i > 0 { before, _ = utf8.DecodeLastRuneInString(line[:i]) } after, _ := utf8.DecodeRuneInString(line[i+len(symbol):]) if !symbolRune(before) && !symbolRune(after) { line = strings.Replace(line, symbol, mappedSymbol, 1) i += len(mappedSymbol) } else { i += len(symbol) } } } lines = append(lines, line) } return lines, nil } func arLines(lines []string, arPath string) ([]string, error) { arFile, err := os.Open(arPath) if err != nil { return nil, err } defer arFile.Close() ar, err := ParseAR(arFile) if err != nil { return nil, err } if len(ar) != 1 { return nil, fmt.Errorf("expected one file in archive, but found %d", len(ar)) } for _, contents := range ar { scanner := bufio.NewScanner(bytes.NewBuffer(contents)) for scanner.Scan() { lines = append(lines, scanner.Text()) } if err := scanner.Err(); err != nil { return nil, err } } return lines, nil } // validSymbolName returns true if s is a valid (non-local) name for a symbol. func validSymbolName(s string) bool { if len(s) == 0 { return false } r, n := utf8.DecodeRuneInString(s) // symbols don't start with a digit. if r == utf8.RuneError || !symbolRune(r) || ('0' <= s[0] && s[0] <= '9') { return false } return strings.IndexFunc(s[n:], func(r rune) bool { return !symbolRune(r) }) == -1 } // symbolRune returns true if r is valid in a symbol name. func symbolRune(r rune) bool { return (r >= 'a' && r <= 'z') || (r >= 'A' && r <= 'Z') || (r >= '0' && r <= '9') || r == '$' || r == '_' } // symbolRuneOrUnderscore maps s where runes valid in a symbol name map to // themselves and all other runs map to underscore. func symbolRuneOrUnderscore(s string) string { runes := make([]rune, 0, len(s)) for _, r := range s { if symbolRune(r) { runes = append(runes, r) } else { runes = append(runes, '_') } } return string(runes) }