package log import ( "bytes" "fmt" "math/big" "reflect" "strconv" "time" "unicode/utf8" "github.com/holiman/uint256" "golang.org/x/exp/slog" ) const ( timeFormat = "2006-01-02T15:04:05-0700" floatFormat = 'f' termMsgJust = 40 termCtxMaxPadding = 40 ) // 40 spaces var spaces = []byte(" ") // TerminalStringer is an analogous interface to the stdlib stringer, allowing // own types to have custom shortened serialization formats when printed to the // screen. type TerminalStringer interface { TerminalString() string } func (h *TerminalHandler) format(buf []byte, r slog.Record, usecolor bool) []byte { msg := escapeMessage(r.Message) var color = "" if usecolor { switch r.Level { case LevelCrit: color = "\x1b[35m" case slog.LevelError: color = "\x1b[31m" case slog.LevelWarn: color = "\x1b[33m" case slog.LevelInfo: color = "\x1b[32m" case slog.LevelDebug: color = "\x1b[36m" case LevelTrace: color = "\x1b[34m" } } if buf == nil { buf = make([]byte, 0, 30+termMsgJust) } b := bytes.NewBuffer(buf) if color != "" { // Start color b.WriteString(color) b.WriteString(LevelAlignedString(r.Level)) b.WriteString("\x1b[0m") } else { b.WriteString(LevelAlignedString(r.Level)) } b.WriteString("[") writeTimeTermFormat(b, r.Time) b.WriteString("] ") b.WriteString(msg) // try to justify the log output for short messages //length := utf8.RuneCountInString(msg) length := len(msg) if (r.NumAttrs()+len(h.attrs)) > 0 && length < termMsgJust { b.Write(spaces[:termMsgJust-length]) } // print the attributes h.formatAttributes(b, r, color) return b.Bytes() } func (h *TerminalHandler) formatAttributes(buf *bytes.Buffer, r slog.Record, color string) { // tmp is a temporary buffer we use, until bytes.Buffer.AvailableBuffer() (1.21) // can be used. var tmp = make([]byte, 40) writeAttr := func(attr slog.Attr, first, last bool) { buf.WriteByte(' ') if color != "" { buf.WriteString(color) //buf.Write(appendEscapeString(buf.AvailableBuffer(), attr.Key)) buf.Write(appendEscapeString(tmp[:0], attr.Key)) buf.WriteString("\x1b[0m=") } else { //buf.Write(appendEscapeString(buf.AvailableBuffer(), attr.Key)) buf.Write(appendEscapeString(tmp[:0], attr.Key)) buf.WriteByte('=') } //val := FormatSlogValue(attr.Value, true, buf.AvailableBuffer()) val := FormatSlogValue(attr.Value, tmp[:0]) padding := h.fieldPadding[attr.Key] length := utf8.RuneCount(val) if padding < length && length <= termCtxMaxPadding { padding = length h.fieldPadding[attr.Key] = padding } buf.Write(val) if !last && padding > length { buf.Write(spaces[:padding-length]) } } var n = 0 var nAttrs = len(h.attrs) + r.NumAttrs() for _, attr := range h.attrs { writeAttr(attr, n == 0, n == nAttrs-1) n++ } r.Attrs(func(attr slog.Attr) bool { writeAttr(attr, n == 0, n == nAttrs-1) n++ return true }) buf.WriteByte('\n') } // FormatSlogValue formats a slog.Value for serialization to terminal. func FormatSlogValue(v slog.Value, tmp []byte) (result []byte) { var value any defer func() { if err := recover(); err != nil { if v := reflect.ValueOf(value); v.Kind() == reflect.Ptr && v.IsNil() { result = []byte("") } else { panic(err) } } }() switch v.Kind() { case slog.KindString: return appendEscapeString(tmp, v.String()) case slog.KindInt64: // All int-types (int8, int16 etc) wind up here return appendInt64(tmp, v.Int64()) case slog.KindUint64: // All uint-types (uint8, uint16 etc) wind up here return appendUint64(tmp, v.Uint64(), false) case slog.KindFloat64: return strconv.AppendFloat(tmp, v.Float64(), floatFormat, 3, 64) case slog.KindBool: return strconv.AppendBool(tmp, v.Bool()) case slog.KindDuration: value = v.Duration() case slog.KindTime: // Performance optimization: No need for escaping since the provided // timeFormat doesn't have any escape characters, and escaping is // expensive. return v.Time().AppendFormat(tmp, timeFormat) default: value = v.Any() } if value == nil { return []byte("") } switch v := value.(type) { case *big.Int: // Need to be before fmt.Stringer-clause return appendBigInt(tmp, v) case *uint256.Int: // Need to be before fmt.Stringer-clause return appendU256(tmp, v) case error: return appendEscapeString(tmp, v.Error()) case TerminalStringer: return appendEscapeString(tmp, v.TerminalString()) case fmt.Stringer: return appendEscapeString(tmp, v.String()) } // We can use the 'tmp' as a scratch-buffer, to first format the // value, and in a second step do escaping. internal := fmt.Appendf(tmp, "%+v", value) return appendEscapeString(tmp, string(internal)) } // appendInt64 formats n with thousand separators and writes into buffer dst. func appendInt64(dst []byte, n int64) []byte { if n < 0 { return appendUint64(dst, uint64(-n), true) } return appendUint64(dst, uint64(n), false) } // appendUint64 formats n with thousand separators and writes into buffer dst. func appendUint64(dst []byte, n uint64, neg bool) []byte { // Small numbers are fine as is if n < 100000 { if neg { return strconv.AppendInt(dst, -int64(n), 10) } else { return strconv.AppendInt(dst, int64(n), 10) } } // Large numbers should be split const maxLength = 26 var ( out = make([]byte, maxLength) i = maxLength - 1 comma = 0 ) for ; n > 0; i-- { if comma == 3 { comma = 0 out[i] = ',' } else { comma++ out[i] = '0' + byte(n%10) n /= 10 } } if neg { out[i] = '-' i-- } return append(dst, out[i+1:]...) } // FormatLogfmtUint64 formats n with thousand separators. func FormatLogfmtUint64(n uint64) string { return string(appendUint64(nil, n, false)) } // appendBigInt formats n with thousand separators and writes to dst. func appendBigInt(dst []byte, n *big.Int) []byte { if n.IsUint64() { return appendUint64(dst, n.Uint64(), false) } if n.IsInt64() { return appendInt64(dst, n.Int64()) } var ( text = n.String() buf = make([]byte, len(text)+len(text)/3) comma = 0 i = len(buf) - 1 ) for j := len(text) - 1; j >= 0; j, i = j-1, i-1 { c := text[j] switch { case c == '-': buf[i] = c case comma == 3: buf[i] = ',' i-- comma = 0 fallthrough default: buf[i] = c comma++ } } return append(dst, buf[i+1:]...) } // appendU256 formats n with thousand separators. func appendU256(dst []byte, n *uint256.Int) []byte { if n.IsUint64() { return appendUint64(dst, n.Uint64(), false) } res := []byte(n.PrettyDec(',')) return append(dst, res...) } // appendEscapeString writes the string s to the given writer, with // escaping/quoting if needed. func appendEscapeString(dst []byte, s string) []byte { needsQuoting := false needsEscaping := false for _, r := range s { // If it contains spaces or equal-sign, we need to quote it. if r == ' ' || r == '=' { needsQuoting = true continue } // We need to escape it, if it contains // - character " (0x22) and lower (except space) // - characters above ~ (0x7E), plus equal-sign if r <= '"' || r > '~' { needsEscaping = true break } } if needsEscaping { return strconv.AppendQuote(dst, s) } // No escaping needed, but we might have to place within quote-marks, in case // it contained a space if needsQuoting { dst = append(dst, '"') dst = append(dst, []byte(s)...) return append(dst, '"') } return append(dst, []byte(s)...) } // escapeMessage checks if the provided string needs escaping/quoting, similarly // to escapeString. The difference is that this method is more lenient: it allows // for spaces and linebreaks to occur without needing quoting. func escapeMessage(s string) string { needsQuoting := false for _, r := range s { // Allow CR/LF/TAB. This is to make multi-line messages work. if r == '\r' || r == '\n' || r == '\t' { continue } // We quote everything below (0x20) and above~ (0x7E), // plus equal-sign if r < ' ' || r > '~' || r == '=' { needsQuoting = true break } } if !needsQuoting { return s } return strconv.Quote(s) } // writeTimeTermFormat writes on the format "01-02|15:04:05.000" func writeTimeTermFormat(buf *bytes.Buffer, t time.Time) { _, month, day := t.Date() writePosIntWidth(buf, int(month), 2) buf.WriteByte('-') writePosIntWidth(buf, day, 2) buf.WriteByte('|') hour, min, sec := t.Clock() writePosIntWidth(buf, hour, 2) buf.WriteByte(':') writePosIntWidth(buf, min, 2) buf.WriteByte(':') writePosIntWidth(buf, sec, 2) ns := t.Nanosecond() buf.WriteByte('.') writePosIntWidth(buf, ns/1e6, 3) } // writePosIntWidth writes non-negative integer i to the buffer, padded on the left // by zeroes to the given width. Use a width of 0 to omit padding. // Adapted from golang.org/x/exp/slog/internal/buffer/buffer.go func writePosIntWidth(b *bytes.Buffer, i, width int) { // Cheap integer to fixed-width decimal ASCII. // Copied from log/log.go. if i < 0 { panic("negative int") } // Assemble decimal in reverse order. var bb [20]byte bp := len(bb) - 1 for i >= 10 || width > 1 { width-- q := i / 10 bb[bp] = byte('0' + i - q*10) bp-- i = q } // i < 10 bb[bp] = byte('0' + i) b.Write(bb[bp:]) }