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diskii/lib/supermon/supermon.go

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// Copyright © 2016 Zellyn Hunter <zellyn@gmail.com>
// Package supermon contains routines for working with the on-disk
// structures of NakedOS/Super-Mon disks.
package supermon
// TODO(zellyn): remove panics.
import (
"fmt"
"strings"
"github.com/zellyn/diskii/lib/disk"
)
const (
// FileIllegal (zero) is not allowed in the sector map.
FileIllegal = 0
// FileFree signifies unused space in the sector map.
FileFree = 0xff
// FileReserved signifies space used by NakedOS in the sector map.
FileReserved = 0xfe
)
// SectorMap is the list of sectors by file. It's always 560 bytes
// long (35 tracks * 16 sectors).
type SectorMap []byte
// LoadSectorMap loads a NakedOS sector map.
func LoadSectorMap(sd disk.SectorDisk) (SectorMap, error) {
sm := SectorMap(make([]byte, 560))
sector09, err := sd.ReadPhysicalSector(0, 9)
if err != nil {
return sm, err
}
sector0A, err := sd.ReadPhysicalSector(0, 0xA)
if err != nil {
return sm, err
}
sector0B, err := sd.ReadPhysicalSector(0, 0xB)
if err != nil {
return sm, err
}
copy(sm[0:0x30], sector09[0xd0:])
copy(sm[0x30:0x130], sector0A)
copy(sm[0x130:0x230], sector0B)
return sm, nil
}
// Verify checks that we actually have a NakedOS disk.
func (sm SectorMap) Verify() error {
for sector := byte(0); sector <= 0xB; sector++ {
if file := sm.FileForSector(0, sector); file != FileReserved {
return fmt.Errorf("Expected track 0, sectors 0-C to be reserved (0xFE), but got 0x%02X in sector %X", file, sector)
}
}
for track := byte(0); track < 35; track++ {
for sector := byte(0); sector < 16; sector++ {
file := sm.FileForSector(track, sector)
if file == FileIllegal {
return fmt.Errorf("Found illegal sector map value (%02X), in track %X sector %X", FileIllegal, track, sector)
}
}
}
return nil
}
// FileForSector returns the file that owns the given track/sector.
func (sm SectorMap) FileForSector(track, sector byte) byte {
if track >= 35 {
panic(fmt.Sprintf("FileForSector called with track=%d > 34", track))
}
if sector >= 16 {
panic(fmt.Sprintf("FileForSector called with sector=%d > 15", sector))
}
return sm[int(track)*16+int(sector)]
}
// SectorsForFile returns the list of sectors that belong to the given
// file.
func (sm SectorMap) SectorsForFile(file byte) []disk.TrackSector {
var result []disk.TrackSector
for track := byte(0); track < 35; track++ {
for sector := byte(0); sector < 16; sector++ {
if file == sm.FileForSector(track, sector) {
result = append(result, disk.TrackSector{Track: track, Sector: sector})
}
}
}
return result
}
// SectorsByFile returns a map of file number to slice of sectors.
func (sm SectorMap) SectorsByFile() map[byte][]disk.TrackSector {
result := map[byte][]disk.TrackSector{}
for file := byte(0x01); file < FileReserved; file++ {
sectors := sm.SectorsForFile(file)
if len(sectors) > 0 {
result[file] = sectors
}
}
return result
}
// ReadFile reads the contents of a file.
func (sm SectorMap) ReadFile(sd disk.SectorDisk, file byte) []byte {
var result []byte
for _, ts := range sm.SectorsForFile(file) {
bytes, err := sd.ReadPhysicalSector(ts.Track, ts.Sector)
if err != nil {
panic(err.Error())
}
result = append(result, bytes...)
}
return result
}
// Symbol represents a single Super-Mon symbol.
type Symbol struct {
// Address is the memory address the symbol points to, or 0 for an
// empty symbol table entry.
Address uint16
// Name is the name of the symbol.
Name string
// Link is the index of the next symbol in the symbol chain for this
// hash key, or -1 if none.
Link int
}
// decodeSymbol decodes a Super-Mon encoded symbol table entry,
// returning the string representation.
func decodeSymbol(five []byte, extra byte) string {
result := ""
value := uint64(five[0]) + uint64(five[1])<<8 + uint64(five[2])<<16 + uint64(five[3])<<24 + uint64(five[4])<<32 + uint64(extra)<<40
for value&0x1f > 0 {
if value&0x1f < 27 {
result = result + string(value&0x1f+'@')
value >>= 5
continue
}
if value&0x20 == 0 {
result = result + string((value&0x1f)-0x1b+'0')
} else {
result = result + string((value&0x1f)-0x1b+'5')
}
value >>= 6
}
return result
}
// SymbolTable represents an entire Super-Mon symbol table. It'll
// always be 819 entries long, because it includes blanks.
type SymbolTable []Symbol
// ReadSymbolTable reads the symbol table from a disk. If there are
// problems with the symbol table (like it doesn't exist, or the link
// pointers are problematic), it'll return nil and an error.
func (sm SectorMap) ReadSymbolTable(sd disk.SectorDisk) (SymbolTable, error) {
table := make(SymbolTable, 0, 819)
symtbl1 := sm.ReadFile(sd, 3)
if len(symtbl1) != 0x1000 {
return nil, fmt.Errorf("expected file FSYMTBL1(0x3) to be 0x1000 bytes long; got 0x%04X", len(symtbl1))
}
symtbl2 := sm.ReadFile(sd, 4)
if len(symtbl2) != 0x1000 {
return nil, fmt.Errorf("expected file FSYMTBL1(0x4) to be 0x1000 bytes long; got 0x%04X", len(symtbl2))
}
five := []byte{0, 0, 0, 0, 0}
for i := 0; i < 0x0fff; i += 5 {
address := uint16(symtbl1[i]) + uint16(symtbl1[i+1])<<8
if address == 0 {
table = append(table, Symbol{})
continue
}
linkAddr := uint16(symtbl1[i+2]) + uint16(symtbl1[i+3])<<8
link := -1
if linkAddr != 0 {
if linkAddr < 0xD000 || linkAddr >= 0xDFFF {
return nil, fmt.Errorf("Expected symbol table link address between 0xD000 and 0xDFFE; got 0x%04X", linkAddr)
}
if (linkAddr-0xD000)%5 != 0 {
return nil, fmt.Errorf("Expected symbol table link address to 0xD000+5x; got 0x%04X", linkAddr)
}
link = (int(linkAddr) - 0xD000) % 5
}
extra := symtbl1[i+4]
copy(five, symtbl2[i:i+5])
name := decodeSymbol(five, extra)
symbol := Symbol{
Address: address,
Name: name,
Link: link,
}
table = append(table, symbol)
}
// TODO(zellyn): check link addresses.
return table, nil
}
// SymbolsByAddress returns a map of addresses to slices of symbols.
func (st SymbolTable) SymbolsByAddress() map[uint16][]Symbol {
result := map[uint16][]Symbol{}
for _, symbol := range st {
if symbol.Address != 0 {
result[symbol.Address] = append(result[symbol.Address], symbol)
}
}
return result
}
func FilenameString(file byte, symbols []Symbol) string {
if len(symbols) > 0 {
for _, symbol := range symbols {
if strings.HasPrefix(symbol.Name, "F") {
return symbol.Name
}
}
return symbols[0].Name
}
return fmt.Sprintf("%02X", file)
}
// operator is a disk.Operator - an interface for performing
// high-level operations on files and directories.
type operator struct {
sd disk.SectorDisk
sm SectorMap
st SymbolTable
symbols map[uint16][]Symbol
}
var _ disk.Operator = operator{}
// operatorName is the keyword name for the operator that undestands
// NakedOS/Super-Mon disks.
const operatorName = "nakedos"
// Name returns the name of the operator.
func (o operator) Name() string {
return operatorName
}
// HasSubdirs returns true if the underlying operating system on the
// disk allows subdirectories.
func (o operator) HasSubdirs() bool {
return false
}
// Catalog returns a catalog of disk entries. subdir should be empty
// for operating systems that do not support subdirectories.
func (o operator) Catalog(subdir string) ([]disk.Descriptor, error) {
var descs []disk.Descriptor
sectorsByFile := o.sm.SectorsByFile()
for file := byte(1); file < FileReserved; file++ {
l := len(sectorsByFile[file])
if l == 0 {
continue
}
fileAddr := uint16(0xDF00) + uint16(file)
descs = append(descs, disk.Descriptor{
Name: FilenameString(file, o.symbols[fileAddr]),
Sectors: l,
Length: l * 256,
Locked: false,
})
}
return descs, nil
}
// operatorFactory is the factory that returns dos33 operators given
// disk images.
func operatorFactory(sd disk.SectorDisk) (disk.Operator, error) {
sm, err := LoadSectorMap(sd)
if err != nil {
return nil, err
}
if err := sm.Verify(); err != nil {
return nil, err
}
op := operator{sd: sd, sm: sm}
st, err := sm.ReadSymbolTable(sd)
if err == nil {
op.st = st
op.symbols = st.SymbolsByAddress()
}
return op, nil
}
func init() {
disk.RegisterOperatorFactory(operatorName, operatorFactory)
}
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