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package state
import (
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"fmt"
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"log"
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)
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// State holds the command stack, error condition of a unique execution session.
//
// It also holds cached values for all results of executed symbols.
//
// Cached values are linked to the command stack level it which they were loaded. When they go out of scope they are freed.
//
// Values must be mapped to a level in order to be available for retrieval and count towards size
//
// It can hold a single argument, which is freed once it is read
//
// Symbols are loaded with individual size limitations. The limitations apply if a load symbol is updated. Symbols may be added with a 0-value for limits, called a "sink." If mapped, the sink will consume all net remaining size allowance unused by other symbols. Only one sink may be mapped per level.
//
// Symbol keys do not count towards cache size limitations.
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//
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// 8 first flags are reserved.
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type State struct {
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Flags [ ] byte // Error state
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input [ ] byte // Last input
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code [ ] byte // Pending bytecode to execute
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execPath [ ] string // Command symbols stack
arg * string // Optional argument. Nil if not set.
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bitSize uint32 // size of (32-bit capacity) bit flag byte array
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sizeIdx uint16
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}
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// number of bytes necessary to represent a bitfield of the given size.
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func toByteSize ( bitSize uint32 ) uint8 {
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if bitSize == 0 {
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return 0
}
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n := bitSize % 8
if n > 0 {
bitSize += ( 8 - n )
}
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return uint8 ( bitSize / 8 )
}
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// Retrieve the state of a state flag
func getFlag ( bitIndex uint32 , bitField [ ] byte ) bool {
byteIndex := bitIndex / 8
localBitIndex := bitIndex % 8
b := bitField [ byteIndex ]
return ( b & ( 1 << localBitIndex ) ) > 0
}
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// NewState creates a new State object with bitSize number of error condition states in ADDITION to the 8 builtin flags.
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func NewState ( bitSize uint32 ) State {
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st := State {
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bitSize : bitSize + 8 ,
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}
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byteSize := toByteSize ( bitSize + 8 )
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if byteSize > 0 {
st . Flags = make ( [ ] byte , byteSize )
} else {
st . Flags = [ ] byte { }
}
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return st
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}
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// SetFlag sets the flag at the given bit field index
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//
// Returns true if bit state was changed.
//
// Fails if bitindex is out of range.
func ( st * State ) SetFlag ( bitIndex uint32 ) ( bool , error ) {
if bitIndex + 1 > st . bitSize {
return false , fmt . Errorf ( "bit index %v is out of range of bitfield size %v" , bitIndex , st . bitSize )
}
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r := getFlag ( bitIndex , st . Flags )
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if r {
return false , nil
}
byteIndex := bitIndex / 8
localBitIndex := bitIndex % 8
b := st . Flags [ byteIndex ]
st . Flags [ byteIndex ] = b | ( 1 << localBitIndex )
return true , nil
}
// ResetFlag resets the flag at the given bit field index.
//
// Returns true if bit state was changed.
//
// Fails if bitindex is out of range.
func ( st * State ) ResetFlag ( bitIndex uint32 ) ( bool , error ) {
if bitIndex + 1 > st . bitSize {
return false , fmt . Errorf ( "bit index %v is out of range of bitfield size %v" , bitIndex , st . bitSize )
}
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r := getFlag ( bitIndex , st . Flags )
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if ! r {
return false , nil
}
byteIndex := bitIndex / 8
localBitIndex := bitIndex % 8
b := st . Flags [ byteIndex ]
st . Flags [ byteIndex ] = b & ( ^ ( 1 << localBitIndex ) )
return true , nil
}
// GetFlag returns the state of the flag at the given bit field index.
//
// Fails if bit field index is out of range.
func ( st * State ) GetFlag ( bitIndex uint32 ) ( bool , error ) {
if bitIndex + 1 > st . bitSize {
return false , fmt . Errorf ( "bit index %v is out of range of bitfield size %v" , bitIndex , st . bitSize )
}
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return getFlag ( bitIndex , st . Flags ) , nil
}
// FlagBitSize reports the amount of bits available in the bit field index.
func ( st * State ) FlagBitSize ( ) uint32 {
return st . bitSize
}
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// FlagBitSize reports the amount of bits available in the bit field index.
func ( st * State ) FlagByteSize ( ) uint8 {
return uint8 ( len ( st . Flags ) )
}
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// MatchFlag matches the current state of the given flag.
//
// The flag is specified given its bit index in the bit field.
//
// If invertMatch is set, a positive result will be returned if the flag is not set.
func ( st * State ) MatchFlag ( sig uint32 , invertMatch bool ) ( bool , error ) {
r , err := st . GetFlag ( sig )
if err != nil {
return false , err
}
if invertMatch {
if ! r {
return true , nil
}
} else if r {
return true , nil
}
return false , nil
}
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// GetIndex scans a byte slice in same order as in storage, and returns the index of the first set bit.
//
// If the given byte slice is too small for the bit field bitsize, the check will terminate at end-of-data without error.
func ( st * State ) GetIndex ( flags [ ] byte ) bool {
var globalIndex uint32
if st . bitSize == 0 {
return false
}
if len ( flags ) == 0 {
return false
}
var byteIndex uint8
var localIndex uint8
l := uint8 ( len ( flags ) )
var i uint32
for i = 0 ; i < st . bitSize ; i ++ {
testVal := flags [ byteIndex ] & ( 1 << localIndex )
if ( testVal & st . Flags [ byteIndex ] ) > 0 {
return true
}
globalIndex += 1
if globalIndex % 8 == 0 {
byteIndex += 1
localIndex = 0
if byteIndex > ( l - 1 ) {
return false
}
} else {
localIndex += 1
}
}
return false
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}
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// Where returns the current active rendering symbol.
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func ( st * State ) Where ( ) ( string , uint16 ) {
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if len ( st . execPath ) == 0 {
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return "" , 0
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}
l := len ( st . execPath )
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return st . execPath [ l - 1 ] , st . sizeIdx
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}
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// Next moves to the next sink page index.
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func ( st * State ) Next ( ) ( uint16 , error ) {
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if len ( st . execPath ) == 0 {
return 0 , fmt . Errorf ( "state root node not yet defined" )
}
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st . sizeIdx += 1
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s , idx := st . Where ( )
log . Printf ( "next page for %s: %v" , s , idx )
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return st . sizeIdx , nil
}
// Previous moves to the next sink page index.
//
// Fails if try to move beyond index 0.
func ( st * State ) Previous ( ) ( uint16 , error ) {
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if len ( st . execPath ) == 0 {
return 0 , fmt . Errorf ( "state root node not yet defined" )
}
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if st . sizeIdx == 0 {
return 0 , fmt . Errorf ( "already at first index" )
}
st . sizeIdx -= 1
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s , idx := st . Where ( )
log . Printf ( "previous page for %s: %v" , s , idx )
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return st . sizeIdx , nil
}
// Sides informs the caller which index page options will currently succeed.
//
// Two values are returned, for the "next" and "previous" options in that order. A false value means the option is not available in the current state.
func ( st * State ) Sides ( ) ( bool , bool ) {
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if len ( st . execPath ) == 0 {
return false , false
}
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next := true
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log . Printf ( "sides %v" , st . sizeIdx )
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if st . sizeIdx == 0 {
return next , false
}
return next , true
}
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// Top returns true if currently at topmode node.
//
// Fails if first Down() was never called.
func ( st * State ) Top ( ) ( bool , error ) {
if len ( st . execPath ) == 0 {
return false , fmt . Errorf ( "state root node not yet defined" )
}
return len ( st . execPath ) == 1 , nil
}
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// Down adds the given symbol to the command stack.
//
// Clears mapping and sink.
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func ( st * State ) Down ( input string ) error {
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st . execPath = append ( st . execPath , input )
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st . sizeIdx = 0
return nil
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}
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// Up removes the latest symbol to the command stack, and make the previous symbol current.
//
// Frees all symbols and associated values loaded at the previous stack level. Cache capacity is increased by the corresponding amount.
//
// Clears mapping and sink.
//
// Fails if called at top frame.
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func ( st * State ) Up ( ) ( string , error ) {
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l := len ( st . execPath )
if l == 0 {
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return "" , fmt . Errorf ( "exit called beyond top frame" )
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}
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st . execPath = st . execPath [ : l - 1 ]
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sym := ""
if len ( st . execPath ) > 0 {
sym = st . execPath [ len ( st . execPath ) - 1 ]
}
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st . sizeIdx = 0
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return sym , nil
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}
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// Depth returns the current call stack depth.
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func ( st * State ) Depth ( ) uint8 {
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return uint8 ( len ( st . execPath ) - 1 )
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}
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//func(st *State) SetMenuSize(size uint16) error {
// st.menuSize = size
// log.Printf("menu size changed to %v", st.menuSize)
// return nil
//}
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//
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//func(st *State) GetMenuSize() uint16 {
// return st.menuSize
//}
//
//func(st *State) GetOutputSize() uint32 {
// return st.outputSize
//}
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// Appendcode adds the given bytecode to the end of the existing code.
func ( st * State ) AppendCode ( b [ ] byte ) error {
st . code = append ( st . code , b ... )
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log . Printf ( "code changed to 0x%x" , b )
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return nil
}
// SetCode replaces the current bytecode with the given bytecode.
func ( st * State ) SetCode ( b [ ] byte ) {
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log . Printf ( "code set to 0x%x" , b )
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st . code = b
}
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// Get the remaning cached bytecode
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func ( st * State ) GetCode ( ) ( [ ] byte , error ) {
b := st . code
st . code = [ ] byte { }
return b , nil
}
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// GetInput gets the most recent client input.
func ( st * State ) GetInput ( ) ( [ ] byte , error ) {
if st . input == nil {
return nil , fmt . Errorf ( "no input has been set" )
}
return st . input , nil
}
// SetInput is used to record the latest client input.
func ( st * State ) SetInput ( input [ ] byte ) error {
l := len ( input )
if l > 255 {
return fmt . Errorf ( "input size %v too large (limit %v)" , l , 255 )
}
st . input = input
return nil
}