neoneo-go/pkg/vm/stack/stack.go

package stack

import (
	"errors"
	"fmt"
)

const (
	// StackAverageSize is used to set the capacity of the stack
	// setting this number too low, will cause extra allocations
	StackAverageSize = 20
)

// RandomAccess represents a Random Access Stack
type RandomAccess struct {
	vals []Item
}

// New will return a new random access stack
func New() *RandomAccess {
	return &RandomAccess{
		vals: make([]Item, 0, StackAverageSize),
	}
}

// Items will return all items in the stack
func (ras *RandomAccess) items() []Item {
	return ras.vals
}

//Len will return the length of the stack
func (ras *RandomAccess) Len() int {
	if ras.vals == nil {
		return -1
	}
	return len(ras.vals)
}

// Clear will remove all items in the stack
func (ras *RandomAccess) Clear() {
	ras.vals = make([]Item, 0, StackAverageSize)
}

// Pop will remove the last stack item that was added
func (ras *RandomAccess) Pop() (Item, error) {
	if len(ras.vals) == 0 {
		return nil, errors.New("There are no items on the stack to pop")
	}
	if ras.vals == nil {
		return nil, errors.New("Cannot pop from a nil stack")
	}

	l := len(ras.vals)
	item := ras.vals[l-1]
	ras.vals = ras.vals[:l-1]

	return item, nil
}

// Push will put a stack item onto the top of the stack
func (ras *RandomAccess) Push(item Item) *RandomAccess {
	if ras.vals == nil {
		ras.vals = make([]Item, 0, StackAverageSize)
	}

	ras.vals = append(ras.vals, item)

	return ras
}

// Insert will push a stackItem onto the stack at position `n`
// Note; index 0 is the top of the stack, which is the end of slice
func (ras *RandomAccess) Insert(n uint16, item Item) (*RandomAccess, error) {

	if n == 0 {
		return ras.Push(item), nil
	}

	if ras.vals == nil {
		ras.vals = make([]Item, 0, StackAverageSize)
	}

	// Check that we are not inserting out of the bounds
	stackSize := uint16(len(ras.vals))
	if n > stackSize-1 {
		return nil, fmt.Errorf("Tried to insert at index %d when length of stack is %d", n, len(ras.vals))
	}

	index := stackSize - n

	ras.vals = append(ras.vals, item)
	copy(ras.vals[index:], ras.vals[index-1:])
	ras.vals[index] = item

	return ras, nil
}

// Peek will check an element at a given index
// Note: 0 is the top of the stack, which is the end of the slice
func (ras *RandomAccess) Peek(n uint16) (Item, error) {

	stackSize := uint16(len(ras.vals))

	if n == 0 {
		index := stackSize - 1
		return ras.vals[index], nil
	}

	if ras.Len() < 1 {
		return nil, fmt.Errorf("cannot peak at a stack with no item, length of stack is %d", ras.Len())
	}

	// Check that we are not peeking out of the bounds
	if n > stackSize-1 {
		return nil, fmt.Errorf("Tried to peek at index %d when length of stack is %d", n, len(ras.vals))
	}
	index := stackSize - n - 1

	return ras.vals[index], nil
}

// CopyTo will copy all of the stack items from `ras` into the stack that is passed as an argument
// XXX: once maxstacksize is implemented, we will return error if size goes over
// There will also be additional checks needed once stack isolation is added
func (ras *RandomAccess) CopyTo(stack *RandomAccess) error {
	stack.vals = append(stack.vals, ras.vals...)
	return nil
}

// Convenience Functions

// PopInt will remove the last stack item that was added
// And cast it to an integer
func (ras *RandomAccess) PopInt() (*Int, error) {
	item, err := ras.Pop()
	if err != nil {
		return nil, err
	}
	return item.Integer()
}

// PopByteArray will remove the last stack item that was added
// And cast it to an ByteArray
func (ras *RandomAccess) PopByteArray() (*ByteArray, error) {
	item, err := ras.Pop()
	if err != nil {
		return nil, err
	}
	return item.ByteArray()
}
VM: Add basic vm (#166) * VM:Add abstract stack item * VM: Add stackItems; Array, Boolean, Int and ByteArray * VM: Add tests for stack item * VM: first pass at Random Access Stack object * VM: Add Sub, Mul, Mod LSH, RSH * VM: moved test helper functions into separate file * VM: removed helper functions from stack_test.go * Add conversions for bytearray and Int stack items * Add instructions file for vm * - Add guide to stack readme - Add testReadInt64 * Add Builder * Refactor Int, Boolean, ByteArray conversion * Add Context stack Item * Add Invocation stack - convenience RAS * rename testhelper to test_helper * Move opcode file * - Add `Add` OpCode - Add Opcode Function map * - Add test for math `Add` opcode - basic opcode execution * Add popTwoIntegers convenience func * Add `SUB` Opcode * Export Context Read methods - Return errors where failable * - Add `Op` to handleOP func signature - Add PushNBytes OPcode * remove error on NewBoolean - Expose underlying with Getter on Boolean StackItem - Add Equals method for ByteArray * Make Next() method on Context failable, refactor peekContext and Peek * Add ExecuteOp, Step and Run methods on the VM * Add Equal Opcode * Add THROWIFNOT Opcode * Add RET Opcode * Refactor PushNBytes Opcode * refactor Add, Sub to return VMSTATE add popTwoByteArrays helper function * Add basic tests for vm * clarify vm states * Add astack * [VM] Pass ResultStack to the opcode handlers * [VM] refactor handlers to have rstack as argument * [Stack] - Change RemoveCurrentContext for PopCurrentContext - Add CopTo method to stack * [VM] Add Result stack Len check in simple run test * [VM] fix typo * [Peer/Stall] Change seconds to milliseconds in test 2019-03-18 21:40:21 +00:00			`package stack`

			`import (`
			`"errors"`
			`"fmt"`
			`)`

			`const (`
			`// StackAverageSize is used to set the capacity of the stack`
			`// setting this number too low, will cause extra allocations`
			`StackAverageSize = 20`
			`)`

			`// RandomAccess represents a Random Access Stack`
			`type RandomAccess struct {`
			`vals []Item`
			`}`

			`// New will return a new random access stack`
			`func New() *RandomAccess {`
			`return &RandomAccess{`
			`vals: make([]Item, 0, StackAverageSize),`
			`}`
			`}`

			`// Items will return all items in the stack`
			`func (ras *RandomAccess) items() []Item {`
			`return ras.vals`
			`}`

			`//Len will return the length of the stack`
			`func (ras *RandomAccess) Len() int {`
			`if ras.vals == nil {`
			`return -1`
			`}`
			`return len(ras.vals)`
			`}`

			`// Clear will remove all items in the stack`
			`func (ras *RandomAccess) Clear() {`
			`ras.vals = make([]Item, 0, StackAverageSize)`
			`}`

			`// Pop will remove the last stack item that was added`
			`func (ras *RandomAccess) Pop() (Item, error) {`
			`if len(ras.vals) == 0 {`
			`return nil, errors.New("There are no items on the stack to pop")`
			`}`
			`if ras.vals == nil {`
			`return nil, errors.New("Cannot pop from a nil stack")`
			`}`

			`l := len(ras.vals)`
			`item := ras.vals[l-1]`
			`ras.vals = ras.vals[:l-1]`

			`return item, nil`
			`}`

			`// Push will put a stack item onto the top of the stack`
			`func (ras RandomAccess) Push(item Item) RandomAccess {`
			`if ras.vals == nil {`
			`ras.vals = make([]Item, 0, StackAverageSize)`
			`}`

			`ras.vals = append(ras.vals, item)`

			`return ras`
			`}`

			// Insert will push a stackItem onto the stack at position `n`
			`// Note; index 0 is the top of the stack, which is the end of slice`
			`func (ras RandomAccess) Insert(n uint16, item Item) (RandomAccess, error) {`

			`if n == 0 {`
			`return ras.Push(item), nil`
			`}`

			`if ras.vals == nil {`
			`ras.vals = make([]Item, 0, StackAverageSize)`
			`}`

			`// Check that we are not inserting out of the bounds`
			`stackSize := uint16(len(ras.vals))`
			`if n > stackSize-1 {`
			`return nil, fmt.Errorf("Tried to insert at index %d when length of stack is %d", n, len(ras.vals))`
			`}`

			`index := stackSize - n`

			`ras.vals = append(ras.vals, item)`
			`copy(ras.vals[index:], ras.vals[index-1:])`
			`ras.vals[index] = item`

			`return ras, nil`
			`}`

			`// Peek will check an element at a given index`
			`// Note: 0 is the top of the stack, which is the end of the slice`
			`func (ras *RandomAccess) Peek(n uint16) (Item, error) {`

			`stackSize := uint16(len(ras.vals))`

			`if n == 0 {`
			`index := stackSize - 1`
			`return ras.vals[index], nil`
			`}`

			`if ras.Len() < 1 {`
			`return nil, fmt.Errorf("cannot peak at a stack with no item, length of stack is %d", ras.Len())`
			`}`

			`// Check that we are not peeking out of the bounds`
			`if n > stackSize-1 {`
			`return nil, fmt.Errorf("Tried to peek at index %d when length of stack is %d", n, len(ras.vals))`
			`}`
			`index := stackSize - n - 1`

			`return ras.vals[index], nil`
			`}`

			// CopyTo will copy all of the stack items from `ras` into the stack that is passed as an argument
			`// XXX: once maxstacksize is implemented, we will return error if size goes over`
			`// There will also be additional checks needed once stack isolation is added`
			`func (ras RandomAccess) CopyTo(stack RandomAccess) error {`
			`stack.vals = append(stack.vals, ras.vals...)`
			`return nil`
			`}`

			`// Convenience Functions`

			`// PopInt will remove the last stack item that was added`
			`// And cast it to an integer`
			`func (ras RandomAccess) PopInt() (Int, error) {`
			`item, err := ras.Pop()`
			`if err != nil {`
			`return nil, err`
			`}`
			`return item.Integer()`
			`}`

			`// PopByteArray will remove the last stack item that was added`
			`// And cast it to an ByteArray`
			`func (ras RandomAccess) PopByteArray() (ByteArray, error) {`
			`item, err := ras.Pop()`
			`if err != nil {`
			`return nil, err`
			`}`
			`return item.ByteArray()`
			`}`