package circuitcompiler
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import (
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"errors"
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"fmt"
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"io"
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"os"
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"regexp"
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"strings"
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)
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// Parser data structure holds the Scanner and the Parsing functions
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type Parser struct {
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s *Scanner
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buf struct {
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tok Token // last read token
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lit string // last read literal
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n int // buffer size (max=1)
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}
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}
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// NewParser creates a new parser from a io.Reader
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func NewParser(r io.Reader) *Parser {
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return &Parser{s: NewScanner(r)}
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}
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func (p *Parser) scan() (tok Token, lit string) {
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// if there is a token in the buffer return it
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if p.buf.n != 0 {
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p.buf.n = 0
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return p.buf.tok, p.buf.lit
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}
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tok, lit = p.s.scan()
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p.buf.tok, p.buf.lit = tok, lit
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return
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}
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func (p *Parser) unscan() {
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p.buf.n = 1
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}
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func (p *Parser) scanIgnoreWhitespace() (tok Token, lit string) {
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tok, lit = p.scan()
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if tok == WS {
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tok, lit = p.scan()
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}
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return
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}
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// parseLine parses the current line
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func (p *Parser) parseLine() (*Constraint, error) {
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/*
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in this version,
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line will be for example s3 = s1 * s4
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this is:
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val eq val op val
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*/
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c := &Constraint{}
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tok, lit := p.scanIgnoreWhitespace()
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c.Out = lit
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c.Literal += lit
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if c.Literal == "func" {
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// format: `func name(in):`
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line, err := p.s.r.ReadString(':')
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if err != nil {
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return c, err
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}
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// read string inside ( )
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rgx := regexp.MustCompile(`\((.*?)\)`)
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insideParenthesis := rgx.FindStringSubmatch(line)
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varsString := strings.Replace(insideParenthesis[1], " ", "", -1)
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allInputs := strings.Split(varsString, ",")
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// from allInputs, get the private and the public separated
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for _, in := range allInputs {
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if strings.Contains(in, "private") {
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input := strings.Replace(in, "private", "", -1)
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c.PrivateInputs = append(c.PrivateInputs, input)
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} else if strings.Contains(in, "public") {
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input := strings.Replace(in, "public", "", -1)
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c.PublicInputs = append(c.PublicInputs, input)
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} else {
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// TODO give more info about the circuit code error
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fmt.Println("error on declaration of public and private inputs")
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os.Exit(0)
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}
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}
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return c, nil
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}
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if c.Literal == "equals" {
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// format: `equals(a, b)`
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line, err := p.s.r.ReadString(')')
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if err != nil {
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return c, err
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}
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// read string inside ( )
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rgx := regexp.MustCompile(`\((.*?)\)`)
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insideParenthesis := rgx.FindStringSubmatch(line)
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varsString := strings.Replace(insideParenthesis[1], " ", "", -1)
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params := strings.Split(varsString, ",")
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fmt.Println("params", params)
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// TODO
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c.V1 = params[0]
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c.V2 = params[1]
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return c, nil
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}
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// if c.Literal == "out" {
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// // TODO
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// return c, nil
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// }
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_, lit = p.scanIgnoreWhitespace() // skip =
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c.Literal += lit
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// v1
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_, lit = p.scanIgnoreWhitespace()
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c.V1 = lit
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c.Literal += lit
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// operator
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_, lit = p.scanIgnoreWhitespace()
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c.Op = lit
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c.Literal += lit
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// v2
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_, lit = p.scanIgnoreWhitespace()
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c.V2 = lit
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c.Literal += lit
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if tok == EOF {
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return nil, errors.New("eof in parseline")
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}
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return c, nil
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}
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func existInArray(arr []string, elem string) bool {
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for _, v := range arr {
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if v == elem {
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return true
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}
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}
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return false
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}
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func addToArrayIfNotExist(arr []string, elem string) []string {
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for _, v := range arr {
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if v == elem {
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return arr
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}
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}
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arr = append(arr, elem)
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return arr
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}
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// Parse parses the lines and returns the compiled Circuit
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func (p *Parser) Parse() (*Circuit, error) {
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circuit := &Circuit{}
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circuit.Signals = append(circuit.Signals, "one")
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nInputs := 0
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for {
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constraint, err := p.parseLine()
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if err != nil {
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break
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}
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fmt.Println(constraint)
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if constraint.Literal == "func" {
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// one constraint for each input
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for _, in := range constraint.PublicInputs {
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newConstr := &Constraint{
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Op: "in",
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Out: in,
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}
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circuit.Constraints = append(circuit.Constraints, *newConstr)
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nInputs++
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circuit.Signals = addToArrayIfNotExist(circuit.Signals, in)
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circuit.NPublic++
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}
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for _, in := range constraint.PrivateInputs {
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newConstr := &Constraint{
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Op: "in",
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Out: in,
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}
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circuit.Constraints = append(circuit.Constraints, *newConstr)
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nInputs++
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circuit.Signals = addToArrayIfNotExist(circuit.Signals, in)
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}
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circuit.PublicInputs = constraint.PublicInputs
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circuit.PrivateInputs = constraint.PrivateInputs
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continue
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}
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if constraint.Literal == "equals" {
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// TODO
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fmt.Println("circuit.Signals", circuit.Signals)
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constr1 := &Constraint{
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Op: "*",
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V1: constraint.V2,
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V2: "1",
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Out: constraint.V1,
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Literal: "equals(" + constraint.V1 + ", " + constraint.V2 + "): " + constraint.V1 + "==" + constraint.V2 + " * 1",
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}
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circuit.Constraints = append(circuit.Constraints, *constr1)
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constr2 := &Constraint{
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Op: "*",
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V1: constraint.V1,
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V2: "1",
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Out: constraint.V2,
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Literal: "equals(" + constraint.V1 + ", " + constraint.V2 + "): " + constraint.V2 + "==" + constraint.V1 + " * 1",
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}
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circuit.Constraints = append(circuit.Constraints, *constr2)
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continue
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}
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circuit.Constraints = append(circuit.Constraints, *constraint)
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isVal, _ := isValue(constraint.V1)
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if !isVal {
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circuit.Signals = addToArrayIfNotExist(circuit.Signals, constraint.V1)
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}
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isVal, _ = isValue(constraint.V2)
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if !isVal {
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circuit.Signals = addToArrayIfNotExist(circuit.Signals, constraint.V2)
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}
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// if constraint.Out == "out" {
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// if Out is "out", put it after first value (one) and before the inputs
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// if constraint.Out == circuit.PublicInputs[0] {
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// if existInArray(circuit.PublicInputs, constraint.Out) {
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// // if Out is a public signal, put it after first value (one) and before the private inputs
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// if !existInArray(circuit.Signals, constraint.Out) {
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// // if already don't exists in signal array
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// signalsCopy := copyArray(circuit.Signals)
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// var auxSignals []string
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// auxSignals = append(auxSignals, signalsCopy[0])
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// auxSignals = append(auxSignals, constraint.Out)
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// auxSignals = append(auxSignals, signalsCopy[1:]...)
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// circuit.Signals = auxSignals
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// // circuit.PublicInputs = append(circuit.PublicInputs, constraint.Out)
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// circuit.NPublic++
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// }
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// } else {
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circuit.Signals = addToArrayIfNotExist(circuit.Signals, constraint.Out)
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// }
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}
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circuit.NVars = len(circuit.Signals)
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circuit.NSignals = len(circuit.Signals)
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return circuit, nil
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}
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func copyArray(in []string) []string { // tmp
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var out []string
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for _, e := range in {
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out = append(out, e)
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}
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return out
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}
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