package circuitcompiler
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import (
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"fmt"
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"github.com/mottla/go-snark/bn128"
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"github.com/mottla/go-snark/fields"
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"github.com/mottla/go-snark/r1csqap"
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"math/big"
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"sync"
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)
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type utils struct {
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Bn bn128.Bn128
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FqR fields.Fq
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PF r1csqap.PolynomialField
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}
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type Program struct {
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functions map[string]*Circuit
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globalInputs []string
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arithmeticEnvironment utils //find a better name
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R1CS struct {
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A [][]*big.Int
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B [][]*big.Int
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C [][]*big.Int
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}
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}
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func (p *Program) PrintContraintTrees() {
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for k, v := range p.functions {
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fmt.Println(k)
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PrintTree(v.root)
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}
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}
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func (p *Program) BuildConstraintTrees() {
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mainRoot := p.getMainCircuit().root
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if mainRoot.value.Op&(MINUS|PLUS) != 0 {
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newOut := Constraint{Out: "out", V1: "1", V2: "out2", Op: MULTIPLY}
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p.getMainCircuit().addConstraint(&newOut)
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mainRoot.value.Out = "main@out2"
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p.getMainCircuit().gateMap[mainRoot.value.Out] = mainRoot
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}
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for _, in := range p.getMainCircuit().Inputs {
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p.globalInputs = append(p.globalInputs, composeNewFunction(in, p.getMainCircuit().Inputs))
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}
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var wg = sync.WaitGroup{}
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for _, circuit := range p.functions {
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wg.Add(1)
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func() {
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circuit.buildTree(circuit.root)
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wg.Done()
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}()
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}
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wg.Wait()
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return
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}
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func (c *Circuit) buildTree(g *gate) {
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if _, ex := c.gateMap[g.value.Out]; ex {
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if g.OperationType()&(IN|CONST) != 0 {
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return
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}
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} else {
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panic(fmt.Sprintf("undefined variable %s", g.value.Out))
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}
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if g.OperationType() == FUNC {
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//g.funcInputs = []*gate{}
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for _, in := range g.value.Inputs {
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if gate, ex := c.gateMap[in]; ex {
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g.funcInputs = append(g.funcInputs, gate)
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//note that we do repeated work here. the argument
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c.buildTree(gate)
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} else {
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panic(fmt.Sprintf("undefined argument %s", g.value.V1))
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}
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}
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return
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}
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if constr, ex := c.gateMap[g.value.V1]; ex {
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g.left = constr
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c.buildTree(g.left)
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} else {
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panic(fmt.Sprintf("undefined value %s", g.value.V1))
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}
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if constr, ex := c.gateMap[g.value.V2]; ex {
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g.right = constr
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c.buildTree(g.right)
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} else {
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panic(fmt.Sprintf("undefined value %s", g.value.V2))
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}
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}
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func (p *Program) ReduceCombinedTree() (orderedmGates []gate) {
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mGatesUsed := make(map[string]bool)
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orderedmGates = []gate{}
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p.r1CSRecursiveBuild(p.getMainCircuit(), p.getMainCircuit().root, mGatesUsed, &orderedmGates, false, false)
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return orderedmGates
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}
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func (p *Program) r1CSRecursiveBuild(currentCircuit *Circuit, root *gate, mGatesUsed map[string]bool, orderedmGates *[]gate, negate bool, inverse bool) (variableEnd bool) {
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if root.OperationType() == IN {
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return true
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}
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if root.OperationType() == CONST {
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return false
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}
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if root.OperationType() == FUNC {
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nextContext := p.extendedFunctionRenamer(currentCircuit, root.value)
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currentCircuit = nextContext
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root = nextContext.root
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}
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originOfVariable := p.functions[getContextFromVariable(root.value.Out)]
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if _, alreadyComputed := mGatesUsed[composeNewFunction(root.value.Out, originOfVariable.currentOutputs())]; alreadyComputed {
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return true
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}
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variableEnd = p.r1CSRecursiveBuild(currentCircuit, root.left, mGatesUsed, orderedmGates, negate, inverse)
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cons := p.r1CSRecursiveBuild(currentCircuit, root.right, mGatesUsed, orderedmGates, Xor(negate, root.value.negate), Xor(inverse, root.value.invert))
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if root.OperationType() == MULTIPLY {
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if !(variableEnd && cons) && !root.value.invert && root != p.getMainCircuit().root {
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return variableEnd || cons
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}
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root.leftIns = p.collectFactors(currentCircuit, root.left, mGatesUsed, false, false)
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//if root.left.value.Out== root.right.value.Out{
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// //note this is not a full copy, but shouldnt be a problem
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// root.rightIns= root.leftIns
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//}else{
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// collectAtomsInSubtree(root.right, mGatesUsed, 1, root.rightIns, functionRootMap, Xor(negate, root.value.negate), Xor(inverse, root.value.invert))
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//}
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//root.rightIns = collectAtomsInSubtree3(root.right, mGatesUsed, Xor(negate, root.value.negate), Xor(inverse, root.value.invert))
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root.rightIns = p.collectFactors(currentCircuit, root.right, mGatesUsed, false, false)
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root.index = len(mGatesUsed)
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var nn = composeNewFunction(root.value.Out, originOfVariable.currentOutputs())
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//var nn = root.value.Out
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//if _, ex := p.functions[root.value.Out]; ex {
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// nn = currentCircuit.currentOutputName()
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//}
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if _, ex := mGatesUsed[nn]; ex {
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panic(fmt.Sprintf("told ya so %v", nn))
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}
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mGatesUsed[nn] = true
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rootGate := cloneGate(root)
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rootGate.value.Out = nn
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*orderedmGates = append(*orderedmGates, *rootGate)
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}
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return variableEnd || cons
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//TODO optimize if output is not a multipication gate
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}
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type factor struct {
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typ Token
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name string
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invert, negate bool
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multiplicative [2]int
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}
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func (f factor) String() string {
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if f.typ == CONST {
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return fmt.Sprintf("(const fac: %v)", f.multiplicative)
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}
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str := f.name
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if f.invert {
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str += "^-1"
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}
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if f.negate {
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str = "-" + str
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}
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return fmt.Sprintf("(\"%s\" fac: %v)", str, f.multiplicative)
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}
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func mul2DVector(a, b [2]int) [2]int {
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return [2]int{a[0] * b[0], a[1] * b[1]}
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}
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func mulFactors(leftFactors, rightFactors []factor) (result []factor) {
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for _, facLeft := range leftFactors {
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for i, facRight := range rightFactors {
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if facLeft.typ == CONST && facRight.typ == IN {
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rightFactors[i] = factor{typ: IN, name: facRight.name, negate: Xor(facLeft.negate, facRight.negate), invert: facRight.invert, multiplicative: mul2DVector(facRight.multiplicative, facLeft.multiplicative)}
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continue
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}
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if facRight.typ == CONST && facLeft.typ == IN {
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rightFactors[i] = factor{typ: IN, name: facLeft.name, negate: Xor(facLeft.negate, facRight.negate), invert: facLeft.invert, multiplicative: mul2DVector(facRight.multiplicative, facLeft.multiplicative)}
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continue
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}
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if facRight.typ&facLeft.typ == CONST {
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rightFactors[i] = factor{typ: CONST, negate: Xor(facRight.negate, facLeft.negate), multiplicative: mul2DVector(facRight.multiplicative, facLeft.multiplicative)}
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continue
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}
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//tricky part here
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//this one should only be reached, after a true mgate had its left and right braches computed. here we
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//a factor can appear at most in quadratic form. we reduce terms a*a^-1 here.
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if facRight.typ&facLeft.typ == IN {
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if facLeft.name == facRight.name {
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if facRight.invert != facLeft.invert {
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rightFactors[i] = factor{typ: CONST, negate: Xor(facRight.negate, facLeft.negate), multiplicative: mul2DVector(facRight.multiplicative, facLeft.multiplicative)}
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continue
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}
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}
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//rightFactors[i] = factor{typ: CONST, negate: Xor(facRight.negate, facLeft.negate), multiplicative: mul2DVector(facRight.multiplicative, facLeft.multiplicative)}
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//continue
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}
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fmt.Println("dsf")
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panic("unexpected")
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}
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}
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return rightFactors
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}
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//returns the absolute value of a signed int and a flag telling if the input was positive or not
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//this implementation is awesome and fast (see Henry S Warren, Hackers's Delight)
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func abs(n int) (val int, positive bool) {
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y := n >> 63
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return (n ^ y) - y, y == 0
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}
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//returns the reduced sum of two input factor arrays
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//if no reduction was done (worst case), it returns the concatenation of the input arrays
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func addFactors(leftFactors, rightFactors []factor) []factor {
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var found bool
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res := make([]factor, 0, len(leftFactors)+len(rightFactors))
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for _, facLeft := range leftFactors {
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found = false
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for i, facRight := range rightFactors {
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if facLeft.typ&facRight.typ == CONST {
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var a0, b0 = facLeft.multiplicative[0], facRight.multiplicative[0]
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if facLeft.negate {
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a0 *= -1
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}
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if facRight.negate {
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b0 *= -1
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}
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absValue, positive := abs(a0*facRight.multiplicative[1] + facLeft.multiplicative[1]*b0)
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rightFactors[i] = factor{typ: CONST, negate: !positive, multiplicative: [2]int{absValue, facLeft.multiplicative[1] * facRight.multiplicative[1]}}
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found = true
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//res = append(res, factor{typ: CONST, negate: negate, multiplicative: [2]int{absValue, facLeft.multiplicative[1] * facRight.multiplicative[1]}})
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break
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}
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if facLeft.typ&facRight.typ == IN && facLeft.invert == facRight.invert && facLeft.name == facRight.name {
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var a0, b0 = facLeft.multiplicative[0], facRight.multiplicative[0]
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if facLeft.negate {
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a0 *= -1
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}
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if facRight.negate {
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b0 *= -1
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}
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absValue, positive := abs(a0*facRight.multiplicative[1] + facLeft.multiplicative[1]*b0)
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rightFactors[i] = factor{typ: IN, invert: facRight.invert, name: facRight.name, negate: !positive, multiplicative: [2]int{absValue, facLeft.multiplicative[1] * facRight.multiplicative[1]}}
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found = true
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//res = append(res, factor{typ: CONST, negate: negate, multiplicative: [2]int{absValue, facLeft.multiplicative[1] * facRight.multiplicative[1]}})
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break
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}
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}
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if !found {
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res = append(res, facLeft)
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}
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}
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for _, val := range rightFactors {
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if val.multiplicative[0] != 0 {
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res = append(res, val)
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}
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}
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return res
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}
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func (p *Program) collectFactors(contextCircut *Circuit, node *gate, mGatesUsed map[string]bool, negate bool, invert bool) []factor {
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if node.OperationType() == CONST {
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b1, v1 := isValue(node.value.Out)
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if !b1 {
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panic("not a constant")
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}
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if invert {
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return []factor{{typ: CONST, negate: negate, multiplicative: [2]int{1, v1}}}
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}
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return []factor{{typ: CONST, negate: negate, multiplicative: [2]int{v1, 1}}}
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}
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if node.OperationType() == FUNC {
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nextContext := p.extendedFunctionRenamer(contextCircut, node.value)
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//if _, ex := mGatesUsed[nextContext.currentOutputName()]; ex {
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// return []factor{{typ: IN, name: nextContext.currentOutputName(), invert: invert, negate: negate, multiplicative: [2]int{1, 1}}}
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//}
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contextCircut = nextContext
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node = nextContext.root
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}
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originOfVariable := p.functions[getContextFromVariable(node.value.Out)]
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if originOfVariable == nil {
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fmt.Println("asdf")
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}
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lookingFOr := composeNewFunction(node.value.Out, originOfVariable.currentOutputs())
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//if _, ex := mGatesUsed[node.value.Out]; ex {
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// return []factor{{typ: IN, name: node.value.Out, invert: invert, negate: negate, multiplicative: [2]int{1, 1}}}
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//}
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if node.OperationType() == IN {
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return []factor{{typ: IN, name: lookingFOr, invert: invert, negate: negate, multiplicative: [2]int{1, 1}}}
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}
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if _, alreadyComputed := mGatesUsed[lookingFOr]; alreadyComputed {
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return []factor{{typ: IN, name: lookingFOr, invert: invert, negate: negate, multiplicative: [2]int{1, 1}}}
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}
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leftFactors := p.collectFactors(contextCircut, node.left, mGatesUsed, negate, invert)
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rightFactors := p.collectFactors(contextCircut, node.right, mGatesUsed, Xor(negate, node.value.negate), Xor(invert, node.value.invert))
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switch node.OperationType() {
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case MULTIPLY:
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return mulFactors(leftFactors, rightFactors)
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case PLUS:
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return addFactors(leftFactors, rightFactors)
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default:
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panic("unexpected gate")
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}
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}
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//copies a gate neglecting its references to other gates
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func cloneGate(in *gate) (out *gate) {
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constr := &Constraint{Inputs: in.value.Inputs, Out: in.value.Out, Op: in.value.Op, invert: in.value.invert, negate: in.value.negate, V2: in.value.V2, V1: in.value.V1}
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nRightins := make([]factor, len(in.rightIns))
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nLeftInst := make([]factor, len(in.leftIns))
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for k, v := range in.rightIns {
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nRightins[k] = v
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}
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for k, v := range in.leftIns {
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nLeftInst[k] = v
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}
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return &gate{value: constr, leftIns: nLeftInst, rightIns: nRightins, index: in.index}
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}
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func (p *Program) getMainCircuit() *Circuit {
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return p.functions["main"]
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}
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//func (p *Program) addGlobalInput(c Constraint) {
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// c.Out = "main@" + c.Out
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// p.globalInputs = append(p.globalInputs, c)
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//}
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func prepareUtils() utils {
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bn, err := bn128.NewBn128()
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if err != nil {
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panic(err)
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}
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// new Finite Field
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fqR := fields.NewFq(bn.R)
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// new Polynomial Field
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pf := r1csqap.NewPolynomialField(fqR)
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return utils{
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Bn: bn,
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FqR: fqR,
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PF: pf,
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}
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}
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func (p *Program) extendedFunctionRenamer(contextCircuit *Circuit, constraint *Constraint) (nextContext *Circuit) {
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if constraint.Op != FUNC {
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panic("not a function")
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}
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//if _, ex := contextCircuit.gateMap[constraint.Out]; !ex {
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// panic("constraint must be within the contextCircuit circuit")
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//}
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b, n, _ := isFunction(constraint.Out)
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if !b {
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panic("not expected")
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}
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if newContext, v := p.functions[n]; v {
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//am i certain that constraint.inputs is alwazs equal to n??? me dont like it
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for i, argument := range constraint.Inputs {
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isConst, _ := isValue(argument)
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if isConst {
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continue
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}
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isFunc, _, _ := isFunction(argument)
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if isFunc {
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panic("functions as arguments no supported yet")
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//p.extendedFunctionRenamer(contextCircuit,)
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}
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//at this point I assert that argument is a variable. This can become troublesome later
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//first we get the circuit in which the argument was created
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inputOriginCircuit := p.functions[getContextFromVariable(argument)]
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|
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//we pick the gate that has the argument as output
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if gate, ex := inputOriginCircuit.gateMap[argument]; ex {
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//we pick the old circuit inputs and let them now reference the same as the argument gate did,
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oldGate := newContext.gateMap[newContext.Inputs[i]]
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//we take the old gate which was nothing but a input
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//and link this input to its constituents coming from the calling contextCircuit.
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//i think this is pretty neat
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oldGate.value = gate.value
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oldGate.right = gate.right
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oldGate.left = gate.left
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} else {
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panic("not expected")
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}
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}
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//newContext.renameInputs(constraint.Inputs)
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return newContext
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}
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|
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return nil
|
|
}
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|
|
func NewProgram() (p *Program) {
|
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p = &Program{functions: map[string]*Circuit{}, globalInputs: []string{"one"}, arithmeticEnvironment: prepareUtils()}
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return
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}
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|
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// GenerateR1CS generates the R1CS polynomials from the Circuit
|
|
func (p *Program) GenerateReducedR1CS(mGates []gate) (a, b, c [][]*big.Int) {
|
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// from flat code to R1CS
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|
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offset := len(p.globalInputs)
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// one + in1 +in2+... + gate1 + gate2 .. + out
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size := offset + len(mGates)
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indexMap := make(map[string]int)
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|
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for i, v := range p.globalInputs {
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indexMap[v] = i
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|
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}
|
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for i, v := range mGates {
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indexMap[v.value.Out] = i + offset
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}
|
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|
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for _, gate := range mGates {
|
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|
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if gate.OperationType() == MULTIPLY {
|
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aConstraint := r1csqap.ArrayOfBigZeros(size)
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bConstraint := r1csqap.ArrayOfBigZeros(size)
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|
cConstraint := r1csqap.ArrayOfBigZeros(size)
|
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|
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for _, val := range gate.leftIns {
|
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if val.typ != CONST {
|
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if _, ex := indexMap[val.name]; !ex {
|
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panic(fmt.Sprintf("%v index not found!!!", val.name))
|
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}
|
|
}
|
|
convertAndInsertFactorAt(aConstraint, val, indexMap[val.name])
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}
|
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|
|
for _, val := range gate.rightIns {
|
|
if val.typ != CONST {
|
|
if _, ex := indexMap[val.name]; !ex {
|
|
panic(fmt.Sprintf("%v index not found!!!", val.name))
|
|
}
|
|
}
|
|
|
|
convertAndInsertFactorAt(bConstraint, val, indexMap[val.name])
|
|
}
|
|
|
|
cConstraint[indexMap[gate.value.Out]] = big.NewInt(int64(1))
|
|
|
|
if gate.value.invert {
|
|
tmp := aConstraint
|
|
aConstraint = cConstraint
|
|
cConstraint = tmp
|
|
}
|
|
a = append(a, aConstraint)
|
|
b = append(b, bConstraint)
|
|
c = append(c, cConstraint)
|
|
|
|
} else {
|
|
panic("not a m gate")
|
|
}
|
|
}
|
|
p.R1CS.A = a
|
|
p.R1CS.B = b
|
|
p.R1CS.C = c
|
|
return a, b, c
|
|
}
|
|
|
|
var Utils = prepareUtils()
|
|
|
|
func fractionToField(in [2]int) *big.Int {
|
|
return Utils.FqR.Mul(big.NewInt(int64(in[0])), Utils.FqR.Inverse(big.NewInt(int64(in[1]))))
|
|
|
|
}
|
|
|
|
func convertAndInsertFactorAt(arr []*big.Int, val factor, index int) {
|
|
value := new(big.Int).Add(new(big.Int), fractionToField(val.multiplicative))
|
|
|
|
if val.negate {
|
|
value.Neg(value)
|
|
}
|
|
|
|
//not that index is 0 if its a constant, since 0 is the map default if no entry was found
|
|
arr[index] = value
|
|
|
|
}
|
|
|
|
func (p *Program) CalculateWitness(input []*big.Int) (witness []*big.Int) {
|
|
|
|
if len(p.globalInputs)-1 != len(input) {
|
|
panic("input do not match the required inputs")
|
|
}
|
|
|
|
witness = r1csqap.ArrayOfBigZeros(len(p.R1CS.A[0]))
|
|
set := make([]bool, len(witness))
|
|
witness[0] = big.NewInt(int64(1))
|
|
set[0] = true
|
|
|
|
for i := range input {
|
|
witness[i+1] = input[i]
|
|
set[i+1] = true
|
|
}
|
|
|
|
zero := big.NewInt(int64(0))
|
|
|
|
for i := 0; i < len(p.R1CS.A); i++ {
|
|
gatesLeftInputs := p.R1CS.A[i]
|
|
gatesRightInputs := p.R1CS.B[i]
|
|
gatesOutputs := p.R1CS.C[i]
|
|
|
|
sumLeft := big.NewInt(int64(0))
|
|
sumRight := big.NewInt(int64(0))
|
|
sumOut := big.NewInt(int64(0))
|
|
|
|
index := -1
|
|
division := false
|
|
for j, val := range gatesLeftInputs {
|
|
if val.Cmp(zero) != 0 {
|
|
if !set[j] {
|
|
index = j
|
|
division = true
|
|
break
|
|
}
|
|
sumLeft.Add(sumLeft, new(big.Int).Mul(val, witness[j]))
|
|
}
|
|
}
|
|
for j, val := range gatesRightInputs {
|
|
if val.Cmp(zero) != 0 {
|
|
sumRight.Add(sumRight, new(big.Int).Mul(val, witness[j]))
|
|
}
|
|
}
|
|
|
|
for j, val := range gatesOutputs {
|
|
if val.Cmp(zero) != 0 {
|
|
if !set[j] {
|
|
if index != -1 {
|
|
panic("invalid R1CS form")
|
|
}
|
|
|
|
index = j
|
|
break
|
|
}
|
|
sumOut.Add(sumOut, new(big.Int).Mul(val, witness[j]))
|
|
}
|
|
}
|
|
|
|
if !division {
|
|
set[index] = true
|
|
witness[index] = new(big.Int).Mul(sumLeft, sumRight)
|
|
|
|
} else {
|
|
b := sumRight.Int64()
|
|
c := sumOut.Int64()
|
|
set[index] = true
|
|
witness[index] = big.NewInt(c / b)
|
|
}
|
|
|
|
}
|
|
|
|
return
|
|
}
|