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include "./range_check.pil"; | ||
// This module handles comparisons (equality and GT) | ||
// GT also enables us to support LT (by swapping the inputs of GT) and LTE (by inverting the result of GT) | ||
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// TODO: See if we can make this faster for non-FF GT ops | ||
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namespace cmp(256); | ||
pol commit clk; | ||
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// ========= Initialize Range Check Gadget =============================== | ||
// We need this as a unique key to the range check gadget | ||
pol commit range_chk_clk; | ||
op_gt * (range_chk_clk - (clk * 2**8 + cmp_rng_ctr)) = 0; | ||
// These are the i/o for the gadget | ||
pol commit input_a; | ||
pol commit input_b; | ||
pol commit result; | ||
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// We range check two columns per row of the cmp gadget, the lo and hi bit ranges resp. | ||
#[PERM_RNG_CMP_LO] | ||
range_check.cmp_lo_bits_rng_chk {range_check.clk, range_check.value} | ||
is | ||
sel_rng_chk {range_chk_clk, a_lo}; | ||
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#[PERM_RNG_CMP_HI] | ||
range_check.cmp_hi_bits_rng_chk {range_check.clk, range_check.value} | ||
is | ||
sel_rng_chk {range_chk_clk, a_hi}; | ||
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// These are the selectors that will be useful | ||
pol commit sel_cmp; | ||
pol commit op_eq; | ||
pol commit op_gt; | ||
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sel_cmp = op_eq + op_gt; | ||
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// There are some standardised constraints on this gadget | ||
// The result is always a boolean | ||
#[CMP_RES_IS_BOOL] | ||
(op_eq + op_gt) * (result * (1 - result)) = 0; | ||
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// ========= EQUALITY Operation Constraints =============================== | ||
// TODO: Note this method differs from the approach taken for "equality to zero" checks | ||
// in handling the error tags found in main and mem files. The predicted relation difference | ||
// is minor and when we optimise we will harmonise the methods based on actual performance. | ||
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// Equality of two elements is found by performing an "equality to zero" check. | ||
// This relies on the fact that the inverse of a field element exists for all elements except zero | ||
// 1) Given two values x & y, find the difference z = x - y | ||
// 2) If x & y are equal, z == 0 otherwise z != 0 | ||
// 3) Field equality to zero can be done as follows | ||
// a) z(e(x - w) + w) - 1 + e = 0; | ||
// b) where w = z^-1 and e is a boolean value indicating if z == 0 | ||
// c) if e == 0; zw = 1 && z has an inverse. If e == 1; z == 0 and we set w = 0; | ||
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// Registers input_a and input_b hold the values that equality is to be tested on | ||
pol DIFF = input_a - input_b; | ||
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// Need an additional helper that holds the inverse of the difference; | ||
pol commit op_eq_diff_inv; | ||
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#[CMP_OP_EQ] | ||
op_eq * (DIFF * (result * (1 - op_eq_diff_inv) + op_eq_diff_inv) - 1 + result) = 0; | ||
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// ========= LT/LTE Operation Constraints =============================== | ||
// There are two routines that we utilise as part of this LT/LTE check | ||
// (1) Decomposition into two 128-bit limbs, lo and hi respectively and a borrow (1 or 0); | ||
// (2) 128 bit-range checks when checking an arithmetic operation has not overflowed the field. | ||
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// ========= COMPARISON OPERATION - EXPLANATIONS ================================================= | ||
// To simplify the comparison circuit, we implement a GreaterThan(GT) circuit. This is ideal since | ||
// if we need a LT operation, we just swap the inputs and if we need the LTE operation, we just NOT the GT constraint | ||
// Given the inputs x, y and q where x & y are integers in the range [0,...,p-1] and q is the boolean result to the query (x > y). | ||
// Then there are two scenarios: | ||
// (1) (x > y) -> x - y - 1 = result, where 0 <= result. i.e. the result does not underflow the field. | ||
// (2)!(x > y) -> (x <= y) = y - x = result, where the same applies as above. | ||
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// Check the result of input_a > input_b; | ||
pol POW_128 = 2 ** 128; | ||
pol P_LO = 53438638232309528389504892708671455232; // Lower 128 bits of (p - 1) | ||
pol P_HI = 64323764613183177041862057485226039389; // Upper 128 bits of (p - 1) | ||
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pol commit borrow; | ||
pol commit a_lo; | ||
pol commit a_hi; | ||
#[INPUT_DECOMP_1] | ||
op_gt * ( input_a - (a_lo + POW_128 * a_hi)) = 0; | ||
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pol commit b_lo; | ||
pol commit b_hi; | ||
#[INPUT_DECOMP_2] | ||
op_gt * ( input_b - (b_lo + POW_128 * b_hi)) = 0; | ||
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pol commit p_sub_a_lo; // p_lo - a_lo | ||
pol commit p_sub_a_hi; // p_hi - a_hi | ||
pol commit p_a_borrow; | ||
p_a_borrow * (1 - p_a_borrow) = 0; | ||
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// Check that decomposition of a into lo and hi limbs do not overflow p. | ||
// This is achieved by checking a does not underflow p: (p_lo > a_lo && p_hi >= ahi) || (p_lo <= a_lo && p_hi > a_hi) | ||
// First condition is if borrow = 0, second condition is if borrow = 1 | ||
// This underflow check is done by the 128-bit check that is performed on each of these lo and hi limbs. | ||
#[SUB_LO_1] | ||
op_gt * (p_sub_a_lo - (P_LO - a_lo + p_a_borrow * POW_128)) = 0; | ||
#[SUB_HI_1] | ||
op_gt * (p_sub_a_hi - (P_HI - a_hi - p_a_borrow)) = 0; | ||
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pol commit p_sub_b_lo; | ||
pol commit p_sub_b_hi; | ||
pol commit p_b_borrow; | ||
p_b_borrow * (1 - p_b_borrow) = 0; | ||
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// Check that decomposition of b into lo and hi limbs do not overflow/underflow p. | ||
// This is achieved by checking (p_lo > b_lo && p_hi >= bhi) || (p_lo <= b_lo && p_hi > b_hi) | ||
// First condition is if borrow = 0, second condition is if borrow = 1; | ||
#[SUB_LO_2] | ||
op_gt * (p_sub_b_lo - (P_LO - b_lo + p_b_borrow * POW_128)) = 0; | ||
#[SUB_HI_2] | ||
op_gt * (p_sub_b_hi - (P_HI - b_hi - p_b_borrow)) = 0; | ||
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// Calculate the combined relation: (a - b - 1) * q + (b -a ) * (1-q) | ||
// Check that (a > b) by checking (a_lo > b_lo && a_hi >= bhi) || (alo <= b_lo && a_hi > b_hi) | ||
// First condition is if borrow = 0, second condition is if borrow = 1; | ||
pol A_SUB_B_LO = a_lo - b_lo - 1 + borrow * POW_128; | ||
pol A_SUB_B_HI = a_hi - b_hi - borrow; | ||
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// Check that (a <= b) by checking (b_lo >= a_lo && b_hi >= a_hi) || (b_lo < a_lo && b_hi > a_hi) | ||
// First condition is if borrow = 0, second condition is if borrow = 1; | ||
pol B_SUB_A_LO = b_lo - a_lo + borrow * POW_128; | ||
pol B_SUB_A_HI = b_hi - a_hi - borrow; | ||
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pol IS_GT = op_gt * result; | ||
// When IS_GT = 1, we enforce the condition that a > b and thus a - b - 1 does not underflow. | ||
// When IS_GT = 0, we enforce the condition that a <= b and thus b - a does not underflow. | ||
// ========= Analysing res_lo and res_hi scenarios for LTE ================================= | ||
// (1) Assume a proof satisfies the constraints for LTE(x,y,1), i.e., x <= y | ||
// Therefore ia = x, ib = y and ic = 1. | ||
// (a) We do not swap the operands, so a = x and b = y, | ||
// (b) IS_GT = 1 - ic = 0 | ||
// (c) res_lo = B_SUB_A_LO and res_hi = B_SUB_A_HI | ||
// (d) res_lo = y_lo - x_lo + borrow * 2**128 and res_hi = y_hi - x_hi - borrow. | ||
// (e) Due to 128-bit range checks on res_lo, res_hi, y_lo, x_lo, y_hi, x_hi, we | ||
// have the guarantee that res_lo >= 0 && res_hi >= 0. Furthermore, borrow is | ||
// boolean and so we have two cases to consider: | ||
// (i) borrow == 0 ==> y_lo >= x_lo && y_hi >= x_hi | ||
// (ii) borrow == 1 ==> y_hi >= x_hi + 1 ==> y_hi > x_hi | ||
// This concludes the proof as for both cases, we must have: y >= x | ||
// | ||
// (2) Assume a proof satisfies the constraints for LTE(x,y,0), i.e. x > y. | ||
// Therefore ia = x, ib = y and ic = 0. | ||
// (a) We do not swap the operands, so a = x and b = y, | ||
// (b) IS_GT = 1 - ic = 1 | ||
// (c) res_lo = A_SUB_B_LO and res_hi = A_SUB_B_HI | ||
// (d) res_lo = x_lo - y_lo - 1 + borrow * 2**128 and res_hi = x_hi - y_hi - borrow. | ||
// (e) Due to 128-bit range checks on res_lo, res_hi, y_lo, x_lo, y_hi, x_hi, we | ||
// have the guarantee that res_lo >= 0 && res_hi >= 0. Furthermore, borrow is | ||
// boolean and so we have two cases to consider: | ||
// (i) borrow == 0 ==> x_lo > y_lo && x_hi >= y_hi | ||
// (ii) borrow == 1 ==> x_hi > y_hi | ||
// This concludes the proof as for both cases, we must have: x > y | ||
// | ||
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// ========= Analysing res_lo and res_hi scenarios for LT ================================== | ||
// (1) Assume a proof satisfies the constraints for LT(x,y,1), i.e. x < y. | ||
// Therefore ia = x, ib = y and ic = 1. | ||
// (a) We DO swap the operands, so a = y and b = x, | ||
// (b) IS_GT = ic = 1 | ||
// (c) res_lo = A_SUB_B_LO and res_hi = A_SUB_B_HI, **remember we have swapped inputs** | ||
// (d) res_lo = y_lo - x_lo - 1 + borrow * 2**128 and res_hi = y_hi - x_hi - borrow. | ||
// (e) Due to 128-bit range checks on res_lo, res_hi, y_lo, x_lo, y_hi, x_hi, we | ||
// have the guarantee that res_lo >= 0 && res_hi >= 0. Furthermore, borrow is | ||
// boolean and so we have two cases to consider: | ||
// (i) borrow == 0 ==> y_lo > x_lo && y_hi >= x_hi | ||
// (ii) borrow == 1 ==> y_hi > x_hi | ||
// This concludes the proof as for both cases, we must have: x < y | ||
// | ||
// (2) Assume a proof satisfies the constraint for LT(x,y,0), i.e. x >= y. | ||
// Therefore ia = x, ib = y and ic = 0. | ||
// (a) We DO swap the operands, so a = y and b = x, | ||
// (b) IS_GT = ic = 0 | ||
// (c) res_lo = B_SUB_A_LO and res_hi = B_SUB_A_HI, **remember we have swapped inputs** | ||
// (d) res_lo = a_lo - y_lo + borrow * 2**128 and res_hi = a_hi - y_hi - borrow. | ||
// (e) Due to 128-bit range checks on res_lo, res_hi, y_lo, x_lo, y_hi, x_hi, we | ||
// have the guarantee that res_lo >= 0 && res_hi >= 0. Furthermore, borrow is | ||
// boolean and so we have two cases to consider: | ||
// (i) borrow == 0 ==> x_lo >= y_lo && x_hi >= y_hi | ||
// (ii) borrow == 1 ==> x_hi > y_hi | ||
// This concludes the proof as for both cases, we must have: x >= y | ||
pol commit res_lo; | ||
pol commit res_hi; | ||
#[RES_LO] | ||
op_gt * (res_lo - (A_SUB_B_LO * IS_GT + B_SUB_A_LO * (1 - IS_GT))) = 0; | ||
#[RES_HI] | ||
op_gt * (res_hi - (A_SUB_B_HI * IS_GT + B_SUB_A_HI * (1 - IS_GT))) = 0; | ||
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// ========= RANGE OPERATIONS =============================== | ||
// We need to dispatch to the range check gadget | ||
pol commit sel_rng_chk; | ||
sel_rng_chk * (1 - sel_rng_chk) = 0; | ||
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// Each call to LT/LTE requires 5x 256-bit range checks. We keep track of how many are left here. | ||
pol commit cmp_rng_ctr; | ||
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// the number of range checks must decrement by 1 until it is equal to 0; | ||
#[CMP_CTR_REL_1] | ||
(cmp_rng_ctr' - cmp_rng_ctr + 1) * cmp_rng_ctr = 0; | ||
// if this row is a comparison operation, the next range_check_remaining value is set to 5 | ||
#[CMP_CTR_REL_2] | ||
op_gt * (cmp_rng_ctr - 5) = 0; | ||
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// sel_rng_chk = 1 when cmp_rng_ctr != 0 and sel_rng_chk = 0 when cmp_rng_ctr = 0; | ||
#[CTR_NON_ZERO_REL] | ||
cmp_rng_ctr * ((1 - sel_rng_chk) * (1 - op_eq_diff_inv) + op_eq_diff_inv) - sel_rng_chk = 0; | ||
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// Shift all elements "across" by 2 columns | ||
// TODO: there is an optimisation where we are able to do 1 less range check as the range check on | ||
// P_SUB_B is implied by the other range checks. | ||
// Briefly: given a > b and p > a and p > a - b - 1, it is sufficient confirm that p > b without a range check | ||
// To accomplish this we would likely change the order of the range_check so we can skip p_sub_b | ||
#[SHIFT_RELS_0] | ||
(a_lo' - b_lo) * (op_gt' - sel_rng_chk') = 0; | ||
(a_hi' - b_hi) * (op_gt' - sel_rng_chk') = 0; | ||
#[SHIFT_RELS_1] | ||
(b_lo' - p_sub_a_lo) * (op_gt' - sel_rng_chk') = 0; | ||
(b_hi' - p_sub_a_hi) * (op_gt' - sel_rng_chk') = 0; | ||
#[SHIFT_RELS_2] | ||
(p_sub_a_lo' - p_sub_b_lo) * (op_gt' - sel_rng_chk') = 0; | ||
(p_sub_a_hi' - p_sub_b_hi) * (op_gt' - sel_rng_chk') = 0; | ||
#[SHIFT_RELS_3] | ||
(p_sub_b_lo' - res_lo) * (op_gt' - sel_rng_chk') = 0; | ||
(p_sub_b_hi' - res_hi) * (op_gt' - sel_rng_chk') = 0; | ||
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