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Merge pull request #1622 from bMacSwigg/sandbox
Spec & proof for add_precomputed
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Require Import bedrock2.Array. | ||
Require Import bedrock2.FE310CSemantics. | ||
Require Import bedrock2.Loops. | ||
Require Import bedrock2.Map.Separation. | ||
Require Import bedrock2.Map.SeparationLogic. | ||
Require Import bedrock2.NotationsCustomEntry. | ||
Require Import bedrock2.ProgramLogic. | ||
Require Import bedrock2.Scalars. | ||
Require Import bedrock2.Semantics. | ||
Require Import bedrock2.Syntax. | ||
Require Import bedrock2.WeakestPrecondition. | ||
Require Import bedrock2.WeakestPreconditionProperties. | ||
Require Import bedrock2.ZnWords. | ||
Require Import compiler.MMIO. | ||
Require Import compiler.Pipeline. | ||
Require Import compiler.Symbols. | ||
Require Import coqutil.Byte. | ||
Require Import coqutil.Map.Interface. | ||
Require Import coqutil.Map.OfListWord. | ||
From coqutil.Tactics Require Import Tactics letexists eabstract rdelta reference_to_string ident_of_string. | ||
Require Import coqutil.Word.Bitwidth32. | ||
Require Import coqutil.Word.Bitwidth. | ||
Require Import coqutil.Word.Interface. | ||
Require Import Coq.Init.Byte. | ||
Require Import Coq.Lists.List. | ||
Require Import Coq.Strings.String. | ||
Require Import Coq.ZArith.ZArith. | ||
Require Import Crypto.Arithmetic.PrimeFieldTheorems. | ||
Require Import Crypto.Bedrock.Field.Interface.Compilation2. | ||
Require Import Crypto.Bedrock.Field.Synthesis.New.UnsaturatedSolinas. | ||
Require Import Crypto.Bedrock.Group.AdditionChains. | ||
Require Import Crypto.Bedrock.Group.ScalarMult.CSwap. | ||
Require Import Crypto.Bedrock.Group.ScalarMult.LadderStep. | ||
Require Import Crypto.Bedrock.Group.ScalarMult.MontgomeryLadder. | ||
Require Import Crypto.Bedrock.End2End.X25519.Field25519. | ||
Require Import Crypto.Bedrock.Specs.Field. | ||
Require Import Crypto.Spec.Curve25519. | ||
Require Import Curves.Edwards.XYZT.Precomputed. | ||
Require Import Lia. | ||
Require Crypto.Bedrock.Field.Synthesis.New.Signature. | ||
Local Open Scope string_scope. | ||
Local Open Scope Z_scope. | ||
Import LittleEndianList. | ||
Import ListNotations. | ||
Import ProgramLogic.Coercions. | ||
Import WeakestPrecondition. | ||
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Local Existing Instance field_parameters. | ||
Local Instance frep25519 : Field.FieldRepresentation := field_representation n Field25519.s c. | ||
Local Existing Instance frep25519_ok. | ||
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Definition add_precomputed := func! (ox, oy, oz, ot, X1, Y1, Z1, T1, ypx2, ymx2, xy2d2) { | ||
stackalloc 40 as YpX1; | ||
fe25519_add(YpX1, Y1, X1); | ||
stackalloc 40 as YmX1; | ||
fe25519_sub(YmX1, Y1, X1); | ||
stackalloc 40 as A; | ||
fe25519_mul(A, YpX1, ypx2); | ||
stackalloc 40 as B; | ||
fe25519_mul(B, YmX1, ymx2); | ||
stackalloc 40 as C; | ||
fe25519_mul(C, xy2d2, T1); | ||
stackalloc 40 as Two; | ||
fe25519_from_word(Two, $2); | ||
stackalloc 40 as D; | ||
fe25519_mul(D, Z1, Two); (* TODO: Should be Z1 + Z1, but mul has tighter bounds *) | ||
fe25519_sub(ox, A, B); | ||
fe25519_add(oy, A, B); | ||
fe25519_add(oz, D, C); | ||
fe25519_sub(ot, D, C); | ||
fe25519_mul(ox, ox, ot); | ||
fe25519_mul(oy, oy, oz); | ||
fe25519_mul(oz, ot, oz); | ||
fe25519_mul(ot, ox, oy) | ||
}. | ||
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Section WithParameters. | ||
Context {two_lt_M: 2 < M_pos}. | ||
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Local Coercion F.to_Z : F >-> Z. | ||
Local Notation "m =* P" := ((P%sep) m) (at level 70, only parsing). | ||
Local Notation "xs $@ a" := (Array.array ptsto (word.of_Z 1) a xs) (at level 10, format "xs $@ a"). | ||
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Local Notation FElem := (FElem(FieldRepresentation:=frep25519)). | ||
Local Notation bounded_by := (bounded_by(FieldRepresentation:=frep25519)). | ||
Local Notation word := (Naive.word 32). | ||
Local Notation felem := (felem(FieldRepresentation:=frep25519)). | ||
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Global Instance spec_of_add_precomputed : spec_of "add_precomputed" := | ||
fnspec! "add_precomputed" | ||
(oxK oyK ozK otK X1K Y1K Z1K T1K ypx2K ymx2K xy2d2K : word) / | ||
(ox oy oz ot X1 Y1 Z1 T1 ypx2 ymx2 xy2d2 : felem) (R : _ -> Prop), | ||
{ requires t m := | ||
bounded_by tight_bounds X1 /\ | ||
bounded_by tight_bounds Y1 /\ | ||
bounded_by loose_bounds Z1 /\ | ||
bounded_by loose_bounds T1 /\ | ||
bounded_by loose_bounds ypx2 /\ | ||
bounded_by loose_bounds ymx2 /\ | ||
bounded_by loose_bounds xy2d2 /\ | ||
m =* (FElem X1K X1) * (FElem Y1K Y1) * (FElem Z1K Z1) * (FElem T1K T1) * (FElem ypx2K ypx2) * (FElem ymx2K ymx2) * (FElem xy2d2K xy2d2) * (FElem oxK ox) * (FElem oyK oy) * (FElem ozK oz) * (FElem otK ot) * R; | ||
ensures t' m' := | ||
t = t' /\ | ||
exists ox' oy' oz' ot', | ||
((feval ox'), (feval oy'), (feval oz'), (feval ot')) = (@m1add_precomputed_coordinates (F M_pos) (F.add) (F.sub) (F.mul) ((feval X1), (feval Y1), (feval Z1), (feval T1)) ((feval ypx2), (feval ymx2), (feval xy2d2))) /\ | ||
bounded_by loose_bounds ox' /\ | ||
bounded_by loose_bounds oy' /\ | ||
bounded_by loose_bounds oz' /\ | ||
bounded_by loose_bounds ot' /\ | ||
m' =* (FElem X1K X1) * (FElem Y1K Y1) * (FElem Z1K Z1) * (FElem T1K T1) * (FElem ypx2K ypx2) * (FElem ymx2K ymx2) * (FElem xy2d2K xy2d2) * (FElem oxK ox') * (FElem oyK oy') * (FElem ozK oz') * (FElem otK ot') * R }. | ||
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Local Instance spec_of_fe25519_square : spec_of "fe25519_square" := Field.spec_of_UnOp un_square. | ||
Local Instance spec_of_fe25519_mul : spec_of "fe25519_mul" := Field.spec_of_BinOp bin_mul. | ||
Local Instance spec_of_fe25519_add : spec_of "fe25519_add" := Field.spec_of_BinOp bin_add. | ||
Local Instance spec_of_fe25519_sub : spec_of "fe25519_sub" := Field.spec_of_BinOp bin_sub. | ||
Local Instance spec_of_fe25519_from_word : spec_of "fe25519_from_word" := Field.spec_of_from_word. | ||
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Local Arguments word.rep : simpl never. | ||
Local Arguments word.wrap : simpl never. | ||
Local Arguments word.unsigned : simpl never. | ||
Local Arguments word.of_Z : simpl never. | ||
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Local Ltac cbv_bounds H := | ||
cbv [un_xbounds bin_xbounds bin_ybounds un_square bin_mul bin_add bin_sub un_outbounds bin_outbounds] in H; | ||
cbv [un_xbounds bin_xbounds bin_ybounds un_square bin_mul bin_add bin_sub un_outbounds bin_outbounds]. | ||
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Local Ltac solve_bounds := | ||
repeat match goal with | ||
| H: bounded_by loose_bounds ?x |- bounded_by loose_bounds ?x => apply H | ||
| H: bounded_by tight_bounds ?x |- bounded_by tight_bounds ?x => apply H | ||
| H: bounded_by tight_bounds ?x |- bounded_by loose_bounds ?x => apply relax_bounds | ||
| H: bounded_by _ ?x |- bounded_by _ ?x => cbv_bounds H | ||
end. | ||
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Local Ltac solve_mem := | ||
repeat match goal with | ||
| |- exists _ : _ -> Prop, _%sep _ => eexists | ||
| |- _%sep _ => ecancel_assumption | ||
end. | ||
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Local Ltac solve_stack := | ||
(* Rewrites the `stack$@a` term in H to use a Bignum instead *) | ||
cbv [FElem]; | ||
match goal with | ||
| H: _%sep ?m |- (Bignum.Bignum felem_size_in_words ?a _ * _)%sep ?m => | ||
seprewrite_in (@Bignum.Bignum_of_bytes _ _ _ _ _ _ 10 a) H | ||
end; | ||
[> transitivity 40%nat; trivial | ]; | ||
(* proves the memory matches up *) | ||
use_sep_assumption; cancel; cancel_seps_at_indices 0%nat 0%nat; cbn; [> trivial | eapply RelationClasses.reflexivity]. | ||
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Local Ltac single_step := | ||
repeat straightline; straightline_call; ssplit; try solve_mem; try solve_bounds; try solve_stack. | ||
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(* An example that demonstrates why we need to set Strategy in add_precomputed_ok below *) | ||
Example demo_strategy : forall x, | ||
(@Field.bounded_by field_parameters (Zpos (xO (xO (xO (xO (xO xH)))))) | ||
BW32 (Naive.word (Zpos (xO (xO (xO (xO (xO xH))))))) | ||
(@SortedListWord.map (Zpos (xO (xO (xO (xO (xO xH)))))) | ||
(Naive.word (Zpos (xO (xO (xO (xO (xO xH))))))) Naive.word32_ok | ||
byte) frep25519 | ||
(@loose_bounds field_parameters (Zpos (xO (xO (xO (xO (xO xH)))))) | ||
BW32 (Naive.word (Zpos (xO (xO (xO (xO (xO xH))))))) | ||
(@SortedListWord.map (Zpos (xO (xO (xO (xO (xO xH)))))) | ||
(Naive.word (Zpos (xO (xO (xO (xO (xO xH))))))) Naive.word32_ok | ||
byte) frep25519) x = | ||
@Field.bounded_by field_parameters (Zpos (xO (xO (xO (xO (xO xH)))))) | ||
BW32 (Naive.word (Zpos (xO (xO (xO (xO (xO xH))))))) | ||
(@SortedListWord.map (Zpos (xO (xO (xO (xO (xO xH)))))) | ||
(Naive.word (Zpos (xO (xO (xO (xO (xO xH))))))) Naive.word32_ok | ||
byte) frep25519 | ||
(@bin_outbounds (Zpos (xO (xO (xO (xO (xO xH)))))) BW32 | ||
(Naive.word (Zpos (xO (xO (xO (xO (xO xH))))))) | ||
(@SortedListWord.map (Zpos (xO (xO (xO (xO (xO xH)))))) | ||
(Naive.word (Zpos (xO (xO (xO (xO (xO xH))))))) Naive.word32_ok | ||
byte) field_parameters frep25519 (@add field_parameters) | ||
(@bin_add (Zpos (xO (xO (xO (xO (xO xH)))))) BW32 | ||
(Naive.word (Zpos (xO (xO (xO (xO (xO xH))))))) | ||
(@SortedListWord.map (Zpos (xO (xO (xO (xO (xO xH)))))) | ||
(Naive.word (Zpos (xO (xO (xO (xO (xO xH))))))) | ||
Naive.word32_ok byte) field_parameters frep25519)) x). | ||
Proof. | ||
(* reflexivity. *) (* Does not complete within 1 minute. *) | ||
(* Now set Strategy precedence... *) | ||
Strategy -1000 [bin_outbounds bin_add]. | ||
reflexivity. (* ...and completes immediately *) | ||
Qed. | ||
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Lemma add_precomputed_ok : program_logic_goal_for_function! add_precomputed. | ||
Proof. | ||
(* Without this, resolution of cbv stalls out Qed. *) | ||
Strategy -1000 [un_xbounds bin_xbounds bin_ybounds un_square bin_mul bin_add bin_sub un_outbounds bin_outbounds]. | ||
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(* Unwrap each call in the program. *) | ||
(* Each binop produces 2 memory goals on the inputs, 2 bounds goals on the inputs, and 1 memory goal on the output. *) | ||
single_step. (* fe25519_add(YpX1, Y1, X1) *) | ||
single_step. (* fe25519_sub(YmX1, Y1, X1) *) | ||
single_step. (* fe25519_mul(A, YpX1, ypx2) *) | ||
single_step. (* fe25519_mul(B, YmX1, ymx2) *) | ||
single_step. (* fe25519_mul(C, xy2d2, T1) *) | ||
single_step. (* fe25519_from_word(Two, $2) *) | ||
single_step. (* fe25519_mul(D, Z1, Two) *) | ||
single_step. (* fe25519_sub(ox, A, B) *) | ||
single_step. (* fe25519_add(oy, A, B) *) | ||
single_step. (* fe25519_add(oz, D, C) *) | ||
single_step. (* fe25519_sub(ot, D, C) *) | ||
single_step. (* fe25519_mul(ox, ox, ot) *) | ||
single_step. (* fe25519_mul(oy, oy, oz) *) | ||
single_step. (* fe25519_mul(oz, ot, oz) *) | ||
single_step. (* fe25519_mul(ot, ox, oy) *) | ||
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(* Solve the postconditions *) | ||
repeat straightline. | ||
(* Rewrites the FElems for the stack (in H96) to be about bytes instead *) | ||
cbv [FElem] in *. | ||
(* Prevent output from being rewritten by seprewrite_in *) | ||
remember (Bignum.Bignum felem_size_in_words otK _) as Pt in H96. | ||
remember (Bignum.Bignum felem_size_in_words ozK _) as Pz in H96. | ||
remember (Bignum.Bignum felem_size_in_words oyK _) as Py in H96. | ||
remember (Bignum.Bignum felem_size_in_words oxK _) as Px in H96. | ||
do 7 (seprewrite_in @Bignum.Bignum_to_bytes H96). | ||
subst Pt Pz Py Px. | ||
extract_ex1_and_emp_in H96. | ||
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(* Solve stack/memory stuff *) | ||
repeat straightline. | ||
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(* Post-conditions *) | ||
exists x10,x11,x12,x13; ssplit. 2,3,4,5:solve_bounds. | ||
{ (* Correctness: result matches Gallina *) | ||
cbv [bin_model bin_mul bin_add bin_sub] in *. | ||
cbv match beta delta [m1add_precomputed_coordinates]. | ||
assert ((feval Z1 * F.of_Z M_pos (word.of_Z(width:=32) 2))%F = (feval Z1 + feval Z1)%F) as <-. | ||
{ rewrite word.unsigned_of_Z_nowrap by lia. apply F.eq_to_Z_iff. rewrite F.to_Z_mul. rewrite F.to_Z_add. | ||
rewrite F.to_Z_of_Z. f_equal. rewrite Z.mod_small. all:lia. } | ||
congruence. | ||
} | ||
(* Safety: memory is what it should be *) | ||
ecancel_assumption. | ||
Qed. | ||
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End WithParameters. |
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