Nuprl Lemma : hdf-compose2-transformation2

∀[L1,L2,G1,G2,init,S:Top]. ∀[m1,m2:ℕ].
  (fix((λmk-hdf.(inl (λa.cbva_seq(L1[a]; λg.<mk-hdf, G1[g]>; m1)))))
   o (fix((λmk-hdf,s. (inl (λa.cbva_seq(L2[s;a]; λg.<mk-hdf S[g;s], G2[g;s]>; m2))))) init)
  ~ fix((λmk-hdf,s. (inl (λa.cbva_seq(λn.if n <z m1 then L1[a] n

                                         if n <z m1 + m2 then mk_lambdas(L2[s;a] (n - m1);m1)

                                         else mk_lambdas_fun(λg1.mk_lambdas_fun(λg2.⋃f∈G1[g1].⋃b∈G2[g2;s].f b;m2);m1)

                                         fi ; λg.<mk-hdf S[partial_ap_gen(g;(m1 + m2) + 1;m1;m2);s]

                                                 , select_fun_last(g;m1 + m2)

                                                 >; (m1 + m2) + 1)))))

init)

Proof

Definitions occuring in Statement : hdf-compose2: X o Y, nat: ℕ, ifthenelse: if b then t else f fi , lt_int: i <z j, uall: ∀[x:A]. B[x], top: Top, so_apply: x[s1;s2], so_apply: x[s], apply: f a, fix: fix(F), lambda: λx.A[x], pair: <a, b>, inl: inl x, subtract: n - m, add: n + m, natural_number: $n, sqequal: s ~ t, bag-combine: ⋃x∈bs.f[x], select_fun_last: select_fun_last(g;m), partial_ap_gen: partial_ap_gen(g;n;s;m), mk_lambdas: mk_lambdas(F;m), mk_lambdas_fun: mk_lambdas_fun(F;m), cbva_seq: cbva_seq(L; F; m)
Definitions unfolded in proof : uall: ∀[x:A]. B[x], member: t ∈ T, so_apply: x[s1;s2], so_apply: x[s], lt_int: i <z j, ifthenelse: if b then t else f fi , hdf-compose2: X o Y, bfalse: ff, btrue: tt, hdf-halted: hdf-halted(P), bor: p ∨_bq, hdf-ap: X(a), mk-hdf: mk-hdf(s,m.G[s; m];st.H[st];s0), hdf-run: hdf-run(P), hdf-halt: hdf-halt(), isr: isr(x), so_lambda: so_lambda(x,y,z,w.t[x; y; z; w]), so_apply: x[s1;s2;s3;s4], so_lambda: λ₂x.t[x], top: Top, uimplies: b supposing a, strict4: strict4(F), and: P ∧ Q, all: ∀x:A. B[x], implies: P ⇒ Q, has-value: (a)↓, prop: ℙ, guard: {T}, or: P ∨ Q, squash: ↓T, so_lambda: λ₂x y.t[x; y], nat: ℕ, false: False, ge: i ≥ j , satisfiable_int_formula: satisfiable_int_formula(fmla), exists: ∃x:A. B[x], not: ¬A, fun_exp: f^n, primrec: primrec(n;b;c), cbva_seq: cbva_seq(L; F; m), callbyvalueall_seq: callbyvalueall_seq(L;G;F;n;m), le_int: i ≤z j, bnot: ¬_bb, mk_lambdas: mk_lambdas(F;m), subtract: n - m, mk_lambdas_fun: mk_lambdas_fun(F;m), mk_lambdas-fun: mk_lambdas-fun(F;G;n;m), bag-combine: ⋃x∈bs.f[x], bag-union: bag-union(bbs), concat: concat(ll), reduce: reduce(f;k;as), list_ind: list_ind, append: as @ bs, cons: [a / b], nil: [], it: ⋅, bag-map: bag-map(f;bs), map: map(f;as), partial_ap_gen: partial_ap_gen(g;n;s;m), select_fun_last: select_fun_last(g;m), select_fun_ap: select_fun_ap(g;n;m), decidable: Dec(P), exposed-bfalse: exposed-bfalse, bool: 𝔹, unit: Unit, uiff: uiff(P;Q), sq_type: SQType(T), assert: ↑b, compose: f o g, nequal: a ≠ b ∈ T , eq_int: (i =_z j), subtype_rel: A ⊆r B

Latex:
\mforall{}[L1,L2,G1,G2,init,S:Top]. \mforall{}[m1,m2:\mBbbN{}]. (fix((\mlambda{}mk-hdf.(inl (\mlambda{}a.cbva\_seq(L1[a]; \mlambda{}g.<mk-hdf, G1[g]> m1))))) o (fix((\mlambda{}mk-hdf,s. (inl (\mlambda{}a.cbva\_seq(L2[s;a]; \mlambda{}g.<mk-hdf S[g;s], G2[g;s]> m2))))) init) \msim{} fix((\mlambda{}mk-hdf,s. (inl (\mlambda{}a.cbva\_seq(\mlambda{}n.if n <z m1 then L1[a] n if n <z m1 + m2 then mk\_lambdas(L2[s;a] (n - m1);m1) else mk\_lambdas\_fun(\mlambda{}g1.mk\_lambdas\_fun(\mlambda{}g2.\mcup{}f\mmember{}G1[g1]. \mcup{}b\mmember{}G2[g2;s]. f b;m2);m1) fi ; \mlambda{}g.<mk-hdf S[partial\_ap\_gen(g;(m1 + m2) + 1;m1;m2);s] , select\_fun\_last(g;m1 + m2) > (m1 + m2) + 1))))) init) Date html generated: 2016_05_16-AM-10_47_57 Last ObjectModification: 2016_01_17-AM-11_09_16 Theory : halting!dataflow Home Index