Nuprl Lemma : hdf-memory-base3-3

∀[F1,F2,F3,f1,f2,f3,s:Top]. ∀[hdr1,hdr2,hdr3:Name].
(hdf-memory((λx,s. f1[x;s]) o hdf-base(a.if name_eq(fst(a);hdr1) then [F1[a]] else [] fi )

              || (λx,s. f2[x;s]) o hdf-base(a.if name_eq(fst(a);hdr2) then [F2[a]] else [] fi ) || (λx,s. f3[x;s])

o hdf-base(a.if name_eq(fst(a);hdr3) then [F3[a]] else [] fi );[s])
~ fix((λmk-hdf,s. (inl (λa.cbva_seq(λn.if name_eq(fst(a);hdr1) then f1[F1[a];s]

                                            if name_eq(fst(a);hdr2) then f2[F2[a];s]

                                            if name_eq(fst(a);hdr3) then f3[F3[a];s]

else s

                                            fi ; λg.<mk-hdf (g (λx.x)), [s]>; 1)))))

       s) supposing
     ((¬(hdr1 = hdr2 ∈ Name)) and
     (¬(hdr1 = hdr3 ∈ Name)) and
     (¬(hdr2 = hdr3 ∈ Name)))

Proof

Definitions occuring in Statement : hdf-parallel: X || Y, hdf-memory: hdf-memory(X;bs), hdf-compose1: f o X, hdf-base: hdf-base(m.F[m]), name_eq: name_eq(x;y), name: Name, cons: [a / b], nil: [], ifthenelse: if b then t else f fi , uimplies: b supposing a, uall: ∀[x:A]. B[x], top: Top, so_apply: x[s1;s2], so_apply: x[s], pi1: fst(t), not: ¬A, apply: f a, fix: fix(F), lambda: λx.A[x], pair: <a, b>, inl: inl x, natural_number: $n, sqequal: s ~ t, equal: s = t ∈ T, cbva_seq: cbva_seq(L; F; m)
Definitions unfolded in proof : uall: ∀[x:A]. B[x], so_lambda: λ₂x.t[x], member: t ∈ T, top: Top, so_apply: x[s], nat: ℕ, le: A ≤ B, and: P ∧ Q, less_than': less_than'(a;b), false: False, not: ¬A, implies: P ⇒ Q, prop: ℙ, cbva_seq: cbva_seq(L; F; m), select_fun_last: select_fun_last(g;m), select_fun_ap: select_fun_ap(g;n;m), mk_lambdas_fun: mk_lambdas_fun(F;m), bag-map: bag-map(f;bs), mk_lambdas: mk_lambdas(F;m), all: ∀x:A. B[x], subtract: n - m, callbyvalueall_seq: callbyvalueall_seq(L;G;F;n;m), le_int: i ≤z j, lt_int: i <z j, bnot: ¬_bb, ifthenelse: if b then t else f fi , btrue: tt, bfalse: ff, eq_int: (i =_z j), mk_lambdas-fun: mk_lambdas-fun(F;G;n;m), ge: i ≥ j , uimplies: b supposing a, satisfiable_int_formula: satisfiable_int_formula(fmla), exists: ∃x:A. B[x], decidable: Dec(P), or: P ∨ Q, nat_plus: ℕ⁺, callbyvalueall: callbyvalueall, evalall: evalall(t), nil: [], it: ⋅, bag-append: as + bs, append: as @ bs, list_ind: list_ind, cons: [a / b], so_lambda: so_lambda(x,y,z.t[x; y; z]), so_apply: x[s1;s2;s3], empty-bag: {}, subtype_rel: A ⊆r B, name: Name, has-valueall: has-valueall(a), bag-null: bag-null(bs), has-value: (a)↓, bag-combine: ⋃x∈bs.f[x], bag-union: bag-union(bbs), concat: concat(ll), reduce: reduce(f;k;as), map: map(f;as), null: null(as), so_lambda: λ₂x y.t[x; y], so_apply: x[s1;s2]

Latex:
\mforall{}[F1,F2,F3,f1,f2,f3,s:Top]. \mforall{}[hdr1,hdr2,hdr3:Name]. (hdf-memory((\mlambda{}x,s. f1[x;s]) o hdf-base(a.if name\_eq(fst(a);hdr1) then [F1[a]] else [] fi ) || (\mlambda{}x,s. f2[x;s]) o hdf-base(a.if name\_eq(fst(a);hdr2) then [F2[a]] else [] fi ) || (\mlambda{}x,s. f3[x;s]) o hdf-base(a.if name\_eq(fst(a);hdr3) then [F3[a]] else [] fi );[\000Cs]) \msim{} fix((\mlambda{}mk-hdf,s. (inl (\mlambda{}a.cbva\_seq(\mlambda{}n.if name\_eq(fst(a);hdr1) then f1[F1[a];s] if name\_eq(fst(a);hdr2) then f2[F2[a];s] if name\_eq(fst(a);hdr3) then f3[F3[a];s] else s fi ; \mlambda{}g.<mk-hdf (g (\mlambda{}x.x)), [s]> 1))))) s) supposing ((\mneg{}(hdr1 = hdr2)) and (\mneg{}(hdr1 = hdr3)) and (\mneg{}(hdr2 = hdr3))) Date html generated: 2016_05_16-AM-10_50_11 Last ObjectModification: 2016_01_17-AM-11_08_48 Theory : halting!dataflow Home Index