## lustrec / optim / oversampling / out / typed / f_step_assert_5.coq @ 6a93d814

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(* ---------------------------------------------------------- *) |
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(* --- Assertion (file oversampling0_4.c, line 173) --- *) |

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(* ---------------------------------------------------------- *) |

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Require Import ZArith. |

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Require Import Reals. |

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Require Import BuiltIn. |

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Require Import bool.Bool. |

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Require Import int.Int. |

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Require Import int.Abs. |

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Require Import int.ComputerDivision. |

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Require Import real.Real. |

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Require Import real.RealInfix. |

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Require Import real.FromInt. |

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Require Import map.Map. |

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Require Import Qedlib. |

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Require Import Qed. |

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Require Import S_f_mem_pack. |

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Require Import Memory. |

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Require Import Cint. |

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Require Import Compound. |

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Require Import Axiomatic. |

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Goal |

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forall (i_1 i : Z), |

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forall (t : array Z), |

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forall (t_2 t_1 : farray addr Z), |

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forall (t_3 : farray addr addr), |

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forall (a_2 a_1 a : addr), |

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forall (f_1 f : S_f_mem_pack), |

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let a_3 := t_3.[ (shiftfield_F_f_mem_ni_2 a_2) ] in |

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let x := (1%Z + i%Z)%Z in |

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let m := t_1.[ a <- x ] in |

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let x_1 := (1%Z + i_1%Z)%Z in |

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let m_1 := t_2.[ a_1 <- x_1 ] in |

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let a_4 := (shiftfield_F__arrow_reg__first |

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((shiftfield_F__arrow_mem__reg a_3))) in |

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let x_2 := (m_1.[ a_4 ])%Z in |

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let x_3 := (t_1.[ a_1 ])%Z in |

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(a <> a_1) -> |

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((IsS_f_mem_pack f)) -> |

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((IsS_f_mem_pack f_1)) -> |

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((framed t_3)) -> |

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((linked t)) -> |

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((is_sint32 i%Z)) -> |

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((is_sint32 i_1%Z)) -> |

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(a <> a_3) -> |

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(a_1 <> a_3) -> |

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((valid_rw t a 1%Z)) -> |

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((valid_rw t a_1 1%Z)) -> |

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((P_valid_f t t_3 a_2)) -> |

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((((region ((base a))%Z)) <= 0)%Z) -> |

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((((region ((base a_1))%Z)) <= 0)%Z) -> |

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((((region ((base a_2))%Z)) <= 0)%Z) -> |

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((separated a_2 2%Z a 1%Z)) -> |

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((separated a_2 2%Z a_1 1%Z)) -> |

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((P_f_pack2 t_3 t_2 f_1 a_2)) -> |

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((separated a_2 2%Z a_3 1%Z)) -> |

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((P_f_pack1 t_3 m f a_2)) -> |

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((is_uint32 x_2)) -> |

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(itep ((0 = x_2)%Z) (t_1 = m_1) (t_1 = (m_1.[ a_4 <- (0)%Z ]))) -> |

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(itep ((0 = x_2)%Z) |

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((i |

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= (t_1.[ (shiftfield_F_f_reg___f_2 ((shiftfield_F_f_mem__reg a_2))) ]))%Z) |

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((0 = i)%Z)) -> |

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(forall (f_2 : S_f_mem_pack), ((IsS_f_mem_pack f_2)) -> |

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(forall (f_3 : S_f_mem_pack), (P_f_pack0) -> ((IsS_f_mem_pack f_3)) -> |

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((P_f_pack2 t_3 t_2 f_2 a_2)) -> (P_trans_fA))) -> |

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(forall (f_2 : S_f_mem_pack), ((IsS_f_mem_pack f_2)) -> |

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(forall (f_3 : S_f_mem_pack), (P_f_pack0) -> ((IsS_f_mem_pack f_3)) -> |

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((P_f_pack2 t_3 t_2 f_2 a_2)) -> ((P_trans_fB i_1%Z x_1)))) -> |

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(forall (f_2 : S_f_mem_pack), ((IsS_f_mem_pack f_2)) -> |

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(forall (f_3 : S_f_mem_pack), ((IsS_f_mem_pack f_3)) -> |

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((P_f_pack1 t_3 t_1 f_3 a_2)) -> ((P_f_pack2 t_3 t_2 f_2 a_2)) -> |

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((P_trans_fD i_1%Z f_2 f_3 x_3 i%Z)))) -> |

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(forall (f_2 : S_f_mem_pack), ((IsS_f_mem_pack f_2)) -> |

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(forall (f_3 : S_f_mem_pack), ((IsS_f_mem_pack f_3)) -> |

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((P_f_pack1 t_3 t_1 f_3 a_2)) -> ((P_f_pack2 t_3 t_2 f_2 a_2)) -> |

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((P_trans_fC i_1%Z f_2 f_3 x_3 x_2)))) -> |

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((P_trans_fE i_1%Z f_1 f (m.[ a_1 ])%Z x)). |

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