author | ballarin |
Thu, 24 Mar 2005 16:34:15 +0100 | |
changeset 15622 | 4723248c982b |
parent 15531 | 08c8dad8e399 |
child 15780 | 6744bba5561d |
permissions | -rw-r--r-- |
15524 | 1 |
(* Title: HOL/Orderings.thy |
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ID: $Id$ |
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Author: Tobias Nipkow, Markus Wenzel, and Larry Paulson |
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FIXME: derive more of the min/max laws generically via semilattices |
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*) |
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header {* Type classes for $\le$ *} |
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theory Orderings |
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imports Lattice_Locales |
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files ("antisym_setup.ML") |
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begin |
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subsection {* Order signatures and orders *} |
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axclass |
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ord < type |
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syntax |
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"op <" :: "['a::ord, 'a] => bool" ("op <") |
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"op <=" :: "['a::ord, 'a] => bool" ("op <=") |
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global |
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consts |
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"op <" :: "['a::ord, 'a] => bool" ("(_/ < _)" [50, 51] 50) |
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"op <=" :: "['a::ord, 'a] => bool" ("(_/ <= _)" [50, 51] 50) |
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local |
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syntax (xsymbols) |
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"op <=" :: "['a::ord, 'a] => bool" ("op \<le>") |
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"op <=" :: "['a::ord, 'a] => bool" ("(_/ \<le> _)" [50, 51] 50) |
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syntax (HTML output) |
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"op <=" :: "['a::ord, 'a] => bool" ("op \<le>") |
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"op <=" :: "['a::ord, 'a] => bool" ("(_/ \<le> _)" [50, 51] 50) |
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text{* Syntactic sugar: *} |
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consts |
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"_gt" :: "'a::ord => 'a => bool" (infixl ">" 50) |
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"_ge" :: "'a::ord => 'a => bool" (infixl ">=" 50) |
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translations |
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"x > y" => "y < x" |
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"x >= y" => "y <= x" |
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syntax (xsymbols) |
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"_ge" :: "'a::ord => 'a => bool" (infixl "\<ge>" 50) |
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syntax (HTML output) |
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"_ge" :: "['a::ord, 'a] => bool" (infixl "\<ge>" 50) |
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subsection {* Monotonicity *} |
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locale mono = |
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fixes f |
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assumes mono: "A <= B ==> f A <= f B" |
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lemmas monoI [intro?] = mono.intro |
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and monoD [dest?] = mono.mono |
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constdefs |
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min :: "['a::ord, 'a] => 'a" |
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"min a b == (if a <= b then a else b)" |
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max :: "['a::ord, 'a] => 'a" |
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"max a b == (if a <= b then b else a)" |
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lemma min_leastL: "(!!x. least <= x) ==> min least x = least" |
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by (simp add: min_def) |
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lemma min_of_mono: |
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"ALL x y. (f x <= f y) = (x <= y) ==> min (f m) (f n) = f (min m n)" |
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by (simp add: min_def) |
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lemma max_leastL: "(!!x. least <= x) ==> max least x = x" |
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by (simp add: max_def) |
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lemma max_of_mono: |
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"ALL x y. (f x <= f y) = (x <= y) ==> max (f m) (f n) = f (max m n)" |
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by (simp add: max_def) |
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subsection "Orders" |
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axclass order < ord |
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order_refl [iff]: "x <= x" |
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order_trans: "x <= y ==> y <= z ==> x <= z" |
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order_antisym: "x <= y ==> y <= x ==> x = y" |
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order_less_le: "(x < y) = (x <= y & x ~= y)" |
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text{* Connection to locale: *} |
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lemma partial_order_order: |
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"partial_order (op \<le> :: 'a::order \<Rightarrow> 'a \<Rightarrow> bool)" |
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apply(rule partial_order.intro) |
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apply(rule order_refl, erule (1) order_trans, erule (1) order_antisym) |
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done |
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text {* Reflexivity. *} |
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lemma order_eq_refl: "!!x::'a::order. x = y ==> x <= y" |
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-- {* This form is useful with the classical reasoner. *} |
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apply (erule ssubst) |
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apply (rule order_refl) |
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done |
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lemma order_less_irrefl [iff]: "~ x < (x::'a::order)" |
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by (simp add: order_less_le) |
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lemma order_le_less: "((x::'a::order) <= y) = (x < y | x = y)" |
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-- {* NOT suitable for iff, since it can cause PROOF FAILED. *} |
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apply (simp add: order_less_le, blast) |
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done |
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lemmas order_le_imp_less_or_eq = order_le_less [THEN iffD1, standard] |
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lemma order_less_imp_le: "!!x::'a::order. x < y ==> x <= y" |
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by (simp add: order_less_le) |
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text {* Asymmetry. *} |
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lemma order_less_not_sym: "(x::'a::order) < y ==> ~ (y < x)" |
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by (simp add: order_less_le order_antisym) |
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lemma order_less_asym: "x < (y::'a::order) ==> (~P ==> y < x) ==> P" |
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apply (drule order_less_not_sym) |
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apply (erule contrapos_np, simp) |
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done |
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lemma order_eq_iff: "!!x::'a::order. (x = y) = (x \<le> y & y \<le> x)" |
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by (blast intro: order_antisym) |
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lemma order_antisym_conv: "(y::'a::order) <= x ==> (x <= y) = (x = y)" |
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by(blast intro:order_antisym) |
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text {* Transitivity. *} |
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lemma order_less_trans: "!!x::'a::order. [| x < y; y < z |] ==> x < z" |
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apply (simp add: order_less_le) |
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apply (blast intro: order_trans order_antisym) |
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done |
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lemma order_le_less_trans: "!!x::'a::order. [| x <= y; y < z |] ==> x < z" |
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apply (simp add: order_less_le) |
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apply (blast intro: order_trans order_antisym) |
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done |
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lemma order_less_le_trans: "!!x::'a::order. [| x < y; y <= z |] ==> x < z" |
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apply (simp add: order_less_le) |
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apply (blast intro: order_trans order_antisym) |
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done |
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text {* Useful for simplification, but too risky to include by default. *} |
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lemma order_less_imp_not_less: "(x::'a::order) < y ==> (~ y < x) = True" |
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by (blast elim: order_less_asym) |
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lemma order_less_imp_triv: "(x::'a::order) < y ==> (y < x --> P) = True" |
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by (blast elim: order_less_asym) |
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lemma order_less_imp_not_eq: "(x::'a::order) < y ==> (x = y) = False" |
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by auto |
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lemma order_less_imp_not_eq2: "(x::'a::order) < y ==> (y = x) = False" |
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by auto |
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text {* Other operators. *} |
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lemma min_leastR: "(!!x::'a::order. least <= x) ==> min x least = least" |
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apply (simp add: min_def) |
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apply (blast intro: order_antisym) |
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done |
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lemma max_leastR: "(!!x::'a::order. least <= x) ==> max x least = x" |
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apply (simp add: max_def) |
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apply (blast intro: order_antisym) |
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done |
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subsection {* Transitivity rules for calculational reasoning *} |
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lemma order_neq_le_trans: "a ~= b ==> (a::'a::order) <= b ==> a < b" |
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by (simp add: order_less_le) |
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lemma order_le_neq_trans: "(a::'a::order) <= b ==> a ~= b ==> a < b" |
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by (simp add: order_less_le) |
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lemma order_less_asym': "(a::'a::order) < b ==> b < a ==> P" |
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by (rule order_less_asym) |
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subsection {* Least value operator *} |
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constdefs |
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Least :: "('a::ord => bool) => 'a" (binder "LEAST " 10) |
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"Least P == THE x. P x & (ALL y. P y --> x <= y)" |
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-- {* We can no longer use LeastM because the latter requires Hilbert-AC. *} |
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lemma LeastI2: |
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"[| P (x::'a::order); |
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!!y. P y ==> x <= y; |
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!!x. [| P x; ALL y. P y --> x \<le> y |] ==> Q x |] |
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==> Q (Least P)" |
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apply (unfold Least_def) |
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apply (rule theI2) |
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apply (blast intro: order_antisym)+ |
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done |
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lemma Least_equality: |
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"[| P (k::'a::order); !!x. P x ==> k <= x |] ==> (LEAST x. P x) = k" |
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apply (simp add: Least_def) |
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apply (rule the_equality) |
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apply (auto intro!: order_antisym) |
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done |
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subsection "Linear / total orders" |
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axclass linorder < order |
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linorder_linear: "x <= y | y <= x" |
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lemma linorder_less_linear: "!!x::'a::linorder. x<y | x=y | y<x" |
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apply (simp add: order_less_le) |
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apply (insert linorder_linear, blast) |
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done |
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lemma linorder_le_less_linear: "!!x::'a::linorder. x\<le>y | y<x" |
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by (simp add: order_le_less linorder_less_linear) |
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lemma linorder_le_cases [case_names le ge]: |
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"((x::'a::linorder) \<le> y ==> P) ==> (y \<le> x ==> P) ==> P" |
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by (insert linorder_linear, blast) |
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lemma linorder_cases [case_names less equal greater]: |
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"((x::'a::linorder) < y ==> P) ==> (x = y ==> P) ==> (y < x ==> P) ==> P" |
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by (insert linorder_less_linear, blast) |
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lemma linorder_not_less: "!!x::'a::linorder. (~ x < y) = (y <= x)" |
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apply (simp add: order_less_le) |
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apply (insert linorder_linear) |
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apply (blast intro: order_antisym) |
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done |
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lemma linorder_not_le: "!!x::'a::linorder. (~ x <= y) = (y < x)" |
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apply (simp add: order_less_le) |
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apply (insert linorder_linear) |
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apply (blast intro: order_antisym) |
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done |
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lemma linorder_neq_iff: "!!x::'a::linorder. (x ~= y) = (x<y | y<x)" |
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by (cut_tac x = x and y = y in linorder_less_linear, auto) |
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lemma linorder_neqE: "x ~= (y::'a::linorder) ==> (x < y ==> R) ==> (y < x ==> R) ==> R" |
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by (simp add: linorder_neq_iff, blast) |
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lemma linorder_antisym_conv1: "~ (x::'a::linorder) < y ==> (x <= y) = (x = y)" |
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by(blast intro:order_antisym dest:linorder_not_less[THEN iffD1]) |
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lemma linorder_antisym_conv2: "(x::'a::linorder) <= y ==> (~ x < y) = (x = y)" |
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by(blast intro:order_antisym dest:linorder_not_less[THEN iffD1]) |
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lemma linorder_antisym_conv3: "~ (y::'a::linorder) < x ==> (~ x < y) = (x = y)" |
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by(blast intro:order_antisym dest:linorder_not_less[THEN iffD1]) |
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use "antisym_setup.ML"; |
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setup antisym_setup |
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subsection {* Setup of transitivity reasoner as Solver *} |
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lemma less_imp_neq: "[| (x::'a::order) < y |] ==> x ~= y" |
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by (erule contrapos_pn, erule subst, rule order_less_irrefl) |
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lemma eq_neq_eq_imp_neq: "[| x = a ; a ~= b; b = y |] ==> x ~= y" |
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by (erule subst, erule ssubst, assumption) |
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ML_setup {* |
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(* The setting up of Quasi_Tac serves as a demo. Since there is no |
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class for quasi orders, the tactics Quasi_Tac.trans_tac and |
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Quasi_Tac.quasi_tac are not of much use. *) |
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fun decomp_gen sort sign (Trueprop $ t) = |
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Transitivity reasoner ignores types amenable to linear arithmetic.
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let fun of_sort t = let val T = type_of t in |
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Transitivity reasoner ignores types amenable to linear arithmetic.
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(* exclude numeric types: linear arithmetic subsumes transitivity *) |
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T <> HOLogic.natT andalso T <> HOLogic.intT andalso |
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T <> HOLogic.realT andalso Sign.of_sort sign (T, sort) end |
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fun dec (Const ("Not", _) $ t) = ( |
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case dec t of |
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NONE => NONE |
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| SOME (t1, rel, t2) => SOME (t1, "~" ^ rel, t2)) |
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| dec (Const ("op =", _) $ t1 $ t2) = |
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if of_sort t1 |
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then SOME (t1, "=", t2) |
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else NONE |
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| dec (Const ("op <=", _) $ t1 $ t2) = |
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if of_sort t1 |
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then SOME (t1, "<=", t2) |
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else NONE |
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| dec (Const ("op <", _) $ t1 $ t2) = |
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if of_sort t1 |
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then SOME (t1, "<", t2) |
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else NONE |
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| dec _ = NONE |
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in dec t end; |
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structure Quasi_Tac = Quasi_Tac_Fun ( |
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struct |
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val le_trans = thm "order_trans"; |
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val le_refl = thm "order_refl"; |
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val eqD1 = thm "order_eq_refl"; |
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val eqD2 = thm "sym" RS thm "order_eq_refl"; |
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val less_reflE = thm "order_less_irrefl" RS thm "notE"; |
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val less_imp_le = thm "order_less_imp_le"; |
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val le_neq_trans = thm "order_le_neq_trans"; |
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val neq_le_trans = thm "order_neq_le_trans"; |
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val less_imp_neq = thm "less_imp_neq"; |
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val decomp_trans = decomp_gen ["Orderings.order"]; |
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val decomp_quasi = decomp_gen ["Orderings.order"]; |
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end); (* struct *) |
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structure Order_Tac = Order_Tac_Fun ( |
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struct |
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val less_reflE = thm "order_less_irrefl" RS thm "notE"; |
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val le_refl = thm "order_refl"; |
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val less_imp_le = thm "order_less_imp_le"; |
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val not_lessI = thm "linorder_not_less" RS thm "iffD2"; |
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val not_leI = thm "linorder_not_le" RS thm "iffD2"; |
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val not_lessD = thm "linorder_not_less" RS thm "iffD1"; |
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val not_leD = thm "linorder_not_le" RS thm "iffD1"; |
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val eqI = thm "order_antisym"; |
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val eqD1 = thm "order_eq_refl"; |
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val eqD2 = thm "sym" RS thm "order_eq_refl"; |
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val less_trans = thm "order_less_trans"; |
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val less_le_trans = thm "order_less_le_trans"; |
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val le_less_trans = thm "order_le_less_trans"; |
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val le_trans = thm "order_trans"; |
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val le_neq_trans = thm "order_le_neq_trans"; |
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val neq_le_trans = thm "order_neq_le_trans"; |
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val less_imp_neq = thm "less_imp_neq"; |
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val eq_neq_eq_imp_neq = thm "eq_neq_eq_imp_neq"; |
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val decomp_part = decomp_gen ["Orderings.order"]; |
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val decomp_lin = decomp_gen ["Orderings.linorder"]; |
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end); (* struct *) |
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simpset_ref() := simpset () |
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addSolver (mk_solver "Trans_linear" (fn _ => Order_Tac.linear_tac)) |
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addSolver (mk_solver "Trans_partial" (fn _ => Order_Tac.partial_tac)); |
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(* Adding the transitivity reasoners also as safe solvers showed a slight |
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speed up, but the reasoning strength appears to be not higher (at least |
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no breaking of additional proofs in the entire HOL distribution, as |
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of 5 March 2004, was observed). *) |
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*} |
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(* Optional setup of methods *) |
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(* |
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method_setup trans_partial = |
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{* Method.no_args (Method.SIMPLE_METHOD' HEADGOAL (Order_Tac.partial_tac)) *} |
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{* transitivity reasoner for partial orders *} |
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method_setup trans_linear = |
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{* Method.no_args (Method.SIMPLE_METHOD' HEADGOAL (Order_Tac.linear_tac)) *} |
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{* transitivity reasoner for linear orders *} |
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*) |
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(* |
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declare order.order_refl [simp del] order_less_irrefl [simp del] |
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can currently not be removed, abel_cancel relies on it. |
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*) |
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subsection "Min and max on (linear) orders" |
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lemma min_same [simp]: "min (x::'a::order) x = x" |
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by (simp add: min_def) |
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lemma max_same [simp]: "max (x::'a::order) x = x" |
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by (simp add: max_def) |
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text{* Instantiate locales: *} |
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lemma lower_semilattice_lin_min: |
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"lower_semilattice(op \<le>) (min :: 'a::linorder \<Rightarrow> 'a \<Rightarrow> 'a)" |
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apply(rule lower_semilattice.intro) |
|
394 |
apply(rule partial_order_order) |
|
395 |
apply(rule lower_semilattice_axioms.intro) |
|
396 |
apply(simp add:min_def linorder_not_le order_less_imp_le) |
|
397 |
apply(simp add:min_def linorder_not_le order_less_imp_le) |
|
398 |
apply(simp add:min_def linorder_not_le order_less_imp_le) |
|
399 |
done |
|
400 |
||
401 |
lemma upper_semilattice_lin_max: |
|
402 |
"upper_semilattice(op \<le>) (max :: 'a::linorder \<Rightarrow> 'a \<Rightarrow> 'a)" |
|
403 |
apply(rule upper_semilattice.intro) |
|
404 |
apply(rule partial_order_order) |
|
405 |
apply(rule upper_semilattice_axioms.intro) |
|
406 |
apply(simp add: max_def linorder_not_le order_less_imp_le) |
|
407 |
apply(simp add: max_def linorder_not_le order_less_imp_le) |
|
408 |
apply(simp add: max_def linorder_not_le order_less_imp_le) |
|
409 |
done |
|
410 |
||
411 |
lemma lattice_min_max: "lattice (op \<le>) (min :: 'a::linorder \<Rightarrow> 'a \<Rightarrow> 'a) max" |
|
412 |
apply(rule lattice.intro) |
|
413 |
apply(rule partial_order_order) |
|
414 |
apply(rule lower_semilattice.axioms[OF lower_semilattice_lin_min]) |
|
415 |
apply(rule upper_semilattice.axioms[OF upper_semilattice_lin_max]) |
|
416 |
done |
|
417 |
||
418 |
lemma distrib_lattice_min_max: |
|
419 |
"distrib_lattice (op \<le>) (min :: 'a::linorder \<Rightarrow> 'a \<Rightarrow> 'a) max" |
|
420 |
apply(rule distrib_lattice.intro) |
|
421 |
apply(rule partial_order_order) |
|
422 |
apply(rule lower_semilattice.axioms[OF lower_semilattice_lin_min]) |
|
423 |
apply(rule upper_semilattice.axioms[OF upper_semilattice_lin_max]) |
|
424 |
apply(rule distrib_lattice_axioms.intro) |
|
425 |
apply(rule_tac x=x and y=y in linorder_le_cases) |
|
426 |
apply(rule_tac x=x and y=z in linorder_le_cases) |
|
427 |
apply(rule_tac x=y and y=z in linorder_le_cases) |
|
428 |
apply(simp add:min_def max_def) |
|
429 |
apply(simp add:min_def max_def) |
|
430 |
apply(rule_tac x=y and y=z in linorder_le_cases) |
|
431 |
apply(simp add:min_def max_def) |
|
432 |
apply(simp add:min_def max_def) |
|
433 |
apply(rule_tac x=x and y=z in linorder_le_cases) |
|
434 |
apply(rule_tac x=y and y=z in linorder_le_cases) |
|
435 |
apply(simp add:min_def max_def) |
|
436 |
apply(simp add:min_def max_def) |
|
437 |
apply(rule_tac x=y and y=z in linorder_le_cases) |
|
438 |
apply(simp add:min_def max_def) |
|
439 |
apply(simp add:min_def max_def) |
|
440 |
done |
|
441 |
||
442 |
lemma le_max_iff_disj: "!!z::'a::linorder. (z <= max x y) = (z <= x | z <= y)" |
|
443 |
apply(simp add:max_def) |
|
444 |
apply (insert linorder_linear) |
|
445 |
apply (blast intro: order_trans) |
|
446 |
done |
|
447 |
||
448 |
lemma le_maxI1: "(x::'a::linorder) <= max x y" |
|
449 |
by(rule upper_semilattice.sup_ge1[OF upper_semilattice_lin_max]) |
|
450 |
||
451 |
lemma le_maxI2: "(y::'a::linorder) <= max x y" |
|
452 |
-- {* CANNOT use with @{text "[intro!]"} because blast will give PROOF FAILED. *} |
|
453 |
by(rule upper_semilattice.sup_ge2[OF upper_semilattice_lin_max]) |
|
454 |
||
455 |
lemma less_max_iff_disj: "!!z::'a::linorder. (z < max x y) = (z < x | z < y)" |
|
456 |
apply (simp add: max_def order_le_less) |
|
457 |
apply (insert linorder_less_linear) |
|
458 |
apply (blast intro: order_less_trans) |
|
459 |
done |
|
460 |
||
461 |
lemma max_le_iff_conj [simp]: |
|
462 |
"!!z::'a::linorder. (max x y <= z) = (x <= z & y <= z)" |
|
463 |
by (rule upper_semilattice.above_sup_conv[OF upper_semilattice_lin_max]) |
|
464 |
||
465 |
lemma max_less_iff_conj [simp]: |
|
466 |
"!!z::'a::linorder. (max x y < z) = (x < z & y < z)" |
|
467 |
apply (simp add: order_le_less max_def) |
|
468 |
apply (insert linorder_less_linear) |
|
469 |
apply (blast intro: order_less_trans) |
|
470 |
done |
|
471 |
||
472 |
lemma le_min_iff_conj [simp]: |
|
473 |
"!!z::'a::linorder. (z <= min x y) = (z <= x & z <= y)" |
|
474 |
-- {* @{text "[iff]"} screws up a @{text blast} in MiniML *} |
|
475 |
by (rule lower_semilattice.below_inf_conv[OF lower_semilattice_lin_min]) |
|
476 |
||
477 |
lemma min_less_iff_conj [simp]: |
|
478 |
"!!z::'a::linorder. (z < min x y) = (z < x & z < y)" |
|
479 |
apply (simp add: order_le_less min_def) |
|
480 |
apply (insert linorder_less_linear) |
|
481 |
apply (blast intro: order_less_trans) |
|
482 |
done |
|
483 |
||
484 |
lemma min_le_iff_disj: "!!z::'a::linorder. (min x y <= z) = (x <= z | y <= z)" |
|
485 |
apply (simp add: min_def) |
|
486 |
apply (insert linorder_linear) |
|
487 |
apply (blast intro: order_trans) |
|
488 |
done |
|
489 |
||
490 |
lemma min_less_iff_disj: "!!z::'a::linorder. (min x y < z) = (x < z | y < z)" |
|
491 |
apply (simp add: min_def order_le_less) |
|
492 |
apply (insert linorder_less_linear) |
|
493 |
apply (blast intro: order_less_trans) |
|
494 |
done |
|
495 |
||
496 |
lemma max_assoc: "!!x::'a::linorder. max (max x y) z = max x (max y z)" |
|
497 |
by (rule upper_semilattice.sup_assoc[OF upper_semilattice_lin_max]) |
|
498 |
||
499 |
lemma max_commute: "!!x::'a::linorder. max x y = max y x" |
|
500 |
by (rule upper_semilattice.sup_commute[OF upper_semilattice_lin_max]) |
|
501 |
||
502 |
lemmas max_ac = max_assoc max_commute |
|
503 |
mk_left_commute[of max,OF max_assoc max_commute] |
|
504 |
||
505 |
lemma min_assoc: "!!x::'a::linorder. min (min x y) z = min x (min y z)" |
|
506 |
by (rule lower_semilattice.inf_assoc[OF lower_semilattice_lin_min]) |
|
507 |
||
508 |
lemma min_commute: "!!x::'a::linorder. min x y = min y x" |
|
509 |
by (rule lower_semilattice.inf_commute[OF lower_semilattice_lin_min]) |
|
510 |
||
511 |
lemmas min_ac = min_assoc min_commute |
|
512 |
mk_left_commute[of min,OF min_assoc min_commute] |
|
513 |
||
514 |
lemma split_min: |
|
515 |
"P (min (i::'a::linorder) j) = ((i <= j --> P(i)) & (~ i <= j --> P(j)))" |
|
516 |
by (simp add: min_def) |
|
517 |
||
518 |
lemma split_max: |
|
519 |
"P (max (i::'a::linorder) j) = ((i <= j --> P(j)) & (~ i <= j --> P(i)))" |
|
520 |
by (simp add: max_def) |
|
521 |
||
522 |
||
523 |
subsection "Bounded quantifiers" |
|
524 |
||
525 |
syntax |
|
526 |
"_lessAll" :: "[idt, 'a, bool] => bool" ("(3ALL _<_./ _)" [0, 0, 10] 10) |
|
527 |
"_lessEx" :: "[idt, 'a, bool] => bool" ("(3EX _<_./ _)" [0, 0, 10] 10) |
|
528 |
"_leAll" :: "[idt, 'a, bool] => bool" ("(3ALL _<=_./ _)" [0, 0, 10] 10) |
|
529 |
"_leEx" :: "[idt, 'a, bool] => bool" ("(3EX _<=_./ _)" [0, 0, 10] 10) |
|
530 |
||
531 |
"_gtAll" :: "[idt, 'a, bool] => bool" ("(3ALL _>_./ _)" [0, 0, 10] 10) |
|
532 |
"_gtEx" :: "[idt, 'a, bool] => bool" ("(3EX _>_./ _)" [0, 0, 10] 10) |
|
533 |
"_geAll" :: "[idt, 'a, bool] => bool" ("(3ALL _>=_./ _)" [0, 0, 10] 10) |
|
534 |
"_geEx" :: "[idt, 'a, bool] => bool" ("(3EX _>=_./ _)" [0, 0, 10] 10) |
|
535 |
||
536 |
syntax (xsymbols) |
|
537 |
"_lessAll" :: "[idt, 'a, bool] => bool" ("(3\<forall>_<_./ _)" [0, 0, 10] 10) |
|
538 |
"_lessEx" :: "[idt, 'a, bool] => bool" ("(3\<exists>_<_./ _)" [0, 0, 10] 10) |
|
539 |
"_leAll" :: "[idt, 'a, bool] => bool" ("(3\<forall>_\<le>_./ _)" [0, 0, 10] 10) |
|
540 |
"_leEx" :: "[idt, 'a, bool] => bool" ("(3\<exists>_\<le>_./ _)" [0, 0, 10] 10) |
|
541 |
||
542 |
"_gtAll" :: "[idt, 'a, bool] => bool" ("(3\<forall>_>_./ _)" [0, 0, 10] 10) |
|
543 |
"_gtEx" :: "[idt, 'a, bool] => bool" ("(3\<exists>_>_./ _)" [0, 0, 10] 10) |
|
544 |
"_geAll" :: "[idt, 'a, bool] => bool" ("(3\<forall>_\<ge>_./ _)" [0, 0, 10] 10) |
|
545 |
"_geEx" :: "[idt, 'a, bool] => bool" ("(3\<exists>_\<ge>_./ _)" [0, 0, 10] 10) |
|
546 |
||
547 |
syntax (HOL) |
|
548 |
"_lessAll" :: "[idt, 'a, bool] => bool" ("(3! _<_./ _)" [0, 0, 10] 10) |
|
549 |
"_lessEx" :: "[idt, 'a, bool] => bool" ("(3? _<_./ _)" [0, 0, 10] 10) |
|
550 |
"_leAll" :: "[idt, 'a, bool] => bool" ("(3! _<=_./ _)" [0, 0, 10] 10) |
|
551 |
"_leEx" :: "[idt, 'a, bool] => bool" ("(3? _<=_./ _)" [0, 0, 10] 10) |
|
552 |
||
553 |
syntax (HTML output) |
|
554 |
"_lessAll" :: "[idt, 'a, bool] => bool" ("(3\<forall>_<_./ _)" [0, 0, 10] 10) |
|
555 |
"_lessEx" :: "[idt, 'a, bool] => bool" ("(3\<exists>_<_./ _)" [0, 0, 10] 10) |
|
556 |
"_leAll" :: "[idt, 'a, bool] => bool" ("(3\<forall>_\<le>_./ _)" [0, 0, 10] 10) |
|
557 |
"_leEx" :: "[idt, 'a, bool] => bool" ("(3\<exists>_\<le>_./ _)" [0, 0, 10] 10) |
|
558 |
||
559 |
"_gtAll" :: "[idt, 'a, bool] => bool" ("(3\<forall>_>_./ _)" [0, 0, 10] 10) |
|
560 |
"_gtEx" :: "[idt, 'a, bool] => bool" ("(3\<exists>_>_./ _)" [0, 0, 10] 10) |
|
561 |
"_geAll" :: "[idt, 'a, bool] => bool" ("(3\<forall>_\<ge>_./ _)" [0, 0, 10] 10) |
|
562 |
"_geEx" :: "[idt, 'a, bool] => bool" ("(3\<exists>_\<ge>_./ _)" [0, 0, 10] 10) |
|
563 |
||
564 |
translations |
|
565 |
"ALL x<y. P" => "ALL x. x < y --> P" |
|
566 |
"EX x<y. P" => "EX x. x < y & P" |
|
567 |
"ALL x<=y. P" => "ALL x. x <= y --> P" |
|
568 |
"EX x<=y. P" => "EX x. x <= y & P" |
|
569 |
"ALL x>y. P" => "ALL x. x > y --> P" |
|
570 |
"EX x>y. P" => "EX x. x > y & P" |
|
571 |
"ALL x>=y. P" => "ALL x. x >= y --> P" |
|
572 |
"EX x>=y. P" => "EX x. x >= y & P" |
|
573 |
||
574 |
print_translation {* |
|
575 |
let |
|
576 |
fun mk v v' q n P = |
|
577 |
if v=v' andalso not(v mem (map fst (Term.add_frees([],n)))) |
|
578 |
then Syntax.const q $ Syntax.mark_bound v' $ n $ P else raise Match; |
|
579 |
fun all_tr' [Const ("_bound",_) $ Free (v,_), |
|
580 |
Const("op -->",_) $ (Const ("op <",_) $ (Const ("_bound",_) $ Free (v',_)) $ n ) $ P] = |
|
581 |
mk v v' "_lessAll" n P |
|
582 |
||
583 |
| all_tr' [Const ("_bound",_) $ Free (v,_), |
|
584 |
Const("op -->",_) $ (Const ("op <=",_) $ (Const ("_bound",_) $ Free (v',_)) $ n ) $ P] = |
|
585 |
mk v v' "_leAll" n P |
|
586 |
||
587 |
| all_tr' [Const ("_bound",_) $ Free (v,_), |
|
588 |
Const("op -->",_) $ (Const ("op <",_) $ n $ (Const ("_bound",_) $ Free (v',_))) $ P] = |
|
589 |
mk v v' "_gtAll" n P |
|
590 |
||
591 |
| all_tr' [Const ("_bound",_) $ Free (v,_), |
|
592 |
Const("op -->",_) $ (Const ("op <=",_) $ n $ (Const ("_bound",_) $ Free (v',_))) $ P] = |
|
593 |
mk v v' "_geAll" n P; |
|
594 |
||
595 |
fun ex_tr' [Const ("_bound",_) $ Free (v,_), |
|
596 |
Const("op &",_) $ (Const ("op <",_) $ (Const ("_bound",_) $ Free (v',_)) $ n ) $ P] = |
|
597 |
mk v v' "_lessEx" n P |
|
598 |
||
599 |
| ex_tr' [Const ("_bound",_) $ Free (v,_), |
|
600 |
Const("op &",_) $ (Const ("op <=",_) $ (Const ("_bound",_) $ Free (v',_)) $ n ) $ P] = |
|
601 |
mk v v' "_leEx" n P |
|
602 |
||
603 |
| ex_tr' [Const ("_bound",_) $ Free (v,_), |
|
604 |
Const("op &",_) $ (Const ("op <",_) $ n $ (Const ("_bound",_) $ Free (v',_))) $ P] = |
|
605 |
mk v v' "_gtEx" n P |
|
606 |
||
607 |
| ex_tr' [Const ("_bound",_) $ Free (v,_), |
|
608 |
Const("op &",_) $ (Const ("op <=",_) $ n $ (Const ("_bound",_) $ Free (v',_))) $ P] = |
|
609 |
mk v v' "_geEx" n P |
|
610 |
in |
|
611 |
[("ALL ", all_tr'), ("EX ", ex_tr')] |
|
612 |
end |
|
613 |
*} |
|
614 |
||
615 |
end |