wneuper/isa: src/Tools/isac/Knowledge/Integrate.thy@46fe5a8c3911 (annotated)

neuper@37906	1	(* integration over the reals
neuper@37906	2	author: Walther Neuper
neuper@37906	3	050814, 08:51
neuper@37906	4	(c) due to copyright terms
neuper@37906	5	*)
neuper@37906	6
neuper@37954	7	theory Integrate imports Diff begin
neuper@37906	8
neuper@37906	9	consts
neuper@37906	10
neuper@37906	11	Integral :: "[real, real]=> real" ("Integral _ D _" 91)
neuper@37906	12	(new'_c :: "real => real" ("new'_c _" 66))
neuper@37906	13	is'_f'_x :: "real => bool" ("_ is'_f'_x" 10)
neuper@37906	14
neuper@37906	15	(descriptions in the related problems)
neuper@37996	16	integrateBy :: "real => una"
neuper@37996	17	antiDerivative :: "real => una"
neuper@37996	18	antiDerivativeName :: "(real => real) => una"
neuper@37906	19
neuper@37906	20	(the CAS-command, eg. "Integrate (2x^^^3, x)"*)
neuper@37906	21	Integrate :: "[real * real] => real"
neuper@37906	22
neuper@52148	23	axiomatization where
neuper@37906	24	(*stated as axioms, todo: prove as theorems
neuper@37906	25	'bdv' is a constant handled on the meta-level
neuper@37906	26	specifically as a 'bound variable' *)
neuper@37906	27
neuper@52148	28	integral_const: "Not (bdv occurs_in u) ==> Integral u D bdv = u * bdv" and
neuper@52148	29	integral_var: "Integral bdv D bdv = bdv ^^^ 2 / 2" and
neuper@37906	30
neuper@37983	31	integral_add: "Integral (u + v) D bdv =
neuper@52148	32	(Integral u D bdv) + (Integral v D bdv)" and
neuper@37983	33	integral_mult: "[\| Not (bdv occurs_in u); bdv occurs_in v \|] ==>
neuper@52148	34	Integral (u * v) D bdv = u * (Integral v D bdv)" and
neuper@37906	35	(*WN080222: this goes into sub-terms, too ...
neuper@37983	36	call_for_new_c: "[\| Not (matches (u + new_c v) a); Not (a is_f_x) \|] ==>
neuper@37954	37	a = a + new_c a"
neuper@37906	38	*)
neuper@37983	39	integral_pow: "Integral bdv ^^^ n D bdv = bdv ^^^ (n+1) / (n + 1)"
neuper@37906	40
wneuper@59472	41	ML \<open>
neuper@37972	42	val thy = @{theory};
neuper@37972	43
neuper@37954	44	( eval functions )
neuper@37954	45
neuper@37954	46	val c = Free ("c", HOLogic.realT);
walther@59878	47	(*.create a new unique variable 'c..' in a term; for use by Rule.Eval in a rls;
neuper@37954	48	an alternative to do this would be '(Try (Calculate new_c_) (new_c es__))'
neuper@37954	49	in the script; this will be possible if currying doesnt take the value
neuper@37954	50	from a variable, but the value '(new_c es__)' itself.*)
neuper@37954	51	fun new_c term =
neuper@37954	52	let fun selc var =
neuper@40836	53	case (Symbol.explode o id_of) var of
neuper@37954	54	"c"::[] => true
walther@59875	55	\| "c"::"_"::is => (case (TermC.int_opt_of_string o implode) is of
neuper@37954	56	SOME _ => true
neuper@37954	57	\| NONE => false)
neuper@37954	58	\| _ => false;
neuper@40836	59	fun get_coeff c = case (Symbol.explode o id_of) c of
walther@59875	60	"c"::"_"::is => (the o TermC.int_opt_of_string o implode) is
neuper@37954	61	\| _ => 0;
wneuper@59389	62	val cs = filter selc (TermC.vars term);
neuper@37954	63	in
neuper@37954	64	case cs of
neuper@37954	65	[] => c
neuper@37954	66	\| [c] => Free ("c_2", HOLogic.realT)
neuper@37954	67	\| cs =>
neuper@37954	68	let val max_coeff = maxl (map get_coeff cs)
neuper@37954	69	in Free ("c_"^string_of_int (max_coeff + 1), HOLogic.realT) end
neuper@37954	70	end;
neuper@37954	71
neuper@37954	72	(*WN080222
neuper@37954	73	(("new_c", ("Integrate.new'_c", eval_new_c "#new_c_")))
neuper@37954	74	fun eval_new_c _ _ (p as (Const ("Integrate.new'_c",_) $ t)) _ =
walther@59868	75	SOME ((UnparseC.term p) ^ " = " ^ UnparseC.term (new_c p),
neuper@37954	76	Trueprop $ (mk_equality (p, new_c p)))
neuper@37954	77	\| eval_new_c _ _ _ _ = NONE;
neuper@37954	78	*)
neuper@37954	79
neuper@37954	80	(WN080222:)
neuper@37954	81	(*("add_new_c", ("Integrate.add'_new'_c", eval_add_new_c "#add_new_c_"))
neuper@37954	82	add a new c to a term or a fun-equation;
neuper@37954	83	this is _not in_ the term, because only applied to _whole_ term*)
neuper@37954	84	fun eval_add_new_c (_:string) "Integrate.add'_new'_c" p (_:theory) =
neuper@37954	85	let val p' = case p of
neuper@41922	86	Const ("HOL.eq", T) $ lh $ rh =>
wneuper@59389	87	Const ("HOL.eq", T) $ lh $ TermC.mk_add rh (new_c rh)
wneuper@59389	88	\| p => TermC.mk_add p (new_c p)
walther@59868	89	in SOME ((UnparseC.term p) ^ " = " ^ UnparseC.term p',
wneuper@59390	90	HOLogic.Trueprop $ (TermC.mk_equality (p, p')))
neuper@37954	91	end
neuper@37954	92	\| eval_add_new_c _ _ _ _ = NONE;
neuper@37954	93
neuper@37954	94
neuper@37954	95	(("is_f_x", ("Integrate.is'_f'_x", eval_is_f_x "is_f_x_")))
neuper@37954	96	fun eval_is_f_x _ _(p as (Const ("Integrate.is'_f'_x", _)
neuper@37954	97	$ arg)) _ =
wneuper@59389	98	if TermC.is_f_x arg
walther@59868	99	then SOME ((UnparseC.term p) ^ " = True",
wneuper@59390	100	HOLogic.Trueprop $ (TermC.mk_equality (p, @{term True})))
walther@59868	101	else SOME ((UnparseC.term p) ^ " = False",
wneuper@59390	102	HOLogic.Trueprop $ (TermC.mk_equality (p, @{term False})))
neuper@37954	103	\| eval_is_f_x _ _ _ _ = NONE;
wneuper@59472	104	\<close>
wneuper@59472	105	setup \<open>KEStore_Elems.add_calcs
s1210629013@52145	106	[("add_new_c", ("Integrate.add'_new'_c", eval_add_new_c "add_new_c_")),
wneuper@59472	107	("is_f_x", ("Integrate.is'_f'_x", eval_is_f_x "is_f_idextifier_"))]\<close>
wneuper@59472	108	ML \<open>
neuper@37954	109	( rulesets )
neuper@37954	110
neuper@37954	111	(.rulesets for integration.)
neuper@37954	112	val integration_rules =
walther@59851	113	Rule_Def.Repeat {id="integration_rules", preconds = [],
neuper@37954	114	rew_ord = ("termlessI",termlessI),
walther@59851	115	erls = Rule_Def.Repeat {id="conditions_in_integration_rules",
neuper@37954	116	preconds = [],
neuper@37954	117	rew_ord = ("termlessI",termlessI),
walther@59851	118	erls = Rule_Set.Empty,
walther@59851	119	srls = Rule_Set.Empty, calc = [], errpatts = [],
neuper@37954	120	rules = [(for rewriting conditions in Thm's)
walther@59878	121	Rule.Eval ("Prog_Expr.occurs'_in", Prog_Expr.eval_occurs_in "#occurs_in_"),
walther@59871	122	Rule.Thm ("not_true", ThmC.numerals_to_Free @{thm not_true}),
wneuper@59416	123	Rule.Thm ("not_false",@{thm not_false})
neuper@37954	124	],
walther@59878	125	scr = Rule.Empty_Prog},
walther@59851	126	srls = Rule_Set.Empty, calc = [], errpatts = [],
neuper@37954	127	rules = [
walther@59871	128	Rule.Thm ("integral_const", ThmC.numerals_to_Free @{thm integral_const}),
walther@59871	129	Rule.Thm ("integral_var", ThmC.numerals_to_Free @{thm integral_var}),
walther@59871	130	Rule.Thm ("integral_add", ThmC.numerals_to_Free @{thm integral_add}),
walther@59871	131	Rule.Thm ("integral_mult", ThmC.numerals_to_Free @{thm integral_mult}),
walther@59871	132	Rule.Thm ("integral_pow", ThmC.numerals_to_Free @{thm integral_pow}),
walther@59878	133	Rule.Eval ("Groups.plus_class.plus", (*)eval_binop "#add_")(for n+1*)
neuper@37954	134	],
walther@59878	135	scr = Rule.Empty_Prog};
wneuper@59472	136	\<close>
wneuper@59472	137	ML \<open>
neuper@37954	138	val add_new_c =
walther@59878	139	Rule_Set.Sequence {id="add_new_c", preconds = [],
neuper@37954	140	rew_ord = ("termlessI",termlessI),
walther@59851	141	erls = Rule_Def.Repeat {id="conditions_in_add_new_c",
neuper@37954	142	preconds = [],
neuper@37954	143	rew_ord = ("termlessI",termlessI),
walther@59851	144	erls = Rule_Set.Empty,
walther@59851	145	srls = Rule_Set.Empty, calc = [], errpatts = [],
walther@59878	146	rules = [Rule.Eval ("Prog_Expr.matches", Prog_Expr.eval_matches""),
walther@59878	147	Rule.Eval ("Integrate.is'_f'_x",
neuper@37954	148	eval_is_f_x "is_f_x_"),
walther@59871	149	Rule.Thm ("not_true", ThmC.numerals_to_Free @{thm not_true}),
walther@59871	150	Rule.Thm ("not_false", ThmC.numerals_to_Free @{thm not_false})
neuper@37954	151	],
walther@59878	152	scr = Rule.Empty_Prog},
walther@59851	153	srls = Rule_Set.Empty, calc = [], errpatts = [],
walther@59871	154	rules = [ (Rule.Thm ("call_for_new_c", ThmC.numerals_to_Free @{thm call_for_new_c}),)
wneuper@59416	155	Rule.Cal1 ("Integrate.add'_new'_c", eval_add_new_c "new_c_")
neuper@37954	156	],
walther@59878	157	scr = Rule.Empty_Prog};
wneuper@59472	158	\<close>
wneuper@59472	159	ML \<open>
neuper@37954	160
neuper@37954	161	(.rulesets for simplifying Integrals.)
neuper@37954	162
neuper@37954	163	(.for simplify_Integral adapted from 'norm_Rational_rls'.)
neuper@37954	164	val norm_Rational_rls_noadd_fractions =
walther@59851	165	Rule_Def.Repeat {id = "norm_Rational_rls_noadd_fractions", preconds = [],
walther@59857	166	rew_ord = ("dummy_ord",Rewrite_Ord.dummy_ord),
walther@59851	167	erls = norm_rat_erls, srls = Rule_Set.Empty, calc = [], errpatts = [],
wneuper@59416	168	rules = [(Rule.Rls_ add_fractions_p_rls,!!!)
wneuper@59416	169	Rule.Rls_ (rat_mult_div_pow original corrected WN051028)
walther@59851	170	(Rule_Def.Repeat {id = "rat_mult_div_pow", preconds = [],
walther@59857	171	rew_ord = ("dummy_ord",Rewrite_Ord.dummy_ord),
walther@59852	172	erls = (FIXME.WN051028 Rule_Set.empty,)
walther@59852	173	Rule_Set.append_rules "Rule_Set.empty-is_polyexp" Rule_Set.empty
walther@59878	174	[Rule.Eval ("Poly.is'_polyexp",
neuper@37954	175	eval_is_polyexp "")],
walther@59851	176	srls = Rule_Set.Empty, calc = [], errpatts = [],
walther@59871	177	rules = [Rule.Thm ("rat_mult", ThmC.numerals_to_Free @{thm rat_mult}),
neuper@37954	178	("?a / ?b (?c / ?d) = ?a * ?c / (?b * ?d)"*)
walther@59871	179	Rule.Thm ("rat_mult_poly_l", ThmC.numerals_to_Free @{thm rat_mult_poly_l}),
neuper@37954	180	("?c is_polyexp ==> ?c (?a / ?b) = ?c * ?a / ?b"*)
walther@59871	181	Rule.Thm ("rat_mult_poly_r", ThmC.numerals_to_Free @{thm rat_mult_poly_r}),
neuper@37954	182	("?c is_polyexp ==> ?a / ?b ?c = ?a * ?c / ?b"*)
neuper@37954	183
wneuper@59416	184	Rule.Thm ("real_divide_divide1_mg",
walther@59871	185	ThmC.numerals_to_Free @{thm real_divide_divide1_mg}),
neuper@37954	186	("y ~= 0 ==> (u / v) / (y / z) = (u z) / (y * v)"*)
wneuper@59416	187	Rule.Thm ("divide_divide_eq_right",
walther@59871	188	ThmC.numerals_to_Free @{thm divide_divide_eq_right}),
neuper@37954	189	("?x / (?y / ?z) = ?x ?z / ?y"*)
wneuper@59416	190	Rule.Thm ("divide_divide_eq_left",
walther@59871	191	ThmC.numerals_to_Free @{thm divide_divide_eq_left}),
neuper@37954	192	("?x / ?y / ?z = ?x / (?y ?z)"*)
walther@59878	193	Rule.Eval ("Rings.divide_class.divide", Prog_Expr.eval_cancel "#divide_e"),
neuper@37954	194
walther@59871	195	Rule.Thm ("rat_power", ThmC.numerals_to_Free @{thm rat_power})
neuper@37954	196	("(?a / ?b) ^^^ ?n = ?a ^^^ ?n / ?b ^^^ ?n")
neuper@37954	197	],
walther@59878	198	scr = Rule.Empty_Prog
neuper@37954	199	}),
wneuper@59416	200	Rule.Rls_ make_rat_poly_with_parentheses,
wneuper@59416	201	Rule.Rls_ cancel_p_rls,(FIXME:cancel_p does NOT order sometimes)
wneuper@59416	202	Rule.Rls_ rat_reduce_1
neuper@37954	203	],
walther@59878	204	scr = Rule.Empty_Prog
wneuper@59406	205	};
neuper@37954	206
neuper@37954	207	(.for simplify_Integral adapted from 'norm_Rational'.)
neuper@37954	208	val norm_Rational_noadd_fractions =
walther@59878	209	Rule_Set.Sequence {id = "norm_Rational_noadd_fractions", preconds = [],
walther@59857	210	rew_ord = ("dummy_ord",Rewrite_Ord.dummy_ord),
walther@59851	211	erls = norm_rat_erls, srls = Rule_Set.Empty, calc = [], errpatts = [],
wneuper@59416	212	rules = [Rule.Rls_ discard_minus,
wneuper@59416	213	Rule.Rls_ rat_mult_poly,(* removes double fractions like a/b/c *)
wneuper@59416	214	Rule.Rls_ make_rat_poly_with_parentheses, (WN0510 also in(#)below)
wneuper@59416	215	Rule.Rls_ cancel_p_rls, (FIXME.MG:cancel_p does NOT order sometim)
wneuper@59416	216	Rule.Rls_ norm_Rational_rls_noadd_fractions,(* the main rls (#) *)
wneuper@59416	217	Rule.Rls_ discard_parentheses1 (* mult only *)
neuper@37954	218	],
walther@59878	219	scr = Rule.Empty_Prog
wneuper@59406	220	};
neuper@37954	221
neuper@37954	222	(*.simplify terms before and after Integration such that
neuper@37954	223	..a.x^2/2 + b.x^3/3.. is made to ..a/2.x^2 + b/3.x^3.. (and NO
neuper@37954	224	common denominator as done by norm_Rational or make_ratpoly_in.
neuper@37954	225	This is a copy from 'make_ratpoly_in' with respective reduction of rules and
neuper@37954	226	1 expand the term, ie. distribute * and / over +
neuper@37954	227	.*)
neuper@37954	228	val separate_bdv2 =
walther@59852	229	Rule_Set.append_rules "separate_bdv2"
neuper@37954	230	collect_bdv
walther@59871	231	[Rule.Thm ("separate_bdv", ThmC.numerals_to_Free @{thm separate_bdv}),
neuper@37954	232	("?a ?bdv / ?b = ?a / ?b * ?bdv"*)
walther@59871	233	Rule.Thm ("separate_bdv_n", ThmC.numerals_to_Free @{thm separate_bdv_n}),
walther@59871	234	Rule.Thm ("separate_1_bdv", ThmC.numerals_to_Free @{thm separate_1_bdv}),
neuper@37954	235	("?bdv / ?b = (1 / ?b) ?bdv"*)
walther@59871	236	Rule.Thm ("separate_1_bdv_n", ThmC.numerals_to_Free @{thm separate_1_bdv_n})(*,
neuper@37954	237	("?bdv ^^^ ?n / ?b = 1 / ?b ?bdv ^^^ ?n"*)
wneuper@59416	238	*****Rule.Thm ("add_divide_distrib",
walther@59871	239	***** ThmC.numerals_to_Free @{thm add_divide_distrib})
neuper@37954	240	("(?x + ?y) / ?z = ?x / ?z + ?y / ?z")----------*)
neuper@37954	241	];
neuper@37954	242	val simplify_Integral =
walther@59878	243	Rule_Set.Sequence {id = "simplify_Integral", preconds = []:term list,
walther@59857	244	rew_ord = ("dummy_ord", Rewrite_Ord.dummy_ord),
walther@59851	245	erls = Atools_erls, srls = Rule_Set.Empty,
neuper@42451	246	calc = [], errpatts = [],
walther@59871	247	rules = [Rule.Thm ("distrib_right", ThmC.numerals_to_Free @{thm distrib_right}),
neuper@37954	248	("(?z1.0 + ?z2.0) ?w = ?z1.0 * ?w + ?z2.0 * ?w"*)
walther@59871	249	Rule.Thm ("add_divide_distrib", ThmC.numerals_to_Free @{thm add_divide_distrib}),
neuper@37954	250	("(?x + ?y) / ?z = ?x / ?z + ?y / ?z")
neuper@37954	251	(^^^^^ 1* ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^*)
wneuper@59416	252	Rule.Rls_ norm_Rational_noadd_fractions,
wneuper@59416	253	Rule.Rls_ order_add_mult_in,
wneuper@59416	254	Rule.Rls_ discard_parentheses,
wneuper@59416	255	(Rule.Rls_ collect_bdv, from make_polynomial_in)
wneuper@59416	256	Rule.Rls_ separate_bdv2,
walther@59878	257	Rule.Eval ("Rings.divide_class.divide", Prog_Expr.eval_cancel "#divide_e")
neuper@37954	258	],
walther@59878	259	scr = Rule.Empty_Prog};
neuper@37954	260
neuper@37954	261
neuper@37954	262	(*simplify terms before and after Integration such that
neuper@37954	263	..a.x^2/2 + b.x^3/3.. is made to ..a/2.x^2 + b/3.x^3.. (and NO
neuper@37954	264	common denominator as done by norm_Rational or make_ratpoly_in.
neuper@37954	265	This is a copy from 'make_polynomial_in' with insertions from
neuper@37954	266	'make_ratpoly_in'
neuper@37954	267	THIS IS KEPT FOR COMPARISON ............................................
s1210629013@55444	268	* val simplify_Integral = prep_rls'(
walther@59878	269	* Rule_Set.Sequence {id = "", preconds = []:term list,
walther@59857	270	* rew_ord = ("dummy_ord", Rewrite_Ord.dummy_ord),
walther@59851	271	* erls = Atools_erls, srls = Rule_Set.Empty,
neuper@37954	272	* calc = [], (asm_thm = [],)
wneuper@59416	273	* rules = [Rule.Rls_ expand_poly,
wneuper@59416	274	* Rule.Rls_ order_add_mult_in,
wneuper@59416	275	* Rule.Rls_ simplify_power,
wneuper@59416	276	* Rule.Rls_ collect_numerals,
wneuper@59416	277	* Rule.Rls_ reduce_012,
walther@59871	278	* Rule.Thm ("realpow_oneI", ThmC.numerals_to_Free @{thm realpow_oneI}),
wneuper@59416	279	* Rule.Rls_ discard_parentheses,
wneuper@59416	280	* Rule.Rls_ collect_bdv,
neuper@37954	281	* (below inserted from 'make_ratpoly_in')
walther@59852	282	* Rule.Rls_ (Rule_Set.append_rules "separate_bdv"
neuper@37954	283	* collect_bdv
walther@59871	284	* [Rule.Thm ("separate_bdv", ThmC.numerals_to_Free @{thm separate_bdv}),
neuper@37954	285	* ("?a ?bdv / ?b = ?a / ?b * ?bdv"*)
walther@59871	286	* Rule.Thm ("separate_bdv_n", ThmC.numerals_to_Free @{thm separate_bdv_n}),
walther@59871	287	* Rule.Thm ("separate_1_bdv", ThmC.numerals_to_Free @{thm separate_1_bdv}),
neuper@37954	288	* ("?bdv / ?b = (1 / ?b) ?bdv"*)
walther@59871	289	* Rule.Thm ("separate_1_bdv_n", ThmC.numerals_to_Free @{thm separate_1_bdv_n})(*,
neuper@37954	290	* ("?bdv ^^^ ?n / ?b = 1 / ?b ?bdv ^^^ ?n"*)
wneuper@59416	291	* Rule.Thm ("add_divide_distrib",
walther@59871	292	* ThmC.numerals_to_Free @{thm add_divide_distrib})
neuper@37954	293	* ("(?x + ?y) / ?z = ?x / ?z + ?y / ?z")*)
neuper@37954	294	* ]),
walther@59878	295	* Rule.Eval ("Rings.divide_class.divide" , eval_cancel "#divide_e")
neuper@37954	296	* ],
walther@59878	297	* scr = Rule.Empty_Prog
wneuper@59406	298	* });
neuper@37954	299	.......................................................................*)
neuper@37954	300
neuper@37954	301	val integration =
walther@59878	302	Rule_Set.Sequence {id="integration", preconds = [],
neuper@37954	303	rew_ord = ("termlessI",termlessI),
walther@59851	304	erls = Rule_Def.Repeat {id="conditions_in_integration",
neuper@37954	305	preconds = [],
neuper@37954	306	rew_ord = ("termlessI",termlessI),
walther@59851	307	erls = Rule_Set.Empty,
walther@59851	308	srls = Rule_Set.Empty, calc = [], errpatts = [],
neuper@37954	309	rules = [],
walther@59878	310	scr = Rule.Empty_Prog},
walther@59851	311	srls = Rule_Set.Empty, calc = [], errpatts = [],
wneuper@59416	312	rules = [ Rule.Rls_ integration_rules,
wneuper@59416	313	Rule.Rls_ add_new_c,
wneuper@59416	314	Rule.Rls_ simplify_Integral
neuper@37954	315	],
walther@59878	316	scr = Rule.Empty_Prog};
s1210629013@55444	317
walther@59618	318	val prep_rls' = Auto_Prog.prep_rls @{theory};
wneuper@59472	319	\<close>
wneuper@59472	320	setup \<open>KEStore_Elems.add_rlss
s1210629013@55444	321	[("integration_rules", (Context.theory_name @{theory}, prep_rls' integration_rules)),
s1210629013@55444	322	("add_new_c", (Context.theory_name @{theory}, prep_rls' add_new_c)),
s1210629013@55444	323	("simplify_Integral", (Context.theory_name @{theory}, prep_rls' simplify_Integral)),
s1210629013@55444	324	("integration", (Context.theory_name @{theory}, prep_rls' integration)),
s1210629013@55444	325	("separate_bdv2", (Context.theory_name @{theory}, prep_rls' separate_bdv2)),
neuper@52125	326
neuper@52125	327	("norm_Rational_noadd_fractions", (Context.theory_name @{theory},
s1210629013@55444	328	prep_rls' norm_Rational_noadd_fractions)),
neuper@52125	329	("norm_Rational_rls_noadd_fractions", (Context.theory_name @{theory},
wneuper@59472	330	prep_rls' norm_Rational_rls_noadd_fractions))]\<close>
neuper@37954	331
neuper@37954	332	( problems )
wneuper@59472	333	setup \<open>KEStore_Elems.add_pbts
walther@59973	334	[(Problem.prep_input thy "pbl_fun_integ" [] Problem.id_empty
walther@59997	335	(["integrate", "function"],
s1210629013@55339	336	[("#Given" ,["functionTerm f_f", "integrateBy v_v"]),
s1210629013@55339	337	("#Find" ,["antiDerivative F_F"])],
walther@59852	338	Rule_Set.append_rules "empty" Rule_Set.empty [(for preds in where_)],
s1210629013@55339	339	SOME "Integrate (f_f, v_v)",
walther@59997	340	[["diff", "integration"]])),
s1210629013@55339	341	(here "named" is used differently from Differentiation")
walther@59973	342	(Problem.prep_input thy "pbl_fun_integ_nam" [] Problem.id_empty
walther@59997	343	(["named", "integrate", "function"],
s1210629013@55339	344	[("#Given" ,["functionTerm f_f", "integrateBy v_v"]),
s1210629013@55339	345	("#Find" ,["antiDerivativeName F_F"])],
walther@59852	346	Rule_Set.append_rules "empty" Rule_Set.empty [(for preds in where_)],
s1210629013@55339	347	SOME "Integrate (f_f, v_v)",
walther@59997	348	[["diff", "integration", "named"]]))]\<close>
s1210629013@55380	349
neuper@37954	350	( methods )
wneuper@59545	351
wneuper@59504	352	partial_function (tailrec) integrate :: "real \<Rightarrow> real \<Rightarrow> real"
wneuper@59504	353	where
walther@59635	354	"integrate f_f v_v = (
walther@59635	355	let
walther@59635	356	t_t = Take (Integral f_f D v_v)
walther@59635	357	in
walther@59635	358	(Rewrite_Set_Inst [(''bdv'', v_v)] ''integration'') t_t)"
wneuper@59472	359	setup \<open>KEStore_Elems.add_mets
walther@59973	360	[Method.prep_input thy "met_diffint" [] Method.id_empty
walther@59997	361	(["diff", "integration"],
s1210629013@55373	362	[("#Given" ,["functionTerm f_f", "integrateBy v_v"]), ("#Find" ,["antiDerivative F_F"])],
walther@59852	363	{rew_ord'="tless_true", rls'=Atools_erls, calc = [], srls = Rule_Set.empty, prls=Rule_Set.empty,
walther@59852	364	crls = Atools_erls, errpats = [], nrls = Rule_Set.empty},
wneuper@59551	365	@{thm integrate.simps})]
wneuper@59473	366	\<close>
wneuper@59545	367
wneuper@59504	368	partial_function (tailrec) intergrate_named :: "real \<Rightarrow> real \<Rightarrow> (real \<Rightarrow> real) \<Rightarrow> bool"
walther@59635	369	where
walther@59635	370	"intergrate_named f_f v_v F_F =(
walther@59635	371	let
walther@59635	372	t_t = Take (F_F v_v = Integral f_f D v_v)
walther@59635	373	in (
walther@59637	374	(Try (Rewrite_Set_Inst [(''bdv'', v_v)] ''simplify_Integral'')) #>
walther@59635	375	(Rewrite_Set_Inst [(''bdv'', v_v)] ''integration'')
walther@59635	376	) t_t)"
wneuper@59473	377	setup \<open>KEStore_Elems.add_mets
walther@59973	378	[Method.prep_input thy "met_diffint_named" [] Method.id_empty
walther@59997	379	(["diff", "integration", "named"],
s1210629013@55373	380	[("#Given" ,["functionTerm f_f", "integrateBy v_v"]),
s1210629013@55373	381	("#Find" ,["antiDerivativeName F_F"])],
walther@59852	382	{rew_ord'="tless_true", rls'=Atools_erls, calc = [], srls = Rule_Set.empty, prls=Rule_Set.empty,
walther@59852	383	crls = Atools_erls, errpats = [], nrls = Rule_Set.empty},
wneuper@59551	384	@{thm intergrate_named.simps})]
wneuper@59472	385	\<close>
neuper@37954	386
neuper@37906	387	end

author	Walther Neuper <walther.neuper@jku.at>
	Wed, 20 May 2020 12:52:09 +0200
changeset 59997	46fe5a8c3911
parent 59973	8a46c2e7c27a
child 60154	2ab0d1523731
permissions	-rw-r--r--