Isabelle NEWS -- history user-relevant changes
==============================================
New in Isabelle2012 (May 2012)
------------------------------
*** General ***
* Prover IDE (PIDE) improvements:
- more robust Sledgehammer integration (as before the sledgehammer
command line needs to be typed into the source buffer)
- markup for bound variables
- markup for types of term variables (e.g. displayed as tooltips)
- support for user-defined Isar commands within the running session
- improved support for Unicode outside original 16bit range
e.g. glyph for \ (thanks to jEdit 4.5.1)
* Updated and extended reference manuals ("isar-ref" and
"implementation"); reduced remaining material in old "ref" manual.
* Rule attributes in local theory declarations (e.g. locale or class)
are now statically evaluated: the resulting theorem is stored instead
of the original expression. INCOMPATIBILITY in rare situations, where
the historic accident of dynamic re-evaluation in interpretations
etc. was exploited.
* Commands 'lemmas' and 'theorems' allow local variables using 'for'
declaration, and results are standardized before being stored. Thus
old-style "standard" after instantiation or composition of facts
becomes obsolete. Minor INCOMPATIBILITY, due to potential change of
indices of schematic variables.
* Renamed some inner syntax categories:
num ~> num_token
xnum ~> xnum_token
xstr ~> str_token
Minor INCOMPATIBILITY. Note that in practice "num_const" or
"num_position" etc. are mainly used instead (which also include
position information via constraints).
* Simplified configuration options for syntax ambiguity: see
"syntax_ambiguity_warning" and "syntax_ambiguity_limit" in isar-ref
manual. Minor INCOMPATIBILITY.
* Forward declaration of outer syntax keywords within the theory
header -- minor INCOMPATIBILITY for user-defined commands. Allow new
commands to be used in the same theory where defined.
*** Pure ***
* Auxiliary contexts indicate block structure for specifications with
additional parameters and assumptions. Such unnamed contexts may be
nested within other targets, like 'theory', 'locale', 'class',
'instantiation' etc. Results from the local context are generalized
accordingly and applied to the enclosing target context. Example:
context
fixes x y z :: 'a
assumes xy: "x = y" and yz: "y = z"
begin
lemma my_trans: "x = z" using xy yz by simp
end
thm my_trans
The most basic application is to factor-out context elements of
several fixes/assumes/shows theorem statements, e.g. see
~~/src/HOL/Isar_Examples/Group_Context.thy
Any other local theory specification element works within the "context
... begin ... end" block as well.
* Bundled declarations associate attributed fact expressions with a
given name in the context. These may be later included in other
contexts. This allows to manage context extensions casually, without
the logical dependencies of locales and locale interpretation.
See commands 'bundle', 'include', 'including' etc. in the isar-ref
manual.
* Rule composition via attribute "OF" (or ML functions OF/MRS) is more
tolerant against multiple unifiers, as long as the final result is
unique. (As before, rules are composed in canonical right-to-left
order to accommodate newly introduced premises.)
* Command 'definition' no longer exports the foundational "raw_def"
into the user context. Minor INCOMPATIBILITY, may use the regular
"def" result with attribute "abs_def" to imitate the old version.
* Attribute "abs_def" turns an equation of the form "f x y == t" into
"f == %x y. t", which ensures that "simp" or "unfold" steps always
expand it. This also works for object-logic equality. (Formerly
undocumented feature.)
* Discontinued old "prems" fact, which used to refer to the accidental
collection of foundational premises in the context (already marked as
legacy since Isabelle2011).
* Obsolete command 'types' has been discontinued. Use 'type_synonym'
instead. INCOMPATIBILITY.
* Old code generator for SML and its commands 'code_module',
'code_library', 'consts_code', 'types_code' have been discontinued.
Use commands of the generic code generator instead. INCOMPATIBILITY.
* Redundant attribute "code_inline" has been discontinued. Use
"code_unfold" instead. INCOMPATIBILITY.
* Dropped attribute "code_unfold_post" in favor of the its dual
"code_abbrev", which yields a common pattern in definitions like
definition [code_abbrev]: "f = t"
INCOMPATIBILITY.
* Sort constraints are now propagated in simultaneous statements, just
like type constraints. INCOMPATIBILITY in rare situations, where
distinct sorts used to be assigned accidentally. For example:
lemma "P (x::'a::foo)" and "Q (y::'a::bar)" -- "now illegal"
lemma "P (x::'a)" and "Q (y::'a::bar)"
-- "now uniform 'a::bar instead of default sort for first occurrence (!)"
*** HOL ***
* New tutorial "Programming and Proving in Isabelle/HOL" ("prog-prove").
It completely supercedes "A Tutorial Introduction to Structured Isar Proofs",
which has been removed. It supercedes "Isabelle/HOL, A Proof Assistant
for Higher-Order Logic" as the recommended beginners tutorial
but does not cover all of the material of that old tutorial.
* Discontinued old Tutorial on Isar ("isar-overview");
* Type 'a set is now a proper type constructor (just as before
Isabelle2008). Definitions mem_def and Collect_def have disappeared.
Non-trivial INCOMPATIBILITY. For developments keeping predicates and
sets separate, it is often sufficient to rephrase sets S accidentally
used as predicates by "%x. x : S" and predicates P accidentally used
as sets by "{x. P x}". Corresponding proofs in a first step should be
pruned from any tinkering with former theorems mem_def and Collect_def
as far as possible.
For developments which deliberately mixed predicates and sets, a
planning step is necessary to determine what should become a predicate
and what a set. It can be helpful to carry out that step in
Isabelle2011-1 before jumping right into the current release.
* The representation of numerals has changed. Datatype "num"
represents strictly positive binary numerals, along with functions
"numeral :: num => 'a" and "neg_numeral :: num => 'a" to represent
positive and negated numeric literals, respectively. (See definitions
in ~~/src/HOL/Num.thy.) Potential INCOMPATIBILITY, some user theories
may require adaptations as follows:
- Theorems with number_ring or number_semiring constraints: These
classes are gone; use comm_ring_1 or comm_semiring_1 instead.
- Theories defining numeric types: Remove number, number_semiring,
and number_ring instances. Defer all theorems about numerals until
after classes one and semigroup_add have been instantiated.
- Numeral-only simp rules: Replace each rule having a "number_of v"
pattern with two copies, one for numeral and one for neg_numeral.
- Theorems about subclasses of semiring_1 or ring_1: These classes
automatically support numerals now, so more simp rules and
simprocs may now apply within the proof.
- Definitions and theorems using old constructors Pls/Min/Bit0/Bit1:
Redefine using other integer operations.
* Code generation by default implements sets as container type rather
than predicates. INCOMPATIBILITY.
* New proof import from HOL Light: Faster, simpler, and more scalable.
Requires a proof bundle, which is available as an external component.
Discontinued old (and mostly dead) Importer for HOL4 and HOL Light.
INCOMPATIBILITY.
* New type synonym 'a rel = ('a * 'a) set
* More default pred/set conversions on a couple of relation operations
and predicates. Added powers of predicate relations. Consolidation
of some relation theorems:
converse_def ~> converse_unfold
rel_comp_def ~> relcomp_unfold
symp_def ~> (dropped, use symp_def and sym_def instead)
transp_def ~> transp_trans
Domain_def ~> Domain_unfold
Range_def ~> Domain_converse [symmetric]
Generalized theorems INF_INT_eq, INF_INT_eq2, SUP_UN_eq, SUP_UN_eq2.
See theory "Relation" for examples for making use of pred/set
conversions by means of attributes "to_set" and "to_pred".
INCOMPATIBILITY.
* Renamed facts about the power operation on relations, i.e., relpow
to match the constant's name:
rel_pow_1 ~> relpow_1
rel_pow_0_I ~> relpow_0_I
rel_pow_Suc_I ~> relpow_Suc_I
rel_pow_Suc_I2 ~> relpow_Suc_I2
rel_pow_0_E ~> relpow_0_E
rel_pow_Suc_E ~> relpow_Suc_E
rel_pow_E ~> relpow_E
rel_pow_Suc_D2 ~> relpow_Suc_D2
rel_pow_Suc_E2 ~> relpow_Suc_E2
rel_pow_Suc_D2' ~> relpow_Suc_D2'
rel_pow_E2 ~> relpow_E2
rel_pow_add ~> relpow_add
rel_pow_commute ~> relpow
rel_pow_empty ~> relpow_empty:
rtrancl_imp_UN_rel_pow ~> rtrancl_imp_UN_relpow
rel_pow_imp_rtrancl ~> relpow_imp_rtrancl
rtrancl_is_UN_rel_pow ~> rtrancl_is_UN_relpow
rtrancl_imp_rel_pow ~> rtrancl_imp_relpow
rel_pow_fun_conv ~> relpow_fun_conv
rel_pow_finite_bounded1 ~> relpow_finite_bounded1
rel_pow_finite_bounded ~> relpow_finite_bounded
rtrancl_finite_eq_rel_pow ~> rtrancl_finite_eq_relpow
trancl_finite_eq_rel_pow ~> trancl_finite_eq_relpow
single_valued_rel_pow ~> single_valued_relpow
INCOMPATIBILITY.
* Theory Relation: Consolidated constant name for relation composition
and corresponding theorem names:
- Renamed constant rel_comp to relcomp.
- Dropped abbreviation pred_comp. Use relcompp instead.
- Renamed theorems:
rel_compI ~> relcompI
rel_compEpair ~> relcompEpair
rel_compE ~> relcompE
pred_comp_rel_comp_eq ~> relcompp_relcomp_eq
rel_comp_empty1 ~> relcomp_empty1
rel_comp_mono ~> relcomp_mono
rel_comp_subset_Sigma ~> relcomp_subset_Sigma
rel_comp_distrib ~> relcomp_distrib
rel_comp_distrib2 ~> relcomp_distrib2
rel_comp_UNION_distrib ~> relcomp_UNION_distrib
rel_comp_UNION_distrib2 ~> relcomp_UNION_distrib2
single_valued_rel_comp ~> single_valued_relcomp
rel_comp_def ~> relcomp_unfold
converse_rel_comp ~> converse_relcomp
pred_compI ~> relcomppI
pred_compE ~> relcomppE
pred_comp_bot1 ~> relcompp_bot1
pred_comp_bot2 ~> relcompp_bot2
transp_pred_comp_less_eq ~> transp_relcompp_less_eq
pred_comp_mono ~> relcompp_mono
pred_comp_distrib ~> relcompp_distrib
pred_comp_distrib2 ~> relcompp_distrib2
converse_pred_comp ~> converse_relcompp
finite_rel_comp ~> finite_relcomp
set_rel_comp ~> set_relcomp
INCOMPATIBILITY.
* Theory Divides: Discontinued redundant theorems about div and mod.
INCOMPATIBILITY, use the corresponding generic theorems instead.
DIVISION_BY_ZERO ~> div_by_0, mod_by_0
zdiv_self ~> div_self
zmod_self ~> mod_self
zdiv_zero ~> div_0
zmod_zero ~> mod_0
zdiv_zmod_equality ~> div_mod_equality2
zdiv_zmod_equality2 ~> div_mod_equality
zmod_zdiv_trivial ~> mod_div_trivial
zdiv_zminus_zminus ~> div_minus_minus
zmod_zminus_zminus ~> mod_minus_minus
zdiv_zminus2 ~> div_minus_right
zmod_zminus2 ~> mod_minus_right
zdiv_minus1_right ~> div_minus1_right
zmod_minus1_right ~> mod_minus1_right
zdvd_mult_div_cancel ~> dvd_mult_div_cancel
zmod_zmult1_eq ~> mod_mult_right_eq
zpower_zmod ~> power_mod
zdvd_zmod ~> dvd_mod
zdvd_zmod_imp_zdvd ~> dvd_mod_imp_dvd
mod_mult_distrib ~> mult_mod_left
mod_mult_distrib2 ~> mult_mod_right
* Removed redundant theorems nat_mult_2 and nat_mult_2_right; use
generic mult_2 and mult_2_right instead. INCOMPATIBILITY.
* Finite_Set.fold now qualified. INCOMPATIBILITY.
* Consolidated theorem names concerning fold combinators:
inf_INFI_fold_inf ~> inf_INF_fold_inf
sup_SUPR_fold_sup ~> sup_SUP_fold_sup
INFI_fold_inf ~> INF_fold_inf
SUPR_fold_sup ~> SUP_fold_sup
union_set ~> union_set_fold
minus_set ~> minus_set_fold
INFI_set_fold ~> INF_set_fold
SUPR_set_fold ~> SUP_set_fold
INF_code ~> INF_set_foldr
SUP_code ~> SUP_set_foldr
foldr.simps ~> foldr.simps (in point-free formulation)
foldr_fold_rev ~> foldr_conv_fold
foldl_fold ~> foldl_conv_fold
foldr_foldr ~> foldr_conv_foldl
foldl_foldr ~> foldl_conv_foldr
fold_set_remdups ~> fold_set_fold_remdups
fold_set ~> fold_set_fold
fold1_set ~> fold1_set_fold
INCOMPATIBILITY.
* Dropped rarely useful theorems concerning fold combinators:
foldl_apply, foldl_fun_comm, foldl_rev, fold_weak_invariant,
rev_foldl_cons, fold_set_remdups, fold_set, fold_set1,
concat_conv_foldl, foldl_weak_invariant, foldl_invariant,
foldr_invariant, foldl_absorb0, foldl_foldr1_lemma, foldl_foldr1,
listsum_conv_fold, listsum_foldl, sort_foldl_insort, foldl_assoc,
foldr_conv_foldl, start_le_sum, elem_le_sum, sum_eq_0_conv.
INCOMPATIBILITY. For the common phrases "%xs. List.foldr plus xs 0"
and "List.foldl plus 0", prefer "List.listsum". Otherwise it can be
useful to boil down "List.foldr" and "List.foldl" to "List.fold" by
unfolding "foldr_conv_fold" and "foldl_conv_fold".
* Dropped lemmas minus_set_foldr, union_set_foldr, union_coset_foldr,
inter_coset_foldr, Inf_fin_set_foldr, Sup_fin_set_foldr,
Min_fin_set_foldr, Max_fin_set_foldr, Inf_set_foldr, Sup_set_foldr,
INF_set_foldr, SUP_set_foldr. INCOMPATIBILITY. Prefer corresponding
lemmas over fold rather than foldr, or make use of lemmas
fold_conv_foldr and fold_rev.
* Congruence rules Option.map_cong and Option.bind_cong for recursion
through option types.
* Concrete syntax for case expressions includes constraints for source
positions, and thus produces Prover IDE markup for its bindings.
INCOMPATIBILITY for old-style syntax translations that augment the
pattern notation; e.g. see src/HOL/HOLCF/One.thy for translations of
one_case.
* Discontinued configuration option "syntax_positions": atomic terms
in parse trees are always annotated by position constraints.
* New theory HOL/Library/DAList provides an abstract type for
association lists with distinct keys.
* 'datatype' specifications allow explicit sort constraints.
* Theory HOL/Library/Diagonalize has been removed. INCOMPATIBILITY,
use theory HOL/Library/Nat_Bijection instead.
* Theory HOL/Library/RBT_Impl: Backing implementation of red-black
trees is now inside a type class context. Names of affected
operations and lemmas have been prefixed by rbt_. INCOMPATIBILITY for
theories working directly with raw red-black trees, adapt the names as
follows:
Operations:
bulkload -> rbt_bulkload
del_from_left -> rbt_del_from_left
del_from_right -> rbt_del_from_right
del -> rbt_del
delete -> rbt_delete
ins -> rbt_ins
insert -> rbt_insert
insertw -> rbt_insert_with
insert_with_key -> rbt_insert_with_key
map_entry -> rbt_map_entry
lookup -> rbt_lookup
sorted -> rbt_sorted
tree_greater -> rbt_greater
tree_less -> rbt_less
tree_less_symbol -> rbt_less_symbol
union -> rbt_union
union_with -> rbt_union_with
union_with_key -> rbt_union_with_key
Lemmas:
balance_left_sorted -> balance_left_rbt_sorted
balance_left_tree_greater -> balance_left_rbt_greater
balance_left_tree_less -> balance_left_rbt_less
balance_right_sorted -> balance_right_rbt_sorted
balance_right_tree_greater -> balance_right_rbt_greater
balance_right_tree_less -> balance_right_rbt_less
balance_sorted -> balance_rbt_sorted
balance_tree_greater -> balance_rbt_greater
balance_tree_less -> balance_rbt_less
bulkload_is_rbt -> rbt_bulkload_is_rbt
combine_sorted -> combine_rbt_sorted
combine_tree_greater -> combine_rbt_greater
combine_tree_less -> combine_rbt_less
delete_in_tree -> rbt_delete_in_tree
delete_is_rbt -> rbt_delete_is_rbt
del_from_left_tree_greater -> rbt_del_from_left_rbt_greater
del_from_left_tree_less -> rbt_del_from_left_rbt_less
del_from_right_tree_greater -> rbt_del_from_right_rbt_greater
del_from_right_tree_less -> rbt_del_from_right_rbt_less
del_in_tree -> rbt_del_in_tree
del_inv1_inv2 -> rbt_del_inv1_inv2
del_sorted -> rbt_del_rbt_sorted
del_tree_greater -> rbt_del_rbt_greater
del_tree_less -> rbt_del_rbt_less
dom_lookup_Branch -> dom_rbt_lookup_Branch
entries_lookup -> entries_rbt_lookup
finite_dom_lookup -> finite_dom_rbt_lookup
insert_sorted -> rbt_insert_rbt_sorted
insertw_is_rbt -> rbt_insertw_is_rbt
insertwk_is_rbt -> rbt_insertwk_is_rbt
insertwk_sorted -> rbt_insertwk_rbt_sorted
insertw_sorted -> rbt_insertw_rbt_sorted
ins_sorted -> ins_rbt_sorted
ins_tree_greater -> ins_rbt_greater
ins_tree_less -> ins_rbt_less
is_rbt_sorted -> is_rbt_rbt_sorted
lookup_balance -> rbt_lookup_balance
lookup_bulkload -> rbt_lookup_rbt_bulkload
lookup_delete -> rbt_lookup_rbt_delete
lookup_Empty -> rbt_lookup_Empty
lookup_from_in_tree -> rbt_lookup_from_in_tree
lookup_in_tree -> rbt_lookup_in_tree
lookup_ins -> rbt_lookup_ins
lookup_insert -> rbt_lookup_rbt_insert
lookup_insertw -> rbt_lookup_rbt_insertw
lookup_insertwk -> rbt_lookup_rbt_insertwk
lookup_keys -> rbt_lookup_keys
lookup_map -> rbt_lookup_map
lookup_map_entry -> rbt_lookup_rbt_map_entry
lookup_tree_greater -> rbt_lookup_rbt_greater
lookup_tree_less -> rbt_lookup_rbt_less
lookup_union -> rbt_lookup_rbt_union
map_entry_color_of -> rbt_map_entry_color_of
map_entry_inv1 -> rbt_map_entry_inv1
map_entry_inv2 -> rbt_map_entry_inv2
map_entry_is_rbt -> rbt_map_entry_is_rbt
map_entry_sorted -> rbt_map_entry_rbt_sorted
map_entry_tree_greater -> rbt_map_entry_rbt_greater
map_entry_tree_less -> rbt_map_entry_rbt_less
map_tree_greater -> map_rbt_greater
map_tree_less -> map_rbt_less
map_sorted -> map_rbt_sorted
paint_sorted -> paint_rbt_sorted
paint_lookup -> paint_rbt_lookup
paint_tree_greater -> paint_rbt_greater
paint_tree_less -> paint_rbt_less
sorted_entries -> rbt_sorted_entries
tree_greater_eq_trans -> rbt_greater_eq_trans
tree_greater_nit -> rbt_greater_nit
tree_greater_prop -> rbt_greater_prop
tree_greater_simps -> rbt_greater_simps
tree_greater_trans -> rbt_greater_trans
tree_less_eq_trans -> rbt_less_eq_trans
tree_less_nit -> rbt_less_nit
tree_less_prop -> rbt_less_prop
tree_less_simps -> rbt_less_simps
tree_less_trans -> rbt_less_trans
tree_ord_props -> rbt_ord_props
union_Branch -> rbt_union_Branch
union_is_rbt -> rbt_union_is_rbt
unionw_is_rbt -> rbt_unionw_is_rbt
unionwk_is_rbt -> rbt_unionwk_is_rbt
unionwk_sorted -> rbt_unionwk_rbt_sorted
* Theory HOL/Library/Float: Floating point numbers are now defined as a
subset of the real numbers. All operations are defined using the
lifing-framework and proofs use the transfer method.
INCOMPATIBILITY.
Changed Operations:
float_abs -> abs
float_nprt -> nprt
float_pprt -> pprt
pow2 -> use powr
round_down -> float_round_down
round_up -> float_round_up
scale -> exponent
Removed Operations:
ceiling_fl, lb_mult, lb_mod, ub_mult, ub_mod
Renamed Lemmas:
abs_float_def -> Float.compute_float_abs
bitlen_ge0 -> bitlen_nonneg
bitlen.simps -> Float.compute_bitlen
float_components -> Float_mantissa_exponent
float_divl.simps -> Float.compute_float_divl
float_divr.simps -> Float.compute_float_divr
float_eq_odd -> mult_powr_eq_mult_powr_iff
float_power -> real_of_float_power
lapprox_posrat_def -> Float.compute_lapprox_posrat
lapprox_rat.simps -> Float.compute_lapprox_rat
le_float_def' -> Float.compute_float_le
le_float_def -> less_eq_float.rep_eq
less_float_def' -> Float.compute_float_less
less_float_def -> less_float.rep_eq
normfloat_def -> Float.compute_normfloat
normfloat_imp_odd_or_zero -> mantissa_not_dvd and mantissa_noteq_0
normfloat -> normfloat_def
normfloat_unique -> use normfloat_def
number_of_float_Float -> Float.compute_float_numeral, Float.compute_float_neg_numeral
one_float_def -> Float.compute_float_one
plus_float_def -> Float.compute_float_plus
rapprox_posrat_def -> Float.compute_rapprox_posrat
rapprox_rat.simps -> Float.compute_rapprox_rat
real_of_float_0 -> zero_float.rep_eq
real_of_float_1 -> one_float.rep_eq
real_of_float_abs -> abs_float.rep_eq
real_of_float_add -> plus_float.rep_eq
real_of_float_minus -> uminus_float.rep_eq
real_of_float_mult -> times_float.rep_eq
real_of_float_simp -> Float.rep_eq
real_of_float_sub -> minus_float.rep_eq
round_down.simps -> Float.compute_float_round_down
round_up.simps -> Float.compute_float_round_up
times_float_def -> Float.compute_float_times
uminus_float_def -> Float.compute_float_uminus
zero_float_def -> Float.compute_float_zero
Lemmas not necessary anymore, use the transfer method:
bitlen_B0, bitlen_B1, bitlen_ge1, bitlen_Min, bitlen_Pls, float_divl,
float_divr, float_le_simp, float_less1_mantissa_bound,
float_less_simp, float_less_zero, float_le_zero,
float_pos_less1_e_neg, float_pos_m_pos, float_split, float_split2,
floor_pos_exp, lapprox_posrat, lapprox_posrat_bottom, lapprox_rat,
lapprox_rat_bottom, normalized_float, rapprox_posrat,
rapprox_posrat_le1, rapprox_rat, real_of_float_ge0_exp,
real_of_float_neg_exp, real_of_float_nge0_exp, round_down floor_fl,
round_up, zero_le_float, zero_less_float
* Session HOL-Word: Discontinued many redundant theorems specific to
type 'a word. INCOMPATIBILITY, use the corresponding generic theorems
instead.
word_sub_alt ~> word_sub_wi
word_add_alt ~> word_add_def
word_mult_alt ~> word_mult_def
word_minus_alt ~> word_minus_def
word_0_alt ~> word_0_wi
word_1_alt ~> word_1_wi
word_add_0 ~> add_0_left
word_add_0_right ~> add_0_right
word_mult_1 ~> mult_1_left
word_mult_1_right ~> mult_1_right
word_add_commute ~> add_commute
word_add_assoc ~> add_assoc
word_add_left_commute ~> add_left_commute
word_mult_commute ~> mult_commute
word_mult_assoc ~> mult_assoc
word_mult_left_commute ~> mult_left_commute
word_left_distrib ~> left_distrib
word_right_distrib ~> right_distrib
word_left_minus ~> left_minus
word_diff_0_right ~> diff_0_right
word_diff_self ~> diff_self
word_sub_def ~> diff_minus
word_diff_minus ~> diff_minus
word_add_ac ~> add_ac
word_mult_ac ~> mult_ac
word_plus_ac0 ~> add_0_left add_0_right add_ac
word_times_ac1 ~> mult_1_left mult_1_right mult_ac
word_order_trans ~> order_trans
word_order_refl ~> order_refl
word_order_antisym ~> order_antisym
word_order_linear ~> linorder_linear
lenw1_zero_neq_one ~> zero_neq_one
word_number_of_eq ~> number_of_eq
word_of_int_add_hom ~> wi_hom_add
word_of_int_sub_hom ~> wi_hom_sub
word_of_int_mult_hom ~> wi_hom_mult
word_of_int_minus_hom ~> wi_hom_neg
word_of_int_succ_hom ~> wi_hom_succ
word_of_int_pred_hom ~> wi_hom_pred
word_of_int_0_hom ~> word_0_wi
word_of_int_1_hom ~> word_1_wi
* New tactic "word_bitwise" for splitting machine word equalities and
inequalities into logical circuits. Requires theory "WordBitwise" from HOL-Word
session. Supports addition, subtraction, multiplication, shifting by
constants, bitwise operators and numeric constants. Requires fixed-length word
types, cannot operate on 'a word. Solves many standard word identies outright
and converts more into first order problems amenable to blast or similar. See
HOL/Word/WordBitwise.thy and examples in HOL/Word/Examples/WordExamples.thy.
* Clarified attribute "mono_set": pure declaration without modifying
the result of the fact expression.
* "Transitive_Closure.ntrancl": bounded transitive closure on
relations.
* Constant "Set.not_member" now qualified. INCOMPATIBILITY.
* Theory Int: Discontinued many legacy theorems specific to type int.
INCOMPATIBILITY, use the corresponding generic theorems instead.
zminus_zminus ~> minus_minus
zminus_0 ~> minus_zero
zminus_zadd_distrib ~> minus_add_distrib
zadd_commute ~> add_commute
zadd_assoc ~> add_assoc
zadd_left_commute ~> add_left_commute
zadd_ac ~> add_ac
zmult_ac ~> mult_ac
zadd_0 ~> add_0_left
zadd_0_right ~> add_0_right
zadd_zminus_inverse2 ~> left_minus
zmult_zminus ~> mult_minus_left
zmult_commute ~> mult_commute
zmult_assoc ~> mult_assoc
zadd_zmult_distrib ~> left_distrib
zadd_zmult_distrib2 ~> right_distrib
zdiff_zmult_distrib ~> left_diff_distrib
zdiff_zmult_distrib2 ~> right_diff_distrib
zmult_1 ~> mult_1_left
zmult_1_right ~> mult_1_right
zle_refl ~> order_refl
zle_trans ~> order_trans
zle_antisym ~> order_antisym
zle_linear ~> linorder_linear
zless_linear ~> linorder_less_linear
zadd_left_mono ~> add_left_mono
zadd_strict_right_mono ~> add_strict_right_mono
zadd_zless_mono ~> add_less_le_mono
int_0_less_1 ~> zero_less_one
int_0_neq_1 ~> zero_neq_one
zless_le ~> less_le
zpower_zadd_distrib ~> power_add
zero_less_zpower_abs_iff ~> zero_less_power_abs_iff
zero_le_zpower_abs ~> zero_le_power_abs
* Theory Deriv: Renamed
DERIV_nonneg_imp_nonincreasing ~> DERIV_nonneg_imp_nondecreasing
* Theory Library/Multiset: Improved code generation of multisets.
* Session HOL-Probability: Introduced the type "'a measure" to represent
measures, this replaces the records 'a algebra and 'a measure_space. The
locales based on subset_class now have two locale-parameters the space
\ and the set of measurables sets M. The product of probability spaces
uses now the same constant as the finite product of sigma-finite measure
spaces "PiM :: ('i => 'a) measure". Most constants are defined now
outside of locales and gain an additional parameter, like null_sets,
almost_eventually or \'. Measure space constructions for distributions
and densities now got their own constants distr and density. Instead of
using locales to describe measure spaces with a finite space, the
measure count_space and point_measure is introduced. INCOMPATIBILITY.
Renamed constants:
measure -> emeasure
finite_measure.\' -> measure
product_algebra_generator -> prod_algebra
product_prob_space.emb -> prod_emb
product_prob_space.infprod_algebra -> PiM
Removed locales:
completeable_measure_space
finite_measure_space
finite_prob_space
finite_product_finite_prob_space
finite_product_sigma_algebra
finite_sigma_algebra
measure_space
pair_finite_prob_space
pair_finite_sigma_algebra
pair_finite_space
pair_sigma_algebra
product_sigma_algebra
Removed constants:
distribution -> use distr measure, or distributed predicate
joint_distribution -> use distr measure, or distributed predicate
product_prob_space.infprod_algebra -> use PiM
subvimage
image_space
conditional_space
pair_measure_generator
Replacement theorems:
sigma_algebra.measurable_sigma -> measurable_measure_of
measure_space.additive -> emeasure_additive
measure_space.measure_additive -> plus_emeasure
measure_space.measure_mono -> emeasure_mono
measure_space.measure_top -> emeasure_space
measure_space.measure_compl -> emeasure_compl
measure_space.measure_Diff -> emeasure_Diff
measure_space.measure_countable_increasing -> emeasure_countable_increasing
measure_space.continuity_from_below -> SUP_emeasure_incseq
measure_space.measure_incseq -> incseq_emeasure
measure_space.continuity_from_below_Lim -> Lim_emeasure_incseq
measure_space.measure_decseq -> decseq_emeasure
measure_space.continuity_from_above -> INF_emeasure_decseq
measure_space.measure_insert -> emeasure_insert
measure_space.measure_setsum -> setsum_emeasure
measure_space.measure_finite_singleton -> emeasure_eq_setsum_singleton
finite_additivity_sufficient -> ring_of_sets.countably_additiveI_finite
measure_space.measure_setsum_split -> setsum_emeasure_cover
measure_space.measure_subadditive -> subadditive
measure_space.measure_subadditive_finite -> emeasure_subadditive_finite
measure_space.measure_eq_0 -> emeasure_eq_0
measure_space.measure_finitely_subadditive -> emeasure_subadditive_finite
measure_space.measure_countably_subadditive -> emeasure_subadditive_countably
measure_space.measure_UN_eq_0 -> emeasure_UN_eq_0
measure_unique_Int_stable -> measure_eqI_generator_eq
measure_space.measure_Diff_null_set -> emeasure_Diff_null_set
measure_space.measure_Un_null_set -> emeasure_Un_null_set
measure_space.almost_everywhere_def -> eventually_ae_filter
measure_space.almost_everywhere_vimage -> AE_distrD
measure_space.measure_space_vimage -> emeasure_distr
measure_space.AE_iff_null_set -> AE_iff_null
measure_space.real_measure_Union -> measure_Union
measure_space.real_measure_finite_Union -> measure_finite_Union
measure_space.real_measure_Diff -> measure_Diff
measure_space.real_measure_UNION -> measure_UNION
measure_space.real_measure_subadditive -> measure_subadditive
measure_space.real_measure_setsum_singleton -> measure_eq_setsum_singleton
measure_space.real_continuity_from_below -> Lim_measure_incseq
measure_space.continuity_from_above_Lim -> Lim_emeasure_decseq
measure_space.real_continuity_from_above -> Lim_measure_decseq
measure_space.real_measure_countably_subadditive -> measure_subadditive_countably
finite_measure.finite_measure -> finite_measure.emeasure_finite
finite_measure.finite_measure_eq -> finite_measure.emeasure_eq_measure
finite_measure.positive_measure' -> measure_nonneg
finite_measure.real_measure -> finite_measure.emeasure_real
finite_measure.empty_measure -> measure_empty
finite_measure.finite_measure_countably_subadditive -> finite_measure.finite_measure_subadditive_countably
finite_measure.finite_measure_finite_singleton -> finite_measure.finite_measure_eq_setsum_singleton
finite_measure.finite_continuity_from_below -> finite_measure.finite_Lim_measure_incseq
finite_measure.finite_continuity_from_above -> finite_measure.finite_Lim_measure_decseq
measure_space.simple_integral_vimage -> simple_integral_distr
measure_space.integrable_vimage -> integrable_distr
measure_space.positive_integral_translated_density -> positive_integral_density
measure_space.integral_translated_density -> integral_density
measure_space.integral_vimage -> integral_distr
measure_space_density -> emeasure_density
measure_space.positive_integral_vimage -> positive_integral_distr
measure_space.simple_function_vimage -> simple_function_comp
measure_space.simple_integral_vimage -> simple_integral_distr
pair_sigma_algebra.measurable_cut_fst -> sets_Pair1
pair_sigma_algebra.measurable_cut_snd -> sets_Pair2
pair_sigma_algebra.measurable_pair_image_fst -> measurable_Pair1
pair_sigma_algebra.measurable_pair_image_snd -> measurable_Pair2
pair_sigma_algebra.measurable_product_swap -> measurable_pair_swap_iff
pair_sigma_finite.measure_cut_measurable_fst -> pair_sigma_finite.measurable_emeasure_Pair1
pair_sigma_finite.measure_cut_measurable_snd -> pair_sigma_finite.measurable_emeasure_Pair2
measure_space.measure_not_negative -> emeasure_not_MInf
pair_sigma_finite.measure_preserving_swap -> pair_sigma_finite.distr_pair_swap
pair_sigma_finite.pair_measure_alt -> pair_sigma_finite.emeasure_pair_measure_alt
pair_sigma_finite.pair_measure_alt2 -> pair_sigma_finite.emeasure_pair_measure_alt2
pair_sigma_finite.pair_measure_times -> pair_sigma_finite.emeasure_pair_measure_Times
pair_sigma_algebra.pair_sigma_algebra_measurable -> measurable_pair_swap
pair_sigma_algebra.pair_sigma_algebra_swap_measurable -> measurable_pair_swap'
pair_sigma_algebra.sets_swap -> sets_pair_swap
finite_product_sigma_algebra.in_P -> sets_PiM_I_finite
Int_stable_product_algebra_generator -> positive_integral
product_sigma_finite.measure_fold -> product_sigma_finite.distr_merge
product_sigma_finite.measure_preserving_component_singelton -> product_sigma_finite.distr_singleton
product_sigma_finite.measure_preserving_merge -> product_sigma_finite.distr_merge
finite_product_sigma_algebra.P_empty -> space_PiM_empty, sets_PiM_empty
product_algebra_generator_der -> prod_algebra_eq_finite
product_algebra_generator_into_space -> prod_algebra_sets_into_space
product_sigma_algebra.product_algebra_into_space -> space_closed
product_algebraE -> prod_algebraE_all
product_algebraI -> sets_PiM_I_finite
product_measure_exists -> product_sigma_finite.sigma_finite
sets_product_algebra -> sets_PiM
sigma_product_algebra_sigma_eq -> sigma_prod_algebra_sigma_eq
space_product_algebra -> space_PiM
Int_stable_cuboids -> Int_stable_atLeastAtMost
measure_space.density_is_absolutely_continuous -> absolutely_continuousI_density
sigma_finite_measure.RN_deriv_vimage -> sigma_finite_measure.RN_deriv_distr
prob_space_unique_Int_stable -> measure_eqI_prob_space
sigma_finite_measure.disjoint_sigma_finite -> sigma_finite_disjoint
prob_space.measure_space_1 -> prob_space.emeasure_space_1
prob_space.prob_space_vimage -> prob_space_distr
prob_space.random_variable_restrict -> measurable_restrict
measure_preserving -> equality "distr M N f = N" "f : measurable M N"
measure_unique_Int_stable_vimage -> measure_eqI_generator_eq
measure_space.measure_preserving_Int_stable -> measure_eqI_generator_eq
product_prob_space.finite_index_eq_finite_product -> product_prob_space.sets_PiM_generator
product_prob_space.finite_measure_infprod_emb_Pi -> product_prob_space.measure_PiM_emb
finite_product_prob_space.finite_measure_times -> finite_product_prob_space.finite_measure_PiM_emb
product_prob_space.infprod_spec -> product_prob_space.emeasure_PiM_emb_not_empty
product_prob_space.measurable_component -> measurable_component_singleton
product_prob_space.measurable_emb -> measurable_prod_emb
product_prob_space.measurable_into_infprod_algebra -> measurable_PiM_single
product_prob_space.measurable_singleton_infprod -> measurable_component_singleton
product_prob_space.measure_emb -> emeasure_prod_emb
sequence_space.measure_infprod -> sequence_space.measure_PiM_countable
product_prob_space.measure_preserving_restrict -> product_prob_space.distr_restrict
prob_space.indep_distribution_eq_measure -> prob_space.indep_vars_iff_distr_eq_PiM
prob_space.indep_var_distributionD -> prob_space.indep_var_distribution_eq
conditional_entropy_positive -> conditional_entropy_nonneg_simple
conditional_entropy_eq -> conditional_entropy_simple_distributed
conditional_mutual_information_eq_mutual_information -> conditional_mutual_information_eq_mutual_information_simple
conditional_mutual_information_generic_positive -> conditional_mutual_information_nonneg_simple
conditional_mutual_information_positive -> conditional_mutual_information_nonneg_simple
entropy_commute -> entropy_commute_simple
entropy_eq -> entropy_simple_distributed
entropy_generic_eq -> entropy_simple_distributed
entropy_positive -> entropy_nonneg_simple
entropy_uniform_max -> entropy_uniform
KL_eq_0 -> KL_same_eq_0
KL_eq_0_imp -> KL_eq_0_iff_eq
KL_ge_0 -> KL_nonneg
mutual_information_eq -> mutual_information_simple_distributed
mutual_information_positive -> mutual_information_nonneg_simple
* New "case_product" attribute to generate a case rule doing multiple
case distinctions at the same time. E.g.
list.exhaust [case_product nat.exhaust]
produces a rule which can be used to perform case distinction on both
a list and a nat.
* New Transfer package:
- transfer_rule attribute: Maintains a collection of transfer rules,
which relate constants at two different types. Transfer rules may
relate different type instances of the same polymorphic constant,
or they may relate an operation on a raw type to a corresponding
operation on an abstract type (quotient or subtype). For example:
((A ===> B) ===> list_all2 A ===> list_all2 B) map map
(cr_int ===> cr_int ===> cr_int) (%(x,y) (u,v). (x+u, y+v)) plus_int
- transfer method: Replaces a subgoal on abstract types with an
equivalent subgoal on the corresponding raw types. Constants are
replaced with corresponding ones according to the transfer rules.
Goals are generalized over all free variables by default; this is
necessary for variables whose types changes, but can be overridden
for specific variables with e.g. 'transfer fixing: x y z'.
The variant transfer' method allows replacing a subgoal with
one that is logically stronger (rather than equivalent).
- relator_eq attribute: Collects identity laws for relators of
various type constructors, e.g. "list_all2 (op =) = (op =)". The
transfer method uses these lemmas to infer transfer rules for
non-polymorphic constants on the fly.
- transfer_prover method: Assists with proving a transfer rule for a
new constant, provided the constant is defined in terms of other
constants that already have transfer rules. It should be applied
after unfolding the constant definitions.
- HOL/ex/Transfer_Int_Nat.thy: Example theory demonstrating transfer
from type nat to type int.
* New Lifting package:
- lift_definition command: Defines operations on an abstract type in
terms of a corresponding operation on a representation type. Example
syntax:
lift_definition dlist_insert :: "'a => 'a dlist => 'a dlist"
is List.insert
Users must discharge a respectfulness proof obligation when each
constant is defined. (For a type copy, i.e. a typedef with UNIV,
the proof is discharged automatically.) The obligation is
presented in a user-friendly, readable form; a respectfulness
theorem in the standard format and a transfer rule are generated
by the package.
- Integration with code_abstype: For typedefs (e.g. subtypes
corresponding to a datatype invariant, such as dlist),
lift_definition generates a code certificate theorem and sets up
code generation for each constant.
- setup_lifting command: Sets up the Lifting package to work with
a user-defined type. The user must provide either a quotient
theorem or a type_definition theorem. The package configures
transfer rules for equality and quantifiers on the type, and sets
up the lift_definition command to work with the type.
- Usage examples: See Quotient_Examples/Lift_DList.thy,
Quotient_Examples/Lift_RBT.thy, Word/Word.thy and
Library/Float.thy.
* Quotient package:
- The 'quotient_type' command now supports a 'morphisms' option with
rep and abs functions, similar to typedef.
- 'quotient_type' sets up new types to work with the Lifting and
Transfer packages, as with 'setup_lifting'.
- The 'quotient_definition' command now requires the user to prove a
respectfulness property at the point where the constant is
defined, similar to lift_definition; INCOMPATIBILITY.
- Renamed predicate 'Quotient' to 'Quotient3', and renamed theorems
accordingly, INCOMPATIBILITY.
* New diagnostic command 'find_unused_assms' to find potentially
superfluous assumptions in theorems using Quickcheck.
* Quickcheck:
- Quickcheck returns variable assignments as counterexamples, which
allows to reveal the underspecification of functions under test.
For example, refuting "hd xs = x", it presents the variable
assignment xs = [] and x = a1 as a counterexample, assuming that
any property is false whenever "hd []" occurs in it.
These counterexample are marked as potentially spurious, as
Quickcheck also returns "xs = []" as a counterexample to the
obvious theorem "hd xs = hd xs".
After finding a potentially spurious counterexample, Quickcheck
continues searching for genuine ones.
By default, Quickcheck shows potentially spurious and genuine
counterexamples. The option "genuine_only" sets quickcheck to only
show genuine counterexamples.
- The command 'quickcheck_generator' creates random and exhaustive
value generators for a given type and operations.
It generates values by using the operations as if they were
constructors of that type.
- Support for multisets.
- Added "use_subtype" options.
- Added "quickcheck_locale" configuration to specify how to process
conjectures in a locale context.
* Nitpick:
- Fixed infinite loop caused by the 'peephole_optim' option and
affecting 'rat' and 'real'.
* Sledgehammer:
- Integrated more tightly with SPASS, as described in the ITP 2012 paper "More
SPASS with Isabelle".
- Made it try "smt" as a fallback if "metis" fails or times out.
- Added support for the following provers: Alt-Ergo (via Why3 and TFF1),
iProver, iProver-Eq.
- Replaced remote E-SInE with remote Satallax in the default setup.
- Sped up the minimizer.
- Added "lam_trans", "uncurry_aliases", and "minimize" options.
- Renamed "slicing" ("no_slicing") option to "slice" ("dont_slice").
- Renamed "sound" option to "strict".
* Metis:
- Added possibility to specify lambda translations scheme as a
parenthesized argument (e.g., "by (metis (lifting) ...)").
* SMT:
- Renamed "smt_fixed" option to "smt_read_only_certificates".
* Command 'try0':
- Renamed from 'try_methods'. INCOMPATIBILITY.
* New "eventually_elim" method as a generalized variant of the
eventually_elim* rules. Supports structured proofs.
* HOL/TPTP: support to parse and import TPTP problems (all languages)
into Isabelle/HOL.
*** FOL ***
* New "case_product" attribute (see HOL).
*** ZF ***
* Greater support for structured proofs involving induction or case
analysis.
* Much greater use of mathematical symbols.
* Removal of many ML theorem bindings. INCOMPATIBILITY.
*** ML ***
* Antiquotation @{keyword "name"} produces a parser for outer syntax
from a minor keyword introduced via theory header declaration.
* Antiquotation @{command_spec "name"} produces the
Outer_Syntax.command_spec from a major keyword introduced via theory
header declaration; it can be passed to Outer_Syntax.command etc.
* Local_Theory.define no longer hard-wires default theorem name
"foo_def", but retains the binding as given. If that is Binding.empty
/ Attrib.empty_binding, the result is not registered as user-level
fact. The Local_Theory.define_internal variant allows to specify a
non-empty name (used for the foundation in the background theory),
while omitting the fact binding in the user-context. Potential
INCOMPATIBILITY for derived definitional packages: need to specify
naming policy for primitive definitions more explicitly.
* Renamed Thm.capply to Thm.apply, and Thm.cabs to Thm.lambda in
conformance with similar operations in structure Term and Logic.
* Antiquotation @{attributes [...]} embeds attribute source
representation into the ML text, which is particularly useful with
declarations like Local_Theory.note.
* Structure Proof_Context follows standard naming scheme. Old
ProofContext has been discontinued. INCOMPATIBILITY.
* Refined Local_Theory.declaration {syntax, pervasive}, with subtle
change of semantics: update is applied to auxiliary local theory
context as well.
* Modernized some old-style infix operations:
addeqcongs ~> Simplifier.add_eqcong
deleqcongs ~> Simplifier.del_eqcong
addcongs ~> Simplifier.add_cong
delcongs ~> Simplifier.del_cong
setmksimps ~> Simplifier.set_mksimps
setmkcong ~> Simplifier.set_mkcong
setmksym ~> Simplifier.set_mksym
setmkeqTrue ~> Simplifier.set_mkeqTrue
settermless ~> Simplifier.set_termless
setsubgoaler ~> Simplifier.set_subgoaler
addsplits ~> Splitter.add_split
delsplits ~> Splitter.del_split
*** System ***
* USER_HOME settings variable points to cross-platform user home
directory, which coincides with HOME on POSIX systems only. Likewise,
the Isabelle path specification "~" now expands to $USER_HOME, instead
of former $HOME. A different default for USER_HOME may be set
explicitly in shell environment, before Isabelle settings are
evaluated. Minor INCOMPATIBILITY: need to adapt Isabelle path where
the generic user home was intended.
* ISABELLE_JDK_HOME settings variable points to JDK with javac and jar
(not just JRE).
* ISABELLE_HOME_WINDOWS refers to ISABELLE_HOME in windows file name
notation, which is useful for the jEdit file browser, for example.
New in Isabelle2011-1 (October 2011)
------------------------------------
*** General ***
* Improved Isabelle/jEdit Prover IDE (PIDE), which can be invoked as
"isabelle jedit" or "ISABELLE_HOME/Isabelle" on the command line.
- Management of multiple theory files directly from the editor
buffer store -- bypassing the file-system (no requirement to save
files for checking).
- Markup of formal entities within the text buffer, with semantic
highlighting, tooltips and hyperlinks to jump to defining source
positions.
- Improved text rendering, with sub/superscripts in the source
buffer (including support for copy/paste wrt. output panel, HTML
theory output and other non-Isabelle text boxes).
- Refined scheduling of proof checking and printing of results,
based on interactive editor view. (Note: jEdit folding and
narrowing allows to restrict buffer perspectives explicitly.)
- Reduced CPU performance requirements, usable on machines with few
cores.
- Reduced memory requirements due to pruning of unused document
versions (garbage collection).
See also ~~/src/Tools/jEdit/README.html for further information,
including some remaining limitations.
* Theory loader: source files are exclusively located via the master
directory of each theory node (where the .thy file itself resides).
The global load path (such as src/HOL/Library) has been discontinued.
Note that the path element ~~ may be used to reference theories in the
Isabelle home folder -- for instance, "~~/src/HOL/Library/FuncSet".
INCOMPATIBILITY.
* Theory loader: source files are identified by content via SHA1
digests. Discontinued former path/modtime identification and optional
ISABELLE_FILE_IDENT plugin scripts.
* Parallelization of nested Isar proofs is subject to
Goal.parallel_proofs_threshold (default 100). See also isabelle
usedir option -Q.
* Name space: former unsynchronized references are now proper
configuration options, with more conventional names:
long_names ~> names_long
short_names ~> names_short
unique_names ~> names_unique
Minor INCOMPATIBILITY, need to declare options in context like this:
declare [[names_unique = false]]
* Literal facts `prop` may contain dummy patterns, e.g. `_ = _`. Note
that the result needs to be unique, which means fact specifications
may have to be refined after enriching a proof context.
* Attribute "case_names" has been refined: the assumptions in each case
can be named now by following the case name with [name1 name2 ...].
* Isabelle/Isar reference manual has been updated and extended:
- "Synopsis" provides a catalog of main Isar language concepts.
- Formal references in syntax diagrams, via @{rail} antiquotation.
- Updated material from classic "ref" manual, notably about
"Classical Reasoner".
*** HOL ***
* Class bot and top require underlying partial order rather than
preorder: uniqueness of bot and top is guaranteed. INCOMPATIBILITY.
* Class complete_lattice: generalized a couple of lemmas from sets;
generalized theorems INF_cong and SUP_cong. New type classes for
complete boolean algebras and complete linear orders. Lemmas
Inf_less_iff, less_Sup_iff, INF_less_iff, less_SUP_iff now reside in
class complete_linorder.
Changed proposition of lemmas Inf_bool_def, Sup_bool_def, Inf_fun_def,
Sup_fun_def, Inf_apply, Sup_apply.
Removed redundant lemmas (the right hand side gives hints how to
replace them for (metis ...), or (simp only: ...) proofs):
Inf_singleton ~> Inf_insert [where A="{}", unfolded Inf_empty inf_top_right]
Sup_singleton ~> Sup_insert [where A="{}", unfolded Sup_empty sup_bot_right]
Inf_binary ~> Inf_insert, Inf_empty, and inf_top_right
Sup_binary ~> Sup_insert, Sup_empty, and sup_bot_right
Int_eq_Inter ~> Inf_insert, Inf_empty, and inf_top_right
Un_eq_Union ~> Sup_insert, Sup_empty, and sup_bot_right
Inter_def ~> INF_def, image_def
Union_def ~> SUP_def, image_def
INT_eq ~> INF_def, and image_def
UN_eq ~> SUP_def, and image_def
INF_subset ~> INF_superset_mono [OF _ order_refl]
More consistent and comprehensive names:
INTER_eq_Inter_image ~> INF_def
UNION_eq_Union_image ~> SUP_def
INFI_def ~> INF_def
SUPR_def ~> SUP_def
INF_leI ~> INF_lower
INF_leI2 ~> INF_lower2
le_INFI ~> INF_greatest
le_SUPI ~> SUP_upper
le_SUPI2 ~> SUP_upper2
SUP_leI ~> SUP_least
INFI_bool_eq ~> INF_bool_eq
SUPR_bool_eq ~> SUP_bool_eq
INFI_apply ~> INF_apply
SUPR_apply ~> SUP_apply
INTER_def ~> INTER_eq
UNION_def ~> UNION_eq
INCOMPATIBILITY.
* Renamed theory Complete_Lattice to Complete_Lattices.
INCOMPATIBILITY.
* Theory Complete_Lattices: lemmas Inf_eq_top_iff, INF_eq_top_iff,
INF_image, Inf_insert, INF_top, Inf_top_conv, INF_top_conv, SUP_bot,
Sup_bot_conv, SUP_bot_conv, Sup_eq_top_iff, SUP_eq_top_iff, SUP_image,
Sup_insert are now declared as [simp]. INCOMPATIBILITY.
* Theory Lattice: lemmas compl_inf_bot, compl_le_comp_iff,
compl_sup_top, inf_idem, inf_left_idem, inf_sup_absorb, sup_idem,
sup_inf_absob, sup_left_idem are now declared as [simp]. Minor
INCOMPATIBILITY.
* Added syntactic classes "inf" and "sup" for the respective
constants. INCOMPATIBILITY: Changes in the argument order of the
(mostly internal) locale predicates for some derived classes.
* Theorem collections ball_simps and bex_simps do not contain theorems
referring to UNION any longer; these have been moved to collection
UN_ball_bex_simps. INCOMPATIBILITY.
* Theory Archimedean_Field: floor now is defined as parameter of a
separate type class floor_ceiling.
* Theory Finite_Set: more coherent development of fold_set locales:
locale fun_left_comm ~> locale comp_fun_commute
locale fun_left_comm_idem ~> locale comp_fun_idem
Both use point-free characterization; interpretation proofs may need
adjustment. INCOMPATIBILITY.
* Theory Limits: Type "'a net" has been renamed to "'a filter", in
accordance with standard mathematical terminology. INCOMPATIBILITY.
* Theory Complex_Main: The locale interpretations for the
bounded_linear and bounded_bilinear locales have been removed, in
order to reduce the number of duplicate lemmas. Users must use the
original names for distributivity theorems, potential INCOMPATIBILITY.
divide.add ~> add_divide_distrib
divide.diff ~> diff_divide_distrib
divide.setsum ~> setsum_divide_distrib
mult.add_right ~> right_distrib
mult.diff_right ~> right_diff_distrib
mult_right.setsum ~> setsum_right_distrib
mult_left.diff ~> left_diff_distrib
* Theory Complex_Main: Several redundant theorems have been removed or
replaced by more general versions. INCOMPATIBILITY.
real_diff_def ~> minus_real_def
real_divide_def ~> divide_real_def
real_less_def ~> less_le
real_abs_def ~> abs_real_def
real_sgn_def ~> sgn_real_def
real_mult_commute ~> mult_commute
real_mult_assoc ~> mult_assoc
real_mult_1 ~> mult_1_left
real_add_mult_distrib ~> left_distrib
real_zero_not_eq_one ~> zero_neq_one
real_mult_inverse_left ~> left_inverse
INVERSE_ZERO ~> inverse_zero
real_le_refl ~> order_refl
real_le_antisym ~> order_antisym
real_le_trans ~> order_trans
real_le_linear ~> linear
real_le_eq_diff ~> le_iff_diff_le_0
real_add_left_mono ~> add_left_mono
real_mult_order ~> mult_pos_pos
real_mult_less_mono2 ~> mult_strict_left_mono
real_of_int_real_of_nat ~> real_of_int_of_nat_eq
real_0_le_divide_iff ~> zero_le_divide_iff
realpow_two_disj ~> power2_eq_iff
real_squared_diff_one_factored ~> square_diff_one_factored
realpow_two_diff ~> square_diff_square_factored
reals_complete2 ~> complete_real
real_sum_squared_expand ~> power2_sum
exp_ln_eq ~> ln_unique
expi_add ~> exp_add
expi_zero ~> exp_zero
lemma_DERIV_subst ~> DERIV_cong
LIMSEQ_Zfun_iff ~> tendsto_Zfun_iff
LIMSEQ_const ~> tendsto_const
LIMSEQ_norm ~> tendsto_norm
LIMSEQ_add ~> tendsto_add
LIMSEQ_minus ~> tendsto_minus
LIMSEQ_minus_cancel ~> tendsto_minus_cancel
LIMSEQ_diff ~> tendsto_diff
bounded_linear.LIMSEQ ~> bounded_linear.tendsto
bounded_bilinear.LIMSEQ ~> bounded_bilinear.tendsto
LIMSEQ_mult ~> tendsto_mult
LIMSEQ_inverse ~> tendsto_inverse
LIMSEQ_divide ~> tendsto_divide
LIMSEQ_pow ~> tendsto_power
LIMSEQ_setsum ~> tendsto_setsum
LIMSEQ_setprod ~> tendsto_setprod
LIMSEQ_norm_zero ~> tendsto_norm_zero_iff
LIMSEQ_rabs_zero ~> tendsto_rabs_zero_iff
LIMSEQ_imp_rabs ~> tendsto_rabs
LIMSEQ_add_minus ~> tendsto_add [OF _ tendsto_minus]
LIMSEQ_add_const ~> tendsto_add [OF _ tendsto_const]
LIMSEQ_diff_const ~> tendsto_diff [OF _ tendsto_const]
LIMSEQ_Complex ~> tendsto_Complex
LIM_ident ~> tendsto_ident_at
LIM_const ~> tendsto_const
LIM_add ~> tendsto_add
LIM_add_zero ~> tendsto_add_zero
LIM_minus ~> tendsto_minus
LIM_diff ~> tendsto_diff
LIM_norm ~> tendsto_norm
LIM_norm_zero ~> tendsto_norm_zero
LIM_norm_zero_cancel ~> tendsto_norm_zero_cancel
LIM_norm_zero_iff ~> tendsto_norm_zero_iff
LIM_rabs ~> tendsto_rabs
LIM_rabs_zero ~> tendsto_rabs_zero
LIM_rabs_zero_cancel ~> tendsto_rabs_zero_cancel
LIM_rabs_zero_iff ~> tendsto_rabs_zero_iff
LIM_compose ~> tendsto_compose
LIM_mult ~> tendsto_mult
LIM_scaleR ~> tendsto_scaleR
LIM_of_real ~> tendsto_of_real
LIM_power ~> tendsto_power
LIM_inverse ~> tendsto_inverse
LIM_sgn ~> tendsto_sgn
isCont_LIM_compose ~> isCont_tendsto_compose
bounded_linear.LIM ~> bounded_linear.tendsto
bounded_linear.LIM_zero ~> bounded_linear.tendsto_zero
bounded_bilinear.LIM ~> bounded_bilinear.tendsto
bounded_bilinear.LIM_prod_zero ~> bounded_bilinear.tendsto_zero
bounded_bilinear.LIM_left_zero ~> bounded_bilinear.tendsto_left_zero
bounded_bilinear.LIM_right_zero ~> bounded_bilinear.tendsto_right_zero
LIM_inverse_fun ~> tendsto_inverse [OF tendsto_ident_at]
* Theory Complex_Main: The definition of infinite series was
generalized. Now it is defined on the type class {topological_space,
comm_monoid_add}. Hence it is useable also for extended real numbers.
* Theory Complex_Main: The complex exponential function "expi" is now
a type-constrained abbreviation for "exp :: complex => complex"; thus
several polymorphic lemmas about "exp" are now applicable to "expi".
* Code generation:
- Theory Library/Code_Char_ord provides native ordering of
characters in the target language.
- Commands code_module and code_library are legacy, use export_code
instead.
- Method "evaluation" is legacy, use method "eval" instead.
- Legacy evaluator "SML" is deactivated by default. May be
reactivated by the following theory command:
setup {* Value.add_evaluator ("SML", Codegen.eval_term) *}
* Declare ext [intro] by default. Rare INCOMPATIBILITY.
* New proof method "induction" that gives induction hypotheses the
name "IH", thus distinguishing them from further hypotheses that come
from rule induction. The latter are still called "hyps". Method
"induction" is a thin wrapper around "induct" and follows the same
syntax.
* Method "fastsimp" has been renamed to "fastforce", but "fastsimp" is
still available as a legacy feature for some time.
* Nitpick:
- Added "need" and "total_consts" options.
- Reintroduced "show_skolems" option by popular demand.
- Renamed attribute: nitpick_def ~> nitpick_unfold.
INCOMPATIBILITY.
* Sledgehammer:
- Use quasi-sound (and efficient) translations by default.
- Added support for the following provers: E-ToFoF, LEO-II,
Satallax, SNARK, Waldmeister, and Z3 with TPTP syntax.
- Automatically preplay and minimize proofs before showing them if
this can be done within reasonable time.
- sledgehammer available_provers ~> sledgehammer supported_provers.
INCOMPATIBILITY.
- Added "preplay_timeout", "slicing", "type_enc", "sound",
"max_mono_iters", and "max_new_mono_instances" options.
- Removed "explicit_apply" and "full_types" options as well as "Full
Types" Proof General menu item. INCOMPATIBILITY.
* Metis:
- Removed "metisF" -- use "metis" instead. INCOMPATIBILITY.
- Obsoleted "metisFT" -- use "metis (full_types)" instead.
INCOMPATIBILITY.
* Command 'try':
- Renamed 'try_methods' and added "simp:", "intro:", "dest:", and
"elim:" options. INCOMPATIBILITY.
- Introduced 'try' that not only runs 'try_methods' but also
'solve_direct', 'sledgehammer', 'quickcheck', and 'nitpick'.
* Quickcheck:
- Added "eval" option to evaluate terms for the found counterexample
(currently only supported by the default (exhaustive) tester).
- Added post-processing of terms to obtain readable counterexamples
(currently only supported by the default (exhaustive) tester).
- New counterexample generator quickcheck[narrowing] enables
narrowing-based testing. Requires the Glasgow Haskell compiler
with its installation location defined in the Isabelle settings
environment as ISABELLE_GHC.
- Removed quickcheck tester "SML" based on the SML code generator
(formly in HOL/Library).
* Function package: discontinued option "tailrec". INCOMPATIBILITY,
use 'partial_function' instead.
* Theory Library/Extended_Reals replaces now the positive extended
reals found in probability theory. This file is extended by
Multivariate_Analysis/Extended_Real_Limits.
* Theory Library/Old_Recdef: old 'recdef' package has been moved here,
from where it must be imported explicitly if it is really required.
INCOMPATIBILITY.
* Theory Library/Wfrec: well-founded recursion combinator "wfrec" has
been moved here. INCOMPATIBILITY.
* Theory Library/Saturated provides type of numbers with saturated
arithmetic.
* Theory Library/Product_Lattice defines a pointwise ordering for the
product type 'a * 'b, and provides instance proofs for various order
and lattice type classes.
* Theory Library/Countable now provides the "countable_datatype" proof
method for proving "countable" class instances for datatypes.
* Theory Library/Cset_Monad allows do notation for computable sets
(cset) via the generic monad ad-hoc overloading facility.
* Library: Theories of common data structures are split into theories
for implementation, an invariant-ensuring type, and connection to an
abstract type. INCOMPATIBILITY.
- RBT is split into RBT and RBT_Mapping.
- AssocList is split and renamed into AList and AList_Mapping.
- DList is split into DList_Impl, DList, and DList_Cset.
- Cset is split into Cset and List_Cset.
* Theory Library/Nat_Infinity has been renamed to
Library/Extended_Nat, with name changes of the following types and
constants:
type inat ~> type enat
Fin ~> enat
Infty ~> infinity (overloaded)
iSuc ~> eSuc
the_Fin ~> the_enat
Every theorem name containing "inat", "Fin", "Infty", or "iSuc" has
been renamed accordingly. INCOMPATIBILITY.
* Session Multivariate_Analysis: The euclidean_space type class now
fixes a constant "Basis :: 'a set" consisting of the standard
orthonormal basis for the type. Users now have the option of
quantifying over this set instead of using the "basis" function, e.g.
"ALL x:Basis. P x" vs "ALL i vec_eq_iff
dist_nth_le_cart ~> dist_vec_nth_le
tendsto_vector ~> vec_tendstoI
Cauchy_vector ~> vec_CauchyI
* Session Multivariate_Analysis: Several duplicate theorems have been
removed, and other theorems have been renamed or replaced with more
general versions. INCOMPATIBILITY.
finite_choice ~> finite_set_choice
eventually_conjI ~> eventually_conj
eventually_and ~> eventually_conj_iff
eventually_false ~> eventually_False
setsum_norm ~> norm_setsum
Lim_sequentially ~> LIMSEQ_def
Lim_ident_at ~> LIM_ident
Lim_const ~> tendsto_const
Lim_cmul ~> tendsto_scaleR [OF tendsto_const]
Lim_neg ~> tendsto_minus
Lim_add ~> tendsto_add
Lim_sub ~> tendsto_diff
Lim_mul ~> tendsto_scaleR
Lim_vmul ~> tendsto_scaleR [OF _ tendsto_const]
Lim_null_norm ~> tendsto_norm_zero_iff [symmetric]
Lim_linear ~> bounded_linear.tendsto
Lim_component ~> tendsto_euclidean_component
Lim_component_cart ~> tendsto_vec_nth
Lim_inner ~> tendsto_inner [OF tendsto_const]
dot_lsum ~> inner_setsum_left
dot_rsum ~> inner_setsum_right
continuous_cmul ~> continuous_scaleR [OF continuous_const]
continuous_neg ~> continuous_minus
continuous_sub ~> continuous_diff
continuous_vmul ~> continuous_scaleR [OF _ continuous_const]
continuous_mul ~> continuous_scaleR
continuous_inv ~> continuous_inverse
continuous_at_within_inv ~> continuous_at_within_inverse
continuous_at_inv ~> continuous_at_inverse
continuous_at_norm ~> continuous_norm [OF continuous_at_id]
continuous_at_infnorm ~> continuous_infnorm [OF continuous_at_id]
continuous_at_component ~> continuous_component [OF continuous_at_id]
continuous_on_neg ~> continuous_on_minus
continuous_on_sub ~> continuous_on_diff
continuous_on_cmul ~> continuous_on_scaleR [OF continuous_on_const]
continuous_on_vmul ~> continuous_on_scaleR [OF _ continuous_on_const]
continuous_on_mul ~> continuous_on_scaleR
continuous_on_mul_real ~> continuous_on_mult
continuous_on_inner ~> continuous_on_inner [OF continuous_on_const]
continuous_on_norm ~> continuous_on_norm [OF continuous_on_id]
continuous_on_inverse ~> continuous_on_inv
uniformly_continuous_on_neg ~> uniformly_continuous_on_minus
uniformly_continuous_on_sub ~> uniformly_continuous_on_diff
subset_interior ~> interior_mono
subset_closure ~> closure_mono
closure_univ ~> closure_UNIV
real_arch_lt ~> reals_Archimedean2
real_arch ~> reals_Archimedean3
real_abs_norm ~> abs_norm_cancel
real_abs_sub_norm ~> norm_triangle_ineq3
norm_cauchy_schwarz_abs ~> Cauchy_Schwarz_ineq2
* Session HOL-Probability:
- Caratheodory's extension lemma is now proved for ring_of_sets.
- Infinite products of probability measures are now available.
- Sigma closure is independent, if the generator is independent
- Use extended reals instead of positive extended
reals. INCOMPATIBILITY.
* Session HOLCF: Discontinued legacy theorem names, INCOMPATIBILITY.
expand_fun_below ~> fun_below_iff
below_fun_ext ~> fun_belowI
expand_cfun_eq ~> cfun_eq_iff
ext_cfun ~> cfun_eqI
expand_cfun_below ~> cfun_below_iff
below_cfun_ext ~> cfun_belowI
monofun_fun_fun ~> fun_belowD
monofun_fun_arg ~> monofunE
monofun_lub_fun ~> adm_monofun [THEN admD]
cont_lub_fun ~> adm_cont [THEN admD]
cont2cont_Rep_CFun ~> cont2cont_APP
cont_Rep_CFun_app ~> cont_APP_app
cont_Rep_CFun_app_app ~> cont_APP_app_app
cont_cfun_fun ~> cont_Rep_cfun1 [THEN contE]
cont_cfun_arg ~> cont_Rep_cfun2 [THEN contE]
contlub_cfun ~> lub_APP [symmetric]
contlub_LAM ~> lub_LAM [symmetric]
thelubI ~> lub_eqI
UU_I ~> bottomI
lift_distinct1 ~> lift.distinct(1)
lift_distinct2 ~> lift.distinct(2)
Def_not_UU ~> lift.distinct(2)
Def_inject ~> lift.inject
below_UU_iff ~> below_bottom_iff
eq_UU_iff ~> eq_bottom_iff
*** Document preparation ***
* Antiquotation @{rail} layouts railroad syntax diagrams, see also
isar-ref manual, both for description and actual application of the
same.
* Antiquotation @{value} evaluates the given term and presents its
result.
* Antiquotations: term style "isub" provides ad-hoc conversion of
variables x1, y23 into subscripted form x\<^isub>1,
y\<^isub>2\<^isub>3.
* Predefined LaTeX macros for Isabelle symbols \ and \
(e.g. see ~~/src/HOL/Library/Monad_Syntax.thy).
* Localized \isabellestyle switch can be used within blocks or groups
like this:
\isabellestyle{it} %preferred default
{\isabellestylett @{text "typewriter stuff"}}
* Discontinued special treatment of hard tabulators. Implicit
tab-width is now defined as 1. Potential INCOMPATIBILITY for visual
layouts.
*** ML ***
* The inner syntax of sort/type/term/prop supports inlined YXML
representations within quoted string tokens. By encoding logical
entities via Term_XML (in ML or Scala) concrete syntax can be
bypassed, which is particularly useful for producing bits of text
under external program control.
* Antiquotations for ML and document preparation are managed as theory
data, which requires explicit setup.
* Isabelle_Process.is_active allows tools to check if the official
process wrapper is running (Isabelle/Scala/jEdit) or the old TTY loop
(better known as Proof General).
* Structure Proof_Context follows standard naming scheme. Old
ProofContext is still available for some time as legacy alias.
* Structure Timing provides various operations for timing; supersedes
former start_timing/end_timing etc.
* Path.print is the official way to show file-system paths to users
(including quotes etc.).
* Inner syntax: identifiers in parse trees of generic categories
"logic", "aprop", "idt" etc. carry position information (disguised as
type constraints). Occasional INCOMPATIBILITY with non-compliant
translations that choke on unexpected type constraints. Positions can
be stripped in ML translations via Syntax.strip_positions /
Syntax.strip_positions_ast, or via the syntax constant
"_strip_positions" within parse trees. As last resort, positions can
be disabled via the configuration option Syntax.positions, which is
called "syntax_positions" in Isar attribute syntax.
* Discontinued special status of various ML structures that contribute
to structure Syntax (Ast, Lexicon, Mixfix, Parser, Printer etc.): less
pervasive content, no inclusion in structure Syntax. INCOMPATIBILITY,
refer directly to Ast.Constant, Lexicon.is_identifier,
Syntax_Trans.mk_binder_tr etc.
* Typed print translation: discontinued show_sorts argument, which is
already available via context of "advanced" translation.
* Refined PARALLEL_GOALS tactical: degrades gracefully for schematic
goal states; body tactic needs to address all subgoals uniformly.
* Slightly more special eq_list/eq_set, with shortcut involving
pointer equality (assumes that eq relation is reflexive).
* Classical tactics use proper Proof.context instead of historic types
claset/clasimpset. Old-style declarations like addIs, addEs, addDs
operate directly on Proof.context. Raw type claset retains its use as
snapshot of the classical context, which can be recovered via
(put_claset HOL_cs) etc. Type clasimpset has been discontinued.
INCOMPATIBILITY, classical tactics and derived proof methods require
proper Proof.context.
*** System ***
* Discontinued support for Poly/ML 5.2, which was the last version
without proper multithreading and TimeLimit implementation.
* Discontinued old lib/scripts/polyml-platform, which has been
obsolete since Isabelle2009-2.
* Various optional external tools are referenced more robustly and
uniformly by explicit Isabelle settings as follows:
ISABELLE_CSDP (formerly CSDP_EXE)
ISABELLE_GHC (formerly EXEC_GHC or GHC_PATH)
ISABELLE_OCAML (formerly EXEC_OCAML)
ISABELLE_SWIPL (formerly EXEC_SWIPL)
ISABELLE_YAP (formerly EXEC_YAP)
Note that automated detection from the file-system or search path has
been discontinued. INCOMPATIBILITY.
* Scala layer provides JVM method invocation service for static
methods of type (String)String, see Invoke_Scala.method in ML. For
example:
Invoke_Scala.method "java.lang.System.getProperty" "java.home"
Together with YXML.string_of_body/parse_body and XML.Encode/Decode
this allows to pass structured values between ML and Scala.
* The IsabelleText fonts includes some further glyphs to support the
Prover IDE. Potential INCOMPATIBILITY: users who happen to have
installed a local copy (which is normally *not* required) need to
delete or update it from ~~/lib/fonts/.
New in Isabelle2011 (January 2011)
----------------------------------
*** General ***
* Experimental Prover IDE based on Isabelle/Scala and jEdit (see
src/Tools/jEdit). This also serves as IDE for Isabelle/ML, with
useful tooltips and hyperlinks produced from its static analysis. The
bundled component provides an executable Isabelle tool that can be run
like this:
Isabelle2011/bin/isabelle jedit
* Significantly improved Isabelle/Isar implementation manual.
* System settings: ISABELLE_HOME_USER now includes ISABELLE_IDENTIFIER
(and thus refers to something like $HOME/.isabelle/Isabelle2011),
while the default heap location within that directory lacks that extra
suffix. This isolates multiple Isabelle installations from each
other, avoiding problems with old settings in new versions.
INCOMPATIBILITY, need to copy/upgrade old user settings manually.
* Source files are always encoded as UTF-8, instead of old-fashioned
ISO-Latin-1. INCOMPATIBILITY. Isabelle LaTeX documents might require
the following package declarations:
\usepackage[utf8]{inputenc}
\usepackage{textcomp}
* Explicit treatment of UTF-8 sequences as Isabelle symbols, such that
a Unicode character is treated as a single symbol, not a sequence of
non-ASCII bytes as before. Since Isabelle/ML string literals may
contain symbols without further backslash escapes, Unicode can now be
used here as well. Recall that Symbol.explode in ML provides a
consistent view on symbols, while raw explode (or String.explode)
merely give a byte-oriented representation.
* Theory loader: source files are primarily located via the master
directory of each theory node (where the .thy file itself resides).
The global load path is still partially available as legacy feature.
Minor INCOMPATIBILITY due to subtle change in file lookup: use
explicit paths, relatively to the theory.
* Special treatment of ML file names has been discontinued.
Historically, optional extensions .ML or .sml were added on demand --
at the cost of clarity of file dependencies. Recall that Isabelle/ML
files exclusively use the .ML extension. Minor INCOMPATIBILTY.
* Various options that affect pretty printing etc. are now properly
handled within the context via configuration options, instead of
unsynchronized references or print modes. There are both ML Config.T
entities and Isar declaration attributes to access these.
ML (Config.T) Isar (attribute)
eta_contract eta_contract
show_brackets show_brackets
show_sorts show_sorts
show_types show_types
show_question_marks show_question_marks
show_consts show_consts
show_abbrevs show_abbrevs
Syntax.ast_trace syntax_ast_trace
Syntax.ast_stat syntax_ast_stat
Syntax.ambiguity_level syntax_ambiguity_level
Goal_Display.goals_limit goals_limit
Goal_Display.show_main_goal show_main_goal
Method.rule_trace rule_trace
Thy_Output.display thy_output_display
Thy_Output.quotes thy_output_quotes
Thy_Output.indent thy_output_indent
Thy_Output.source thy_output_source
Thy_Output.break thy_output_break
Note that corresponding "..._default" references in ML may only be
changed globally at the ROOT session setup, but *not* within a theory.
The option "show_abbrevs" supersedes the former print mode
"no_abbrevs" with inverted meaning.
* More systematic naming of some configuration options.
INCOMPATIBILITY.
trace_simp ~> simp_trace
debug_simp ~> simp_debug
* Support for real valued configuration options, using simplistic
floating-point notation that coincides with the inner syntax for
float_token.
* Support for real valued preferences (with approximative PGIP type):
front-ends need to accept "pgint" values in float notation.
INCOMPATIBILITY.
* The IsabelleText font now includes Cyrillic, Hebrew, Arabic from
DejaVu Sans.
* Discontinued support for Poly/ML 5.0 and 5.1 versions.
*** Pure ***
* Command 'type_synonym' (with single argument) replaces somewhat
outdated 'types', which is still available as legacy feature for some
time.
* Command 'nonterminal' (with 'and' separated list of arguments)
replaces somewhat outdated 'nonterminals'. INCOMPATIBILITY.
* Command 'notepad' replaces former 'example_proof' for
experimentation in Isar without any result. INCOMPATIBILITY.
* Locale interpretation commands 'interpret' and 'sublocale' accept
lists of equations to map definitions in a locale to appropriate
entities in the context of the interpretation. The 'interpretation'
command already provided this functionality.
* Diagnostic command 'print_dependencies' prints the locale instances
that would be activated if the specified expression was interpreted in
the current context. Variant "print_dependencies!" assumes a context
without interpretations.
* Diagnostic command 'print_interps' prints interpretations in proofs
in addition to interpretations in theories.
* Discontinued obsolete 'global' and 'local' commands to manipulate
the theory name space. Rare INCOMPATIBILITY. The ML functions
Sign.root_path and Sign.local_path may be applied directly where this
feature is still required for historical reasons.
* Discontinued obsolete 'constdefs' command. INCOMPATIBILITY, use
'definition' instead.
* The "prems" fact, which refers to the accidental collection of
foundational premises in the context, is now explicitly marked as
legacy feature and will be discontinued soon. Consider using "assms"
of the head statement or reference facts by explicit names.
* Document antiquotations @{class} and @{type} print classes and type
constructors.
* Document antiquotation @{file} checks file/directory entries within
the local file system.
*** HOL ***
* Coercive subtyping: functions can be declared as coercions and type
inference will add them as necessary upon input of a term. Theory
Complex_Main declares real :: nat => real and real :: int => real as
coercions. A coercion function f is declared like this:
declare [[coercion f]]
To lift coercions through type constructors (e.g. from nat => real to
nat list => real list), map functions can be declared, e.g.
declare [[coercion_map map]]
Currently coercion inference is activated only in theories including
real numbers, i.e. descendants of Complex_Main. This is controlled by
the configuration option "coercion_enabled", e.g. it can be enabled in
other theories like this:
declare [[coercion_enabled]]
* Command 'partial_function' provides basic support for recursive
function definitions over complete partial orders. Concrete instances
are provided for i) the option type, ii) tail recursion on arbitrary
types, and iii) the heap monad of Imperative_HOL. See
src/HOL/ex/Fundefs.thy and src/HOL/Imperative_HOL/ex/Linked_Lists.thy
for examples.
* Function package: f.psimps rules are no longer implicitly declared
as [simp]. INCOMPATIBILITY.
* Datatype package: theorems generated for executable equality (class
"eq") carry proper names and are treated as default code equations.
* Inductive package: now offers command 'inductive_simps' to
automatically derive instantiated and simplified equations for
inductive predicates, similar to 'inductive_cases'.
* Command 'enriched_type' allows to register properties of the
functorial structure of types.
* Improved infrastructure for term evaluation using code generator
techniques, in particular static evaluation conversions.
* Code generator: Scala (2.8 or higher) has been added to the target
languages.
* Code generator: globbing constant expressions "*" and "Theory.*"
have been replaced by the more idiomatic "_" and "Theory._".
INCOMPATIBILITY.
* Code generator: export_code without explicit file declaration prints
to standard output. INCOMPATIBILITY.
* Code generator: do not print function definitions for case
combinators any longer.
* Code generator: simplification with rules determined with
src/Tools/Code/code_simp.ML and method "code_simp".
* Code generator for records: more idiomatic representation of record
types. Warning: records are not covered by ancient SML code
generation any longer. INCOMPATIBILITY. In cases of need, a suitable
rep_datatype declaration helps to succeed then:
record 'a foo = ...
...
rep_datatype foo_ext ...
* Records: logical foundation type for records does not carry a
'_type' suffix any longer (obsolete due to authentic syntax).
INCOMPATIBILITY.
* Quickcheck now by default uses exhaustive testing instead of random
testing. Random testing can be invoked by "quickcheck [random]",
exhaustive testing by "quickcheck [exhaustive]".
* Quickcheck instantiates polymorphic types with small finite
datatypes by default. This enables a simple execution mechanism to
handle quantifiers and function equality over the finite datatypes.
* Quickcheck random generator has been renamed from "code" to
"random". INCOMPATIBILITY.
* Quickcheck now has a configurable time limit which is set to 30
seconds by default. This can be changed by adding [timeout = n] to the
quickcheck command. The time limit for Auto Quickcheck is still set
independently.
* Quickcheck in locales considers interpretations of that locale for
counter example search.
* Sledgehammer:
- Added "smt" and "remote_smt" provers based on the "smt" proof
method. See the Sledgehammer manual for details ("isabelle doc
sledgehammer").
- Renamed commands:
sledgehammer atp_info ~> sledgehammer running_provers
sledgehammer atp_kill ~> sledgehammer kill_provers
sledgehammer available_atps ~> sledgehammer available_provers
INCOMPATIBILITY.
- Renamed options:
sledgehammer [atps = ...] ~> sledgehammer [provers = ...]
sledgehammer [atp = ...] ~> sledgehammer [prover = ...]
sledgehammer [timeout = 77 s] ~> sledgehammer [timeout = 77]
(and "ms" and "min" are no longer supported)
INCOMPATIBILITY.
* Nitpick:
- Renamed options:
nitpick [timeout = 77 s] ~> nitpick [timeout = 77]
nitpick [tac_timeout = 777 ms] ~> nitpick [tac_timeout = 0.777]
INCOMPATIBILITY.
- Added support for partial quotient types.
- Added local versions of the "Nitpick.register_xxx" functions.
- Added "whack" option.
- Allow registration of quotient types as codatatypes.
- Improved "merge_type_vars" option to merge more types.
- Removed unsound "fast_descrs" option.
- Added custom symmetry breaking for datatypes, making it possible to reach
higher cardinalities.
- Prevent the expansion of too large definitions.
* Proof methods "metis" and "meson" now have configuration options
"meson_trace", "metis_trace", and "metis_verbose" that can be enabled
to diagnose these tools. E.g.
using [[metis_trace = true]]
* Auto Solve: Renamed "Auto Solve Direct". The tool is now available
manually as command 'solve_direct'.
* The default SMT solver Z3 must be enabled explicitly (due to
licensing issues) by setting the environment variable
Z3_NON_COMMERCIAL in etc/settings of the component, for example. For
commercial applications, the SMT solver CVC3 is provided as fall-back;
changing the SMT solver is done via the configuration option
"smt_solver".
* Remote SMT solvers need to be referred to by the "remote_" prefix,
i.e. "remote_cvc3" and "remote_z3".
* Added basic SMT support for datatypes, records, and typedefs using
the oracle mode (no proofs). Direct support of pairs has been dropped
in exchange (pass theorems fst_conv snd_conv pair_collapse to the SMT
support for a similar behavior). Minor INCOMPATIBILITY.
* Changed SMT configuration options:
- Renamed:
z3_proofs ~> smt_oracle (with inverted meaning)
z3_trace_assms ~> smt_trace_used_facts
INCOMPATIBILITY.
- Added:
smt_verbose
smt_random_seed
smt_datatypes
smt_infer_triggers
smt_monomorph_limit
cvc3_options
remote_cvc3_options
remote_z3_options
yices_options
* Boogie output files (.b2i files) need to be declared in the theory
header.
* Simplification procedure "list_to_set_comprehension" rewrites list
comprehensions applied to List.set to set comprehensions. Occasional
INCOMPATIBILITY, may be deactivated like this:
declare [[simproc del: list_to_set_comprehension]]
* Removed old version of primrec package. INCOMPATIBILITY.
* Removed simplifier congruence rule of "prod_case", as has for long
been the case with "split". INCOMPATIBILITY.
* String.literal is a type, but not a datatype. INCOMPATIBILITY.
* Removed [split_format ... and ... and ...] version of
[split_format]. Potential INCOMPATIBILITY.
* Predicate "sorted" now defined inductively, with nice induction
rules. INCOMPATIBILITY: former sorted.simps now named sorted_simps.
* Constant "contents" renamed to "the_elem", to free the generic name
contents for other uses. INCOMPATIBILITY.
* Renamed class eq and constant eq (for code generation) to class
equal and constant equal, plus renaming of related facts and various
tuning. INCOMPATIBILITY.
* Dropped type classes mult_mono and mult_mono1. INCOMPATIBILITY.
* Removed output syntax "'a ~=> 'b" for "'a => 'b option".
INCOMPATIBILITY.
* Renamed theory Fset to Cset, type Fset.fset to Cset.set, in order to
avoid confusion with finite sets. INCOMPATIBILITY.
* Abandoned locales equiv, congruent and congruent2 for equivalence
relations. INCOMPATIBILITY: use equivI rather than equiv_intro (same
for congruent(2)).
* Some previously unqualified names have been qualified:
types
bool ~> HOL.bool
nat ~> Nat.nat
constants
Trueprop ~> HOL.Trueprop
True ~> HOL.True
False ~> HOL.False
op & ~> HOL.conj
op | ~> HOL.disj
op --> ~> HOL.implies
op = ~> HOL.eq
Not ~> HOL.Not
The ~> HOL.The
All ~> HOL.All
Ex ~> HOL.Ex
Ex1 ~> HOL.Ex1
Let ~> HOL.Let
If ~> HOL.If
Ball ~> Set.Ball
Bex ~> Set.Bex
Suc ~> Nat.Suc
Pair ~> Product_Type.Pair
fst ~> Product_Type.fst
snd ~> Product_Type.snd
curry ~> Product_Type.curry
op : ~> Set.member
Collect ~> Set.Collect
INCOMPATIBILITY.
* More canonical naming convention for some fundamental definitions:
bot_bool_eq ~> bot_bool_def
top_bool_eq ~> top_bool_def
inf_bool_eq ~> inf_bool_def
sup_bool_eq ~> sup_bool_def
bot_fun_eq ~> bot_fun_def
top_fun_eq ~> top_fun_def
inf_fun_eq ~> inf_fun_def
sup_fun_eq ~> sup_fun_def
INCOMPATIBILITY.
* More stylized fact names:
expand_fun_eq ~> fun_eq_iff
expand_set_eq ~> set_eq_iff
set_ext ~> set_eqI
nat_number ~> eval_nat_numeral
INCOMPATIBILITY.
* Refactoring of code-generation specific operations in theory List:
constants
null ~> List.null
facts
mem_iff ~> member_def
null_empty ~> null_def
INCOMPATIBILITY. Note that these were not supposed to be used
regularly unless for striking reasons; their main purpose was code
generation.
Various operations from the Haskell prelude are used for generating
Haskell code.
* Term "bij f" is now an abbreviation of "bij_betw f UNIV UNIV". Term
"surj f" is now an abbreviation of "range f = UNIV". The theorems
bij_def and surj_def are unchanged. INCOMPATIBILITY.
* Abolished some non-alphabetic type names: "prod" and "sum" replace
"*" and "+" respectively. INCOMPATIBILITY.
* Name "Plus" of disjoint sum operator "<+>" is now hidden. Write
"Sum_Type.Plus" instead.
* Constant "split" has been merged with constant "prod_case"; names of
ML functions, facts etc. involving split have been retained so far,
though. INCOMPATIBILITY.
* Dropped old infix syntax "_ mem _" for List.member; use "_ : set _"
instead. INCOMPATIBILITY.
* Removed lemma "Option.is_none_none" which duplicates "is_none_def".
INCOMPATIBILITY.
* Former theory Library/Enum is now part of the HOL-Main image.
INCOMPATIBILITY: all constants of the Enum theory now have to be
referred to by its qualified name.
enum ~> Enum.enum
nlists ~> Enum.nlists
product ~> Enum.product
* Theory Library/Monad_Syntax provides do-syntax for monad types.
Syntax in Library/State_Monad has been changed to avoid ambiguities.
INCOMPATIBILITY.
* Theory Library/SetsAndFunctions has been split into
Library/Function_Algebras and Library/Set_Algebras; canonical names
for instance definitions for functions; various improvements.
INCOMPATIBILITY.
* Theory Library/Multiset provides stable quicksort implementation of
sort_key.
* Theory Library/Multiset: renamed empty_idemp ~> empty_neutral.
INCOMPATIBILITY.
* Session Multivariate_Analysis: introduced a type class for euclidean
space. Most theorems are now stated in terms of euclidean spaces
instead of finite cartesian products.
types
real ^ 'n ~> 'a::real_vector
~> 'a::euclidean_space
~> 'a::ordered_euclidean_space
(depends on your needs)
constants
_ $ _ ~> _ $$ _
\ x. _ ~> \\ x. _
CARD('n) ~> DIM('a)
Also note that the indices are now natural numbers and not from some
finite type. Finite cartesian products of euclidean spaces, products
of euclidean spaces the real and complex numbers are instantiated to
be euclidean_spaces. INCOMPATIBILITY.
* Session Probability: introduced pextreal as positive extended real
numbers. Use pextreal as value for measures. Introduce the
Radon-Nikodym derivative, product spaces and Fubini's theorem for
arbitrary sigma finite measures. Introduces Lebesgue measure based on
the integral in Multivariate Analysis. INCOMPATIBILITY.
* Session Imperative_HOL: revamped, corrected dozens of inadequacies.
INCOMPATIBILITY.
* Session SPARK (with image HOL-SPARK) provides commands to load and
prove verification conditions generated by the SPARK Ada program
verifier. See also src/HOL/SPARK and src/HOL/SPARK/Examples.
*** HOL-Algebra ***
* Theorems for additive ring operations (locale abelian_monoid and
descendants) are generated by interpretation from their multiplicative
counterparts. Names (in particular theorem names) have the mandatory
qualifier 'add'. Previous theorem names are redeclared for
compatibility.
* Structure "int_ring" is now an abbreviation (previously a
definition). This fits more natural with advanced interpretations.
*** HOLCF ***
* The domain package now runs in definitional mode by default: The
former command 'new_domain' is now called 'domain'. To use the domain
package in its original axiomatic mode, use 'domain (unsafe)'.
INCOMPATIBILITY.
* The new class "domain" is now the default sort. Class "predomain"
is an unpointed version of "domain". Theories can be updated by
replacing sort annotations as shown below. INCOMPATIBILITY.
'a::type ~> 'a::countable
'a::cpo ~> 'a::predomain
'a::pcpo ~> 'a::domain
* The old type class "rep" has been superseded by class "domain".
Accordingly, users of the definitional package must remove any
"default_sort rep" declarations. INCOMPATIBILITY.
* The domain package (definitional mode) now supports unpointed
predomain argument types, as long as they are marked 'lazy'. (Strict
arguments must be in class "domain".) For example, the following
domain definition now works:
domain natlist = nil | cons (lazy "nat discr") (lazy "natlist")
* Theory HOLCF/Library/HOL_Cpo provides cpo and predomain class
instances for types from main HOL: bool, nat, int, char, 'a + 'b,
'a option, and 'a list. Additionally, it configures fixrec and the
domain package to work with these types. For example:
fixrec isInl :: "('a + 'b) u -> tr"
where "isInl$(up$(Inl x)) = TT" | "isInl$(up$(Inr y)) = FF"
domain V = VFun (lazy "V -> V") | VCon (lazy "nat") (lazy "V list")
* The "(permissive)" option of fixrec has been replaced with a
per-equation "(unchecked)" option. See
src/HOL/HOLCF/Tutorial/Fixrec_ex.thy for examples. INCOMPATIBILITY.
* The "bifinite" class no longer fixes a constant "approx"; the class
now just asserts that such a function exists. INCOMPATIBILITY.
* Former type "alg_defl" has been renamed to "defl". HOLCF no longer
defines an embedding of type 'a defl into udom by default; instances
of "bifinite" and "domain" classes are available in
src/HOL/HOLCF/Library/Defl_Bifinite.thy.
* The syntax "REP('a)" has been replaced with "DEFL('a)".
* The predicate "directed" has been removed. INCOMPATIBILITY.
* The type class "finite_po" has been removed. INCOMPATIBILITY.
* The function "cprod_map" has been renamed to "prod_map".
INCOMPATIBILITY.
* The monadic bind operator on each powerdomain has new binder syntax
similar to sets, e.g. "\\x\xs. t" represents
"upper_bind\xs\(\ x. t)".
* The infix syntax for binary union on each powerdomain has changed
from e.g. "+\" to "\\", for consistency with set
syntax. INCOMPATIBILITY.
* The constant "UU" has been renamed to "bottom". The syntax "UU" is
still supported as an input translation.
* Renamed some theorems (the original names are also still available).
expand_fun_below ~> fun_below_iff
below_fun_ext ~> fun_belowI
expand_cfun_eq ~> cfun_eq_iff
ext_cfun ~> cfun_eqI
expand_cfun_below ~> cfun_below_iff
below_cfun_ext ~> cfun_belowI
cont2cont_Rep_CFun ~> cont2cont_APP
* The Abs and Rep functions for various types have changed names.
Related theorem names have also changed to match. INCOMPATIBILITY.
Rep_CFun ~> Rep_cfun
Abs_CFun ~> Abs_cfun
Rep_Sprod ~> Rep_sprod
Abs_Sprod ~> Abs_sprod
Rep_Ssum ~> Rep_ssum
Abs_Ssum ~> Abs_ssum
* Lemmas with names of the form *_defined_iff or *_strict_iff have
been renamed to *_bottom_iff. INCOMPATIBILITY.
* Various changes to bisimulation/coinduction with domain package:
- Definitions of "bisim" constants no longer mention definedness.
- With mutual recursion, "bisim" predicate is now curried.
- With mutual recursion, each type gets a separate coind theorem.
- Variable names in bisim_def and coinduct rules have changed.
INCOMPATIBILITY.
* Case combinators generated by the domain package for type "foo" are
now named "foo_case" instead of "foo_when". INCOMPATIBILITY.
* Several theorems have been renamed to more accurately reflect the
names of constants and types involved. INCOMPATIBILITY.
thelub_const ~> lub_const
lub_const ~> is_lub_const
thelubI ~> lub_eqI
is_lub_lub ~> is_lubD2
lubI ~> is_lub_lub
unique_lub ~> is_lub_unique
is_ub_lub ~> is_lub_rangeD1
lub_bin_chain ~> is_lub_bin_chain
lub_fun ~> is_lub_fun
thelub_fun ~> lub_fun
thelub_cfun ~> lub_cfun
thelub_Pair ~> lub_Pair
lub_cprod ~> is_lub_prod
thelub_cprod ~> lub_prod
minimal_cprod ~> minimal_prod
inst_cprod_pcpo ~> inst_prod_pcpo
UU_I ~> bottomI
compact_UU ~> compact_bottom
deflation_UU ~> deflation_bottom
finite_deflation_UU ~> finite_deflation_bottom
* Many legacy theorem names have been discontinued. INCOMPATIBILITY.
sq_ord_less_eq_trans ~> below_eq_trans
sq_ord_eq_less_trans ~> eq_below_trans
refl_less ~> below_refl
trans_less ~> below_trans
antisym_less ~> below_antisym
antisym_less_inverse ~> po_eq_conv [THEN iffD1]
box_less ~> box_below
rev_trans_less ~> rev_below_trans
not_less2not_eq ~> not_below2not_eq
less_UU_iff ~> below_UU_iff
flat_less_iff ~> flat_below_iff
adm_less ~> adm_below
adm_not_less ~> adm_not_below
adm_compact_not_less ~> adm_compact_not_below
less_fun_def ~> below_fun_def
expand_fun_less ~> fun_below_iff
less_fun_ext ~> fun_belowI
less_discr_def ~> below_discr_def
discr_less_eq ~> discr_below_eq
less_unit_def ~> below_unit_def
less_cprod_def ~> below_prod_def
prod_lessI ~> prod_belowI
Pair_less_iff ~> Pair_below_iff
fst_less_iff ~> fst_below_iff
snd_less_iff ~> snd_below_iff
expand_cfun_less ~> cfun_below_iff
less_cfun_ext ~> cfun_belowI
injection_less ~> injection_below
less_up_def ~> below_up_def
not_Iup_less ~> not_Iup_below
Iup_less ~> Iup_below
up_less ~> up_below
Def_inject_less_eq ~> Def_below_Def
Def_less_is_eq ~> Def_below_iff
spair_less_iff ~> spair_below_iff
less_sprod ~> below_sprod
spair_less ~> spair_below
sfst_less_iff ~> sfst_below_iff
ssnd_less_iff ~> ssnd_below_iff
fix_least_less ~> fix_least_below
dist_less_one ~> dist_below_one
less_ONE ~> below_ONE
ONE_less_iff ~> ONE_below_iff
less_sinlD ~> below_sinlD
less_sinrD ~> below_sinrD
*** FOL and ZF ***
* All constant names are now qualified internally and use proper
identifiers, e.g. "IFOL.eq" instead of "op =". INCOMPATIBILITY.
*** ML ***
* Antiquotation @{assert} inlines a function bool -> unit that raises
Fail if the argument is false. Due to inlining the source position of
failed assertions is included in the error output.
* Discontinued antiquotation @{theory_ref}, which is obsolete since ML
text is in practice always evaluated with a stable theory checkpoint.
Minor INCOMPATIBILITY, use (Theory.check_thy @{theory}) instead.
* Antiquotation @{theory A} refers to theory A from the ancestry of
the current context, not any accidental theory loader state as before.
Potential INCOMPATIBILITY, subtle change in semantics.
* Syntax.pretty_priority (default 0) configures the required priority
of pretty-printed output and thus affects insertion of parentheses.
* Syntax.default_root (default "any") configures the inner syntax
category (nonterminal symbol) for parsing of terms.
* Former exception Library.UnequalLengths now coincides with
ListPair.UnequalLengths.
* Renamed structure MetaSimplifier to Raw_Simplifier. Note that the
main functionality is provided by structure Simplifier.
* Renamed raw "explode" function to "raw_explode" to emphasize its
meaning. Note that internally to Isabelle, Symbol.explode is used in
almost all situations.
* Discontinued obsolete function sys_error and exception SYS_ERROR.
See implementation manual for further details on exceptions in
Isabelle/ML.
* Renamed setmp_noncritical to Unsynchronized.setmp to emphasize its
meaning.
* Renamed structure PureThy to Pure_Thy and moved most of its
operations to structure Global_Theory, to emphasize that this is
rarely-used global-only stuff.
* Discontinued Output.debug. Minor INCOMPATIBILITY, use plain writeln
instead (or tracing for high-volume output).
* Configuration option show_question_marks only affects regular pretty
printing of types and terms, not raw Term.string_of_vname.
* ML_Context.thm and ML_Context.thms are no longer pervasive. Rare
INCOMPATIBILITY, superseded by static antiquotations @{thm} and
@{thms} for most purposes.
* ML structure Unsynchronized is never opened, not even in Isar
interaction mode as before. Old Unsynchronized.set etc. have been
discontinued -- use plain := instead. This should be *rare* anyway,
since modern tools always work via official context data, notably
configuration options.
* Parallel and asynchronous execution requires special care concerning
interrupts. Structure Exn provides some convenience functions that
avoid working directly with raw Interrupt. User code must not absorb
interrupts -- intermediate handling (for cleanup etc.) needs to be
followed by re-raising of the original exception. Another common
source of mistakes are "handle _" patterns, which make the meaning of
the program subject to physical effects of the environment.
New in Isabelle2009-2 (June 2010)
---------------------------------
*** General ***
* Authentic syntax for *all* logical entities (type classes, type
constructors, term constants): provides simple and robust
correspondence between formal entities and concrete syntax. Within
the parse tree / AST representations, "constants" are decorated by
their category (class, type, const) and spelled out explicitly with
their full internal name.
Substantial INCOMPATIBILITY concerning low-level syntax declarations
and translations (translation rules and translation functions in ML).
Some hints on upgrading:
- Many existing uses of 'syntax' and 'translations' can be replaced
by more modern 'type_notation', 'notation' and 'abbreviation',
which are independent of this issue.
- 'translations' require markup within the AST; the term syntax
provides the following special forms:
CONST c -- produces syntax version of constant c from context
XCONST c -- literally c, checked as constant from context
c -- literally c, if declared by 'syntax'
Plain identifiers are treated as AST variables -- occasionally the
system indicates accidental variables via the error "rhs contains
extra variables".
Type classes and type constructors are marked according to their
concrete syntax. Some old translations rules need to be written
for the "type" category, using type constructor application
instead of pseudo-term application of the default category
"logic".
- 'parse_translation' etc. in ML may use the following
antiquotations:
@{class_syntax c} -- type class c within parse tree / AST
@{term_syntax c} -- type constructor c within parse tree / AST
@{const_syntax c} -- ML version of "CONST c" above
@{syntax_const c} -- literally c (checked wrt. 'syntax' declarations)
- Literal types within 'typed_print_translations', i.e. those *not*
represented as pseudo-terms are represented verbatim. Use @{class
c} or @{type_name c} here instead of the above syntax
antiquotations.
Note that old non-authentic syntax was based on unqualified base
names, so all of the above "constant" names would coincide. Recall
that 'print_syntax' and ML_command "set Syntax.trace_ast" help to
diagnose syntax problems.
* Type constructors admit general mixfix syntax, not just infix.
* Concrete syntax may be attached to local entities without a proof
body, too. This works via regular mixfix annotations for 'fix',
'def', 'obtain' etc. or via the explicit 'write' command, which is
similar to the 'notation' command in theory specifications.
* Discontinued unnamed infix syntax (legacy feature for many years) --
need to specify constant name and syntax separately. Internal ML
datatype constructors have been renamed from InfixName to Infix etc.
Minor INCOMPATIBILITY.
* Schematic theorem statements need to be explicitly markup as such,
via commands 'schematic_lemma', 'schematic_theorem',
'schematic_corollary'. Thus the relevance of the proof is made
syntactically clear, which impacts performance in a parallel or
asynchronous interactive environment. Minor INCOMPATIBILITY.
* Use of cumulative prems via "!" in some proof methods has been
discontinued (old legacy feature).
* References 'trace_simp' and 'debug_simp' have been replaced by
configuration options stored in the context. Enabling tracing (the
case of debugging is similar) in proofs works via
using [[trace_simp = true]]
Tracing is then active for all invocations of the simplifier in
subsequent goal refinement steps. Tracing may also still be enabled or
disabled via the ProofGeneral settings menu.
* Separate commands 'hide_class', 'hide_type', 'hide_const',
'hide_fact' replace the former 'hide' KIND command. Minor
INCOMPATIBILITY.
* Improved parallelism of proof term normalization: usedir -p2 -q0 is
more efficient than combinations with -q1 or -q2.
*** Pure ***
* Proofterms record type-class reasoning explicitly, using the
"unconstrain" operation internally. This eliminates all sort
constraints from a theorem and proof, introducing explicit
OFCLASS-premises. On the proof term level, this operation is
automatically applied at theorem boundaries, such that closed proofs
are always free of sort constraints. INCOMPATIBILITY for tools that
inspect proof terms.
* Local theory specifications may depend on extra type variables that
are not present in the result type -- arguments TYPE('a) :: 'a itself
are added internally. For example:
definition unitary :: bool where "unitary = (ALL (x::'a) y. x = y)"
* Predicates of locales introduced by classes carry a mandatory
"class" prefix. INCOMPATIBILITY.
* Vacuous class specifications observe default sort. INCOMPATIBILITY.
* Old 'axclass' command has been discontinued. INCOMPATIBILITY, use
'class' instead.
* Command 'code_reflect' allows to incorporate generated ML code into
runtime environment; replaces immature code_datatype antiquotation.
INCOMPATIBILITY.
* Code generator: simple concept for abstract datatypes obeying
invariants.
* Code generator: details of internal data cache have no impact on the
user space functionality any longer.
* Methods "unfold_locales" and "intro_locales" ignore non-locale
subgoals. This is more appropriate for interpretations with 'where'.
INCOMPATIBILITY.
* Command 'example_proof' opens an empty proof body. This allows to
experiment with Isar, without producing any persistent result.
* Commands 'type_notation' and 'no_type_notation' declare type syntax
within a local theory context, with explicit checking of the
constructors involved (in contrast to the raw 'syntax' versions).
* Commands 'types' and 'typedecl' now work within a local theory
context -- without introducing dependencies on parameters or
assumptions, which is not possible in Isabelle/Pure.
* Command 'defaultsort' has been renamed to 'default_sort', it works
within a local theory context. Minor INCOMPATIBILITY.
*** HOL ***
* Command 'typedef' now works within a local theory context -- without
introducing dependencies on parameters or assumptions, which is not
possible in Isabelle/Pure/HOL. Note that the logical environment may
contain multiple interpretations of local typedefs (with different
non-emptiness proofs), even in a global theory context.
* New package for quotient types. Commands 'quotient_type' and
'quotient_definition' may be used for defining types and constants by
quotient constructions. An example is the type of integers created by
quotienting pairs of natural numbers:
fun
intrel :: "(nat * nat) => (nat * nat) => bool"
where
"intrel (x, y) (u, v) = (x + v = u + y)"
quotient_type int = "nat * nat" / intrel
by (auto simp add: equivp_def expand_fun_eq)
quotient_definition
"0::int" is "(0::nat, 0::nat)"
The method "lifting" can be used to lift of theorems from the
underlying "raw" type to the quotient type. The example
src/HOL/Quotient_Examples/FSet.thy includes such a quotient
construction and provides a reasoning infrastructure for finite sets.
* Renamed Library/Quotient.thy to Library/Quotient_Type.thy to avoid
clash with new theory Quotient in Main HOL.
* Moved the SMT binding into the main HOL session, eliminating
separate HOL-SMT session.
* List membership infix mem operation is only an input abbreviation.
INCOMPATIBILITY.
* Theory Library/Word.thy has been removed. Use library Word/Word.thy
for future developements; former Library/Word.thy is still present in
the AFP entry RSAPPS.
* Theorem Int.int_induct renamed to Int.int_of_nat_induct and is no
longer shadowed. INCOMPATIBILITY.
* Dropped theorem duplicate comp_arith; use semiring_norm instead.
INCOMPATIBILITY.
* Dropped theorem RealPow.real_sq_order; use power2_le_imp_le instead.
INCOMPATIBILITY.
* Dropped normalizing_semiring etc; use the facts in semiring classes
instead. INCOMPATIBILITY.
* Dropped several real-specific versions of lemmas about floor and
ceiling; use the generic lemmas from theory "Archimedean_Field"
instead. INCOMPATIBILITY.
floor_number_of_eq ~> floor_number_of
le_floor_eq_number_of ~> number_of_le_floor
le_floor_eq_zero ~> zero_le_floor
le_floor_eq_one ~> one_le_floor
floor_less_eq_number_of ~> floor_less_number_of
floor_less_eq_zero ~> floor_less_zero
floor_less_eq_one ~> floor_less_one
less_floor_eq_number_of ~> number_of_less_floor
less_floor_eq_zero ~> zero_less_floor
less_floor_eq_one ~> one_less_floor
floor_le_eq_number_of ~> floor_le_number_of
floor_le_eq_zero ~> floor_le_zero
floor_le_eq_one ~> floor_le_one
floor_subtract_number_of ~> floor_diff_number_of
floor_subtract_one ~> floor_diff_one
ceiling_number_of_eq ~> ceiling_number_of
ceiling_le_eq_number_of ~> ceiling_le_number_of
ceiling_le_zero_eq ~> ceiling_le_zero
ceiling_le_eq_one ~> ceiling_le_one
less_ceiling_eq_number_of ~> number_of_less_ceiling
less_ceiling_eq_zero ~> zero_less_ceiling
less_ceiling_eq_one ~> one_less_ceiling
ceiling_less_eq_number_of ~> ceiling_less_number_of
ceiling_less_eq_zero ~> ceiling_less_zero
ceiling_less_eq_one ~> ceiling_less_one
le_ceiling_eq_number_of ~> number_of_le_ceiling
le_ceiling_eq_zero ~> zero_le_ceiling
le_ceiling_eq_one ~> one_le_ceiling
ceiling_subtract_number_of ~> ceiling_diff_number_of
ceiling_subtract_one ~> ceiling_diff_one
* Theory "Finite_Set": various folding_XXX locales facilitate the
application of the various fold combinators on finite sets.
* Library theory "RBT" renamed to "RBT_Impl"; new library theory "RBT"
provides abstract red-black tree type which is backed by "RBT_Impl" as
implementation. INCOMPATIBILTY.
* Theory Library/Coinductive_List has been removed -- superseded by
AFP/thys/Coinductive.
* Theory PReal, including the type "preal" and related operations, has
been removed. INCOMPATIBILITY.
* Real: new development using Cauchy Sequences.
* Split off theory "Big_Operators" containing setsum, setprod,
Inf_fin, Sup_fin, Min, Max from theory Finite_Set. INCOMPATIBILITY.
* Theory "Rational" renamed to "Rat", for consistency with "Nat",
"Int" etc. INCOMPATIBILITY.
* Constant Rat.normalize needs to be qualified. INCOMPATIBILITY.
* New set of rules "ac_simps" provides combined assoc / commute
rewrites for all interpretations of the appropriate generic locales.
* Renamed theory "OrderedGroup" to "Groups" and split theory
"Ring_and_Field" into theories "Rings" and "Fields"; for more
appropriate and more consistent names suitable for name prefixes
within the HOL theories. INCOMPATIBILITY.
* Some generic constants have been put to appropriate theories:
- less_eq, less: Orderings
- zero, one, plus, minus, uminus, times, abs, sgn: Groups
- inverse, divide: Rings
INCOMPATIBILITY.
* More consistent naming of type classes involving orderings (and
lattices):
lower_semilattice ~> semilattice_inf
upper_semilattice ~> semilattice_sup
dense_linear_order ~> dense_linorder
pordered_ab_group_add ~> ordered_ab_group_add
pordered_ab_group_add_abs ~> ordered_ab_group_add_abs
pordered_ab_semigroup_add ~> ordered_ab_semigroup_add
pordered_ab_semigroup_add_imp_le ~> ordered_ab_semigroup_add_imp_le
pordered_cancel_ab_semigroup_add ~> ordered_cancel_ab_semigroup_add
pordered_cancel_comm_semiring ~> ordered_cancel_comm_semiring
pordered_cancel_semiring ~> ordered_cancel_semiring
pordered_comm_monoid_add ~> ordered_comm_monoid_add
pordered_comm_ring ~> ordered_comm_ring
pordered_comm_semiring ~> ordered_comm_semiring
pordered_ring ~> ordered_ring
pordered_ring_abs ~> ordered_ring_abs
pordered_semiring ~> ordered_semiring
ordered_ab_group_add ~> linordered_ab_group_add
ordered_ab_semigroup_add ~> linordered_ab_semigroup_add
ordered_cancel_ab_semigroup_add ~> linordered_cancel_ab_semigroup_add
ordered_comm_semiring_strict ~> linordered_comm_semiring_strict
ordered_field ~> linordered_field
ordered_field_no_lb ~> linordered_field_no_lb
ordered_field_no_ub ~> linordered_field_no_ub
ordered_field_dense_linear_order ~> dense_linordered_field
ordered_idom ~> linordered_idom
ordered_ring ~> linordered_ring
ordered_ring_le_cancel_factor ~> linordered_ring_le_cancel_factor
ordered_ring_less_cancel_factor ~> linordered_ring_less_cancel_factor
ordered_ring_strict ~> linordered_ring_strict
ordered_semidom ~> linordered_semidom
ordered_semiring ~> linordered_semiring
ordered_semiring_1 ~> linordered_semiring_1
ordered_semiring_1_strict ~> linordered_semiring_1_strict
ordered_semiring_strict ~> linordered_semiring_strict
The following slightly odd type classes have been moved to a
separate theory Library/Lattice_Algebras:
lordered_ab_group_add ~> lattice_ab_group_add
lordered_ab_group_add_abs ~> lattice_ab_group_add_abs
lordered_ab_group_add_meet ~> semilattice_inf_ab_group_add
lordered_ab_group_add_join ~> semilattice_sup_ab_group_add
lordered_ring ~> lattice_ring
INCOMPATIBILITY.
* Refined field classes:
- classes division_ring_inverse_zero, field_inverse_zero,
linordered_field_inverse_zero include rule inverse 0 = 0 --
subsumes former division_by_zero class;
- numerous lemmas have been ported from field to division_ring.
INCOMPATIBILITY.
* Refined algebra theorem collections:
- dropped theorem group group_simps, use algebra_simps instead;
- dropped theorem group ring_simps, use field_simps instead;
- proper theorem collection field_simps subsumes former theorem
groups field_eq_simps and field_simps;
- dropped lemma eq_minus_self_iff which is a duplicate for
equal_neg_zero.
INCOMPATIBILITY.
* Theory Finite_Set and List: some lemmas have been generalized from
sets to lattices:
fun_left_comm_idem_inter ~> fun_left_comm_idem_inf
fun_left_comm_idem_union ~> fun_left_comm_idem_sup
inter_Inter_fold_inter ~> inf_Inf_fold_inf
union_Union_fold_union ~> sup_Sup_fold_sup
Inter_fold_inter ~> Inf_fold_inf
Union_fold_union ~> Sup_fold_sup
inter_INTER_fold_inter ~> inf_INFI_fold_inf
union_UNION_fold_union ~> sup_SUPR_fold_sup
INTER_fold_inter ~> INFI_fold_inf
UNION_fold_union ~> SUPR_fold_sup
* Theory "Complete_Lattice": lemmas top_def and bot_def have been
replaced by the more convenient lemmas Inf_empty and Sup_empty.
Dropped lemmas Inf_insert_simp and Sup_insert_simp, which are subsumed
by Inf_insert and Sup_insert. Lemmas Inf_UNIV and Sup_UNIV replace
former Inf_Univ and Sup_Univ. Lemmas inf_top_right and sup_bot_right
subsume inf_top and sup_bot respectively. INCOMPATIBILITY.
* Reorganized theory Multiset: swapped notation of pointwise and
multiset order:
- pointwise ordering is instance of class order with standard syntax
<= and <;
- multiset ordering has syntax <=# and <#; partial order properties
are provided by means of interpretation with prefix
multiset_order;
- less duplication, less historical organization of sections,
conversion from associations lists to multisets, rudimentary code
generation;
- use insert_DiffM2 [symmetric] instead of elem_imp_eq_diff_union,
if needed.
Renamed:
multiset_eq_conv_count_eq ~> multiset_ext_iff
multi_count_ext ~> multiset_ext
diff_union_inverse2 ~> diff_union_cancelR
INCOMPATIBILITY.
* Theory Permutation: replaced local "remove" by List.remove1.
* Code generation: ML and OCaml code is decorated with signatures.
* Theory List: added transpose.
* Library/Nat_Bijection.thy is a collection of bijective functions
between nat and other types, which supersedes the older libraries
Library/Nat_Int_Bij.thy and HOLCF/NatIso.thy. INCOMPATIBILITY.
Constants:
Nat_Int_Bij.nat2_to_nat ~> prod_encode
Nat_Int_Bij.nat_to_nat2 ~> prod_decode
Nat_Int_Bij.int_to_nat_bij ~> int_encode
Nat_Int_Bij.nat_to_int_bij ~> int_decode
Countable.pair_encode ~> prod_encode
NatIso.prod2nat ~> prod_encode
NatIso.nat2prod ~> prod_decode
NatIso.sum2nat ~> sum_encode
NatIso.nat2sum ~> sum_decode
NatIso.list2nat ~> list_encode
NatIso.nat2list ~> list_decode
NatIso.set2nat ~> set_encode
NatIso.nat2set ~> set_decode
Lemmas:
Nat_Int_Bij.bij_nat_to_int_bij ~> bij_int_decode
Nat_Int_Bij.nat2_to_nat_inj ~> inj_prod_encode
Nat_Int_Bij.nat2_to_nat_surj ~> surj_prod_encode
Nat_Int_Bij.nat_to_nat2_inj ~> inj_prod_decode
Nat_Int_Bij.nat_to_nat2_surj ~> surj_prod_decode
Nat_Int_Bij.i2n_n2i_id ~> int_encode_inverse
Nat_Int_Bij.n2i_i2n_id ~> int_decode_inverse
Nat_Int_Bij.surj_nat_to_int_bij ~> surj_int_encode
Nat_Int_Bij.surj_int_to_nat_bij ~> surj_int_decode
Nat_Int_Bij.inj_nat_to_int_bij ~> inj_int_encode
Nat_Int_Bij.inj_int_to_nat_bij ~> inj_int_decode
Nat_Int_Bij.bij_nat_to_int_bij ~> bij_int_encode
Nat_Int_Bij.bij_int_to_nat_bij ~> bij_int_decode
* Sledgehammer:
- Renamed ATP commands:
atp_info ~> sledgehammer running_atps
atp_kill ~> sledgehammer kill_atps
atp_messages ~> sledgehammer messages
atp_minimize ~> sledgehammer minimize
print_atps ~> sledgehammer available_atps
INCOMPATIBILITY.
- Added user's manual ("isabelle doc sledgehammer").
- Added option syntax and "sledgehammer_params" to customize
Sledgehammer's behavior. See the manual for details.
- Modified the Isar proof reconstruction code so that it produces
direct proofs rather than proofs by contradiction. (This feature
is still experimental.)
- Made Isar proof reconstruction work for SPASS, remote ATPs, and in
full-typed mode.
- Added support for TPTP syntax for SPASS via the "spass_tptp" ATP.
* Nitpick:
- Added and implemented "binary_ints" and "bits" options.
- Added "std" option and implemented support for nonstandard models.
- Added and implemented "finitize" option to improve the precision
of infinite datatypes based on a monotonicity analysis.
- Added support for quotient types.
- Added support for "specification" and "ax_specification"
constructs.
- Added support for local definitions (for "function" and
"termination" proofs).
- Added support for term postprocessors.
- Optimized "Multiset.multiset" and "FinFun.finfun".
- Improved efficiency of "destroy_constrs" optimization.
- Fixed soundness bugs related to "destroy_constrs" optimization and
record getters.
- Fixed soundness bug related to higher-order constructors.
- Fixed soundness bug when "full_descrs" is enabled.
- Improved precision of set constructs.
- Added "atoms" option.
- Added cache to speed up repeated Kodkod invocations on the same
problems.
- Renamed "MiniSatJNI", "zChaffJNI", "BerkMinAlloy", and
"SAT4JLight" to "MiniSat_JNI", "zChaff_JNI", "BerkMin_Alloy", and
"SAT4J_Light". INCOMPATIBILITY.
- Removed "skolemize", "uncurry", "sym_break", "flatten_prop",
"sharing_depth", and "show_skolems" options. INCOMPATIBILITY.
- Removed "nitpick_intro" attribute. INCOMPATIBILITY.
* Method "induct" now takes instantiations of the form t, where t is not
a variable, as a shorthand for "x == t", where x is a fresh variable.
If this is not intended, t has to be enclosed in parentheses.
By default, the equalities generated by definitional instantiations
are pre-simplified, which may cause parameters of inductive cases
to disappear, or may even delete some of the inductive cases.
Use "induct (no_simp)" instead of "induct" to restore the old
behaviour. The (no_simp) option is also understood by the "cases"
and "nominal_induct" methods, which now perform pre-simplification, too.
INCOMPATIBILITY.
*** HOLCF ***
* Variable names in lemmas generated by the domain package have
changed; the naming scheme is now consistent with the HOL datatype
package. Some proof scripts may be affected, INCOMPATIBILITY.
* The domain package no longer defines the function "foo_copy" for
recursive domain "foo". The reach lemma is now stated directly in
terms of "foo_take". Lemmas and proofs that mention "foo_copy" must
be reformulated in terms of "foo_take", INCOMPATIBILITY.
* Most definedness lemmas generated by the domain package (previously
of the form "x ~= UU ==> foo$x ~= UU") now have an if-and-only-if form
like "foo$x = UU <-> x = UU", which works better as a simp rule.
Proofs that used definedness lemmas as intro rules may break,
potential INCOMPATIBILITY.
* Induction and casedist rules generated by the domain package now
declare proper case_names (one called "bottom", and one named for each
constructor). INCOMPATIBILITY.
* For mutually-recursive domains, separate "reach" and "take_lemma"
rules are generated for each domain, INCOMPATIBILITY.
foo_bar.reach ~> foo.reach bar.reach
foo_bar.take_lemmas ~> foo.take_lemma bar.take_lemma
* Some lemmas generated by the domain package have been renamed for
consistency with the datatype package, INCOMPATIBILITY.
foo.ind ~> foo.induct
foo.finite_ind ~> foo.finite_induct
foo.coind ~> foo.coinduct
foo.casedist ~> foo.exhaust
foo.exhaust ~> foo.nchotomy
* For consistency with other definition packages, the fixrec package
now generates qualified theorem names, INCOMPATIBILITY.
foo_simps ~> foo.simps
foo_unfold ~> foo.unfold
foo_induct ~> foo.induct
* The "fixrec_simp" attribute has been removed. The "fixrec_simp"
method and internal fixrec proofs now use the default simpset instead.
INCOMPATIBILITY.
* The "contlub" predicate has been removed. Proof scripts should use
lemma contI2 in place of monocontlub2cont, INCOMPATIBILITY.
* The "admw" predicate has been removed, INCOMPATIBILITY.
* The constants cpair, cfst, and csnd have been removed in favor of
Pair, fst, and snd from Isabelle/HOL, INCOMPATIBILITY.
*** ML ***
* Antiquotations for basic formal entities:
@{class NAME} -- type class
@{class_syntax NAME} -- syntax representation of the above
@{type_name NAME} -- logical type
@{type_abbrev NAME} -- type abbreviation
@{nonterminal NAME} -- type of concrete syntactic category
@{type_syntax NAME} -- syntax representation of any of the above
@{const_name NAME} -- logical constant (INCOMPATIBILITY)
@{const_abbrev NAME} -- abbreviated constant
@{const_syntax NAME} -- syntax representation of any of the above
* Antiquotation @{syntax_const NAME} ensures that NAME refers to a raw
syntax constant (cf. 'syntax' command).
* Antiquotation @{make_string} inlines a function to print arbitrary
values similar to the ML toplevel. The result is compiler dependent
and may fall back on "?" in certain situations.
* Diagnostic commands 'ML_val' and 'ML_command' may refer to
antiquotations @{Isar.state} and @{Isar.goal}. This replaces impure
Isar.state() and Isar.goal(), which belong to the old TTY loop and do
not work with the asynchronous Isar document model.
* Configuration options now admit dynamic default values, depending on
the context or even global references.
* SHA1.digest digests strings according to SHA-1 (see RFC 3174). It
uses an efficient external library if available (for Poly/ML).
* Renamed some important ML structures, while keeping the old names
for some time as aliases within the structure Legacy:
OuterKeyword ~> Keyword
OuterLex ~> Token
OuterParse ~> Parse
OuterSyntax ~> Outer_Syntax
PrintMode ~> Print_Mode
SpecParse ~> Parse_Spec
ThyInfo ~> Thy_Info
ThyLoad ~> Thy_Load
ThyOutput ~> Thy_Output
TypeInfer ~> Type_Infer
Note that "open Legacy" simplifies porting of sources, but forgetting
to remove it again will complicate porting again in the future.
* Most operations that refer to a global context are named
accordingly, e.g. Simplifier.global_context or
ProofContext.init_global. There are some situations where a global
context actually works, but under normal circumstances one needs to
pass the proper local context through the code!
* Discontinued old TheoryDataFun with its copy/init operation -- data
needs to be pure. Functor Theory_Data_PP retains the traditional
Pretty.pp argument to merge, which is absent in the standard
Theory_Data version.
* Sorts.certify_sort and derived "cert" operations for types and terms
no longer minimize sorts. Thus certification at the boundary of the
inference kernel becomes invariant under addition of class relations,
which is an important monotonicity principle. Sorts are now minimized
in the syntax layer only, at the boundary between the end-user and the
system. Subtle INCOMPATIBILITY, may have to use Sign.minimize_sort
explicitly in rare situations.
* Renamed old-style Drule.standard to Drule.export_without_context, to
emphasize that this is in no way a standard operation.
INCOMPATIBILITY.
* Subgoal.FOCUS (and variants): resulting goal state is normalized as
usual for resolution. Rare INCOMPATIBILITY.
* Renamed varify/unvarify operations to varify_global/unvarify_global
to emphasize that these only work in a global situation (which is
quite rare).
* Curried take and drop in library.ML; negative length is interpreted
as infinity (as in chop). Subtle INCOMPATIBILITY.
* Proof terms: type substitutions on proof constants now use canonical
order of type variables. INCOMPATIBILITY for tools working with proof
terms.
* Raw axioms/defs may no longer carry sort constraints, and raw defs
may no longer carry premises. User-level specifications are
transformed accordingly by Thm.add_axiom/add_def.
*** System ***
* Discontinued special HOL_USEDIR_OPTIONS for the main HOL image;
ISABELLE_USEDIR_OPTIONS applies uniformly to all sessions. Note that
proof terms are enabled unconditionally in the new HOL-Proofs image.
* Discontinued old ISABELLE and ISATOOL environment settings (legacy
feature since Isabelle2009). Use ISABELLE_PROCESS and ISABELLE_TOOL,
respectively.
* Old lib/scripts/polyml-platform is superseded by the
ISABELLE_PLATFORM setting variable, which defaults to the 32 bit
variant, even on a 64 bit machine. The following example setting
prefers 64 bit if available:
ML_PLATFORM="${ISABELLE_PLATFORM64:-$ISABELLE_PLATFORM}"
* The preliminary Isabelle/jEdit application demonstrates the emerging
Isabelle/Scala layer for advanced prover interaction and integration.
See src/Tools/jEdit or "isabelle jedit" provided by the properly built
component.
* "IsabelleText" is a Unicode font derived from Bitstream Vera Mono
and Bluesky TeX fonts. It provides the usual Isabelle symbols,
similar to the default assignment of the document preparation system
(cf. isabellesym.sty). The Isabelle/Scala class Isabelle_System
provides some operations for direct access to the font without asking
the user for manual installation.
New in Isabelle2009-1 (December 2009)
-------------------------------------
*** General ***
* Discontinued old form of "escaped symbols" such as \\. Only
one backslash should be used, even in ML sources.
*** Pure ***
* Locale interpretation propagates mixins along the locale hierarchy.
The currently only available mixins are the equations used to map
local definitions to terms of the target domain of an interpretation.
* Reactivated diagnostic command 'print_interps'. Use "print_interps
loc" to print all interpretations of locale "loc" in the theory.
Interpretations in proofs are not shown.
* Thoroughly revised locales tutorial. New section on conditional
interpretation.
* On instantiation of classes, remaining undefined class parameters
are formally declared. INCOMPATIBILITY.
*** Document preparation ***
* New generalized style concept for printing terms: @{foo (style) ...}
instead of @{foo_style style ...} (old form is still retained for
backward compatibility). Styles can be also applied for
antiquotations prop, term_type and typeof.
*** HOL ***
* New proof method "smt" for a combination of first-order logic with
equality, linear and nonlinear (natural/integer/real) arithmetic, and
fixed-size bitvectors; there is also basic support for higher-order
features (esp. lambda abstractions). It is an incomplete decision
procedure based on external SMT solvers using the oracle mechanism;
for the SMT solver Z3, this method is proof-producing. Certificates
are provided to avoid calling the external solvers solely for
re-checking proofs. Due to a remote SMT service there is no need for
installing SMT solvers locally. See src/HOL/SMT.
* New commands to load and prove verification conditions generated by
the Boogie program verifier or derived systems (e.g. the Verifying C
Compiler (VCC) or Spec#). See src/HOL/Boogie.
* New counterexample generator tool 'nitpick' based on the Kodkod
relational model finder. See src/HOL/Tools/Nitpick and
src/HOL/Nitpick_Examples.
* New commands 'code_pred' and 'values' to invoke the predicate
compiler and to enumerate values of inductive predicates.
* A tabled implementation of the reflexive transitive closure.
* New implementation of quickcheck uses generic code generator;
default generators are provided for all suitable HOL types, records
and datatypes. Old quickcheck can be re-activated importing theory
Library/SML_Quickcheck.
* New testing tool Mirabelle for automated proof tools. Applies
several tools and tactics like sledgehammer, metis, or quickcheck, to
every proof step in a theory. To be used in batch mode via the
"mirabelle" utility.
* New proof method "sos" (sum of squares) for nonlinear real
arithmetic (originally due to John Harison). It requires theory
Library/Sum_Of_Squares. It is not a complete decision procedure but
works well in practice on quantifier-free real arithmetic with +, -,
*, ^, =, <= and <, i.e. boolean combinations of equalities and
inequalities between polynomials. It makes use of external
semidefinite programming solvers. Method "sos" generates a
certificate that can be pasted into the proof thus avoiding the need
to call an external tool every time the proof is checked. See
src/HOL/Library/Sum_Of_Squares.
* New method "linarith" invokes existing linear arithmetic decision
procedure only.
* New command 'atp_minimal' reduces result produced by Sledgehammer.
* New Sledgehammer option "Full Types" in Proof General settings menu.
Causes full type information to be output to the ATPs. This slows
ATPs down considerably but eliminates a source of unsound "proofs"
that fail later.
* New method "metisFT": A version of metis that uses full type
information in order to avoid failures of proof reconstruction.
* New evaluator "approximate" approximates an real valued term using
the same method as the approximation method.
* Method "approximate" now supports arithmetic expressions as
boundaries of intervals and implements interval splitting and Taylor
series expansion.
* ML antiquotation @{code_datatype} inserts definition of a datatype
generated by the code generator; e.g. see src/HOL/Predicate.thy.
* New theory SupInf of the supremum and infimum operators for sets of
reals.
* New theory Probability, which contains a development of measure
theory, eventually leading to Lebesgue integration and probability.
* Extended Multivariate Analysis to include derivation and Brouwer's
fixpoint theorem.
* Reorganization of number theory, INCOMPATIBILITY:
- new number theory development for nat and int, in theories Divides
and GCD as well as in new session Number_Theory
- some constants and facts now suffixed with _nat and _int
accordingly
- former session NumberTheory now named Old_Number_Theory, including
theories Legacy_GCD and Primes (prefer Number_Theory if possible)
- moved theory Pocklington from src/HOL/Library to
src/HOL/Old_Number_Theory
* Theory GCD includes functions Gcd/GCD and Lcm/LCM for the gcd and
lcm of finite and infinite sets. It is shown that they form a complete
lattice.
* Class semiring_div requires superclass no_zero_divisors and proof of
div_mult_mult1; theorems div_mult_mult1, div_mult_mult2,
div_mult_mult1_if, div_mult_mult1 and div_mult_mult2 have been
generalized to class semiring_div, subsuming former theorems
zdiv_zmult_zmult1, zdiv_zmult_zmult1_if, zdiv_zmult_zmult1 and
zdiv_zmult_zmult2. div_mult_mult1 is now [simp] by default.
INCOMPATIBILITY.
* Refinements to lattice classes and sets:
- less default intro/elim rules in locale variant, more default
intro/elim rules in class variant: more uniformity
- lemma ge_sup_conv renamed to le_sup_iff, in accordance with
le_inf_iff
- dropped lemma alias inf_ACI for inf_aci (same for sup_ACI and
sup_aci)
- renamed ACI to inf_sup_aci
- new class "boolean_algebra"
- class "complete_lattice" moved to separate theory
"Complete_Lattice"; corresponding constants (and abbreviations)
renamed and with authentic syntax:
Set.Inf ~> Complete_Lattice.Inf
Set.Sup ~> Complete_Lattice.Sup
Set.INFI ~> Complete_Lattice.INFI
Set.SUPR ~> Complete_Lattice.SUPR
Set.Inter ~> Complete_Lattice.Inter
Set.Union ~> Complete_Lattice.Union
Set.INTER ~> Complete_Lattice.INTER
Set.UNION ~> Complete_Lattice.UNION
- authentic syntax for
Set.Pow
Set.image
- mere abbreviations:
Set.empty (for bot)
Set.UNIV (for top)
Set.inter (for inf, formerly Set.Int)
Set.union (for sup, formerly Set.Un)
Complete_Lattice.Inter (for Inf)
Complete_Lattice.Union (for Sup)
Complete_Lattice.INTER (for INFI)
Complete_Lattice.UNION (for SUPR)
- object-logic definitions as far as appropriate
INCOMPATIBILITY. Care is required when theorems Int_subset_iff or
Un_subset_iff are explicitly deleted as default simp rules; then also
their lattice counterparts le_inf_iff and le_sup_iff have to be
deleted to achieve the desired effect.
* Rules inf_absorb1, inf_absorb2, sup_absorb1, sup_absorb2 are no simp
rules by default any longer; the same applies to min_max.inf_absorb1
etc. INCOMPATIBILITY.
* Rules sup_Int_eq and sup_Un_eq are no longer declared as
pred_set_conv by default. INCOMPATIBILITY.
* Power operations on relations and functions are now one dedicated
constant "compow" with infix syntax "^^". Power operation on
multiplicative monoids retains syntax "^" and is now defined generic
in class power. INCOMPATIBILITY.
* Relation composition "R O S" now has a more standard argument order:
"R O S = {(x, z). EX y. (x, y) : R & (y, z) : S}". INCOMPATIBILITY,
rewrite propositions with "S O R" --> "R O S". Proofs may occasionally
break, since the O_assoc rule was not rewritten like this. Fix using
O_assoc[symmetric]. The same applies to the curried version "R OO S".
* Function "Inv" is renamed to "inv_into" and function "inv" is now an
abbreviation for "inv_into UNIV". Lemmas are renamed accordingly.
INCOMPATIBILITY.
* Most rules produced by inductive and datatype package have mandatory
prefixes. INCOMPATIBILITY.
* Changed "DERIV_intros" to a dynamic fact, which can be augmented by
the attribute of the same name. Each of the theorems in the list
DERIV_intros assumes composition with an additional function and
matches a variable to the derivative, which has to be solved by the
Simplifier. Hence (auto intro!: DERIV_intros) computes the derivative
of most elementary terms. Former Maclauren.DERIV_tac and
Maclauren.deriv_tac should be replaced by (auto intro!: DERIV_intros).
INCOMPATIBILITY.
* Code generator attributes follow the usual underscore convention:
code_unfold replaces code unfold
code_post replaces code post
etc.
INCOMPATIBILITY.
* Renamed methods:
sizechange -> size_change
induct_scheme -> induction_schema
INCOMPATIBILITY.
* Discontinued abbreviation "arbitrary" of constant "undefined".
INCOMPATIBILITY, use "undefined" directly.
* Renamed theorems:
Suc_eq_add_numeral_1 -> Suc_eq_plus1
Suc_eq_add_numeral_1_left -> Suc_eq_plus1_left
Suc_plus1 -> Suc_eq_plus1
*anti_sym -> *antisym*
vector_less_eq_def -> vector_le_def
INCOMPATIBILITY.
* Added theorem List.map_map as [simp]. Removed List.map_compose.
INCOMPATIBILITY.
* Removed predicate "M hassize n" (<--> card M = n & finite M).
INCOMPATIBILITY.
*** HOLCF ***
* Theory Representable defines a class "rep" of domains that are
representable (via an ep-pair) in the universal domain type "udom".
Instances are provided for all type constructors defined in HOLCF.
* The 'new_domain' command is a purely definitional version of the
domain package, for representable domains. Syntax is identical to the
old domain package. The 'new_domain' package also supports indirect
recursion using previously-defined type constructors. See
src/HOLCF/ex/New_Domain.thy for examples.
* Method "fixrec_simp" unfolds one step of a fixrec-defined constant
on the left-hand side of an equation, and then performs
simplification. Rewriting is done using rules declared with the
"fixrec_simp" attribute. The "fixrec_simp" method is intended as a
replacement for "fixpat"; see src/HOLCF/ex/Fixrec_ex.thy for examples.
* The pattern-match compiler in 'fixrec' can now handle constructors
with HOL function types. Pattern-match combinators for the Pair
constructor are pre-configured.
* The 'fixrec' package now produces better fixed-point induction rules
for mutually-recursive definitions: Induction rules have conclusions
of the form "P foo bar" instead of "P ".
* The constant "sq_le" (with infix syntax "<<" or "\") has
been renamed to "below". The name "below" now replaces "less" in many
theorem names. (Legacy theorem names using "less" are still supported
as well.)
* The 'fixrec' package now supports "bottom patterns". Bottom
patterns can be used to generate strictness rules, or to make
functions more strict (much like the bang-patterns supported by the
Glasgow Haskell Compiler). See src/HOLCF/ex/Fixrec_ex.thy for
examples.
*** ML ***
* Support for Poly/ML 5.3.0, with improved reporting of compiler
errors and run-time exceptions, including detailed source positions.
* Structure Name_Space (formerly NameSpace) now manages uniquely
identified entries, with some additional information such as source
position, logical grouping etc.
* Theory and context data is now introduced by the simplified and
modernized functors Theory_Data, Proof_Data, Generic_Data. Data needs
to be pure, but the old TheoryDataFun for mutable data (with explicit
copy operation) is still available for some time.
* Structure Synchronized (cf. src/Pure/Concurrent/synchronized.ML)
provides a high-level programming interface to synchronized state
variables with atomic update. This works via pure function
application within a critical section -- its runtime should be as
short as possible; beware of deadlocks if critical code is nested,
either directly or indirectly via other synchronized variables!
* Structure Unsynchronized (cf. src/Pure/ML-Systems/unsynchronized.ML)
wraps raw ML references, explicitly indicating their non-thread-safe
behaviour. The Isar toplevel keeps this structure open, to
accommodate Proof General as well as quick and dirty interactive
experiments with references.
* PARALLEL_CHOICE and PARALLEL_GOALS provide basic support for
parallel tactical reasoning.
* Tacticals Subgoal.FOCUS, Subgoal.FOCUS_PREMS, Subgoal.FOCUS_PARAMS
are similar to SUBPROOF, but are slightly more flexible: only the
specified parts of the subgoal are imported into the context, and the
body tactic may introduce new subgoals and schematic variables.
* Old tactical METAHYPS, which does not observe the proof context, has
been renamed to Old_Goals.METAHYPS and awaits deletion. Use SUBPROOF
or Subgoal.FOCUS etc.
* Renamed functor TableFun to Table, and GraphFun to Graph. (Since
functors have their own ML name space there is no point to mark them
separately.) Minor INCOMPATIBILITY.
* Renamed NamedThmsFun to Named_Thms. INCOMPATIBILITY.
* Renamed several structures FooBar to Foo_Bar. Occasional,
INCOMPATIBILITY.
* Operations of structure Skip_Proof no longer require quick_and_dirty
mode, which avoids critical setmp.
* Eliminated old Attrib.add_attributes, Method.add_methods and related
combinators for "args". INCOMPATIBILITY, need to use simplified
Attrib/Method.setup introduced in Isabelle2009.
* Proper context for simpset_of, claset_of, clasimpset_of. May fall
back on global_simpset_of, global_claset_of, global_clasimpset_of as
last resort. INCOMPATIBILITY.
* Display.pretty_thm now requires a proper context (cf. former
ProofContext.pretty_thm). May fall back on Display.pretty_thm_global
or even Display.pretty_thm_without_context as last resort.
INCOMPATIBILITY.
* Discontinued Display.pretty_ctyp/cterm etc. INCOMPATIBILITY, use
Syntax.pretty_typ/term directly, preferably with proper context
instead of global theory.
*** System ***
* Further fine tuning of parallel proof checking, scales up to 8 cores
(max. speedup factor 5.0). See also Goal.parallel_proofs in ML and
usedir option -q.
* Support for additional "Isabelle components" via etc/components, see
also the system manual.
* The isabelle makeall tool now operates on all components with
IsaMakefile, not just hardwired "logics".
* Removed "compress" option from isabelle-process and isabelle usedir;
this is always enabled.
* Discontinued support for Poly/ML 4.x versions.
* Isabelle tool "wwwfind" provides web interface for 'find_theorems'
on a given logic image. This requires the lighttpd webserver and is
currently supported on Linux only.
New in Isabelle2009 (April 2009)
--------------------------------
*** General ***
* Simplified main Isabelle executables, with less surprises on
case-insensitive file-systems (such as Mac OS).
- The main Isabelle tool wrapper is now called "isabelle" instead of
"isatool."
- The former "isabelle" alias for "isabelle-process" has been
removed (should rarely occur to regular users).
- The former "isabelle-interface" and its alias "Isabelle" have been
removed (interfaces are now regular Isabelle tools).
Within scripts and make files, the Isabelle environment variables
ISABELLE_TOOL and ISABELLE_PROCESS replace old ISATOOL and ISABELLE,
respectively. (The latter are still available as legacy feature.)
The old isabelle-interface wrapper could react in confusing ways if
the interface was uninstalled or changed otherwise. Individual
interface tool configuration is now more explicit, see also the
Isabelle system manual. In particular, Proof General is now available
via "isabelle emacs".
INCOMPATIBILITY, need to adapt derivative scripts. Users may need to
purge installed copies of Isabelle executables and re-run "isabelle
install -p ...", or use symlinks.
* The default for ISABELLE_HOME_USER is now ~/.isabelle instead of the
old ~/isabelle, which was slightly non-standard and apt to cause
surprises on case-insensitive file-systems (such as Mac OS).
INCOMPATIBILITY, need to move existing ~/isabelle/etc,
~/isabelle/heaps, ~/isabelle/browser_info to the new place. Special
care is required when using older releases of Isabelle. Note that
ISABELLE_HOME_USER can be changed in Isabelle/etc/settings of any
Isabelle distribution, in order to use the new ~/.isabelle uniformly.
* Proofs of fully specified statements are run in parallel on
multi-core systems. A speedup factor of 2.5 to 3.2 can be expected on
a regular 4-core machine, if the initial heap space is made reasonably
large (cf. Poly/ML option -H). (Requires Poly/ML 5.2.1 or later.)
* The main reference manuals ("isar-ref", "implementation", and
"system") have been updated and extended. Formally checked references
as hyperlinks are now available uniformly.
*** Pure ***
* Complete re-implementation of locales. INCOMPATIBILITY in several
respects. The most important changes are listed below. See the
Tutorial on Locales ("locales" manual) for details.
- In locale expressions, instantiation replaces renaming. Parameters
must be declared in a for clause. To aid compatibility with previous
parameter inheritance, in locale declarations, parameters that are not
'touched' (instantiation position "_" or omitted) are implicitly added
with their syntax at the beginning of the for clause.
- Syntax from abbreviations and definitions in locales is available in
locale expressions and context elements. The latter is particularly
useful in locale declarations.
- More flexible mechanisms to qualify names generated by locale
expressions. Qualifiers (prefixes) may be specified in locale
expressions, and can be marked as mandatory (syntax: "name!:") or
optional (syntax "name?:"). The default depends for plain "name:"
depends on the situation where a locale expression is used: in
commands 'locale' and 'sublocale' prefixes are optional, in
'interpretation' and 'interpret' prefixes are mandatory. The old
implicit qualifiers derived from the parameter names of a locale are
no longer generated.
- Command "sublocale l < e" replaces "interpretation l < e". The
instantiation clause in "interpretation" and "interpret" (square
brackets) is no longer available. Use locale expressions.
- When converting proof scripts, mandatory qualifiers in
'interpretation' and 'interpret' should be retained by default, even
if this is an INCOMPATIBILITY compared to former behavior. In the
worst case, use the "name?:" form for non-mandatory ones. Qualifiers
in locale expressions range over a single locale instance only.
- Dropped locale element "includes". This is a major INCOMPATIBILITY.
In existing theorem specifications replace the includes element by the
respective context elements of the included locale, omitting those
that are already present in the theorem specification. Multiple
assume elements of a locale should be replaced by a single one
involving the locale predicate. In the proof body, declarations (most
notably theorems) may be regained by interpreting the respective
locales in the proof context as required (command "interpret").
If using "includes" in replacement of a target solely because the
parameter types in the theorem are not as general as in the target,
consider declaring a new locale with additional type constraints on
the parameters (context element "constrains").
- Discontinued "locale (open)". INCOMPATIBILITY.
- Locale interpretation commands no longer attempt to simplify goal.
INCOMPATIBILITY: in rare situations the generated goal differs. Use
methods intro_locales and unfold_locales to clarify.
- Locale interpretation commands no longer accept interpretation
attributes. INCOMPATIBILITY.
* Class declaration: so-called "base sort" must not be given in import
list any longer, but is inferred from the specification. Particularly
in HOL, write
class foo = ...
instead of
class foo = type + ...
* Class target: global versions of theorems stemming do not carry a
parameter prefix any longer. INCOMPATIBILITY.
* Class 'instance' command no longer accepts attached definitions.
INCOMPATIBILITY, use proper 'instantiation' target instead.
* Recovered hiding of consts, which was accidentally broken in
Isabelle2007. Potential INCOMPATIBILITY, ``hide const c'' really
makes c inaccessible; consider using ``hide (open) const c'' instead.
* Slightly more coherent Pure syntax, with updated documentation in
isar-ref manual. Removed locales meta_term_syntax and
meta_conjunction_syntax: TERM and &&& (formerly &&) are now permanent,
INCOMPATIBILITY in rare situations. Note that &&& should not be used
directly in regular applications.
* There is a new syntactic category "float_const" for signed decimal
fractions (e.g. 123.45 or -123.45).
* Removed exotic 'token_translation' command. INCOMPATIBILITY, use ML
interface with 'setup' command instead.
* Command 'local_setup' is similar to 'setup', but operates on a local
theory context.
* The 'axiomatization' command now only works within a global theory
context. INCOMPATIBILITY.
* Goal-directed proof now enforces strict proof irrelevance wrt. sort
hypotheses. Sorts required in the course of reasoning need to be
covered by the constraints in the initial statement, completed by the
type instance information of the background theory. Non-trivial sort
hypotheses, which rarely occur in practice, may be specified via
vacuous propositions of the form SORT_CONSTRAINT('a::c). For example:
lemma assumes "SORT_CONSTRAINT('a::empty)" shows False ...
The result contains an implicit sort hypotheses as before --
SORT_CONSTRAINT premises are eliminated as part of the canonical rule
normalization.
* Generalized Isar history, with support for linear undo, direct state
addressing etc.
* Changed defaults for unify configuration options:
unify_trace_bound = 50 (formerly 25)
unify_search_bound = 60 (formerly 30)
* Different bookkeeping for code equations (INCOMPATIBILITY):
a) On theory merge, the last set of code equations for a particular
constant is taken (in accordance with the policy applied by other
parts of the code generator framework).
b) Code equations stemming from explicit declarations (e.g. code
attribute) gain priority over default code equations stemming
from definition, primrec, fun etc.
* Keyword 'code_exception' now named 'code_abort'. INCOMPATIBILITY.
* Unified theorem tables for both code generators. Thus [code
func] has disappeared and only [code] remains. INCOMPATIBILITY.
* Command 'find_consts' searches for constants based on type and name
patterns, e.g.
find_consts "_ => bool"
By default, matching is against subtypes, but it may be restricted to
the whole type. Searching by name is possible. Multiple queries are
conjunctive and queries may be negated by prefixing them with a
hyphen:
find_consts strict: "_ => bool" name: "Int" -"int => int"
* New 'find_theorems' criterion "solves" matches theorems that
directly solve the current goal (modulo higher-order unification).
* Auto solve feature for main theorem statements: whenever a new goal
is stated, "find_theorems solves" is called; any theorems that could
solve the lemma directly are listed as part of the goal state.
Cf. associated options in Proof General Isabelle settings menu,
enabled by default, with reasonable timeout for pathological cases of
higher-order unification.
*** Document preparation ***
* Antiquotation @{lemma} now imitates a regular terminal proof,
demanding keyword 'by' and supporting the full method expression
syntax just like the Isar command 'by'.
*** HOL ***
* Integrated main parts of former image HOL-Complex with HOL. Entry
points Main and Complex_Main remain as before.
* Logic image HOL-Plain provides a minimal HOL with the most important
tools available (inductive, datatype, primrec, ...). This facilitates
experimentation and tool development. Note that user applications
(and library theories) should never refer to anything below theory
Main, as before.
* Logic image HOL-Main stops at theory Main, and thus facilitates
experimentation due to shorter build times.
* Logic image HOL-NSA contains theories of nonstandard analysis which
were previously part of former HOL-Complex. Entry point Hyperreal
remains valid, but theories formerly using Complex_Main should now use
new entry point Hypercomplex.
* Generic ATP manager for Sledgehammer, based on ML threads instead of
Posix processes. Avoids potentially expensive forking of the ML
process. New thread-based implementation also works on non-Unix
platforms (Cygwin). Provers are no longer hardwired, but defined
within the theory via plain ML wrapper functions. Basic Sledgehammer
commands are covered in the isar-ref manual.
* Wrapper scripts for remote SystemOnTPTP service allows to use
sledgehammer without local ATP installation (Vampire etc.). Other
provers may be included via suitable ML wrappers, see also
src/HOL/ATP_Linkup.thy.
* ATP selection (E/Vampire/Spass) is now via Proof General's settings
menu.
* The metis method no longer fails because the theorem is too trivial
(contains the empty clause).
* The metis method now fails in the usual manner, rather than raising
an exception, if it determines that it cannot prove the theorem.
* Method "coherent" implements a prover for coherent logic (see also
src/Tools/coherent.ML).
* Constants "undefined" and "default" replace "arbitrary". Usually
"undefined" is the right choice to replace "arbitrary", though
logically there is no difference. INCOMPATIBILITY.
* Command "value" now integrates different evaluation mechanisms. The
result of the first successful evaluation mechanism is printed. In
square brackets a particular named evaluation mechanisms may be
specified (currently, [SML], [code] or [nbe]). See further
src/HOL/ex/Eval_Examples.thy.
* Normalization by evaluation now allows non-leftlinear equations.
Declare with attribute [code nbe].
* Methods "case_tac" and "induct_tac" now refer to the very same rules
as the structured Isar versions "cases" and "induct", cf. the
corresponding "cases" and "induct" attributes. Mutual induction rules
are now presented as a list of individual projections
(e.g. foo_bar.inducts for types foo and bar); the old format with
explicit HOL conjunction is no longer supported. INCOMPATIBILITY, in
rare situations a different rule is selected --- notably nested tuple
elimination instead of former prod.exhaust: use explicit (case_tac t
rule: prod.exhaust) here.
* Attributes "cases", "induct", "coinduct" support "del" option.
* Removed fact "case_split_thm", which duplicates "case_split".
* The option datatype has been moved to a new theory Option. Renamed
option_map to Option.map, and o2s to Option.set, INCOMPATIBILITY.
* New predicate "strict_mono" classifies strict functions on partial
orders. With strict functions on linear orders, reasoning about
(in)equalities is facilitated by theorems "strict_mono_eq",
"strict_mono_less_eq" and "strict_mono_less".
* Some set operations are now proper qualified constants with
authentic syntax. INCOMPATIBILITY:
op Int ~> Set.Int
op Un ~> Set.Un
INTER ~> Set.INTER
UNION ~> Set.UNION
Inter ~> Set.Inter
Union ~> Set.Union
{} ~> Set.empty
UNIV ~> Set.UNIV
* Class complete_lattice with operations Inf, Sup, INFI, SUPR now in
theory Set.
* Auxiliary class "itself" has disappeared -- classes without any
parameter are treated as expected by the 'class' command.
* Leibnitz's Series for Pi and the arcus tangens and logarithm series.
* Common decision procedures (Cooper, MIR, Ferrack, Approximation,
Dense_Linear_Order) are now in directory HOL/Decision_Procs.
* Theory src/HOL/Decision_Procs/Approximation provides the new proof
method "approximation". It proves formulas on real values by using
interval arithmetic. In the formulas are also the transcendental
functions sin, cos, tan, atan, ln, exp and the constant pi are
allowed. For examples see
src/HOL/Descision_Procs/ex/Approximation_Ex.thy.
* Theory "Reflection" now resides in HOL/Library.
* Entry point to Word library now simply named "Word".
INCOMPATIBILITY.
* Made source layout more coherent with logical distribution
structure:
src/HOL/Library/RType.thy ~> src/HOL/Typerep.thy
src/HOL/Library/Code_Message.thy ~> src/HOL/
src/HOL/Library/GCD.thy ~> src/HOL/
src/HOL/Library/Order_Relation.thy ~> src/HOL/
src/HOL/Library/Parity.thy ~> src/HOL/
src/HOL/Library/Univ_Poly.thy ~> src/HOL/
src/HOL/Real/ContNotDenum.thy ~> src/HOL/Library/
src/HOL/Real/Lubs.thy ~> src/HOL/
src/HOL/Real/PReal.thy ~> src/HOL/
src/HOL/Real/Rational.thy ~> src/HOL/
src/HOL/Real/RComplete.thy ~> src/HOL/
src/HOL/Real/RealDef.thy ~> src/HOL/
src/HOL/Real/RealPow.thy ~> src/HOL/
src/HOL/Real/Real.thy ~> src/HOL/
src/HOL/Complex/Complex_Main.thy ~> src/HOL/
src/HOL/Complex/Complex.thy ~> src/HOL/
src/HOL/Complex/FrechetDeriv.thy ~> src/HOL/Library/
src/HOL/Complex/Fundamental_Theorem_Algebra.thy ~> src/HOL/Library/
src/HOL/Hyperreal/Deriv.thy ~> src/HOL/
src/HOL/Hyperreal/Fact.thy ~> src/HOL/
src/HOL/Hyperreal/Integration.thy ~> src/HOL/
src/HOL/Hyperreal/Lim.thy ~> src/HOL/
src/HOL/Hyperreal/Ln.thy ~> src/HOL/
src/HOL/Hyperreal/Log.thy ~> src/HOL/
src/HOL/Hyperreal/MacLaurin.thy ~> src/HOL/
src/HOL/Hyperreal/NthRoot.thy ~> src/HOL/
src/HOL/Hyperreal/Series.thy ~> src/HOL/
src/HOL/Hyperreal/SEQ.thy ~> src/HOL/
src/HOL/Hyperreal/Taylor.thy ~> src/HOL/
src/HOL/Hyperreal/Transcendental.thy ~> src/HOL/
src/HOL/Real/Float ~> src/HOL/Library/
src/HOL/Real/HahnBanach ~> src/HOL/HahnBanach
src/HOL/Real/RealVector.thy ~> src/HOL/
src/HOL/arith_data.ML ~> src/HOL/Tools
src/HOL/hologic.ML ~> src/HOL/Tools
src/HOL/simpdata.ML ~> src/HOL/Tools
src/HOL/int_arith1.ML ~> src/HOL/Tools/int_arith.ML
src/HOL/int_factor_simprocs.ML ~> src/HOL/Tools
src/HOL/nat_simprocs.ML ~> src/HOL/Tools
src/HOL/Real/float_arith.ML ~> src/HOL/Tools
src/HOL/Real/float_syntax.ML ~> src/HOL/Tools
src/HOL/Real/rat_arith.ML ~> src/HOL/Tools
src/HOL/Real/real_arith.ML ~> src/HOL/Tools
src/HOL/Library/Array.thy ~> src/HOL/Imperative_HOL
src/HOL/Library/Heap_Monad.thy ~> src/HOL/Imperative_HOL
src/HOL/Library/Heap.thy ~> src/HOL/Imperative_HOL
src/HOL/Library/Imperative_HOL.thy ~> src/HOL/Imperative_HOL
src/HOL/Library/Ref.thy ~> src/HOL/Imperative_HOL
src/HOL/Library/Relational.thy ~> src/HOL/Imperative_HOL
* If methods "eval" and "evaluation" encounter a structured proof
state with !!/==>, only the conclusion is evaluated to True (if
possible), avoiding strange error messages.
* Method "sizechange" automates termination proofs using (a
modification of) the size-change principle. Requires SAT solver. See
src/HOL/ex/Termination.thy for examples.
* Simplifier: simproc for let expressions now unfolds if bound
variable occurs at most once in let expression body. INCOMPATIBILITY.
* Method "arith": Linear arithmetic now ignores all inequalities when
fast_arith_neq_limit is exceeded, instead of giving up entirely.
* New attribute "arith" for facts that should always be used
automatically by arithmetic. It is intended to be used locally in
proofs, e.g.
assumes [arith]: "x > 0"
Global usage is discouraged because of possible performance impact.
* New classes "top" and "bot" with corresponding operations "top" and
"bot" in theory Orderings; instantiation of class "complete_lattice"
requires instantiation of classes "top" and "bot". INCOMPATIBILITY.
* Changed definition lemma "less_fun_def" in order to provide an
instance for preorders on functions; use lemma "less_le" instead.
INCOMPATIBILITY.
* Theory Orderings: class "wellorder" moved here, with explicit
induction rule "less_induct" as assumption. For instantiation of
"wellorder" by means of predicate "wf", use rule wf_wellorderI.
INCOMPATIBILITY.
* Theory Orderings: added class "preorder" as superclass of "order".
INCOMPATIBILITY: Instantiation proofs for order, linorder
etc. slightly changed. Some theorems named order_class.* now named
preorder_class.*.
* Theory Relation: renamed "refl" to "refl_on", "reflexive" to "refl,
"diag" to "Id_on".
* Theory Finite_Set: added a new fold combinator of type
('a => 'b => 'b) => 'b => 'a set => 'b
Occasionally this is more convenient than the old fold combinator
which is now defined in terms of the new one and renamed to
fold_image.
* Theories Ring_and_Field and OrderedGroup: The lemmas "group_simps"
and "ring_simps" have been replaced by "algebra_simps" (which can be
extended with further lemmas!). At the moment both still exist but
the former will disappear at some point.
* Theory Power: Lemma power_Suc is now declared as a simp rule in
class recpower. Type-specific simp rules for various recpower types
have been removed. INCOMPATIBILITY, rename old lemmas as follows:
rat_power_0 -> power_0
rat_power_Suc -> power_Suc
realpow_0 -> power_0
realpow_Suc -> power_Suc
complexpow_0 -> power_0
complexpow_Suc -> power_Suc
power_poly_0 -> power_0
power_poly_Suc -> power_Suc
* Theories Ring_and_Field and Divides: Definition of "op dvd" has been
moved to separate class dvd in Ring_and_Field; a couple of lemmas on
dvd has been generalized to class comm_semiring_1. Likewise a bunch
of lemmas from Divides has been generalized from nat to class
semiring_div. INCOMPATIBILITY. This involves the following theorem
renames resulting from duplicate elimination:
dvd_def_mod ~> dvd_eq_mod_eq_0
zero_dvd_iff ~> dvd_0_left_iff
dvd_0 ~> dvd_0_right
DIVISION_BY_ZERO_DIV ~> div_by_0
DIVISION_BY_ZERO_MOD ~> mod_by_0
mult_div ~> div_mult_self2_is_id
mult_mod ~> mod_mult_self2_is_0
* Theory IntDiv: removed many lemmas that are instances of class-based
generalizations (from Divides and Ring_and_Field). INCOMPATIBILITY,
rename old lemmas as follows:
dvd_diff -> nat_dvd_diff
dvd_zminus_iff -> dvd_minus_iff
mod_add1_eq -> mod_add_eq
mod_mult1_eq -> mod_mult_right_eq
mod_mult1_eq' -> mod_mult_left_eq
mod_mult_distrib_mod -> mod_mult_eq
nat_mod_add_left_eq -> mod_add_left_eq
nat_mod_add_right_eq -> mod_add_right_eq
nat_mod_div_trivial -> mod_div_trivial
nat_mod_mod_trivial -> mod_mod_trivial
zdiv_zadd_self1 -> div_add_self1
zdiv_zadd_self2 -> div_add_self2
zdiv_zmult_self1 -> div_mult_self2_is_id
zdiv_zmult_self2 -> div_mult_self1_is_id
zdvd_triv_left -> dvd_triv_left
zdvd_triv_right -> dvd_triv_right
zdvd_zmult_cancel_disj -> dvd_mult_cancel_left
zmod_eq0_zdvd_iff -> dvd_eq_mod_eq_0[symmetric]
zmod_zadd_left_eq -> mod_add_left_eq
zmod_zadd_right_eq -> mod_add_right_eq
zmod_zadd_self1 -> mod_add_self1
zmod_zadd_self2 -> mod_add_self2
zmod_zadd1_eq -> mod_add_eq
zmod_zdiff1_eq -> mod_diff_eq
zmod_zdvd_zmod -> mod_mod_cancel
zmod_zmod_cancel -> mod_mod_cancel
zmod_zmult_self1 -> mod_mult_self2_is_0
zmod_zmult_self2 -> mod_mult_self1_is_0
zmod_1 -> mod_by_1
zdiv_1 -> div_by_1
zdvd_abs1 -> abs_dvd_iff
zdvd_abs2 -> dvd_abs_iff
zdvd_refl -> dvd_refl
zdvd_trans -> dvd_trans
zdvd_zadd -> dvd_add
zdvd_zdiff -> dvd_diff
zdvd_zminus_iff -> dvd_minus_iff
zdvd_zminus2_iff -> minus_dvd_iff
zdvd_zmultD -> dvd_mult_right
zdvd_zmultD2 -> dvd_mult_left
zdvd_zmult_mono -> mult_dvd_mono
zdvd_0_right -> dvd_0_right
zdvd_0_left -> dvd_0_left_iff
zdvd_1_left -> one_dvd
zminus_dvd_iff -> minus_dvd_iff
* Theory Rational: 'Fract k 0' now equals '0'. INCOMPATIBILITY.
* The real numbers offer decimal input syntax: 12.34 is translated
into 1234/10^2. This translation is not reversed upon output.
* Theory Library/Polynomial defines an abstract type 'a poly of
univariate polynomials with coefficients of type 'a. In addition to
the standard ring operations, it also supports div and mod. Code
generation is also supported, using list-style constructors.
* Theory Library/Inner_Product defines a class of real_inner for real
inner product spaces, with an overloaded operation inner :: 'a => 'a
=> real. Class real_inner is a subclass of real_normed_vector from
theory RealVector.
* Theory Library/Product_Vector provides instances for the product
type 'a * 'b of several classes from RealVector and Inner_Product.
Definitions of addition, subtraction, scalar multiplication, norms,
and inner products are included.
* Theory Library/Bit defines the field "bit" of integers modulo 2. In
addition to the field operations, numerals and case syntax are also
supported.
* Theory Library/Diagonalize provides constructive version of Cantor's
first diagonalization argument.
* Theory Library/GCD: Curried operations gcd, lcm (for nat) and zgcd,
zlcm (for int); carried together from various gcd/lcm developements in
the HOL Distribution. Constants zgcd and zlcm replace former igcd and
ilcm; corresponding theorems renamed accordingly. INCOMPATIBILITY,
may recover tupled syntax as follows:
hide (open) const gcd
abbreviation gcd where
"gcd == (%(a, b). GCD.gcd a b)"
notation (output)
GCD.gcd ("gcd '(_, _')")
The same works for lcm, zgcd, zlcm.
* Theory Library/Nat_Infinity: added addition, numeral syntax and more
instantiations for algebraic structures. Removed some duplicate
theorems. Changes in simp rules. INCOMPATIBILITY.
* ML antiquotation @{code} takes a constant as argument and generates
corresponding code in background and inserts name of the corresponding
resulting ML value/function/datatype constructor binding in place.
All occurrences of @{code} with a single ML block are generated
simultaneously. Provides a generic and safe interface for
instrumentalizing code generation. See
src/HOL/Decision_Procs/Ferrack.thy for a more ambitious application.
In future you ought to refrain from ad-hoc compiling generated SML
code on the ML toplevel. Note that (for technical reasons) @{code}
cannot refer to constants for which user-defined serializations are
set. Refer to the corresponding ML counterpart directly in that
cases.
* Command 'rep_datatype': instead of theorem names the command now
takes a list of terms denoting the constructors of the type to be
represented as datatype. The characteristic theorems have to be
proven. INCOMPATIBILITY. Also observe that the following theorems
have disappeared in favour of existing ones:
unit_induct ~> unit.induct
prod_induct ~> prod.induct
sum_induct ~> sum.induct
Suc_Suc_eq ~> nat.inject
Suc_not_Zero Zero_not_Suc ~> nat.distinct
*** HOL-Algebra ***
* New locales for orders and lattices where the equivalence relation
is not restricted to equality. INCOMPATIBILITY: all order and lattice
locales use a record structure with field eq for the equivalence.
* New theory of factorial domains.
* Units_l_inv and Units_r_inv are now simp rules by default.
INCOMPATIBILITY. Simplifier proof that require deletion of l_inv
and/or r_inv will now also require deletion of these lemmas.
* Renamed the following theorems, INCOMPATIBILITY:
UpperD ~> Upper_memD
LowerD ~> Lower_memD
least_carrier ~> least_closed
greatest_carrier ~> greatest_closed
greatest_Lower_above ~> greatest_Lower_below
one_zero ~> carrier_one_zero
one_not_zero ~> carrier_one_not_zero (collision with assumption)
*** HOL-Nominal ***
* Nominal datatypes can now contain type-variables.
* Commands 'nominal_inductive' and 'equivariance' work with local
theory targets.
* Nominal primrec can now works with local theory targets and its
specification syntax now conforms to the general format as seen in
'inductive' etc.
* Method "perm_simp" honours the standard simplifier attributes
(no_asm), (no_asm_use) etc.
* The new predicate #* is defined like freshness, except that on the
left hand side can be a set or list of atoms.
* Experimental command 'nominal_inductive2' derives strong induction
principles for inductive definitions. In contrast to
'nominal_inductive', which can only deal with a fixed number of
binders, it can deal with arbitrary expressions standing for sets of
atoms to be avoided. The only inductive definition we have at the
moment that needs this generalisation is the typing rule for Lets in
the algorithm W:
Gamma |- t1 : T1 (x,close Gamma T1)::Gamma |- t2 : T2 x#Gamma
-----------------------------------------------------------------
Gamma |- Let x be t1 in t2 : T2
In this rule one wants to avoid all the binders that are introduced by
"close Gamma T1". We are looking for other examples where this
feature might be useful. Please let us know.
*** HOLCF ***
* Reimplemented the simplification procedure for proving continuity
subgoals. The new simproc is extensible; users can declare additional
continuity introduction rules with the attribute [cont2cont].
* The continuity simproc now uses a different introduction rule for
solving continuity subgoals on terms with lambda abstractions. In
some rare cases the new simproc may fail to solve subgoals that the
old one could solve, and "simp add: cont2cont_LAM" may be necessary.
Potential INCOMPATIBILITY.
* Command 'fixrec': specification syntax now conforms to the general
format as seen in 'inductive' etc. See src/HOLCF/ex/Fixrec_ex.thy for
examples. INCOMPATIBILITY.
*** ZF ***
* Proof of Zorn's Lemma for partial orders.
*** ML ***
* Multithreading for Poly/ML 5.1/5.2 is no longer supported, only for
Poly/ML 5.2.1 or later. Important note: the TimeLimit facility
depends on multithreading, so timouts will not work before Poly/ML
5.2.1!
* High-level support for concurrent ML programming, see
src/Pure/Cuncurrent. The data-oriented model of "future values" is
particularly convenient to organize independent functional
computations. The concept of "synchronized variables" provides a
higher-order interface for components with shared state, avoiding the
delicate details of mutexes and condition variables. (Requires
Poly/ML 5.2.1 or later.)
* ML bindings produced via Isar commands are stored within the Isar
context (theory or proof). Consequently, commands like 'use' and 'ML'
become thread-safe and work with undo as expected (concerning
top-level bindings, not side-effects on global references).
INCOMPATIBILITY, need to provide proper Isar context when invoking the
compiler at runtime; really global bindings need to be given outside a
theory. (Requires Poly/ML 5.2 or later.)
* Command 'ML_prf' is analogous to 'ML' but works within a proof
context. Top-level ML bindings are stored within the proof context in
a purely sequential fashion, disregarding the nested proof structure.
ML bindings introduced by 'ML_prf' are discarded at the end of the
proof. (Requires Poly/ML 5.2 or later.)
* Simplified ML attribute and method setup, cf. functions Attrib.setup
and Method.setup, as well as Isar commands 'attribute_setup' and
'method_setup'. INCOMPATIBILITY for 'method_setup', need to simplify
existing code accordingly, or use plain 'setup' together with old
Method.add_method.
* Simplified ML oracle interface Thm.add_oracle promotes 'a -> cterm
to 'a -> thm, while results are always tagged with an authentic oracle
name. The Isar command 'oracle' is now polymorphic, no argument type
is specified. INCOMPATIBILITY, need to simplify existing oracle code
accordingly. Note that extra performance may be gained by producing
the cterm carefully, avoiding slow Thm.cterm_of.
* Simplified interface for defining document antiquotations via
ThyOutput.antiquotation, ThyOutput.output, and optionally
ThyOutput.maybe_pretty_source. INCOMPATIBILITY, need to simplify user
antiquotations accordingly, see src/Pure/Thy/thy_output.ML for common
examples.
* More systematic treatment of long names, abstract name bindings, and
name space operations. Basic operations on qualified names have been
move from structure NameSpace to Long_Name, e.g. Long_Name.base_name,
Long_Name.append. Old type bstring has been mostly replaced by
abstract type binding (see structure Binding), which supports precise
qualification by packages and local theory targets, as well as proper
tracking of source positions. INCOMPATIBILITY, need to wrap old
bstring values into Binding.name, or better pass through abstract
bindings everywhere. See further src/Pure/General/long_name.ML,
src/Pure/General/binding.ML and src/Pure/General/name_space.ML
* Result facts (from PureThy.note_thms, ProofContext.note_thms,
LocalTheory.note etc.) now refer to the *full* internal name, not the
bstring as before. INCOMPATIBILITY, not detected by ML type-checking!
* Disposed old type and term read functions (Sign.read_def_typ,
Sign.read_typ, Sign.read_def_terms, Sign.read_term,
Thm.read_def_cterms, Thm.read_cterm etc.). INCOMPATIBILITY, should
use regular Syntax.read_typ, Syntax.read_term, Syntax.read_typ_global,
Syntax.read_term_global etc.; see also OldGoals.read_term as last
resort for legacy applications.
* Disposed old declarations, tactics, tactic combinators that refer to
the simpset or claset of an implicit theory (such as Addsimps,
Simp_tac, SIMPSET). INCOMPATIBILITY, should use @{simpset} etc. in
embedded ML text, or local_simpset_of with a proper context passed as
explicit runtime argument.
* Rules and tactics that read instantiations (read_instantiate,
res_inst_tac, thin_tac, subgoal_tac etc.) now demand a proper proof
context, which is required for parsing and type-checking. Moreover,
the variables are specified as plain indexnames, not string encodings
thereof. INCOMPATIBILITY.
* Generic Toplevel.add_hook interface allows to analyze the result of
transactions. E.g. see src/Pure/ProofGeneral/proof_general_pgip.ML
for theorem dependency output of transactions resulting in a new
theory state.
* ML antiquotations: block-structured compilation context indicated by
\ ... \; additional antiquotation forms:
@{binding name} - basic name binding
@{let ?pat = term} - term abbreviation (HO matching)
@{note name = fact} - fact abbreviation
@{thm fact} - singleton fact (with attributes)
@{thms fact} - general fact (with attributes)
@{lemma prop by method} - singleton goal
@{lemma prop by meth1 meth2} - singleton goal
@{lemma prop1 ... propN by method} - general goal
@{lemma prop1 ... propN by meth1 meth2} - general goal
@{lemma (open) ...} - open derivation
*** System ***
* The Isabelle "emacs" tool provides a specific interface to invoke
Proof General / Emacs, with more explicit failure if that is not
installed (the old isabelle-interface script silently falls back on
isabelle-process). The PROOFGENERAL_HOME setting determines the
installation location of the Proof General distribution.
* Isabelle/lib/classes/Pure.jar provides basic support to integrate
the Isabelle process into a JVM/Scala application. See
Isabelle/lib/jedit/plugin for a minimal example. (The obsolete Java
process wrapper has been discontinued.)
* Added homegrown Isabelle font with unicode layout, see lib/fonts.
* Various status messages (with exact source position information) are
emitted, if proper markup print mode is enabled. This allows
user-interface components to provide detailed feedback on internal
prover operations.
New in Isabelle2008 (June 2008)
-------------------------------
*** General ***
* The Isabelle/Isar Reference Manual (isar-ref) has been reorganized
and updated, with formally checked references as hyperlinks.
* Theory loader: use_thy (and similar operations) no longer set the
implicit ML context, which was occasionally hard to predict and in
conflict with concurrency. INCOMPATIBILITY, use ML within Isar which
provides a proper context already.
* Theory loader: old-style ML proof scripts being *attached* to a thy
file are no longer supported. INCOMPATIBILITY, regular 'uses' and
'use' within a theory file will do the job.
* Name space merge now observes canonical order, i.e. the second space
is inserted into the first one, while existing entries in the first
space take precedence. INCOMPATIBILITY in rare situations, may try to
swap theory imports.
* Syntax: symbol \ is now considered a letter. Potential
INCOMPATIBILITY in identifier syntax etc.
* Outer syntax: string tokens no longer admit escaped white space,
which was an accidental (undocumented) feature. INCOMPATIBILITY, use
white space without escapes.
* Outer syntax: string tokens may contain arbitrary character codes
specified via 3 decimal digits (as in SML). E.g. "foo\095bar" for
"foo_bar".
*** Pure ***
* Context-dependent token translations. Default setup reverts locally
fixed variables, and adds hilite markup for undeclared frees.
* Unused theorems can be found using the new command 'unused_thms'.
There are three ways of invoking it:
(1) unused_thms
Only finds unused theorems in the current theory.
(2) unused_thms thy_1 ... thy_n -
Finds unused theorems in the current theory and all of its ancestors,
excluding the theories thy_1 ... thy_n and all of their ancestors.
(3) unused_thms thy_1 ... thy_n - thy'_1 ... thy'_m
Finds unused theorems in the theories thy'_1 ... thy'_m and all of
their ancestors, excluding the theories thy_1 ... thy_n and all of
their ancestors.
In order to increase the readability of the list produced by
unused_thms, theorems that have been created by a particular instance
of a theory command such as 'inductive' or 'function' are considered
to belong to the same "group", meaning that if at least one theorem in
this group is used, the other theorems in the same group are no longer
reported as unused. Moreover, if all theorems in the group are
unused, only one theorem in the group is displayed.
Note that proof objects have to be switched on in order for
unused_thms to work properly (i.e. !proofs must be >= 1, which is
usually the case when using Proof General with the default settings).
* Authentic naming of facts disallows ad-hoc overwriting of previous
theorems within the same name space. INCOMPATIBILITY, need to remove
duplicate fact bindings, or even accidental fact duplications. Note
that tools may maintain dynamically scoped facts systematically, using
PureThy.add_thms_dynamic.
* Command 'hide' now allows to hide from "fact" name space as well.
* Eliminated destructive theorem database, simpset, claset, and
clasimpset. Potential INCOMPATIBILITY, really need to observe linear
update of theories within ML code.
* Eliminated theory ProtoPure and CPure, leaving just one Pure theory.
INCOMPATIBILITY, object-logics depending on former Pure require
additional setup PureThy.old_appl_syntax_setup; object-logics
depending on former CPure need to refer to Pure.
* Commands 'use' and 'ML' are now purely functional, operating on
theory/local_theory. Removed former 'ML_setup' (on theory), use 'ML'
instead. Added 'ML_val' as mere diagnostic replacement for 'ML'.
INCOMPATIBILITY.
* Command 'setup': discontinued implicit version with ML reference.
* Instantiation target allows for simultaneous specification of class
instance operations together with an instantiation proof.
Type-checking phase allows to refer to class operations uniformly.
See src/HOL/Complex/Complex.thy for an Isar example and
src/HOL/Library/Eval.thy for an ML example.
* Indexing of literal facts: be more serious about including only
facts from the visible specification/proof context, but not the
background context (locale etc.). Affects `prop` notation and method
"fact". INCOMPATIBILITY: need to name facts explicitly in rare
situations.
* Method "cases", "induct", "coinduct": removed obsolete/undocumented
"(open)" option, which used to expose internal bound variables to the
proof text.
* Isar statements: removed obsolete case "rule_context".
INCOMPATIBILITY, better use explicit fixes/assumes.
* Locale proofs: default proof step now includes 'unfold_locales';
hence 'proof' without argument may be used to unfold locale
predicates.
*** Document preparation ***
* Simplified pdfsetup.sty: color/hyperref is used unconditionally for
both pdf and dvi (hyperlinks usually work in xdvi as well); removed
obsolete thumbpdf setup (contemporary PDF viewers do this on the
spot); renamed link color from "darkblue" to "linkcolor" (default
value unchanged, can be redefined via \definecolor); no longer sets
"a4paper" option (unnecessary or even intrusive).
* Antiquotation @{lemma A method} proves proposition A by the given
method (either a method name or a method name plus (optional) method
arguments in parentheses) and prints A just like @{prop A}.
*** HOL ***
* New primrec package. Specification syntax conforms in style to
definition/function/.... No separate induction rule is provided. The
"primrec" command distinguishes old-style and new-style specifications
by syntax. The former primrec package is now named OldPrimrecPackage.
When adjusting theories, beware: constants stemming from new-style
primrec specifications have authentic syntax.
* Metis prover is now an order of magnitude faster, and also works
with multithreading.
* Metis: the maximum number of clauses that can be produced from a
theorem is now given by the attribute max_clauses. Theorems that
exceed this number are ignored, with a warning printed.
* Sledgehammer no longer produces structured proofs by default. To
enable, declare [[sledgehammer_full = true]]. Attributes
reconstruction_modulus, reconstruction_sorts renamed
sledgehammer_modulus, sledgehammer_sorts. INCOMPATIBILITY.
* Method "induct_scheme" derives user-specified induction rules
from well-founded induction and completeness of patterns. This factors
out some operations that are done internally by the function package
and makes them available separately. See
src/HOL/ex/Induction_Scheme.thy for examples.
* More flexible generation of measure functions for termination
proofs: Measure functions can be declared by proving a rule of the
form "is_measure f" and giving it the [measure_function] attribute.
The "is_measure" predicate is logically meaningless (always true), and
just guides the heuristic. To find suitable measure functions, the
termination prover sets up the goal "is_measure ?f" of the appropriate
type and generates all solutions by prolog-style backwards proof using
the declared rules.
This setup also deals with rules like
"is_measure f ==> is_measure (list_size f)"
which accommodates nested datatypes that recurse through lists.
Similar rules are predeclared for products and option types.
* Turned the type of sets "'a set" into an abbreviation for "'a => bool"
INCOMPATIBILITIES:
- Definitions of overloaded constants on sets have to be replaced by
definitions on => and bool.
- Some definitions of overloaded operators on sets can now be proved
using the definitions of the operators on => and bool. Therefore,
the following theorems have been renamed:
subset_def -> subset_eq
psubset_def -> psubset_eq
set_diff_def -> set_diff_eq
Compl_def -> Compl_eq
Sup_set_def -> Sup_set_eq
Inf_set_def -> Inf_set_eq
sup_set_def -> sup_set_eq
inf_set_def -> inf_set_eq
- Due to the incompleteness of the HO unification algorithm, some
rules such as subst may require manual instantiation, if some of
the unknowns in the rule is a set.
- Higher order unification and forward proofs:
The proof pattern
have "P (S::'a set)" <...>
then have "EX S. P S" ..
no longer works (due to the incompleteness of the HO unification
algorithm) and must be replaced by the pattern
have "EX S. P S"
proof
show "P S" <...>
qed
- Calculational reasoning with subst (or similar rules):
The proof pattern
have "P (S::'a set)" <...>
also have "S = T" <...>
finally have "P T" .
no longer works (for similar reasons as the previous example) and
must be replaced by something like
have "P (S::'a set)" <...>
moreover have "S = T" <...>
ultimately have "P T" by simp
- Tactics or packages written in ML code:
Code performing pattern matching on types via
Type ("set", [T]) => ...
must be rewritten. Moreover, functions like strip_type or
binder_types no longer return the right value when applied to a
type of the form
T1 => ... => Tn => U => bool
rather than
T1 => ... => Tn => U set
* Merged theories Wellfounded_Recursion, Accessible_Part and
Wellfounded_Relations to theory Wellfounded.
* Explicit class "eq" for executable equality. INCOMPATIBILITY.
* Class finite no longer treats UNIV as class parameter. Use class
enum from theory Library/Enum instead to achieve a similar effect.
INCOMPATIBILITY.
* Theory List: rule list_induct2 now has explicitly named cases "Nil"
and "Cons". INCOMPATIBILITY.
* HOL (and FOL): renamed variables in rules imp_elim and swap.
Potential INCOMPATIBILITY.
* Theory Product_Type: duplicated lemmas split_Pair_apply and
injective_fst_snd removed, use split_eta and prod_eqI instead.
Renamed upd_fst to apfst and upd_snd to apsnd. INCOMPATIBILITY.
* Theory Nat: removed redundant lemmas that merely duplicate lemmas of
the same name in theory Orderings:
less_trans
less_linear
le_imp_less_or_eq
le_less_trans
less_le_trans
less_not_sym
less_asym
Renamed less_imp_le to less_imp_le_nat, and less_irrefl to
less_irrefl_nat. Potential INCOMPATIBILITY due to more general types
and different variable names.
* Library/Option_ord.thy: Canonical order on option type.
* Library/RBT.thy: Red-black trees, an efficient implementation of
finite maps.
* Library/Countable.thy: Type class for countable types.
* Theory Int: The representation of numerals has changed. The infix
operator BIT and the bit datatype with constructors B0 and B1 have
disappeared. INCOMPATIBILITY, use "Int.Bit0 x" and "Int.Bit1 y" in
place of "x BIT bit.B0" and "y BIT bit.B1", respectively. Theorems
involving BIT, B0, or B1 have been renamed with "Bit0" or "Bit1"
accordingly.
* Theory Nat: definition of <= and < on natural numbers no longer
depend on well-founded relations. INCOMPATIBILITY. Definitions
le_def and less_def have disappeared. Consider lemmas not_less
[symmetric, where ?'a = nat] and less_eq [symmetric] instead.
* Theory Finite_Set: locales ACf, ACe, ACIf, ACIfSL and ACIfSLlin
(whose purpose mainly is for various fold_set functionals) have been
abandoned in favor of the existing algebraic classes
ab_semigroup_mult, comm_monoid_mult, ab_semigroup_idem_mult,
lower_semilattice (resp. upper_semilattice) and linorder.
INCOMPATIBILITY.
* Theory Transitive_Closure: induct and cases rules now declare proper
case_names ("base" and "step"). INCOMPATIBILITY.
* Theorem Inductive.lfp_ordinal_induct generalized to complete
lattices. The form set-specific version is available as
Inductive.lfp_ordinal_induct_set.
* Renamed theorems "power.simps" to "power_int.simps".
INCOMPATIBILITY.
* Class semiring_div provides basic abstract properties of semirings
with division and modulo operations. Subsumes former class dvd_mod.
* Merged theories IntDef, Numeral and IntArith into unified theory
Int. INCOMPATIBILITY.
* Theory Library/Code_Index: type "index" now represents natural
numbers rather than integers. INCOMPATIBILITY.
* New class "uminus" with operation "uminus" (split of from class
"minus" which now only has operation "minus", binary).
INCOMPATIBILITY.
* Constants "card", "internal_split", "option_map" now with authentic
syntax. INCOMPATIBILITY.
* Definitions subset_def, psubset_def, set_diff_def, Compl_def,
le_bool_def, less_bool_def, le_fun_def, less_fun_def, inf_bool_def,
sup_bool_def, Inf_bool_def, Sup_bool_def, inf_fun_def, sup_fun_def,
Inf_fun_def, Sup_fun_def, inf_set_def, sup_set_def, Inf_set_def,
Sup_set_def, le_def, less_def, option_map_def now with object
equality. INCOMPATIBILITY.
* Records. Removed K_record, and replaced it by pure lambda term
%x. c. The simplifier setup is now more robust against eta expansion.
INCOMPATIBILITY: in cases explicitly referring to K_record.
* Library/Multiset: {#a, b, c#} abbreviates {#a#} + {#b#} + {#c#}.
* Library/ListVector: new theory of arithmetic vector operations.
* Library/Order_Relation: new theory of various orderings as sets of
pairs. Defines preorders, partial orders, linear orders and
well-orders on sets and on types.
*** ZF ***
* Renamed some theories to allow to loading both ZF and HOL in the
same session:
Datatype -> Datatype_ZF
Inductive -> Inductive_ZF
Int -> Int_ZF
IntDiv -> IntDiv_ZF
Nat -> Nat_ZF
List -> List_ZF
Main -> Main_ZF
INCOMPATIBILITY: ZF theories that import individual theories below
Main might need to be adapted. Regular theory Main is still
available, as trivial extension of Main_ZF.
*** ML ***
* ML within Isar: antiquotation @{const name} or @{const
name(typargs)} produces statically-checked Const term.
* Functor NamedThmsFun: data is available to the user as dynamic fact
(of the same name). Removed obsolete print command.
* Removed obsolete "use_legacy_bindings" function.
* The ``print mode'' is now a thread-local value derived from a global
template (the former print_mode reference), thus access becomes
non-critical. The global print_mode reference is for session
management only; user-code should use print_mode_value,
print_mode_active, PrintMode.setmp etc. INCOMPATIBILITY.
* Functions system/system_out provide a robust way to invoke external
shell commands, with propagation of interrupts (requires Poly/ML
5.2.1). Do not use OS.Process.system etc. from the basis library!
*** System ***
* Default settings: PROOFGENERAL_OPTIONS no longer impose xemacs ---
in accordance with Proof General 3.7, which prefers GNU emacs.
* isatool tty runs Isabelle process with plain tty interaction;
optional line editor may be specified via ISABELLE_LINE_EDITOR
setting, the default settings attempt to locate "ledit" and "rlwrap".
* isatool browser now works with Cygwin as well, using general
"javapath" function defined in Isabelle process environment.
* YXML notation provides a simple and efficient alternative to
standard XML transfer syntax. See src/Pure/General/yxml.ML and
isatool yxml as described in the Isabelle system manual.
* JVM class isabelle.IsabelleProcess (located in Isabelle/lib/classes)
provides general wrapper for managing an Isabelle process in a robust
fashion, with ``cooked'' output from stdin/stderr.
* Rudimentary Isabelle plugin for jEdit (see Isabelle/lib/jedit),
based on Isabelle/JVM process wrapper (see Isabelle/lib/classes).
* Removed obsolete THIS_IS_ISABELLE_BUILD feature. NB: the documented
way of changing the user's settings is via
ISABELLE_HOME_USER/etc/settings, which is a fully featured bash
script.
* Multithreading.max_threads := 0 refers to the number of actual CPU
cores of the underlying machine, which is a good starting point for
optimal performance tuning. The corresponding usedir option -M allows
"max" as an alias for "0". WARNING: does not work on certain versions
of Mac OS (with Poly/ML 5.1).
* isabelle-process: non-ML sessions are run with "nice", to reduce the
adverse effect of Isabelle flooding interactive front-ends (notably
ProofGeneral / XEmacs).
New in Isabelle2007 (November 2007)
-----------------------------------
*** General ***
* More uniform information about legacy features, notably a
warning/error of "Legacy feature: ...", depending on the state of the
tolerate_legacy_features flag (default true). FUTURE INCOMPATIBILITY:
legacy features will disappear eventually.
* Theory syntax: the header format ``theory A = B + C:'' has been
discontinued in favour of ``theory A imports B C begin''. Use isatool
fixheaders to convert existing theory files. INCOMPATIBILITY.
* Theory syntax: the old non-Isar theory file format has been
discontinued altogether. Note that ML proof scripts may still be used
with Isar theories; migration is usually quite simple with the ML
function use_legacy_bindings. INCOMPATIBILITY.
* Theory syntax: some popular names (e.g. 'class', 'declaration',
'fun', 'help', 'if') are now keywords. INCOMPATIBILITY, use double
quotes.
* Theory loader: be more serious about observing the static theory
header specifications (including optional directories), but not the
accidental file locations of previously successful loads. The strict
update policy of former update_thy is now already performed by
use_thy, so the former has been removed; use_thys updates several
theories simultaneously, just as 'imports' within a theory header
specification, but without merging the results. Potential
INCOMPATIBILITY: may need to refine theory headers and commands
ROOT.ML which depend on load order.
* Theory loader: optional support for content-based file
identification, instead of the traditional scheme of full physical
path plus date stamp; configured by the ISABELLE_FILE_IDENT setting
(cf. the system manual). The new scheme allows to work with
non-finished theories in persistent session images, such that source
files may be moved later on without requiring reloads.
* Theory loader: old-style ML proof scripts being *attached* to a thy
file (with the same base name as the theory) are considered a legacy
feature, which will disappear eventually. Even now, the theory loader
no longer maintains dependencies on such files.
* Syntax: the scope for resolving ambiguities via type-inference is
now limited to individual terms, instead of whole simultaneous
specifications as before. This greatly reduces the complexity of the
syntax module and improves flexibility by separating parsing and
type-checking. INCOMPATIBILITY: additional type-constraints (explicit
'fixes' etc.) are required in rare situations.
* Syntax: constants introduced by new-style packages ('definition',
'abbreviation' etc.) are passed through the syntax module in
``authentic mode''. This means that associated mixfix annotations
really stick to such constants, independently of potential name space
ambiguities introduced later on. INCOMPATIBILITY: constants in parse
trees are represented slightly differently, may need to adapt syntax
translations accordingly. Use CONST marker in 'translations' and
@{const_syntax} antiquotation in 'parse_translation' etc.
* Legacy goal package: reduced interface to the bare minimum required
to keep existing proof scripts running. Most other user-level
functions are now part of the OldGoals structure, which is *not* open
by default (consider isatool expandshort before open OldGoals).
Removed top_sg, prin, printyp, pprint_term/typ altogether, because
these tend to cause confusion about the actual goal (!) context being
used here, which is not necessarily the same as the_context().
* Command 'find_theorems': supports "*" wild-card in "name:"
criterion; "with_dups" option. Certain ProofGeneral versions might
support a specific search form (see ProofGeneral/CHANGES).
* The ``prems limit'' option (cf. ProofContext.prems_limit) is now -1
by default, which means that "prems" (and also "fixed variables") are
suppressed from proof state output. Note that the ProofGeneral
settings mechanism allows to change and save options persistently, but
older versions of Isabelle will fail to start up if a negative prems
limit is imposed.
* Local theory targets may be specified by non-nested blocks of
``context/locale/class ... begin'' followed by ``end''. The body may
contain definitions, theorems etc., including any derived mechanism
that has been implemented on top of these primitives. This concept
generalizes the existing ``theorem (in ...)'' towards more versatility
and scalability.
* Proof General interface: proper undo of final 'end' command;
discontinued Isabelle/classic mode (ML proof scripts).
*** Document preparation ***
* Added antiquotation @{theory name} which prints the given name,
after checking that it refers to a valid ancestor theory in the
current context.
* Added antiquotations @{ML_type text} and @{ML_struct text} which
check the given source text as ML type/structure, printing verbatim.
* Added antiquotation @{abbrev "c args"} which prints the abbreviation
"c args == rhs" given in the current context. (Any number of
arguments may be given on the LHS.)
*** Pure ***
* The 'class' package offers a combination of axclass and locale to
achieve Haskell-like type classes in Isabelle. Definitions and
theorems within a class context produce both relative results (with
implicit parameters according to the locale context), and polymorphic
constants with qualified polymorphism (according to the class
context). Within the body context of a 'class' target, a separate
syntax layer ("user space type system") takes care of converting
between global polymorphic consts and internal locale representation.
See src/HOL/ex/Classpackage.thy for examples (as well as main HOL).
"isatool doc classes" provides a tutorial.
* Generic code generator framework allows to generate executable
code for ML and Haskell (including Isabelle classes). A short usage
sketch:
internal compilation:
export_code in SML
writing SML code to a file:
export_code in SML
writing OCaml code to a file:
export_code in OCaml
writing Haskell code to a bunch of files:
export_code in Haskell
evaluating closed propositions to True/False using code generation:
method ``eval''
Reasonable default setup of framework in HOL.
Theorem attributs for selecting and transforming function equations theorems:
[code fun]: select a theorem as function equation for a specific constant
[code fun del]: deselect a theorem as function equation for a specific constant
[code inline]: select an equation theorem for unfolding (inlining) in place
[code inline del]: deselect an equation theorem for unfolding (inlining) in place
User-defined serializations (target in {SML, OCaml, Haskell}):
code_const
{(target) }+
code_type
{(target) }+
code_instance
{(target)}+
where instance ::= ::
code_class
{(target) }+
where class target syntax ::= {where { == }+}?
code_instance and code_class only are effective to target Haskell.
For example usage see src/HOL/ex/Codegenerator.thy and
src/HOL/ex/Codegenerator_Pretty.thy. A separate tutorial on code
generation from Isabelle/HOL theories is available via "isatool doc
codegen".
* Code generator: consts in 'consts_code' Isar commands are now
referred to by usual term syntax (including optional type
annotations).
* Command 'no_translations' removes translation rules from theory
syntax.
* Overloaded definitions are now actually checked for acyclic
dependencies. The overloading scheme is slightly more general than
that of Haskell98, although Isabelle does not demand an exact
correspondence to type class and instance declarations.
INCOMPATIBILITY, use ``defs (unchecked overloaded)'' to admit more
exotic versions of overloading -- at the discretion of the user!
Polymorphic constants are represented via type arguments, i.e. the
instantiation that matches an instance against the most general
declaration given in the signature. For example, with the declaration
c :: 'a => 'a => 'a, an instance c :: nat => nat => nat is represented
as c(nat). Overloading is essentially simultaneous structural
recursion over such type arguments. Incomplete specification patterns
impose global constraints on all occurrences, e.g. c('a * 'a) on the
LHS means that more general c('a * 'b) will be disallowed on any RHS.
Command 'print_theory' outputs the normalized system of recursive
equations, see section "definitions".
* Configuration options are maintained within the theory or proof
context (with name and type bool/int/string), providing a very simple
interface to a poor-man's version of general context data. Tools may
declare options in ML (e.g. using Attrib.config_int) and then refer to
these values using Config.get etc. Users may change options via an
associated attribute of the same name. This form of context
declaration works particularly well with commands 'declare' or
'using', for example ``declare [[foo = 42]]''. Thus it has become
very easy to avoid global references, which would not observe Isar
toplevel undo/redo and fail to work with multithreading.
Various global ML references of Pure and HOL have been turned into
configuration options:
Unify.search_bound unify_search_bound
Unify.trace_bound unify_trace_bound
Unify.trace_simp unify_trace_simp
Unify.trace_types unify_trace_types
Simplifier.simp_depth_limit simp_depth_limit
Blast.depth_limit blast_depth_limit
DatatypeProp.dtK datatype_distinctness_limit
fast_arith_neq_limit fast_arith_neq_limit
fast_arith_split_limit fast_arith_split_limit
* Named collections of theorems may be easily installed as context
data using the functor NamedThmsFun (see also
src/Pure/Tools/named_thms.ML). The user may add or delete facts via
attributes; there is also a toplevel print command. This facility is
just a common case of general context data, which is the preferred way
for anything more complex than just a list of facts in canonical
order.
* Isar: command 'declaration' augments a local theory by generic
declaration functions written in ML. This enables arbitrary content
being added to the context, depending on a morphism that tells the
difference of the original declaration context wrt. the application
context encountered later on.
* Isar: proper interfaces for simplification procedures. Command
'simproc_setup' declares named simprocs (with match patterns, and body
text in ML). Attribute "simproc" adds/deletes simprocs in the current
context. ML antiquotation @{simproc name} retrieves named simprocs.
* Isar: an extra pair of brackets around attribute declarations
abbreviates a theorem reference involving an internal dummy fact,
which will be ignored later --- only the effect of the attribute on
the background context will persist. This form of in-place
declarations is particularly useful with commands like 'declare' and
'using', for example ``have A using [[simproc a]] by simp''.
* Isar: method "assumption" (and implicit closing of subproofs) now
takes simple non-atomic goal assumptions into account: after applying
an assumption as a rule the resulting subgoals are solved by atomic
assumption steps. This is particularly useful to finish 'obtain'
goals, such as "!!x. (!!x. P x ==> thesis) ==> P x ==> thesis",
without referring to the original premise "!!x. P x ==> thesis" in the
Isar proof context. POTENTIAL INCOMPATIBILITY: method "assumption" is
more permissive.
* Isar: implicit use of prems from the Isar proof context is
considered a legacy feature. Common applications like ``have A .''
may be replaced by ``have A by fact'' or ``note `A`''. In general,
referencing facts explicitly here improves readability and
maintainability of proof texts.
* Isar: improper proof element 'guess' is like 'obtain', but derives
the obtained context from the course of reasoning! For example:
assume "EX x y. A x & B y" -- "any previous fact"
then guess x and y by clarify
This technique is potentially adventurous, depending on the facts and
proof tools being involved here.
* Isar: known facts from the proof context may be specified as literal
propositions, using ASCII back-quote syntax. This works wherever
named facts used to be allowed so far, in proof commands, proof
methods, attributes etc. Literal facts are retrieved from the context
according to unification of type and term parameters. For example,
provided that "A" and "A ==> B" and "!!x. P x ==> Q x" are known
theorems in the current context, then these are valid literal facts:
`A` and `A ==> B` and `!!x. P x ==> Q x" as well as `P a ==> Q a` etc.
There is also a proof method "fact" which does the same composition
for explicit goal states, e.g. the following proof texts coincide with
certain special cases of literal facts:
have "A" by fact == note `A`
have "A ==> B" by fact == note `A ==> B`
have "!!x. P x ==> Q x" by fact == note `!!x. P x ==> Q x`
have "P a ==> Q a" by fact == note `P a ==> Q a`
* Isar: ":" (colon) is no longer a symbolic identifier character in
outer syntax. Thus symbolic identifiers may be used without
additional white space in declarations like this: ``assume *: A''.
* Isar: 'print_facts' prints all local facts of the current context,
both named and unnamed ones.
* Isar: 'def' now admits simultaneous definitions, e.g.:
def x == "t" and y == "u"
* Isar: added command 'unfolding', which is structurally similar to
'using', but affects both the goal state and facts by unfolding given
rewrite rules. Thus many occurrences of the 'unfold' method or
'unfolded' attribute may be replaced by first-class proof text.
* Isar: methods 'unfold' / 'fold', attributes 'unfolded' / 'folded',
and command 'unfolding' now all support object-level equalities
(potentially conditional). The underlying notion of rewrite rule is
analogous to the 'rule_format' attribute, but *not* that of the
Simplifier (which is usually more generous).
* Isar: the new attribute [rotated n] (default n = 1) rotates the
premises of a theorem by n. Useful in conjunction with drule.
* Isar: the goal restriction operator [N] (default N = 1) evaluates a
method expression within a sandbox consisting of the first N
sub-goals, which need to exist. For example, ``simp_all [3]''
simplifies the first three sub-goals, while (rule foo, simp_all)[]
simplifies all new goals that emerge from applying rule foo to the
originally first one.
* Isar: schematic goals are no longer restricted to higher-order
patterns; e.g. ``lemma "?P(?x)" by (rule TrueI)'' now works as
expected.
* Isar: the conclusion of a long theorem statement is now either
'shows' (a simultaneous conjunction, as before), or 'obtains'
(essentially a disjunction of cases with local parameters and
assumptions). The latter allows to express general elimination rules
adequately; in this notation common elimination rules look like this:
lemma exE: -- "EX x. P x ==> (!!x. P x ==> thesis) ==> thesis"
assumes "EX x. P x"
obtains x where "P x"
lemma conjE: -- "A & B ==> (A ==> B ==> thesis) ==> thesis"
assumes "A & B"
obtains A and B
lemma disjE: -- "A | B ==> (A ==> thesis) ==> (B ==> thesis) ==> thesis"
assumes "A | B"
obtains
A
| B
The subsequent classical rules even refer to the formal "thesis"
explicitly:
lemma classical: -- "(~ thesis ==> thesis) ==> thesis"
obtains "~ thesis"
lemma Peirce's_Law: -- "((thesis ==> something) ==> thesis) ==> thesis"
obtains "thesis ==> something"
The actual proof of an 'obtains' statement is analogous to that of the
Isar proof element 'obtain', only that there may be several cases.
Optional case names may be specified in parentheses; these will be
available both in the present proof and as annotations in the
resulting rule, for later use with the 'cases' method (cf. attribute
case_names).
* Isar: the assumptions of a long theorem statement are available as
"assms" fact in the proof context. This is more appropriate than the
(historical) "prems", which refers to all assumptions of the current
context, including those from the target locale, proof body etc.
* Isar: 'print_statement' prints theorems from the current theory or
proof context in long statement form, according to the syntax of a
top-level lemma.
* Isar: 'obtain' takes an optional case name for the local context
introduction rule (default "that").
* Isar: removed obsolete 'concl is' patterns. INCOMPATIBILITY, use
explicit (is "_ ==> ?foo") in the rare cases where this still happens
to occur.
* Pure: syntax "CONST name" produces a fully internalized constant
according to the current context. This is particularly useful for
syntax translations that should refer to internal constant
representations independently of name spaces.
* Pure: syntax constant for foo (binder "FOO ") is called "foo_binder"
instead of "FOO ". This allows multiple binder declarations to coexist
in the same context. INCOMPATIBILITY.
* Isar/locales: 'notation' provides a robust interface to the 'syntax'
primitive that also works in a locale context (both for constants and
fixed variables). Type declaration and internal syntactic representation
of given constants retrieved from the context. Likewise, the
'no_notation' command allows to remove given syntax annotations from the
current context.
* Isar/locales: new derived specification elements 'axiomatization',
'definition', 'abbreviation', which support type-inference, admit
object-level specifications (equality, equivalence). See also the
isar-ref manual. Examples:
axiomatization
eq (infix "===" 50) where
eq_refl: "x === x" and eq_subst: "x === y ==> P x ==> P y"
definition "f x y = x + y + 1"
definition g where "g x = f x x"
abbreviation
neq (infix "=!=" 50) where
"x =!= y == ~ (x === y)"
These specifications may be also used in a locale context. Then the
constants being introduced depend on certain fixed parameters, and the
constant name is qualified by the locale base name. An internal
abbreviation takes care for convenient input and output, making the
parameters implicit and using the original short name. See also
src/HOL/ex/Abstract_NAT.thy for an example of deriving polymorphic
entities from a monomorphic theory.
Presently, abbreviations are only available 'in' a target locale, but
not inherited by general import expressions. Also note that
'abbreviation' may be used as a type-safe replacement for 'syntax' +
'translations' in common applications. The "no_abbrevs" print mode
prevents folding of abbreviations in term output.
Concrete syntax is attached to specified constants in internal form,
independently of name spaces. The parse tree representation is
slightly different -- use 'notation' instead of raw 'syntax', and
'translations' with explicit "CONST" markup to accommodate this.
* Pure/Isar: unified syntax for new-style specification mechanisms
(e.g. 'definition', 'abbreviation', or 'inductive' in HOL) admits
full type inference and dummy patterns ("_"). For example:
definition "K x _ = x"
inductive conj for A B
where "A ==> B ==> conj A B"
* Pure: command 'print_abbrevs' prints all constant abbreviations of
the current context. Print mode "no_abbrevs" prevents inversion of
abbreviations on output.
* Isar/locales: improved parameter handling: use of locales "var" and
"struct" no longer necessary; - parameter renamings are no longer
required to be injective. For example, this allows to define
endomorphisms as locale endom = homom mult mult h.
* Isar/locales: changed the way locales with predicates are defined.
Instead of accumulating the specification, the imported expression is
now an interpretation. INCOMPATIBILITY: different normal form of
locale expressions. In particular, in interpretations of locales with
predicates, goals repesenting already interpreted fragments are not
removed automatically. Use methods `intro_locales' and
`unfold_locales'; see below.
* Isar/locales: new methods `intro_locales' and `unfold_locales'
provide backward reasoning on locales predicates. The methods are
aware of interpretations and discharge corresponding goals.
`intro_locales' is less aggressive then `unfold_locales' and does not
unfold predicates to assumptions.
* Isar/locales: the order in which locale fragments are accumulated
has changed. This enables to override declarations from fragments due
to interpretations -- for example, unwanted simp rules.
* Isar/locales: interpretation in theories and proof contexts has been
extended. One may now specify (and prove) equations, which are
unfolded in interpreted theorems. This is useful for replacing
defined concepts (constants depending on locale parameters) by
concepts already existing in the target context. Example:
interpretation partial_order ["op <= :: [int, int] => bool"]
where "partial_order.less (op <=) (x::int) y = (x < y)"
Typically, the constant `partial_order.less' is created by a
definition specification element in the context of locale
partial_order.
* Method "induct": improved internal context management to support
local fixes and defines on-the-fly. Thus explicit meta-level
connectives !! and ==> are rarely required anymore in inductive goals
(using object-logic connectives for this purpose has been long
obsolete anyway). Common proof patterns are explained in
src/HOL/Induct/Common_Patterns.thy, see also
src/HOL/Isar_examples/Puzzle.thy and src/HOL/Lambda for realistic
examples.
* Method "induct": improved handling of simultaneous goals. Instead of
introducing object-level conjunction, the statement is now split into
several conclusions, while the corresponding symbolic cases are nested
accordingly. INCOMPATIBILITY, proofs need to be structured explicitly,
see src/HOL/Induct/Common_Patterns.thy, for example.
* Method "induct": mutual induction rules are now specified as a list
of rule sharing the same induction cases. HOL packages usually provide
foo_bar.inducts for mutually defined items foo and bar (e.g. inductive
predicates/sets or datatypes). INCOMPATIBILITY, users need to specify
mutual induction rules differently, i.e. like this:
(induct rule: foo_bar.inducts)
(induct set: foo bar)
(induct pred: foo bar)
(induct type: foo bar)
The ML function ProjectRule.projections turns old-style rules into the
new format.
* Method "coinduct": dual of induction, see
src/HOL/Library/Coinductive_List.thy for various examples.
* Method "cases", "induct", "coinduct": the ``(open)'' option is
considered a legacy feature.
* Attribute "symmetric" produces result with standardized schematic
variables (index 0). Potential INCOMPATIBILITY.
* Simplifier: by default the simplifier trace only shows top level
rewrites now. That is, trace_simp_depth_limit is set to 1 by
default. Thus there is less danger of being flooded by the trace. The
trace indicates where parts have been suppressed.
* Provers/classical: removed obsolete classical version of elim_format
attribute; classical elim/dest rules are now treated uniformly when
manipulating the claset.
* Provers/classical: stricter checks to ensure that supplied intro,
dest and elim rules are well-formed; dest and elim rules must have at
least one premise.
* Provers/classical: attributes dest/elim/intro take an optional
weight argument for the rule (just as the Pure versions). Weights are
ignored by automated tools, but determine the search order of single
rule steps.
* Syntax: input syntax now supports dummy variable binding "%_. b",
where the body does not mention the bound variable. Note that dummy
patterns implicitly depend on their context of bounds, which makes
"{_. _}" match any set comprehension as expected. Potential
INCOMPATIBILITY -- parse translations need to cope with syntactic
constant "_idtdummy" in the binding position.
* Syntax: removed obsolete syntactic constant "_K" and its associated
parse translation. INCOMPATIBILITY -- use dummy abstraction instead,
for example "A -> B" => "Pi A (%_. B)".
* Pure: 'class_deps' command visualizes the subclass relation, using
the graph browser tool.
* Pure: 'print_theory' now suppresses certain internal declarations by
default; use '!' option for full details.
*** HOL ***
* Method "metis" proves goals by applying the Metis general-purpose
resolution prover (see also http://gilith.com/software/metis/).
Examples are in the directory MetisExamples. WARNING: the
Isabelle/HOL-Metis integration does not yet work properly with
multi-threading.
* Command 'sledgehammer' invokes external automatic theorem provers as
background processes. It generates calls to the "metis" method if
successful. These can be pasted into the proof. Users do not have to
wait for the automatic provers to return. WARNING: does not really
work with multi-threading.
* New "auto_quickcheck" feature tests outermost goal statements for
potential counter-examples. Controlled by ML references
auto_quickcheck (default true) and auto_quickcheck_time_limit (default
5000 milliseconds). Fails silently if statements is outside of
executable fragment, or any other codgenerator problem occurs.
* New constant "undefined" with axiom "undefined x = undefined".
* Added class "HOL.eq", allowing for code generation with polymorphic
equality.
* Some renaming of class constants due to canonical name prefixing in
the new 'class' package:
HOL.abs ~> HOL.abs_class.abs
HOL.divide ~> HOL.divide_class.divide
0 ~> HOL.zero_class.zero
1 ~> HOL.one_class.one
op + ~> HOL.plus_class.plus
op - ~> HOL.minus_class.minus
uminus ~> HOL.minus_class.uminus
op * ~> HOL.times_class.times
op < ~> HOL.ord_class.less
op <= > HOL.ord_class.less_eq
Nat.power ~> Power.power_class.power
Nat.size ~> Nat.size_class.size
Numeral.number_of ~> Numeral.number_class.number_of
FixedPoint.Inf ~> Lattices.complete_lattice_class.Inf
FixedPoint.Sup ~> Lattices.complete_lattice_class.Sup
Orderings.min ~> Orderings.ord_class.min
Orderings.max ~> Orderings.ord_class.max
Divides.op div ~> Divides.div_class.div
Divides.op mod ~> Divides.div_class.mod
Divides.op dvd ~> Divides.div_class.dvd
INCOMPATIBILITY. Adaptions may be required in the following cases:
a) User-defined constants using any of the names "plus", "minus",
"times", "less" or "less_eq". The standard syntax translations for
"+", "-" and "*" may go wrong. INCOMPATIBILITY: use more specific
names.
b) Variables named "plus", "minus", "times", "less", "less_eq"
INCOMPATIBILITY: use more specific names.
c) Permutative equations (e.g. "a + b = b + a")
Since the change of names also changes the order of terms, permutative
rewrite rules may get applied in a different order. Experience shows
that this is rarely the case (only two adaptions in the whole Isabelle
distribution). INCOMPATIBILITY: rewrite proofs
d) ML code directly refering to constant names
This in general only affects hand-written proof tactics, simprocs and
so on. INCOMPATIBILITY: grep your sourcecode and replace names.
Consider using @{const_name} antiquotation.
* New class "default" with associated constant "default".
* Function "sgn" is now overloaded and available on int, real, complex
(and other numeric types), using class "sgn". Two possible defs of
sgn are given as equational assumptions in the classes sgn_if and
sgn_div_norm; ordered_idom now also inherits from sgn_if.
INCOMPATIBILITY.
* Locale "partial_order" now unified with class "order" (cf. theory
Orderings), added parameter "less". INCOMPATIBILITY.
* Renamings in classes "order" and "linorder": facts "refl", "trans" and
"cases" to "order_refl", "order_trans" and "linorder_cases", to avoid
clashes with HOL "refl" and "trans". INCOMPATIBILITY.
* Classes "order" and "linorder": potential INCOMPATIBILITY due to
changed order of proof goals in instance proofs.
* The transitivity reasoner for partial and linear orders is set up
for classes "order" and "linorder". Instances of the reasoner are available
in all contexts importing or interpreting the corresponding locales.
Method "order" invokes the reasoner separately; the reasoner
is also integrated with the Simplifier as a solver. Diagnostic
command 'print_orders' shows the available instances of the reasoner
in the current context.
* Localized monotonicity predicate in theory "Orderings"; integrated
lemmas max_of_mono and min_of_mono with this predicate.
INCOMPATIBILITY.
* Formulation of theorem "dense" changed slightly due to integration
with new class dense_linear_order.
* Uniform lattice theory development in HOL.
constants "meet" and "join" now named "inf" and "sup"
constant "Meet" now named "Inf"
classes "meet_semilorder" and "join_semilorder" now named
"lower_semilattice" and "upper_semilattice"
class "lorder" now named "lattice"
class "comp_lat" now named "complete_lattice"
Instantiation of lattice classes allows explicit definitions
for "inf" and "sup" operations (or "Inf" and "Sup" for complete lattices).
INCOMPATIBILITY. Theorem renames:
meet_left_le ~> inf_le1
meet_right_le ~> inf_le2
join_left_le ~> sup_ge1
join_right_le ~> sup_ge2
meet_join_le ~> inf_sup_ord
le_meetI ~> le_infI
join_leI ~> le_supI
le_meet ~> le_inf_iff
le_join ~> ge_sup_conv
meet_idempotent ~> inf_idem
join_idempotent ~> sup_idem
meet_comm ~> inf_commute
join_comm ~> sup_commute
meet_leI1 ~> le_infI1
meet_leI2 ~> le_infI2
le_joinI1 ~> le_supI1
le_joinI2 ~> le_supI2
meet_assoc ~> inf_assoc
join_assoc ~> sup_assoc
meet_left_comm ~> inf_left_commute
meet_left_idempotent ~> inf_left_idem
join_left_comm ~> sup_left_commute
join_left_idempotent ~> sup_left_idem
meet_aci ~> inf_aci
join_aci ~> sup_aci
le_def_meet ~> le_iff_inf
le_def_join ~> le_iff_sup
join_absorp2 ~> sup_absorb2
join_absorp1 ~> sup_absorb1
meet_absorp1 ~> inf_absorb1
meet_absorp2 ~> inf_absorb2
meet_join_absorp ~> inf_sup_absorb
join_meet_absorp ~> sup_inf_absorb
distrib_join_le ~> distrib_sup_le
distrib_meet_le ~> distrib_inf_le
add_meet_distrib_left ~> add_inf_distrib_left
add_join_distrib_left ~> add_sup_distrib_left
is_join_neg_meet ~> is_join_neg_inf
is_meet_neg_join ~> is_meet_neg_sup
add_meet_distrib_right ~> add_inf_distrib_right
add_join_distrib_right ~> add_sup_distrib_right
add_meet_join_distribs ~> add_sup_inf_distribs
join_eq_neg_meet ~> sup_eq_neg_inf
meet_eq_neg_join ~> inf_eq_neg_sup
add_eq_meet_join ~> add_eq_inf_sup
meet_0_imp_0 ~> inf_0_imp_0
join_0_imp_0 ~> sup_0_imp_0
meet_0_eq_0 ~> inf_0_eq_0
join_0_eq_0 ~> sup_0_eq_0
neg_meet_eq_join ~> neg_inf_eq_sup
neg_join_eq_meet ~> neg_sup_eq_inf
join_eq_if ~> sup_eq_if
mono_meet ~> mono_inf
mono_join ~> mono_sup
meet_bool_eq ~> inf_bool_eq
join_bool_eq ~> sup_bool_eq
meet_fun_eq ~> inf_fun_eq
join_fun_eq ~> sup_fun_eq
meet_set_eq ~> inf_set_eq
join_set_eq ~> sup_set_eq
meet1_iff ~> inf1_iff
meet2_iff ~> inf2_iff
meet1I ~> inf1I
meet2I ~> inf2I
meet1D1 ~> inf1D1
meet2D1 ~> inf2D1
meet1D2 ~> inf1D2
meet2D2 ~> inf2D2
meet1E ~> inf1E
meet2E ~> inf2E
join1_iff ~> sup1_iff
join2_iff ~> sup2_iff
join1I1 ~> sup1I1
join2I1 ~> sup2I1
join1I1 ~> sup1I1
join2I2 ~> sup1I2
join1CI ~> sup1CI
join2CI ~> sup2CI
join1E ~> sup1E
join2E ~> sup2E
is_meet_Meet ~> is_meet_Inf
Meet_bool_def ~> Inf_bool_def
Meet_fun_def ~> Inf_fun_def
Meet_greatest ~> Inf_greatest
Meet_lower ~> Inf_lower
Meet_set_def ~> Inf_set_def
Sup_def ~> Sup_Inf
Sup_bool_eq ~> Sup_bool_def
Sup_fun_eq ~> Sup_fun_def
Sup_set_eq ~> Sup_set_def
listsp_meetI ~> listsp_infI
listsp_meet_eq ~> listsp_inf_eq
meet_min ~> inf_min
join_max ~> sup_max
* Added syntactic class "size"; overloaded constant "size" now has
type "'a::size ==> bool"
* Internal reorganisation of `size' of datatypes: size theorems
"foo.size" are no longer subsumed by "foo.simps" (but are still
simplification rules by default!); theorems "prod.size" now named
"*.size".
* Class "div" now inherits from class "times" rather than "type".
INCOMPATIBILITY.
* HOL/Finite_Set: "name-space" locales Lattice, Distrib_lattice,
Linorder etc. have disappeared; operations defined in terms of
fold_set now are named Inf_fin, Sup_fin. INCOMPATIBILITY.
* HOL/Nat: neq0_conv no longer declared as iff. INCOMPATIBILITY.
* HOL-Word: New extensive library and type for generic, fixed size
machine words, with arithmetic, bit-wise, shifting and rotating
operations, reflection into int, nat, and bool lists, automation for
linear arithmetic (by automatic reflection into nat or int), including
lemmas on overflow and monotonicity. Instantiated to all appropriate
arithmetic type classes, supporting automatic simplification of
numerals on all operations.
* Library/Boolean_Algebra: locales for abstract boolean algebras.
* Library/Numeral_Type: numbers as types, e.g. TYPE(32).
* Code generator library theories:
- Code_Integer represents HOL integers by big integer literals in target
languages.
- Code_Char represents HOL characters by character literals in target
languages.
- Code_Char_chr like Code_Char, but also offers treatment of character
codes; includes Code_Integer.
- Executable_Set allows to generate code for finite sets using lists.
- Executable_Rat implements rational numbers as triples (sign, enumerator,
denominator).
- Executable_Real implements a subset of real numbers, namly those
representable by rational numbers.
- Efficient_Nat implements natural numbers by integers, which in general will
result in higher efficency; pattern matching with 0/Suc is eliminated;
includes Code_Integer.
- Code_Index provides an additional datatype index which is mapped to
target-language built-in integers.
- Code_Message provides an additional datatype message_string which is isomorphic to
strings; messages are mapped to target-language strings.
* New package for inductive predicates
An n-ary predicate p with m parameters z_1, ..., z_m can now be defined via
inductive
p :: "U_1 => ... => U_m => T_1 => ... => T_n => bool"
for z_1 :: U_1 and ... and z_n :: U_m
where
rule_1: "... ==> p z_1 ... z_m t_1_1 ... t_1_n"
| ...
with full support for type-inference, rather than
consts s :: "U_1 => ... => U_m => (T_1 * ... * T_n) set"
abbreviation p :: "U_1 => ... => U_m => T_1 => ... => T_n => bool"
where "p z_1 ... z_m x_1 ... x_n == (x_1, ..., x_n) : s z_1 ... z_m"
inductive "s z_1 ... z_m"
intros
rule_1: "... ==> (t_1_1, ..., t_1_n) : s z_1 ... z_m"
...
For backward compatibility, there is a wrapper allowing inductive
sets to be defined with the new package via
inductive_set
s :: "U_1 => ... => U_m => (T_1 * ... * T_n) set"
for z_1 :: U_1 and ... and z_n :: U_m
where
rule_1: "... ==> (t_1_1, ..., t_1_n) : s z_1 ... z_m"
| ...
or
inductive_set
s :: "U_1 => ... => U_m => (T_1 * ... * T_n) set"
and p :: "U_1 => ... => U_m => T_1 => ... => T_n => bool"
for z_1 :: U_1 and ... and z_n :: U_m
where
"p z_1 ... z_m x_1 ... x_n == (x_1, ..., x_n) : s z_1 ... z_m"
| rule_1: "... ==> p z_1 ... z_m t_1_1 ... t_1_n"
| ...
if the additional syntax "p ..." is required.
Numerous examples can be found in the subdirectories src/HOL/Auth,
src/HOL/Bali, src/HOL/Induct, and src/HOL/MicroJava.
INCOMPATIBILITIES:
- Since declaration and definition of inductive sets or predicates
is no longer separated, abbreviations involving the newly
introduced sets or predicates must be specified together with the
introduction rules after the 'where' keyword (see above), rather
than before the actual inductive definition.
- The variables in induction and elimination rules are now
quantified in the order of their occurrence in the introduction
rules, rather than in alphabetical order. Since this may break
some proofs, these proofs either have to be repaired, e.g. by
reordering the variables a_i_1 ... a_i_{k_i} in Isar 'case'
statements of the form
case (rule_i a_i_1 ... a_i_{k_i})
or the old order of quantification has to be restored by explicitly adding
meta-level quantifiers in the introduction rules, i.e.
| rule_i: "!!a_i_1 ... a_i_{k_i}. ... ==> p z_1 ... z_m t_i_1 ... t_i_n"
- The format of the elimination rules is now
p z_1 ... z_m x_1 ... x_n ==>
(!!a_1_1 ... a_1_{k_1}. x_1 = t_1_1 ==> ... ==> x_n = t_1_n ==> ... ==> P)
==> ... ==> P
for predicates and
(x_1, ..., x_n) : s z_1 ... z_m ==>
(!!a_1_1 ... a_1_{k_1}. x_1 = t_1_1 ==> ... ==> x_n = t_1_n ==> ... ==> P)
==> ... ==> P
for sets rather than
x : s z_1 ... z_m ==>
(!!a_1_1 ... a_1_{k_1}. x = (t_1_1, ..., t_1_n) ==> ... ==> P)
==> ... ==> P
This may require terms in goals to be expanded to n-tuples
(e.g. using case_tac or simplification with the split_paired_all
rule) before the above elimination rule is applicable.
- The elimination or case analysis rules for (mutually) inductive
sets or predicates are now called "p_1.cases" ... "p_k.cases". The
list of rules "p_1_..._p_k.elims" is no longer available.
* New package "function"/"fun" for general recursive functions,
supporting mutual and nested recursion, definitions in local contexts,
more general pattern matching and partiality. See HOL/ex/Fundefs.thy
for small examples, and the separate tutorial on the function
package. The old recdef "package" is still available as before, but
users are encouraged to use the new package.
* Method "lexicographic_order" automatically synthesizes termination
relations as lexicographic combinations of size measures.
* Case-expressions allow arbitrary constructor-patterns (including
"_") and take their order into account, like in functional
programming. Internally, this is translated into nested
case-expressions; missing cases are added and mapped to the predefined
constant "undefined". In complicated cases printing may no longer show
the original input but the internal form. Lambda-abstractions allow
the same form of pattern matching: "% pat1 => e1 | ..." is an
abbreviation for "%x. case x of pat1 => e1 | ..." where x is a new
variable.
* IntDef: The constant "int :: nat => int" has been removed; now "int"
is an abbreviation for "of_nat :: nat => int". The simplification
rules for "of_nat" have been changed to work like "int" did
previously. Potential INCOMPATIBILITY:
- "of_nat (Suc m)" simplifies to "1 + of_nat m" instead of "of_nat m + 1"
- of_nat_diff and of_nat_mult are no longer default simp rules
* Method "algebra" solves polynomial equations over (semi)rings using
Groebner bases. The (semi)ring structure is defined by locales and the
tool setup depends on that generic context. Installing the method for
a specific type involves instantiating the locale and possibly adding
declarations for computation on the coefficients. The method is
already instantiated for natural numbers and for the axiomatic class
of idoms with numerals. See also the paper by Chaieb and Wenzel at
CALCULEMUS 2007 for the general principles underlying this
architecture of context-aware proof-tools.
* Method "ferrack" implements quantifier elimination over
special-purpose dense linear orders using locales (analogous to
"algebra"). The method is already installed for class
{ordered_field,recpower,number_ring} which subsumes real, hyperreal,
rat, etc.
* Former constant "List.op @" now named "List.append". Use ML
antiquotations @{const_name List.append} or @{term " ... @ ... "} to
circumvent possible incompatibilities when working on ML level.
* primrec: missing cases mapped to "undefined" instead of "arbitrary".
* New function listsum :: 'a list => 'a for arbitrary monoids.
Special syntax: "SUM x <- xs. f x" (and latex variants)
* New syntax for Haskell-like list comprehension (input only), eg.
[(x,y). x <- xs, y <- ys, x ~= y], see also src/HOL/List.thy.
* The special syntax for function "filter" has changed from [x :
xs. P] to [x <- xs. P] to avoid an ambiguity caused by list
comprehension syntax, and for uniformity. INCOMPATIBILITY.
* [a..b] is now defined for arbitrary linear orders. It used to be
defined on nat only, as an abbreviation for [a.. B" for equality on bool (with priority
25 like -->); output depends on the "iff" print_mode, the default is
"A = B" (with priority 50).
* Relations less (<) and less_eq (<=) are also available on type bool.
Modified syntax to disallow nesting without explicit parentheses,
e.g. "(x < y) < z" or "x < (y < z)", but NOT "x < y < z". Potential
INCOMPATIBILITY.
* "LEAST x:A. P" expands to "LEAST x. x:A & P" (input only).
* Relation composition operator "op O" now has precedence 75 and binds
stronger than union and intersection. INCOMPATIBILITY.
* The old set interval syntax "{m..n(}" (and relatives) has been
removed. Use "{m.. ==> False", equivalences
(i.e. "=" on type bool) are handled, variable names of the form
"lit_" are no longer reserved, significant speedup.
* Methods "sat" and "satx" can now replay MiniSat proof traces.
zChaff is still supported as well.
* 'inductive' and 'datatype': provide projections of mutual rules,
bundled as foo_bar.inducts;
* Library: moved theories Parity, GCD, Binomial, Infinite_Set to
Library.
* Library: moved theory Accessible_Part to main HOL.
* Library: added theory Coinductive_List of potentially infinite lists
as greatest fixed-point.
* Library: added theory AssocList which implements (finite) maps as
association lists.
* Method "evaluation" solves goals (i.e. a boolean expression)
efficiently by compiling it to ML. The goal is "proved" (via an
oracle) if it evaluates to True.
* Linear arithmetic now splits certain operators (e.g. min, max, abs)
also when invoked by the simplifier. This results in the Simplifier
being more powerful on arithmetic goals. INCOMPATIBILITY.
Configuration option fast_arith_split_limit=0 recovers the old
behavior.
* Support for hex (0x20) and binary (0b1001) numerals.
* New method: reify eqs (t), where eqs are equations for an
interpretation I :: 'a list => 'b => 'c and t::'c is an optional
parameter, computes a term s::'b and a list xs::'a list and proves the
theorem I xs s = t. This is also known as reification or quoting. The
resulting theorem is applied to the subgoal to substitute t with I xs
s. If t is omitted, the subgoal itself is reified.
* New method: reflection corr_thm eqs (t). The parameters eqs and (t)
are as explained above. corr_thm is a theorem for I vs (f t) = I vs t,
where f is supposed to be a computable function (in the sense of code
generattion). The method uses reify to compute s and xs as above then
applies corr_thm and uses normalization by evaluation to "prove" f s =
r and finally gets the theorem t = r, which is again applied to the
subgoal. An Example is available in src/HOL/ex/ReflectionEx.thy.
* Reflection: Automatic reification now handels binding, an example is
available in src/HOL/ex/ReflectionEx.thy
* HOL-Statespace: ``State Spaces: The Locale Way'' introduces a
command 'statespace' that is similar to 'record', but introduces an
abstract specification based on the locale infrastructure instead of
HOL types. This leads to extra flexibility in composing state spaces,
in particular multiple inheritance and renaming of components.
*** HOL-Complex ***
* Hyperreal: Functions root and sqrt are now defined on negative real
inputs so that root n (- x) = - root n x and sqrt (- x) = - sqrt x.
Nonnegativity side conditions have been removed from many lemmas, so
that more subgoals may now be solved by simplification; potential
INCOMPATIBILITY.
* Real: new type classes formalize real normed vector spaces and
algebras, using new overloaded constants scaleR :: real => 'a => 'a
and norm :: 'a => real.
* Real: constant of_real :: real => 'a::real_algebra_1 injects from
reals into other types. The overloaded constant Reals :: 'a set is now
defined as range of_real; potential INCOMPATIBILITY.
* Real: proper support for ML code generation, including 'quickcheck'.
Reals are implemented as arbitrary precision rationals.
* Hyperreal: Several constants that previously worked only for the
reals have been generalized, so they now work over arbitrary vector
spaces. Type annotations may need to be added in some cases; potential
INCOMPATIBILITY.
Infinitesimal :: ('a::real_normed_vector) star set
HFinite :: ('a::real_normed_vector) star set
HInfinite :: ('a::real_normed_vector) star set
approx :: ('a::real_normed_vector) star => 'a star => bool
monad :: ('a::real_normed_vector) star => 'a star set
galaxy :: ('a::real_normed_vector) star => 'a star set
(NS)LIMSEQ :: [nat => 'a::real_normed_vector, 'a] => bool
(NS)convergent :: (nat => 'a::real_normed_vector) => bool
(NS)Bseq :: (nat => 'a::real_normed_vector) => bool
(NS)Cauchy :: (nat => 'a::real_normed_vector) => bool
(NS)LIM :: ['a::real_normed_vector => 'b::real_normed_vector, 'a, 'b] => bool
is(NS)Cont :: ['a::real_normed_vector => 'b::real_normed_vector, 'a] => bool
deriv :: ['a::real_normed_field => 'a, 'a, 'a] => bool
sgn :: 'a::real_normed_vector => 'a
exp :: 'a::{recpower,real_normed_field,banach} => 'a
* Complex: Some complex-specific constants are now abbreviations for
overloaded ones: complex_of_real = of_real, cmod = norm, hcmod =
hnorm. Other constants have been entirely removed in favor of the
polymorphic versions (INCOMPATIBILITY):
approx <-- capprox
HFinite <-- CFinite
HInfinite <-- CInfinite
Infinitesimal <-- CInfinitesimal
monad <-- cmonad
galaxy <-- cgalaxy
(NS)LIM <-- (NS)CLIM, (NS)CRLIM
is(NS)Cont <-- is(NS)Contc, is(NS)contCR
(ns)deriv <-- (ns)cderiv
*** HOL-Algebra ***
* Formalisation of ideals and the quotient construction over rings.
* Order and lattice theory no longer based on records.
INCOMPATIBILITY.
* Renamed lemmas least_carrier -> least_closed and greatest_carrier ->
greatest_closed. INCOMPATIBILITY.
* Method algebra is now set up via an attribute. For examples see
Ring.thy. INCOMPATIBILITY: the method is now weaker on combinations
of algebraic structures.
* Renamed theory CRing to Ring.
*** HOL-Nominal ***
* Substantial, yet incomplete support for nominal datatypes (binding
structures) based on HOL-Nominal logic. See src/HOL/Nominal and
src/HOL/Nominal/Examples. Prospective users should consult
http://isabelle.in.tum.de/nominal/
*** ML ***
* ML basics: just one true type int, which coincides with IntInf.int
(even on SML/NJ).
* ML within Isar: antiquotations allow to embed statically-checked
formal entities in the source, referring to the context available at
compile-time. For example:
ML {* @{sort "{zero,one}"} *}
ML {* @{typ "'a => 'b"} *}
ML {* @{term "%x. x"} *}
ML {* @{prop "x == y"} *}
ML {* @{ctyp "'a => 'b"} *}
ML {* @{cterm "%x. x"} *}
ML {* @{cprop "x == y"} *}
ML {* @{thm asm_rl} *}
ML {* @{thms asm_rl} *}
ML {* @{type_name c} *}
ML {* @{type_syntax c} *}
ML {* @{const_name c} *}
ML {* @{const_syntax c} *}
ML {* @{context} *}
ML {* @{theory} *}
ML {* @{theory Pure} *}
ML {* @{theory_ref} *}
ML {* @{theory_ref Pure} *}
ML {* @{simpset} *}
ML {* @{claset} *}
ML {* @{clasimpset} *}
The same works for sources being ``used'' within an Isar context.
* ML in Isar: improved error reporting; extra verbosity with
ML_Context.trace enabled.
* Pure/General/table.ML: the join operations now works via exceptions
DUP/SAME instead of type option. This is simpler in simple cases, and
admits slightly more efficient complex applications.
* Pure: 'advanced' translation functions (parse_translation etc.) now
use Context.generic instead of just theory.
* Pure: datatype Context.generic joins theory/Proof.context and
provides some facilities for code that works in either kind of
context, notably GenericDataFun for uniform theory and proof data.
* Pure: simplified internal attribute type, which is now always
Context.generic * thm -> Context.generic * thm. Global (theory) vs.
local (Proof.context) attributes have been discontinued, while
minimizing code duplication. Thm.rule_attribute and
Thm.declaration_attribute build canonical attributes; see also structure
Context for further operations on Context.generic, notably
GenericDataFun. INCOMPATIBILITY, need to adapt attribute type
declarations and definitions.
* Context data interfaces (Theory/Proof/GenericDataFun): removed
name/print, uninitialized data defaults to ad-hoc copy of empty value,
init only required for impure data. INCOMPATIBILITY: empty really need
to be empty (no dependencies on theory content!)
* Pure/kernel: consts certification ignores sort constraints given in
signature declarations. (This information is not relevant to the
logic, but only for type inference.) SIGNIFICANT INTERNAL CHANGE,
potential INCOMPATIBILITY.
* Pure: axiomatic type classes are now purely definitional, with
explicit proofs of class axioms and super class relations performed
internally. See Pure/axclass.ML for the main internal interfaces --
notably AxClass.define_class supercedes AxClass.add_axclass, and
AxClass.axiomatize_class/classrel/arity supersede
Sign.add_classes/classrel/arities.
* Pure/Isar: Args/Attrib parsers operate on Context.generic --
global/local versions on theory vs. Proof.context have been
discontinued; Attrib.syntax and Method.syntax have been adapted
accordingly. INCOMPATIBILITY, need to adapt parser expressions for
attributes, methods, etc.
* Pure: several functions of signature "... -> theory -> theory * ..."
have been reoriented to "... -> theory -> ... * theory" in order to
allow natural usage in combination with the ||>, ||>>, |-> and
fold_map combinators.
* Pure: official theorem names (closed derivations) and additional
comments (tags) are now strictly separate. Name hints -- which are
maintained as tags -- may be attached any time without affecting the
derivation.
* Pure: primitive rule lift_rule now takes goal cterm instead of an
actual goal state (thm). Use Thm.lift_rule (Thm.cprem_of st i) to
achieve the old behaviour.
* Pure: the "Goal" constant is now called "prop", supporting a
slightly more general idea of ``protecting'' meta-level rule
statements.
* Pure: Logic.(un)varify only works in a global context, which is now
enforced instead of silently assumed. INCOMPATIBILITY, may use
Logic.legacy_(un)varify as temporary workaround.
* Pure: structure Name provides scalable operations for generating
internal variable names, notably Name.variants etc. This replaces
some popular functions from term.ML:
Term.variant -> Name.variant
Term.variantlist -> Name.variant_list
Term.invent_names -> Name.invent_list
Note that low-level renaming rarely occurs in new code -- operations
from structure Variable are used instead (see below).
* Pure: structure Variable provides fundamental operations for proper
treatment of fixed/schematic variables in a context. For example,
Variable.import introduces fixes for schematics of given facts and
Variable.export reverses the effect (up to renaming) -- this replaces
various freeze_thaw operations.
* Pure: structure Goal provides simple interfaces for
init/conclude/finish and tactical prove operations (replacing former
Tactic.prove). Goal.prove is the canonical way to prove results
within a given context; Goal.prove_global is a degraded version for
theory level goals, including a global Drule.standard. Note that
OldGoals.prove_goalw_cterm has long been obsolete, since it is
ill-behaved in a local proof context (e.g. with local fixes/assumes or
in a locale context).
* Pure/Syntax: generic interfaces for parsing (Syntax.parse_term etc.)
and type checking (Syntax.check_term etc.), with common combinations
(Syntax.read_term etc.). These supersede former Sign.read_term etc.
which are considered legacy and await removal.
* Pure/Syntax: generic interfaces for type unchecking
(Syntax.uncheck_terms etc.) and unparsing (Syntax.unparse_term etc.),
with common combinations (Syntax.pretty_term, Syntax.string_of_term
etc.). Former Sign.pretty_term, Sign.string_of_term etc. are still
available for convenience, but refer to the very same operations using
a mere theory instead of a full context.
* Isar: simplified treatment of user-level errors, using exception
ERROR of string uniformly. Function error now merely raises ERROR,
without any side effect on output channels. The Isar toplevel takes
care of proper display of ERROR exceptions. ML code may use plain
handle/can/try; cat_error may be used to concatenate errors like this:
... handle ERROR msg => cat_error msg "..."
Toplevel ML code (run directly or through the Isar toplevel) may be
embedded into the Isar toplevel with exception display/debug like
this:
Isar.toplevel (fn () => ...)
INCOMPATIBILITY, removed special transform_error facilities, removed
obsolete variants of user-level exceptions (ERROR_MESSAGE,
Context.PROOF, ProofContext.CONTEXT, Proof.STATE, ProofHistory.FAIL)
-- use plain ERROR instead.
* Isar: theory setup now has type (theory -> theory), instead of a
list. INCOMPATIBILITY, may use #> to compose setup functions.
* Isar: ML toplevel pretty printer for type Proof.context, subject to
ProofContext.debug/verbose flags.
* Isar: Toplevel.theory_to_proof admits transactions that modify the
theory before entering a proof state. Transactions now always see a
quasi-functional intermediate checkpoint, both in interactive and
batch mode.
* Isar: simplified interfaces for outer syntax. Renamed
OuterSyntax.add_keywords to OuterSyntax.keywords. Removed
OuterSyntax.add_parsers -- this functionality is now included in
OuterSyntax.command etc. INCOMPATIBILITY.
* Simplifier: the simpset of a running simplification process now
contains a proof context (cf. Simplifier.the_context), which is the
very context that the initial simpset has been retrieved from (by
simpset_of/local_simpset_of). Consequently, all plug-in components
(solver, looper etc.) may depend on arbitrary proof data.
* Simplifier.inherit_context inherits the proof context (plus the
local bounds) of the current simplification process; any simproc
etc. that calls the Simplifier recursively should do this! Removed
former Simplifier.inherit_bounds, which is already included here --
INCOMPATIBILITY. Tools based on low-level rewriting may even have to
specify an explicit context using Simplifier.context/theory_context.
* Simplifier/Classical Reasoner: more abstract interfaces
change_simpset/claset for modifying the simpset/claset reference of a
theory; raw versions simpset/claset_ref etc. have been discontinued --
INCOMPATIBILITY.
* Provers: more generic wrt. syntax of object-logics, avoid hardwired
"Trueprop" etc.
*** System ***
* settings: the default heap location within ISABELLE_HOME_USER now
includes ISABELLE_IDENTIFIER. This simplifies use of multiple
Isabelle installations.
* isabelle-process: option -S (secure mode) disables some critical
operations, notably runtime compilation and evaluation of ML source
code.
* Basic Isabelle mode for jEdit, see Isabelle/lib/jedit/.
* Support for parallel execution, using native multicore support of
Poly/ML 5.1. The theory loader exploits parallelism when processing
independent theories, according to the given theory header
specifications. The maximum number of worker threads is specified via
usedir option -M or the "max-threads" setting in Proof General. A
speedup factor of 1.5--3.5 can be expected on a 4-core machine, and up
to 6 on a 8-core machine. User-code needs to observe certain
guidelines for thread-safe programming, see appendix A in the Isar
Implementation manual.
New in Isabelle2005 (October 2005)
----------------------------------
*** General ***
* Theory headers: the new header syntax for Isar theories is
theory
imports ...
uses ...
begin
where the 'uses' part is optional. The previous syntax
theory = + ... + :
will disappear in the next release. Use isatool fixheaders to convert
existing theory files. Note that there is no change in ancient
non-Isar theories now, but these will disappear soon.
* Theory loader: parent theories can now also be referred to via
relative and absolute paths.
* Command 'find_theorems' searches for a list of criteria instead of a
list of constants. Known criteria are: intro, elim, dest, name:string,
simp:term, and any term. Criteria can be preceded by '-' to select
theorems that do not match. Intro, elim, dest select theorems that
match the current goal, name:s selects theorems whose fully qualified
name contain s, and simp:term selects all simplification rules whose
lhs match term. Any other term is interpreted as pattern and selects
all theorems matching the pattern. Available in ProofGeneral under
'ProofGeneral -> Find Theorems' or C-c C-f. Example:
C-c C-f (100) "(_::nat) + _ + _" intro -name: "HOL."
prints the last 100 theorems matching the pattern "(_::nat) + _ + _",
matching the current goal as introduction rule and not having "HOL."
in their name (i.e. not being defined in theory HOL).
* Command 'thms_containing' has been discontinued in favour of
'find_theorems'; INCOMPATIBILITY.
* Communication with Proof General is now 8bit clean, which means that
Unicode text in UTF-8 encoding may be used within theory texts (both
formal and informal parts). Cf. option -U of the Isabelle Proof
General interface. Here are some simple examples (cf. src/HOL/ex):
http://isabelle.in.tum.de/library/HOL/ex/Hebrew.html
http://isabelle.in.tum.de/library/HOL/ex/Chinese.html
* Improved efficiency of the Simplifier and, to a lesser degree, the
Classical Reasoner. Typical big applications run around 2 times
faster.
*** Document preparation ***
* Commands 'display_drafts' and 'print_drafts' perform simple output
of raw sources. Only those symbols that do not require additional
LaTeX packages (depending on comments in isabellesym.sty) are
displayed properly, everything else is left verbatim. isatool display
and isatool print are used as front ends (these are subject to the
DVI/PDF_VIEWER and PRINT_COMMAND settings, respectively).
* Command tags control specific markup of certain regions of text,
notably folding and hiding. Predefined tags include "theory" (for
theory begin and end), "proof" for proof commands, and "ML" for
commands involving ML code; the additional tags "visible" and
"invisible" are unused by default. Users may give explicit tag
specifications in the text, e.g. ''by %invisible (auto)''. The
interpretation of tags is determined by the LaTeX job during document
preparation: see option -V of isatool usedir, or options -n and -t of
isatool document, or even the LaTeX macros \isakeeptag, \isafoldtag,
\isadroptag.
Several document versions may be produced at the same time via isatool
usedir (the generated index.html will link all of them). Typical
specifications include ''-V document=theory,proof,ML'' to present
theory/proof/ML parts faithfully, ''-V outline=/proof,/ML'' to fold
proof and ML commands, and ''-V mutilated=-theory,-proof,-ML'' to omit
these parts without any formal replacement text. The Isabelle site
default settings produce ''document'' and ''outline'' versions as
specified above.
* Several new antiquotations:
@{term_type term} prints a term with its type annotated;
@{typeof term} prints the type of a term;
@{const const} is the same as @{term const}, but checks that the
argument is a known logical constant;
@{term_style style term} and @{thm_style style thm} print a term or
theorem applying a "style" to it
@{ML text}
Predefined styles are 'lhs' and 'rhs' printing the lhs/rhs of
definitions, equations, inequations etc., 'concl' printing only the
conclusion of a meta-logical statement theorem, and 'prem1' .. 'prem19'
to print the specified premise. TermStyle.add_style provides an ML
interface for introducing further styles. See also the "LaTeX Sugar"
document practical applications. The ML antiquotation prints
type-checked ML expressions verbatim.
* Markup commands 'chapter', 'section', 'subsection', 'subsubsection',
and 'text' support optional locale specification '(in loc)', which
specifies the default context for interpreting antiquotations. For
example: 'text (in lattice) {* @{thm inf_assoc}*}'.
* Option 'locale=NAME' of antiquotations specifies an alternative
context interpreting the subsequent argument. For example: @{thm
[locale=lattice] inf_assoc}.
* Proper output of proof terms (@{prf ...} and @{full_prf ...}) within
a proof context.
* Proper output of antiquotations for theory commands involving a
proof context (such as 'locale' or 'theorem (in loc) ...').
* Delimiters of outer tokens (string etc.) now produce separate LaTeX
macros (\isachardoublequoteopen, isachardoublequoteclose etc.).
* isatool usedir: new option -C (default true) controls whether option
-D should include a copy of the original document directory; -C false
prevents unwanted effects such as copying of administrative CVS data.
*** Pure ***
* Considerably improved version of 'constdefs' command. Now performs
automatic type-inference of declared constants; additional support for
local structure declarations (cf. locales and HOL records), see also
isar-ref manual. Potential INCOMPATIBILITY: need to observe strictly
sequential dependencies of definitions within a single 'constdefs'
section; moreover, the declared name needs to be an identifier. If
all fails, consider to fall back on 'consts' and 'defs' separately.
* Improved indexed syntax and implicit structures. First of all,
indexed syntax provides a notational device for subscripted
application, using the new syntax \<^bsub>term\<^esub> for arbitrary
expressions. Secondly, in a local context with structure
declarations, number indexes \<^sub>n or the empty index (default
number 1) refer to a certain fixed variable implicitly; option
show_structs controls printing of implicit structures. Typical
applications of these concepts involve record types and locales.
* New command 'no_syntax' removes grammar declarations (and
translations) resulting from the given syntax specification, which is
interpreted in the same manner as for the 'syntax' command.
* 'Advanced' translation functions (parse_translation etc.) may depend
on the signature of the theory context being presently used for
parsing/printing, see also isar-ref manual.
* Improved 'oracle' command provides a type-safe interface to turn an
ML expression of type theory -> T -> term into a primitive rule of
type theory -> T -> thm (i.e. the functionality of Thm.invoke_oracle
is already included here); see also FOL/ex/IffExample.thy;
INCOMPATIBILITY.
* axclass: name space prefix for class "c" is now "c_class" (was "c"
before); "cI" is no longer bound, use "c.intro" instead.
INCOMPATIBILITY. This change avoids clashes of fact bindings for
axclasses vs. locales.
* Improved internal renaming of symbolic identifiers -- attach primes
instead of base 26 numbers.
* New flag show_question_marks controls printing of leading question
marks in schematic variable names.
* In schematic variable names, *any* symbol following \<^isub> or
\<^isup> is now treated as part of the base name. For example, the
following works without printing of awkward ".0" indexes:
lemma "x\<^isub>1 = x\<^isub>2 ==> x\<^isub>2 = x\<^isub>1"
by simp
* Inner syntax includes (*(*nested*) comments*).
* Pretty printer now supports unbreakable blocks, specified in mixfix
annotations as "(00...)".
* Clear separation of logical types and nonterminals, where the latter
may only occur in 'syntax' specifications or type abbreviations.
Before that distinction was only partially implemented via type class
"logic" vs. "{}". Potential INCOMPATIBILITY in rare cases of improper
use of 'types'/'consts' instead of 'nonterminals'/'syntax'. Some very
exotic syntax specifications may require further adaption
(e.g. Cube/Cube.thy).
* Removed obsolete type class "logic", use the top sort {} instead.
Note that non-logical types should be declared as 'nonterminals'
rather than 'types'. INCOMPATIBILITY for new object-logic
specifications.
* Attributes 'induct' and 'cases': type or set names may now be
locally fixed variables as well.
* Simplifier: can now control the depth to which conditional rewriting
is traced via the PG menu Isabelle -> Settings -> Trace Simp Depth
Limit.
* Simplifier: simplification procedures may now take the current
simpset into account (cf. Simplifier.simproc(_i) / mk_simproc
interface), which is very useful for calling the Simplifier
recursively. Minor INCOMPATIBILITY: the 'prems' argument of simprocs
is gone -- use prems_of_ss on the simpset instead. Moreover, the
low-level mk_simproc no longer applies Logic.varify internally, to
allow for use in a context of fixed variables.
* thin_tac now works even if the assumption being deleted contains !!
or ==>. More generally, erule now works even if the major premise of
the elimination rule contains !! or ==>.
* Method 'rules' has been renamed to 'iprover'. INCOMPATIBILITY.
* Reorganized bootstrapping of the Pure theories; CPure is now derived
from Pure, which contains all common declarations already. Both
theories are defined via plain Isabelle/Isar .thy files.
INCOMPATIBILITY: elements of CPure (such as the CPure.intro /
CPure.elim / CPure.dest attributes) now appear in the Pure name space;
use isatool fixcpure to adapt your theory and ML sources.
* New syntax 'name(i-j, i-, i, ...)' for referring to specific
selections of theorems in named facts via index ranges.
* 'print_theorems': in theory mode, really print the difference
wrt. the last state (works for interactive theory development only),
in proof mode print all local facts (cf. 'print_facts');
* 'hide': option '(open)' hides only base names.
* More efficient treatment of intermediate checkpoints in interactive
theory development.
* Code generator is now invoked via code_module (incremental code
generation) and code_library (modular code generation, ML structures
for each theory). INCOMPATIBILITY: new keywords 'file' and 'contains'
must be quoted when used as identifiers.
* New 'value' command for reading, evaluating and printing terms using
the code generator. INCOMPATIBILITY: command keyword 'value' must be
quoted when used as identifier.
*** Locales ***
* New commands for the interpretation of locale expressions in
theories (1), locales (2) and proof contexts (3). These generate
proof obligations from the expression specification. After the
obligations have been discharged, theorems of the expression are added
to the theory, target locale or proof context. The synopsis of the
commands is a follows:
(1) interpretation expr inst
(2) interpretation target < expr
(3) interpret expr inst
Interpretation in theories and proof contexts require a parameter
instantiation of terms from the current context. This is applied to
specifications and theorems of the interpreted expression.
Interpretation in locales only permits parameter renaming through the
locale expression. Interpretation is smart in that interpretations
that are active already do not occur in proof obligations, neither are
instantiated theorems stored in duplicate. Use 'print_interps' to
inspect active interpretations of a particular locale. For details,
see the Isar Reference manual. Examples can be found in
HOL/Finite_Set.thy and HOL/Algebra/UnivPoly.thy.
INCOMPATIBILITY: former 'instantiate' has been withdrawn, use
'interpret' instead.
* New context element 'constrains' for adding type constraints to
parameters.
* Context expressions: renaming of parameters with syntax
redeclaration.
* Locale declaration: 'includes' disallowed.
* Proper static binding of attribute syntax -- i.e. types / terms /
facts mentioned as arguments are always those of the locale definition
context, independently of the context of later invocations. Moreover,
locale operations (renaming and type / term instantiation) are applied
to attribute arguments as expected.
INCOMPATIBILITY of the ML interface: always pass Attrib.src instead of
actual attributes; rare situations may require Attrib.attribute to
embed those attributes into Attrib.src that lack concrete syntax.
Attribute implementations need to cooperate properly with the static
binding mechanism. Basic parsers Args.XXX_typ/term/prop and
Attrib.XXX_thm etc. already do the right thing without further
intervention. Only unusual applications -- such as "where" or "of"
(cf. src/Pure/Isar/attrib.ML), which process arguments depending both
on the context and the facts involved -- may have to assign parsed
values to argument tokens explicitly.
* Changed parameter management in theorem generation for long goal
statements with 'includes'. INCOMPATIBILITY: produces a different
theorem statement in rare situations.
* Locale inspection command 'print_locale' omits notes elements. Use
'print_locale!' to have them included in the output.
*** Provers ***
* Provers/hypsubst.ML: improved version of the subst method, for
single-step rewriting: it now works in bound variable contexts. New is
'subst (asm)', for rewriting an assumption. INCOMPATIBILITY: may
rewrite a different subterm than the original subst method, which is
still available as 'simplesubst'.
* Provers/quasi.ML: new transitivity reasoners for transitivity only
and quasi orders.
* Provers/trancl.ML: new transitivity reasoner for transitive and
reflexive-transitive closure of relations.
* Provers/blast.ML: new reference depth_limit to make blast's depth
limit (previously hard-coded with a value of 20) user-definable.
* Provers/simplifier.ML has been moved to Pure, where Simplifier.setup
is peformed already. Object-logics merely need to finish their
initial simpset configuration as before. INCOMPATIBILITY.
*** HOL ***
* Symbolic syntax of Hilbert Choice Operator is now as follows:
syntax (epsilon)
"_Eps" :: "[pttrn, bool] => 'a" ("(3\_./ _)" [0, 10] 10)
The symbol \ is displayed as the alternative epsilon of LaTeX
and x-symbol; use option '-m epsilon' to get it actually printed.
Moreover, the mathematically important symbolic identifier \
becomes available as variable, constant etc. INCOMPATIBILITY,
* "x > y" abbreviates "y < x" and "x >= y" abbreviates "y <= x".
Similarly for all quantifiers: "ALL x > y" etc. The x-symbol for >=
is \. New transitivity rules have been added to HOL/Orderings.thy to
support corresponding Isar calculations.
* "{x:A. P}" abbreviates "{x. x:A & P}", and similarly for "\"
instead of ":".
* theory SetInterval: changed the syntax for open intervals:
Old New
{..n(} {.. {\1<\.\.}
\.\.\([^(}]*\)(} -> \.\.<\1}
* Theory Commutative_Ring (in Library): method comm_ring for proving
equalities in commutative rings; method 'algebra' provides a generic
interface.
* Theory Finite_Set: changed the syntax for 'setsum', summation over
finite sets: "setsum (%x. e) A", which used to be "\x:A. e", is
now either "SUM x:A. e" or "\x \ A. e". The bound variable can
be a tuple pattern.
Some new syntax forms are available:
"\x | P. e" for "setsum (%x. e) {x. P}"
"\x = a..b. e" for "setsum (%x. e) {a..b}"
"\x = a..x < k. e" for "setsum (%x. e) {..x < k. e" used to be based on a separate
function "Summation", which has been discontinued.
* theory Finite_Set: in structured induction proofs, the insert case
is now 'case (insert x F)' instead of the old counterintuitive 'case
(insert F x)'.
* The 'refute' command has been extended to support a much larger
fragment of HOL, including axiomatic type classes, constdefs and
typedefs, inductive datatypes and recursion.
* New tactics 'sat' and 'satx' to prove propositional tautologies.
Requires zChaff with proof generation to be installed. See
HOL/ex/SAT_Examples.thy for examples.
* Datatype induction via method 'induct' now preserves the name of the
induction variable. For example, when proving P(xs::'a list) by
induction on xs, the induction step is now P(xs) ==> P(a#xs) rather
than P(list) ==> P(a#list) as previously. Potential INCOMPATIBILITY
in unstructured proof scripts.
* Reworked implementation of records. Improved scalability for
records with many fields, avoiding performance problems for type
inference. Records are no longer composed of nested field types, but
of nested extension types. Therefore the record type only grows linear
in the number of extensions and not in the number of fields. The
top-level (users) view on records is preserved. Potential
INCOMPATIBILITY only in strange cases, where the theory depends on the
old record representation. The type generated for a record is called
_ext_type.
Flag record_quick_and_dirty_sensitive can be enabled to skip the
proofs triggered by a record definition or a simproc (if
quick_and_dirty is enabled). Definitions of large records can take
quite long.
New simproc record_upd_simproc for simplification of multiple record
updates enabled by default. Moreover, trivial updates are also
removed: r(|x := x r|) = r. INCOMPATIBILITY: old proofs break
occasionally, since simplification is more powerful by default.
* typedef: proper support for polymorphic sets, which contain extra
type-variables in the term.
* Simplifier: automatically reasons about transitivity chains
involving "trancl" (r^+) and "rtrancl" (r^*) by setting up tactics
provided by Provers/trancl.ML as additional solvers. INCOMPATIBILITY:
old proofs break occasionally as simplification may now solve more
goals than previously.
* Simplifier: converts x <= y into x = y if assumption y <= x is
present. Works for all partial orders (class "order"), in particular
numbers and sets. For linear orders (e.g. numbers) it treats ~ x < y
just like y <= x.
* Simplifier: new simproc for "let x = a in f x". If a is a free or
bound variable or a constant then the let is unfolded. Otherwise
first a is simplified to b, and then f b is simplified to g. If
possible we abstract b from g arriving at "let x = b in h x",
otherwise we unfold the let and arrive at g. The simproc can be
enabled/disabled by the reference use_let_simproc. Potential
INCOMPATIBILITY since simplification is more powerful by default.
* Classical reasoning: the meson method now accepts theorems as arguments.
* Prover support: pre-release of the Isabelle-ATP linkup, which runs background
jobs to provide advice on the provability of subgoals.
* Theory OrderedGroup and Ring_and_Field: various additions and
improvements to faciliate calculations involving equalities and
inequalities.
The following theorems have been eliminated or modified
(INCOMPATIBILITY):
abs_eq now named abs_of_nonneg
abs_of_ge_0 now named abs_of_nonneg
abs_minus_eq now named abs_of_nonpos
imp_abs_id now named abs_of_nonneg
imp_abs_neg_id now named abs_of_nonpos
mult_pos now named mult_pos_pos
mult_pos_le now named mult_nonneg_nonneg
mult_pos_neg_le now named mult_nonneg_nonpos
mult_pos_neg2_le now named mult_nonneg_nonpos2
mult_neg now named mult_neg_neg
mult_neg_le now named mult_nonpos_nonpos
* The following lemmas in Ring_and_Field have been added to the simplifier:
zero_le_square
not_square_less_zero
The following lemmas have been deleted from Real/RealPow:
realpow_zero_zero
realpow_two
realpow_less
zero_le_power
realpow_two_le
abs_realpow_two
realpow_two_abs
* Theory Parity: added rules for simplifying exponents.
* Theory List:
The following theorems have been eliminated or modified
(INCOMPATIBILITY):
list_all_Nil now named list_all.simps(1)
list_all_Cons now named list_all.simps(2)
list_all_conv now named list_all_iff
set_mem_eq now named mem_iff
* Theories SetsAndFunctions and BigO (see HOL/Library) support
asymptotic "big O" calculations. See the notes in BigO.thy.
*** HOL-Complex ***
* Theory RealDef: better support for embedding natural numbers and
integers in the reals.
The following theorems have been eliminated or modified
(INCOMPATIBILITY):
exp_ge_add_one_self now requires no hypotheses
real_of_int_add reversed direction of equality (use [symmetric])
real_of_int_minus reversed direction of equality (use [symmetric])
real_of_int_diff reversed direction of equality (use [symmetric])
real_of_int_mult reversed direction of equality (use [symmetric])
* Theory RComplete: expanded support for floor and ceiling functions.
* Theory Ln is new, with properties of the natural logarithm
* Hyperreal: There is a new type constructor "star" for making
nonstandard types. The old type names are now type synonyms:
hypreal = real star
hypnat = nat star
hcomplex = complex star
* Hyperreal: Many groups of similarly-defined constants have been
replaced by polymorphic versions (INCOMPATIBILITY):
star_of <-- hypreal_of_real, hypnat_of_nat, hcomplex_of_complex
starset <-- starsetNat, starsetC
*s* <-- *sNat*, *sc*
starset_n <-- starsetNat_n, starsetC_n
*sn* <-- *sNatn*, *scn*
InternalSets <-- InternalNatSets, InternalCSets
starfun <-- starfun{Nat,Nat2,C,RC,CR}
*f* <-- *fNat*, *fNat2*, *fc*, *fRc*, *fcR*
starfun_n <-- starfun{Nat,Nat2,C,RC,CR}_n
*fn* <-- *fNatn*, *fNat2n*, *fcn*, *fRcn*, *fcRn*
InternalFuns <-- InternalNatFuns, InternalNatFuns2, Internal{C,RC,CR}Funs
* Hyperreal: Many type-specific theorems have been removed in favor of
theorems specific to various axiomatic type classes (INCOMPATIBILITY):
add_commute <-- {hypreal,hypnat,hcomplex}_add_commute
add_assoc <-- {hypreal,hypnat,hcomplex}_add_assocs
OrderedGroup.add_0 <-- {hypreal,hypnat,hcomplex}_add_zero_left
OrderedGroup.add_0_right <-- {hypreal,hcomplex}_add_zero_right
right_minus <-- hypreal_add_minus
left_minus <-- {hypreal,hcomplex}_add_minus_left
mult_commute <-- {hypreal,hypnat,hcomplex}_mult_commute
mult_assoc <-- {hypreal,hypnat,hcomplex}_mult_assoc
mult_1_left <-- {hypreal,hypnat}_mult_1, hcomplex_mult_one_left
mult_1_right <-- hcomplex_mult_one_right
mult_zero_left <-- hcomplex_mult_zero_left
left_distrib <-- {hypreal,hypnat,hcomplex}_add_mult_distrib
right_distrib <-- hypnat_add_mult_distrib2
zero_neq_one <-- {hypreal,hypnat,hcomplex}_zero_not_eq_one
right_inverse <-- hypreal_mult_inverse
left_inverse <-- hypreal_mult_inverse_left, hcomplex_mult_inv_left
order_refl <-- {hypreal,hypnat}_le_refl
order_trans <-- {hypreal,hypnat}_le_trans
order_antisym <-- {hypreal,hypnat}_le_anti_sym
order_less_le <-- {hypreal,hypnat}_less_le
linorder_linear <-- {hypreal,hypnat}_le_linear
add_left_mono <-- {hypreal,hypnat}_add_left_mono
mult_strict_left_mono <-- {hypreal,hypnat}_mult_less_mono2
add_nonneg_nonneg <-- hypreal_le_add_order
* Hyperreal: Separate theorems having to do with type-specific
versions of constants have been merged into theorems that apply to the
new polymorphic constants (INCOMPATIBILITY):
STAR_UNIV_set <-- {STAR_real,NatStar_real,STARC_complex}_set
STAR_empty_set <-- {STAR,NatStar,STARC}_empty_set
STAR_Un <-- {STAR,NatStar,STARC}_Un
STAR_Int <-- {STAR,NatStar,STARC}_Int
STAR_Compl <-- {STAR,NatStar,STARC}_Compl
STAR_subset <-- {STAR,NatStar,STARC}_subset
STAR_mem <-- {STAR,NatStar,STARC}_mem
STAR_mem_Compl <-- {STAR,STARC}_mem_Compl
STAR_diff <-- {STAR,STARC}_diff
STAR_star_of_image_subset <-- {STAR_hypreal_of_real, NatStar_hypreal_of_real,
STARC_hcomplex_of_complex}_image_subset
starset_n_Un <-- starset{Nat,C}_n_Un
starset_n_Int <-- starset{Nat,C}_n_Int
starset_n_Compl <-- starset{Nat,C}_n_Compl
starset_n_diff <-- starset{Nat,C}_n_diff
InternalSets_Un <-- Internal{Nat,C}Sets_Un
InternalSets_Int <-- Internal{Nat,C}Sets_Int
InternalSets_Compl <-- Internal{Nat,C}Sets_Compl
InternalSets_diff <-- Internal{Nat,C}Sets_diff
InternalSets_UNIV_diff <-- Internal{Nat,C}Sets_UNIV_diff
InternalSets_starset_n <-- Internal{Nat,C}Sets_starset{Nat,C}_n
starset_starset_n_eq <-- starset{Nat,C}_starset{Nat,C}_n_eq
starset_n_starset <-- starset{Nat,C}_n_starset{Nat,C}
starfun_n_starfun <-- starfun{Nat,Nat2,C,RC,CR}_n_starfun{Nat,Nat2,C,RC,CR}
starfun <-- starfun{Nat,Nat2,C,RC,CR}
starfun_mult <-- starfun{Nat,Nat2,C,RC,CR}_mult
starfun_add <-- starfun{Nat,Nat2,C,RC,CR}_add
starfun_minus <-- starfun{Nat,Nat2,C,RC,CR}_minus
starfun_diff <-- starfun{C,RC,CR}_diff
starfun_o <-- starfun{NatNat2,Nat2,_stafunNat,C,C_starfunRC,_starfunCR}_o
starfun_o2 <-- starfun{NatNat2,_stafunNat,C,C_starfunRC,_starfunCR}_o2
starfun_const_fun <-- starfun{Nat,Nat2,C,RC,CR}_const_fun
starfun_inverse <-- starfun{Nat,C,RC,CR}_inverse
starfun_eq <-- starfun{Nat,Nat2,C,RC,CR}_eq
starfun_eq_iff <-- starfun{C,RC,CR}_eq_iff
starfun_Id <-- starfunC_Id
starfun_approx <-- starfun{Nat,CR}_approx
starfun_capprox <-- starfun{C,RC}_capprox
starfun_abs <-- starfunNat_rabs
starfun_lambda_cancel <-- starfun{C,CR,RC}_lambda_cancel
starfun_lambda_cancel2 <-- starfun{C,CR,RC}_lambda_cancel2
starfun_mult_HFinite_approx <-- starfunCR_mult_HFinite_capprox
starfun_mult_CFinite_capprox <-- starfun{C,RC}_mult_CFinite_capprox
starfun_add_capprox <-- starfun{C,RC}_add_capprox
starfun_add_approx <-- starfunCR_add_approx
starfun_inverse_inverse <-- starfunC_inverse_inverse
starfun_divide <-- starfun{C,CR,RC}_divide
starfun_n <-- starfun{Nat,C}_n
starfun_n_mult <-- starfun{Nat,C}_n_mult
starfun_n_add <-- starfun{Nat,C}_n_add
starfun_n_add_minus <-- starfunNat_n_add_minus
starfun_n_const_fun <-- starfun{Nat,C}_n_const_fun
starfun_n_minus <-- starfun{Nat,C}_n_minus
starfun_n_eq <-- starfun{Nat,C}_n_eq
star_n_add <-- {hypreal,hypnat,hcomplex}_add
star_n_minus <-- {hypreal,hcomplex}_minus
star_n_diff <-- {hypreal,hcomplex}_diff
star_n_mult <-- {hypreal,hcomplex}_mult
star_n_inverse <-- {hypreal,hcomplex}_inverse
star_n_le <-- {hypreal,hypnat}_le
star_n_less <-- {hypreal,hypnat}_less
star_n_zero_num <-- {hypreal,hypnat,hcomplex}_zero_num
star_n_one_num <-- {hypreal,hypnat,hcomplex}_one_num
star_n_abs <-- hypreal_hrabs
star_n_divide <-- hcomplex_divide
star_of_add <-- {hypreal_of_real,hypnat_of_nat,hcomplex_of_complex}_add
star_of_minus <-- {hypreal_of_real,hcomplex_of_complex}_minus
star_of_diff <-- hypreal_of_real_diff
star_of_mult <-- {hypreal_of_real,hypnat_of_nat,hcomplex_of_complex}_mult
star_of_one <-- {hypreal_of_real,hcomplex_of_complex}_one
star_of_zero <-- {hypreal_of_real,hypnat_of_nat,hcomplex_of_complex}_zero
star_of_le <-- {hypreal_of_real,hypnat_of_nat}_le_iff
star_of_less <-- {hypreal_of_real,hypnat_of_nat}_less_iff
star_of_eq <-- {hypreal_of_real,hypnat_of_nat,hcomplex_of_complex}_eq_iff
star_of_inverse <-- {hypreal_of_real,hcomplex_of_complex}_inverse
star_of_divide <-- {hypreal_of_real,hcomplex_of_complex}_divide
star_of_of_nat <-- {hypreal_of_real,hcomplex_of_complex}_of_nat
star_of_of_int <-- {hypreal_of_real,hcomplex_of_complex}_of_int
star_of_number_of <-- {hypreal,hcomplex}_number_of
star_of_number_less <-- number_of_less_hypreal_of_real_iff
star_of_number_le <-- number_of_le_hypreal_of_real_iff
star_of_eq_number <-- hypreal_of_real_eq_number_of_iff
star_of_less_number <-- hypreal_of_real_less_number_of_iff
star_of_le_number <-- hypreal_of_real_le_number_of_iff
star_of_power <-- hypreal_of_real_power
star_of_eq_0 <-- hcomplex_of_complex_zero_iff
* Hyperreal: new method "transfer" that implements the transfer
principle of nonstandard analysis. With a subgoal that mentions
nonstandard types like "'a star", the command "apply transfer"
replaces it with an equivalent one that mentions only standard types.
To be successful, all free variables must have standard types; non-
standard variables must have explicit universal quantifiers.
* Hyperreal: A theory of Taylor series.
*** HOLCF ***
* Discontinued special version of 'constdefs' (which used to support
continuous functions) in favor of the general Pure one with full
type-inference.
* New simplification procedure for solving continuity conditions; it
is much faster on terms with many nested lambda abstractions (cubic
instead of exponential time).
* New syntax for domain package: selector names are now optional.
Parentheses should be omitted unless argument is lazy, for example:
domain 'a stream = cons "'a" (lazy "'a stream")
* New command 'fixrec' for defining recursive functions with pattern
matching; defining multiple functions with mutual recursion is also
supported. Patterns may include the constants cpair, spair, up, sinl,
sinr, or any data constructor defined by the domain package. The given
equations are proven as rewrite rules. See HOLCF/ex/Fixrec_ex.thy for
syntax and examples.
* New commands 'cpodef' and 'pcpodef' for defining predicate subtypes
of cpo and pcpo types. Syntax is exactly like the 'typedef' command,
but the proof obligation additionally includes an admissibility
requirement. The packages generate instances of class cpo or pcpo,
with continuity and strictness theorems for Rep and Abs.
* HOLCF: Many theorems have been renamed according to a more standard naming
scheme (INCOMPATIBILITY):
foo_inject: "foo$x = foo$y ==> x = y"
foo_eq: "(foo$x = foo$y) = (x = y)"
foo_less: "(foo$x << foo$y) = (x << y)"
foo_strict: "foo$UU = UU"
foo_defined: "... ==> foo$x ~= UU"
foo_defined_iff: "(foo$x = UU) = (x = UU)"
*** ZF ***
* ZF/ex: theories Group and Ring provide examples in abstract algebra,
including the First Isomorphism Theorem (on quotienting by the kernel
of a homomorphism).
* ZF/Simplifier: install second copy of type solver that actually
makes use of TC rules declared to Isar proof contexts (or locales);
the old version is still required for ML proof scripts.
*** Cube ***
* Converted to Isar theory format; use locales instead of axiomatic
theories.
*** ML ***
* Pure/library.ML: added ##>, ##>>, #>> -- higher-order counterparts
for ||>, ||>>, |>>,
* Pure/library.ML no longer defines its own option datatype, but uses
that of the SML basis, which has constructors NONE and SOME instead of
None and Some, as well as exception Option.Option instead of OPTION.
The functions the, if_none, is_some, is_none have been adapted
accordingly, while Option.map replaces apsome.
* Pure/library.ML: the exception LIST has been given up in favour of
the standard exceptions Empty and Subscript, as well as
Library.UnequalLengths. Function like Library.hd and Library.tl are
superceded by the standard hd and tl functions etc.
A number of basic list functions are no longer exported to the ML
toplevel, as they are variants of predefined functions. The following
suggests how one can translate existing code:
rev_append xs ys = List.revAppend (xs, ys)
nth_elem (i, xs) = List.nth (xs, i)
last_elem xs = List.last xs
flat xss = List.concat xss
seq fs = List.app fs
partition P xs = List.partition P xs
mapfilter f xs = List.mapPartial f xs
* Pure/library.ML: several combinators for linear functional
transformations, notably reverse application and composition:
x |> f f #> g
(x, y) |-> f f #-> g
* Pure/library.ML: introduced/changed precedence of infix operators:
infix 1 |> |-> ||> ||>> |>> |>>> #> #->;
infix 2 ?;
infix 3 o oo ooo oooo;
infix 4 ~~ upto downto;
Maybe INCOMPATIBILITY when any of those is used in conjunction with other
infix operators.
* Pure/library.ML: natural list combinators fold, fold_rev, and
fold_map support linear functional transformations and nesting. For
example:
fold f [x1, ..., xN] y =
y |> f x1 |> ... |> f xN
(fold o fold) f [xs1, ..., xsN] y =
y |> fold f xs1 |> ... |> fold f xsN
fold f [x1, ..., xN] =
f x1 #> ... #> f xN
(fold o fold) f [xs1, ..., xsN] =
fold f xs1 #> ... #> fold f xsN
* Pure/library.ML: the following selectors on type 'a option are
available:
the: 'a option -> 'a (*partial*)
these: 'a option -> 'a where 'a = 'b list
the_default: 'a -> 'a option -> 'a
the_list: 'a option -> 'a list
* Pure/General: structure AList (cf. Pure/General/alist.ML) provides
basic operations for association lists, following natural argument
order; moreover the explicit equality predicate passed here avoids
potentially expensive polymorphic runtime equality checks.
The old functions may be expressed as follows:
assoc = uncurry (AList.lookup (op =))
assocs = these oo AList.lookup (op =)
overwrite = uncurry (AList.update (op =)) o swap
* Pure/General: structure AList (cf. Pure/General/alist.ML) provides
val make: ('a -> 'b) -> 'a list -> ('a * 'b) list
val find: ('a * 'b -> bool) -> ('c * 'b) list -> 'a -> 'c list
replacing make_keylist and keyfilter (occassionally used)
Naive rewrites:
make_keylist = AList.make
keyfilter = AList.find (op =)
* eq_fst and eq_snd now take explicit equality parameter, thus
avoiding eqtypes. Naive rewrites:
eq_fst = eq_fst (op =)
eq_snd = eq_snd (op =)
* Removed deprecated apl and apr (rarely used).
Naive rewrites:
apl (n, op) =>>= curry op n
apr (op, m) =>>= fn n => op (n, m)
* Pure/General: structure OrdList (cf. Pure/General/ord_list.ML)
provides a reasonably efficient light-weight implementation of sets as
lists.
* Pure/General: generic tables (cf. Pure/General/table.ML) provide a
few new operations; existing lookup and update are now curried to
follow natural argument order (for use with fold etc.);
INCOMPATIBILITY, use (uncurry Symtab.lookup) etc. as last resort.
* Pure/General: output via the Isabelle channels of
writeln/warning/error etc. is now passed through Output.output, with a
hook for arbitrary transformations depending on the print_mode
(cf. Output.add_mode -- the first active mode that provides a output
function wins). Already formatted output may be embedded into further
text via Output.raw; the result of Pretty.string_of/str_of and derived
functions (string_of_term/cterm/thm etc.) is already marked raw to
accommodate easy composition of diagnostic messages etc. Programmers
rarely need to care about Output.output or Output.raw at all, with
some notable exceptions: Output.output is required when bypassing the
standard channels (writeln etc.), or in token translations to produce
properly formatted results; Output.raw is required when capturing
already output material that will eventually be presented to the user
a second time. For the default print mode, both Output.output and
Output.raw have no effect.
* Pure/General: Output.time_accumulator NAME creates an operator ('a
-> 'b) -> 'a -> 'b to measure runtime and count invocations; the
cumulative results are displayed at the end of a batch session.
* Pure/General: File.sysify_path and File.quote_sysify path have been
replaced by File.platform_path and File.shell_path (with appropriate
hooks). This provides a clean interface for unusual systems where the
internal and external process view of file names are different.
* Pure: more efficient orders for basic syntactic entities: added
fast_string_ord, fast_indexname_ord, fast_term_ord; changed sort_ord
and typ_ord to use fast_string_ord and fast_indexname_ord (term_ord is
NOT affected); structures Symtab, Vartab, Typtab, Termtab use the fast
orders now -- potential INCOMPATIBILITY for code that depends on a
particular order for Symtab.keys, Symtab.dest, etc. (consider using
Library.sort_strings on result).
* Pure/term.ML: combinators fold_atyps, fold_aterms, fold_term_types,
fold_types traverse types/terms from left to right, observing natural
argument order. Supercedes previous foldl_XXX versions, add_frees,
add_vars etc. have been adapted as well: INCOMPATIBILITY.
* Pure: name spaces have been refined, with significant changes of the
internal interfaces -- INCOMPATIBILITY. Renamed cond_extern(_table)
to extern(_table). The plain name entry path is superceded by a
general 'naming' context, which also includes the 'policy' to produce
a fully qualified name and external accesses of a fully qualified
name; NameSpace.extend is superceded by context dependent
Sign.declare_name. Several theory and proof context operations modify
the naming context. Especially note Theory.restore_naming and
ProofContext.restore_naming to get back to a sane state; note that
Theory.add_path is no longer sufficient to recover from
Theory.absolute_path in particular.
* Pure: new flags short_names (default false) and unique_names
(default true) for controlling output of qualified names. If
short_names is set, names are printed unqualified. If unique_names is
reset, the name prefix is reduced to the minimum required to achieve
the original result when interning again, even if there is an overlap
with earlier declarations.
* Pure/TheoryDataFun: change of the argument structure; 'prep_ext' is
now 'extend', and 'merge' gets an additional Pretty.pp argument
(useful for printing error messages). INCOMPATIBILITY.
* Pure: major reorganization of the theory context. Type Sign.sg and
Theory.theory are now identified, referring to the universal
Context.theory (see Pure/context.ML). Actual signature and theory
content is managed as theory data. The old code and interfaces were
spread over many files and structures; the new arrangement introduces
considerable INCOMPATIBILITY to gain more clarity:
Context -- theory management operations (name, identity, inclusion,
parents, ancestors, merge, etc.), plus generic theory data;
Sign -- logical signature and syntax operations (declaring consts,
types, etc.), plus certify/read for common entities;
Theory -- logical theory operations (stating axioms, definitions,
oracles), plus a copy of logical signature operations (consts,
types, etc.); also a few basic management operations (Theory.copy,
Theory.merge, etc.)
The most basic sign_of operations (Theory.sign_of, Thm.sign_of_thm
etc.) as well as the sign field in Thm.rep_thm etc. have been retained
for convenience -- they merely return the theory.
* Pure: type Type.tsig is superceded by theory in most interfaces.
* Pure: the Isar proof context type is already defined early in Pure
as Context.proof (note that ProofContext.context and Proof.context are
aliases, where the latter is the preferred name). This enables other
Isabelle components to refer to that type even before Isar is present.
* Pure/sign/theory: discontinued named name spaces (i.e. classK,
typeK, constK, axiomK, oracleK), but provide explicit operations for
any of these kinds. For example, Sign.intern typeK is now
Sign.intern_type, Theory.hide_space Sign.typeK is now
Theory.hide_types. Also note that former
Theory.hide_classes/types/consts are now
Theory.hide_classes_i/types_i/consts_i, while the non '_i' versions
internalize their arguments! INCOMPATIBILITY.
* Pure: get_thm interface (of PureThy and ProofContext) expects
datatype thmref (with constructors Name and NameSelection) instead of
plain string -- INCOMPATIBILITY;
* Pure: cases produced by proof methods specify options, where NONE
means to remove case bindings -- INCOMPATIBILITY in
(RAW_)METHOD_CASES.
* Pure: the following operations retrieve axioms or theorems from a
theory node or theory hierarchy, respectively:
Theory.axioms_of: theory -> (string * term) list
Theory.all_axioms_of: theory -> (string * term) list
PureThy.thms_of: theory -> (string * thm) list
PureThy.all_thms_of: theory -> (string * thm) list
* Pure: print_tac now outputs the goal through the trace channel.
* Isar toplevel: improved diagnostics, mostly for Poly/ML only.
Reference Toplevel.debug (default false) controls detailed printing
and tracing of low-level exceptions; Toplevel.profiling (default 0)
controls execution profiling -- set to 1 for time and 2 for space
(both increase the runtime).
* Isar session: The initial use of ROOT.ML is now always timed,
i.e. the log will show the actual process times, in contrast to the
elapsed wall-clock time that the outer shell wrapper produces.
* Simplifier: improved handling of bound variables (nameless
representation, avoid allocating new strings). Simprocs that invoke
the Simplifier recursively should use Simplifier.inherit_bounds to
avoid local name clashes. Failure to do so produces warnings
"Simplifier: renamed bound variable ..."; set Simplifier.debug_bounds
for further details.
* ML functions legacy_bindings and use_legacy_bindings produce ML fact
bindings for all theorems stored within a given theory; this may help
in porting non-Isar theories to Isar ones, while keeping ML proof
scripts for the time being.
* ML operator HTML.with_charset specifies the charset begin used for
generated HTML files. For example:
HTML.with_charset "utf-8" use_thy "Hebrew";
HTML.with_charset "utf-8" use_thy "Chinese";
*** System ***
* Allow symlinks to all proper Isabelle executables (Isabelle,
isabelle, isatool etc.).
* ISABELLE_DOC_FORMAT setting specifies preferred document format (for
isatool doc, isatool mkdir, display_drafts etc.).
* isatool usedir: option -f allows specification of the ML file to be
used by Isabelle; default is ROOT.ML.
* New isatool version outputs the version identifier of the Isabelle
distribution being used.
* HOL: new isatool dimacs2hol converts files in DIMACS CNF format
(containing Boolean satisfiability problems) into Isabelle/HOL
theories.
New in Isabelle2004 (April 2004)
--------------------------------
*** General ***
* Provers/order.ML: new efficient reasoner for partial and linear orders.
Replaces linorder.ML.
* Pure: Greek letters (except small lambda, \), as well as Gothic
(\...\\...\), calligraphic (\

...\), and Euler
(\...\), are now considered normal letters, and can therefore
be used anywhere where an ASCII letter (a...zA...Z) has until
now. COMPATIBILITY: This obviously changes the parsing of some
terms, especially where a symbol has been used as a binder, say
'\x. ...', which is now a type error since \x will be parsed
as an identifier. Fix it by inserting a space around former
symbols. Call 'isatool fixgreek' to try to fix parsing errors in
existing theory and ML files.
* Pure: Macintosh and Windows line-breaks are now allowed in theory files.
* Pure: single letter sub/superscripts (\<^isub> and \<^isup>) are now
allowed in identifiers. Similar to Greek letters \<^isub> is now considered
a normal (but invisible) letter. For multiple letter subscripts repeat
\<^isub> like this: x\<^isub>1\<^isub>2.
* Pure: There are now sub-/superscripts that can span more than one
character. Text between \<^bsub> and \<^esub> is set in subscript in
ProofGeneral and LaTeX, text between \<^bsup> and \<^esup> in
superscript. The new control characters are not identifier parts.
* Pure: Control-symbols of the form \<^raw:...> will literally print the
content of "..." to the latex file instead of \isacntrl... . The "..."
may consist of any printable characters excluding the end bracket >.
* Pure: Using new Isar command "finalconsts" (or the ML functions
Theory.add_finals or Theory.add_finals_i) it is now possible to
declare constants "final", which prevents their being given a definition
later. It is useful for constants whose behaviour is fixed axiomatically
rather than definitionally, such as the meta-logic connectives.
* Pure: 'instance' now handles general arities with general sorts
(i.e. intersections of classes),
* Presentation: generated HTML now uses a CSS style sheet to make layout
(somewhat) independent of content. It is copied from lib/html/isabelle.css.
It can be changed to alter the colors/layout of generated pages.
*** Isar ***
* Tactic emulation methods rule_tac, erule_tac, drule_tac, frule_tac,
cut_tac, subgoal_tac and thin_tac:
- Now understand static (Isar) contexts. As a consequence, users of Isar
locales are no longer forced to write Isar proof scripts.
For details see Isar Reference Manual, paragraph 4.3.2: Further tactic
emulations.
- INCOMPATIBILITY: names of variables to be instantiated may no
longer be enclosed in quotes. Instead, precede variable name with `?'.
This is consistent with the instantiation attribute "where".
* Attributes "where" and "of":
- Now take type variables of instantiated theorem into account when reading
the instantiation string. This fixes a bug that caused instantiated
theorems to have too special types in some circumstances.
- "where" permits explicit instantiations of type variables.
* Calculation commands "moreover" and "also" no longer interfere with
current facts ("this"), admitting arbitrary combinations with "then"
and derived forms.
* Locales:
- Goal statements involving the context element "includes" no longer
generate theorems with internal delta predicates (those ending on
"_axioms") in the premise.
Resolve particular premise with .intro to obtain old form.
- Fixed bug in type inference ("unify_frozen") that prevented mix of target
specification and "includes" elements in goal statement.
- Rule sets .intro and .axioms no longer declared as
[intro?] and [elim?] (respectively) by default.
- Experimental command for instantiation of locales in proof contexts:
instantiate