In this chapter, we introduce advanced commands to modify the way Coq parses and prints objects, i.e. the translations between the concrete and internal representations of terms and commands.
The main commands to provide custom symbolic notations for terms are :cmd:`Notation` and :cmd:`Infix`; they will be described in the :ref:`next section <Notations>`. There is also a variant of :cmd:`Notation` which does not modify the parser; this provides a form of :ref:`abbreviation <Abbreviations>`. It is sometimes expected that the same symbolic notation has different meanings in different contexts; to achieve this form of overloading, Coq offers a notion of :ref:`notation scopes <Scopes>`. The main command to provide custom notations for tactics is :cmd:`Tactic Notation`.
.. coqtop:: none Set Printing Depth 50.
.. cmd:: Notation @notation_declaration .. insertprodn notation_declaration notation_declaration .. prodn:: notation_declaration ::= @string := @one_term {? ( {+, @syntax_modifier } ) } {? : @scope_name } Defines a *notation*, an alternate syntax for entering or displaying a specific term or term pattern. This command supports the :attr:`local` attribute, which limits its effect to the current module. If the command is inside a section, its effect is limited to the section. Specifying :token:`scope_name` associates the notation with that scope. Otherwise it is a :gdef:`lonely notation`, that is, not associated with a scope. .. todo indentation of this chapter is not consistent with other chapters. Do we have a standard?
For example, the following definition permits using the infix expression :g:`A /\ B` to represent :g:`(and A B)`:
.. coqtop:: in Notation "A /\ B" := (and A B).
:g:`"A /\ B"` is a notation, which tells how to represent the abbreviated term :g:`(and A B)`.
Notations must be in double quotes, except when the
abbreviation has the form of an ordinary applicative expression;
see :ref:`Abbreviations`. The notation consists of tokens separated by
spaces. Tokens which are identifiers (such as A
, x0'
, etc.) are the parameters
of the notation. Each of them must occur at least once in the abbreviated term. The
other elements of the string (such as /\
) are the symbols, which must appear
literally when the notation is used.
Identifiers enclosed in single quotes are treated as symbols and thus lose their role as parameters. For example:
.. coqtop:: in Notation "'IF' c1 'then' c2 'else' c3" := (c1 /\ c2 \/ ~ c1 /\ c3) (at level 200, right associativity).
Symbols that start with a single quote followed by at least 2 characters must be single quoted. For example, the symbol 'ab is represented by ''ab' in the notation string. Quoted strings can be used in notations: they must begin and end with two double quotes. Embedded spaces in these strings are part of the string and do not contribute to the separation between notation tokens. To embed double quotes in these strings, use four double quotes (e.g. the notation :g:`"A ""I'm an """"infix"""" string symbol"" B"` defines an infix notation whose infix symbol is the string :g:`"I'm an ""infix"" string symbol"`). Symbols may contain double quotes without being strings themselves (as e.g. in symbol :g:`|"|`) but notations with such symbols can be used only for printing (see :ref:`Use of notations for printing <UseOfNotationsForPrinting>`). In this case, no spaces are allowed in the symbol. Also, if the symbol starts with a double quote, it must be surrounded with single quotes to prevent confusion with the beginning of a string symbol.
A notation binds a syntactic expression to a term. Unless the parser and pretty-printer of Coq already know how to deal with the syntactic expression (such as through :cmd:`Reserved Notation` or for notations that contain only literals), explicit precedences and associativity rules have to be given.
Note
The right-hand side of a notation is interpreted at the time the notation is given. In particular, disambiguation of constants, :ref:`implicit arguments <ImplicitArguments>` and other notations are resolved at the time of the declaration of the notation. The right-hand side is currently typed only at use time but this may change in the future.
.. exn:: Unterminated string in notation Occurs when the notation string contains an unterminated quoted string, as e.g. in :g:`Reserved Notation "A ""an unended string B"`, for which the user may instead mean :g:`Reserved Notation "A ""an ended string"" B`.
.. exn:: End of quoted string not followed by a space in notation. Occurs when the notation string contains a quoted string which contains a double quote not ending the quoted string, as e.g. in :g:`Reserved Notation "A ""string""! B"` or `Reserved Notation "A ""string""!"" B"`, for which the user may instead mean :g:`Reserved Notation "A ""string"""" ! B`, :g:`Reserved Notation "A ""string""""!"" B`, or :g:`Reserved Notation "A '""string""!' B`.
Mixing different symbolic notations in the same text may cause serious parsing ambiguity. To deal with the ambiguity of notations, Coq uses precedence levels ranging from 0 to 100 (plus one extra level numbered 200) and associativity rules.
Consider for example the new notation
.. coqtop:: in Notation "A \/ B" := (or A B).
Clearly, an expression such as :g:`forall A:Prop, True /\ A \/ A \/ False`
is ambiguous. To tell the Coq parser how to interpret the
expression, a priority between the symbols /\
and \/
has to be
given. Assume for instance that we want conjunction to bind more than
disjunction. This is expressed by assigning a precedence level to each
notation, knowing that a lower level binds more than a higher level.
Hence the level for disjunction must be higher than the level for
conjunction.
Since connectives are not tight articulation points of a text, it is reasonable to choose levels not so far from the highest level which is 100, for example 85 for disjunction and 80 for conjunction [1].
Similarly, an associativity is needed to decide whether :g:`True /\ False /\ False` defaults to :g:`True /\ (False /\ False)` (right associativity) or to :g:`(True /\ False) /\ False` (left associativity). We may even consider that the expression is not well-formed and that parentheses are mandatory (this is a “no associativity”) [2]. We do not know of a special convention for the associativity of disjunction and conjunction, so let us apply right associativity (which is the choice of Coq).
Precedence levels and associativity rules of notations are specified with a list of parenthesized :n:`@syntax_modifier`s. Here is how the previous examples refine:
.. coqtop:: in Notation "A /\ B" := (and A B) (at level 80, right associativity). Notation "A \/ B" := (or A B) (at level 85, right associativity).
By default, a notation is considered nonassociative, but the
precedence level is mandatory (except for special cases whose level is
canonical). The level is either a number or the phrase next level
whose meaning is obvious.
Some :ref:`associativities are predefined <init-notations>` in the
Notations
module.
Notations can be made from arbitrarily complex symbols. One can for instance define prefix notations.
.. coqtop:: in Notation "~ x" := (not x) (at level 75, right associativity).
One can also define notations for incomplete terms, with the hole expected to be inferred during type checking.
.. coqtop:: in Notation "x = y" := (@eq _ x y) (at level 70, no associativity).
One can define closed notations whose both sides are symbols. In this case, the default precedence level for the inner sub-expression is 200, and the default level for the notation itself is 0.
.. coqtop:: in Notation "( x , y )" := (@pair _ _ x y).
One can also define notations for binders.
.. coqtop:: in Notation "{ x : A | P }" := (sig A (fun x => P)).
In the last case though, there is a conflict with the notation for
type casts. The notation for type casts, as shown by the command :cmd:`Print
Grammar` constr is at level 100. To avoid x : A
being parsed as a type cast,
it is necessary to put x
at a level below 100, typically 99. Hence, a correct
definition is the following:
.. coqtop:: reset all Notation "{ x : A | P }" := (sig A (fun x => P)) (x at level 99).
More generally, it is required that notations are explicitly factorized on the left. See the next section for more about factorization.
Coq extensible parsing is performed by Camlp5 which is essentially a LL1 parser: it decides which notation to parse by looking at tokens from left to right. Hence, some care has to be taken not to hide already existing rules by new rules. Some simple left factorization work has to be done. Here is an example.
.. coqtop:: all Notation "x < y" := (lt x y) (at level 70). Fail Notation "x < y < z" := (x < y /\ y < z) (at level 70).
In order to factorize the left part of the rules, the subexpression
referred to by y
has to be at the same level in both rules. However the
default behavior puts y
at the next level below 70 in the first rule
(no associativity
is the default), and at level 200 in the second
rule (level 200
is the default for inner expressions). To fix this, we
need to force the parsing level of y
, as follows.
.. coqtop:: in Notation "x < y" := (lt x y) (at level 70). Notation "x < y < z" := (x < y /\ y < z) (at level 70, y at next level).
For the sake of factorization with Coq predefined rules, simple rules
have to be observed for notations starting with a symbol, e.g., rules
starting with “{
” or “(
” should be put at level 0. The list
of Coq predefined notations can be found in the chapter on :ref:`thecoqlibrary`.
The command :cmd:`Notation` has an effect both on the Coq parser and on the Coq printer. For example:
.. coqtop:: all Check (and True True).
However, printing, especially pretty-printing, also requires some care. We may want specific indentations, line breaks, alignment if on several lines, etc. For pretty-printing, Coq relies on OCaml formatting library, which provides indentation and automatic line breaks depending on page width by means of formatting boxes.
The default printing of notations is rudimentary. For printing a notation, a formatting box is opened in such a way that if the notation and its arguments cannot fit on a single line, a line break is inserted before the symbols of the notation and the arguments on the next lines are aligned with the argument on the first line.
A first, simple control that a user can have on the printing of a notation is the insertion of spaces at some places of the notation. This is performed by adding extra spaces between the symbols and parameters: each extra space (other than the single space needed to separate the components) is interpreted as a space to be inserted by the printer. Here is an example showing how to add spaces next to the curly braces.
.. coqtop:: in Notation "{{ x : A | P }}" := (sig (fun x : A => P)) (at level 0, x at level 99).
.. coqtop:: all Check (sig (fun x : nat => x=x)).
The second, more powerful control on printing is by using :n:`@syntax_modifier`s. Here is an example
.. coqtop:: in Definition IF_then_else (P Q R:Prop) := P /\ Q \/ ~ P /\ R.
.. coqtop:: all Notation "'If' c1 'then' c2 'else' c3" := (IF_then_else c1 c2 c3) (at level 200, right associativity, format "'[v ' 'If' c1 '/' '[' 'then' c2 ']' '/' '[' 'else' c3 ']' ']'").
.. coqtop:: all Check (IF_then_else (IF_then_else True False True) (IF_then_else True False True) (IF_then_else True False True)).
A format is an extension of the string denoting the notation with the possible following elements delimited by single quotes:
- tokens of the form
'/ '
are translated into breaking points. If there is a line break, indents the number of spaces appearing after the “/
” (no indentation in the example) - tokens of the form
'//'
force writing on a new line - well-bracketed pairs of tokens of the form
'[ '
and']'
are translated into printing boxes; if there is a line break, an extra indentation of the number of spaces after the “[
” is applied - well-bracketed pairs of tokens of the form
'[hv '
and']'
are translated into horizontal-or-else-vertical printing boxes; if the content of the box does not fit on a single line, then every breaking point forces a new line and an extra indentation of the number of spaces after the “[hv
” is applied at the beginning of each new line - well-bracketed pairs of tokens of the form
'[v '
and']'
are translated into vertical printing boxes; every breaking point forces a new line, even if the line is large enough to display the whole content of the box, and an extra indentation of the number of spaces after the “[v
” is applied at the beginning of each new line (3 spaces in the example) - extra spaces in other tokens are preserved in the output
Notations disappear when a section is closed. No typing of the denoted expression is performed at definition time. Type checking is done only at the time of use of the notation.
Note
The default for a notation is to be used both for parsing and
printing. It is possible to declare a notation only for parsing by
adding the option only parsing
to the list of
:n:`@syntax_modifier`s of :cmd:`Notation`. Symmetrically, the
only printing
:n:`@syntax_modifier` can be used to declare that
a notation should only be used for printing.
If a notation to be used both for parsing and printing is overridden, both the parsing and printing are invalided, even if the overriding rule is only parsing.
If a given notation string occurs only in only printing
rules,
the parser is not modified at all.
To a given notation string and scope can be attached at most one
notation with both parsing and printing or with only
parsing. Contrastingly, an arbitrary number of only printing
notations differing in their right-hand sides but only a unique
right-hand side can be attached to a given string and
scope. Obviously, expressions printed by means of such extra
printing rules will not be reparsed to the same form.
Note
When several notations can be used to print a given term, the notations which capture the largest subterm of the term are used preferentially. Here is an example:
.. coqtop:: in Notation "x < y" := (lt x y) (at level 70). Notation "x < y < z" := (lt x y /\ lt y z) (at level 70, y at next level). Check (0 < 1 /\ 1 < 2).
When several notations match the same subterm, or incomparable subterms of the term to print, the notation declared most recently is selected. Moreover, reimporting a library or module declares the notations of this library or module again. If the notation is in a scope (see :ref:`Scopes`), either the scope has to be opened or a delimiter has to exist in the scope for the notation to be usable.
The :cmd:`Infix` command is a shortcut for declaring notations for infix symbols.
.. cmd:: Infix @notation_declaration The command :n:`Infix @string := @one_term {? ( {+, @syntax_modifier } ) } {? : @scope_name }` is equivalent to :n:`Notation "x @string y" := (@one_term x y) {? ( {+, @syntax_modifier } ) } {? : @scope_name }` where ``x`` and ``y`` are fresh names and omitting the quotes around :n:`@string`. Here is an example: .. coqtop:: in Infix "/\" := and (at level 80, right associativity).
.. cmd:: Reserved Notation @string {? ( {+, @syntax_modifier } ) } A given notation may be used in different contexts. Coq expects all uses of the notation to be defined at the same precedence and with the same associativity. To avoid giving the precedence and associativity every time, this command declares a parsing rule (:token:`string`) in advance without giving its interpretation. Here is an example from the initial state of Coq. .. coqtop:: in Reserved Notation "x = y" (at level 70, no associativity). Reserving a notation is also useful for simultaneously defining an inductive type or a recursive constant and a notation for it. .. note:: The notations mentioned in the module :ref:`init-notations` are reserved. Hence their precedence and associativity cannot be changed. .. cmd:: Reserved Infix @string {? ( {+, @syntax_modifier } ) } This command declares an infix parsing rule without giving its interpretation. When a format is attached to a reserved notation (with the `format` :token:`syntax_modifier`), it is used by default by all subsequent interpretations of the corresponding notation. Individual interpretations can override the format.
Thanks to reserved notations, inductive and coinductive type declarations, recursive and corecursive definitions can use customized notations. To do this, insert a :token:`decl_notations` clause after the definition of the (co)inductive type or (co)recursive term (or after the definition of each of them in case of mutual definitions). Note that only syntax modifiers that do not require adding or changing a parsing rule are accepted.
.. prodn:: decl_notations ::= where @notation_declaration {* and @notation_declaration }
Here are examples:
.. coqtop:: in Reserved Notation "A & B" (at level 80).
.. coqtop:: in Inductive and' (A B : Prop) : Prop := conj' : A -> B -> A & B where "A & B" := (and' A B).
.. coqtop:: none Arguments S _ : clear scopes.
.. coqtop:: in Fixpoint plus (n m : nat) {struct n} : nat := match n with | O => m | S p => S (p + m) end where "n + m" := (plus n m).
.. cmd:: {| Enable | Disable } Notation {? {| @string | @qualid {* @ident__parm } } } {? := @one_term } {? ( {+, @enable_notation_flag } ) } {? {| : @scope_name | : no scope } } :name: Enable Notation; Disable Notation .. insertprodn enable_notation_flag enable_notation_flag .. prodn:: enable_notation_flag ::= all | only parsing | only printing | in custom @ident | in constr Enables or disables notations previously defined with :cmd:`Notation` or :cmd:`Notation (abbreviation)`. Disabling a notation doesn't remove parsing rules or tokens defined by the notation. The command has no effect on notations reserved with :cmd:`Reserved Notation`. At least one of :token:`string`, :token:`qualid`, :token:`one_term` or :token:`scope_name` must be provided. When multiple clauses are provided, the notations enabled or disabled must satisfy all of their constraints. This command supports the :attr:`local` and :attr:`global` attributes. :n:`@string` Notations to enable or disable. :n:`@string` can be a single token in the notation such as "`->`" or a pattern that matches the notation. See :ref:`locating-notations`. If no :n:`{? := @one_term }` is given, the variables of the notation can be replaced by :n:`_`. :n:`@qualid {* @ident__parm }` Enable or disable :ref:`abbreviations <Abbreviations>` whose absolute name has :n:`@qualid` as a suffix. The :n:`{* @ident__parm }` are the parameters of the abbreviation. :n:`{? := @one_term }` Enable or disable notations matching :token:`one_term`. :token:`one_term` can be written using notations or not, as well as :n:`_`, just like in the :cmd:`Notation` command. If no :n:`@string` nor :n:`@qualid {* @ident__parm }` is given, the variables of the notation can be replaced by :n:`_`. :n:`all` Enable or disable all notations meeting the given constraints, even if there are multiple ones. Otherwise, there must be a single notation meeting the constraints. :n:`only parsing` The notation is enabled or disabled only for parsing. :n:`only printing` The notation is enabled or disabled only for printing. :n:`in custom @ident` Enable or disable notations in the given :ref:`custom entry <custom-entries>`. :n:`in constr` Enable or disable notations in the custom entry for :n:`constr`. See :ref:`custom entries <custom-entries>`. :n:`{| : @scope_name | : no scope }` If given, only notations in scope :token:`scope_name` are affected (or :term:`lonely notations <lonely notation>` for :n:`no scope`). .. exn:: Unexpected only printing for an only parsing notation. Cannot enable or disable for printing a notation that was originally defined as only parsing. .. exn:: Unexpected only parsing for an only printing notation. Cannot enable or disable for parsing a notation that was originally defined as only printing. .. warn:: Found no matching notation to enable or disable. :name: Found no matching notation to enable or disable No previously defined notation satisfies the given constraints. .. exn:: More than one interpretation bound to this notation, confirm with the "all" modifier. Use :n:`all` to allow enabling or disabling multiple notations in a single command. .. exn:: Unknown custom entry. In :n:`in custom @ident`, :token:`ident` is not a valid custom entry name. .. exn:: No notation provided. At least one of :token:`string`, :token:`qualid`, :token:`one_term` or :token:`scope_name` must be provided. .. warn:: Activation of abbreviations does not expect mentioning a grammar entry. ``in custom`` and ``in constr`` are not compatible with :ref:`abbreviations <Abbreviations>`. .. warn:: Activation of abbreviations does not expect mentioning a scope. Scopes are not compatible with :ref:`abbreviations <Abbreviations>`. .. example:: Enabling and disabling notations .. coqtop:: all Disable Notation "+" (all). Enable Notation "_ + _" (all) : type_scope. Disable Notation "x + y" := (sum x y).
.. flag:: Printing Notations This :term:`flag` controls whether to use notations for printing terms wherever possible. Default is on.
.. flag:: Printing Raw Literals This :term:`flag` controls whether to use string and number notations for printing terms wherever possible (see :ref:`string-notations`). Default is off.
.. flag:: Printing Parentheses When this :term:`flag` is on, parentheses are printed even if implied by associativity and precedence. Default is off.
.. seealso:: :flag:`Printing All` to disable other elements in addition to notations.
.. cmd:: Print Notation @string {? in custom @ident } Displays information about the previously reserved notation string :token:`string`. :token:`ident`, if specified, is the name of the associated custom entry. See :cmd:`Declare Custom Entry`. .. coqtop:: all Reserved Notation "x # y" (at level 123, right associativity). Print Notation "_ # _". Variables can be indicated with either `"_"` or names, as long as these can not be confused with notation symbols. When confusion may arise, for example with notation symbols that are entirely made up of letters, use single quotes to delimit those symbols. Using `"_"` is preferred, as it avoids this confusion. Note that there must always be (at least) a space between notation symbols and arguments, even when the notation format does not include those spaces. .. example:: :cmd:`Print Notation` .. coqtop:: all Reserved Notation "x 'mod' y" (at level 40, no associativity). Print Notation "_ mod _". Print Notation "x 'mod' y". Reserved Notation "/ x /" (at level 0, format "/ x /"). Fail Print Notation "/x/". Print Notation "/ x /". Reserved Notation "( x , y , .. , z )" (at level 0). Print Notation "( _ , _ , .. , _ )". Reserved Notation "x $ y" (at level 50, left associativity). Declare Custom Entry expr. Reserved Notation "x $ y" (in custom expr at level 30, x custom expr, y at level 80, no associativity). Print Notation "_ $ _". Print Notation "_ $ _" in custom expr. .. exn:: @string cannot be interpreted as a known notation. Make sure that symbols are surrounded by spaces and that holes are explicitly denoted by "_". Occurs when :cmd:`Print Notation` can't find a notation associated with :token:`string`. This can happen, for example, when the notation does not exist in the current context, :token:`string` is not specific enough, there are missing spaces between symbols, or some symbols need to be quoted with `"'"`. .. exn:: @string cannot be interpreted as a known notation in @ident entry. Make sure that symbols are surrounded by spaces and that holes are explicitly denoted by "_". :undocumented:
.. seealso:: :cmd:`Locate` for information on the definitions and scopes associated with a notation.
.. cmd:: Print Keywords Prints the current reserved :ref:`keywords <keywords>` and parser tokens, one per line. Keywords cannot be used as identifiers.
.. cmd:: Print Grammar {* @ident } When no :token:`ident` is provided, shows the whole grammar. Otherwise shows the grammar for the nonterminal :token:`ident`\s, except for the following, which will include some related nonterminals: - `constr` - for :token:`term`\s - `tactic` - for currently-defined tactic notations, :token:`tactic`\s and tacticals (corresponding to :token:`ltac_expr` in the documentation). - `vernac` - for :token:`command`\s - `ltac2` - for Ltac2 notations (corresponding to :token:`ltac2_expr`) This command can display any nonterminal in the grammar reachable from `vernac_control`. Most of the grammar in the documentation was updated in 8.12 to make it accurate and readable. This was done using a new developer tool that extracts the grammar from the source code, edits it and inserts it into the documentation files. While the edited grammar is equivalent to the original, for readability some nonterminals have been renamed and others have been eliminated by substituting the nonterminal definition where the nonterminal was referenced. This command shows the original grammar, so it won't exactly match the documentation. The Coq parser is based on Camlp5. The documentation for `Extensible grammars <http://camlp5.github.io/doc/htmlc/grammars.html>`_ is the most relevant but it assumes considerable knowledge. Here are the essentials: Productions can contain the following elements: - nonterminal names - identifiers in the form `[a-zA-Z0-9_]*` - `"…"` - a literal string that becomes a keyword and cannot be used as an :token:`ident`. The string doesn't have to be a valid identifier; frequently the string will contain only punctuation characters. - `IDENT "…"` - a literal string that has the form of an :token:`ident` - `OPT element` - optionally include `element` (e.g. a nonterminal, IDENT "…" or "…") - `LIST1 element` - a list of one or more `element`\s - `LIST0 element` - an optional list of `element`\s - `LIST1 element SEP sep` - a list of `element`\s separated by `sep` - `LIST0 element SEP sep` - an optional list of `element`\s separated by `sep` - `[ elements1 | elements2 | … ]` - alternatives (either `elements1` or `elements2` or …) Nonterminals can have multiple **levels** to specify precedence and associativity of its productions. This feature of grammars makes it simple to parse input such as `1+2*3` in the usual way as `1+(2*3)`. However, most nonterminals have a single level. For example, this output from `Print Grammar tactic` shows the first 3 levels for `ltac_expr`, designated as "5", "4" and "3". Level 3 is right-associative, which applies to the productions within it, such as the `try` construct:: Entry ltac_expr is [ "5" RIGHTA [ ] | "4" LEFTA [ SELF; ";"; SELF | SELF; ";"; tactic_then_locality; for_each_goal; "]" ] | "3" RIGHTA [ IDENT "try"; SELF : The interpretation of `SELF` depends on its position in the production and the associativity of the level: - At the beginning of a production, `SELF` means the next level. In the fragment shown above, the next level for `try` is "2". (This is defined by the order of appearance in the grammar or output; the levels could just as well be named "foo" and "bar".) - In the middle of a production, `SELF` means the top level ("5" in the fragment) - At the end of a production, `SELF` means the next level within `LEFTA` levels and the current level within `RIGHTA` levels. `NEXT` always means the next level. `nonterminal LEVEL "…"` is a reference to the specified level for `nonterminal`. `Associativity <http://camlp5.github.io/doc/htmlc/grammars.html#b:Associativity>`_ explains `SELF` and `NEXT` in somewhat more detail. The output for `Print Grammar constr` includes :cmd:`Notation` definitions, which are dynamically added to the grammar at run time. For example, in the definition for `term`, the production on the second line shown here is defined by a :cmd:`Reserved Notation` command in `Notations.v`:: | "50" LEFTA [ SELF; "||"; NEXT Similarly, `Print Grammar tactic` includes :cmd:`Tactic Notation`\s, such as :tacn:`dintuition`. The file `doc/tools/docgram/fullGrammar <http://github.com/coq/coq/blob/master/doc/tools/docgram/fullGrammar>`_ in the source tree extracts the full grammar for Coq (not including notations and tactic notations defined in `*.v` files nor some optionally-loaded plugins) in a single file with minor changes to handle nonterminals using multiple levels (described in `doc/tools/docgram/README.md <http://github.com/coq/coq/blob/master/doc/tools/docgram/README.md>`_). This is complete and much easier to read than the grammar source files. `doc/tools/docgram/orderedGrammar <http://github.com/coq/coq/blob/master/doc/tools/docgram/orderedGrammar>`_ has the edited grammar that's used in the documentation. Developer documentation for parsing is in `dev/doc/parsing.md <http://github.com/coq/coq/blob/master/dev/doc/parsing.md>`_.
To know to which notations a given symbol belongs to, use the :cmd:`Locate`
command. You can call it on any (composite) symbol surrounded by double quotes.
To locate a particular notation, use a string where the variables of the
notation are replaced by “_
” and where possible single quotes inserted around
identifiers or tokens starting with a single quote are dropped.
.. coqtop:: all Locate "exists". Locate "exists _ .. _ , _".
If the right-hand side of a notation is a partially applied constant, the notation inherits the implicit arguments (see :ref:`ImplicitArguments`) and notation scopes (see :ref:`Scopes`) of the constant. For instance:
.. coqtop:: in reset Record R := {dom : Type; op : forall {A}, A -> dom}. Notation "# x" := (@op x) (at level 8).
.. coqtop:: all Check fun x:R => # x 3.
As an exception, if the right-hand side is just of the form :n:`@@qualid`, this conventionally stops the inheritance of implicit arguments (but not of notation scopes).
Notations can include binders. This section lists different ways to deal with binders. For further examples, see also :ref:`RecursiveNotationsWithBinders`.
Here is the basic example of a notation using a binder:
.. coqtop:: in Notation "'sigma' x : A , B" := (sigT (fun x : A => B)) (at level 200, x name, A at level 200, right associativity).
The binding variables in the right-hand side that occur as a parameter of the notation (here :g:`x`) dynamically bind all the occurrences in their respective binding scope after instantiation of the parameters of the notation. This means that the term bound to :g:`B` can refer to the variable name bound to :g:`x` as shown in the following application of the notation:
.. coqtop:: all Check sigma z : nat, z = 0.
Note the :n:`@syntax_modifier x name` in the declaration of the notation. It tells to parse :g:`x` as a single identifier (or as the unnamed variable :g:`_`).
In the same way as patterns can be used as binders, as in :g:`fun '(x,y) => x+y` or :g:`fun '(existT _ x _) => x`, notations can be defined so that any :n:`@pattern` can be used in place of the binder. Here is an example:
.. coqtop:: in reset Notation "'subset' ' p , P " := (sig (fun p => P)) (at level 200, p pattern, format "'subset' ' p , P").
.. coqtop:: all Check subset '(x,y), x+y=0.
The :n:`@syntax_modifier p pattern` in the declaration of the notation tells to parse :g:`p` as a pattern. Note that a single variable is both an identifier and a pattern, so, e.g., the following also works:
.. coqtop:: all Check subset 'x, x=0.
If one wants to prevent such a notation to be used for printing when the
pattern is reduced to a single identifier, one has to use instead
the :n:`@syntax_modifier p strict pattern`. For parsing, however, a
strict pattern
will continue to include the case of a
variable. Here is an example showing the difference:
.. coqtop:: in Notation "'subset_bis' ' p , P" := (sig (fun p => P)) (at level 200, p strict pattern). Notation "'subset_bis' p , P " := (sig (fun p => P)) (at level 200, p name).
.. coqtop:: all Check subset_bis 'x, x=0.
The default level for a pattern
is 0. One can use a different level by
using pattern at level
n where the scale is the same as the one for
terms (see :ref:`init-notations`).
Sometimes, for the sake of factorization of rules, a binder has to be parsed as a term. This is typically the case for a notation such as the following:
.. coqdoc:: Notation "{ x : A | P }" := (sig (fun x : A => P)) (at level 0, x at level 99 as name).
This is so because the grammar also contains rules starting with :g:`{}` and followed by a term, such as the rule for the notation :g:`{ A } + { B }` for the constant :g:`sumbool` (see :ref:`specification`).
Then, in the rule, x name
is replaced by x at level 99 as name
meaning
that x
is parsed as a term at level 99 (as done in the notation for
:g:`sumbool`), but that this term has actually to be a name, i.e. an
identifier or :g:`_`.
The notation :g:`{ x | P }` is already defined in the standard
library with the as name
:n:`@syntax_modifier`. We cannot redefine it but
one can define an alternative notation, say :g:`{ p such that P }`,
using instead as pattern
.
.. coqtop:: in Notation "{ p 'such' 'that' P }" := (sig (fun p => P)) (at level 0, p at level 99 as pattern).
Then, the following works:
.. coqtop:: all Check {(x,y) such that x+y=0}.
To enforce that the pattern should not be used for printing when it
is just a name, one could have said
p at level 99 as strict pattern
.
Note also that in the absence of a as name
, as strict pattern
or
as pattern
:n:`@syntax_modifier`s, the default is to consider sub-expressions occurring
in binding position and parsed as terms to be as name
.
It is also possible to rely on Coq's syntax of binders using the binder modifier as follows:
.. coqtop:: in Notation "'myforall' p , [ P , Q ] " := (forall p, P -> Q) (at level 200, p binder).
In this case, all of :n:`@ident`, :n:`{@ident}`, :n:`[@ident]`, :n:`@ident:@type`, :n:`{@ident:@type}`, :n:`[@ident:@type]`, :n:`'@pattern` can be used in place of the corresponding notation variable. In particular, the binder can declare implicit arguments:
.. coqtop:: all Check fun (f : myforall {a}, [a=0, Prop]) => f eq_refl. Check myforall '((x,y):nat*nat), [ x = y, True ].
By using instead closed binder, the same list of binders is allowed except that :n:`@ident:@type` requires parentheses around.
We can also have binders in the right-hand side of a notation which are not themselves bound in the notation. In this case, the binders are considered up to renaming of the internal binder. E.g., for the notation
.. coqtop:: in Notation "'exists_different' n" := (exists p:nat, p<>n) (at level 200).
the next command fails because p does not bind in the instance of n.
.. coqtop:: all Fail Check (exists_different p).
.. coqtop:: in Notation "[> a , .. , b <]" := (cons a .. (cons b nil) .., cons b .. (cons a nil) ..).
It is possible to use parameters of the notation both in term and binding position. Here is an example:
.. coqtop:: in Definition force n (P:nat -> Prop) := forall n', n' >= n -> P n'. Notation "▢_ n P" := (force n (fun n => P)) (at level 0, n name, P at level 9, format "▢_ n P").
.. coqtop:: all Check exists p, ▢_p (p >= 1).
More generally, the parameter can be a pattern, as in the following variant:
.. coqtop:: in reset Definition force2 q (P:nat*nat -> Prop) := (forall n', n' >= fst q -> forall p', p' >= snd q -> P q). Notation "▢_ p P" := (force2 p (fun p => P)) (at level 0, p pattern at level 0, P at level 9, format "▢_ p P").
.. coqtop:: all Check exists x y, ▢_(x,y) (x >= 1 /\ y >= 2).
This support is experimental. For instance, the notation is used for printing only if the occurrence of the parameter in term position comes in the right-hand side before the occurrence in binding position.
A mechanism is provided for declaring elementary notations with recursive patterns. The basic example is:
.. coqtop:: all Notation "[ x ; .. ; y ]" := (cons x .. (cons y nil) ..).
On the right-hand side, an extra construction of the form .. t ..
can
be used. Notice that ..
is part of the Coq syntax and it must not be
confused with the three-dots notation “…
” used in this manual to denote
a sequence of arbitrary size.
On the left-hand side, the part “x s .. s y
” of the notation parses
any number of times (but at least once) a sequence of expressions
separated by the sequence of tokens s
(in the example, s
is just “;
”).
The right-hand side must contain a subterm of the form either
φ(x, .. φ(y,t) ..)
or φ(y, .. φ(x,t) ..)
where \varphi ([~]_E , [~]_I),
called the iterator of the recursive notation is an arbitrary expression with
distinguished placeholders and where t is called the terminating
expression of the recursive notation. In the example, we choose the names
x and y but in practice they can of course be chosen
arbitrarily. Note that the placeholder [~]_I has to occur only once but
[~]_E can occur several times.
Parsing the notation produces a list of expressions which are used to fill the first placeholder of the iterating pattern which itself is repeatedly nested as many times as the length of the list, the second placeholder being the nesting point. In the innermost occurrence of the nested iterating pattern, the second placeholder is finally filled with the terminating expression.
In the example above, the iterator \varphi ([~]_E , [~]_I) is cons [~]_E\, [~]_I
and the terminating expression is nil
.
Here is another example with the pattern associating on the left:
.. coqtop:: in Notation "( x , y , .. , z )" := (pair .. (pair x y) .. z) (at level 0).
Here is an example with more involved recursive patterns:
.. coqtop:: in Notation "[| t * ( x , y , .. , z ) ; ( a , b , .. , c ) * u |]" := (pair (pair .. (pair (pair t x) (pair t y)) .. (pair t z)) (pair .. (pair (pair a u) (pair b u)) .. (pair c u))) (t at level 39).
To give a flavor of the extent and limits of the mechanism, here is an
example showing a notation for a chain of equalities. It relies on an
artificial expansion of the intended denotation so as to expose a
φ(x, .. φ(y,t) ..)
structure, with the drawback that if ever the
beta-redexes are contracted, the notations stops to be used for
printing. Support for notations defined in this way should be considered
experimental.
.. coqtop:: in Notation "x ⪯ y ⪯ .. ⪯ z ⪯ t" := ((fun b A a => a <= b /\ A b) y .. ((fun b A a => a <= b /\ A b) z (fun b => b <= t)) .. x) (at level 70, y at next level, z at next level, t at next level).
Note finally that notations with recursive patterns can be reserved like standard notations, they can also be declared within :ref:`notation scopes <Scopes>`.
Recursive notations can also be used with binders. The basic example is:
.. coqtop:: in Notation "'exists' x .. y , p" := (ex (fun x => .. (ex (fun y => p)) ..)) (at level 200, x binder, y binder, right associativity).
The principle is the same as in :ref:`RecursiveNotations`
except that in the iterator
\varphi ([~]_E , [~]_I), the placeholder [~]_E can also occur in
position of the binding variable of a fun
or a forall
.
To specify that the part “x .. y
” of the notation parses a sequence of
binders, x
and y
must be marked as binder
in the list of :n:`@syntax_modifier`s
of the notation. The binders of the parsed sequence are used to fill the
occurrences of the first placeholder of the iterating pattern which is
repeatedly nested as many times as the number of binders generated. If ever the
generalization operator '
(see :ref:`implicit-generalization`) is
used in the binding list, the added binders are taken into account too.
There are two flavors of binder parsing. If x
and y
are marked as binder,
then a sequence such as :g:`a b c : T` will be accepted and interpreted as
the sequence of binders :g:`(a:T) (b:T) (c:T)`. For instance, in the
notation above, the syntax :g:`exists a b : nat, a = b` is valid.
The variables x
and y
can also be marked as closed binder in which
case only well-bracketed binders of the form :g:`(a b c:T)` or :g:`{a b c:T}`
etc. are accepted.
With closed binders, the recursive sequence in the left-hand side can
be of the more general form x s .. s y
where s
is an arbitrary sequence of
tokens. With open binders though, s
has to be empty. Here is an
example of recursive notation with closed binders:
.. coqtop:: in Notation "'mylet' f x .. y := t 'in' u":= (let f := fun x => .. (fun y => t) .. in u) (at level 200, x closed binder, y closed binder, right associativity).
A recursive pattern for binders can be used in position of a recursive pattern for terms. Here is an example:
.. coqtop:: in Notation "'FUNAPP' x .. y , f" := (fun x => .. (fun y => (.. (f x) ..) y ) ..) (at level 200, x binder, y binder, right associativity).
If an occurrence of the [~]_E is not in position of a binding variable but of a term, it is the name used in the binding which is used. Here is an example:
.. coqtop:: in Notation "'exists_non_null' x .. y , P" := (ex (fun x => x <> 0 /\ .. (ex (fun y => y <> 0 /\ P)) ..)) (at level 200, x binder).
By default, sub-expressions are parsed as terms and the corresponding
grammar entry is called constr
. However, one may sometimes want
to restrict the syntax of terms in a notation. For instance, the
following notation will accept to parse only global reference in
position of :g:`x`:
.. coqtop:: in Notation "'apply' f a1 .. an" := (.. (f a1) .. an) (at level 10, f global, a1, an at level 9).
In addition to global
, one can restrict the syntax of a
sub-expression by using the entry names ident
, name
or pattern
already seen in :ref:`NotationsWithBinders`, even when the
corresponding expression is not used as a binder in the right-hand
side. E.g.:
.. coqtop:: in Notation "'apply_id' f a1 .. an" := (.. (f a1) .. an) (at level 10, f ident, a1, an at level 9).
.. cmd:: Declare Custom Entry @ident Defines new grammar entries, called *custom entries*, that can later be referred to using the entry name :n:`custom @ident`. This command supports the :attr:`local` attribute, which limits the entry to the current module. Non-local custom entries survive module closing and are declared when a file is Required.
.. example:: For instance, we may want to define an ad hoc parser for arithmetical operations and proceed as follows: .. coqtop:: all Inductive Expr := | One : Expr | Mul : Expr -> Expr -> Expr | Add : Expr -> Expr -> Expr. Declare Custom Entry expr. Notation "[ e ]" := e (e custom expr at level 2). Notation "1" := One (in custom expr at level 0). Notation "x y" := (Mul x y) (in custom expr at level 1, left associativity). Notation "x + y" := (Add x y) (in custom expr at level 2, left associativity). Notation "( x )" := x (in custom expr, x at level 2). Notation "{ x }" := x (in custom expr, x constr). Notation "x" := x (in custom expr at level 0, x ident). Axiom f : nat -> Expr. Check fun x y z => [1 + y z + {f x}]. Unset Printing Notations. Check fun x y z => [1 + y z + {f x}]. Set Printing Notations. Check fun e => match e with | [1 + 1] => [1] | [x y + z] => [x + y z] | y => [y + e] end.
Custom entries have levels, like the main grammar of terms and grammar of patterns have. The lower level is 0 and this is the level used by default to put rules delimited with tokens on both ends. The level is left to be inferred by Coq when using :n:`in custom @ident`. The level is otherwise given explicitly by using the syntax :n:`in custom @ident at level @natural`, where :n:`@natural` refers to the level.
Levels are cumulative: a notation at level n
of which the left end
is a term shall use rules at level less than n
to parse this
subterm. More precisely, it shall use rules at level strictly less
than n
if the rule is declared with right associativity
and
rules at level less or equal than n
if the rule is declared with
left associativity
. Similarly, a notation at level n
of which
the right end is a term shall use by default rules at level strictly
less than n
to parse this subterm if the rule is declared left
associative and rules at level less or equal than n
if the rule is
declared right associative. This is what happens for instance in the
rule
.. coqtop:: in Notation "x + y" := (Add x y) (in custom expr at level 2, left associativity).
where x
is any expression parsed in entry
expr
at level less or equal than 2
(including, recursively,
the given rule) and y
is any expression parsed in entry expr
at level strictly less than 2
.
Rules associated with an entry can refer different sub-entries. The
grammar entry name constr
can be used to refer to the main grammar
of term as in the rule
.. coqtop:: in Notation "{ x }" := x (in custom expr at level 0, x constr).
which indicates that the subterm x
should be
parsed using the main grammar. If not indicated, the level is computed
as for notations in constr
, e.g. using 200 as default level for
inner sub-expressions. The level can otherwise be indicated explicitly
by using constr at level n
for some n
, or constr at next
level
.
Conversely, custom entries can be used to parse sub-expressions of the main grammar, or from another custom entry as is the case in
.. coqtop:: in Notation "[ e ]" := e (e custom expr at level 2).
to indicate that e
has to be parsed at level 2
of the grammar
associated with the custom entry expr
. The level can be omitted, as in
.. coqdoc:: Notation "[ e ]" := e (e custom expr).
in which case Coq infer it. If the sub-expression is at a border of
the notation (as e.g. x
and y
in x + y
), the level is
determined by the associativity. If the sub-expression is not at the
border of the notation (as e.g. e
in "[ e ]
), the level is
inferred to be the highest level used for the entry. In particular,
this level depends on the highest level existing in the entry at the
time of use of the notation.
In the absence of an explicit entry for parsing or printing a
sub-expression of a notation in a custom entry, the default is to
consider that this sub-expression is parsed or printed in the same
custom entry where the notation is defined. In particular, if x at
level n
is used for a sub-expression of a notation defined in custom
entry foo
, it shall be understood the same as x custom foo at
level n
.
In general, rules are required to be productive on the right-hand side, i.e. that they are bound to an expression which is not reduced to a single variable. If the rule is not productive on the right-hand side, as it is the case above for
.. coqtop:: in Notation "( x )" := x (in custom expr at level 0, x at level 2).
and
.. coqtop:: in Notation "{ x }" := x (in custom expr at level 0, x constr).
it is used as a grammar coercion which means that it is used to parse or print an expression which is not available in the current grammar at the current level of parsing or printing for this grammar but which is available in another grammar or in another level of the current grammar. For instance,
.. coqtop:: in Notation "( x )" := x (in custom expr at level 0, x at level 2).
tells that parentheses can be inserted to parse or print an expression
declared at level 2
of expr
whenever this expression is
expected to be used as a subterm at level 0 or 1. This allows for
instance to parse and print :g:`Add x y` as a subterm of :g:`Mul (Add
x y) z` using the syntax (x + y) z
. Similarly,
.. coqtop:: in Notation "{ x }" := x (in custom expr at level 0, x constr).
gives a way to let any arbitrary expression which is not handled by the
custom entry expr
be parsed or printed by the main grammar of term
up to the insertion of a pair of curly brackets.
Another special situation is when parsing global references or identifiers. To indicate that a custom entry should parse identifiers, use the following form:
.. coqtop:: reset none Declare Custom Entry expr.
.. coqtop:: in Notation "x" := x (in custom expr at level 0, x ident).
Similarly, to indicate that a custom entry should parse global references (i.e. qualified or unqualified identifiers), use the following form:
.. coqtop:: reset none Declare Custom Entry expr.
.. coqtop:: in Notation "x" := x (in custom expr at level 0, x global).
.. cmd:: Print Custom Grammar @ident This displays the state of the grammar for terms associated with the custom entry :token:`ident`.
Here are the syntax elements used by the various notation commands.
.. prodn:: syntax_modifier ::= at level @natural | in custom @ident {? at level @natural } | {+, @ident } {| at @level | in scope @ident } | @ident at @level {? @binder_interp } | @ident @explicit_subentry | @ident @binder_interp | left associativity | right associativity | no associativity | only parsing | format @string | only printing explicit_subentry ::= ident | name | global | bigint | strict pattern {? at level @natural } | binder | closed binder | constr {? at @level } {? @binder_interp } | custom @ident {? at @level } {? @binder_interp } | pattern {? at level @natural } binder_interp ::= as ident | as name | as pattern | as strict pattern level ::= level @natural | next level
Note that _ by itself is a valid :n:`@name` but is not a valid :n:`@ident`.
Note
No typing of the denoted expression is performed at definition time. Type checking is done only at the time of use of the notation.
Note
Some examples of Notation may be found in the files composing the initial state of Coq (see directory :file:`$COQLIB/theories/Init`).
Note
The notation "{ x }"
has a special status in the main grammars of
terms and patterns so that
complex notations of the form "x + { y }"
or "x * { y }"
can be
nested with correct precedences. Especially, every notation involving
a pattern of the form "{ x }"
is parsed as a notation where the
pattern "{ x }"
has been simply replaced by "x"
and the curly
braces are parsed separately. E.g. "y + { z }"
is not parsed as a
term of the given form but as a term of the form "y + z"
where z
has been parsed using the rule parsing "{ x }"
. Especially, level
and precedences for a rule including patterns of the form "{ x }"
are relative not to the textual notation but to the notation where the
curly braces have been removed (e.g. the level and the associativity
given to some notation, say "{ y } & { z }"
in fact applies to the
underlying "{ x }"
-free rule which is "y & z"
).
Note
Notations such as "( p | q )"
(or starting with "( x | "
,
more generally) are deprecated as they conflict with the syntax for
nested disjunctive patterns (see :ref:`extendedpatternmatching`),
and are not honored in pattern expressions.
.. warn:: Use of @string Notation is deprecated as it is inconsistent with pattern syntax. This warning is disabled by default to avoid spurious diagnostics due to legacy notation in the Coq standard library. It can be turned on with the ``-w disj-pattern-notation`` flag.
.. exn:: Unknown custom entry: @ident. Occurs when :cmd:`Notation` or :cmd:`Print Notation` can't find the custom entry given by the user.
A :gdef:`notation scope` is a set of notations for terms with their
interpretations. Notation scopes provide a weak, purely
syntactic form of notation overloading: a symbol may
refer to different definitions depending on which notation scopes
are currently open. For instance, the infix symbol +
can be
used to refer to distinct definitions of the addition operator,
such as for natural numbers, integers or reals.
Notation scopes can include an interpretation for numbers and
strings with the :cmd:`Number Notation` and :cmd:`String Notation` commands.
.. prodn:: scope ::= @scope_name | @scope_key scope_name ::= @ident scope_key ::= @ident
Each notation scope has a single :token:`scope_name`, which by convention ends with the suffix "_scope", as in "nat_scope". One or more :token:`scope_key`s (delimiting keys) may be associated with a notation scope with the :cmd:`Delimit Scope` command. Most commands use :token:`scope_name`; :token:`scope_key`s are used within :token:`term`s.
.. cmd:: Declare Scope @scope_name Declares a new notation scope. Note that the initial state of Coq declares the following notation scopes: ``core_scope``, ``type_scope``, ``function_scope``, ``nat_scope``, ``bool_scope``, ``list_scope``, ``dec_int_scope``, ``dec_uint_scope``. Use commands such as :cmd:`Notation` to add notations to the scope.
.. exn:: Scope names should not start with an underscore. Scope names starting with an underscore would make the :g:`%_` syntax ambiguous.
At any time, the interpretation of a notation for a term is done within a stack of notation scopes and :term:`lonely notations <lonely notation>`. If a notation is defined in multiple scopes, Coq uses the interpretation from the most recently opened notation scope or declared lonely notation.
Note that "stack" is a misleading name. Each scope or lonely notation can only appear in the stack once. New items are pushed onto the top of the stack, except that adding a item that's already in the stack moves it to the top of the stack instead. Scopes are removed by name (e.g. by :cmd:`Close Scope`) wherever they are in the stack, rather than through "pop" operations.
Use the :cmd:`Print Visibility` command to display the current notation scope stack.
.. cmd:: Open Scope @scope Adds a scope to the notation scope stack. If the scope is already present, the command moves it to the top of the stack. If the command appears in a section: By default, the scope is only added within the section. Specifying :attr:`global` marks the scope for export as part of the current module. Specifying :attr:`local` behaves like the default. If the command does not appear in a section: By default, the scope marks the scope for export as part of the current module. Specifying :attr:`local` prevents exporting the scope. Specifying :attr:`global` behaves like the default.
.. cmd:: Close Scope @scope Removes a scope from the notation scope stack. If the command appears in a section: By default, the scope is only removed within the section. Specifying :attr:`global` marks the scope removal for export as part of the current module. Specifying :attr:`local` behaves like the default. If the command does not appear in a section: By default, the scope marks the scope removal for export as part of the current module. Specifying :attr:`local` prevents exporting the removal. Specifying :attr:`global` behaves like the default. .. todo: Strange notion, exporting something that _removes_ a scope. See https://github.com/coq/coq/pull/11718#discussion_r413667817
In addition to the global rules of interpretation of notations, some ways to change the interpretation of subterms are available.
.. prodn:: term_scope ::= @term0 % @scope_key | @term0 %_ @scope_key
The notation scope stack can be locally extended within a :token:`term` with the syntax :n:`(@term)%@scope_key` (or simply :n:`@term0%@scope_key` for atomic terms).
In this case, :n:`@term` is interpreted in the scope stack extended with the scope bound to :n:`@scope_key`.
The term :n:`@term0%_@scope_key` is interpreted similarly to :n:`@term0%@scope_key` except that the scope stack is only temporarily extended for the head of :n:`@term0`, rather than all its subterms.
.. cmd:: Delimit Scope @scope_name with @scope_key Binds the delimiting key :token:`scope_key` to a scope.
.. cmd:: Undelimit Scope @scope_name Removes the delimiting keys associated with a scope.
.. exn:: Scope delimiters should not start with an underscore. Scope delimiters starting with an underscore would make the :g:`%_` syntax ambiguous.
The arguments of an :ref:`abbreviation <Abbreviations>` can be interpreted in a scope stack locally extended with a given scope by using the modifier :n:`{+, @ident } in scope @scope_name`.s
.. cmd:: Bind Scope @scope_name with {+ @coercion_class } Binds the notation scope :token:`scope_name` to the type or coercion class :token:`coercion_class`. When bound, arguments of that type for any function will be interpreted in that scope by default. This default can be overridden for individual functions with the :cmd:`Arguments` command. See :ref:`binding_to_scope` for details. The association may be convenient when a notation scope is naturally associated with a :token:`type` (e.g. `nat` and the natural numbers). Whether the argument of a function has some type ``type`` is determined statically. For instance, if ``f`` is a polymorphic function of type :g:`forall X:Type, X -> X` and type :g:`t` is bound to a scope ``scope``, then :g:`a` of type :g:`t` in :g:`f t a` is not recognized as an argument to be interpreted in scope ``scope``. In explicit :ref:`casts <type-cast>` :n:`@term : @coercion_class`, the :n:`term` is interpreted in the :token:`scope_name` associated with :n:`@coercion_class`. This command supports the :attr:`local`, :attr:`global`, :attr:`add_top` and :attr:`add_bottom` attributes. .. attr:: add_top add_bottom These :ref:`attributes <attribute>` allow adding additional bindings at the top or bottom of the stack of already declared bindings. In absence of such attributes, any new binding clears the previous ones. This makes it possible to bind multiple scopes to the same :token:`coercion_class`. .. example:: Binding scopes to a type Let's declare two scopes with a notation in each and an arbitrary function on type ``bool``. .. coqtop:: in reset Declare Scope T_scope. Declare Scope F_scope. Notation "#" := true (only parsing) : T_scope. Notation "#" := false (only parsing) : F_scope. Parameter f : bool -> bool. By default, the argument of ``f`` is interpreted in the currently opened scopes. .. coqtop:: all Open Scope T_scope. Check f #. Open Scope F_scope. Check f #. This can be changed by binding scopes to the type ``bool``. .. coqtop:: all Bind Scope T_scope with bool. Check f #. When multiple scopes are attached to a type, notations are interpreted in the first scope containing them, from the top of the stack. .. coqtop:: all #[add_top] Bind Scope F_scope with bool. Check f #. Notation "##" := (negb false) (only parsing) : T_scope. Check f ##. Bindings for functions can be displayed with the :cmd:`About` command. .. coqtop:: all About f. Bindings are also used in casts. .. coqtop:: all Close Scope F_scope. Check #. Check # : bool. .. note:: Such stacks of scopes can be handy to share notations between multiple types. For instance, the scope ``T_scope`` above could contain many generic notations used for both the ``bool`` and ``nat`` types, while the scope ``F_scope`` could override some of these notations specifically for ``bool`` and another ``F'_scope`` could override them specifically for ``nat``, which could then be bound to ``%F'_scope%T_scope``. .. note:: When active, a bound scope has effect on all defined functions (even if they are defined after the :cmd:`Bind Scope` directive), except if argument scopes were assigned explicitly using the :cmd:`Arguments` command. .. note:: The scopes ``type_scope`` and ``function_scope`` also have a local effect on interpretation. See the next section.
.. index:: type_scope
The scope type_scope
has a special status. It is a primitive interpretation
scope which is temporarily activated each time a subterm of an expression is
expected to be a type. It is delimited by the key type
, and bound to the
coercion class Sortclass
. It is also used in certain situations where an
expression is statically known to be a type, including the conclusion and the
type of hypotheses within an Ltac goal match (see
:ref:`ltac-match-goal`), the statement of a theorem, the type of a definition,
the type of a binder, the domain and codomain of implication, the codomain of
products, and more generally any type argument of a declared or defined
constant.
.. index:: function_scope
The scope function_scope
also has a special status.
It is temporarily activated each time the argument of a global reference is
recognized to be a Funclass
instance, i.e., of type :g:`forall x:A, B` or
:g:`A -> B`.
We give an overview of the scopes used in the standard library of Coq. For a complete list of notations in each scope, use the commands :cmd:`Print Scopes` or :cmd:`Print Scope`.
type_scope
- This scope includes infix * for product types and infix + for sum types. It
is delimited by the key
type
, and bound to the coercion classSortclass
, as described above. function_scope
- This scope is delimited by the key
function
, and bound to the coercion classFunclass
, as described above. nat_scope
- This scope includes the standard arithmetical operators and relations on type
nat. Positive integer numbers in this scope are mapped to their canonical
representent built from :g:`O` and :g:`S`. The scope is delimited by the key
nat
, and bound to the type :g:`nat` (see above). N_scope
- This scope includes the standard arithmetical operators and relations on
type :g:`N` (binary natural numbers). It is delimited by the key
N
and comes with an interpretation for numbers as closed terms of type :g:`N`. Z_scope
- This scope includes the standard arithmetical operators and relations on
type :g:`Z` (binary integer numbers). It is delimited by the key
Z
and comes with an interpretation for numbers as closed terms of type :g:`Z`. positive_scope
- This scope includes the standard arithmetical operators and relations on
type :g:`positive` (binary strictly positive numbers). It is delimited by
key
positive
and comes with an interpretation for numbers as closed terms of type :g:`positive`. Q_scope
- This scope includes the standard arithmetical operators and relations on type :g:`Q` (rational numbers defined as fractions of an integer and a strictly positive integer modulo the equality of the numerator- denominator cross-product) and comes with an interpretation for numbers as closed terms of type :g:`Q`.
Qc_scope
- This scope includes the standard arithmetical operators and relations on the type :g:`Qc` of rational numbers defined as the type of irreducible fractions of an integer and a strictly positive integer.
R_scope
- This scope includes the standard arithmetical operators and relations on
type :g:`R` (axiomatic real numbers). It is delimited by the key
R
and comes with an interpretation for numbers using the :g:`IZR` morphism from binary integer numbers to :g:`R` and :g:`Z.pow_pos` for potential exponent parts. bool_scope
- This scope includes notations for the boolean operators. It is delimited by the
key
bool
, and bound to the type :g:`bool` (see above). list_scope
- This scope includes notations for the list operators. It is delimited by the key
list
, and bound to the type :g:`list` (see above). core_scope
- This scope includes the notation for pairs. It is delimited by the key
core
. string_scope
- This scope includes notation for strings as elements of the type string. Special characters and escaping follow Coq conventions on strings (see :ref:`lexical-conventions`). Especially, there is no convention to visualize non printable characters of a string. The file :file:`String.v` shows an example that contains quotes, a newline and a beep (i.e. the ASCII character of code 7).
char_scope
- This scope includes interpretation for all strings of the form
"c"
where :g:`c` is an ASCII character, or of the form"nnn"
where nnn is a three-digit number (possibly with leading 0s), or of the form""""
. Their respective denotations are the ASCII code of :g:`c`, the decimal ASCII codennn
, or the ascii code of the character"
(i.e. the ASCII code 34), all of them being represented in the type :g:`ascii`.
.. cmd:: Print Visibility {? @scope_name } Displays the current notation scope stack. The top of the stack is displayed last. Notations in scopes whose interpretation is hidden by the same notation in a more recently opened scope are not displayed. Hence each notation is displayed only once. If :n:`@scope_name` is specified, displays the current notation scope stack as if the scope :n:`@scope_name` is pushed on top of the stack. This is useful to see how a subterm occurring locally in the scope is interpreted.
.. cmd:: Print Scopes Displays, for each existing notation scope, all accessible notations (whether or not currently in the notation scope stack), the most-recently defined delimiting key and the class the notation scope is bound to. The display also includes :term:`lonely notations <lonely notation>`. .. todo should the command report all delimiting keys? Use the :cmd:`Print Visibility` command to display the current notation scope stack.
.. cmd:: Print Scope @scope_name Displays all notations defined in the notation scope :n:`@scope_name`. It also displays the delimiting key and the class to which the scope is bound, if any.
.. cmd:: Notation @ident {* @ident__parm } := @one_term {? ( {+, @syntax_modifier } ) } :name: Notation (abbreviation) .. todo: for some reason, Sphinx doesn't complain about a duplicate name if :name: is omitted Defines an abbreviation :token:`ident` with the parameters :n:`@ident__parm`. This command supports the :attr:`local` attribute, which limits the notation to the current module. An *abbreviation* is a name, possibly applied to arguments, that denotes a (presumably) more complex expression. Here are examples: .. coqtop:: none Require Import List. Require Import Relations. Set Printing Notations. .. coqtop:: in Notation Nlist := (list nat). .. coqtop:: all Check 1 :: 2 :: 3 :: nil. .. coqtop:: in Notation reflexive R := (forall x, R x x). .. coqtop:: all Check forall A:Prop, A <-> A. Check reflexive iff. .. coqtop:: in Notation Plus1 B := (Nat.add B 1). .. coqtop:: all Compute (Plus1 3). An abbreviation expects no precedence nor associativity, since it is parsed as an usual application. Abbreviations are used as much as possible by the Coq printers unless the modifier ``(only parsing)`` is given. An abbreviation is bound to an absolute name as an ordinary definition is and it also can be referred to by a qualified name. Abbreviations are syntactic in the sense that they are bound to expressions which are not typed at the time of the definition of the abbreviation but at the time they are used. Especially, abbreviations can be bound to terms with holes (i.e. with “``_``”). For example: .. coqtop:: none reset Set Strict Implicit. Set Printing Depth 50. .. coqtop:: in Definition explicit_id (A:Set) (a:A) := a. .. coqtop:: in Notation id := (explicit_id _). .. coqtop:: all Check (id 0). Abbreviations disappear when a section is closed. No typing of the denoted expression is performed at definition time. Type checking is done only at the time of use of the abbreviation. Like for notations, if the right-hand side of an abbreviation is a partially applied constant, the abbreviation inherits the implicit arguments and notation scopes of the constant. As an exception, if the right-hand side is just of the form :n:`@@qualid`, this conventionally stops the inheritance of implicit arguments. Like for notations, it is possible to bind binders in abbreviations. Here is an example: .. coqtop:: in reset Definition force2 q (P:nat*nat -> Prop) := (forall n', n' >= fst q -> forall p', p' >= snd q -> P q). Notation F p P := (force2 p (fun p => P)). Check exists x y, F (x,y) (x >= 1 /\ y >= 2).
.. prodn:: number_or_string ::= @number | @string
Numbers and strings have no predefined semantics in the calculus. They are merely notations that can be bound to objects through the notation mechanism. Initially, numbers are bound to :n:`nat`, Peano’s representation of natural numbers (see :ref:`datatypes`).
Note
Negative integers are not at the same level as :n:`@natural`, for this would make precedence unnatural.
.. cmd:: Number Notation @qualid__type @qualid__parse @qualid__print {? ( {+, @number_modifier } ) } : @scope_name .. insertprodn number_modifier number_string_via .. prodn:: number_modifier ::= warning after @bignat | abstract after @bignat | @number_string_via number_string_via ::= via @qualid mapping [ {+, {| @qualid => @qualid | [ @qualid ] => @qualid } } ] Customizes the way number literals are parsed and printed within the current :term:`notation scope`. :n:`@qualid__type` the name of an inductive type, while :n:`@qualid__parse` and :n:`@qualid__print` should be the names of the parsing and printing functions, respectively. The parsing function :n:`@qualid__parse` should have one of the following types: * :n:`Number.int -> @qualid__type` * :n:`Number.int -> option @qualid__type` * :n:`Number.uint -> @qualid__type` * :n:`Number.uint -> option @qualid__type` * :n:`Z -> @qualid__type` * :n:`Z -> option @qualid__type` * :n:`PrimInt63.pos_neg_int63 -> @qualid__type` * :n:`PrimInt63.pos_neg_int63 -> option @qualid__type` * :n:`PrimFloat.float -> @qualid__type` * :n:`PrimFloat.float -> option @qualid__type` * :n:`Number.number -> @qualid__type` * :n:`Number.number -> option @qualid__type` And the printing function :n:`@qualid__print` should have one of the following types: * :n:`@qualid__type -> Number.int` * :n:`@qualid__type -> option Number.int` * :n:`@qualid__type -> Number.uint` * :n:`@qualid__type -> option Number.uint` * :n:`@qualid__type -> Z` * :n:`@qualid__type -> option Z` * :n:`@qualid__type -> PrimInt63.pos_neg_int63` * :n:`@qualid__type -> option PrimInt63.pos_neg_int63` * :n:`@qualid__type -> PrimFloat.float` * :n:`@qualid__type -> option PrimFloat.float` * :n:`@qualid__type -> Number.number` * :n:`@qualid__type -> option Number.number` When parsing, the application of the parsing function :n:`@qualid__parse` to the number will be fully reduced, and universes of the resulting term will be refreshed. Note that only fully-reduced ground terms (terms containing only function application, constructors, inductive type families, sorts, primitive integers, primitive floats, primitive arrays and type constants for primitive types) will be considered for printing. .. note:: Instead of an inductive type, :n:`@qualid__type` can be :n:`PrimInt63.int` or :n:`PrimFloat.float`, in which case :n:`@qualid__print` takes :n:`PrimInt63.int_wrapper` or :n:`PrimFloat.float_wrapper` as input instead of :n:`PrimInt63.int` or :n:`PrimFloat.float`. See below for an :ref:`example <example-number-notation-primitive-int>`. .. note:: When :n:`PrimFloat.float` is used as input type of :n:`@qualid__parse`, only numerical values will be parsed this way, (no infinities nor NaN). Similarly, printers :n:`@qualid__print` with output type :n:`PrimFloat.float` or :n:`option PrimFloat.float` are ignored when they return non numerical values. .. _number-string-via: :n:`via @qualid__ind mapping [ {+, @qualid__constant => @qualid__constructor } ]` When using this option, :n:`@qualid__type` no longer needs to be an inductive type and is instead mapped to the inductive type :n:`@qualid__ind` according to the provided list of pairs, whose first component :n:`@qualid__constant` is a constant of type :n:`@qualid__type` (or a function of type :n:`{* _ -> } @qualid__type`) and the second a constructor of type :n:`@qualid__ind`. The type :n:`@qualid__type` is then replaced by :n:`@qualid__ind` in the above parser and printer types. When :n:`@qualid__constant` is surrounded by square brackets, all the implicit arguments of :n:`@qualid__constant` (whether maximally inserted or not) are ignored when translating to :n:`@qualid__constructor` (i.e., before applying :n:`@qualid__print`) and replaced with implicit argument holes :g:`_` when translating from :n:`@qualid__constructor` to :n:`@qualid__constant` (after :n:`@qualid__parse`). See below for an :ref:`example <example-number-notation-implicit-args>`. .. note:: The implicit status of the arguments is considered only at notation declaration time, any further modification of this status has no impact on the previously declared notations. .. note:: In case of multiple implicit options (for instance :g:`Arguments eq_refl {A}%_type_scope {x}, [_] _`), an argument is considered implicit when it is implicit in any of the options. .. note:: To use a :token:`sort` as the target type :n:`@qualid__type`, use an :ref:`abbreviation <Abbreviations>` as in the :ref:`example below <example-number-notation-non-inductive>`. :n:`warning after @bignat` displays a warning message about a possible stack overflow when calling :n:`@qualid__parse` to parse a literal larger than :n:`@bignat`. .. warn:: Stack overflow or segmentation fault happens when working with large numbers in @type (threshold may vary depending on your system limits and on the command executed). When a :cmd:`Number Notation` is registered in the current scope with :n:`(warning after @bignat)`, this warning is emitted when parsing a number greater than or equal to :token:`bignat`. :n:`abstract after @bignat` returns :n:`(@qualid__parse m)` when parsing a literal :n:`m` that's greater than :n:`@bignat` rather than reducing it to a normal form. Here :g:`m` will be a :g:`Number.int`, :g:`Number.uint`, :g:`Z` or :g:`Number.number`, depending on the type of the parsing function :n:`@qualid__parse`. This allows for a more compact representation of literals in types such as :g:`nat`, and limits parse failures due to stack overflow. Note that a warning will be emitted when an integer larger than :token:`bignat` is parsed. Note that :n:`(abstract after @bignat)` has no effect when :n:`@qualid__parse` lands in an :g:`option` type. .. warn:: To avoid stack overflow, large numbers in @type are interpreted as applications of @qualid__parse. When a :cmd:`Number Notation` is registered in the current scope with :n:`(abstract after @bignat)`, this warning is emitted when parsing a number greater than or equal to :token:`bignat`. Typically, this indicates that the fully computed representation of numbers can be so large that non-tail-recursive OCaml functions run out of stack space when trying to walk them. .. warn:: The 'abstract after' directive has no effect when the parsing function (@qualid__parse) targets an option type. As noted above, the :n:`(abstract after @natural)` directive has no effect when :n:`@qualid__parse` lands in an :g:`option` type. .. exn:: 'via' and 'abstract' cannot be used together. With the :n:`abstract after` option, the parser function :n:`@qualid__parse` does not reduce large numbers to a normal form, which prevents doing the translation given in the :n:`mapping` list. .. exn:: Cannot interpret this number as a value of type @type The number notation registered for :token:`type` does not support the given number. This error is given when the interpretation function returns :g:`None`, or if the interpretation is registered only for integers or non-negative integers, and the given number has a fractional or exponent part or is negative. .. exn:: overflow in int63 literal @bigint The constant's absolute value is too big to fit into a 63-bit integer :n:`PrimInt63.int`. .. exn:: @qualid__parse should go from Number.int to @type or (option @type). Instead of Number.int, the types Number.uint or Z or PrimInt63.pos_neg_int63 or PrimFloat.float or Number.number could be used (you may need to require BinNums or Number or PrimInt63 or PrimFloat first). The parsing function given to the :cmd:`Number Notation` command is not of the right type. .. exn:: @qualid__print should go from @type to Number.int or (option Number.int). Instead of Number.int, the types Number.uint or Z or PrimInt63.pos_neg_int63 or Number.number could be used (you may need to require BinNums or Number or PrimInt63 first). The printing function given to the :cmd:`Number Notation` command is not of the right type. .. exn:: Unexpected term @term while parsing a number notation. Parsing functions must always return ground terms, made up of function application, constructors, inductive type families, sorts and primitive integers. Parsing functions may not return terms containing axioms, bare (co)fixpoints, lambdas, etc. .. exn:: Unexpected non-option term @term while parsing a number notation. Parsing functions expected to return an :g:`option` must always return a concrete :g:`Some` or :g:`None` when applied to a concrete number expressed as a (hexa)decimal. They may not return opaque constants. .. exn:: Multiple 'via' options. At most one :g:`via` option can be given. .. exn:: Multiple 'warning after' or 'abstract after' options. At most one :g:`warning after` or :g:`abstract after` option can be given.
.. cmd:: String Notation @qualid__type @qualid__parse @qualid__print {? ( @number_string_via ) } : @scope_name Allows the user to customize how strings are parsed and printed. :n:`@qualid__type` the name of an inductive type, while :n:`@qualid__parse` and :n:`@qualid__print` should be the names of the parsing and printing functions, respectively. The parsing function :n:`@qualid__parse` should have one of the following types: * :n:`Byte.byte -> @qualid__type` * :n:`Byte.byte -> option @qualid__type` * :n:`list Byte.byte -> @qualid__type` * :n:`list Byte.byte -> option @qualid__type` The printing function :n:`@qualid__print` should have one of the following types: * :n:`@qualid__type -> Byte.byte` * :n:`@qualid__type -> option Byte.byte` * :n:`@qualid__type -> list Byte.byte` * :n:`@qualid__type -> option (list Byte.byte)` When parsing, the application of the parsing function :n:`@qualid__parse` to the string will be fully reduced, and universes of the resulting term will be refreshed. Note that only fully-reduced ground terms (terms containing only function application, constructors, inductive type families, sorts, primitive integers, primitive floats, primitive arrays and type constants for primitive types) will be considered for printing. :n:`via @qualid__ind mapping [ {+, @qualid__constant => @qualid__constructor } ]` works as for :ref:`number notations above <number-string-via>`. .. exn:: Cannot interpret this string as a value of type @type The string notation registered for :token:`type` does not support the given string. This error is given when the interpretation function returns :g:`None`. .. exn:: @qualid__parse should go from Byte.byte or (list Byte.byte) to @type or (option @type). The parsing function given to the :cmd:`String Notation` command is not of the right type. .. exn:: @qualid__print should go from @type to Byte.byte or (option Byte.byte) or (list Byte.byte) or (option (list Byte.byte)). The printing function given to the :cmd:`String Notation` command is not of the right type. .. exn:: Unexpected term @term while parsing a string notation. Parsing functions must always return ground terms, made up of function application, constructors, inductive type families, sorts and primitive integers. Parsing functions may not return terms containing axioms, bare (co)fixpoints, lambdas, etc. .. exn:: Unexpected non-option term @term while parsing a string notation. Parsing functions expected to return an :g:`option` must always return a concrete :g:`Some` or :g:`None` when applied to a concrete string expressed as a decimal. They may not return opaque constants.
Note
Number or string notations for parameterized inductive types can be added by declaring an :ref:`abbreviation <Abbreviations>` for the inductive which instantiates all parameters. See :ref:`example below <example-string-notation-parameterized-inductive>`.
The following errors apply to both string and number notations:
.. exn:: @type is not an inductive type. String and number notations can only be declared for inductive types. Declare string or numeral notations for non-inductive types using :n:`@number_string_via`... exn:: @qualid was already mapped to @qualid and cannot be remapped to @qualid Duplicates are not allowed in the :n:`mapping` list... exn:: Missing mapping for constructor @qualid A mapping should be provided for :n:`@qualid` in the :n:`mapping` list... warn:: @type was already mapped to @type, mapping it also to @type might yield ill typed terms when using the notation. Two pairs in the :n:`mapping` list associate types that might be incompatible... warn:: Type of @qualid seems incompatible with the type of @qualid. Expected type is: @type instead of @type. This might yield ill typed terms when using the notation. A mapping given in the :n:`mapping` list associates a constant with a seemingly incompatible constructor... exn:: Cannot interpret in @scope_name because @qualid could not be found in the current environment. The inductive type used to register the string or number notation is no longer available in the environment. Most likely, this is because the notation was declared inside a functor for an inductive type inside the functor. This use case is not currently supported. Alternatively, you might be trying to use a primitive token notation from a plugin which forgot to specify which module you must :g:`Require` for access to that notation... exn:: Syntax error: [prim:reference] expected after 'Notation' (in [vernac:command]). The type passed to :cmd:`String Notation` or :cmd:`Number Notation` must be a single qualified identifier... exn:: Syntax error: [prim:reference] expected after [prim:reference] (in [vernac:command]). Both functions passed to :cmd:`String Notation` or :cmd:`Number Notation` must be single qualified identifiers. .. todo: generally we don't document syntax errors. Is this a good execption?.. exn:: @qualid is bound to a notation that does not denote a reference. Identifiers passed to :cmd:`String Notation` or :cmd:`Number Notation` must be global references, or notations which evaluate to single qualified identifiers. .. todo note on "single qualified identifiers" https://github.com/coq/coq/pull/11718#discussion_r415076703
.. example:: Number Notation for radix 3 The following example parses and prints natural numbers whose digits are :g:`0`, :g:`1` or :g:`2` as terms of the following inductive type encoding radix 3 numbers. .. coqtop:: in reset Inductive radix3 : Set := | x0 : radix3 | x3 : radix3 -> radix3 | x3p1 : radix3 -> radix3 | x3p2 : radix3 -> radix3. We first define a parsing function .. coqtop:: in Definition of_uint_dec (u : Decimal.uint) : option radix3 := let fix f u := match u with | Decimal.Nil => Some x0 | Decimal.D0 u => match f u with Some u => Some (x3 u) | None => None end | Decimal.D1 u => match f u with Some u => Some (x3p1 u) | None => None end | Decimal.D2 u => match f u with Some u => Some (x3p2 u) | None => None end | _ => None end in f (Decimal.rev u). Definition of_uint (u : Number.uint) : option radix3 := match u with Number.UIntDecimal u => of_uint_dec u | Number.UIntHexadecimal _ => None end. and a printing function .. coqtop:: in Definition to_uint_dec (x : radix3) : Decimal.uint := let fix f x := match x with | x0 => Decimal.Nil | x3 x => Decimal.D0 (f x) | x3p1 x => Decimal.D1 (f x) | x3p2 x => Decimal.D2 (f x) end in Decimal.rev (f x). Definition to_uint (x : radix3) : Number.uint := Number.UIntDecimal (to_uint_dec x). before declaring the notation .. coqtop:: in Declare Scope radix3_scope. Open Scope radix3_scope. Number Notation radix3 of_uint to_uint : radix3_scope. We can check the printer .. coqtop:: all Check x3p2 (x3p1 x0). and the parser .. coqtop:: all Set Printing All. Check 120. Digits other than :g:`0`, :g:`1` and :g:`2` are rejected. .. coqtop:: all fail Check 3.
.. example:: Number Notation for primitive integers This shows the use of the primitive integers :n:`PrimInt63.int` as :n:`@qualid__type`. It is the way parsing and printing of primitive integers are actually implemented in `PrimInt63.v`. .. coqtop:: in reset Require Import PrimInt63. Definition parser (x : pos_neg_int63) : option int := match x with Pos p => Some p | Neg _ => None end. Definition printer (x : int_wrapper) : pos_neg_int63 := Pos (int_wrap x). Number Notation int parser printer : uint63_scope.
.. example:: Number Notation for a non-inductive type The following example encodes the terms in the form :g:`sum unit ( ... (sum unit unit) ... )` as the number of units in the term. For instance :g:`sum unit (sum unit unit)` is encoded as :g:`3` while :g:`unit` is :g:`1` and :g:`0` stands for :g:`Empty_set`. The inductive :g:`I` will be used as :n:`@qualid__ind`. .. coqtop:: in reset Inductive I := Iempty : I | Iunit : I | Isum : I -> I -> I. We then define :n:`@qualid__parse` and :n:`@qualid__print` .. coqtop:: in Definition of_uint (x : Number.uint) : I := let fix f n := match n with | O => Iempty | S O => Iunit | S n => Isum Iunit (f n) end in f (Nat.of_num_uint x). Definition to_uint (x : I) : Number.uint := let fix f i := match i with | Iempty => O | Iunit => 1 | Isum i1 i2 => f i1 + f i2 end in Nat.to_num_uint (f x). Inductive sum (A : Set) (B : Set) : Set := pair : A -> B -> sum A B. the number notation itself .. coqtop:: in Notation nSet := Set (only parsing). Number Notation nSet of_uint to_uint (via I mapping [Empty_set => Iempty, unit => Iunit, sum => Isum]) : type_scope. and check the printer .. coqtop:: all Local Open Scope type_scope. Check sum unit (sum unit unit). and the parser .. coqtop:: all Set Printing All. Check 3.
.. example:: Number Notation with implicit arguments The following example parses and prints natural numbers between :g:`0` and :g:`n-1` as terms of type :g:`Fin.t n`. .. coqtop:: all reset Require Import Vector. Print Fin.t. Note the implicit arguments of :g:`Fin.F1` and :g:`Fin.FS`, which won't appear in the corresponding inductive type. .. coqtop:: in Inductive I := I1 : I | IS : I -> I. Definition of_uint (x : Number.uint) : I := let fix f n := match n with O => I1 | S n => IS (f n) end in f (Nat.of_num_uint x). Definition to_uint (x : I) : Number.uint := let fix f i := match i with I1 => O | IS n => S (f n) end in Nat.to_num_uint (f x). Declare Scope fin_scope. Delimit Scope fin_scope with fin. Local Open Scope fin_scope. Number Notation Fin.t of_uint to_uint (via I mapping [[Fin.F1] => I1, [Fin.FS] => IS]) : fin_scope. Now :g:`2` is parsed as :g:`Fin.FS (Fin.FS Fin.F1)`, that is :g:`@Fin.FS _ (@Fin.FS _ (@Fin.F1 _))`. .. coqtop:: all Check 2. which can be of type :g:`Fin.t 3` (numbers :g:`0`, :g:`1` and :g:`2`) .. coqtop:: all Check 2 : Fin.t 3. but cannot be of type :g:`Fin.t 2` (only :g:`0` and :g:`1`) .. coqtop:: all fail Check 2 : Fin.t 2.
.. example:: String Notation with a parameterized inductive type The parameter :g:`Byte.byte` for the parameterized inductive type :g:`list` is given through an :ref:`abbreviation <Abbreviations>`. .. coqtop:: in reset Notation string := (list Byte.byte) (only parsing). Definition id_string := @id string. String Notation string id_string id_string : list_scope. .. coqtop:: all Check "abc"%list.
Tactic notations allow customizing the syntax of tactics.
.. cmd:: Tactic Notation {? ( at level @natural ) } {+ @ltac_production_item } := @ltac_expr .. insertprodn ltac_production_item ltac_production_item .. prodn:: ltac_production_item ::= @string | @ident {? ( @ident {? , @string } ) } Defines a *tactic notation*, which extends the parsing and pretty-printing of tactics. This command supports the :attr:`local` attribute, which limits the notation to the current module. :token:`natural` The parsing precedence to assign to the notation. This information is particularly relevant for notations for tacticals. Levels can be in the range 0 .. 5 (default is 5). :n:`{+ @ltac_production_item }` The notation syntax. Notations for simple tactics should begin with a :token:`string`. Note that `Tactic Notation foo := idtac` is not valid; it should be `Tactic Notation "foo" := idtac`. .. todo: "Tactic Notation constr := idtac" gives a nice message, would be good to show that message for the "foo" example above. :token:`string` represents a literal value in the notation :n:`@ident` is the name of a grammar nonterminal listed in the table below. In a few cases, to maintain backward compatibility, the name differs from the nonterminal name used elsewhere in the documentation. :n:`( @ident__parm {? , @string__s } )` :n:`@ident__parm` is the parameter name associated with :n:`@ident`. The :n:`@string__s` is the separator string to use when :n:`@ident` specifies a list with separators (i.e. :n:`@ident` ends with `_list_sep`). :n:`@ltac_expr` The tactic expression to substitute for the notation. :n:`@ident__parm` tokens appearing in :n:`@ltac_expr` are substituted with the associated nonterminal value. For example, the following command defines a notation with a single parameter `x`. .. coqtop:: in Tactic Notation "destruct_with_eqn" constr(x) := destruct x eqn:?. For a complex example, examine the 16 `Tactic Notation "setoid_replace"`\s defined in :file:`$COQLIB/theories/Classes/SetoidTactics.v`, which are designed to accept any subset of 4 optional parameters. The nonterminals that can specified in the tactic notation are: .. todo uconstr represents a type with holes. At the moment uconstr doesn't appear in the documented grammar. Maybe worth ressurecting with a better name, maybe "open_term"? see https://github.com/coq/coq/pull/11718#discussion_r413721234 .. todo 'open_constr' appears to be another possible value based on the the message from "Tactic Notation open_constr := idtac". Also (at least) "ref", "string", "preident", "int" and "ssrpatternarg". (from reading .v files). Looks like any string passed to "make0" in the code is valid. But do we want to support all these? @JasonGross's opinion here: https://github.com/coq/coq/pull/11718#discussion_r415387421 .. list-table:: :header-rows: 1 * - Specified :token:`ident` - Parsed as - Interpreted as - as in tactic * - ``ident`` - :token:`ident` - a user-given name - :tacn:`intro` * - ``simple_intropattern`` - :token:`simple_intropattern` - an introduction pattern - :tacn:`assert` `as` * - ``hyp`` - :token:`ident` - a hypothesis defined in context - :tacn:`clear` * - ``reference`` - :token:`qualid` - a qualified identifier - name of an |Ltac|-defined tactic * - ``smart_global`` - :token:`reference` - a global reference of term - :tacn:`unfold`, :tacn:`with_strategy` * - ``constr`` - :token:`one_term` - a term - :tacn:`exact` * - ``uconstr`` - :token:`one_term` - an untyped term - :tacn:`refine` * - ``integer`` - :token:`integer` - an integer - * - ``int_or_var`` - :token:`int_or_var` - an integer - :tacn:`do` * - ``strategy_level`` - :token:`strategy_level` - a strategy level - * - ``strategy_level_or_var`` - :token:`strategy_level_or_var` - a strategy level - :tacn:`with_strategy` * - ``tactic`` - :token:`ltac_expr` - a tactic - * - ``tactic``\ *n* (*n* in 0..5) - :token:`ltac_expr`\ *n* - a tactic at level *n* - * - *entry*\ ``_list`` - :n:`{* entry }` - a list of how *entry* is interpreted - * - ``ne_``\ *entry*\ ``_list`` - :n:`{+ entry }` - a list of how *entry* is interpreted - * - *entry*\ ``_list_sep`` - :n:`{*s entry }` - a list of how *entry* is interpreted - * - ``ne_``\ *entry*\ ``_list_sep`` - :n:`{+s entry }` - a list of how *entry* is interpreted - .. todo: notation doesn't support italics .. note:: In order to be bound in tactic definitions, each syntactic entry for argument type must include the case of a simple |Ltac| identifier as part of what it parses. This is naturally the case for ``ident``, ``simple_intropattern``, ``reference``, ``constr``, ... but not for ``integer`` nor for ``strategy_level``. This is the reason for introducing special entries ``int_or_var`` and ``strategy_level_or_var`` which evaluate to integers or strategy levels only, respectively, but which syntactically includes identifiers in order to be usable in tactic definitions. .. note:: The *entry*\ ``_list*`` and ``ne_``\ *entry*\ ``_list*`` entries can be used in primitive tactics or in other notations at places where a list of the underlying entry can be used: entry is either ``constr``, ``hyp``, ``integer``, ``reference``, ``strategy_level``, ``strategy_level_or_var``, or ``int_or_var``.
Footnotes
[1] | which are the levels effectively chosen in the current implementation of Coq |
[2] | Coq accepts notations declared as nonassociative but the parser on
which Coq is built, namely Camlp5, currently does not implement no associativity and
replaces it with left associativity ; hence it is the same for Coq: no associativity
is in fact left associativity for the purposes of parsing |