Removed Nano_JSON, which is is now an official AFP entry: https://www.isa-afp.org/entries/Nano_JSON.html
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Nano_JSON.thy
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Nano_JSON.thy
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(***********************************************************************************
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* Copyright (c) 2019 Achim D. Brucker
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*
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* All rights reserved.
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*
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* Redistribution and use in source and binary forms, with or without
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* modification, are permitted provided that the following conditions are met:
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*
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* * Redistributions of source code must retain the above copyright notice, this
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*
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* * Redistributions in binary form must reproduce the above copyright notice,
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* this list of conditions and the following disclaimer in the documentation
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* and/or other materials provided with the distribution.
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*
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* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
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* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
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* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
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* DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE
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* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
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* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
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* SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
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* CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
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* OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
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* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
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*
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* SPDX-License-Identifier: BSD-2-Clause
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* Repository: https://git.logicalhacking.com/adbrucker/isabelle-hacks/
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* Dependencies: None (assert.thy is used for testing the theory but it is
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* not required for providing the functionality of this hack)
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***********************************************************************************)
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(***********************************************************************************
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# Changelog
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This comment documents all notable changes to this file in a format inspired by
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[Keep a Changelog](https://keepachangelog.com/en/1.0.0/), and this project adheres
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to [Semantic Versioning](https://semver.org/spec/v2.0.0.html).
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## [Unreleased]
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- Improved representation of IEEE reals
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- Fixed serializer for definitions using equality from Pure
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## [1.0.0] - 2019-01-21
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- Initial release
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***********************************************************************************)
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chapter\<open>An Import/Export of JSON-like Formats for Isabelle/HOL\<close>
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theory
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"Nano_JSON"
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imports
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Complex_Main (* required for type real *)
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keywords
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"import_JSON" :: thy_decl
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and "definition_JSON" :: thy_decl
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and "serialize_JSON" :: thy_decl
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begin
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text\<open>
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This theory implements an import/export format for Isabelle/HOL that is inspired by
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JSON (JavaScript Object Notation). While the format defined in this theory is inspired
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by the JSON standard (@{url "https://www.json.org"}), it is not fully compliant. Most
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notably,
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\<^item> only basic support for Unicode characters
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\<^item> numbers are mapped to @{type "real"}, which is not a faithful representation of IEEE floating
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point numbers, moreover, we extended the abstract syntax to allow for representing integers as
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@{type "int"}.
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Still, our JSON-like import/expert should work with most real-world JSON files, i.e., simplifying
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the data exchange between Isabelle/HOL and tools that can read/write JSON.
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Overall, this theory should enable you to work with JSON encoded data in Isabelle/HOL without
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the need of implementing parsers or serialization in Isabelle/ML. You should be able to implement
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mapping from the Nano JSON HOL data types to your own data types on the level of Isabelle/HOL (i.e.,
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as executable HOL functions). Nevertheless, the provided ML routine that converts between the
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ML representation and the HOL representation of Nano JSON can also serve as a starting point
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for converting the ML representation to your own, domain-specific, HOL encoding.
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\<close>
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section\<open>Defining a JSON-like Data Structure\<close>
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text\<open>
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In this section
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\<close>
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datatype number = INTEGER int | REAL real
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datatype json = OBJECT "(string * json) list"
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| ARRAY "json list"
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| NUMBER "number"
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| STRING "string"
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| BOOL "bool"
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| NULL
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text\<open>
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Using the data type @{typ "json"}, we can now represent JSON encoded data easily in HOL:
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\<close>
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subsection\<open>Example\<close>
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definition example01::json where
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"example01 =
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OBJECT [(''menu'', OBJECT [(''id'', STRING ''file''), (''value'', STRING ''File''),
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(''popup'', OBJECT [(''menuitem'', ARRAY
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[OBJECT [(''value'', STRING ''New''), (''onclick'', STRING ''CreateNewDoc()'')],
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OBJECT [(''value'', STRING ''Open''), (''onclick'', STRING ''OpenDoc()'')],
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OBJECT [(''value'', STRING ''Close''), (''onclick'', STRING ''CloseDoc()'')]
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])]
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)])]"
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text\<open>
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The translation of the data type @{typ "json"} to ML is straight forward. In addition, we also
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provide methods for converting JSON instances between the representation as Isabelle terms and
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the representation as ML data structure.
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\<close>
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subsection\<open>ML Implementation\<close>
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ML\<open>
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signature NANO_JSON_TYPE = sig
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datatype number = INTEGER of int | REAL of IEEEReal.decimal_approx
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datatype json = OBJECT of (string * json) list
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| ARRAY of json list
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| NUMBER of number
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| STRING of string
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| BOOL of bool
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| NULL
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val term_of_json: json -> term
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val json_of_term: term -> json
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end
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structure Nano_Json_Type : NANO_JSON_TYPE = struct
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datatype number = INTEGER of int | REAL of IEEEReal.decimal_approx
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datatype json = OBJECT of (string * json) list
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| ARRAY of json list
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| NUMBER of number
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| STRING of string
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| BOOL of bool
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| NULL
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fun ieee_real_to_rat_approx rat = let
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val _ = warning ("Conversion of (real) numbers is not JSON compliant.")
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(* val rat = Real.toDecimal r *)
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fun pow (_, 0) = 1
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| pow (x, n) = if n mod 2 = 0 then pow (x*x, n div 2)
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else x * pow (x*x, n div 2);
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fun rat_of_dec rat = let
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val sign = #sign rat
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val digits = #digits rat
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val exp = #exp rat
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fun numerator_of _ [] = 0
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| numerator_of c (x::xs) = x*pow(10,c) + (numerator_of (c+1) xs)
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val numerator_abs = numerator_of 0 (rev digits)
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val denominator = pow(10, (List.length digits - exp))
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in
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(if sign then ~ numerator_abs else numerator_abs, denominator)
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end
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in
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case #class rat of
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IEEEReal.ZERO => (0,0)
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| IEEEReal.SUBNORMAL => rat_of_dec rat
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| IEEEReal.NORMAL => rat_of_dec rat
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| IEEEReal.INF => error "Real is INF, not yet supported."
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| IEEEReal.NAN => error "Real is NaN, not yet supported."
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end
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fun mk_divide t1 t2 = @{const Rings.divide_class.divide (real)} $ t1 $ t2
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fun mk_real_num i = HOLogic.mk_number @{typ "Real.real"} i
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fun mk_real (p,q) = if q = 1 then mk_real_num p else mk_divide (mk_real_num p) (mk_real_num q)
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fun dest_real (@{const Rings.divide_class.divide (real)} $a$b) =
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Real.toDecimal(Real.fromInt(HOLogic.dest_number a |> snd)
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/ Real.fromInt(HOLogic.dest_number b |> snd))
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| dest_real t = Real.toDecimal (Real.fromInt (HOLogic.dest_number t |> snd))
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fun term_of_json (OBJECT l) = @{const "OBJECT"}
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$(HOLogic.mk_list ((HOLogic.mk_prodT (HOLogic.stringT,@{typ "json"})))
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(map (fn (s,j) => HOLogic.mk_tuple[HOLogic.mk_string s, term_of_json j]) l))
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| term_of_json (ARRAY l) = @{const "ARRAY"}
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$(HOLogic.mk_list ( @{typ "json"}) (map term_of_json l))
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| term_of_json (NUMBER (INTEGER i)) = @{const "NUMBER"}
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$(@{const "INTEGER"}$(HOLogic.mk_number @{typ "int"} i))
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| term_of_json (NUMBER (REAL r)) = @{const "NUMBER"}
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$(@{const "REAL"}$(mk_real (ieee_real_to_rat_approx r)))
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| term_of_json (STRING s) = @{const "STRING"}$(HOLogic.mk_string s)
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| term_of_json (BOOL v) = @{const "BOOL"}$(if v then @{const "True"} else @{const "False"})
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| term_of_json (NULL) = @{const "NULL"}
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fun json_of_term t = let
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fun dest_key_value [string, json] = (HOLogic.dest_string string, json_of json)
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| dest_key_value _ = error "dest_key_value: not a key-value pair."
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and json_of (@{const "OBJECT"} $ l) = OBJECT (map (dest_key_value o HOLogic.strip_tuple) (HOLogic.dest_list l))
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| json_of (@{const "ARRAY"} $ l) = ARRAY (map json_of (HOLogic.dest_list l))
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| json_of (@{const "NUMBER"} $ @{const "INTEGER"} $ i) = (NUMBER (INTEGER (HOLogic.dest_numeral i)))
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| json_of (@{const "NUMBER"} $ @{const "REAL"} $ r) = (NUMBER (REAL (dest_real r)))
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| json_of (@{const "STRING"} $ s) = STRING (HOLogic.dest_string s)
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| json_of (@{const "BOOL"} $ @{const "True"}) = BOOL true
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| json_of (@{const "BOOL"} $ @{const "False"}) = BOOL true
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| json_of @{const "NULL"} = NULL
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| json_of _ = error "Term not supported in json_of_term."
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in
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if type_of t = @{typ "json"} then json_of t
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else error "Term not of type json."
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end
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end
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\<close>
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section\<open>Parsing Nano JSON\<close>
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text\<open>
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In this section, we define the infrastructure for parsing JSON-like data structures as
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well as for importing them into Isabelle/HOL. This implementation was inspired by the
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``Simple Standard ML JSON parser'' from Chris Cannam.
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\<close>
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subsection\<open>ML Implementation\<close>
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subsubsection\<open>Lexer\<close>
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ML\<open>
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signature NANO_JSON_LEXER = sig
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structure T : sig
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datatype token = NUMBER of char list
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| STRING of string
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| BOOL of bool
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| NULL
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| CURLY_L
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| CURLY_R
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| SQUARE_L
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| SQUARE_R
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| COLON
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| COMMA
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val string_of_T : token -> string
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end
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val tokenize_string: string -> T.token list
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end
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structure Nano_Json_Lexer : NANO_JSON_LEXER = struct
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structure T = struct
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datatype token = NUMBER of char list
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| STRING of string
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| BOOL of bool
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| NULL
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| CURLY_L
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| CURLY_R
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| SQUARE_L
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| SQUARE_R
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| COLON
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| COMMA
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fun string_of_T t =
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case t of NUMBER digits => String.implode digits
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| STRING s => s
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| BOOL b => Bool.toString b
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| NULL => "null"
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| CURLY_L => "{"
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| CURLY_R => "}"
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| SQUARE_L => "["
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| SQUARE_R => "]"
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| COLON => ":"
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| COMMA => ","
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end
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fun lexer_error pos text = error (text ^ " at character position " ^
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Int.toString (pos - 1))
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fun token_error pos = lexer_error pos ("Unexpected token")
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fun bmp_to_utf8 cp = map (Char.chr o Word.toInt)
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(if cp < 0wx80
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then [cp]
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else if cp < 0wx800
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then [Word.orb(0wxc0, Word.>>(cp,0w6)),
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Word.orb(0wx8, Word.andb (cp, 0wx3f))]
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else if cp < 0wx10000
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then [Word.orb(0wxe0,Word.>>(cp, 0w12)),
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Word.orb(0wx80, Word.andb(Word.>>(cp,0w6), 0wx3f)),
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Word.orb(0wx80,Word.andb(cp, 0wx3f))]
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else error ("Invalid BMP point in bmp_to_utf8 " ^ (Word.toString cp)))
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fun lexNull pos acc (#"u" :: #"l" :: #"l" :: xs) =
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lex (pos + 3) (T.NULL :: acc) xs
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| lexNull pos _ _ = token_error pos
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and lexTrue pos acc (#"r" :: #"u" :: #"e" :: xs) =
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lex (pos + 3) (T.BOOL true :: acc) xs
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| lexTrue pos _ _ = token_error pos
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and lexFalse pos acc (#"a" :: #"l" :: #"s" :: #"e" :: xs) =
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lex (pos + 4) (T.BOOL false :: acc) xs
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| lexFalse pos _ _ = token_error pos
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and lexChar tok pos acc xs =
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lex pos (tok :: acc) xs
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and lexString pos acc cc =
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let datatype escaped = ESCAPED | NORMAL
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fun lexString' pos _ ESCAPED [] =
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lexer_error pos "End of input during escape sequence"
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| lexString' pos _ NORMAL [] =
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lexer_error pos "End of input during string"
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| lexString' pos text ESCAPED (x :: xs) =
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let fun esc c = lexString' (pos + 1) (c :: text) NORMAL xs
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in case x of
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#"\"" => esc x
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| #"\\" => esc x
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| #"/" => esc x
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| #"b" => esc #"\b"
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| #"f" => esc #"\f"
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| #"n" => esc #"\n"
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| #"r" => esc #"\r"
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| #"t" => esc #"\t"
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| _ => lexer_error pos ("Invalid escape \\" ^
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Char.toString x)
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end
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| lexString' pos text NORMAL (#"\\" :: #"u" ::a::b::c::d:: xs) =
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if List.all Char.isHexDigit [a,b,c,d]
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then case Word.fromString ("0wx" ^ (String.implode [a,b,c,d])) of
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SOME w => (let val utf = rev (bmp_to_utf8 w) in
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lexString' (pos + 6) (utf @ text)
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NORMAL xs
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end
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handle Fail err => lexer_error pos err)
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| NONE => lexer_error pos "Invalid Unicode BMP escape sequence"
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else lexer_error pos "Invalid Unicode BMP escape sequence"
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| lexString' pos text NORMAL (x :: xs) =
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if Char.ord x < 0x20
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then lexer_error pos "Invalid unescaped control character"
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else
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case x of
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#"\"" => (rev text, xs, pos + 1)
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| #"\\" => lexString' (pos + 1) text ESCAPED xs
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| _ => lexString' (pos + 1) (x :: text) NORMAL xs
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val (text, rest, newpos) = lexString' pos [] NORMAL cc
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in
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lex newpos (T.STRING (String.implode text) :: acc) rest
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end
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and lexNumber firstChar pos acc cc =
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let val valid = String.explode ".+-e"
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fun lexNumber' pos digits [] = (rev digits, [], pos)
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| lexNumber' pos digits (x :: xs) =
|
|
||||||
if x = #"E" then lexNumber' (pos + 1) (#"e" :: digits) xs
|
|
||||||
else if Char.isDigit x orelse List.exists (fn c => x = c) valid
|
|
||||||
then lexNumber' (pos + 1) (x :: digits) xs
|
|
||||||
else (rev digits, x :: xs, pos)
|
|
||||||
val (digits, rest, newpos) =
|
|
||||||
lexNumber' (pos - 1) [] (firstChar :: cc)
|
|
||||||
in
|
|
||||||
case digits of
|
|
||||||
[] => token_error pos
|
|
||||||
| _ => lex newpos (T.NUMBER digits :: acc) rest
|
|
||||||
end
|
|
||||||
|
|
||||||
and lex _ acc [] = rev acc
|
|
||||||
| lex pos acc (x::xs) =
|
|
||||||
(case x of
|
|
||||||
#" " => lex
|
|
||||||
| #"\t" => lex
|
|
||||||
| #"\n" => lex
|
|
||||||
| #"\r" => lex
|
|
||||||
| #"{" => lexChar T.CURLY_L
|
|
||||||
| #"}" => lexChar T.CURLY_R
|
|
||||||
| #"[" => lexChar T.SQUARE_L
|
|
||||||
| #"]" => lexChar T.SQUARE_R
|
|
||||||
| #":" => lexChar T.COLON
|
|
||||||
| #"," => lexChar T.COMMA
|
|
||||||
| #"\"" => lexString
|
|
||||||
| #"t" => lexTrue
|
|
||||||
| #"f" => lexFalse
|
|
||||||
| #"n" => lexNull
|
|
||||||
| x => lexNumber x) (pos + 1) acc xs
|
|
||||||
|
|
||||||
fun tokenize_string str = lex 1 [] (String.explode str)
|
|
||||||
end
|
|
||||||
\<close>
|
|
||||||
|
|
||||||
subsubsection\<open>Parser\<close>
|
|
||||||
ML\<open>
|
|
||||||
signature NANO_JSON_PARSER = sig
|
|
||||||
val json_of_string : string -> Nano_Json_Type.json
|
|
||||||
val term_of_json_string : string -> term
|
|
||||||
end
|
|
||||||
|
|
||||||
structure Nano_Json_Parser : NANO_JSON_PARSER = struct
|
|
||||||
open Nano_Json_Type
|
|
||||||
open Nano_Json_Lexer
|
|
||||||
|
|
||||||
fun show [] = "end of input"
|
|
||||||
| show (tok :: _) = T.string_of_T tok
|
|
||||||
|
|
||||||
val parse_error = error
|
|
||||||
|
|
||||||
fun parseNumber digits =
|
|
||||||
let open Char
|
|
||||||
|
|
||||||
fun okExpDigits [] = false
|
|
||||||
| okExpDigits (c :: []) = isDigit c
|
|
||||||
| okExpDigits (c :: cs) = isDigit c andalso okExpDigits cs
|
|
||||||
|
|
||||||
fun okExponent [] = false
|
|
||||||
| okExponent (#"+" :: cs) = okExpDigits cs
|
|
||||||
| okExponent (#"-" :: cs) = okExpDigits cs
|
|
||||||
| okExponent cc = okExpDigits cc
|
|
||||||
|
|
||||||
fun okFracTrailing [] = true
|
|
||||||
| okFracTrailing (c :: cs) =
|
|
||||||
(isDigit c andalso okFracTrailing cs) orelse
|
|
||||||
(c = #"e" andalso okExponent cs)
|
|
||||||
|
|
||||||
fun okFraction [] = false
|
|
||||||
| okFraction (c :: cs) =
|
|
||||||
isDigit c andalso okFracTrailing cs
|
|
||||||
|
|
||||||
fun okPosTrailing [] = true
|
|
||||||
| okPosTrailing (#"." :: cs) = okFraction cs
|
|
||||||
| okPosTrailing (#"e" :: cs) = okExponent cs
|
|
||||||
| okPosTrailing (c :: cs) =
|
|
||||||
isDigit c andalso okPosTrailing cs
|
|
||||||
|
|
||||||
fun okPositive [] = false
|
|
||||||
| okPositive (#"0" :: []) = true
|
|
||||||
| okPositive (#"0" :: #"." :: cs) = okFraction cs
|
|
||||||
| okPositive (#"0" :: #"e" :: cs) = okExponent cs
|
|
||||||
| okPositive (#"0" :: _) = false
|
|
||||||
| okPositive (c :: cs) = isDigit c andalso okPosTrailing cs
|
|
||||||
|
|
||||||
fun okNumber (#"-" :: cs) = okPositive cs
|
|
||||||
| okNumber cc = okPositive cc
|
|
||||||
in
|
|
||||||
if okNumber digits then let
|
|
||||||
val number = String.implode digits
|
|
||||||
in
|
|
||||||
if List.all (Char.isDigit) (String.explode number)
|
|
||||||
then (case Int.fromString (String.implode digits) of
|
|
||||||
NONE => parse_error "Number out of range"
|
|
||||||
| SOME r => INTEGER r)
|
|
||||||
else (case IEEEReal.fromString (String.implode digits) of
|
|
||||||
NONE => parse_error "Number out of range"
|
|
||||||
| SOME r => REAL r)
|
|
||||||
end
|
|
||||||
else parse_error ("Invalid number \"" ^ (String.implode digits) ^ "\"")
|
|
||||||
end
|
|
||||||
|
|
||||||
fun parseObject (T.CURLY_R :: xs) = (OBJECT [], xs)
|
|
||||||
| parseObject tokens =
|
|
||||||
let fun parsePair (T.STRING key :: T.COLON :: xs) = let
|
|
||||||
val (j, xs) = parseTokens xs
|
|
||||||
in
|
|
||||||
((key, j), xs)
|
|
||||||
end
|
|
||||||
| parsePair other =
|
|
||||||
parse_error("Object key/value pair expected around \"" ^
|
|
||||||
show other ^ "\"")
|
|
||||||
fun parseObject' _ [] = parse_error "End of input during object"
|
|
||||||
| parseObject' acc tokens =
|
|
||||||
case parsePair tokens of
|
|
||||||
(pair, T.COMMA :: xs) =>
|
|
||||||
parseObject' (pair :: acc) xs
|
|
||||||
| (pair, T.CURLY_R :: xs) =>
|
|
||||||
(OBJECT (rev (pair :: acc)), xs)
|
|
||||||
| (_, _) =>parse_error "Expected , or } after object element"
|
|
||||||
in
|
|
||||||
parseObject' [] tokens
|
|
||||||
end
|
|
||||||
|
|
||||||
and parseArray (T.SQUARE_R :: xs) = (ARRAY [], xs)
|
|
||||||
| parseArray tokens =
|
|
||||||
let fun parseArray' _ [] = error "End of input during array"
|
|
||||||
| parseArray' acc tokens =
|
|
||||||
case parseTokens tokens of
|
|
||||||
(j, T.COMMA :: xs) => parseArray' (j :: acc) xs
|
|
||||||
| (j, T.SQUARE_R :: xs) => (ARRAY (rev (j :: acc)), xs)
|
|
||||||
| (_, _) => error "Expected , or ] after array element"
|
|
||||||
in
|
|
||||||
parseArray' [] tokens
|
|
||||||
end
|
|
||||||
|
|
||||||
and parseTokens [] = parse_error "Value expected"
|
|
||||||
| parseTokens (tok :: xs) =
|
|
||||||
(case tok of
|
|
||||||
T.NUMBER d => (NUMBER ((parseNumber d)), xs)
|
|
||||||
| T.STRING s => (STRING s, xs)
|
|
||||||
| T.BOOL b => (BOOL b, xs)
|
|
||||||
| T.NULL => (NULL, xs)
|
|
||||||
| T.CURLY_L => parseObject xs
|
|
||||||
| T.SQUARE_L => parseArray xs
|
|
||||||
| _ => parse_error ("Unexpected token " ^ T.string_of_T tok ^
|
|
||||||
" before " ^ show xs))
|
|
||||||
|
|
||||||
fun json_of_string str = case parseTokens (Nano_Json_Lexer.tokenize_string str) of
|
|
||||||
(value, []) => value
|
|
||||||
| (_, _) => parse_error "Extra data after input"
|
|
||||||
val term_of_json_string = term_of_json o json_of_string
|
|
||||||
end
|
|
||||||
\<close>
|
|
||||||
|
|
||||||
|
|
||||||
subsection\<open>Isar Setup\<close>
|
|
||||||
|
|
||||||
subsubsection\<open>The JSON Cartouche\<close>
|
|
||||||
|
|
||||||
syntax "_cartouche_nano_json" :: "cartouche_position \<Rightarrow> 'a" ("JSON _")
|
|
||||||
parse_translation\<open>
|
|
||||||
let
|
|
||||||
fun translation args =
|
|
||||||
let
|
|
||||||
fun err () = raise TERM ("Common._cartouche_nano_json", args)
|
|
||||||
fun input s pos = Symbol_Pos.implode (Symbol_Pos.cartouche_content (Symbol_Pos.explode (s, pos)))
|
|
||||||
in
|
|
||||||
case args of
|
|
||||||
[(c as Const (@{syntax_const "_constrain"}, _)) $ Free (s, _) $ p] =>
|
|
||||||
(case Term_Position.decode_position p of
|
|
||||||
SOME (pos, _) => c $ Nano_Json_Parser.term_of_json_string (input s pos) $ p
|
|
||||||
| NONE => err ())
|
|
||||||
| _ => err ()
|
|
||||||
end
|
|
||||||
in
|
|
||||||
[(@{syntax_const "_cartouche_nano_json"}, K translation)]
|
|
||||||
end
|
|
||||||
\<close>
|
|
||||||
|
|
||||||
subsubsection\<open>Isar Top-Level Commands\<close>
|
|
||||||
ML\<open>
|
|
||||||
structure Nano_Json_Parser_Isar = struct
|
|
||||||
fun make_const_def (constname, trm) lthy = let
|
|
||||||
val arg = ((Binding.name constname, NoSyn), ((Binding.name (constname^"_def"),[]), trm))
|
|
||||||
val ((_, (_ , thm)), lthy') = Local_Theory.define arg lthy
|
|
||||||
in
|
|
||||||
(thm, lthy')
|
|
||||||
end
|
|
||||||
fun def_json name json = snd o (make_const_def (name, Nano_Json_Parser.term_of_json_string json ))
|
|
||||||
fun def_json_file name filename lthy = let
|
|
||||||
val filename = Path.explode filename
|
|
||||||
val thy = Proof_Context.theory_of lthy
|
|
||||||
val master_dir = Resources.master_directory thy
|
|
||||||
val abs_filename = if (Path.is_absolute filename)
|
|
||||||
then filename
|
|
||||||
else Path.append master_dir filename
|
|
||||||
val json = File.read abs_filename
|
|
||||||
in
|
|
||||||
def_json name json lthy
|
|
||||||
end
|
|
||||||
val jsonFileP = Parse.name -- Parse.name
|
|
||||||
val jsonP = Parse.name -- Parse.cartouche
|
|
||||||
end
|
|
||||||
\<close>
|
|
||||||
|
|
||||||
ML\<open>
|
|
||||||
val _ = Outer_Syntax.local_theory @{command_keyword "definition_JSON"} "Define JSON."
|
|
||||||
(Nano_Json_Parser_Isar.jsonP >> (fn (name, json) => Nano_Json_Parser_Isar.def_json name json));
|
|
||||||
val _ = Outer_Syntax.local_theory @{command_keyword "import_JSON"} "Define JSON from file."
|
|
||||||
(Nano_Json_Parser_Isar.jsonFileP >> (fn (name, filename) => Nano_Json_Parser_Isar.def_json_file name filename));
|
|
||||||
\<close>
|
|
||||||
|
|
||||||
subsection\<open>Examples\<close>
|
|
||||||
|
|
||||||
text\<open>
|
|
||||||
Now we can use the JSON Cartouche for defining JSON-like data ``on-the-fly'', e.g.:
|
|
||||||
\<close>
|
|
||||||
lemma \<open>y == JSON\<open>{"name": [true,false,"test"]}\<close>\<close>
|
|
||||||
oops
|
|
||||||
text\<open>
|
|
||||||
Note that you need to escape quotes within the JSON Cartouche, if you are using
|
|
||||||
quotes as lemma delimiters, e.g.,:
|
|
||||||
\<close>
|
|
||||||
lemma "y == JSON\<open>{\"name\": [true,false,\"test\"]}\<close>"
|
|
||||||
oops
|
|
||||||
text\<open>
|
|
||||||
Thus, we recommend to use the Cartouche delimiters when using the JSON Cartouche with non
|
|
||||||
trivial data structures:
|
|
||||||
\<close>
|
|
||||||
|
|
||||||
lemma \<open> example01 == JSON \<open>{"menu": {
|
|
||||||
"id": "file",
|
|
||||||
"value": "File",
|
|
||||||
"popup": {
|
|
||||||
"menuitem": [
|
|
||||||
{"value": "New", "onclick": "CreateNewDoc()"},
|
|
||||||
{"value": "Open", "onclick": "OpenDoc()"},
|
|
||||||
{"value": "Close", "onclick": "CloseDoc()"}
|
|
||||||
]
|
|
||||||
}
|
|
||||||
}}\<close>\<close>
|
|
||||||
by(simp add: example01_def)
|
|
||||||
|
|
||||||
text\<open>
|
|
||||||
Using the top level Isar commands defined in the last section, we can now easily define
|
|
||||||
JSON-like data:
|
|
||||||
\<close>
|
|
||||||
|
|
||||||
definition_JSON example02 \<open>
|
|
||||||
{"menu": {
|
|
||||||
"id": "file",
|
|
||||||
"value": "File",
|
|
||||||
"popup": {
|
|
||||||
"menuitem": [
|
|
||||||
{"value": "New", "onclick": "CreateNewDoc()"},
|
|
||||||
{"value": "Open", "onclick": "OpenDoc()"},
|
|
||||||
{"value": "Close", "onclick": "CloseDoc()"}
|
|
||||||
]
|
|
||||||
}
|
|
||||||
}}
|
|
||||||
\<close>
|
|
||||||
thm example02_def
|
|
||||||
|
|
||||||
lemma "example01 = example02"
|
|
||||||
by(simp add: example01_def example02_def)
|
|
||||||
|
|
||||||
text\<open>
|
|
||||||
Moreover, we can import JSON from external files:
|
|
||||||
\<close>
|
|
||||||
|
|
||||||
import_JSON example03 "example.json"
|
|
||||||
thm example03_def
|
|
||||||
|
|
||||||
lemma "example01 = example03"
|
|
||||||
by(simp add: example01_def example03_def)
|
|
||||||
|
|
||||||
section\<open>Serializing Nano JSON\<close>
|
|
||||||
|
|
||||||
text\<open>
|
|
||||||
In this section, we define the necessary infrastructure to serialize (export) data from HOL using
|
|
||||||
a JSON-like data structure that other JSON tools should be able to import.
|
|
||||||
\<close>
|
|
||||||
|
|
||||||
subsection\<open>ML Implementation\<close>
|
|
||||||
ML\<open>
|
|
||||||
signature NANO_JSON_SERIALIZER = sig
|
|
||||||
val serialize_json: Nano_Json_Type.json -> string
|
|
||||||
val serialize_json_pretty: Nano_Json_Type.json -> string
|
|
||||||
val serialize_term: term -> string
|
|
||||||
val serialize_term_pretty: term -> string
|
|
||||||
end
|
|
||||||
|
|
||||||
structure Nano_Json_Serializer : NANO_JSON_SERIALIZER = struct
|
|
||||||
open Nano_Json_Type
|
|
||||||
|
|
||||||
fun escapeJsonString s =
|
|
||||||
let fun bs c = "\\"^(Char.toString c)
|
|
||||||
fun escape #"\"" = bs #"\""
|
|
||||||
| escape #"\\" = bs #"\\"
|
|
||||||
| escape #"\b" = bs #"b"
|
|
||||||
| escape #"\f" = bs #"f"
|
|
||||||
| escape #"\n" = bs #"n"
|
|
||||||
| escape #"\r" = bs #"r"
|
|
||||||
| escape #"\t" = bs #"t"
|
|
||||||
| escape c =
|
|
||||||
let val ord = Char.ord c
|
|
||||||
in
|
|
||||||
if ord < 0x20
|
|
||||||
then let val hex = Word.toString (Word.fromInt ord)
|
|
||||||
val prfx = if ord < 0x10 then "\\u000" else "\\u00"
|
|
||||||
in
|
|
||||||
prfx^hex
|
|
||||||
end
|
|
||||||
else
|
|
||||||
Char.toString c
|
|
||||||
end
|
|
||||||
in
|
|
||||||
String.concat (map escape (String.explode s))
|
|
||||||
end
|
|
||||||
|
|
||||||
fun serialize pretty json = let
|
|
||||||
val nl = if pretty = NONE then "" else "\n"
|
|
||||||
fun indent' 0 = ""
|
|
||||||
| indent' n = " "^(indent' (n-1))
|
|
||||||
fun indent n = (case pretty of NONE => ""
|
|
||||||
| SOME n' => indent' (n+n'))
|
|
||||||
fun serialize' _ (OBJECT []) = "{}"
|
|
||||||
| serialize' _ (ARRAY []) = "[]"
|
|
||||||
| serialize' n (OBJECT pp) = "{"^nl^(indent (n+1)) ^ String.concatWith
|
|
||||||
(","^nl^(indent (n+1)))
|
|
||||||
(map (fn (key, value) =>
|
|
||||||
serialize' (n+1) (STRING key) ^ ":" ^
|
|
||||||
serialize' (n+1) value) pp) ^
|
|
||||||
nl^(indent n)^"}"
|
|
||||||
| serialize' n (ARRAY arr) = "["^nl^(indent (n+1)) ^ String.concatWith
|
|
||||||
(","^nl^(indent (n+1)))
|
|
||||||
(map (serialize' (n+1) ) arr) ^
|
|
||||||
nl^(indent n)^"]"
|
|
||||||
| serialize' _ (NUMBER (REAL n)) = String.implode (map (fn #"~" => #"-" | c => c)
|
|
||||||
(String.explode (IEEEReal.toString n)))
|
|
||||||
| serialize' _ (NUMBER (INTEGER n)) = String.implode (map (fn #"~" => #"-" | c => c)
|
|
||||||
(String.explode (Int.toString n)))
|
|
||||||
| serialize' _ (STRING s) = "\"" ^ escapeJsonString s ^ "\""
|
|
||||||
| serialize' _ (BOOL b) = Bool.toString b
|
|
||||||
| serialize' _ NULL = "null"
|
|
||||||
|
|
||||||
in
|
|
||||||
(serialize' 0 json)^nl
|
|
||||||
end
|
|
||||||
|
|
||||||
val serialize_json = serialize NONE
|
|
||||||
val serialize_json_pretty = serialize (SOME 0)
|
|
||||||
val serialize_term = (serialize NONE) o json_of_term
|
|
||||||
val serialize_term_pretty = (serialize (SOME 0)) o json_of_term
|
|
||||||
end
|
|
||||||
\<close>
|
|
||||||
|
|
||||||
subsection\<open>Isar Setup\<close>
|
|
||||||
ML\<open>
|
|
||||||
structure Nano_Json_Serialize_Isar = struct
|
|
||||||
fun export_json ctxt json_const filename =
|
|
||||||
let
|
|
||||||
val thy = Proof_Context.theory_of ctxt
|
|
||||||
val master_dir = Resources.master_directory thy
|
|
||||||
val term = Thm.concl_of (Global_Theory.get_thm thy (json_const^"_def"))
|
|
||||||
val json_term = case term of
|
|
||||||
Const (@{const_name "Pure.eq"}, _) $ _ $ json_term => json_term
|
|
||||||
| _ $ (_ $ json_term) => json_term
|
|
||||||
| _ => error ("Term structure not supported: "
|
|
||||||
^(Sledgehammer_Util.hackish_string_of_term ctxt term))
|
|
||||||
val json_string = Nano_Json_Serializer.serialize_term_pretty json_term
|
|
||||||
in
|
|
||||||
case filename of
|
|
||||||
SOME filename => let
|
|
||||||
val filename = Path.explode filename
|
|
||||||
val abs_filename = if (Path.is_absolute filename)
|
|
||||||
then filename
|
|
||||||
else Path.append master_dir filename
|
|
||||||
in
|
|
||||||
File.write (abs_filename) json_string
|
|
||||||
handle (IO.Io{name=name,...}) => warning ("Could not write \""^name^"\".")
|
|
||||||
end
|
|
||||||
| NONE => tracing json_string
|
|
||||||
end
|
|
||||||
end
|
|
||||||
\<close>
|
|
||||||
|
|
||||||
|
|
||||||
ML\<open>
|
|
||||||
Outer_Syntax.command ("serialize_JSON", Position.none) "export JSON data to an external file"
|
|
||||||
(Parse.name -- Scan.option Parse.name >> (fn (const_name,filename) =>
|
|
||||||
(Toplevel.keep (fn state => Nano_Json_Serialize_Isar.export_json (Toplevel.context_of state) const_name filename))));
|
|
||||||
\<close>
|
|
||||||
|
|
||||||
|
|
||||||
subsection\<open>Examples\<close>
|
|
||||||
text\<open>
|
|
||||||
We can now serialize JSON and print the result in the output window of Isabelle/HOL:
|
|
||||||
\<close>
|
|
||||||
serialize_JSON example01
|
|
||||||
|
|
||||||
text\<open>
|
|
||||||
Alternatively, we can export the serialized JSON into a file:
|
|
||||||
\<close>
|
|
||||||
serialize_JSON example01 example01.json
|
|
||||||
|
|
||||||
section\<open>Putting Everything Together\<close>
|
|
||||||
text\<open>
|
|
||||||
For convenience, we provide an ML structure that provides access to both the parser and the
|
|
||||||
serializer:,
|
|
||||||
\<close>
|
|
||||||
ML\<open>
|
|
||||||
structure Nano_Json = struct
|
|
||||||
open Nano_Json_Type
|
|
||||||
open Nano_Json_Parser
|
|
||||||
open Nano_Json_Serializer
|
|
||||||
end
|
|
||||||
\<close>
|
|
||||||
|
|
||||||
end
|
|
10
README.md
10
README.md
|
@ -32,13 +32,17 @@ older versions might be available on a dedicated branch.
|
||||||
* [Ml_Yacc_Lib.thy](Ml_Yacc_Lib.thy) provides Isabelle support for parser
|
* [Ml_Yacc_Lib.thy](Ml_Yacc_Lib.thy) provides Isabelle support for parser
|
||||||
generated by ml-yacc (part of sml/NJ).
|
generated by ml-yacc (part of sml/NJ).
|
||||||
|
|
||||||
* [Nano_JSON.thy](Nano_JSON.thy) provides support for a JSON-like
|
|
||||||
data exchange for Isabelle/HOL.
|
|
||||||
|
|
||||||
* [Simple_Oracle.thy](Simple_Oracle.thy) provides an example on integrating
|
* [Simple_Oracle.thy](Simple_Oracle.thy) provides an example on integrating
|
||||||
an external tool as simple oracle or counter example generator, similar
|
an external tool as simple oracle or counter example generator, similar
|
||||||
to the built-in quickcheck.
|
to the built-in quickcheck.
|
||||||
|
|
||||||
|
### No Longer Maintained Hacks
|
||||||
|
|
||||||
|
* Nano_JSON.thy (support for a JSON-like data exchange for Isabelle/HOL)
|
||||||
|
has been developed into an AFP entry "[Nano_JSON](https://www.isa-afp.org/entries/Nano_JSON.html)",
|
||||||
|
which contains documentation and examples for using JSON encoded data with
|
||||||
|
Isabelle/HOL and Isabelle/ML.
|
||||||
|
|
||||||
## Authors
|
## Authors
|
||||||
|
|
||||||
Main author: [Achim D. Brucker](http://www.brucker.ch/)
|
Main author: [Achim D. Brucker](http://www.brucker.ch/)
|
||||||
|
|
1
ROOT
1
ROOT
|
@ -6,7 +6,6 @@ session "isabelle-hacks" = "HOL" +
|
||||||
Fxp
|
Fxp
|
||||||
Hiding_Type_Variables
|
Hiding_Type_Variables
|
||||||
Ml_Yacc_Lib
|
Ml_Yacc_Lib
|
||||||
Nano_JSON
|
|
||||||
Simple_Oracle
|
Simple_Oracle
|
||||||
document_files
|
document_files
|
||||||
root.tex
|
root.tex
|
||||||
|
|
11
example.json
11
example.json
|
@ -1,11 +0,0 @@
|
||||||
{"menu": {
|
|
||||||
"id": "file",
|
|
||||||
"value": "File",
|
|
||||||
"popup": {
|
|
||||||
"menuitem": [
|
|
||||||
{"value": "New", "onclick": "CreateNewDoc()"},
|
|
||||||
{"value": "Open", "onclick": "OpenDoc()"},
|
|
||||||
{"value": "Close", "onclick": "CloseDoc()"}
|
|
||||||
]
|
|
||||||
}
|
|
||||||
}}
|
|
Loading…
Reference in New Issue