Merge pull request #101 from aeternity/release-3.2

Prepare version 3.2.0

.circleci/config.yml

@@ -19,16 +19,16 @@ jobs:
             - dialyzer-cache-v2-
       - run:
           name: Build
-          command: rebar3 compile
+          command: ./rebar3 compile
       - run:
           name: Static Analysis
-          command: rebar3 dialyzer
+          command: ./rebar3 dialyzer
       - run:
           name: Eunit
-          command: rebar3 eunit
+          command: ./rebar3 eunit
       - run:
           name: Common Tests
-          command: rebar3 ct
+          command: ./rebar3 ct
       - save_cache:
           key: dialyzer-cache-v2-{{ .Branch }}-{{ .Revision }}
           paths:

.gitignore

@@ -1,5 +1,5 @@
 .rebar3
-_*
+_[^_]*
 .eunit
 *.o
 *.beam
@@ -16,3 +16,6 @@ _build
 .idea
 *.iml
 rebar3.crashdump
+*.erl~
+*.aes~
+aesophia

CHANGELOG.md

@@ -0,0 +1,111 @@
+# Changelog
+All notable changes to this project will be documented in this file.
+
+The format is based on [Keep a Changelog](https://keepachangelog.com/en/1.0.0/),
+and this project adheres to [Semantic Versioning](https://semver.org/spec/v2.0.0.html).
+
+## [Unreleased]
+### Added
+### Changed
+### Removed
+
+## [3.2.0] - 2019-06-28
+### Added
+- New builtin function `require : (bool, string) => ()`. Defined as
+    ```
+    function require(b, err) = if(!b) abort(err)
+    ```
+- New builtin functions
+    ```
+    Bytes.to_str : bytes(_) => string
+    Bytes.to_int : bytes(_) => int
+    ```
+  for converting a byte array to a hex string and interpreting it as a
+  big-endian encoded integer respectively.
+### Changed
+- Public contract functions must now be declared as *entrypoints*:
+  ```
+  contract Example =
+    // Exported
+    entrypoint exported_fun(x) = local_fun(x)
+    // Not exported
+    function local_fun(x) = x
+  ```
+  Functions in namespaces still use `function` (and `private function` for
+  private functions).
+- The return type of `Chain.block_hash(height)` has changed, it used to
+  be `int`, where `0` denoted an incorrect height. New return type is
+  `option(hash)`, where `None` represents an incorrect height.
+- Event name hashes now use BLAKE2b instead of Keccak256.
+- Fixed bugs when defining record types in namespaces.
+- Fixed a bug in include path handling when passing options to the compiler.
+### Removed
+
+## [3.1.0] - 2019-06-03
+### Added
+### Changed
+- Keyword `indexed` is now optional for word typed (`bool`, `int`, `address`,
+  ...) event arguments.
+- State variable pretty printing now produce `'a, 'b, ...` instead of `'1, '2, ...`.
+- ACI is restructured and improved:
+    - `state` and `event` types (if present) now appear at the top level.
+    - Namespaces and remote interfaces are no longer ignored.
+    - All type definitions are included in the interface rendering.
+    - API functions are renamed, new functions are `contract_interface`
+      and `render_aci_json`.
+- Fixed a bug in `create_calldata`/`to_sophia_value` - it can now handle negative
+  literals.
+### Removed
+
+## [3.0.0] - 2019-05-21
+### Added
+- `stateful` annotations are now properly enforced. Functions must be marked stateful
+  in order to update the state or spend tokens.
+- Primitives `Contract.creator`, `Address.is_contract`, `Address.is_oracle`,
+  `Oracle.check` and `Oracle.check_query` has been added to Sophia.
+- A byte array type `bytes(N)` has been added to generalize `hash (== bytes(32))` and
+  `signature (== bytes(64))` and allow for byte arrays of arbitrary fixed length.
+- `Crypto.ecverify_secp256k1` has been added.
+### Changed
+- Address literals (+ Oracle, Oracle query and remote contracts) have been changed
+  from `#<hex>` to address as `ak_<base58check>`, oracle `ok_<base58check>`,
+  oracle query `oq_<base58check>` and remote contract `ct_<base58check>`.
+- The compilation and typechecking of `letfun` (e.g. `let m(f, xs) = map(f, xs)`) was
+  not working properly and has been fixed.
+### Removed
+- `let rec` has been removed from the language, it has never worked.
+- The standalone CLI compiler is served in the repo `aeternity/aesophia_cli` and has
+  been completely removed from `aesophia`.
+
+## [2.1.0] - 2019-04-11
+### Added
+- Stubs (not yet wired up) for compilation to FATE
+- Add functions specific for Calldata decoding
+- Support for `Auth.tx_hash`, not available in AEVM until Fortuna release
+
+### Changed
+- Improvements to the ACI generator
+
+## [2.0.0] - 2019-03-11
+### Added
+- Add `Crypto.ecverify` to the compiler.
+- Add `Crypto.sha3`, `Crypto.blake2`, `Crypto.sha256`, `String.blake2` and
+  `String.sha256` to the compiler.
+- Add the `bits` type for working with bit fields in Sophia.
+- Add Namespaces to Sophia in order to simplify using library contracts, etc.
+- Add a missig type check on the `init` function - detects programmer errors earlier.
+- Add the ACI (Aeternity Contract Interface) generator.
+
+### Changed
+- Use native bit shift operations in builtin functions, reducing gas cost.
+- Improve type checking of `record` fields - generates more understandable error messages.
+- Improved, more coherent, error messages.
+- Simplify calldata creation - instead of passing a compiled contract, simply
+  pass a (stubbed) contract string.
+
+[Unreleased]: https://github.com/aeternity/aesophia/compare/v3.2.0...HEAD
+[3.2.0]: https://github.com/aeternity/aesophia/compare/v3.1.0...v3.2.0
+[3.1.0]: https://github.com/aeternity/aesophia/compare/v3.0.0...v3.1.0
+[3.0.0]: https://github.com/aeternity/aesophia/compare/v2.1.0...v3.0.0
+[2.1.0]: https://github.com/aeternity/aesophia/compare/v2.0.0...v2.1.0
+[2.0.0]: https://github.com/aeternity/aesophia/tag/v2.0.0

README.md

@@ -5,6 +5,21 @@ This is the __sophia__ compiler for the æternity system which compiles contract
 For more information about æternity smart contracts and the sophia language see [Smart Contracts](https://github.com/aeternity/protocol/blob/master/contracts/contracts.md) and the [Sophia Language](https://github.com/aeternity/protocol/blob/master/contracts/sophia.md).
 
 It is an OTP application written in Erlang and is by default included in
-[æternity Epoch](https://github.com/aeternity/epoch). However, it can
-also be included in other system to compile contracts coded in sophia which
+[the æternity node](https://github.com/aeternity/epoch). However, it can
+also be included in other systems to compile contracts coded in sophia which
 can then be loaded into the æternity system.
+
+## Versioning
+
+`aesophia` has a version that is only loosely connected to the version of the
+Aeternity node - in principle they will share the major version but not
+minor/patch version. The `aesophia` compiler version MUST be bumped whenever
+there is a change in how byte code is generated, but it MAY also be bumped upon
+API changes etc.
+
+## Interface Modules
+
+The basic modules for interfacing the compiler:
+
+* [aeso_compiler: the Sophia compiler](./docs/aeso_compiler.md)
+* [aeso_aci: the ACI interface](./docs/aeso_aci.md)

docs/aeso_aci.md

@@ -0,0 +1,156 @@
+# aeso_aci
+
+### Module
+
+### aeso_aci
+
+The ACI interface encoder and decoder.
+
+### Description
+
+This module provides an interface to generate and convert between
+Sophia contracts and a suitable JSON encoding of contract
+interface. As yet the interface is very basic.
+
+Encoding this contract:
+
+```
+contract Answers =
+  record state = { a : answers }
+  type answers() = map(string, int)
+
+  stateful function init() = { a = {} }
+  private function the_answer() = 42
+  function new_answer(q : string, a : int) : answers() = { [q] = a }
+```
+
+generates the following JSON structure representing the contract interface:
+
+
+``` json
+{
+  "contract": {
+    "functions": [
+      {
+        "arguments": [],
+        "name": "init",
+        "returns": "Answers.state",
+        "stateful": true
+      },
+      {
+        "arguments": [
+          {
+            "name": "q",
+            "type": "string"
+          },
+          {
+            "name": "a",
+            "type": "int"
+          }
+        ],
+        "name": "new_answer",
+        "returns": {
+          "map": [
+            "string",
+            "int"
+          ]
+        },
+        "stateful": false
+      }
+    ],
+    "name": "Answers",
+    "state": {
+      "record": [
+        {
+          "name": "a",
+          "type": "Answers.answers"
+        }
+      ]
+    },
+    "type_defs": [
+      {
+        "name": "answers",
+        "typedef": {
+          "map": [
+            "string",
+            "int"
+          ]
+        },
+        "vars": []
+      }
+    ]
+  }
+}
+```
+
+When that encoding is decoded the following include definition is generated:
+
+```
+contract Answers =
+  record state = {a : Answers.answers}
+  type answers = map(string, int)
+  function init : () => Answers.state
+  function new_answer : (string, int) => map(string, int)
+```
+
+### Types
+```erlang
+-type aci_type()  :: json | string.
+-type json()      :: jsx:json_term().
+-type json_text() :: binary().
+```
+
+### Exports
+
+#### contract\_interface(aci\_type(), string()) -> {ok, json() | string()} | {error, term()}
+
+Generate the JSON encoding of the interface to a contract. The type definitions
+and non-private functions are included in the JSON string.
+
+#### render\_aci\_json(json() | json\_text()) -> string().
+
+Take a JSON encoding of a contract interface and generate a contract interface
+that can be included in another contract.
+
+### Example run
+
+This is an example of using the ACI generator from an Erlang shell. The file
+called `aci_test.aes` contains the contract in the description from which we
+want to generate files `aci_test.json` which is the JSON encoding of the
+contract interface and `aci_test.include` which is the contract definition to
+be included inside another contract.
+
+``` erlang
+1> {ok,Contract} = file:read_file("aci_test.aes").
+{ok,<<"contract Answers =\n  record state = { a : answers }\n  type answers() = map(string, int)\n\n  stateful function"...>>}
+2> {ok,JsonACI} = aeso_aci:contract_interface(json, Contract).
+{ok,[#{contract =>
+           #{functions =>
+                 [#{arguments => [],name => <<"init">>,
+                    returns => <<"Answers.state">>,stateful => true},
+                  #{arguments =>
+                        [#{name => <<"q">>,type => <<"string">>},
+                         #{name => <<"a">>,type => <<"int">>}],
+                    name => <<"new_answer">>,
+                    returns => #{<<"map">> => [<<"string">>,<<"int">>]},
+                    stateful => false}],
+             name => <<"Answers">>,
+             state =>
+                 #{record =>
+                       [#{name => <<"a">>,type => <<"Answers.answers">>}]},
+             type_defs =>
+                 [#{name => <<"answers">>,
+                    typedef => #{<<"map">> => [<<"string">>,<<"int">>]},
+                    vars => []}]}}]}
+3> file:write_file("aci_test.aci", jsx:encode(JsonACI)).
+ok
+4> {ok,InterfaceStub} = aeso_aci:render_aci_json(JsonACI).
+{ok,<<"contract Answers =\n  record state = {a : Answers.answers}\n  type answers = map(string, int)\n  function init "...>>}
+5> file:write_file("aci_test.include", InterfaceStub).
+ok
+6> jsx:prettify(jsx:encode(JsonACI)).
+<<"[\n  {\n    \"contract\": {\n      \"functions\": [\n        {\n          \"arguments\": [],\n          \"name\": \"init\",\n        "...>>
+```
+
+The final call to `jsx:prettify(jsx:encode(JsonACI))` returns the encoding in a
+more easily readable form. This is what is shown in the description above.

docs/aeso_compiler.md

@@ -0,0 +1,86 @@
+# aeso_compiler
+
+### Module
+
+### aeso_compiler
+
+The Sophia compiler
+
+### Description
+
+This module provides the interface to the standard Sophia compiler. It
+returns the compiled module in a map which can then be loaded.
+
+### Types
+``` erlang
+contract_string() = string() | binary()
+contract_map() = #{bytecode => binary(),
+                   compiler_version => binary(),
+                   contract_souce => string(),
+                   type_info => type_info()}
+type_info()
+errorstring() = binary()
+```
+### Exports
+
+#### file(File)
+#### file(File, Options) -> CompRet
+#### from_string(ContractString, Options) -> CompRet
+
+Types
+
+``` erlang
+ContractString = contract_string()
+Options = [Option]
+CompRet = {ok,ContractMap} | {error,ErrorString}
+ContractMap = contract_map()
+ErrorString = errorstring()
+```
+
+Compile a contract defined in a file or in a string.
+
+The **pp_** options all print to standard output the following:
+
+`pp_sophia_code` - print the input Sophia code.
+
+`pp_ast` - print the AST of the code
+
+`pp_types` - print information about the types
+
+`pp_typed_ast` - print the AST with type information at each node
+
+`pp_icode` - print the internal code structure
+
+`pp_assembler` - print the generated assembler code
+
+`pp_bytecode` - print the bytecode instructions
+
+#### check_call(ContractString, Options) -> CheckRet
+
+Types
+```
+ContractString = string() | binary()
+CheckRet = {ok,string(),{Types,Type | any()},Terms} | {error,Term}
+Types = [Type]
+Type = term()
+```
+Check a call in contract through the `__call` function.
+
+#### sophia_type_to_typerep(String) -> TypeRep
+
+Types
+``` erlang
+ {ok,TypeRep} | {error, badtype}
+```
+
+Get the type representation of a type declaration.
+
+#### version() -> {ok, Version} | {error, term()}
+
+Types
+
+``` erlang
+Version = binary()
+```
+
+Get the current version of the Sophia compiler.

include/aeso_heap.hrl

@@ -1,15 +0,0 @@
-
--record(pmap, {key_t  :: aeso_sophia:type(),
-               val_t  :: aeso_sophia:type(),
-               parent :: none | non_neg_integer(),
-               size   = 0 :: non_neg_integer(),
-               data   :: #{aeso_heap:binary_value() => aeso_heap:binary_value() | tombstone}
-                       | stored}).
-
--record(maps, { maps    = #{} :: #{ non_neg_integer() => #pmap{} }
-              , next_id = 0   :: non_neg_integer() }).
-
--record(heap, { maps   :: #maps{},
-                offset :: aeso_heap:offset(),
-                heap   :: binary() | #{non_neg_integer() => non_neg_integer()} }).
-

rebar.config

@@ -1,27 +1,24 @@
+%% -*- mode: erlang; indent-tabs-mode: nil -*-
+
 {erl_opts, [debug_info]}.
 
-{deps, [ {aebytecode, {git, "https://github.com/aeternity/aebytecode.git",
-                            {ref,"99bf097"}}}
+{deps, [ {aebytecode, {git, "https://github.com/aeternity/aebytecode.git", {ref,"c63ac88"}}}
        , {getopt, "1.0.1"}
+       , {eblake2, "1.0.0"}
+       , {jsx, {git, "https://github.com/talentdeficit/jsx.git",
+                     {tag, "2.8.0"}}}
        ]}.
 
-{escript_incl_apps, [aesophia, aebytecode, getopt]}.
-{escript_main_app, aesophia}.
-{escript_name, aesophia}.
-{escript_emu_args, "%%! +sbtu +A0\n"}.
-{provider_hooks, [{post, [{compile, escriptize}]}]}.
-
-{post_hooks, [{"(linux|darwin|solaris|freebsd|netbsd|openbsd)",
-               escriptize,
-               "cp \"$REBAR_BUILD_DIR/bin/aesophia\" ./aesophia"},
-              {"win32",
-               escriptize,
-               "robocopy \"%REBAR_BUILD_DIR%/bin/\" ./ aesophia* "
-               "/njs /njh /nfl /ndl & exit /b 0"} % silence things
-             ]}.
-
 {dialyzer, [
             {warnings, [unknown]},
             {plt_apps, all_deps},
             {base_plt_apps, [erts, kernel, stdlib, crypto, mnesia]}
            ]}.
+
+{relx, [{release, {aesophia, "3.2.0"},
+         [aesophia, aebytecode, getopt]},
+
+        {dev_mode, true},
+        {include_erts, false},
+
+        {extended_start_script, true}]}.

rebar.lock

@@ -1,10 +1,24 @@
 {"1.1.0",
 [{<<"aebytecode">>,
   {git,"https://github.com/aeternity/aebytecode.git",
-       {ref,"99bf097759dedbe7553f87a796bc7e1c7322e64b"}},
+       {ref,"c63ac888dd71c305cbc6d4f70953a176bf1f78f7"}},
   0},
- {<<"getopt">>,{pkg,<<"getopt">>,<<"1.0.1">>},0}]}.
+ {<<"aeserialization">>,
+  {git,"https://github.com/aeternity/aeserialization.git",
+       {ref,"816bf994ffb5cee218c3f22dc5fea296c9e0882e"}},
+  1},
+ {<<"base58">>,
+  {git,"https://github.com/aeternity/erl-base58.git",
+       {ref,"60a335668a60328a29f9731b67c4a0e9e3d50ab6"}},
+  2},
+ {<<"eblake2">>,{pkg,<<"eblake2">>,<<"1.0.0">>},0},
+ {<<"getopt">>,{pkg,<<"getopt">>,<<"1.0.1">>},0},
+ {<<"jsx">>,
+  {git,"https://github.com/talentdeficit/jsx.git",
+       {ref,"3074d4865b3385a050badf7828ad31490d860df5"}},
+  0}]}.
 [
 {pkg_hash,[
+ {<<"eblake2">>, <<"EC8AD20E438AAB3F2E8D5D118C366A0754219195F8A0F536587440F8F9BCF2EF">>},
  {<<"getopt">>, <<"C73A9FA687B217F2FF79F68A3B637711BB1936E712B521D8CE466B29CBF7808A">>}]}
 ].

src/aeso_abi.erl

@@ -1,239 +0,0 @@
-%%%-------------------------------------------------------------------
-%%% @copyright (C) 2017, Aeternity Anstalt
-%%% @doc
-%%%     Encode and decode data and function calls according to
-%%%     Sophia-AEVM-ABI.
-%%% @end
-%%% Created : 25 Jan 2018
-%%%
-%%%-------------------------------------------------------------------
--module(aeso_abi).
--define(HASH_SIZE, 32).
-
--export([ old_create_calldata/3
-        , create_calldata/5
-        , check_calldata/2
-        , function_type_info/3
-        , function_type_hash/3
-        , arg_typerep_from_function/2
-        , type_hash_from_function_name/2
-        , typereps_from_type_hash/2
-        , function_name_from_type_hash/2
-        , get_function_hash_from_calldata/1
-        ]).
-
--type hash() :: <<_:256>>. %% 256 = ?HASH_SIZE * 8.
--type function_name() :: binary(). %% String
--type typerep() :: aeso_sophia:type().
--type function_type_info() :: { FunctionHash :: hash()
-                              , FunctionName :: function_name()
-                              , ArgType      :: binary() %% binary typerep
-                              , OutType      :: binary() %% binary typerep
-                              }.
--type type_info() :: [function_type_info()].
-
-%%%===================================================================
-%%% API
-%%%===================================================================
-
-%%%===================================================================
-%%% Handle calldata
-
-create_calldata(Contract, FunName, Args, ArgTypes, RetType) ->
-    case get_type_info_and_hash(Contract, FunName) of
-        {ok, TypeInfo, TypeHashInt} ->
-            Data = aeso_heap:to_binary({TypeHashInt, list_to_tuple(Args)}),
-            case check_calldata(Data, TypeInfo) of
-                {ok, CallDataType, OutType} ->
-                    case check_given_type(FunName, ArgTypes, RetType, CallDataType, OutType) of
-                        ok ->
-                            {ok, Data, CallDataType, OutType};
-                        {error, _} = Err ->
-                            Err
-                    end;
-                {error,_What} = Err -> Err
-            end;
-        {error, _} = Err -> Err
-    end.
-
-get_type_info_and_hash(#{type_info := TypeInfo}, FunName) ->
-    FunBin = list_to_binary(FunName),
-    case type_hash_from_function_name(FunBin, TypeInfo) of
-        {ok, <<TypeHashInt:?HASH_SIZE/unit:8>>} -> {ok, TypeInfo, TypeHashInt};
-        {ok, _}                   -> {error, bad_type_hash};
-        {error, _} = Err          -> Err
-    end.
-
-%% Check that the given type matches the type from the metadata.
-check_given_type(FunName, GivenArgs, GivenRet, CalldataType, ExpectRet) ->
-    {tuple, [word, {tuple, ExpectArgs}]} = CalldataType,
-    ReturnOk = if FunName == "init" -> true;
-                  GivenRet == any   -> true;
-                  true              -> GivenRet == ExpectRet
-               end,
-    ArgsOk   = ExpectArgs == GivenArgs,
-    case ReturnOk andalso ArgsOk of
-        true -> ok;
-        false when FunName == "init" ->
-            {error, {init_args_mismatch,
-                        {given,    GivenArgs},
-                        {expected, ExpectArgs}}};
-        false ->
-            {error, {call_type_mismatch,
-                        {given,    GivenArgs,  '=>', GivenRet},
-                        {expected, ExpectArgs, '=>', ExpectRet}}}
-    end.
-
--spec check_calldata(binary(), type_info()) ->
-                        {'ok', typerep(), typerep()} | {'error', atom()}.
-check_calldata(CallData, TypeInfo) ->
-    %% The first element of the CallData should be the function name
-    case get_function_hash_from_calldata(CallData) of
-        {ok, Hash} ->
-            case typereps_from_type_hash(Hash, TypeInfo) of
-                {ok, ArgType, OutType} ->
-                    try aeso_heap:from_binary({tuple, [word, ArgType]}, CallData) of
-                        {ok, _Something} ->
-                            {ok, {tuple, [word, ArgType]}, OutType};
-                        {error, _} ->
-                            {error, bad_call_data}
-                    catch
-                        _T:_E ->
-                            {error, bad_call_data}
-                    end;
-                {error, _} ->
-                    {error, unknown_function}
-            end;
-        {error, _What} ->
-            {error, bad_call_data}
-    end.
-
--spec get_function_hash_from_calldata(CallData::binary()) ->
-                                             {ok, binary()} | {error, term()}.
-get_function_hash_from_calldata(CallData) ->
-    case aeso_heap:from_binary({tuple, [word]}, CallData) of
-        {ok, {HashInt}} -> {ok, <<HashInt:?HASH_SIZE/unit:8>>};
-        {error, _} = Error -> Error
-    end.
-
-%%%===================================================================
-%%% Handle type info from contract meta data
-
--spec function_type_info(function_name(), [typerep()], typerep()) ->
-                            function_type_info().
-function_type_info(Name, Args, OutType) ->
-    ArgType = {tuple, [T || {_, T} <- Args]},
-    { function_type_hash(Name, ArgType, OutType)
-    , Name
-    , aeso_heap:to_binary(ArgType)
-    , aeso_heap:to_binary(OutType)
-    }.
-
--spec function_type_hash(function_name(), typerep(), typerep()) -> hash().
-function_type_hash(Name, ArgType, OutType) when is_binary(Name) ->
-    Bin =  iolist_to_binary([ Name
-                            , aeso_heap:to_binary(ArgType)
-                            , aeso_heap:to_binary(OutType)
-                            ]),
-    %% Calculate a 256 bit digest BLAKE2b hash value of a binary
-    {ok, Hash} = aeso_blake2:blake2b(?HASH_SIZE, Bin),
-    Hash.
-
--spec arg_typerep_from_function(function_name(), type_info()) ->
-           {'ok', typerep()} | {'error', 'bad_type_data' | 'unknown_function'}.
-arg_typerep_from_function(Function, TypeInfo) ->
-    case lists:keyfind(Function, 2, TypeInfo) of
-        {_TypeHash, Function, ArgTypeBin,_OutTypeBin} ->
-            case aeso_heap:from_binary(typerep, ArgTypeBin) of
-                {ok, ArgType} -> {ok, ArgType};
-                {error,_} -> {error, bad_type_data}
-            end;
-        false ->
-            {error, unknown_function}
-    end.
-
--spec typereps_from_type_hash(hash(), type_info()) ->
-           {'ok', typerep(), typerep()} | {'error', 'bad_type_data' | 'unknown_function'}.
-typereps_from_type_hash(TypeHash, TypeInfo) ->
-    case lists:keyfind(TypeHash, 1, TypeInfo) of
-        {TypeHash,_Function, ArgTypeBin, OutTypeBin} ->
-            case {aeso_heap:from_binary(typerep, ArgTypeBin),
-                  aeso_heap:from_binary(typerep, OutTypeBin)} of
-                {{ok, ArgType}, {ok, OutType}} -> {ok, ArgType, OutType};
-                {_, _} -> {error, bad_type_data}
-            end;
-        false ->
-            {error, unknown_function}
-    end.
-
--spec function_name_from_type_hash(hash(), type_info()) ->
-                                          {'ok', function_name()}
-                                        | {'error', 'unknown_function'}.
-function_name_from_type_hash(TypeHash, TypeInfo) ->
-    case lists:keyfind(TypeHash, 1, TypeInfo) of
-        {TypeHash, Function,_ArgTypeBin,_OutTypeBin} ->
-            {ok, Function};
-        false ->
-            {error, unknown_function}
-    end.
-
--spec type_hash_from_function_name(function_name(), type_info()) ->
-                                          {'ok', hash()}
-                                        | {'error', 'unknown_function'}.
-type_hash_from_function_name(Name, TypeInfo) ->
-    case lists:keyfind(Name, 2, TypeInfo) of
-        {TypeHash, Name,_ArgTypeBin,_OutTypeBin} ->
-            {ok, TypeHash};
-        false ->
-            {error, unknown_function}
-    end.
-
-%% -- Old calldata creation. Kept for backwards compatibility. ---------------
-
-old_create_calldata(Contract, Function, Argument) when is_map(Contract) ->
-    case aeso_constants:string(Argument) of
-        {ok, {tuple, _, _} = Tuple} ->
-            old_encode_call(Contract, Function, Tuple);
-        {ok, {unit, _} = Tuple} ->
-            old_encode_call(Contract, Function, Tuple);
-        {ok, ParsedArgument} ->
-            %% The Sophia compiler does not parse a singleton tuple (42) as a tuple,
-            %% Wrap it in a tuple.
-            old_encode_call(Contract, Function, {tuple, [], [ParsedArgument]});
-        {error, _} ->
-            {error, argument_syntax_error}
-    end.
-
-%% Call takes one arument.
-%% Use a tuple to pass multiple arguments.
-old_encode_call(Contract, Function, ArgumentAst) ->
-    Argument = old_ast_to_erlang(ArgumentAst),
-    case get_type_info_and_hash(Contract, Function) of
-        {ok, TypeInfo, TypeHashInt} ->
-            Data = aeso_heap:to_binary({TypeHashInt, Argument}),
-            case check_calldata(Data, TypeInfo) of
-                {ok, CallDataType, OutType} ->
-                    {ok, Data, CallDataType, OutType};
-                {error, _} = Err ->
-                    Err
-            end;
-        {error, _} = Err -> Err
-    end.
-
-old_ast_to_erlang({int, _, N}) -> N;
-old_ast_to_erlang({hash, _, <<N:?HASH_SIZE/unit:8>>}) -> N;
-old_ast_to_erlang({hash, _, <<Hi:256, Lo:256>>}) -> {Hi, Lo};    %% signature
-old_ast_to_erlang({bool, _, true}) -> 1;
-old_ast_to_erlang({bool, _, false}) -> 0;
-old_ast_to_erlang({string, _, Bin}) -> Bin;
-old_ast_to_erlang({unit, _}) -> {};
-old_ast_to_erlang({con, _, "None"}) -> none;
-old_ast_to_erlang({app, _, {con, _, "Some"}, [A]}) -> {some, old_ast_to_erlang(A)};
-old_ast_to_erlang({tuple, _, Elems}) ->
-    list_to_tuple(lists:map(fun old_ast_to_erlang/1, Elems));
-old_ast_to_erlang({list, _, Elems}) ->
-    lists:map(fun old_ast_to_erlang/1, Elems);
-old_ast_to_erlang({map, _, Elems}) ->
-    maps:from_list([ {old_ast_to_erlang(element(1, Elem)), old_ast_to_erlang(element(2, Elem))}
-                        || Elem <- Elems ]).
-

src/aeso_aci.erl

@@ -0,0 +1,357 @@
+%%%-------------------------------------------------------------------
+%%% @author Robert Virding
+%%% @copyright (C) 2019, Aeternity Anstalt
+%%% @doc
+%%%     ACI interface
+%%% @end
+%%% Created : 12 Jan 2019
+%%%-------------------------------------------------------------------
+
+-module(aeso_aci).
+
+-export([ file/2
+        , file/3
+        , contract_interface/2
+        , contract_interface/3
+
+        , render_aci_json/1
+
+        , json_encode_expr/1
+        , json_encode_type/1]).
+
+-type aci_type()  :: json | string.
+-type json()      :: jsx:json_term().
+-type json_text() :: binary().
+
+%% External API
+-spec file(aci_type(), string()) -> {ok, json() | string()} | {error, term()}.
+file(Type, File) ->
+    file(Type, File, []).
+
+file(Type, File, Options0) ->
+    Options = aeso_compiler:add_include_path(File, Options0),
+    case file:read_file(File) of
+        {ok, BinCode} ->
+            do_contract_interface(Type, binary_to_list(BinCode), Options);
+        {error, _} = Err -> Err
+    end.
+
+-spec contract_interface(aci_type(), string()) ->
+    {ok, json() | string()} | {error, term()}.
+contract_interface(Type, ContractString) ->
+    contract_interface(Type, ContractString, []).
+
+-spec contract_interface(aci_type(), string(), [term()]) ->
+    {ok, json() | string()} | {error, term()}.
+contract_interface(Type, ContractString, CompilerOpts) ->
+    do_contract_interface(Type, ContractString, CompilerOpts).
+
+-spec render_aci_json(json() | json_text()) -> {ok, binary()}.
+render_aci_json(Json) ->
+    do_render_aci_json(Json).
+
+-spec json_encode_expr(aeso_syntax:expr()) -> json().
+json_encode_expr(Expr) ->
+    encode_expr(Expr).
+
+-spec json_encode_type(aeso_syntax:type()) -> json().
+json_encode_type(Type) ->
+    encode_type(Type).
+
+%% Internal functions
+do_contract_interface(Type, Contract, Options) when is_binary(Contract) ->
+    do_contract_interface(Type, binary_to_list(Contract), Options);
+do_contract_interface(Type, ContractString, Options) ->
+    try
+        Ast = aeso_compiler:parse(ContractString, Options),
+        %% io:format("~p\n", [Ast]),
+        TypedAst = aeso_ast_infer_types:infer(Ast, [dont_unfold]),
+        %% io:format("~p\n", [TypedAst]),
+        JArray = [ encode_contract(C) || C <- TypedAst ],
+
+        case Type of
+            json   -> {ok, JArray};
+            string -> do_render_aci_json(JArray)
+        end
+    catch
+        %% The compiler errors.
+        error:{parse_errors, Errors} ->
+            {error, join_errors("Parse errors", Errors, fun(E) -> E end)};
+        error:{type_errors, Errors} ->
+            {error, join_errors("Type errors", Errors, fun(E) -> E end)};
+        error:{code_errors, Errors} ->
+            {error, join_errors("Code errors", Errors,
+                                fun (E) -> io_lib:format("~p", [E]) end)}
+        %% General programming errors in the compiler just signal error.
+    end.
+
+join_errors(Prefix, Errors, Pfun) ->
+    Ess = [ Pfun(E) || E <- Errors ],
+    list_to_binary(string:join([Prefix|Ess], "\n")).
+
+encode_contract(Contract = {contract, _, {con, _, Name}, _}) ->
+    C0 = #{name => encode_name(Name)},
+
+    Tdefs0 = [ encode_typedef(T) || T <- sort_decls(contract_types(Contract)) ],
+    FilterT = fun(N) -> fun(#{name := N1}) -> N == N1 end end,
+    {Es, Tdefs1} = lists:partition(FilterT(<<"event">>), Tdefs0),
+    {Ss, Tdefs}  = lists:partition(FilterT(<<"state">>), Tdefs1),
+
+    C1 = C0#{type_defs => Tdefs},
+
+    C2 = case Es of
+             []                 -> C1;
+             [#{typedef := ET}] -> C1#{event => ET}
+         end,
+
+    C3 = case Ss of
+             []                 -> C2;
+             [#{typedef := ST}] -> C2#{state => ST}
+         end,
+
+    Fdefs  = [ encode_function(F)
+               || F <- sort_decls(contract_funcs(Contract)),
+                  is_entrypoint(F) ],
+
+    #{contract => C3#{functions => Fdefs}};
+encode_contract(Namespace = {namespace, _, {con, _, Name}, _}) ->
+    Tdefs = [ encode_typedef(T) || T <- sort_decls(contract_types(Namespace)) ],
+    #{namespace => #{name => encode_name(Name),
+                     type_defs => Tdefs}}.
+
+%%  Encode a function definition. Currently we are only interested in
+%%  the interface and type.
+encode_function(FDef = {letfun, _, {id, _, Name}, Args, Type, _}) ->
+    #{name      => encode_name(Name),
+      arguments => encode_args(Args),
+      returns   => encode_type(Type),
+      stateful  => is_stateful(FDef)};
+encode_function(FDecl = {fun_decl, _, {id, _, Name}, {fun_t, _, _, Args, Type}}) ->
+    #{name      => encode_name(Name),
+      arguments => encode_anon_args(Args),
+      returns   => encode_type(Type),
+      stateful  => is_stateful(FDecl)}.
+
+encode_anon_args(Types) ->
+    Anons = [ list_to_binary("_" ++ integer_to_list(X)) || X <- lists:seq(1, length(Types))],
+    [ #{name => V, type => encode_type(T)}
+      || {V, T} <- lists:zip(Anons, Types) ].
+
+encode_args(Args) -> [ encode_arg(A) || A <- Args ].
+
+encode_arg({arg, _, Id, T}) ->
+    #{name => encode_type(Id),
+      type => encode_type(T)}.
+
+encode_typedef(Type) ->
+    Name = typedef_name(Type),
+    Vars = typedef_vars(Type),
+    Def  = typedef_def(Type),
+    #{name    => encode_name(Name),
+      vars    => encode_tvars(Vars),
+      typedef => encode_type(Def)}.
+
+encode_tvars(Vars) ->
+    [ #{name => encode_type(V)} || V <- Vars ].
+
+%% Encode type
+encode_type({tvar, _, N})         -> encode_name(N);
+encode_type({id, _, N})           -> encode_name(N);
+encode_type({con, _, N})          -> encode_name(N);
+encode_type({qid, _, Ns})         -> encode_name(lists:join(".", Ns));
+encode_type({qcon, _, Ns})        -> encode_name(lists:join(".", Ns));
+encode_type({tuple_t, _, As})     -> #{tuple => encode_types(As)};
+encode_type({bytes_t, _, Len})    -> #{bytes => Len};
+encode_type({record_t, Fs})       -> #{record => encode_type_fields(Fs)};
+encode_type({app_t, _, Id, Fs})   -> #{encode_type(Id) => encode_types(Fs)};
+encode_type({variant_t, Cs})      -> #{variant => encode_types(Cs)};
+encode_type({constr_t, _, C, As}) -> #{encode_type(C) => encode_types(As)};
+encode_type({alias_t, Type})      -> encode_type(Type);
+encode_type({fun_t, _, _, As, T}) -> #{function =>
+                                         #{arguments => encode_types(As),
+                                           returns => encode_type(T)}}.
+
+encode_types(Ts) -> [ encode_type(T) || T <- Ts ].
+
+encode_type_fields(Fs) -> [ encode_type_field(F) || F <- Fs ].
+
+encode_type_field({field_t, _, Id, T}) ->
+    #{name => encode_type(Id),
+      type => encode_type(T)}.
+
+encode_name(Name) when is_list(Name) ->
+    list_to_binary(Name);
+encode_name(Name) when is_binary(Name) ->
+    Name.
+
+%% Encode Expr
+encode_exprs(Es) -> [ encode_expr(E) || E <- Es ].
+
+encode_expr({id, _, N})     -> encode_name(N);
+encode_expr({con, _, N})    -> encode_name(N);
+encode_expr({qid, _, Ns})   -> encode_name(lists:join(".", Ns));
+encode_expr({qcon, _, Ns})  -> encode_name(lists:join(".", Ns));
+encode_expr({typed, _, E})  -> encode_expr(E);
+encode_expr({bool, _, B})   -> B;
+encode_expr({int, _, V})    -> V;
+encode_expr({string, _, S}) -> S;
+encode_expr({tuple, _, As}) -> encode_exprs(As);
+encode_expr({list, _, As})  -> encode_exprs(As);
+encode_expr({bytes, _, B})  ->
+    Digits = byte_size(B),
+    <<N:Digits/unit:8>> = B,
+    list_to_binary(lists:flatten(io_lib:format("#~*.16.0b", [Digits*2, N])));
+encode_expr({Lit, _, L}) when Lit == oracle_pubkey; Lit == oracle_query_id;
+                              Lit == contract_pubkey; Lit == account_pubkey ->
+    aeser_api_encoder:encode(Lit, L);
+encode_expr({app, _, F, As}) ->
+    Ef = encode_expr(F),
+    Eas = encode_exprs(As),
+    #{Ef => Eas};
+encode_expr({record, _, Flds}) -> maps:from_list(encode_fields(Flds));
+encode_expr({map, _, KVs})     -> [ [encode_expr(K), encode_expr(V)] || {K, V} <- KVs ];
+encode_expr({Op,_Ann}) ->
+    error({encode_expr_todo, Op}).
+
+encode_fields(Flds) -> [ encode_field(F) || F <- Flds ].
+
+encode_field({field, _, [{proj, _, {id, _, Fld}}], Val}) ->
+    {encode_name(Fld), encode_expr(Val)}.
+
+do_render_aci_json(Json) ->
+    Contracts =
+        case Json of
+            JArray when is_list(JArray)  -> JArray;
+            JObject when is_map(JObject) -> [JObject];
+            JText when is_binary(JText)  ->
+                case jsx:decode(Json, [{labels, atom}, return_maps]) of
+                    JArray when is_list(JArray)  -> JArray;
+                    JObject when is_map(JObject) -> [JObject];
+                    _                            -> error(bad_aci_json)
+                end
+        end,
+    DecodedContracts = [ decode_contract(C) || C <- Contracts ],
+    {ok, list_to_binary(string:join(DecodedContracts, "\n"))}.
+
+decode_contract(#{contract := #{name := Name,
+                                type_defs := Ts0,
+                                functions := Fs} = C}) ->
+    MkTDef = fun(N, T) -> #{name => N, vars => [], typedef => T} end,
+    Ts = [ MkTDef(<<"state">>, maps:get(state, C)) || maps:is_key(state, C) ] ++
+         [ MkTDef(<<"event">>, maps:get(event, C)) || maps:is_key(event, C) ] ++ Ts0,
+    ["contract ", io_lib:format("~s", [Name])," =\n",
+     decode_tdefs(Ts), decode_funcs(Fs)];
+decode_contract(#{namespace := #{name := Name, type_defs := Ts}}) when Ts /= [] ->
+    ["namespace ", io_lib:format("~s", [Name])," =\n",
+     decode_tdefs(Ts)];
+decode_contract(_) -> [].
+
+decode_funcs(Fs) -> [ decode_func(F) || F <- Fs ].
+
+%% decode_func(#{name := init}) -> [];
+decode_func(#{name := Name, arguments := As, returns := T}) ->
+    ["  entrypoint", " ", io_lib:format("~s", [Name]), " : ",
+     decode_args(As), " => ", decode_type(T), $\n].
+
+decode_args(As) ->
+    Das = [ decode_arg(A) || A <- As ],
+    [$(,lists:join(", ", Das),$)].
+
+decode_arg(#{type := T}) -> decode_type(T).
+
+decode_types(Ets) ->
+    [ decode_type(Et) || Et <- Ets ].
+
+decode_type(#{tuple := Ets}) ->
+    Ts = decode_types(Ets),
+    [$(,lists:join(",", Ts),$)];
+decode_type(#{record := Efs}) ->
+    Fs = decode_fields(Efs),
+    [${,lists:join(",", Fs),$}];
+decode_type(#{list := [Et]}) ->
+    T = decode_type(Et),
+    ["list",$(,T,$)];
+decode_type(#{map := Ets}) ->
+    Ts = decode_types(Ets),
+    ["map",$(,lists:join(",", Ts),$)];
+decode_type(#{bytes := Len}) ->
+    ["bytes(", integer_to_list(Len), ")"];
+decode_type(#{variant := Ets}) ->
+    Ts = decode_types(Ets),
+    lists:join(" | ", Ts);
+decode_type(#{function := #{arguments := Args, returns := R}}) ->
+    [decode_type(#{tuple => Args}), " => ", decode_type(R)];
+decode_type(Econs) when is_map(Econs) ->	%General constructor
+    [{Ec,Ets}] = maps:to_list(Econs),
+    AppName = decode_name(Ec),
+    AppArgs = decode_types(Ets),
+    case AppArgs of
+        [] -> [AppName];
+        _  -> [AppName,$(,lists:join(", ", AppArgs),$)]
+    end;
+decode_type(T) ->				%Just raw names.
+    decode_name(T).
+
+decode_name(En) when is_atom(En)   -> erlang:atom_to_list(En);
+decode_name(En) when is_binary(En) -> binary_to_list(En).
+
+decode_fields(Efs) ->
+    [ decode_field(Ef) || Ef <- Efs ].
+
+decode_field(#{name := En, type := Et}) ->
+    Name = decode_name(En),
+    Type = decode_type(Et),
+    [Name," : ",Type].
+
+%% decode_tdefs(Json) -> [TypeString].
+%%  Here we are only interested in the type definitions and ignore the
+%%  aliases. We find them as they always have variants.
+
+decode_tdefs(Ts) -> [ decode_tdef(T) || T <- Ts ].
+
+decode_tdef(#{name := Name, vars := Vs, typedef := T}) ->
+    TypeDef = decode_type(T),
+    DefType = decode_deftype(T),
+    ["  ", DefType, " ", decode_name(Name), decode_tvars(Vs), " = ", TypeDef, $\n].
+
+decode_deftype(#{record := _Efs}) -> "record";
+decode_deftype(#{variant := _})   -> "datatype";
+decode_deftype(_T)                      -> "type".
+
+decode_tvars([]) -> [];                         %No tvars, no parentheses
+decode_tvars(Vs) ->
+    Dvs = [ decode_tvar(V) || V <- Vs ],
+    [$(,lists:join(", ", Dvs),$)].
+
+decode_tvar(#{name := N}) -> io_lib:format("~s", [N]).
+
+%% #contract{Ann, Con, [Declarations]}.
+
+contract_funcs({C, _, _, Decls}) when C == contract; C == namespace ->
+    [ D || D <- Decls, is_fun(D)].
+
+contract_types({C, _, _, Decls}) when C == contract; C == namespace ->
+    [ D || D <- Decls, is_type(D) ].
+
+is_fun({letfun, _, _, _, _, _}) -> true;
+is_fun({fun_decl, _, _, _})     -> true;
+is_fun(_)                       -> false.
+
+is_type({type_def, _, _, _, _}) -> true;
+is_type(_)                      -> false.
+
+sort_decls(Ds) ->
+    Sort = fun (D1, D2) ->
+                   aeso_syntax:get_ann(line, D1, 0) =<
+                       aeso_syntax:get_ann(line, D2, 0)
+           end,
+    lists:sort(Sort, Ds).
+
+is_entrypoint(Node) -> aeso_syntax:get_ann(entrypoint, Node, false).
+is_stateful(Node) -> aeso_syntax:get_ann(stateful, Node, false).
+
+typedef_name({type_def, _, {id, _, Name}, _, _}) -> Name.
+
+typedef_vars({type_def, _, _, Vars, _}) -> Vars.
+
+typedef_def({type_def, _, _, _, Def}) -> Def.

src/aeso_ast.erl

@@ -17,11 +17,11 @@ line({symbol, Line, _}) -> Line.
 symbol_name({symbol, _, Name}) -> Name.
 
 pp(Ast) ->
-    %% TODO: Actually do *Pretty* printing.
-    io:format("~p~n", [Ast]).
+    String = prettypr:format(aeso_pretty:decls(Ast, [])),
+    io:format("Ast:\n~s\n", [String]).
 
 pp_typed(TypedAst) ->
+    %% io:format("Typed tree:\n~p\n",[TypedAst]),
     String = prettypr:format(aeso_pretty:decls(TypedAst, [show_generated])),
-    %%io:format("Typed tree:\n~p\n",[TypedAst]),
-    io:format("Type info:\n~s\n",[String]).
+    io:format("Type ast:\n~s\n",[String]).
 

src/aeso_ast_to_icode.erl

@@ -17,11 +17,19 @@
 
 -spec convert_typed(aeso_syntax:ast(), list()) -> aeso_icode:icode().
 convert_typed(TypedTree, Options) ->
-    code(TypedTree, aeso_icode:new(Options)).
+    Name = case lists:last(TypedTree) of
+               {contract, _, {con, _, Con}, _} -> Con;
+               _ -> gen_error(last_declaration_must_be_contract)
+           end,
+    Icode = code(TypedTree, aeso_icode:set_name(Name, aeso_icode:new(Options))),
+    deadcode_elimination(Icode).
 
-code([{contract, _Attribs, {con, _, Name}, Code}|Rest], Icode) ->
-    NewIcode = contract_to_icode(Code,
-                                 aeso_icode:set_name(Name, Icode)),
+code([{contract, _Attribs, Con, Code}|Rest], Icode) ->
+    NewIcode = contract_to_icode(Code, aeso_icode:set_namespace(Con, Icode)),
+    code(Rest, NewIcode);
+code([{namespace, _Ann, Name, Code}|Rest], Icode) ->
+                                            %% TODO: nested namespaces
+    NewIcode = contract_to_icode(Code, aeso_icode:set_namespace(Name, Icode)),
     code(Rest, NewIcode);
 code([], Icode) ->
     add_default_init_function(add_builtins(Icode)).
@@ -33,30 +41,38 @@ gen_error(Error) ->
 
 %% Create default init function (only if state is unit).
 add_default_init_function(Icode = #{functions := Funs, state_type := State}) ->
-    case lists:keymember("init", 1, Funs) of
+    {_, _, QInit} = aeso_icode:qualify({id, [], "init"}, Icode),
+    case lists:keymember(QInit, 1, Funs) of
         true -> Icode;
-        false when State /= {tuple, []} -> gen_error(missing_init_function);
+        false when State /= {tuple, []} ->
+            gen_error(missing_init_function);
         false ->
             Type  = {tuple, [typerep, {tuple, []}]},
             Value = #tuple{ cpts = [type_value({tuple, []}), {tuple, []}] },
-            DefaultInit = {"init", [], [], Value, Type},
+            DefaultInit = {QInit, [], [], Value, Type},
             Icode#{ functions => [DefaultInit | Funs] }
     end.
 
 -spec contract_to_icode(aeso_syntax:ast(), aeso_icode:icode()) ->
                                aeso_icode:icode().
-contract_to_icode([{type_def, _Attrib, {id, _, Name}, Args, Def} | Rest],
+contract_to_icode([{namespace, _, Name, Defs} | Rest], Icode) ->
+    NS = aeso_icode:get_namespace(Icode),
+    Icode1 = contract_to_icode(Defs, aeso_icode:enter_namespace(Name, Icode)),
+    contract_to_icode(Rest, aeso_icode:set_namespace(NS, Icode1));
+contract_to_icode([{type_def, _Attrib, Id = {id, _, Name}, Args, Def} | Rest],
                   Icode = #{ types := Types, constructors := Constructors }) ->
     TypeDef = make_type_def(Args, Def, Icode),
     NewConstructors =
         case Def of
             {variant_t, Cons} ->
                 Tags = lists:seq(0, length(Cons) - 1),
-                GetName = fun({constr_t, _, {con, _, C}, _}) -> C end,
-                maps:from_list([ {GetName(Con), Tag} || {Tag, Con} <- lists:zip(Tags, Cons) ]);
+                GetName = fun({constr_t, _, C, _}) -> C end,
+                QName = fun(Con) -> {_, _, Xs} = aeso_icode:qualify(GetName(Con), Icode), Xs end,
+                maps:from_list([ {QName(Con), Tag} || {Tag, Con} <- lists:zip(Tags, Cons) ]);
             _ -> #{}
         end,
-    Icode1 = Icode#{ types := Types#{ Name => TypeDef },
+    {_, _, TName} = aeso_icode:qualify(Id, Icode),
+    Icode1 = Icode#{ types := Types#{ TName => TypeDef },
                      constructors := maps:merge(Constructors, NewConstructors) },
     Icode2 = case Name of
                 "state" when Args == [] -> Icode1#{ state_type => ast_typerep(Def, Icode) };
@@ -68,8 +84,7 @@ contract_to_icode([{type_def, _Attrib, {id, _, Name}, Args, Def} | Rest],
     contract_to_icode(Rest, Icode2);
 contract_to_icode([{letfun, Attrib, Name, Args, _What, Body={typed,_,_,T}}|Rest], Icode) ->
     FunAttrs = [ stateful || proplists:get_value(stateful, Attrib, false) ] ++
-               [ private  || proplists:get_value(private, Attrib, false) orelse
-                             proplists:get_value(internal, Attrib, false) ],
+               [ private  || is_private(Attrib, Icode) ],
     %% TODO: Handle types
     FunName = ast_id(Name),
     %% TODO: push funname to env
@@ -84,21 +99,18 @@ contract_to_icode([{letfun, Attrib, Name, Args, _What, Body={typed,_,_,T}}|Rest]
                  {tuple, [typerep, ast_typerep(T, Icode)]}};
             _ -> {ast_body(Body, Icode), ast_typerep(T, Icode)}
         end,
-    NewIcode = ast_fun_to_icode(FunName, FunAttrs, FunArgs, FunBody, TypeRep, Icode),
+    QName    = aeso_icode:qualify(Name, Icode),
+    NewIcode = ast_fun_to_icode(ast_id(QName), FunAttrs, FunArgs, FunBody, TypeRep, Icode),
     contract_to_icode(Rest, NewIcode);
-contract_to_icode([{letrec,_,Defs}|Rest], Icode) ->
-    %% OBS! This code ignores the letrec structure of the source,
-    %% because the back end treats ALL declarations as recursive! We
-    %% need to decide whether to (a) modify the back end to respect
-    %% the letrec structure, or (b) (preferably) modify the front end
-    %% just to parse a list of (mutually recursive) definitions.
-    contract_to_icode(Defs++Rest, Icode);
 contract_to_icode([], Icode) -> Icode;
-contract_to_icode(_Code, Icode) ->
-    %% TODO debug output for debug("Unhandled code ~p~n",[Code]),
-    Icode.
+contract_to_icode([{fun_decl, _, _, _} | Code], Icode) ->
+    contract_to_icode(Code, Icode);
+contract_to_icode([Decl | Code], Icode) ->
+    io:format("Unhandled declaration: ~p\n", [Decl]),
+    contract_to_icode(Code, Icode).
 
-ast_id({id, _, Id}) -> Id.
+ast_id({id, _, Id}) -> Id;
+ast_id({qid, _, Id}) -> Id.
 
 ast_args([{arg, _, Name, Type}|Rest], Acc, Icode) ->
     ast_args(Rest, [{ast_id(Name), ast_type(Type, Icode)}| Acc], Icode);
@@ -121,7 +133,7 @@ ast_type(T, Icode) ->
 ast_body(?qid_app(["Chain","spend"], [To, Amount], _, _), Icode) ->
     prim_call(?PRIM_CALL_SPEND, ast_body(Amount, Icode), [ast_body(To, Icode)], [word], {tuple, []});
 
-ast_body(?qid_app(["Chain","event"], [Event], _, _), Icode) ->
+ast_body(?qid_app([Con, "Chain", "event"], [Event], _, _), Icode = #{ contract_name := Con }) ->
     aeso_builtins:check_event_type(Icode),
     builtin_call({event, maps:get(event_type, Icode)}, [ast_body(Event, Icode)]);
 
@@ -129,10 +141,11 @@ ast_body(?qid_app(["Chain","event"], [Event], _, _), Icode) ->
 ast_body(?qid_app(["Chain", "balance"], [Address], _, _), Icode) ->
     #prim_balance{ address = ast_body(Address, Icode) };
 ast_body(?qid_app(["Chain", "block_hash"], [Height], _, _), Icode) ->
-    #prim_block_hash{ height = ast_body(Height, Icode) };
+    builtin_call(block_hash, [ast_body(Height, Icode)]);
 ast_body(?qid_app(["Call", "gas_left"], [], _, _), _Icode) ->
     prim_gas_left;
 ast_body({qid, _, ["Contract", "address"]}, _Icode)      -> prim_contract_address;
+ast_body({qid, _, ["Contract", "creator"]}, _Icode)      -> prim_contract_creator;
 ast_body({qid, _, ["Contract", "balance"]}, _Icode)      -> #prim_balance{ address = prim_contract_address };
 ast_body({qid, _, ["Call",     "origin"]}, _Icode)       -> prim_call_origin;
 ast_body({qid, _, ["Call",     "caller"]}, _Icode)       -> prim_caller;
@@ -152,16 +165,22 @@ ast_body({qid, _, ["Chain", "spend"]}, _Icode) ->
     gen_error({underapplied_primitive, 'Chain.spend'});
 
 %% State
-ast_body({id, _, "state"}, _Icode) -> prim_state;
-ast_body(?id_app("put", [NewState], _, _), Icode) ->
+ast_body({qid, _, [Con, "state"]}, #{ contract_name := Con }) -> prim_state;
+ast_body(?qid_app([Con, "put"], [NewState], _, _), Icode = #{ contract_name := Con }) ->
     #prim_put{ state = ast_body(NewState, Icode) };
-ast_body({id, _, "put"}, _Icode) ->
+ast_body({qid, _, [Con, "put"]}, #{ contract_name := Con }) ->
     gen_error({underapplied_primitive, put});   %% TODO: eta
 
 %% Abort
 ast_body(?id_app("abort", [String], _, _), Icode) ->
-    #funcall{ function = #var_ref{ name = {builtin, abort} },
-              args     = [ast_body(String, Icode)] };
+    builtin_call(abort, [ast_body(String, Icode)]);
+ast_body(?id_app("require", [Bool, String], _, _), Icode) ->
+    builtin_call(require, [ast_body(Bool, Icode), ast_body(String, Icode)]);
+
+%% Authentication
+ast_body({qid, _, ["Auth", "tx_hash"]}, _Icode) ->
+    prim_call(?PRIM_CALL_AUTH_TX_HASH, #integer{value = 0},
+              [], [], aeso_icode:option_typerep(word));
 
 %% Oracles
 ast_body(?qid_app(["Oracle", "register"], Args, _, ?oracle_t(QType, RType)), Icode) ->
@@ -200,6 +219,17 @@ ast_body(?qid_app(["Oracle", "get_answer"], [Oracle, Q], [_, ?query_t(_, RType)]
     prim_call(?PRIM_CALL_ORACLE_GET_ANSWER, #integer{value = 0},
               [ast_body(Oracle, Icode), ast_body(Q, Icode)], [word, word], aeso_icode:option_typerep(ast_type(RType, Icode)));
 
+ast_body(?qid_app(["Oracle", "check"], [Oracle], [?oracle_t(Q, R)], _), Icode) ->
+    prim_call(?PRIM_CALL_ORACLE_CHECK, #integer{value = 0},
+              [ast_body(Oracle, Icode), ast_type_value(Q, Icode), ast_type_value(R, Icode)],
+              [word, typerep, typerep], word);
+
+ast_body(?qid_app(["Oracle", "check_query"], [Oracle, Query], [_, ?query_t(Q, R)], _), Icode) ->
+    prim_call(?PRIM_CALL_ORACLE_CHECK_QUERY, #integer{value = 0},
+              [ast_body(Oracle, Icode), ast_body(Query, Icode),
+               ast_type_value(Q, Icode), ast_type_value(R, Icode)],
+              [word, typerep, typerep], word);
+
 ast_body({qid, _, ["Oracle", "register"]}, _Icode)     -> gen_error({underapplied_primitive, 'Oracle.register'});
 ast_body({qid, _, ["Oracle", "query"]}, _Icode)        -> gen_error({underapplied_primitive, 'Oracle.query'});
 ast_body({qid, _, ["Oracle", "extend"]}, _Icode)       -> gen_error({underapplied_primitive, 'Oracle.extend'});
@@ -316,47 +346,111 @@ ast_body({map, _, Map, [Upd]}, Icode) ->
 ast_body({map, Ann, Map, [Upd | Upds]}, Icode) ->
     ast_body({map, Ann, {map, Ann, Map, [Upd]}, Upds}, Icode);
 
+%% Crypto
+ast_body(?qid_app(["Crypto", "ecverify"], [Msg, PK, Sig], _, _), Icode) ->
+    prim_call(?PRIM_CALL_CRYPTO_ECVERIFY, #integer{value = 0},
+              [ast_body(Msg, Icode), ast_body(PK, Icode), ast_body(Sig, Icode)],
+              [word, word, sign_t()], word);
+
+ast_body(?qid_app(["Crypto", "ecverify_secp256k1"], [Msg, PK, Sig], _, _), Icode) ->
+    prim_call(?PRIM_CALL_CRYPTO_ECVERIFY_SECP256K1, #integer{value = 0},
+              [ast_body(Msg, Icode), ast_body(PK, Icode), ast_body(Sig, Icode)],
+              [bytes_t(32), bytes_t(64), bytes_t(64)], word);
+
+ast_body(?qid_app(["Crypto", "sha3"], [Term], [Type], _), Icode) ->
+    generic_hash_primop(?PRIM_CALL_CRYPTO_SHA3, Term, Type, Icode);
+ast_body(?qid_app(["Crypto", "sha256"], [Term], [Type], _), Icode) ->
+    generic_hash_primop(?PRIM_CALL_CRYPTO_SHA256, Term, Type, Icode);
+ast_body(?qid_app(["Crypto", "blake2b"], [Term], [Type], _), Icode) ->
+    generic_hash_primop(?PRIM_CALL_CRYPTO_BLAKE2B, Term, Type, Icode);
+ast_body(?qid_app(["String", "sha256"], [String], _, _), Icode) ->
+    string_hash_primop(?PRIM_CALL_CRYPTO_SHA256_STRING, String, Icode);
+ast_body(?qid_app(["String", "blake2b"], [String], _, _), Icode) ->
+    string_hash_primop(?PRIM_CALL_CRYPTO_BLAKE2B_STRING, String, Icode);
+
 %% Strings
 %% -- String length
 ast_body(?qid_app(["String", "length"], [String], _, _), Icode) ->
-    #funcall{ function = #var_ref{ name = {builtin, string_length} },
-              args     = [ast_body(String, Icode)] };
+    builtin_call(string_length, [ast_body(String, Icode)]);
 
 %% -- String concat
 ast_body(?qid_app(["String", "concat"], [String1, String2], _, _), Icode) ->
-    #funcall{ function = #var_ref{ name = {builtin, string_concat} },
-              args     = [ast_body(String1, Icode), ast_body(String2, Icode)] };
+    builtin_call(string_concat, [ast_body(String1, Icode), ast_body(String2, Icode)]);
 
 %% -- String hash (sha3)
 ast_body(?qid_app(["String", "sha3"], [String], _, _), Icode) ->
     #unop{ op = 'sha3', rand = ast_body(String, Icode) };
 
+%% -- Bits
+ast_body(?qid_app(["Bits", Fun], Args, _, _), Icode)
+        when Fun == "test"; Fun == "set"; Fun == "clear";
+             Fun == "union"; Fun == "intersection"; Fun == "difference" ->
+    C  = fun(N) when is_integer(N) -> #integer{ value = N };
+            (X) -> X end,
+    Bin = fun(O) -> fun(A, B) -> #binop{ op = O, left = C(A), right = C(B) } end end,
+    And = Bin('band'),
+    Or  = Bin('bor'),
+    Bsl = fun(A, B) -> (Bin('bsl'))(B, A) end, %% flipped arguments
+    Bsr = fun(A, B) -> (Bin('bsr'))(B, A) end,
+    Neg = fun(A) -> #unop{ op = 'bnot', rand = C(A) } end,
+    case [Fun | [ ast_body(Arg, Icode) || Arg <- Args ]] of
+        ["test", Bits, Ix]     -> And(Bsr(Bits, Ix), 1);
+        ["set", Bits, Ix]      -> Or(Bits, Bsl(1, Ix));
+        ["clear", Bits, Ix]    -> And(Bits, Neg(Bsl(1, Ix)));
+        ["union", A, B]        -> Or(A, B);
+        ["intersection", A, B] -> And(A, B);
+        ["difference", A, B]   -> And(A, Neg(And(A, B)))
+    end;
+ast_body({qid, _, ["Bits", "none"]}, _Icode) ->
+    #integer{ value = 0 };
+ast_body({qid, _, ["Bits", "all"]}, _Icode) ->
+    #integer{ value = 1 bsl 256 - 1 };
+ast_body(?qid_app(["Bits", "sum"], [Bits], _, _), Icode) ->
+    builtin_call(popcount, [ast_body(Bits, Icode), #integer{ value = 0 }]);
+
 %% -- Conversion
 ast_body(?qid_app(["Int", "to_str"], [Int], _, _), Icode) ->
     builtin_call(int_to_str, [ast_body(Int, Icode)]);
 
 ast_body(?qid_app(["Address", "to_str"], [Addr], _, _), Icode) ->
     builtin_call(addr_to_str, [ast_body(Addr, Icode)]);
+ast_body(?qid_app(["Address", "is_oracle"], [Addr], _, _), Icode) ->
+    prim_call(?PRIM_CALL_ADDR_IS_ORACLE, #integer{value = 0},
+              [ast_body(Addr, Icode)], [word], word);
+ast_body(?qid_app(["Address", "is_contract"], [Addr], _, _), Icode) ->
+    prim_call(?PRIM_CALL_ADDR_IS_CONTRACT, #integer{value = 0},
+              [ast_body(Addr, Icode)], [word], word);
+
+ast_body(?qid_app(["Bytes", "to_int"], [Bytes], _, _), Icode) ->
+    {typed, _, _, {bytes_t, _, N}} = Bytes,
+    builtin_call({bytes_to_int, N}, [ast_body(Bytes, Icode)]);
+ast_body(?qid_app(["Bytes", "to_str"], [Bytes], _, _), Icode) ->
+    {typed, _, _, {bytes_t, _, N}} = Bytes,
+    builtin_call({bytes_to_str, N}, [ast_body(Bytes, Icode)]);
 
 %% Other terms
 ast_body({id, _, Name}, _Icode) ->
-    %% TODO Look up id in env
+    #var_ref{name = Name};
+ast_body({qid, _, Name}, _Icode) ->
     #var_ref{name = Name};
 ast_body({bool, _, Bool}, _Icode) ->        %BOOL as ints
     Value = if Bool -> 1 ; true -> 0 end,
     #integer{value = Value};
 ast_body({int, _, Value}, _Icode) ->
     #integer{value = Value};
-ast_body({hash, _, Hash}, _Icode) ->
-    case Hash of
-        <<Value:32/unit:8>> ->              %% address
-            #integer{value = Value};
-        <<Hi:32/unit:8, Lo:32/unit:8>> ->   %% signature
-            #tuple{cpts = [#integer{value = Hi},
-                           #integer{value = Lo}]}
+ast_body({bytes, _, Bin}, _Icode) ->
+    case aeb_memory:binary_to_words(Bin) of
+        [Word] -> #integer{value = Word};
+        Words  -> #tuple{cpts = [#integer{value = W} || W <- Words]}
     end;
+ast_body({Key, _, Bin}, _Icode) when Key == account_pubkey;
+                                     Key == contract_pubkey;
+                                     Key == oracle_pubkey;
+                                     Key == oracle_query_id ->
+    <<Value:32/unit:8>> = Bin,
+    #integer{value = Value};
 ast_body({string,_,Bin}, _Icode) ->
-    Cpts = [size(Bin) | aeso_memory:binary_to_words(Bin)],
+    Cpts = [size(Bin) | aeb_memory:binary_to_words(Bin)],
     #tuple{cpts = [#integer{value=X} || X <- Cpts]};
 ast_body({tuple,_,Args}, Icode) ->
     #tuple{cpts = [ast_body(A, Icode) || A <- Args]};
@@ -380,7 +474,7 @@ ast_body({app, _, {typed, _, {proj, _, {typed, _, Addr, {con, _, Contract}}, {id
     Gas    = proplists:get_value("gas",   ArgOpts ++ Defaults),
     Value  = proplists:get_value("value", ArgOpts ++ Defaults),
     OutType = ast_typerep(OutT, Icode),
-    <<TypeHash:256>> = aeso_abi:function_type_hash(list_to_binary(FunName), ArgType, OutType),
+    <<TypeHash:256>> = aeb_aevm_abi:function_type_hash(list_to_binary(FunName), ArgType, OutType),
     %% The function is represented by its type hash (which includes the name)
     Fun    = #integer{value = TypeHash},
     #prim_call_contract{
@@ -397,9 +491,15 @@ ast_body({proj, _, {typed, _, _, {con, _, Contract}}, {id, _, FunName}}, _Icode)
                string:join([Contract, FunName], ".")});
 
 ast_body({con, _, Name}, Icode) ->
+    Tag = aeso_icode:get_constructor_tag([Name], Icode),
+    #tuple{cpts = [#integer{value = Tag}]};
+ast_body({qcon, _, Name}, Icode) ->
     Tag = aeso_icode:get_constructor_tag(Name, Icode),
     #tuple{cpts = [#integer{value = Tag}]};
 ast_body({app, _, {typed, _, {con, _, Name}, _}, Args}, Icode) ->
+    Tag = aeso_icode:get_constructor_tag([Name], Icode),
+    #tuple{cpts = [#integer{value = Tag} | [ ast_body(Arg, Icode) || Arg <- Args ]]};
+ast_body({app, _, {typed, _, {qcon, _, Name}, _}, Args}, Icode) ->
     Tag = aeso_icode:get_constructor_tag(Name, Icode),
     #tuple{cpts = [#integer{value = Tag} | [ ast_body(Arg, Icode) || Arg <- Args ]]};
 ast_body({app,As,Fun,Args}, Icode) ->
@@ -429,6 +529,8 @@ ast_body({switch,_,A,Cases}, Icode) ->
 ast_body({block,As,[{letval,_,Pat,_,E}|Rest]}, Icode) ->
     #switch{expr=ast_body(E, Icode),
             cases=[{ast_body(Pat, Icode),ast_body({block,As,Rest}, Icode)}]};
+ast_body({block, As, [{letfun, Ann, F, Args, _Type, Expr} | Rest]}, Icode) ->
+    ast_body({block, As, [{letval, Ann, F, unused, {lam, Ann, Args, Expr}} | Rest]}, Icode);
 ast_body({block,_,[]}, _Icode) ->
     #tuple{cpts=[]};
 ast_body({block,_,[E]}, Icode) ->
@@ -496,25 +598,30 @@ ast_binop(Op, Ann, {typed, _, A, Type}, B, Icode)
         _ when not Monomorphic ->
             gen_error({cant_compare_polymorphic_type, Ann, Op, Type});
         word   -> #binop{op = Op, left = ast_body(A, Icode), right = ast_body(B, Icode)};
-        string ->
+        OtherType ->
             Neg = case Op of
                     '==' -> fun(X) -> X end;
                     '!=' -> fun(X) -> #unop{ op = '!', rand = X } end;
                     _    -> gen_error({cant_compare, Ann, Op, Type})
                   end,
-            Neg(#funcall{ function = #var_ref{name = {builtin, str_equal}},
-                          args     = [ast_body(A, Icode), ast_body(B, Icode)] });
-        _ -> gen_error({cant_compare, Ann, Op, Type})
+            Args = [ast_body(A, Icode), ast_body(B, Icode)],
+            Builtin =
+                case OtherType of
+                    string ->
+                        builtin_call(str_equal, Args);
+                    {tuple, Types} ->
+                        case lists:usort(Types) of
+                            [word] ->
+                                builtin_call(str_equal_p, [ #integer{value = 32 * length(Types)} | Args]);
+                            _ -> gen_error({cant_compare, Ann, Op, Type})
+                        end;
+                    _ ->
+                        gen_error({cant_compare, Ann, Op, Type})
+                end,
+            Neg(Builtin)
     end;
 ast_binop('++', _, A, B, Icode) ->
-    #funcall{ function = #var_ref{ name = {builtin, list_concat} },
-              args     = [ast_body(A, Icode), ast_body(B, Icode)] };
-ast_binop('bsl', _, A, B, Icode) ->
-    #binop{op = '*', left = ast_body(A, Icode),
-                     right = #binop{op = '^', left = {integer, 2}, right = ast_body(B, Icode)}};
-ast_binop('bsr', _, A, B, Icode) ->
-    #binop{op = 'div', left = ast_body(A, Icode),
-                       right = #binop{op = '^', left = {integer, 2}, right = ast_body(B, Icode)}};
+    builtin_call(list_concat, [ast_body(A, Icode), ast_body(B, Icode)]);
 ast_binop(Op, _, A, B, Icode) ->
     #binop{op = Op, left = ast_body(A, Icode), right = ast_body(B, Icode)}.
 
@@ -581,7 +688,7 @@ prim_call(Prim, Amount, Args, ArgTypes, OutType) ->
             true ->
                 PrimBin = binary:encode_unsigned(Prim),
                 ArgType = {tuple, ArgTypes},
-                <<TH:256>> = aeso_abi:function_type_hash(PrimBin, ArgType, OutType),
+                <<TH:256>> = aeb_aevm_abi:function_type_hash(PrimBin, ArgType, OutType),
                 TH;
             false ->
                 0
@@ -593,6 +700,16 @@ prim_call(Prim, Amount, Args, ArgTypes, OutType) ->
                          type_hash= #integer{value = TypeHash}
                        }.
 
+generic_hash_primop(PrimOp, Term, Type, Icode) ->
+    ArgType   = ast_type(Type, Icode),
+    TypeValue = type_value(ArgType),
+    prim_call(PrimOp, #integer{value = 0},
+        [TypeValue, ast_body(Term, Icode)],
+        [typerep, ArgType], word).
+
+string_hash_primop(PrimOp, String, Icode) ->
+    prim_call(PrimOp, #integer{value = 0}, [ast_body(String, Icode)], [string], word).
+
 make_type_def(Args, Def, Icode = #{ type_vars := TypeEnv }) ->
     TVars = [ X || {tvar, _, X} <- Args ],
     fun(Types) ->
@@ -600,7 +717,7 @@ make_type_def(Args, Def, Icode = #{ type_vars := TypeEnv }) ->
         ast_typerep(Def, Icode#{ type_vars := maps:merge(TypeEnv, TypeEnv1) })
     end.
 
--spec ast_typerep(aeso_syntax:type()) -> aeso_sophia:type().
+-spec ast_typerep(aeso_syntax:type()) -> aeb_aevm_data:type().
 ast_typerep(Type) -> ast_typerep(Type, aeso_icode:new([])).
 
 ast_typerep({id, _, Name}, Icode) ->
@@ -609,6 +726,8 @@ ast_typerep({qid, _, Name}, Icode) ->
     lookup_type_id(Name, [], Icode);
 ast_typerep({con, _, _}, _) ->
     word;   %% Contract type
+ast_typerep({bytes_t, _, Len}, _) ->
+    bytes_t(Len);
 ast_typerep({app_t, _, {id, _, Name}, Args}, Icode) ->
     ArgReps = [ ast_typerep(Arg, Icode) || Arg <- Args ],
     lookup_type_id(Name, ArgReps, Icode);
@@ -636,8 +755,9 @@ ast_typerep({variant_t, Cons}, Icode) ->
 ttl_t(Icode) ->
     ast_typerep({qid, [], ["Chain", "ttl"]}, Icode).
 
-sign_t() ->
-    {tuple, [word, word]}.
+sign_t() -> bytes_t(64).
+bytes_t(Len) when Len =< 32 -> word;
+bytes_t(Len)                -> {tuple, lists:duplicate((31 + Len) div 32, word)}.
 
 get_signature_arg(Args0) ->
     NamedArgs = [Arg || Arg = {named_arg, _, _, _} <- Args0],
@@ -697,6 +817,13 @@ has_maps({list, T})     -> has_maps(T);
 has_maps({tuple, Ts})   -> lists:any(fun has_maps/1, Ts);
 has_maps({variant, Cs}) -> lists:any(fun has_maps/1, lists:append(Cs)).
 
+%% A function is private if not an 'entrypoint', or if it's not defined in the
+%% main contract name space. (NOTE: changes when we introduce inheritance).
+is_private(Ann, #{ contract_name := MainContract } = Icode) ->
+    {_, _, CurrentNamespace} = aeso_icode:get_namespace(Icode),
+    not proplists:get_value(entrypoint, Ann, false) orelse
+    MainContract /= CurrentNamespace.
+
 %% -------------------------------------------------------------------
 %% Builtins
 %% -------------------------------------------------------------------
@@ -708,3 +835,39 @@ builtin_call(Builtin, Args) ->
 add_builtins(Icode = #{functions := Funs}) ->
     Builtins = aeso_builtins:used_builtins(Funs),
     Icode#{functions := [ aeso_builtins:builtin_function(B) || B <- Builtins ] ++ Funs}.
+
+
+%% -------------------------------------------------------------------
+%% Deadcode elimination
+%% -------------------------------------------------------------------
+
+deadcode_elimination(Icode = #{ functions := Funs }) ->
+    PublicNames = [ Name || {Name, Ann, _, _, _} <- Funs, not lists:member(private, Ann) ],
+    ArgsToPat   = fun(Args) -> [ #var_ref{ name = X } || {X, _} <- Args ] end,
+    Defs        = maps:from_list([ {Name, {binder, ArgsToPat(Args), Body}} || {Name, _, Args, Body, _} <- Funs ]),
+    UsedNames   = chase_names(Defs, PublicNames, #{}),
+    UsedFuns    = [ Def || Def = {Name, _, _, _, _} <- Funs, maps:is_key(Name, UsedNames) ],
+    Icode#{ functions := UsedFuns }.
+
+chase_names(_Defs, [], Used) -> Used;
+chase_names(Defs, [X | Xs], Used) ->
+                              %% can happen when compiling __call contracts
+    case maps:is_key(X, Used) orelse not maps:is_key(X, Defs) of
+        true  -> chase_names(Defs, Xs, Used); %% already chased
+        false ->
+            Def  = maps:get(X, Defs),
+            Vars = maps:keys(free_vars(Def)),
+            chase_names(Defs, Vars ++ Xs, Used#{ X => true })
+    end.
+
+free_vars(#var_ref{ name = X }) -> #{ X => true };
+free_vars(#arg{ name = X }) -> #{ X => true };
+free_vars({binder, Pat, Body}) ->
+    maps:without(maps:keys(free_vars(Pat)), free_vars(Body));
+free_vars(#switch{ expr = E, cases = Cases }) ->
+    free_vars([E | [{binder, P, B} || {P, B} <- Cases]]);
+free_vars(#lambda{ args = Xs, body = E }) ->
+    free_vars({binder, Xs, E});
+free_vars(T) when is_tuple(T) -> free_vars(tuple_to_list(T));
+free_vars([H | T]) -> maps:merge(free_vars(H), free_vars(T));
+free_vars(_) -> #{}.

src/aeso_blake2.erl

@@ -1,149 +0,0 @@
-%%%=============================================================================
-%%% @copyright (C) 2019, Aeternity Anstalt
-%%% @doc
-%%%  BLAKE2b implementation in Erlang - for details see: https://blake2.net
-%%% @end
-%%%=============================================================================
-
--module(aeso_blake2).
-
--export([ blake2b/2
-        , blake2b/3
-        ]).
-
--define(MAX_64BIT, 16#ffffffffffffffff).
-
--spec blake2b(HashLen :: integer(), Msg :: binary()) -> {ok, binary()}.
-blake2b(HashLen, Msg) ->
-    blake2b(HashLen, Msg, <<>>).
-
--spec blake2b(HashLen :: integer(), Msg :: binary(), Key :: binary()) -> {ok, binary()}.
-blake2b(HashLen, Msg0, Key) ->
-    %% If message should be keyed, prepend message with padded key.
-    Msg = <<(pad(128, Key))/binary, Msg0/binary>>,
-
-    %% Set up the initial state
-    Init  = (16#01010000 + (byte_size(Key) bsl 8) + HashLen),
-    <<H0:64, H1_7/binary>> = blake_iv(),
-    H = <<(H0 bxor Init):64, H1_7/binary>>,
-
-    %% Perform the compression - message will be chopped into 128-byte chunks.
-    State = blake2b_compress(H, Msg, 0),
-
-    %% Just return the requested part of the hash
-    {ok, binary_part(to_little_endian(State), {0, HashLen})}.
-
-blake2b_compress(H, <<Chunk:(128*8), Rest/binary>>, BCompr) when Rest /= <<>> ->
-    H1 = blake2b_compress(H, <<Chunk:(128*8)>>, BCompr + 128, false),
-    blake2b_compress(H1, Rest, BCompr + 128);
-blake2b_compress(H, SmallChunk, BCompr) ->
-    Size    = byte_size(SmallChunk),
-    FillSize = (128 - Size) * 8,
-    blake2b_compress(H, <<SmallChunk/binary, 0:FillSize>>, BCompr + Size, true).
-
-blake2b_compress(H, Chunk0, BCompr, Last) ->
-    Chunk = to_big_endian(Chunk0),
-    <<V0_11:(12*64), V12:64, V13:64, V14:64, V15:64>> = <<H/binary, (blake_iv())/binary>>,
-    V12_ = V12 bxor (BCompr band ?MAX_64BIT),
-    V13_ = V13 bxor ((BCompr bsr 64) band ?MAX_64BIT),
-    V14_ = case Last of
-               false -> V14;
-               true  -> V14 bxor ?MAX_64BIT
-           end,
-    V = <<V0_11:(12*64), V12_:64, V13_:64, V14_:64, V15:64>>,
-
-    <<VLow:(8*64), VHigh:(8*64)>> =
-        lists:foldl(fun(Round, Vx) -> blake2b_mix(Round, Chunk, Vx) end, V, lists:seq(0, 11)),
-
-  <<HInt:(8*64)>> = H,
-  <<((HInt bxor VLow) bxor VHigh):(8*64)>>.
-
-blake2b_mix(Rnd, Chunk, V) ->
-    <<V0:64, V1:64, V2:64, V3:64, V4:64, V5:64, V6:64, V7:64, V8:64,
-      V9:64, V10:64, V11:64, V12:64, V13:64, V14:64, V15:64>> = V,
-    <<M0:64, M1:64, M2:64, M3:64, M4:64, M5:64, M6:64, M7:64, M8:64,
-      M9:64, M10:64, M11:64, M12:64, M13:64, M14:64, M15:64>> = Chunk,
-    Ms = {M0, M1, M2, M3, M4, M5, M6, M7, M8, M9, M10, M11, M12, M13, M14, M15},
-    M = fun(Ix) -> element(Ix+1, Ms) end,
-
-    [S0, S1, S2, S3, S4, S5, S6, S7, S8, S9, S10, S11, S12, S13, S14, S15] = sigma(Rnd rem 10),
-
-    {Vx0, Vx4, Vx8,  Vx12} = blake2b_mix(V0, V4, V8,  V12, M(S0), M(S1)),
-    {Vx1, Vx5, Vx9,  Vx13} = blake2b_mix(V1, V5, V9,  V13, M(S2), M(S3)),
-    {Vx2, Vx6, Vx10, Vx14} = blake2b_mix(V2, V6, V10, V14, M(S4), M(S5)),
-    {Vx3, Vx7, Vx11, Vx15} = blake2b_mix(V3, V7, V11, V15, M(S6), M(S7)),
-
-    {Vy0, Vy5, Vy10, Vy15} = blake2b_mix(Vx0, Vx5, Vx10, Vx15, M(S8),  M(S9)),
-    {Vy1, Vy6, Vy11, Vy12} = blake2b_mix(Vx1, Vx6, Vx11, Vx12, M(S10), M(S11)),
-    {Vy2, Vy7, Vy8,  Vy13} = blake2b_mix(Vx2, Vx7, Vx8,  Vx13, M(S12), M(S13)),
-    {Vy3, Vy4, Vy9,  Vy14} = blake2b_mix(Vx3, Vx4, Vx9,  Vx14, M(S14), M(S15)),
-
-    <<Vy0:64, Vy1:64, Vy2:64, Vy3:64, Vy4:64, Vy5:64, Vy6:64, Vy7:64, Vy8:64,
-      Vy9:64, Vy10:64, Vy11:64, Vy12:64, Vy13:64, Vy14:64, Vy15:64>>.
-
-blake2b_mix(Va, Vb, Vc, Vd, X, Y) ->
-    Va1 = (Va + Vb + X) band ?MAX_64BIT,
-    Vd1 = rotr64(32, Vd bxor Va1),
-
-    Vc1 = (Vc + Vd1) band ?MAX_64BIT,
-    Vb1 = rotr64(24, Vb bxor Vc1),
-
-    Va2 = (Va1 + Vb1 + Y) band ?MAX_64BIT,
-    Vd2 = rotr64(16, Va2 bxor Vd1),
-
-    Vc2 = (Vc1 + Vd2) band ?MAX_64BIT,
-    Vb2 = rotr64(63, Vb1 bxor Vc2),
-
-    {Va2, Vb2, Vc2, Vd2}.
-
-blake_iv() ->
-    IV0 = 16#6A09E667F3BCC908,
-    IV1 = 16#BB67AE8584CAA73B,
-    IV2 = 16#3C6EF372FE94F82B,
-    IV3 = 16#A54FF53A5F1D36F1,
-    IV4 = 16#510E527FADE682D1,
-    IV5 = 16#9B05688C2B3E6C1F,
-    IV6 = 16#1F83D9ABFB41BD6B,
-    IV7 = 16#5BE0CD19137E2179,
-    <<IV0:64, IV1:64, IV2:64, IV3:64, IV4:64, IV5:64, IV6:64, IV7:64>>.
-
-sigma(N) ->
-    {_, Row} = lists:keyfind(N, 1, sigma()), Row.
-
-sigma() ->
-    [{0, [ 0,  1,  2,  3,  4,  5,  6,  7,  8,  9, 10, 11, 12, 13, 14, 15]},
-     {1, [14, 10,  4,  8,  9, 15, 13,  6,  1, 12,  0,  2, 11,  7,  5,  3]},
-     {2, [11,  8, 12,  0,  5,  2, 15, 13, 10, 14,  3,  6,  7,  1,  9,  4]},
-     {3, [ 7,  9,  3,  1, 13, 12, 11, 14,  2,  6,  5, 10,  4,  0, 15,  8]},
-     {4, [ 9,  0,  5,  7,  2,  4, 10, 15, 14,  1, 11, 12,  6,  8,  3, 13]},
-     {5, [ 2, 12,  6, 10,  0, 11,  8,  3,  4, 13,  7,  5, 15, 14,  1,  9]},
-     {6, [12,  5,  1, 15, 14, 13,  4, 10,  0,  7,  6,  3,  9,  2,  8, 11]},
-     {7, [13, 11,  7, 14, 12,  1,  3,  9,  5,  0, 15,  4,  8,  6,  2, 10]},
-     {8, [ 6, 15, 14,  9, 11,  3,  0,  8, 12,  2, 13,  7,  1,  4, 10,  5]},
-     {9, [10,  2,  8,  4,  7,  6,  1,  5, 15, 11,  9, 14,  3, 12, 13,  0]}].
-
-rotr64(N, I64) ->
-    <<I64rot:64>> = rotr641(N, <<I64:64>>),
-    I64rot.
-
-rotr641(16, <<X:(64-16), Y:16>>) -> <<Y:16, X:(64-16)>>;
-rotr641(24, <<X:(64-24), Y:24>>) -> <<Y:24, X:(64-24)>>;
-rotr641(32, <<X:(64-32), Y:32>>) -> <<Y:32, X:(64-32)>>;
-rotr641(63, <<X:(64-63), Y:63>>) -> <<Y:63, X:(64-63)>>.
-
-pad(N, Bin) ->
-    case (N - (byte_size(Bin) rem N)) rem N of
-        0   -> Bin;
-        Pad -> <<Bin/binary, 0:(Pad *8)>>
-    end.
-
-to_big_endian(Bin) -> to_big_endian(Bin, <<>>).
-to_big_endian(<<>>, Acc) -> Acc;
-to_big_endian(<<UInt64:1/little-unsigned-integer-unit:64, Rest/binary>>, Acc) ->
-  to_big_endian(Rest, <<Acc/binary, UInt64:1/big-unsigned-integer-unit:64>>).
-
-to_little_endian(Bin) -> to_little_endian(Bin, <<>>).
-to_little_endian(<<>>, Acc) -> Acc;
-to_little_endian(<<UInt64:1/big-unsigned-integer-unit:64, Rest/binary>>, Acc) ->
-  to_little_endian(Rest, <<Acc/binary, UInt64:1/little-unsigned-integer-unit:64>>).
-

src/aeso_builtins.erl

@@ -38,13 +38,15 @@ builtin_deps1({map_upd, Type})            -> [{map_get, Type}, map_put];
 builtin_deps1({map_upd_default, Type})    -> [{map_lookup_default, Type}, map_put];
 builtin_deps1(map_from_list)              -> [map_put];
 builtin_deps1(str_equal)                  -> [str_equal_p];
-builtin_deps1(string_concat)              -> [string_concat_inner1, string_concat_inner2];
+builtin_deps1(string_concat)              -> [string_concat_inner1, string_copy, string_shift_copy];
 builtin_deps1(int_to_str)                 -> [{baseX_int, 10}];
 builtin_deps1(addr_to_str)                -> [{baseX_int, 58}];
 builtin_deps1({baseX_int, X})             -> [{baseX_int_pad, X}];
 builtin_deps1({baseX_int_pad, X})         -> [{baseX_int_encode, X}];
 builtin_deps1({baseX_int_encode, X})      -> [{baseX_int_encode_, X}, {baseX_tab, X}, {baseX_digits, X}];
+builtin_deps1({bytes_to_str, _})          -> [bytes_to_str_worker];
 builtin_deps1(string_reverse)             -> [string_reverse_];
+builtin_deps1(require)                    -> [abort];
 builtin_deps1(_)                          -> [].
 
 dep_closure(Deps) ->
@@ -60,12 +62,14 @@ v(X) when is_list(X) -> #var_ref{name = X}.
 option_none()  -> {tuple, [{integer, 0}]}.
 option_some(X) -> {tuple, [{integer, 1}, X]}.
 
+-define(HASH_BYTES, 32).
+
 -define(call(Fun, Args), #funcall{ function = #var_ref{ name = {builtin, Fun} }, args = Args }).
 -define(I(X), {integer, X}).
 -define(V(X), v(X)).
 -define(A(Op), aeb_opcodes:mnemonic(Op)).
 -define(LET(Var, Expr, Body), {switch, Expr, [{v(Var), Body}]}).
--define(DEREF(Var, Ptr, Body), {switch, v(Ptr), [{{tuple, [v(Var)]}, Body}]}).
+-define(DEREF(Var, Ptr, Body), {switch, operand(Ptr), [{{tuple, [v(Var)]}, Body}]}).
 -define(NXT(Ptr), op('+', Ptr, 32)).
 -define(NEG(A), op('/', A, {unop, '-', {integer, 1}})).
 -define(BYTE(Ix, Word), op('byte', Ix, Word)).
@@ -81,8 +85,9 @@ option_some(X) -> {tuple, [{integer, 1}, X]}.
 -define(EXP(A, B), op('^', A, B)).
 -define(AND(A, B), op('&&', A, B)).
 
--define(BSL(X, B), ?MUL(X, ?EXP(2, ?MUL(B, 8)))).
--define(BSR(X, B), ?DIV(X, ?EXP(2, ?MUL(B, 8)))).
+%% Bit shift operations takes their arguments backwards!?
+-define(BSL(X, B), op('bsl', ?MUL(B, 8), X)).
+-define(BSR(X, B), op('bsr', ?MUL(B, 8), X)).
 
 op(Op, A, B) -> {binop, Op, operand(A), operand(B)}.
 
@@ -90,12 +95,6 @@ operand(A) when is_atom(A) -> v(A);
 operand(I) when is_integer(I) -> {integer, I};
 operand(T) -> T.
 
-str_to_icode(String) when is_list(String) ->
-    str_to_icode(list_to_binary(String));
-str_to_icode(BinStr) ->
-    Cpts = [size(BinStr) | aeso_memory:binary_to_words(BinStr)],
-    #tuple{ cpts = [ #integer{value = X} || X <- Cpts ] }.
-
 check_event_type(Icode) ->
     case maps:get(event_type, Icode) of
         {variant_t, Cons} ->
@@ -105,21 +104,23 @@ check_event_type(Icode) ->
     end.
 
 check_event_type(Evts, Icode) ->
-    [ check_event_type(Name, T, Icode)
-      || {constr_t, _, {con, _, Name}, Types} <- Evts, T <- Types ].
+    [ check_event_type(Name, Ix, T, Icode)
+      || {constr_t, Ann, {con, _, Name}, Types} <- Evts,
+         {Ix, T} <- lists:zip(aeso_syntax:get_ann(indices, Ann), Types) ].
 
-check_event_type(EvtName, Type, Icode) ->
+check_event_type(EvtName, Ix, Type, Icode) ->
     VMType =
         try
            aeso_ast_to_icode:ast_typerep(Type, Icode)
         catch _:_ ->
             error({EvtName, could_not_resolve_type, Type})
         end,
-    case aeso_syntax:get_ann(indexed, Type, false) of
-        true when VMType == word    -> ok;
-        false when VMType == string -> ok;
-        true  -> error({EvtName, indexed_field_should_be_word, is, VMType});
-        false -> error({EvtName, payload_should_be_string, is, VMType})
+    case {Ix, VMType, Type} of
+        {indexed, word, _}      -> ok;
+        {notindexed, string, _} -> ok;
+        {notindexed, _, {bytes_t, _, N}} when N > 32 -> ok;
+        {indexed, _, _}         -> error({EvtName, indexed_field_should_be_word, is, VMType});
+        {notindexed, _, _}      -> error({EvtName, payload_should_be_string, is, VMType})
     end.
 
 bfun(B, {IArgs, IExpr, IRet}) ->
@@ -129,6 +130,8 @@ builtin_function(BF) ->
     case BF of
         {event, EventT}            -> bfun(BF, builtin_event(EventT));
         abort                      -> bfun(BF, builtin_abort());
+        block_hash                 -> bfun(BF, builtin_block_hash());
+        require                    -> bfun(BF, builtin_require());
         {map_lookup, Type}         -> bfun(BF, builtin_map_lookup(Type));
         map_put                    -> bfun(BF, builtin_map_put());
         map_delete                 -> bfun(BF, builtin_map_delete());
@@ -143,9 +146,11 @@ builtin_function(BF) ->
         string_length              -> bfun(BF, builtin_string_length());
         string_concat              -> bfun(BF, builtin_string_concat());
         string_concat_inner1       -> bfun(BF, builtin_string_concat_inner1());
-        string_concat_inner2       -> bfun(BF, builtin_string_concat_inner2());
+        string_copy                -> bfun(BF, builtin_string_copy());
+        string_shift_copy          -> bfun(BF, builtin_string_shift_copy());
         str_equal_p                -> bfun(BF, builtin_str_equal_p());
         str_equal                  -> bfun(BF, builtin_str_equal());
+        popcount                   -> bfun(BF, builtin_popcount());
         int_to_str                 -> bfun(BF, builtin_int_to_str());
         addr_to_str                -> bfun(BF, builtin_addr_to_str());
         {baseX_int, X}             -> bfun(BF, builtin_baseX_int(X));
@@ -154,6 +159,9 @@ builtin_function(BF) ->
         {baseX_int_pad, X}         -> bfun(BF, builtin_baseX_int_pad(X));
         {baseX_int_encode, X}      -> bfun(BF, builtin_baseX_int_encode(X));
         {baseX_int_encode_, X}     -> bfun(BF, builtin_baseX_int_encode_(X));
+        {bytes_to_int, N}          -> bfun(BF, builtin_bytes_to_int(N));
+        {bytes_to_str, N}          -> bfun(BF, builtin_bytes_to_str(N));
+        bytes_to_str_worker        -> bfun(BF, builtin_bytes_to_str_worker());
         string_reverse             -> bfun(BF, builtin_string_reverse());
         string_reverse_            -> bfun(BF, builtin_string_reverse_())
     end.
@@ -166,18 +174,24 @@ builtin_event(EventT) ->
     A         = fun(X) -> aeb_opcodes:mnemonic(X) end,
     VIx       = fun(Ix) -> v(lists:concat(["v", Ix])) end,
     ArgPats   = fun(Ts) -> [ VIx(Ix) || Ix <- lists:seq(0, length(Ts) - 1) ] end,
-    IsIndexed = fun(T) -> aeso_syntax:get_ann(indexed, T, false) end,
     Payload = %% Should put data ptr, length on stack.
-        fun([]) ->  {inline_asm, [A(?PUSH1), 0, A(?PUSH1), 0]};
-           ([V]) -> {seq, [V, {inline_asm, [A(?DUP1), A(?MLOAD),                  %% length, ptr
-                                            A(?SWAP1), A(?PUSH1), 32, A(?ADD)]}]} %% ptr+32, length
+        fun([])            -> {inline_asm, [A(?PUSH1), 0, A(?PUSH1), 0]};
+           ([{{id, _, "string"}, V}]) ->
+                {seq, [V, {inline_asm, [A(?DUP1), A(?MLOAD),  %% length, ptr
+                       A(?SWAP1), A(?PUSH1), 32, A(?ADD)]}]}; %% ptr+32, length
+           ([{{bytes_t, _, N}, V}]) -> {seq, [V, {integer, N}, {inline_asm, A(?SWAP1)}]}
         end,
+    Ix =
+        fun({bytes_t, _, N}, V) when N < 32 -> ?BSR(V, 32 - N);
+           (_, V) -> V end,
     Clause =
-        fun(_Tag, {con, _, Con}, Types) ->
-            Indexed   = [ Var || {Var, Type} <- lists:zip(ArgPats(Types), Types),
-                                 IsIndexed(Type) ],
-            EvtIndex  = {unop, 'sha3', str_to_icode(Con)},
-            {event, lists:reverse(Indexed) ++ [EvtIndex], Payload(ArgPats(Types) -- Indexed)}
+        fun(_Tag, {con, _, Con}, IxTypes) ->
+            Types     = [ T || {_Ix, T} <- IxTypes ],
+            Indexed   = [ Ix(Type, Var) || {Var, {indexed, Type}} <- lists:zip(ArgPats(Types), IxTypes) ],
+            Data      = [ {Type, Var} || {Var, {notindexed, Type}} <- lists:zip(ArgPats(Types), IxTypes) ],
+            {ok, <<EvtIndexN:256>>} = eblake2:blake2b(?HASH_BYTES, list_to_binary(Con)),
+            EvtIndex  = {integer, EvtIndexN},
+            {event, lists:reverse(Indexed) ++ [EvtIndex], Payload(Data)}
         end,
     Pat = fun(Tag, Types) -> {tuple, [{integer, Tag} | ArgPats(Types)]} end,
 
@@ -186,8 +200,8 @@ builtin_event(EventT) ->
 
     {[{"e", event}],
      {switch, v(e),
-         [{Pat(Tag, Types), Clause(Tag, Con, Types)}
-          || {Tag, {constr_t, _, Con, Types}} <- lists:zip(Tags, Cons) ]},
+         [{Pat(Tag, Types), Clause(Tag, Con, lists:zip(aeso_syntax:get_ann(indices, Ann), Types))}
+          || {Tag, {constr_t, Ann, Con, Types}} <- lists:zip(Tags, Cons) ]},
      {tuple, []}}.
 
 %% Abort primitive.
@@ -198,6 +212,17 @@ builtin_abort() ->
                    A(?REVERT)]}, %% Stack: 0,Ptr
      {tuple,[]}}.
 
+builtin_block_hash() ->
+    {[{"height", word}],
+     ?LET(hash, #prim_block_hash{ height = ?V(height)},
+          {ifte, ?EQ(hash, 0), option_none(), option_some(?V(hash))}),
+     aeso_icode:option_typerep(word)}.
+
+builtin_require() ->
+    {[{"c", word}, {"msg", string}],
+     {ifte, ?V(c), {tuple, []}, ?call(abort, [?V(msg)])},
+     {tuple, []}}.
+
 %% Map primitives
 builtin_map_lookup(Type) ->
     Ret = aeso_icode:option_typerep(Type),
@@ -321,14 +346,17 @@ builtin_string_concat() ->
     {[{"s1", string}, {"s2", string}],
      ?DEREF(n1, s1,
      ?DEREF(n2, s2,
-        {ifte, ?EQ(n2, 0),
-            ?V(s1), %% Second string is empty return first string
-            ?LET(ret, {inline_asm, [?A(?MSIZE)]},
-                {seq, [?ADD(n1, n2), {inline_asm, [?A(?MSIZE), ?A(?MSTORE)]}, %% Store total len
-                       ?call(string_concat_inner1, [?V(n1), ?NXT(s1), ?V(n2), ?NXT(s2)]),
-                       {inline_asm, [?A(?POP)]}, %% Discard fun ret val
-                       ?V(ret)                   %% Put the actual return value
-                      ]})}
+        {ifte, ?EQ(n1, 0),
+            ?V(s2), %% First string is empty return second string
+            {ifte, ?EQ(n2, 0),
+                ?V(s1), %% Second string is empty return first string
+                ?LET(ret, {inline_asm, [?A(?MSIZE)]},
+                    {seq, [?ADD(n1, n2), {inline_asm, [?A(?MSIZE), ?A(?MSTORE)]}, %% Store total len
+                           ?call(string_concat_inner1, [?V(n1), ?NXT(s1), ?V(n2), ?NXT(s2)]),
+                           {inline_asm, [?A(?POP)]}, %% Discard fun ret val
+                           ?V(ret)                   %% Put the actual return value
+                          ]})}
+        }
      )),
      word}.
 
@@ -336,33 +364,33 @@ builtin_string_concat_inner1() ->
     %% Copy all whole words from the first string, and set up for word fusion
     %% Special case when the length of the first string is divisible by 32.
     {[{"n1", word}, {"p1", pointer}, {"n2", word}, {"p2", pointer}],
-     ?DEREF(w1, p1,
-        {ifte, ?GT(n1, 32),
-            {seq, [?V(w1), {inline_asm, [?A(?MSIZE), ?A(?MSTORE)]},
-                   ?call(string_concat_inner1, [?SUB(n1, 32), ?NXT(p1), ?V(n2), ?V(p2)])]},
-            {ifte, ?EQ(n1, 0),
-                ?call(string_concat_inner2, [?I(32), ?I(0), ?V(n2), ?V(p2)]),
-                ?call(string_concat_inner2, [?SUB(32, n1), ?V(w1), ?V(n2), ?V(p2)])}
+     ?LET(w1, ?call(string_copy, [?V(n1), ?V(p1)]),
+        ?LET(nx, ?MOD(n1, 32),
+        {ifte, ?EQ(nx, 0),
+            ?LET(w2, ?call(string_copy, [?V(n2), ?V(p2)]),
+                {seq, [?V(w2), {inline_asm, [?A(?MSIZE), ?A(?MSTORE), ?A(?MSIZE)]}]}),
+            ?call(string_shift_copy, [?V(nx), ?V(w1), ?V(n2), ?V(p2)])
+        })),
+     word}.
+
+builtin_string_copy() ->
+    {[{"n", word}, {"p", pointer}],
+     ?DEREF(w, p,
+        {ifte, ?GT(n, 31),
+            {seq, [?V(w), {inline_asm, [?A(?MSIZE), ?A(?MSTORE)]},
+                   ?call(string_copy, [?SUB(n, 32), ?NXT(p)])]},
+            ?V(w)
         }),
      word}.
 
-builtin_string_concat_inner2() ->
-    %% Current "work in progess" word 'x', has 'o' bytes that are "free" - fill them from
-    %% words of the second string.
-    {[{"o", word}, {"x", word}, {"n2", word}, {"p2", pointer}],
-     {ifte, ?LT(n2, 1),
-        {seq, [?V(x), {inline_asm, [?A(?MSIZE), ?A(?MSTORE), ?A(?MSIZE)]}]}, %% Use MSIZE as dummy return value
-        ?DEREF(w2, p2,
-            {ifte, ?GT(n2, o),
-                {seq, [?ADD(x, ?BSR(w2, ?SUB(32, o))),
-                       {inline_asm, [?A(?MSIZE), ?A(?MSTORE)]},
-                       ?call(string_concat_inner2,
-                             [?V(o), ?BSL(w2, o), ?SUB(n2, 32), ?NXT(p2)])
-                      ]},
-                {seq, [?ADD(x, ?BSR(w2, ?SUB(32, o))),
-                       {inline_asm, [?A(?MSIZE), ?A(?MSTORE), ?A(?MSIZE)]}]} %% Use MSIZE as dummy return value
-            })
-     },
+builtin_string_shift_copy() ->
+    {[{"off", word}, {"dst", word}, {"n", word}, {"p", pointer}],
+     ?DEREF(w, p,
+        {seq, [?ADD(dst, ?BSR(w, off)), {inline_asm, [?A(?MSIZE), ?A(?MSTORE)]},
+               {ifte, ?GT(n, ?SUB(32, off)),
+                    ?call(string_shift_copy, [?V(off), ?BSL(w, ?SUB(32, off)), ?SUB(n, 32), ?NXT(p)]),
+                    {inline_asm, [?A(?MSIZE)]}}]
+        }),
      word}.
 
 builtin_str_equal_p() ->
@@ -393,6 +421,17 @@ builtin_str_equal() ->
      )),
      word}.
 
+%% Count the number of 1s in a bit field.
+builtin_popcount() ->
+    %% function popcount(bits, acc) =
+    %%   if (bits == 0) acc
+    %%   else popcount(bits bsr 1, acc + bits band 1)
+    {[{"bits", word}, {"acc", word}],
+     {ifte, ?EQ(bits, 0),
+        ?V(acc),
+        ?call(popcount, [op('bsr', 1, bits), ?ADD(acc, op('band', bits, 1))])
+     }, word}.
+
 builtin_int_to_str() ->
     {[{"i", word}], ?call({baseX_int, 10}, [?V(i)]), word}.
 
@@ -420,6 +459,10 @@ builtin_baseX_int_pad(X = 10) ->
         ?call({baseX_int_encode, X}, [?NEG(src), ?I(1), ?BSL($-, 31)]),
         ?call({baseX_int_encode, X}, [?V(src), ?V(ix), ?V(dst)])},
      word};
+builtin_baseX_int_pad(X = 16) ->
+    {[{"src", word}, {"ix", word}, {"dst", word}],
+        ?call({baseX_int_encode, X}, [?V(src), ?V(ix), ?V(dst)]),
+     word};
 builtin_baseX_int_pad(X = 58) ->
     {[{"src", word}, {"ix", word}, {"dst", word}],
      {ifte, ?GT(?ADD(?DIV(ix, 31), ?BYTE(ix, src)), 0),
@@ -454,6 +497,57 @@ builtin_baseX_digits(X) ->
         {ifte, ?EQ(x1, 0), ?V(dgts), ?call({baseX_digits, X}, [?V(x1), ?ADD(dgts, 1)])}),
      word}.
 
+builtin_bytes_to_int(32) ->
+    {[{"w", word}], ?V(w), word};
+builtin_bytes_to_int(N) when N < 32 ->
+    {[{"w", word}], ?BSR(w, 32 - N), word};
+builtin_bytes_to_int(N) when N > 32 ->
+    LastFullWord = N div 32 - 1,
+    Body = case N rem 32 of
+                0 -> ?DEREF(n, ?ADD(b, LastFullWord * 32), ?V(n));
+                R ->
+                    ?DEREF(hi, ?ADD(b, LastFullWord * 32),
+                    ?DEREF(lo, ?ADD(b, (LastFullWord + 1) * 32),
+                    ?ADD(?BSR(lo, 32 - R), ?BSL(hi, R))))
+           end,
+    {[{"b", pointer}], Body, word}.
+
+builtin_bytes_to_str_worker() ->
+    <<Tab:256>> = <<"0123456789ABCDEF________________">>,
+    {[{"w", word}, {"offs", word}, {"acc", word}],
+     {seq, [{ifte, ?AND(?GT(offs, 0), ?EQ(0, ?MOD(offs, 16))),
+                    {seq, [?V(acc), {inline_asm, [?A(?MSIZE), ?A(?MSTORE)]}]},
+                    {inline_asm, []}},
+            {ifte, ?EQ(offs, 32), {inline_asm, [?A(?MSIZE)]},
+                ?LET(b,  ?BYTE(offs, w),
+                ?LET(lo, ?BYTE(?MOD(b, 16), Tab),
+                ?LET(hi, ?BYTE(op('bsr', 4 , b), Tab),
+                ?call(bytes_to_str_worker,
+                      [?V(w), ?ADD(offs, 1), ?ADD(?BSL(acc, 2), ?ADD(?BSL(hi, 1), lo))]))))
+            }
+           ]},
+     word}.
+
+builtin_bytes_to_str(N) when N =< 32 ->
+    {[{"w", word}],
+     ?LET(ret, {inline_asm, [?A(?MSIZE)]},
+     {seq, [?I(N * 2), {inline_asm, [?A(?MSIZE), ?A(?MSTORE)]},
+            ?call(bytes_to_str_worker, [?V(w), ?I(0), ?I(0)]),
+            {inline_asm, [?A(?POP)]},
+            ?V(ret)]}),
+     string};
+builtin_bytes_to_str(N) when N > 32 ->
+    Work = fun(I) ->
+            [?DEREF(w, ?ADD(p, 32 * I), ?call(bytes_to_str_worker, [?V(w), ?I(0), ?I(0)])),
+             {inline_asm, [?A(?POP)]}]
+           end,
+    {[{"p", pointer}],
+     ?LET(ret, {inline_asm, [?A(?MSIZE)]},
+     {seq, [?I(N * 2), {inline_asm, [?A(?MSIZE), ?A(?MSTORE)]}] ++
+           lists:append([ Work(I) || I <- lists:seq(0, (N + 31) div 32 - 1) ]) ++
+           [?V(ret)]}),
+     string}.
+
 builtin_string_reverse() ->
     {[{"s", string}],
      ?DEREF(n, s,

src/aeso_compiler.erl

@@ -11,131 +11,449 @@
 -export([ file/1
         , file/2
         , from_string/2
-        , check_call/2
-        , create_calldata/3
+        , check_call/4
+        , create_calldata/3  %% deprecated
+        , create_calldata/4
         , version/0
         , sophia_type_to_typerep/1
+        , to_sophia_value/4  %% deprecated, need a backend
+        , to_sophia_value/5
+        , decode_calldata/3  %% deprecated
+        , decode_calldata/4
+        , parse/2
+        , add_include_path/2
         ]).
 
 -include_lib("aebytecode/include/aeb_opcodes.hrl").
 -include("aeso_icode.hrl").
 
 
--type option() :: pp_sophia_code | pp_ast | pp_icode | pp_assembler |
-                  pp_bytecode.
+-type option() :: pp_sophia_code
+                | pp_ast
+                | pp_types
+                | pp_typed_ast
+                | pp_icode
+                | pp_assembler
+                | pp_bytecode
+                | {backend, aevm | fate}
+                | {include, {file_system, [string()]} |
+                            {explicit_files, #{string() => binary()}}}
+                | {src_file, string()}.
 -type options() :: [option()].
 
 -export_type([ option/0
              , options/0
              ]).
 
--define(COMPILER_VERSION_1, 1).
--define(COMPILER_VERSION_2, 2).
-
--define(COMPILER_VERSION, ?COMPILER_VERSION_2).
-
--spec version() -> pos_integer().
+-spec version() -> {ok, binary()} | {error, term()}.
 version() ->
-    ?COMPILER_VERSION.
+    case lists:keyfind(aesophia, 1, application:loaded_applications()) of
+        false ->
+            case application:load(aesophia) of
+                ok ->
+                    case application:get_key(aesophia, vsn) of
+                        {ok, VsnString} ->
+                            {ok, list_to_binary(VsnString)};
+                        undefined ->
+                            {error, failed_to_load_aesophia}
+                    end;
+                Err = {error, _} ->
+                    Err
+            end;
+        {_App, _Des, VsnString} ->
+            {ok, list_to_binary(VsnString)}
+    end.
 
--spec file(string()) -> map().
+-spec file(string()) -> {ok, map()} | {error, binary()}.
 file(Filename) ->
     file(Filename, []).
 
--spec file(string(), options()) -> map().
-file(Filename, Options) ->
-    C = read_contract(Filename),
-    from_string(C, Options).
+-spec file(string(), options()) -> {ok, map()} | {error, binary()}.
+file(File, Options0) ->
+    Options = add_include_path(File, Options0),
+    case read_contract(File) of
+        {ok, Bin} -> from_string(Bin, [{src_file, File} | Options]);
+        {error, Error} ->
+	    ErrorString = [File,": ",file:format_error(Error)],
+	    {error, join_errors("File errors", [ErrorString], fun(E) -> E end)}
+    end.
 
--spec from_string(string(), options()) -> map().
-from_string(ContractString, Options) ->
-    Ast = parse(ContractString, Options),
-    ok = pp_sophia_code(Ast, Options),
-    ok = pp_ast(Ast, Options),
-    TypedAst = aeso_ast_infer_types:infer(Ast, Options),
-    %% pp_types is handled inside aeso_ast_infer_types.
-    ok = pp_typed_ast(TypedAst, Options),
-    ICode = to_icode(TypedAst, Options),
-    TypeInfo = extract_type_info(ICode),
-    ok = pp_icode(ICode, Options),
-    Assembler =  assemble(ICode, Options),
-    ok = pp_assembler(Assembler, Options),
+add_include_path(File, Options) ->
+    case lists:keymember(include, 1, Options) of
+        true  -> Options;
+        false ->
+            Dir = filename:dirname(File),
+            {ok, Cwd} = file:get_cwd(),
+            [{include, {file_system, [Cwd, Dir]}} | Options]
+    end.
+
+-spec from_string(binary() | string(), options()) -> {ok, map()} | {error, binary()}.
+from_string(Contract, Options) ->
+    from_string(proplists:get_value(backend, Options, aevm), Contract, Options).
+
+from_string(Backend, ContractBin, Options) when is_binary(ContractBin) ->
+    from_string(Backend, binary_to_list(ContractBin), Options);
+from_string(Backend, ContractString, Options) ->
+    try
+        from_string1(Backend, ContractString, Options)
+    catch
+        %% The compiler errors.
+        error:{parse_errors, Errors} ->
+            {error, join_errors("Parse errors", Errors, fun(E) -> E end)};
+        error:{type_errors, Errors} ->
+            {error, join_errors("Type errors", Errors, fun(E) -> E end)};
+        error:{code_errors, Errors} ->
+            {error, join_errors("Code errors", Errors,
+                                fun (E) -> io_lib:format("~p", [E]) end)}
+        %% General programming errors in the compiler just signal error.
+    end.
+
+from_string1(aevm, ContractString, Options) ->
+    #{icode := Icode} = string_to_code(ContractString, Options),
+    TypeInfo  = extract_type_info(Icode),
+    Assembler = assemble(Icode, Options),
+    pp_assembler(Assembler, Options),
     ByteCodeList = to_bytecode(Assembler, Options),
     ByteCode = << << B:8 >> || B <- ByteCodeList >>,
-    ok = pp_bytecode(ByteCode, Options),
-    #{byte_code => ByteCode, type_info => TypeInfo,
-      contract_source => ContractString,
-      compiler_version => version()}.
+    pp_bytecode(ByteCode, Options),
+    {ok, Version} = version(),
+    {ok, #{byte_code => ByteCode,
+           compiler_version => Version,
+           contract_source => ContractString,
+           type_info => TypeInfo
+          }};
+from_string1(fate, ContractString, Options) ->
+    #{fcode := FCode} = string_to_code(ContractString, Options),
+    FateCode = aeso_fcode_to_fate:compile(FCode, Options),
+    ByteCode = aeb_fate_code:serialize(FateCode, []),
+    {ok, Version} = version(),
+    {ok, #{byte_code => ByteCode,
+           compiler_version => Version,
+           contract_source => ContractString,
+           type_info => [],
+           fate_code => FateCode
+          }}.
 
--define(CALL_NAME, "__call").
+-spec string_to_code(string(), [option()]) -> map().
+string_to_code(ContractString, Options) ->
+    Ast = parse(ContractString, Options),
+    pp_sophia_code(Ast, Options),
+    pp_ast(Ast, Options),
+    {TypeEnv, TypedAst} = aeso_ast_infer_types:infer(Ast, [return_env]),
+    pp_typed_ast(TypedAst, Options),
+    case proplists:get_value(backend, Options, aevm) of
+        aevm ->
+            Icode = ast_to_icode(TypedAst, Options),
+            pp_icode(Icode, Options),
+            #{ icode => Icode,
+               typed_ast => TypedAst,
+               type_env  => TypeEnv};
+        fate ->
+            Fcode = aeso_ast_to_fcode:ast_to_fcode(TypedAst, Options),
+            #{ fcode => Fcode,
+               typed_ast => TypedAst,
+               type_env  => TypeEnv}
+    end.
+
+join_errors(Prefix, Errors, Pfun) ->
+    Ess = [ Pfun(E) || E <- Errors ],
+    list_to_binary(string:join([Prefix|Ess], "\n")).
+
+-define(CALL_NAME,   "__call").
+-define(DECODE_NAME, "__decode").
 
 %% Takes a string containing a contract with a declaration/prototype of a
-%% function (foo, say) and a function __call() = foo(args) calling this
+%% function (foo, say) and adds function __call() = foo(args) calling this
 %% function. Returns the name of the called functions, typereps and Erlang
 %% terms for the arguments.
--spec check_call(string(), options()) -> {ok, string(), {[Type], Type | any}, [term()]} | {error, term()}
+%% NOTE: Special treatment for "init" since it might be implicit and has
+%%       a special return type (typerep, T)
+-spec check_call(string(), string(), [string()], options()) -> {ok, string(), {[Type], Type}, [term()]}
+                                                                   | {ok, string(), [term()]}
+                                                                   | {error, term()}
     when Type :: term().
-check_call(ContractString, Options) ->
-    Ast = parse(ContractString, Options),
-    ok = pp_sophia_code(Ast, Options),
-    ok = pp_ast(Ast, Options),
-    TypedAst = aeso_ast_infer_types:infer(Ast, [permissive_address_literals]),
-    {ok, {FunName, {fun_t, _, _, ArgTypes, RetType}}} = get_call_type(TypedAst),
-    ok = pp_typed_ast(TypedAst, Options),
-    Icode = to_icode(TypedAst, Options),
-    ArgVMTypes = [ aeso_ast_to_icode:ast_typerep(T, Icode) || T <- ArgTypes ],
-    RetVMType  = case RetType of
-                    {id, _, "_"} -> any;
-                    _            -> aeso_ast_to_icode:ast_typerep(RetType, Icode)
-                end,
-    ok = pp_icode(Icode, Options),
-    #{ functions := Funs } = Icode,
-    ArgIcode = get_arg_icode(Funs),
-    try [ icode_to_term(T, Arg) || {T, Arg} <- lists:zip(ArgVMTypes, ArgIcode) ] of
-        ArgTerms ->
-            {ok, FunName, {ArgVMTypes, RetVMType}, ArgTerms}
-    catch throw:Err ->
-        {error, Err}
+check_call(Source, "init" = FunName, Args, Options) ->
+    case check_call1(Source, FunName, Args, Options) of
+        Err = {error, _} when Args == [] ->
+            %% Try with default init-function
+            case check_call1(insert_init_function(Source, Options), FunName, Args, Options) of
+                {error, _} -> Err; %% The first error is most likely better...
+                Res        -> Res
+            end;
+        Res ->
+            Res
+    end;
+check_call(Source, FunName, Args, Options) ->
+    check_call1(Source, FunName, Args, Options).
+
+check_call1(ContractString0, FunName, Args, Options) ->
+    try
+        case proplists:get_value(backend, Options, aevm) of
+            aevm ->
+                %% First check the contract without the __call function
+                #{} = string_to_code(ContractString0, Options),
+                ContractString = insert_call_function(ContractString0, ?CALL_NAME, FunName, Args, Options),
+                #{typed_ast := TypedAst,
+                  icode     := Icode} = string_to_code(ContractString, Options),
+                {ok, {FunName, {fun_t, _, _, ArgTypes, RetType}}} = get_call_type(TypedAst),
+                ArgVMTypes = [ aeso_ast_to_icode:ast_typerep(T, Icode) || T <- ArgTypes ],
+                RetVMType  = case RetType of
+                                 {id, _, "_"} -> any;
+                                 _            -> aeso_ast_to_icode:ast_typerep(RetType, Icode)
+                             end,
+                #{ functions := Funs } = Icode,
+                ArgIcode = get_arg_icode(Funs),
+                ArgTerms = [ icode_to_term(T, Arg) ||
+                               {T, Arg} <- lists:zip(ArgVMTypes, ArgIcode) ],
+                RetVMType1 =
+                    case FunName of
+                        "init" -> {tuple, [typerep, RetVMType]};
+                        _ -> RetVMType
+                    end,
+                {ok, FunName, {ArgVMTypes, RetVMType1}, ArgTerms};
+            fate ->
+                %% First check the contract without the __call function
+                #{fcode := OrgFcode} = string_to_code(ContractString0, Options),
+                FateCode = aeso_fcode_to_fate:compile(OrgFcode, []),
+                %% collect all hashes and compute the first name without hash collision to
+                SymbolHashes = maps:keys(aeb_fate_code:symbols(FateCode)),
+                CallName = first_none_match(?CALL_NAME, SymbolHashes,
+                                            lists:seq($1, $9) ++ lists:seq($A, $Z) ++ lists:seq($a, $z)),
+                ContractString = insert_call_function(ContractString0, CallName, FunName, Args, Options),
+                #{fcode := Fcode} = string_to_code(ContractString, Options),
+                CallArgs = arguments_of_body(CallName, FunName, Fcode),
+                {ok, FunName, CallArgs}
+        end
+    catch
+        error:{parse_errors, Errors} ->
+            {error, join_errors("Parse errors", Errors, fun (E) -> E end)};
+        error:{type_errors, Errors} ->
+            {error, join_errors("Type errors", Errors, fun (E) -> E end)};
+        error:{badmatch, {error, missing_call_function}} ->
+            {error, join_errors("Type errors", ["missing __call function"],
+                                fun (E) -> E end)};
+        throw:Error ->                          %Don't ask
+            {error, join_errors("Code errors", [Error],
+                                fun (E) -> io_lib:format("~p", [E]) end)}
     end.
 
--spec create_calldata(map(), string(), string()) ->
-                             {ok, binary(), aeso_sophia:type(), aeso_sophia:type()}
-                                 | {error, argument_syntax_error}.
-create_calldata(Contract, "", CallCode) when is_map(Contract) ->
-    case check_call(CallCode, []) of
-        {ok, FunName, {ArgTypes, RetType}, Args} ->
-            aeso_abi:create_calldata(Contract, FunName, Args, ArgTypes, RetType);
+arguments_of_body(CallName, _FunName, Fcode) ->
+    #{body := Body} = maps:get({entrypoint, list_to_binary(CallName)}, maps:get(functions, Fcode)),
+    {def, _FName, Args} = Body,
+    %% FName is either {entrypoint, list_to_binary(FunName)} or 'init'
+    [ aeso_fcode_to_fate:term_to_fate(A) || A <- Args ].
+
+first_none_match(_CallName, _Hashes, []) ->
+    error(unable_to_find_unique_call_name);
+first_none_match(CallName, Hashes, [Char|Chars]) ->
+    case not lists:member(aeb_fate_code:symbol_identifier(list_to_binary(CallName)), Hashes) of
+        true ->
+            CallName;
+        false ->
+            first_none_match(?CALL_NAME++[Char], Hashes, Chars)
+    end.
+
+%% Add the __call function to a contract.
+-spec insert_call_function(string(), string(), string(), [string()], options()) -> string().
+insert_call_function(Code, Call, FunName, Args, Options) ->
+    Ast = parse(Code, Options),
+    Ind = last_contract_indent(Ast),
+    lists:flatten(
+        [ Code,
+          "\n\n",
+          lists:duplicate(Ind, " "),
+          "stateful entrypoint ", Call, "() = ", FunName, "(", string:join(Args, ","), ")\n"
+        ]).
+
+-spec insert_init_function(string(), options()) -> string().
+insert_init_function(Code, Options) ->
+    Ast = parse(Code, Options),
+    Ind = last_contract_indent(Ast),
+    lists:flatten(
+        [ Code,
+          "\n\n",
+          lists:duplicate(Ind, " "), "entrypoint init() = ()\n"
+        ]).
+
+last_contract_indent(Decls) ->
+    case lists:last(Decls) of
+        {_, _, _, [Decl | _]} -> aeso_syntax:get_ann(col, Decl, 1) - 1;
+        _                     -> 0
+    end.
+
+-spec to_sophia_value(string(), string(), ok | error | revert, aeb_aevm_data:data()) ->
+        {ok, aeso_syntax:expr()} | {error, term()}.
+to_sophia_value(ContractString, Fun, ResType, Data) ->
+    to_sophia_value(ContractString, Fun, ResType, Data, [{backend, aevm}]).
+
+-spec to_sophia_value(string(), string(), ok | error | revert, binary(), options()) ->
+        {ok, aeso_syntax:expr()} | {error, term()}.
+to_sophia_value(_, _, error, Err, _Options) ->
+    {ok, {app, [], {id, [], "error"}, [{string, [], Err}]}};
+to_sophia_value(_, _, revert, Data, _Options) ->
+    case aeb_heap:from_binary(string, Data) of
+        {ok, Err} -> {ok, {app, [], {id, [], "abort"}, [{string, [], Err}]}};
         {error, _} = Err -> Err
     end;
-create_calldata(Contract, Function, Argument) when is_map(Contract) ->
-    %% Slightly hacky shortcut to let you get away without writing the full
-    %% call contract code.
-    %% Function should be "foo : type", and
-    %% Argument should be "Arg1, Arg2, .., ArgN" (no parens)
-    case string:lexemes(Function, ": ") of
-                     %% If function is a single word fallback to old calldata generation
-        [FunName] -> aeso_abi:old_create_calldata(Contract, FunName, Argument);
-        [FunName | _] ->
-            Args    = lists:map(fun($\n) -> 32; (X) -> X end, Argument),    %% newline to space
-            CallContract = lists:flatten(
-                [ "contract Call =\n"
-                , "  function ", Function, "\n"
-                , "  function __call() = ", FunName, "(", Args, ")"
-                ]),
-            create_calldata(Contract, "", CallContract)
+to_sophia_value(ContractString, FunName, ok, Data, Options) ->
+    try
+        Code = string_to_code(ContractString, Options),
+        #{ typed_ast := TypedAst, type_env  := TypeEnv} = Code,
+        {ok, _, Type0} = get_decode_type(FunName, TypedAst),
+        Type   = aeso_ast_infer_types:unfold_types_in_type(TypeEnv, Type0, [unfold_record_types, unfold_variant_types]),
+
+        case proplists:get_value(backend, Options, aevm) of
+            aevm ->
+                Icode  = maps:get(icode, Code),
+                VmType = aeso_ast_to_icode:ast_typerep(Type, Icode),
+                case aeb_heap:from_binary(VmType, Data) of
+                    {ok, VmValue} ->
+                        try
+                            {ok, aeso_vm_decode:from_aevm(VmType, Type, VmValue)}
+                        catch throw:cannot_translate_to_sophia ->
+                            Type0Str = prettypr:format(aeso_pretty:type(Type0)),
+                            {error, join_errors("Translation error", [lists:flatten(io_lib:format("Cannot translate VM value ~p\n  of type ~p\n  to Sophia type ~s\n",
+                                                                                    [Data, VmType, Type0Str]))],
+                                                fun (E) -> E end)}
+                        end;
+                    {error, _Err} ->
+                        {error, join_errors("Decode errors", [lists:flatten(io_lib:format("Failed to decode binary at type ~p", [VmType]))],
+                                            fun(E) -> E end)}
+                end;
+            fate ->
+               try
+                   {ok, aeso_vm_decode:from_fate(Type, aeb_fate_encoding:deserialize(Data))}
+               catch throw:cannot_translate_to_sophia ->
+                   {error, join_errors("Translation error",
+                                       [lists:flatten(io_lib:format("Cannot translate fate value ~p\n of Sophia type ~s\n",
+                                                                    [aeb_fate_encoding:deserialize(Data), Type]))],
+                                       fun (E) -> E end)};
+                     _:R ->
+                   {error, iolist_to_binary(io_lib:format("Decode error ~p: ~p\n", [R, erlang:get_stacktrace()]))}
+               end
+        end
+    catch
+        error:{parse_errors, Errors} ->
+            {error, join_errors("Parse errors", Errors, fun (E) -> E end)};
+        error:{type_errors, Errors} ->
+            {error, join_errors("Type errors", Errors, fun (E) -> E end)};
+        error:{badmatch, {error, missing_function}} ->
+            {error, join_errors("Type errors", ["no function: '" ++ FunName ++ "'"],
+                                fun (E) -> E end)};
+        throw:Error ->                          %Don't ask
+            {error, join_errors("Code errors", [Error],
+                                fun (E) -> io_lib:format("~p", [E]) end)}
     end.
 
 
+-spec create_calldata(string(), string(), [string()]) ->
+                             {ok, binary(), aeb_aevm_data:type(), aeb_aevm_data:type()}
+                             | {error, term()}.
+create_calldata(Code, Fun, Args) ->
+    create_calldata(Code, Fun, Args, [{backend, aevm}]).
+
+-spec create_calldata(string(), string(), [string()], [{atom(), any()}]) ->
+                             {ok, binary()}
+                             | {error, term()}.
+create_calldata(Code, Fun, Args, Options) ->
+    case proplists:get_value(backend, Options, aevm) of
+        aevm ->
+            case check_call(Code, Fun, Args, Options) of
+                {ok, FunName, {ArgTypes, RetType}, VMArgs} ->
+                    aeb_aevm_abi:create_calldata(FunName, VMArgs, ArgTypes, RetType);
+                {error, _} = Err -> Err
+            end;
+        fate ->
+            case check_call(Code, Fun, Args, Options) of
+                {ok, FunName, FateArgs} ->
+                    aeb_fate_abi:create_calldata(FunName, FateArgs);
+                {error, _} = Err -> Err
+            end
+    end.
+
+-spec decode_calldata(string(), string(), binary()) ->
+                             {ok, [aeso_syntax:type()], [aeso_syntax:expr()]}
+                             | {error, term()}.
+decode_calldata(ContractString, FunName, Calldata) ->
+    decode_calldata(ContractString, FunName, Calldata, [{backend, aevm}]).
+
+decode_calldata(ContractString, FunName, Calldata, Options) ->
+    try
+        Code = string_to_code(ContractString, Options),
+        #{ typed_ast := TypedAst, type_env  := TypeEnv} = Code,
+
+        {ok, Args, _} = get_decode_type(FunName, TypedAst),
+        DropArg       = fun({arg, _, _, T}) -> T; (T) -> T end,
+        ArgTypes      = lists:map(DropArg, Args),
+        Type0         = {tuple_t, [], ArgTypes},
+        %% user defined data types such as variants needed to match against
+        Type          = aeso_ast_infer_types:unfold_types_in_type(TypeEnv, Type0, [unfold_record_types, unfold_variant_types]),
+        case proplists:get_value(backend, Options, aevm) of
+            aevm ->
+                Icode  = maps:get(icode, Code),
+                VmType = aeso_ast_to_icode:ast_typerep(Type, Icode),
+                case aeb_heap:from_binary({tuple, [word, VmType]}, Calldata) of
+                    {ok, {_, VmValue}} ->
+                        try
+                            {tuple, [], Values} = aeso_vm_decode:from_aevm(VmType, Type, VmValue),
+                            %% Values are Sophia expressions in AST format
+                            {ok, ArgTypes, Values}
+                        catch throw:cannot_translate_to_sophia ->
+                                Type0Str = prettypr:format(aeso_pretty:type(Type0)),
+                                {error, join_errors("Translation error",
+                                                    [lists:flatten(io_lib:format("Cannot translate VM value ~p\n  of type ~p\n  to Sophia type ~s\n",
+                                                                                 [VmValue, VmType, Type0Str]))],
+                                                    fun (E) -> E end)}
+                        end;
+                    {error, _Err} ->
+                        {error, join_errors("Decode errors", [lists:flatten(io_lib:format("Failed to decode binary at type ~p", [VmType]))],
+                                            fun(E) -> E end)}
+                end;
+            fate ->
+                case aeb_fate_abi:decode_calldata(FunName, Calldata) of
+                    {ok, FateArgs} ->
+                        try
+                            {tuple_t, [], ArgTypes1} = Type,
+                            AstArgs = [ aeso_vm_decode:from_fate(ArgType, FateArg)
+                                        || {ArgType, FateArg} <- lists:zip(ArgTypes1, FateArgs)],
+                            {ok, ArgTypes, AstArgs}
+                        catch throw:cannot_translate_to_sophia ->
+                                Type0Str = prettypr:format(aeso_pretty:type(Type0)),
+                                {error, join_errors("Translation error",
+                                                    [lists:flatten(io_lib:format("Cannot translate fate value ~p\n of Sophia type ~s\n",
+                                                                                 [FateArgs, Type0Str]))],
+                                                    fun (E) -> E end)}
+                        end;
+                    {error, _} ->
+                        {error, join_errors("Decode errors", ["Failed to decode binary"],
+                                            fun(E) -> E end)}
+                end
+        end
+    catch
+        error:{parse_errors, Errors} ->
+            {error, join_errors("Parse errors", Errors, fun (E) -> E end)};
+        error:{type_errors, Errors} ->
+            {error, join_errors("Type errors", Errors, fun (E) -> E end)};
+        error:{badmatch, {error, missing_function}} ->
+            {error, join_errors("Type errors", ["no function: '" ++ FunName ++ "'"],
+                                fun (E) -> E end)};
+        throw:Error ->                          %Don't ask
+            {error, join_errors("Code errors", [Error],
+                                fun (E) -> io_lib:format("~p", [E]) end)}
+    end.
+
 get_arg_icode(Funs) ->
-    [Args] = [ Args || {?CALL_NAME, _, _, {funcall, _, Args}, _} <- Funs ],
-    Args.
+    case [ Args || {[_, ?CALL_NAME], _, _, {funcall, _, Args}, _} <- Funs ] of
+        [Args] -> Args;
+        []     -> error({missing_call_function, Funs})
+    end.
 
 get_call_type([{contract, _, _, Defs}]) ->
-    case [ {FunName, FunType}
+    case [ {lists:last(QFunName), FunType}
           || {letfun, _, {id, _, ?CALL_NAME}, [], _Ret,
                 {typed, _,
                     {app, _,
-                        {typed, _, {id, _, FunName}, FunType}, _}, _}} <- Defs ] of
+                        {typed, _, {qid, _, QFunName}, FunType}, _}, _}} <- Defs ] of
         [Call] -> {ok, Call};
         []     -> {error, missing_call_function}
     end;
@@ -143,9 +461,26 @@ get_call_type([_ | Contracts]) ->
     %% The __call should be in the final contract
     get_call_type(Contracts).
 
+get_decode_type(FunName, [{contract, _, _, Defs}]) ->
+    GetType = fun({letfun, _, {id, _, Name}, Args, Ret, _})               when Name == FunName -> [{Args, Ret}];
+                 ({fun_decl, _, {id, _, Name}, {fun_t, _, _, Args, Ret}}) when Name == FunName -> [{Args, Ret}];
+                 (_) -> [] end,
+    case lists:flatmap(GetType, Defs) of
+        [{Args, Ret}] -> {ok, Args, Ret};
+        []            ->
+            case FunName of
+                "init" -> {ok, [], {tuple_t, [], []}};
+                 _ -> {error, missing_function}
+            end
+    end;
+get_decode_type(FunName, [_ | Contracts]) ->
+    %% The __decode should be in the final contract
+    get_decode_type(FunName, Contracts).
+
 %% Translate an icode value (error if not value) to an Erlang term that can be
-%% consumed by aeso_heap:to_binary().
+%% consumed by aeb_heap:to_binary().
 icode_to_term(word, {integer, N}) -> N;
+icode_to_term(word, {unop, '-', {integer, N}}) -> -N;
 icode_to_term(string, {tuple, [{integer, Len} | Words]}) ->
     <<Str:Len/binary, _/binary>> = << <<W:256>> || {integer, W} <- Words >>,
     Str;
@@ -177,10 +512,7 @@ icode_to_term(T, V) ->
 icodes_to_terms(Ts, Vs) ->
     [ icode_to_term(T, V) || {T, V} <- lists:zip(Ts, Vs) ].
 
-parse(C,_Options) ->
-    parse_string(C).
-
-to_icode(TypedAst, Options) ->
+ast_to_icode(TypedAst, Options) ->
     aeso_ast_to_icode:convert_typed(TypedAst, Options).
 
 assemble(Icode, Options) ->
@@ -194,7 +526,9 @@ to_bytecode([Op|Rest], Options) ->
 to_bytecode([], _) -> [].
 
 extract_type_info(#{functions := Functions} =_Icode) ->
-    TypeInfo = [aeso_abi:function_type_info(list_to_binary(Name), Args, TypeRep)
+    ArgTypesOnly = fun(As) -> [ T || {_, T} <- As ] end,
+    TypeInfo = [aeb_aevm_abi:function_type_info(list_to_binary(lists:last(Name)),
+                                            ArgTypesOnly(Args), TypeRep)
                 || {Name, Attrs, Args,_Body, TypeRep} <- Functions,
                    not is_tuple(Name),
                    not lists:member(private, Attrs)
@@ -229,9 +563,9 @@ sophia_type_to_typerep(String) ->
     catch _:_ -> {error, bad_type}
     end.
 
-parse_string(Text) ->
+parse(Text, Options) ->
     %% Try and return something sensible here!
-    case aeso_parser:string(Text) of
+    case aeso_parser:string(Text, Options) of
         %% Yay, it worked!
         {ok, Contract} -> Contract;
         %% Scan errors.
@@ -244,14 +578,22 @@ parse_string(Text) ->
             parse_error(Pos, Error);
         {error, {Pos, ambiguous_parse, As}} ->
             ErrorString = io_lib:format("Ambiguous ~p", [As]),
-            parse_error(Pos, ErrorString)
+            parse_error(Pos, ErrorString);
+        %% Include error
+        {error, {Pos, include_error, File}} ->
+            parse_error(Pos, io_lib:format("could not find include file '~s'", [File]))
     end.
 
-parse_error({Line,Pos}, ErrorString) ->
-    Error = io_lib:format("line ~p, column ~p: ~s", [Line,Pos,ErrorString]),
-    error({parse_errors,[Error]}).
+parse_error(Pos, ErrorString) ->
+    Error = io_lib:format("~s: ~s", [pos_error(Pos), ErrorString]),
+    error({parse_errors, [Error]}).
 
 read_contract(Name) ->
-    {ok, Bin} = file:read_file(Name),
-    binary_to_list(Bin).
+    file:read_file(Name).
 
+pos_error({Line, Pos}) ->
+    io_lib:format("line ~p, column ~p", [Line, Pos]);
+pos_error({no_file, Line, Pos}) ->
+    pos_error({Line, Pos});
+pos_error({File, Line, Pos}) ->
+    io_lib:format("file ~s, line ~p, column ~p", [File, Line, Pos]).

src/aeso_heap.erl

@@ -1,301 +0,0 @@
--module(aeso_heap).
-
--export([ to_binary/1
-        , to_binary/2
-        , from_heap/3
-        , from_binary/2
-        , from_binary/3
-        , maps_with_next_id/1
-        , set_next_id/2
-        , heap_fragment/3
-        , heap_value/3
-        , heap_value/4
-        , heap_value_pointer/1
-        , heap_value_maps/1
-        , heap_value_offset/1
-        , heap_value_heap/1
-        , heap_fragment_maps/1
-        , heap_fragment_offset/1
-        , heap_fragment_heap/1
-        ]).
-
--export_type([binary_value/0, heap_value/0, offset/0, heap_fragment/0]).
-
--include("aeso_icode.hrl").
--include_lib("aesophia/include/aeso_heap.hrl").
-
--type word()            :: non_neg_integer().
--type pointer()         :: word().
--opaque heap_fragment() :: #heap{}.
--type offset()          :: non_neg_integer().
--type binary_value()    :: binary().
--type heap_value()      :: {pointer(), heap_fragment()}.
-
-
--spec maps_with_next_id(heap_fragment()) -> #maps{}.
-%% Create just a maps value, don't keep rest of Heap
-maps_with_next_id(#heap{maps = #maps{next_id = N}}) ->
-    #maps{ next_id = N }.
-
--spec set_next_id(heap_fragment(), non_neg_integer()) -> heap_fragment().
-set_next_id(Heap, N) -> 
-    Heap#heap{ maps = Heap#heap.maps#maps{ next_id = N } }.
-
-%% -- data type heap_fragment
-
--spec heap_fragment(binary() | #{non_neg_integer() => non_neg_integer()}) -> heap_fragment().
-heap_fragment(Heap) ->
-    heap_fragment(#maps{ next_id = 0 }, 0, Heap).
-
--spec heap_fragment(#maps{}, offset(), 
-                    binary() | #{non_neg_integer() => non_neg_integer()}) -> heap_fragment().
-heap_fragment(Maps, Offset, Heap) ->
-    #heap{maps = Maps, offset = Offset, heap = Heap}.
-
--spec heap_fragment_maps(heap_fragment()) -> #maps{}.
-heap_fragment_maps(#heap{maps = Maps}) ->
-    Maps.
-
--spec heap_fragment_offset(heap_fragment()) -> offset().
-heap_fragment_offset(#heap{offset = Offs}) ->
-    Offs.
-
--spec heap_fragment_heap(heap_fragment()) -> binary() | #{non_neg_integer() => non_neg_integer()}.
-heap_fragment_heap(#heap{heap = Heap}) ->
-    Heap.
-
-
-%% -- data type heap_value
-
--spec heap_value(#maps{}, pointer(), 
-                 binary() | #{non_neg_integer() => non_neg_integer()}) -> heap_value().
-heap_value(Maps, Ptr, Heap) ->
-    heap_value(Maps, Ptr, Heap, 0).
-
--spec heap_value(#maps{}, pointer(), 
-                 binary() | #{non_neg_integer() => non_neg_integer()}, offset()) -> heap_value().
-heap_value(Maps, Ptr, Heap, Offs) ->
-    {Ptr, heap_fragment(Maps, Offs, Heap)}.
-
--spec heap_value_pointer(heap_value()) -> pointer().
-heap_value_pointer({Ptr, _}) -> Ptr.
-
--spec heap_value_maps(heap_value()) -> #maps{}.
-heap_value_maps({_, Heap}) -> Heap#heap.maps.
-
--spec heap_value_offset(heap_value()) -> offset().
-heap_value_offset({_, Heap}) -> Heap#heap.offset.
-
--spec heap_value_heap(heap_value()) -> 
-                             binary() | #{non_neg_integer() => non_neg_integer()}.
-heap_value_heap({_, Heap}) -> Heap#heap.heap.
-    
-%% -- Value to binary --------------------------------------------------------
-
--spec to_binary(aeso_sophia:data()) -> aeso_sophia:heap().
-%% Encode the data as a heap where the first word is the value (for unboxed
-%% types) or a pointer to the value (for boxed types).
-to_binary(Data) ->
-    to_binary(Data, 0).
-
-to_binary(Data, BaseAddress) ->
-    {Address, Memory} = to_binary1(Data, BaseAddress + 32),
-    R = <<Address:256, Memory/binary>>,
-    R.
-
-
-%% Allocate the data in memory, from the given address.  Return a pair
-%% of memory contents from that address and the value representing the
-%% data.
-to_binary1(Data,_Address) when is_integer(Data) ->
-    {Data,<<>>};
-to_binary1(Data, Address) when is_binary(Data) ->
-    %% a string
-    Words = aeso_memory:binary_to_words(Data),
-    {Address,<<(size(Data)):256, << <<W:256>> || W <- Words>>/binary>>};
-to_binary1(none, Address)            -> to_binary1({variant, 0, []}, Address);
-to_binary1({some, Value}, Address)   -> to_binary1({variant, 1, [Value]}, Address);
-to_binary1(word, Address)            -> to_binary1({?TYPEREP_WORD_TAG}, Address);
-to_binary1(string, Address)          -> to_binary1({?TYPEREP_STRING_TAG}, Address);
-to_binary1(typerep, Address)         -> to_binary1({?TYPEREP_TYPEREP_TAG}, Address);
-to_binary1(function, Address)        -> to_binary1({?TYPEREP_FUN_TAG}, Address);
-to_binary1({list, T}, Address)       -> to_binary1({?TYPEREP_LIST_TAG, T}, Address);
-to_binary1({option, T}, Address)     -> to_binary1({variant, [[], [T]]}, Address);
-to_binary1({tuple, Ts}, Address)     -> to_binary1({?TYPEREP_TUPLE_TAG, Ts}, Address);
-to_binary1({variant, Cons}, Address) -> to_binary1({?TYPEREP_VARIANT_TAG, Cons}, Address);
-to_binary1({map, K, V}, Address)     -> to_binary1({?TYPEREP_MAP_TAG, K, V}, Address);
-to_binary1({variant, Tag, Args}, Address) ->
-    to_binary1(list_to_tuple([Tag | Args]), Address);
-to_binary1(Map, Address) when is_map(Map) ->
-    Size = maps:size(Map),
-    %% Sort according to binary ordering
-    KVs = lists:sort([ {to_binary(K), to_binary(V)} || {K, V} <- maps:to_list(Map) ]),
-    {Address, <<Size:256, << <<(byte_size(K)):256, K/binary,
-                               (byte_size(V)):256, V/binary>> || {K, V} <- KVs >>/binary >>};
-to_binary1({}, _Address) ->
-    {0, <<>>};
-to_binary1(Data, Address) when is_tuple(Data) ->
-    {Elems,Memory} = to_binaries(tuple_to_list(Data),Address+32*size(Data)),
-    ElemsBin = << <<W:256>> || W <- Elems>>,
-    {Address,<< ElemsBin/binary, Memory/binary >>};
-to_binary1([],_Address) ->
-    <<Nil:256>> = <<(-1):256>>,
-    {Nil,<<>>};
-to_binary1([H|T],Address) ->
-    to_binary1({H,T},Address).
-
-
-to_binaries([],_Address) ->
-    {[],<<>>};
-to_binaries([H|T],Address) ->
-    {HRep,HMem} = to_binary1(H,Address),
-    {TRep,TMem} = to_binaries(T,Address+size(HMem)),
-    {[HRep|TRep],<<HMem/binary, TMem/binary>>}.
-
-%% Interpret a return value (a binary) using a type rep.
-
--spec from_heap(Type :: ?Type(), Heap :: binary(), Ptr :: integer()) ->
-        {ok, term()} | {error, term()}.
-from_heap(Type, Heap, Ptr) ->
-    try {ok, from_binary(#{}, Type, Heap, Ptr)}
-    catch _:Err ->
-        %% io:format("** Error: from_heap failed with ~p\n  ~p\n", [Err, erlang:get_stacktrace()]),
-        {error, Err}
-    end.
-
-%% Base address is the address of the first word of the given heap.
--spec from_binary(T :: ?Type(),
-                  Heap :: binary(),
-                  BaseAddr :: non_neg_integer()) ->
-        {ok, term()} | {error, term()}.
-from_binary(T, Heap = <<V:256, _/binary>>, BaseAddr) ->
-    from_heap(T, <<0:BaseAddr/unit:8, Heap/binary>>, V);
-from_binary(_, Bin, _BaseAddr) ->
-    {error, {binary_too_short, Bin}}.
-
--spec from_binary(?Type(), binary()) -> {ok, term()} | {error, term()}.
-from_binary(T, Heap) ->
-    from_binary(T, Heap, 0).
-
-from_binary(_, word, _, V) ->
-    V;
-from_binary(_, signed_word, _, V) ->
-    <<N:256/signed>> = <<V:256>>,
-    N;
-from_binary(_, bool, _, V) ->
-    case V of
-        0 -> false;
-        1 -> true
-    end;
-from_binary(_, string, Heap, V) ->
-    StringSize = heap_word(Heap,V),
-    BitAddr = 8*(V+32),
-    <<_:BitAddr,Bytes:StringSize/binary,_/binary>> = Heap,
-    Bytes;
-from_binary(_, {tuple, []}, _, _) ->
-    {};
-from_binary(Visited, {tuple,Cpts}, Heap, V) ->
-    check_circular_refs(Visited, V),
-    NewVisited = Visited#{V => true},
-    ElementNums = lists:seq(0, length(Cpts)-1),
-    TypesAndPointers = lists:zip(Cpts, ElementNums),
-    ElementAddress = fun(Index) -> V + 32 * Index end,
-    Element = fun(Index) ->
-                      heap_word(Heap, ElementAddress(Index))
-              end,
-    Convert = fun(Type, Index) ->
-                from_binary(NewVisited, Type, Heap, Element(Index))
-              end,
-    Elements = [Convert(T, I) || {T,I} <- TypesAndPointers],
-    list_to_tuple(Elements);
-from_binary(Visited, {list, Elem}, Heap, V) ->
-    <<Nil:256>> = <<(-1):256>>,
-    if V==Nil ->
-          [];
-       true ->
-          {H,T} = from_binary(Visited, {tuple,[Elem,{list,Elem}]},Heap,V),
-          [H|T]
-    end;
-from_binary(Visited, {option, A}, Heap, V) ->
-    from_binary(Visited, {variant_t, [{none, []}, {some, [A]}]}, Heap, V);
-from_binary(Visited, {variant, Cons}, Heap, V) ->
-    Tag      = heap_word(Heap, V),
-    Args     = lists:nth(Tag + 1, Cons),
-    Visited1 = Visited#{V => true},
-    {variant, Tag, tuple_to_list(from_binary(Visited1, {tuple, Args}, Heap, V + 32))};
-from_binary(Visited, {variant_t, TCons}, Heap, V) ->   %% Tagged variants
-    {Tags, Cons} = lists:unzip(TCons),
-    {variant, I, Args} = from_binary(Visited, {variant, Cons}, Heap, V),
-    Tag = lists:nth(I + 1, Tags),
-    case Args of
-        []  -> Tag;
-        _   -> list_to_tuple([Tag | Args])
-    end;
-from_binary(_Visited, {map, A, B}, Heap, Ptr) ->
-    %% FORMAT: [Size] [KeySize] Key [ValSize] Val .. [KeySize] Key [ValSize] Val
-    Size = heap_word(Heap, Ptr),
-    map_binary_to_value(A, B, Size, Heap, Ptr + 32);
-from_binary(Visited, typerep, Heap, V) ->
-    check_circular_refs(Visited, V),
-    Tag = heap_word(Heap, V),
-    Arg1 = fun(T, I) -> from_binary(Visited#{V => true}, T, Heap, heap_word(Heap, V + 32 * I)) end,
-    Arg  = fun(T) -> Arg1(T, 1) end,
-    case Tag of
-        ?TYPEREP_WORD_TAG    -> word;
-        ?TYPEREP_STRING_TAG  -> string;
-        ?TYPEREP_TYPEREP_TAG -> typerep;
-        ?TYPEREP_LIST_TAG    -> {list,    Arg(typerep)};
-        ?TYPEREP_TUPLE_TAG   -> {tuple,   Arg({list, typerep})};
-        ?TYPEREP_VARIANT_TAG -> {variant, Arg({list, {list, typerep}})};
-        ?TYPEREP_MAP_TAG     -> {map,     Arg(typerep), Arg1(typerep, 2)};
-        ?TYPEREP_FUN_TAG     -> function
-    end.
-
-map_binary_to_value(KeyType, ValType, N, Bin, Ptr) ->
-    %% Avoid looping on bogus sizes
-    MaxN = byte_size(Bin) div 64,
-    Heap = heap_fragment(Bin),
-    map_from_binary({value, KeyType, ValType}, min(N, MaxN), Heap, Ptr, #{}).
-
-map_from_binary(_, 0, _, _, Map) -> Map;
-map_from_binary({value, KeyType, ValType} = Output, I, Heap, Ptr, Map) ->
-    KeySize = get_word(Heap, Ptr),
-    KeyPtr  = Ptr + 32,
-    KeyBin  = get_chunk(Heap, KeyPtr, KeySize),
-    ValSize = get_word(Heap, KeyPtr + KeySize),
-    ValPtr  = KeyPtr + KeySize + 32,
-    ValBin  = get_chunk(Heap, ValPtr, ValSize),
-    %% Keys and values are self contained binaries
-    {ok, Key} = from_binary(KeyType, KeyBin),
-    {ok, Val} = from_binary(ValType, ValBin),
-    map_from_binary(Output, I - 1, Heap, ValPtr + ValSize,  Map#{Key => Val}).
-
-check_circular_refs(Visited, V) ->
-    case maps:is_key(V, Visited) of
-        true ->  exit(circular_references);
-        false -> ok
-    end.
-
-heap_word(Heap, Addr) when is_binary(Heap) ->
-    BitSize = 8*Addr,
-    <<_:BitSize,W:256,_/binary>> = Heap,
-    W;
-heap_word(Heap, Addr) when is_map(Heap) ->
-    0 = Addr rem 32, %% Check that it's word aligned.
-    maps:get(Addr, Heap, 0).
-
-get_word(#heap{offset = Offs, heap = Mem}, Addr) when Addr >= Offs ->
-    get_word(Mem, Addr - Offs);
-get_word(Mem, Addr) when is_binary(Mem) ->
-    <<_:Addr/unit:8, Word:256, _/binary>> = Mem,
-    Word.
-
-get_chunk(#heap{offset = Offs, heap = Mem}, Addr, Bytes) when Addr >= Offs ->
-    get_chunk(Mem, Addr - Offs, Bytes);
-get_chunk(Mem, Addr, Bytes) when is_binary(Mem) ->
-    <<_:Addr/unit:8, Chunk:Bytes/binary, _/binary>> = Mem,
-    Chunk.
-
-
-
-

src/aeso_icode.erl

@@ -9,19 +9,30 @@
 %%%-------------------------------------------------------------------
 -module(aeso_icode).
 
--export([new/1, pp/1, set_name/2, set_functions/2, map_typerep/2, option_typerep/1, get_constructor_tag/2]).
+-export([new/1,
+         pp/1,
+         set_name/2,
+         set_namespace/2,
+         enter_namespace/2,
+         get_namespace/1,
+         qualify/2,
+         set_functions/2,
+         map_typerep/2,
+         option_typerep/1,
+         get_constructor_tag/2]).
+
 -export_type([icode/0]).
 
 -include("aeso_icode.hrl").
 
--type type_def() :: fun(([aeso_sophia:type()]) -> aeso_sophia:type()).
+-type type_def() :: fun(([aeb_aevm_data:type()]) -> aeb_aevm_data:type()).
 
 -type bindings() :: any().
 -type fun_dec() :: { string()
                    , [modifier()]
                    , arg_list()
                    , expr()
-                   , aeso_sophia:type()}.
+                   , aeb_aevm_data:type()}.
 
 -type modifier() :: private | stateful.
 
@@ -29,12 +40,13 @@
 
 -type icode() :: #{ contract_name => string()
                   , functions => [fun_dec()]
+                  , namespace => aeso_syntax:con() | aeso_syntax:qcon()
                   , env => [bindings()]
-                  , state_type => aeso_sophia:type()
-                  , event_type => aeso_sophia:type()
+                  , state_type => aeb_aevm_data:type()
+                  , event_type => aeb_aevm_data:type()
                   , types => #{ type_name() => type_def() }
-                  , type_vars => #{ string() => aeso_sophia:type() }
-                  , constructors => #{ string() => integer() }  %% name to tag
+                  , type_vars => #{ string() => aeb_aevm_data:type() }
+                  , constructors => #{ [string()] => integer() }  %% name to tag
                   , options => [any()]
                   }.
 
@@ -59,6 +71,7 @@ builtin_types() ->
     Word = fun([]) -> word end,
     #{ "bool"         => Word
      , "int"          => Word
+     , "bits"         => Word
      , "string"       => fun([]) -> string end
      , "address"      => Word
      , "hash"         => Word
@@ -72,10 +85,10 @@ builtin_types() ->
      }.
 
 builtin_constructors() ->
-    #{ "RelativeTTL" => 0
-     , "FixedTTL"    => 1
-     , "None"        => 0
-     , "Some"        => 1 }.
+    #{ ["RelativeTTL"] => 0
+     , ["FixedTTL"]    => 1
+     , ["None"]        => 0
+     , ["Some"]        => 1 }.
 
 map_typerep(K, V) ->
     {map, K, V}.
@@ -90,11 +103,30 @@ new_env() ->
 set_name(Name, Icode) ->
     maps:put(contract_name, Name, Icode).
 
+-spec set_namespace(aeso_syntax:con() | aeso_syntax:qcon(), icode()) -> icode().
+set_namespace(NS, Icode) -> Icode#{ namespace => NS }.
+
+-spec enter_namespace(aeso_syntax:con(), icode()) -> icode().
+enter_namespace(NS, Icode = #{ namespace := NS1 }) ->
+    Icode#{ namespace => aeso_syntax:qualify(NS1, NS) };
+enter_namespace(NS, Icode) ->
+    Icode#{ namespace => NS }.
+
+-spec get_namespace(icode()) -> false | aeso_syntax:con() | aeso_syntax:qcon().
+get_namespace(Icode) -> maps:get(namespace, Icode, false).
+
+-spec qualify(aeso_syntax:id() | aeso_syntax:con(), icode()) -> aeso_syntax:id() | aeso_syntax:qid() | aeso_syntax:con() | aeso_syntax:qcon().
+qualify(X, Icode) ->
+    case get_namespace(Icode) of
+        false -> X;
+        NS    -> aeso_syntax:qualify(NS, X)
+    end.
+
 -spec set_functions([fun_dec()], icode()) -> icode().
 set_functions(NewFuns, Icode) ->
     maps:put(functions, NewFuns, Icode).
 
--spec get_constructor_tag(string(), icode()) -> integer().
+-spec get_constructor_tag([string()], icode()) -> integer().
 get_constructor_tag(Name, #{constructors := Constructors}) ->
     case maps:get(Name, Constructors, undefined) of
         undefined -> error({undefined_constructor, Name});

src/aeso_icode.hrl

@@ -1,14 +1,5 @@
 
--define(Type(), aeso_sophia:type()).
-
--define(TYPEREP_WORD_TAG,   0).
--define(TYPEREP_STRING_TAG, 1).
--define(TYPEREP_LIST_TAG,   2).
--define(TYPEREP_TUPLE_TAG,  3).
--define(TYPEREP_VARIANT_TAG, 4).
--define(TYPEREP_TYPEREP_TAG, 5).
--define(TYPEREP_MAP_TAG,     6).
--define(TYPEREP_FUN_TAG,     7).
+-include_lib("aebytecode/include/aeb_typerep_def.hrl").
 
 -record(arg, {name::string(), type::?Type()}).
 
@@ -20,7 +11,7 @@
                  , args :: arg_list()
                  , body :: expr()}).
 
--record(var_ref, { name :: string() | {builtin, atom() | tuple()}}).
+-record(var_ref, { name :: string() | list(string()) | {builtin, atom() | tuple()}}).
 
 -record(prim_call_contract,
     { gas      :: expr()

src/aeso_icode_to_asm.erl

@@ -17,7 +17,7 @@
 i(Code) -> aeb_opcodes:mnemonic(Code).
 
 %% We don't track purity or statefulness in the type checker yet.
-is_stateful({FName, _, _, _, _}) -> FName /= "init".
+is_stateful({FName, _, _, _, _}) -> lists:last(FName) /= "init".
 
 is_public({_Name, Attrs, _Args, _Body, _Type}) -> not lists:member(private, Attrs).
 
@@ -105,7 +105,7 @@ make_args(Args) ->
 
 fun_hash({FName, _, Args, _, TypeRep}) ->
     ArgType = {tuple, [T || {_, T} <- Args]},
-    <<Hash:256>> = aeso_abi:function_type_hash(list_to_binary(FName), ArgType, TypeRep),
+    <<Hash:256>> = aeb_aevm_abi:function_type_hash(list_to_binary(lists:last(FName)), ArgType, TypeRep),
     {integer, Hash}.
 
 %% Expects two return addresses below N elements on the stack. Picks the top
@@ -343,6 +343,8 @@ assemble_expr(Funs, Stack, _Tail, #prim_put{ state = State }) ->
 %% Environment primitives
 assemble_expr(_Funs, _Stack, _Tail, prim_contract_address) ->
     [i(?ADDRESS)];
+assemble_expr(_Funs, _Stack, _Tail, prim_contract_creator) ->
+    [i(?CREATOR)];
 assemble_expr(_Funs, _Stack, _Tail, prim_call_origin) ->
     [i(?ORIGIN)];
 assemble_expr(_Funs, _Stack, _Tail, prim_caller) ->
@@ -562,6 +564,8 @@ assemble_infix('^')    -> i(?EXP);
 assemble_infix('bor')  -> i(?OR);
 assemble_infix('band') -> i(?AND);
 assemble_infix('bxor') -> i(?XOR);
+assemble_infix('bsl')  -> i(?SHL);
+assemble_infix('bsr')  -> i(?SHR);
 assemble_infix('<')    -> i(?SLT);    %% comparisons are SIGNED
 assemble_infix('>')    -> i(?SGT);
 assemble_infix('==')   -> i(?EQ);

src/aeso_memory.erl

@@ -1,19 +0,0 @@
-%%%-------------------------------------------------------------------
-%%% @copyright (C) 2018, Aeternity Anstalt
-%%% @doc
-%%%      Memory speifics that compiler and VM need to agree upon
-%%% @end
-%%% Created : 19 Dec 2018
-%%%-------------------------------------------------------------------
-
--module(aeso_memory).
-
--export([binary_to_words/1]).
-
-binary_to_words(<<>>) ->
-    [];
-binary_to_words(<<N:256,Bin/binary>>) ->
-    [N|binary_to_words(Bin)];
-binary_to_words(Bin) ->
-    binary_to_words(<<Bin/binary,0>>).
-

src/aeso_parse_lib.erl

@@ -19,7 +19,7 @@
 
 -export_type([parser/1, parser_expr/1, pos/0, token/0, tokens/0]).
 
--type pos()    :: {integer(), integer()}.
+-type pos()    :: {string() | no_file, integer(), integer()} | {integer(), integer()}.
 -type token()  :: {atom(), pos(), term()} | {atom(), pos()}.
 -type tokens() :: [token()].
 -type error()  :: {pos(), string() | no_error}.

src/aeso_parser.erl

@@ -5,28 +5,37 @@
 -module(aeso_parser).
 
 -export([string/1,
+         string/2,
          type/1]).
 
 -include("aeso_parse_lib.hrl").
 
--spec string(string()) ->
-                    {ok, aeso_syntax:ast()}
-                        | {error, {aeso_parse_lib:pos(),
-                                   atom(),
-                                   term()}}
-                        | {error, {aeso_parse_lib:pos(),
-                                   atom()}}.
+-type parse_result() :: {ok, aeso_syntax:ast()}
+                      | {error, {aeso_parse_lib:pos(), atom(), term()}}
+                      | {error, {aeso_parse_lib:pos(), atom()}}.
+
+-spec string(string()) -> parse_result().
 string(String) ->
-  parse_and_scan(file(), String).
+    string(String, []).
+
+-spec string(string(), aeso_compiler:options()) -> parse_result().
+string(String, Opts) ->
+    case parse_and_scan(file(), String, Opts) of
+        {ok, AST} ->
+            expand_includes(AST, Opts);
+        Err = {error, _} ->
+            Err
+    end.
 
 type(String) ->
-  parse_and_scan(type(), String).
+    parse_and_scan(type(), String, []).
 
-parse_and_scan(P, S) ->
-  case aeso_scan:scan(S) of
-    {ok, Tokens} -> aeso_parse_lib:parse(P, Tokens);
-    Error        -> Error
-  end.
+parse_and_scan(P, S, Opts) ->
+    set_current_file(proplists:get_value(src_file, Opts, no_file)),
+    case aeso_scan:scan(S) of
+        {ok, Tokens} -> aeso_parse_lib:parse(P, Tokens);
+        Error        -> Error
+    end.
 
 %% -- Parsing rules ----------------------------------------------------------
 
@@ -36,7 +45,9 @@ decl() ->
     ?LAZY_P(
     choice(
       %% Contract declaration
-    [ ?RULE(keyword(contract), con(), tok('='), maybe_block(decl()), {contract, _1, _2, _4})
+    [ ?RULE(keyword(contract),  con(), tok('='), maybe_block(decl()), {contract, _1, _2, _4})
+    , ?RULE(keyword(namespace), con(), tok('='), maybe_block(decl()), {namespace, _1, _2, _4})
+    , ?RULE(keyword(include),   str(), {include, get_ann(_1), _2})
 
       %% Type declarations  TODO: format annotation for "type bla" vs "type bla()"
     , ?RULE(keyword(type),     id(),                                          {type_decl, _1, _2, []})
@@ -49,17 +60,31 @@ decl() ->
     , ?RULE(keyword(datatype), id(), type_vars(), tok('='), typedef(variant), {type_def, _1, _2, _3, _5})
 
       %% Function declarations
-    , ?RULE(modifiers(), keyword(function), id(), tok(':'), type(), add_modifiers(_1, {fun_decl, _2, _3, _5}))
-    , ?RULE(modifiers(), keyword(function), fundef(),               add_modifiers(_1, set_pos(get_pos(_2), _3)))
-    , ?RULE(keyword('let'),    valdef(),                            set_pos(get_pos(_1), _2))
+    , ?RULE(modifiers(), fun_or_entry(), id(), tok(':'), type(), add_modifiers(_1, _2, {fun_decl, get_ann(_2), _3, _5}))
+    , ?RULE(modifiers(), fun_or_entry(), fundef(),               add_modifiers(_1, _2, set_pos(get_pos(get_ann(_2)), _3)))
+    , ?RULE(keyword('let'),    valdef(),                         set_pos(get_pos(_1), _2))
     ])).
 
-modifiers() ->
-    many(choice([token(stateful), token(public), token(private), token(internal)])).
+fun_or_entry() ->
+    choice([?RULE(keyword(function), {function, _1}),
+            ?RULE(keyword(entrypoint), {entrypoint, _1})]).
 
-add_modifiers(Mods, Node) ->
-    lists:foldl(fun({Mod, _}, X) -> set_ann(Mod, true, X) end,
-                Node, Mods).
+modifiers() ->
+    many(choice([token(stateful), token(private), token(public)])).
+
+add_modifiers(Mods, Entry = {entrypoint, _}, Node) ->
+    add_modifiers(Mods ++ [Entry], Node);
+add_modifiers(Mods, {function, _}, Node) ->
+    add_modifiers(Mods, Node).
+
+add_modifiers([], Node) -> Node;
+add_modifiers(Mods = [Tok | _], Node) ->
+    %% Set the position to the position of the first modifier. This is
+    %% important for code transformation tools (like what we do in
+    %% create_calldata) to be able to get the indentation of the declaration.
+    set_pos(get_pos(Tok),
+        lists:foldl(fun({Mod, _}, X) -> set_ann(Mod, true, X) end,
+                    Node, Mods)).
 
 %% -- Type declarations ------------------------------------------------------
 
@@ -71,7 +96,7 @@ constructors() ->
     sep1(constructor(), tok('|')).
 
 constructor() ->    %% TODO: format for Con() vs Con
-    choice(?RULE(con(),              {constr_t, get_ann(_1), _1, []}),
+    choice(?RULE(con(),             {constr_t, get_ann(_1), _1, []}),
            ?RULE(con(), con_args(), {constr_t, get_ann(_1), _1, _2})).
 
 con_args()   -> paren_list(con_arg()).
@@ -83,9 +108,7 @@ con_arg()    -> choice(type(), ?RULE(keyword(indexed), type(), set_ann(indexed,
 %% -- Let declarations -------------------------------------------------------
 
 letdecl() ->
-    choice(
-        ?RULE(keyword('let'), letdef(),                             set_pos(get_pos(_1), _2)),
-        ?RULE(keyword('let'), tok(rec), sep1(letdef(), tok('and')), {letrec, _1, _3})).
+    ?RULE(keyword('let'), letdef(), set_pos(get_pos(_1), _2)).
 
 letdef() -> choice(valdef(), fundef()).
 
@@ -120,11 +143,15 @@ type200() ->
 type300() -> type400().
 
 type400() ->
-    ?RULE(typeAtom(), optional(type_args()),
+    choice(
+    [?RULE(typeAtom(), optional(type_args()),
           case _2 of
             none       -> _1;
             {ok, Args} -> {app_t, get_ann(_1), _1, Args}
-          end).
+          end),
+     ?RULE(id("bytes"), parens(token(int)),
+           {bytes_t, get_ann(_1), element(3, _2)})
+    ]).
 
 typeAtom() ->
     ?LAZY_P(choice(
@@ -176,24 +203,24 @@ expr200() -> infixr(expr300(), binop('||')).
 expr300() -> infixr(expr400(), binop('&&')).
 expr400() -> infix(expr500(),  binop(['<', '>', '=<', '>=', '==', '!='])).
 expr500() -> infixr(expr600(), binop(['::', '++'])).
-expr600() -> infixl(expr650(), binop(['+', '-', 'bor', 'bxor', 'bsr', 'bsl'])).
+expr600() -> infixl(expr650(), binop(['+', '-'])).
 expr650() -> ?RULE(many(token('-')), expr700(), prefixes(_1, _2)).
-expr700() -> infixl(expr750(), binop(['*', '/', mod, 'band'])).
+expr700() -> infixl(expr750(), binop(['*', '/', mod])).
 expr750() -> infixl(expr800(), binop(['^'])).
-expr800() -> ?RULE(many(choice(token('!'), token('bnot'))), expr900(), prefixes(_1, _2)).
+expr800() -> ?RULE(many(token('!')), expr900(), prefixes(_1, _2)).
 expr900() -> ?RULE(exprAtom(), many(elim()), elim(_1, _2)).
 
 exprAtom() ->
     ?LAZY_P(begin
         Expr = ?LAZY_P(expr()),
         choice(
-        [ id(), con(), token(qid), token(qcon)
-        , token(hash), token(string), token(char)
+        [ id_or_addr(), con(), token(qid), token(qcon)
+        , token(bytes), token(string), token(char)
         , token(int)
         , ?RULE(token(hex), set_ann(format, hex, setelement(1, _1, int)))
         , {bool, keyword(true), true}
         , {bool, keyword(false), false}
-        , ?RULE(brace_list(?LAZY_P(field_assignment())), record(_1))
+        , ?LET_P(Fs, brace_list(?LAZY_P(field_assignment())), record(Fs))
         , {list, [], bracket_list(Expr)}
         , ?RULE(tok('['), Expr, binop('..'), Expr, tok(']'), _3(_2, _4))
         , ?RULE(keyword('('), comma_sep(Expr), tok(')'), tuple_e(_1, _2))
@@ -236,14 +263,20 @@ record_update(Ann, E, Flds) ->
 record([]) -> {map, [], []};
 record(Fs) ->
     case record_or_map(Fs) of
-        record -> {record, get_ann(hd(Fs)), Fs};
+        record ->
+            Fld = fun({field, _, [_], _} = F) -> F;
+                     ({field, Ann, LV, Id, _}) ->
+                         bad_expr_err("Cannot use '@' in record construction", infix({lvalue, Ann, LV}, {'@', Ann}, Id));
+                     ({field, Ann, LV, _}) ->
+                         bad_expr_err("Cannot use nested fields or keys in record construction", {lvalue, Ann, LV}) end,
+            {record, get_ann(hd(Fs)), lists:map(Fld, Fs)};
         map    ->
             Ann = get_ann(hd(Fs ++ [{empty, []}])), %% TODO: source location for empty maps
             KV = fun({field, _, [{map_get, _, Key}], Val}) -> {Key, Val};
-                    ({field, _, LV, Id, _}) ->
-                        bad_expr_err("Cannot use '@' in map construction", infix(LV, {op, Ann, '@'}, Id));
-                    ({field, _, LV, _}) ->
-                        bad_expr_err("Cannot use nested fields or keys in map construction", LV) end,
+                    ({field, FAnn, LV, Id, _}) ->
+                        bad_expr_err("Cannot use '@' in map construction", infix({lvalue, FAnn, LV}, {'@', Ann}, Id));
+                    ({field, FAnn, LV, _}) ->
+                        bad_expr_err("Cannot use nested fields or keys in map construction", {lvalue, FAnn, LV}) end,
             {map, Ann, lists:map(KV, Fs)}
     end.
 
@@ -301,6 +334,7 @@ binop(Ops) ->
 con()      -> token(con).
 id()       -> token(id).
 tvar()     -> token(tvar).
+str()      -> token(string).
 
 token(Tag) ->
     ?RULE(tok(Tag),
@@ -309,6 +343,26 @@ token(Tag) ->
         {Tok, {Line, Col}, Val} -> {Tok, pos_ann(Line, Col), Val}
     end).
 
+id(Id) ->
+    ?LET_P({id, A, X} = Y, id(),
+           if X == Id -> Y;
+              true    -> fail({A, "expected 'bytes'"})
+           end).
+
+id_or_addr() ->
+    ?RULE(id(), parse_addr_literal(_1)).
+
+parse_addr_literal(Id = {id, Ann, Name}) ->
+    case lists:member(lists:sublist(Name, 3), ["ak_", "ok_", "oq_", "ct_"]) of
+        false -> Id;
+        true  ->
+            try aeser_api_encoder:decode(list_to_binary(Name)) of
+                {Type, Bin} -> {Type, Ann, Bin}
+            catch _:_ ->
+                Id
+            end
+    end.
+
 %% -- Helpers ----------------------------------------------------------------
 
 keyword(K) -> ann(tok(K)).
@@ -336,10 +390,17 @@ bracket_list(P) -> brackets(comma_sep(P)).
 -type ann_col()  :: aeso_syntax:ann_col().
 
 -spec pos_ann(ann_line(), ann_col()) -> ann().
-pos_ann(Line, Col) -> [{line, Line}, {col, Col}].
+pos_ann(Line, Col) -> [{file, current_file()}, {line, Line}, {col, Col}].
+
+current_file() ->
+    get('$current_file').
+
+set_current_file(File) ->
+    put('$current_file', File).
 
 ann_pos(Ann) ->
-    {proplists:get_value(line, Ann),
+    {proplists:get_value(file, Ann),
+     proplists:get_value(line, Ann),
      proplists:get_value(col, Ann)}.
 
 get_ann(Ann) when is_list(Ann) -> Ann;
@@ -357,10 +418,10 @@ set_ann(Key, Val, Node) ->
     setelement(2, Node, lists:keystore(Key, 1, Ann, {Key, Val})).
 
 get_pos(Node) ->
-    {get_ann(line, Node), get_ann(col, Node)}.
+    {current_file(), get_ann(line, Node), get_ann(col, Node)}.
 
-set_pos({L, C}, Node) ->
-    set_ann(line, L, set_ann(col, C, Node)).
+set_pos({F, L, C}, Node) ->
+    set_ann(file, F, set_ann(line, L, set_ann(col, C, Node))).
 
 infix(L, Op, R) -> set_ann(format, infix,  {app, get_ann(L), Op, [L, R]}).
 
@@ -393,7 +454,7 @@ build_if(Ann, Cond, Then, [{elif, Ann1, Cond1, Then1} | Elses]) ->
 build_if(Ann, Cond, Then, [{else, _Ann, Else}]) ->
     {'if', Ann, Cond, Then, Else};
 build_if(Ann, Cond, Then, []) ->
-    {'if', Ann, Cond, Then, {unit, [{origin, system}]}}.
+    {'if', Ann, Cond, Then, {tuple, [{origin, system}], []}}.
 
 else_branches([Elif = {elif, _, _, _} | Stmts], Acc) ->
     else_branches(Stmts, [Elif | Acc]);
@@ -409,7 +470,6 @@ fun_t(Domains, Type) ->
     lists:foldr(fun({Dom, Ann}, T) -> {fun_t, Ann, [], Dom, T} end,
                 Type, Domains).
 
-tuple_e(Ann, [])      -> {unit, Ann};
 tuple_e(_Ann, [Expr]) -> Expr;  %% Not a tuple
 tuple_e(Ann, Exprs)   -> {tuple, Ann, Exprs}.
 
@@ -430,10 +490,9 @@ parse_pattern({record, Ann, Fs}) ->
     {record, Ann, lists:map(fun parse_field_pattern/1, Fs)};
 parse_pattern(E = {con, _, _})    -> E;
 parse_pattern(E = {id, _, _})     -> E;
-parse_pattern(E = {unit, _})      -> E;
 parse_pattern(E = {int, _, _})    -> E;
 parse_pattern(E = {bool, _, _})   -> E;
-parse_pattern(E = {hash, _, _})   -> E;
+parse_pattern(E = {bytes, _, _})  -> E;
 parse_pattern(E = {string, _, _}) -> E;
 parse_pattern(E = {char, _, _})   -> E;
 parse_pattern(E) -> bad_expr_err("Not a valid pattern", E).
@@ -442,16 +501,53 @@ parse_pattern(E) -> bad_expr_err("Not a valid pattern", E).
 parse_field_pattern({field, Ann, F, E}) ->
     {field, Ann, F, parse_pattern(E)}.
 
-return_error({L, C}, Err) ->
-    fail(io_lib:format("~p:~p:\n~s", [L, C, Err])).
+return_error({no_file, L, C}, Err) ->
+    fail(io_lib:format("~p:~p:\n~s", [L, C, Err]));
+return_error({F, L, C}, Err) ->
+    fail(io_lib:format("In ~s at ~p:~p:\n~s", [F, L, C, Err])).
 
--spec ret_doc_err(ann(), prettypr:document()) -> no_return().
+-spec ret_doc_err(ann(), prettypr:document()) -> aeso_parse_lib:parser(none()).
 ret_doc_err(Ann, Doc) ->
     return_error(ann_pos(Ann), prettypr:format(Doc)).
 
--spec bad_expr_err(string(), aeso_syntax:expr()) -> no_return().
+-spec bad_expr_err(string(), aeso_syntax:expr()) -> aeso_parse_lib:parser(none()).
 bad_expr_err(Reason, E) ->
   ret_doc_err(get_ann(E),
               prettypr:sep([prettypr:text(Reason ++ ":"),
                             prettypr:nest(2, aeso_pretty:expr(E))])).
 
+%% -- Helper functions -------------------------------------------------------
+expand_includes(AST, Opts) ->
+    expand_includes(AST, [], Opts).
+
+expand_includes([], Acc, _Opts) ->
+    {ok, lists:reverse(Acc)};
+expand_includes([{include, _, S = {string, _, File}} | AST], Acc, Opts) ->
+    case read_file(File, Opts) of
+        {ok, Bin} ->
+            Opts1 = lists:keystore(src_file, 1, Opts, {src_file, File}),
+            case string(binary_to_list(Bin), Opts1) of
+                {ok, AST1} ->
+                    expand_includes(AST1 ++ AST, Acc, Opts);
+                Err = {error, _} ->
+                    Err
+            end;
+        {error, _} ->
+            {error, {get_pos(S), include_error, File}}
+    end;
+expand_includes([E | AST], Acc, Opts) ->
+    expand_includes(AST, [E | Acc], Opts).
+
+read_file(File, Opts) ->
+    case proplists:get_value(include, Opts, {explicit_files, #{}}) of
+        {file_system, Paths} ->
+            CandidateNames = [ filename:join(Dir, File) || Dir <- Paths ],
+            lists:foldr(fun(F, {error, _}) -> file:read_file(F);
+                           (_F, OK) -> OK end, {error, not_found}, CandidateNames);
+        {explicit_files, Files} ->
+            case maps:get(binary_to_list(File), Files, not_found) of
+                not_found -> {error, not_found};
+                Src       -> {ok, Src}
+            end
+    end.
+

src/aeso_pretty.erl

@@ -147,19 +147,28 @@ decl(D, Options) ->
 -spec decl(aeso_syntax:decl()) -> doc().
 decl({contract, _, C, Ds}) ->
     block(follow(text("contract"), hsep(name(C), text("="))), decls(Ds));
+decl({namespace, _, C, Ds}) ->
+    block(follow(text("namespace"), hsep(name(C), text("="))), decls(Ds));
 decl({type_decl, _, T, Vars}) -> typedecl(alias_t, T, Vars);
 decl({type_def, _, T, Vars, Def}) ->
     Kind = element(1, Def),
     equals(typedecl(Kind, T, Vars), typedef(Def));
-decl({fun_decl, _, F, T}) ->
-    hsep(text("function"), typed(name(F), T));
+decl({fun_decl, Ann, F, T}) ->
+    Fun = case aeso_syntax:get_ann(entrypoint, Ann, false) of
+            true  -> text("entrypoint");
+            false -> text("function")
+          end,
+    hsep(Fun, typed(name(F), T));
 decl(D = {letfun, Attrs, _, _, _, _}) ->
-    Mod = fun({Mod, true}) when Mod == private; Mod == internal; Mod == public; Mod == stateful ->
+    Mod = fun({Mod, true}) when Mod == private; Mod == stateful ->
                             text(atom_to_list(Mod));
              (_) -> empty() end,
-    hsep(lists:map(Mod, Attrs) ++ [letdecl("function", D)]);
-decl(D = {letval, _, _, _, _})    -> letdecl("let", D);
-decl(D = {letrec, _, _})          -> letdecl("let", D).
+    Fun = case aeso_syntax:get_ann(entrypoint, Attrs, false) of
+              true  -> "entrypoint";
+              false -> "function"
+          end,
+    hsep(lists:map(Mod, Attrs) ++ [letdecl(Fun, D)]);
+decl(D = {letval, _, _, _, _}) -> letdecl("let", D).
 
 -spec expr(aeso_syntax:expr(), options()) -> doc().
 expr(E, Options) ->
@@ -182,9 +191,7 @@ name({typed, _, Name, _}) -> name(Name).
 letdecl(Let, {letval, _, F, T, E}) ->
     block_expr(0, hsep([text(Let), typed(name(F), T), text("=")]), E);
 letdecl(Let, {letfun, _, F, Args, T, E}) ->
-    block_expr(0, hsep([text(Let), typed(beside(name(F), args(Args)), T), text("=")]), E);
-letdecl(Let, {letrec, _, [D | Ds]}) ->
-    hsep(text(Let), above([ letdecl("rec", D) | [ letdecl("and", D1) || D1 <- Ds ] ])).
+    block_expr(0, hsep([text(Let), typed(beside(name(F), args(Args)), T), text("=")]), E).
 
 -spec args([aeso_syntax:arg()]) -> doc().
 args(Args) ->
@@ -234,8 +241,13 @@ type({app_t, _, Type, Args}) ->
     beside(type(Type), tuple_type(Args));
 type({tuple_t, _, Args}) ->
     tuple_type(Args);
-type({named_arg_t, _, Name, Type, Default}) ->
-    follow(hsep(typed(name(Name), Type), text("=")), expr(Default));
+type({bytes_t, _, any}) -> text("bytes(_)");
+type({bytes_t, _, Len}) ->
+    text(lists:concat(["bytes(", Len, ")"]));
+type({named_arg_t, _, Name, Type, _Default}) ->
+    %% Drop the default value
+    %% follow(hsep(typed(name(Name), Type), text("=")), expr(Default));
+    typed(name(Name), Type);
 
 type(R = {record_t, _}) -> typedef(R);
 type(T = {id, _, _})   -> name(T);
@@ -303,6 +315,8 @@ expr_p(P, E = {app, _, F = {Op, _}, Args}) when is_atom(Op) ->
         {prefix, [A]}   -> prefix(P, Op, A);
         _               -> app(P, F, Args)
     end;
+expr_p(_, {app, _, C={Tag, _, _}, []}) when Tag == con; Tag == qcon ->
+    expr_p(0, C);
 expr_p(P, {app, _, F, Args}) ->
     app(P, F, Args);
 %% -- Constants
@@ -313,8 +327,18 @@ expr_p(_, E = {int, _, N}) ->
            end,
     text(S);
 expr_p(_, {bool, _, B}) -> text(atom_to_list(B));
-expr_p(_, {hash, _, <<N:256>>}) -> text("#" ++ integer_to_list(N, 16));
-expr_p(_, {unit, _}) -> text("()");
+expr_p(_, {bytes, _, Bin}) ->
+    Digits = byte_size(Bin),
+    <<N:Digits/unit:8>> = Bin,
+    text(lists:flatten(io_lib:format("#~*.16.0b", [Digits*2, N])));
+expr_p(_, {hash, _, <<N:512>>}) -> text("#" ++ integer_to_list(N, 16));
+expr_p(_, {Type, _, Bin})
+    when Type == account_pubkey;
+         Type == contract_pubkey;
+         Type == oracle_pubkey;
+         Type == oracle_query_id ->
+    text(binary_to_list(aeser_api_encoder:encode(Type, Bin)));
+expr_p(_, {string, _, <<>>}) -> text("\"\"");
 expr_p(_, {string, _, S}) -> term(binary_to_list(S));
 expr_p(_, {char, _, C}) ->
     case C of
@@ -347,6 +371,7 @@ stmt_p({else, Else}) ->
 -spec bin_prec(aeso_syntax:bin_op()) -> {integer(), integer(), integer()}.
 bin_prec('..')   -> {  0,   0,   0};  %% Always printed inside '[ ]'
 bin_prec('=')    -> {  0,   0,   0};  %% Always printed inside '[ ]'
+bin_prec('@')    -> {  0,   0,   0};  %% Only in error messages
 bin_prec('||')   -> {200, 300, 200};
 bin_prec('&&')   -> {300, 400, 300};
 bin_prec('<')    -> {400, 500, 500};
@@ -359,20 +384,14 @@ bin_prec('++')   -> {500, 600, 500};
 bin_prec('::')   -> {500, 600, 500};
 bin_prec('+')    -> {600, 600, 650};
 bin_prec('-')    -> {600, 600, 650};
-bin_prec('bor')  -> {600, 600, 650};
-bin_prec('bxor') -> {600, 600, 650};
-bin_prec('bsl')  -> {600, 600, 650};
-bin_prec('bsr')  -> {600, 600, 650};
 bin_prec('*')    -> {700, 700, 750};
 bin_prec('/')    -> {700, 700, 750};
 bin_prec(mod)    -> {700, 700, 750};
-bin_prec('band') -> {700, 700, 750};
 bin_prec('^')    -> {750, 750, 800}.
 
 -spec un_prec(aeso_syntax:un_op()) -> {integer(), integer()}.
 un_prec('-')    -> {650, 650};
-un_prec('!')    -> {800, 800};
-un_prec('bnot') -> {800, 800}.
+un_prec('!')    -> {800, 800}.
 
 equals(Ann, A, B) ->
     {app, [{format, infix} | Ann], {'=', Ann}, [A, B]}.
@@ -424,7 +443,6 @@ statements(Stmts) ->
 
 statement(S = {letval, _, _, _, _})    -> letdecl("let", S);
 statement(S = {letfun, _, _, _, _, _}) -> letdecl("let", S);
-statement(S = {letrec, _, _})          -> letdecl("let", S);
 statement(E) -> expr(E).
 
 get_elifs(Expr) -> get_elifs(Expr, []).

src/aeso_scan.erl

@@ -20,7 +20,7 @@ lexer() ->
     CON      = [UPPER, "[a-zA-Z0-9_]*"],
     INT      = [DIGIT, "+"],
     HEX      = ["0x", HEXDIGIT, "+"],
-    HASH     = ["#", HEXDIGIT, "+"],
+    BYTES    = ["#", HEXDIGIT, "+"],
     WS       = "[\\000-\\ ]+",
     ID       = [LOWER, "[a-zA-Z0-9_']*"],
     TVAR     = ["'", ID],
@@ -36,9 +36,8 @@ lexer() ->
         , {"\\*/",        pop(skip())}
         , {"[^/*]+|[/*]", skip()} ],
 
-    Keywords = ["contract", "import", "let", "rec", "switch", "type", "record", "datatype", "if", "elif", "else", "function",
-                "stateful", "true", "false", "and", "mod", "public", "private", "indexed", "internal",
-                "band", "bor", "bxor", "bsl", "bsr", "bnot"],
+    Keywords = ["contract", "include", "let", "switch", "type", "record", "datatype", "if", "elif", "else", "function",
+                "stateful", "true", "false", "mod", "public", "entrypoint", "private", "indexed", "namespace"],
     KW = string:join(Keywords, "|"),
 
     Rules =
@@ -55,7 +54,7 @@ lexer() ->
         , {STRING, token(string, fun parse_string/1)}
         , {HEX,    token(hex,    fun parse_hex/1)}
         , {INT,    token(int,    fun list_to_integer/1)}
-        , {HASH,   token(hash,   fun parse_hash/1)}
+        , {BYTES,  token(bytes,  fun parse_bytes/1)}
 
           %% Identifiers (qualified first!)
         , {QID,   token(qid,  fun(S) -> string:tokens(S, ".") end)}
@@ -118,10 +117,8 @@ unescape([C | Chars], Acc) ->
 
 parse_hex("0x" ++ Chars) -> list_to_integer(Chars, 16).
 
-parse_hash("#" ++ Chars) ->
-    N = list_to_integer(Chars, 16),
-    case length(Chars) > 64 of  %% 64 hex digits = 32 bytes
-        true  -> <<N:64/unit:8>>;   %% signature
-        false -> <<N:32/unit:8>>    %% address
-    end.
+parse_bytes("#" ++ Chars) ->
+    N      = list_to_integer(Chars, 16),
+    Digits = (length(Chars) + 1) div 2,
+    <<N:Digits/unit:8>>.
 

src/aeso_sophia.erl

@@ -1,30 +0,0 @@
--module(aeso_sophia).
-
--export_type([data/0,
-              type/0,
-              heap/0]).
-
--type type() :: word | signed_word | string | typerep | function
-              | {list,   type()}
-              | {option, type()}
-              | {tuple, [type()]}
-              | {variant, [[type()]]}.
-
-
--type data() :: none
-              | {some,   data()}
-              | {option, data()}
-              | word
-              | string
-              | {list,   data()}
-              | {tuple, [data()]}
-              | {variant, integer(), [data()]}
-              | integer()
-              | binary()
-              | [data()]
-              | {}
-              | {data()}
-              | {data(), data()}.
-
--type heap() :: binary().
-

src/aeso_syntax.erl

@@ -8,14 +8,14 @@
 
 -module(aeso_syntax).
 
--export([get_ann/1, get_ann/2, get_ann/3, set_ann/2]).
+-export([get_ann/1, get_ann/2, get_ann/3, set_ann/2, qualify/2]).
 
 -export_type([ann_line/0, ann_col/0, ann_origin/0, ann_format/0, ann/0]).
 -export_type([name/0, id/0, con/0, qid/0, qcon/0, tvar/0, op/0]).
 -export_type([bin_op/0, un_op/0]).
 -export_type([decl/0, letbind/0, typedef/0]).
--export_type([arg/0, field_t/0, constructor_t/0]).
--export_type([type/0, constant/0, expr/0, arg_expr/0, field/1, stmt/0, alt/0, lvalue/0, pat/0]).
+-export_type([arg/0, field_t/0, constructor_t/0, named_arg_t/0]).
+-export_type([type/0, constant/0, expr/0, arg_expr/0, field/1, stmt/0, alt/0, lvalue/0, elim/0, pat/0]).
 -export_type([ast/0]).
 
 -type ast() :: [decl()].
@@ -25,7 +25,7 @@
 -type ann_origin() :: system | user.
 -type ann_format() :: '?:' | hex | infix | prefix | elif.
 
--type ann() :: [{line, ann_line()} | {col, ann_col()} | {format, ann_format()} | {origin, ann_origin()}].
+-type ann() :: [{line, ann_line()} | {col, ann_col()} | {format, ann_format()} | {origin, ann_origin()} | stateful | private].
 
 -type name() :: string().
 -type id()   :: {id,   ann(), name()}.
@@ -35,6 +35,7 @@
 -type tvar() :: {tvar, ann(), name()}.
 
 -type decl() :: {contract, ann(), con(), [decl()]}
+              | {namespace, ann(), con(), [decl()]}
               | {type_decl, ann(), id(), [tvar()]}
               | {type_def, ann(), id(), [tvar()], typedef()}
               | {fun_decl, ann(), id(), type()}
@@ -42,8 +43,7 @@
 
 -type letbind()
     :: {letval, ann(), id(), type(), expr()}
-     | {letfun, ann(), id(), [arg()], type(), expr()}
-     | {letrec, ann(), [letbind()]}.
+     | {letfun, ann(), id(), [arg()], type(), expr()}.
 
 -type arg() :: {arg, ann(), id(), type()}.
 
@@ -59,6 +59,7 @@
 -type type() :: {fun_t, ann(), [named_arg_t()], [type()], type()}
               | {app_t, ann(), type(), [type()]}
               | {tuple_t, ann(), [type()]}
+              | {bytes_t, ann(), integer() | any}
               | id()  | qid()
               | con() | qcon()  %% contracts
               | tvar().
@@ -68,17 +69,20 @@
 -type constant()
     :: {int, ann(), integer()}
      | {bool, ann(), true | false}
-     | {hash, ann(), binary()}
-     | {unit, ann()}
+     | {bytes, ann(), binary()}
+     | {account_pubkey, ann(), binary()}
+     | {contract_pubkey, ann(), binary()}
+     | {oracle_pubkey, ann(), binary()}
+     | {oracle_query_id, ann(), binary()}
      | {string, ann(), binary()}
      | {char, ann(), integer()}.
 
 -type op() :: bin_op() | un_op().
 
--type bin_op() :: '+' | '-' | '*' | '/' | mod | '^' | 'band' | 'bor' | 'bsl' | 'bsr' | 'bxor'
+-type bin_op() :: '+' | '-' | '*' | '/' | mod | '^'
                 | '++' | '::' | '<' | '>' | '=<' | '>=' | '==' | '!='
                 | '||' | '&&' | '..'.
--type un_op() :: '-' | '!' | 'bnot'.
+-type un_op() :: '-' | '!'.
 
 -type expr()
     :: {lam, ann(), [arg()], expr()}
@@ -140,3 +144,7 @@ get_ann(Key, Node) ->
 
 get_ann(Key, Node, Default) ->
     proplists:get_value(Key, get_ann(Node), Default).
+
+qualify({con, Ann, N}, X)             -> qualify({qcon, Ann, [N]}, X);
+qualify({qcon, _, NS}, {con, Ann, C}) -> {qcon, Ann, NS ++ [C]};
+qualify({qcon, _, NS}, {id, Ann, X})  -> {qid, Ann, NS ++ [X]}.

src/aeso_syntax_utils.erl

@@ -6,89 +6,142 @@
 %%%-------------------------------------------------------------------
 -module(aeso_syntax_utils).
 
--export([used_ids/1, used_types/1]).
+-export([used_ids/1, used_types/2, used/1]).
 
-%% Var set combinators
-none()           -> [].
-one(X)           -> [X].
-union_map(F, Xs) -> lists:umerge(lists:map(F, Xs)).
-minus(Xs, Ys)    -> Xs -- Ys.
+-record(alg, {zero, plus, scoped}).
 
-%% Compute names used by a definition or expression.
-used_ids(Es) when is_list(Es) ->
-    union_map(fun used_ids/1, Es);
-used_ids({bind, A, B}) ->
-    minus(used_ids(B), used_ids(A));
-%% Declarations
-used_ids({contract, _, _, Decls})    -> used_ids(Decls);
-used_ids({type_decl, _, _, _})       -> none();
-used_ids({type_def, _, _, _, _})     -> none();
-used_ids({fun_decl, _, _, _})        -> none();
-used_ids({letval, _, _, _, E})       -> used_ids(E);
-used_ids({letfun, _, _, Args, _, E}) -> used_ids({bind, Args, E});
-used_ids({letrec, _, Decls})         -> used_ids(Decls);
-%% Args
-used_ids({arg, _, X, _}) -> used_ids(X);
-used_ids({named_arg, _, _, E}) -> used_ids(E);
-%% Constants
-used_ids({int, _, _})    -> none();
-used_ids({bool, _, _})   -> none();
-used_ids({hash, _, _})   -> none();
-used_ids({unit, _})      -> none();
-used_ids({string, _, _}) -> none();
-used_ids({char, _, _})   -> none();
-%% Expressions
-used_ids({lam, _, Args, E})  -> used_ids({bind, Args, E});
-used_ids({'if', _, A, B, C}) -> used_ids([A, B, C]);
-used_ids({switch, _, E, Bs}) -> used_ids([E, Bs]);
-used_ids({app, _, E, Es})    -> used_ids([E | Es]);
-used_ids({proj, _, E, _})    -> used_ids(E);
-used_ids({tuple, _, Es})     -> used_ids(Es);
-used_ids({list, _, Es})      -> used_ids(Es);
-used_ids({typed, _, E, _})   -> used_ids(E);
-used_ids({record, _, Fs})    -> used_ids(Fs);
-used_ids({record, _, E, Fs}) -> used_ids([E, Fs]);
-used_ids({map, _, E, Fs})    -> used_ids([E, Fs]);
-used_ids({map, _, KVs})      -> used_ids([ [K, V] || {K, V} <- KVs ]);
-used_ids({map_get, _, M, K}) -> used_ids([M, K]);
-used_ids({map_get, _, M, K, V}) -> used_ids([M, K, V]);
-used_ids({block, _, Ss})     -> used_ids_s(Ss);
-used_ids({Op, _}) when is_atom(Op) -> none();
-used_ids({id, _, X})   -> [X];
-used_ids({qid, _, _})  -> none();
-used_ids({con, _, _})  -> none();
-used_ids({qcon, _, _}) -> none();
-%% Switch branches
-used_ids({'case', _, P, E}) -> used_ids({bind, P, E});
-%% Fields
-used_ids({field, _, LV, E})    -> used_ids([LV, E]);
-used_ids({field, _, LV, X, E}) -> used_ids([LV, {bind, X, E}]);
-used_ids({proj, _, _})         -> none();
-used_ids({map_get, _, E})      -> used_ids(E).
+-type alg(A) :: #alg{ zero   :: A
+                    , plus   :: fun((A, A) -> A)
+                    , scoped :: fun((A, A) -> A) }.
 
-%% Statements
-used_ids_s([])       -> none();
-used_ids_s([S | Ss]) ->
-    used_ids([S, {bind, bound_ids(S), {block, [], Ss}}]).
+-type kind() :: decl | type | bind_type | expr | bind_expr.
 
-bound_ids({letval, _, X, _, _})    -> one(X);
-bound_ids({letfun, _, X, _, _, _}) -> one(X);
-bound_ids({letrec, _, Decls})      -> union_map(fun bound_ids/1, Decls);
-bound_ids(_)                       -> none().
+-spec fold(alg(A), fun((kind(), _) -> A), kind(), E | [E]) -> A
+    when E :: aeso_syntax:decl()
+            | aeso_syntax:typedef()
+            | aeso_syntax:field_t()
+            | aeso_syntax:constructor_t()
+            | aeso_syntax:type()
+            | aeso_syntax:expr()
+            | aeso_syntax:pat()
+            | aeso_syntax:arg()
+            | aeso_syntax:alt()
+            | aeso_syntax:elim()
+            | aeso_syntax:arg_expr()
+            | aeso_syntax:field(aeso_syntax:expr())
+            | aeso_syntax:stmt().
+fold(Alg = #alg{zero = Zero, plus = Plus, scoped = Scoped}, Fun, K, X) ->
+    Sum  = fun(Xs) -> lists:foldl(Plus, Zero, Xs) end,
+    Same = fun(A) -> fold(Alg, Fun, K, A) end,
+    Decl = fun(D) -> fold(Alg, Fun, decl, D) end,
+    Type = fun(T) -> fold(Alg, Fun, type, T) end,
+    Expr = fun(E) -> fold(Alg, Fun, expr, E) end,
+    BindExpr = fun(P) -> fold(Alg, Fun, bind_expr, P) end,
+    BindType = fun(T) -> fold(Alg, Fun, bind_type, T) end,
+    Top = Fun(K, X),
+    Rec = case X of
+            %% lists (bound things in head scope over tail)
+            [A | As]                 -> Scoped(Same(A), Same(As));
+            %% decl()
+            {contract, _, _, Ds}     -> Decl(Ds);
+            {namespace, _, _, Ds}    -> Decl(Ds);
+            {type_decl, _, I, _}     -> BindType(I);
+            {type_def, _, I, _, D}   -> Plus(BindType(I), Decl(D));
+            {fun_decl, _, _, T}      -> Type(T);
+            {letval, _, F, T, E}     -> Sum([BindExpr(F), Type(T), Expr(E)]);
+            {letfun, _, F, Xs, T, E} -> Sum([BindExpr(F), Type(T), Scoped(BindExpr(Xs), Expr(E))]);
+            %% typedef()
+            {alias_t, T}    -> Type(T);
+            {record_t, Fs}  -> Type(Fs);
+            {variant_t, Cs} -> Type(Cs);
+            %% field_t() and constructor_t()
+            {field_t, _, _, T}   -> Type(T);
+            {constr_t, _, _, Ts} -> Type(Ts);
+            %% type()
+            {fun_t, _, Named, Args, Ret} -> Type([Named, Args, Ret]);
+            {app_t, _, T, Ts}            -> Type([T | Ts]);
+            {tuple_t, _, Ts}             -> Type(Ts);
+            %% named_arg_t()
+            {named_arg_t, _, _, T, E} -> Plus(Type(T), Expr(E));
+            %% expr()
+            {lam, _, Args, E}      -> Scoped(BindExpr(Args), Expr(E));
+            {'if', _, A, B, C}     -> Expr([A, B, C]);
+            {switch, _, E, Alts}   -> Expr([E, Alts]);
+            {app, _, A, As}        -> Expr([A | As]);
+            {proj, _, E, _}        -> Expr(E);
+            {tuple, _, As}         -> Expr(As);
+            {list, _, As}          -> Expr(As);
+            {typed, _, E, T}       -> Plus(Expr(E), Type(T));
+            {record, _, Fs}        -> Expr(Fs);
+            {record, _, E, Fs}     -> Expr([E | Fs]);
+            {map, _, E, Fs}        -> Expr([E | Fs]);
+            {map, _, KVs}          -> Sum([Expr([Key, Val]) || {Key, Val} <- KVs]);
+            {map_get, _, A, B}     -> Expr([A, B]);
+            {map_get, _, A, B, C}  -> Expr([A, B, C]);
+            {block, _, Ss}         -> Expr(Ss);
+            %% field()
+            {field, _, LV, E}    -> Expr([LV, E]);
+            {field, _, LV, _, E} -> Expr([LV, E]);
+            %% arg()
+            {arg, _, X, T} -> Plus(Expr(X), Type(T));
+            %% alt()
+            {'case', _, P, E} -> Scoped(BindExpr(P), Expr(E));
+            %% elim()
+            {proj, _, _}    -> Zero;
+            {map_get, _, E} -> Expr(E);
+            %% arg_expr()
+            {named_arg, _, _, E} -> Expr(E);
+            _ -> Alg#alg.zero
+          end,
+    (Alg#alg.plus)(Top, Rec).
+
+%% Name dependencies
+
+used_ids(E) ->
+    [ X || {{term, [X]}, _} <- used(E) ].
+
+used_types([Top] = _CurrentNS, T) ->
+    F = fun({{type, [X]}, _}) -> [X];
+           ({{type, [Top1, X]}, _}) when Top1 == Top -> [X];
+           (_) -> []
+        end,
+    lists:flatmap(F, used(T)).
+
+-type entity() :: {term, [string()]}
+                | {type, [string()]}
+                | {namespace, [string()]}.
+
+-spec entity_alg() -> alg(#{entity() => aeso_syntax:ann()}).
+entity_alg() ->
+    IsBound = fun({K, _}) -> lists:member(K, [bound_term, bound_type]) end,
+    Unbind  = fun(bound_term) -> term; (bound_type) -> type end,
+    Remove  = fun(Keys, Map) -> lists:foldl(fun maps:remove/2, Map, Keys) end,
+    Scoped = fun(Xs, Ys) ->
+                Bound  = [E || E <- maps:keys(Ys), IsBound(E)],
+                Others = Remove(Bound, Ys),
+                Bound1 = [ {Unbind(Tag), X} || {Tag, X} <- Bound ],
+                maps:merge(Remove(Bound1, Xs), Others)
+            end,
+    #alg{ zero   = #{}
+        , plus   = fun maps:merge/2
+        , scoped = Scoped }.
+
+-spec used(_) -> [{entity(), aeso_syntax:ann()}].
+used(D) ->
+    Kind = fun(expr)      -> term;
+              (bind_expr) -> bound_term;
+              (type)      -> type;
+              (bind_type) -> bound_type
+           end,
+    NS = fun(Xs) -> {namespace, lists:droplast(Xs)} end,
+    NotBound = fun({{Tag, _}, _}) -> not lists:member(Tag, [bound_term, bound_type]) end,
+    Xs =
+        maps:to_list(fold(entity_alg(),
+            fun(K, {id,   Ann, X})  -> #{{Kind(K), [X]} => Ann};
+               (K, {qid,  Ann, Xs}) -> #{{Kind(K), Xs}  => Ann, NS(Xs) => Ann};
+               (K, {con,  Ann, X})  -> #{{Kind(K), [X]} => Ann};
+               (K, {qcon, Ann, Xs}) -> #{{Kind(K), Xs}  => Ann, NS(Xs) => Ann};
+               (_, _)             -> #{}
+            end, decl, D)),
+    lists:filter(NotBound, Xs).
 
-used_types(Ts) when is_list(Ts)    -> union_map(fun used_types/1, Ts);
-used_types({type_def, _, _, _, T}) -> used_types(T);
-used_types({alias_t, T})           -> used_types(T);
-used_types({record_t, Fs})         -> used_types(Fs);
-used_types({variant_t, Cs})        -> used_types(Cs);
-used_types({field_t, _, _, T})     -> used_types(T);
-used_types({constr_t, _, _, Ts})   -> used_types(Ts);
-used_types({fun_t, _, Named, Args, T}) -> used_types([T | Named ++ Args]);
-used_types({named_arg_t, _, _, T, _}) -> used_types(T);
-used_types({app_t, _, T, Ts})      -> used_types([T | Ts]);
-used_types({tuple_t, _, Ts})       -> used_types(Ts);
-used_types({id, _, X})             -> one(X);
-used_types({qid, _, _})            -> none();
-used_types({con, _, _})            -> none();
-used_types({qcon, _, _})           -> none();
-used_types({tvar, _, _})           -> none().

src/aeso_vm_decode.erl

@@ -0,0 +1,113 @@
+%%%-------------------------------------------------------------------
+%%% @copyright (C) 2017, Aeternity Anstalt
+%%% @doc Decoding aevm and fate data to AST
+%%%
+%%% @end
+%%%-------------------------------------------------------------------
+
+-module(aeso_vm_decode).
+
+-export([ from_aevm/3, from_fate/2 ]).
+
+-include_lib("aebytecode/include/aeb_fate_data.hrl").
+
+address_literal(Type, N) -> {Type, [], <<N:256>>}.
+
+-spec from_aevm(aeb_aevm_data:type(), aeso_syntax:type(), aeb_aevm_data:data()) -> aeso_syntax:expr().
+from_aevm(word, {id, _, "address"},                     N) -> address_literal(account_pubkey, N);
+from_aevm(word, {app_t, _, {id, _, "oracle"}, _},       N) -> address_literal(oracle_pubkey, N);
+from_aevm(word, {app_t, _, {id, _, "oracle_query"}, _}, N) -> address_literal(oracle_query_id, N);
+from_aevm(word, {con, _, _Name},                        N) -> address_literal(contract_pubkey, N);
+from_aevm(word, {id, _, "int"},     N) -> <<N1:256/signed>> = <<N:256>>, {int, [], N1};
+from_aevm(word, {id, _, "bits"},    N) -> error({todo, bits, N});
+from_aevm(word, {id, _, "bool"},    N) -> {bool, [], N /= 0};
+from_aevm(word, {bytes_t, _, Len}, Val) when Len =< 32 ->
+    <<Bytes:Len/unit:8, _/binary>> = <<Val:32/unit:8>>,
+    {bytes, [], <<Bytes:Len/unit:8>>};
+from_aevm({tuple, _}, {bytes_t, _, Len}, Val) ->
+    {bytes, [], binary:part(<< <<W:32/unit:8>> || W <- tuple_to_list(Val) >>, 0, Len)};
+from_aevm(string, {id, _, "string"}, S) -> {string, [], S};
+from_aevm({list, VmType}, {app_t, _, {id, _, "list"}, [Type]}, List) ->
+    {list, [], [from_aevm(VmType, Type, X) || X <- List]};
+from_aevm({variant, [[], [VmType]]}, {app_t, _, {id, _, "option"}, [Type]}, Val) ->
+    case Val of
+        {variant, 0, []}  -> {con, [], "None"};
+        {variant, 1, [X]} -> {app, [], {con, [], "Some"}, [from_aevm(VmType, Type, X)]}
+    end;
+from_aevm({tuple, VmTypes}, {tuple_t, _, Types}, Val)
+        when length(VmTypes) == length(Types),
+             length(VmTypes) == tuple_size(Val) ->
+    {tuple, [], [from_aevm(VmType, Type, X)
+                 || {VmType, Type, X} <- lists:zip3(VmTypes, Types, tuple_to_list(Val))]};
+from_aevm({tuple, VmTypes}, {record_t, Fields}, Val)
+        when length(VmTypes) == length(Fields),
+             length(VmTypes) == tuple_size(Val) ->
+    {record, [], [ {field, [], [{proj, [], FName}], from_aevm(VmType, FType, X)}
+                   || {VmType, {field_t, _, FName, FType}, X} <- lists:zip3(VmTypes, Fields, tuple_to_list(Val)) ]};
+from_aevm({map, VmKeyType, VmValType}, {app_t, _, {id, _, "map"}, [KeyType, ValType]}, Map)
+        when is_map(Map) ->
+    {map, [], [ {from_aevm(VmKeyType, KeyType, Key),
+                 from_aevm(VmValType, ValType, Val)}
+                || {Key, Val} <- maps:to_list(Map) ]};
+from_aevm({variant, VmCons}, {variant_t, Cons}, {variant, Tag, Args})
+        when length(VmCons) == length(Cons),
+             length(VmCons) > Tag ->
+    VmTypes = lists:nth(Tag + 1, VmCons),
+    ConType = lists:nth(Tag + 1, Cons),
+    from_aevm(VmTypes, ConType, Args);
+from_aevm(VmTypes, {constr_t, _, Con, Types}, Args)
+        when length(VmTypes) == length(Types),
+             length(VmTypes) == length(Args) ->
+    {app, [], Con, [ from_aevm(VmType, Type, Arg)
+                     || {VmType, Type, Arg} <- lists:zip3(VmTypes, Types, Args) ]};
+from_aevm(_VmType, _Type, _Data) ->
+    throw(cannot_translate_to_sophia).
+
+
+-spec from_fate(aeso_syntax:type(), aeb_fate_data:fate_type()) -> aeso_syntax:expr().
+from_fate({id, _, "address"}, ?FATE_ADDRESS(Bin)) -> {account_pubkey, [], Bin};
+from_fate({app_t, _, {id, _, "oracle"}, _}, ?FATE_ORACLE(Bin)) -> {oracle_pubkey, [], Bin};
+from_fate({app_t, _, {id, _, "oracle_query"}, _}, ?FATE_ORACLE_Q(Bin)) -> {oracle_query_id, [], Bin};
+from_fate({con, _, _Name},  ?FATE_CONTRACT(Bin)) -> {contract_pubkey, [], Bin};
+from_fate({bytes_t, _, N},  ?FATE_BYTES(Bin)) when byte_size(Bin) == N -> {bytes, [], Bin};
+from_fate({id, _, "bits"},  ?FATE_BITS(Bin)) -> error({todo, bits, Bin});
+from_fate({id, _, "int"},     N) when is_integer(N) -> {int, [], N};
+from_fate({id, _, "bool"},    B) when is_boolean(B) -> {bool, [], B};
+from_fate({id, _, "string"}, S) when is_binary(S) -> {string, [], S};
+from_fate({app_t, _, {id, _, "list"}, [Type]}, List) when is_list(List) ->
+    {list, [], [from_fate(Type, X) || X <- List]};
+from_fate({app_t, _, {id, _, "option"}, [Type]}, Val) ->
+    case Val of
+        {variant, [0, 1], 0, {}}  -> {con, [], "None"};
+        {variant, [0, 1], 1, {X}} -> {app, [], {con, [], "Some"}, [from_fate(Type, X)]}
+    end;
+from_fate({tuple_t, _, []}, ?FATE_UNIT) ->
+     {tuple, [], []};
+from_fate({tuple_t, _, Types}, ?FATE_TUPLE(Val))
+        when length(Types) == tuple_size(Val) ->
+    {tuple, [], [from_fate(Type, X)
+                 || {Type, X} <- lists:zip(Types, tuple_to_list(Val))]};
+from_fate({record_t, Fields}, ?FATE_TUPLE(Val))
+        when length(Fields) == tuple_size(Val) ->
+    {record, [], [ {field, [], [{proj, [], FName}], from_fate(FType, X)}
+                   || {{field_t, _, FName, FType}, X} <- lists:zip(Fields, tuple_to_list(Val)) ]};
+from_fate({app_t, _, {id, _, "map"}, [KeyType, ValType]}, Map)
+        when is_map(Map) ->
+    {map, [], [ {from_fate(KeyType, Key),
+                 from_fate(ValType, Val)}
+                || {Key, Val} <- maps:to_list(Map) ]};
+from_fate({variant_t, Cons}, {variant, Ar, Tag, Args})
+        when length(Cons) > Tag ->
+    ConType = lists:nth(Tag + 1, Cons),
+    Arity = lists:nth(Tag + 1, Ar),
+    case tuple_to_list(Args) of
+        ArgList when length(ArgList) == Arity ->
+            from_fate(ConType, ArgList);
+        _ -> throw(cannot_translate_to_sophia)
+    end;
+from_fate({constr_t, _, Con, Types}, Args)
+        when length(Types) == length(Args) ->
+    {app, [], Con, [ from_fate(Type, Arg)
+                     || {Type, Arg} <- lists:zip(Types, Args) ]};
+from_fate(_Type, _Data) ->
+    throw(cannot_translate_to_sophia).

src/aesophia.app.src

@@ -1,13 +1,15 @@
 {application, aesophia,
- [{description, "Contract Language for Aethernity"},
-  {vsn, "1.2.0"},
+ [{description, "Contract Language for aeternity"},
+  {vsn, "3.2.0"},
   {registered, []},
   {applications,
    [kernel,
     stdlib,
+    jsx,
     syntax_tools,
     getopt,
-    aebytecode
+    aebytecode,
+    eblake2
    ]},
   {env,[]},
   {modules, []},

src/aesophia.erl

@@ -1,71 +0,0 @@
--module(aesophia).
-
--export([main/1]).
-
--define(OPT_SPEC,
-    [ {src_file, undefined, undefined, string, "Sophia source code file"}
-    , {verbose, $v, "verbose", undefined, "Verbose output"}
-    , {help, $h, "help", undefined, "Show this message"}
-    , {outfile, $o, "out", string, "Output file (experimental)"} ]).
-
-usage() ->
-    getopt:usage(?OPT_SPEC, "aesophia").
-
-main(Args) ->
-    case getopt:parse(?OPT_SPEC, Args) of
-        {ok, {Opts, []}} ->
-            case proplists:get_value(help, Opts, false) of
-                false ->
-                    compile(Opts);
-                true ->
-                    usage()
-            end;
-
-        {ok, {_, NonOpts}} ->
-            io:format("Can't understand ~p\n\n", [NonOpts]),
-            usage();
-
-        {error, {Reason, Data}} ->
-            io:format("Error: ~s ~p\n\n", [Reason, Data]),
-            usage()
-    end.
-
-
-compile(Opts) ->
-    case proplists:get_value(src_file, Opts, undefined) of
-        undefined ->
-            io:format("Error: no input source file\n\n"),
-            usage();
-        File ->
-            compile(File, Opts)
-    end.
-
-compile(File, Opts) ->
-    Verbose = proplists:get_value(verbose, Opts, false),
-    OutFile = proplists:get_value(outfile, Opts, undefined),
-
-    try
-        Res = aeso_compiler:file(File, [pp_ast || Verbose]),
-        write_outfile(OutFile, Res),
-        io:format("\nCompiled successfully!\n")
-    catch
-        %% The compiler errors.
-        error:{type_errors, Errors} ->
-            io:format("\n~s\n", [string:join(["** Type errors\n" | Errors], "\n")]);
-        error:{parse_errors, Errors} ->
-            io:format("\n~s\n", [string:join(["** Parse errors\n" | Errors], "\n")]);
-        error:{code_errors, Errors} ->
-            ErrorStrings = [ io_lib:format("~p", [E]) || E <- Errors ],
-            io:format("\n~s\n", [string:join(["** Code errors\n" | ErrorStrings], "\n")]);
-        %% General programming errors in the compiler.
-        error:Error ->
-            Where = hd(erlang:get_stacktrace()),
-            ErrorString = io_lib:format("Error: ~p in\n   ~p", [Error,Where]),
-            io:format("\n~s\n", [ErrorString])
-    end.
-
-write_outfile(undefined, _) -> ok;
-write_outfile(Out, ResMap)  ->
-    %% Lazy approach
-    file:write_file(Out, term_to_binary(ResMap)),
-    io:format("Output written to: ~s\n", [Out]).

test/aeso_abi_tests.erl

@@ -1,9 +1,12 @@
 -module(aeso_abi_tests).
 
 -include_lib("eunit/include/eunit.hrl").
--compile(export_all).
+-compile([export_all, nowarn_export_all]).
 
 -define(SANDBOX(Code), sandbox(fun() -> Code end)).
+-define(DUMMY_HASH_WORD, 16#123).
+-define(DUMMY_HASH, <<0:30/unit:8, 127, 119>>). %% 16#123
+-define(DUMMY_HASH_LIT, "#0000000000000000000000000000000000000000000000000000000000000123").
 
 sandbox(Code) ->
     Parent = self(),
@@ -19,8 +22,8 @@ sandbox(Code) ->
 
 malicious_from_binary_test() ->
     CircularList = from_words([32, 1, 32]), %% Xs = 1 :: Xs
-    {ok, {error, circular_references}}   = ?SANDBOX(aeso_heap:from_binary({list, word}, CircularList)),
-    {ok, {error, {binary_too_short, _}}} = ?SANDBOX(aeso_heap:from_binary(word, <<1, 2, 3, 4>>)),
+    {ok, {error, circular_references}}   = ?SANDBOX(aeb_heap:from_binary({list, word}, CircularList)),
+    {ok, {error, {binary_too_short, _}}} = ?SANDBOX(aeb_heap:from_binary(word, <<1, 2, 3, 4>>)),
     ok.
 
 from_words(Ws) ->
@@ -54,35 +57,144 @@ encode_decode_test() ->
     ok.
 
 encode_decode_sophia_test() ->
-    {42} = encode_decode_sophia_string("int", "42"),
-    {1} = encode_decode_sophia_string("bool", "true"),
-    {0} = encode_decode_sophia_string("bool", "false"),
-    {<<"Hello">>} = encode_decode_sophia_string("string", "\"Hello\""),
-    {<<"Hello">>, [1,2,3], {variant, 1, [1]}} =
-        encode_decode_sophia_string(
-          "(string, list(int), option(bool))",
-          "\"Hello\", [1,2,3], Some(true)"),
+    Check = fun(Type, Str) -> case {encode_decode_sophia_string(Type, Str), Str} of
+                                {X, X} -> ok;
+                                Other -> Other
+                              end end,
+    ok = Check("int", "42"),
+    ok = Check("int", "-42"),
+    ok = Check("bool", "true"),
+    ok = Check("bool", "false"),
+    ok = Check("string", "\"Hello\""),
+    ok = Check("(string, list(int), option(bool))",
+               "(\"Hello\", [1, 2, 3], Some(true))"),
+    ok = Check("variant", "Blue({[\"x\"] = 1})"),
+    ok = Check("r", "{x = (\"foo\", 0), y = Red}"),
     ok.
 
 encode_decode_sophia_string(SophiaType, String) ->
     io:format("String ~p~n", [String]),
-    Code = [ "contract Call =\n"
-           , "  function foo : ", SophiaType, " => _\n"
-           , "  function __call() = foo(", String, ")\n" ],
-    {ok, _, {Types, _}, Args} = aeso_compiler:check_call(lists:flatten(Code), []),
-    Arg  = list_to_tuple(Args),
-    Type = {tuple, Types},
-    io:format("Type ~p~n", [Type]),
-    Data = encode(Arg),
-    decode(Type, Data).
+    Code = [ "contract MakeCall =\n"
+           , "  type arg_type = ", SophiaType, "\n"
+           , "  type an_alias('a) = (string, 'a)\n"
+           , "  record r = {x : an_alias(int), y : variant}\n"
+           , "  datatype variant = Red | Blue(map(string, int))\n"
+           , "  entrypoint foo : arg_type => arg_type\n" ],
+    case aeso_compiler:check_call(lists:flatten(Code), "foo", [String], []) of
+        {ok, _, {[Type], _}, [Arg]} ->
+            io:format("Type ~p~n", [Type]),
+            Data = encode(Arg),
+            case aeso_compiler:to_sophia_value(Code, "foo", ok, Data) of
+                {ok, Sophia} ->
+                    lists:flatten(io_lib:format("~s", [prettypr:format(aeso_pretty:expr(Sophia))]));
+                {error, Err} ->
+                    io:format("~s\n", [Err]),
+                    {error, Err}
+            end;
+        {error, Err} ->
+            io:format("~s\n", [Err]),
+            {error, Err}
+    end.
+
+calldata_test() ->
+    [42, <<"foobar">>] = encode_decode_calldata("foo", ["int", "string"], ["42", "\"foobar\""]),
+    Map = #{ <<"a">> => 4 },
+    [{variant, 1, [Map]}, {{<<"b">>, 5}, {variant, 0, []}}] =
+        encode_decode_calldata("foo", ["variant", "r"], ["Blue({[\"a\"] = 4})", "{x = (\"b\", 5), y = Red}"]),
+    [?DUMMY_HASH_WORD, 16#456] = encode_decode_calldata("foo", ["bytes(32)", "address"],
+                                                        [?DUMMY_HASH_LIT, "ak_1111111111111111111111111111113AFEFpt5"]),
+    [?DUMMY_HASH_WORD, ?DUMMY_HASH_WORD] =
+        encode_decode_calldata("foo", ["bytes(32)", "hash"], [?DUMMY_HASH_LIT, ?DUMMY_HASH_LIT]),
+
+    [119, {0, 0}] = encode_decode_calldata("foo", ["int", "signature"], ["119", [$# | lists:duplicate(128, $0)]]),
+
+    [16#456] = encode_decode_calldata("foo", ["Remote"], ["ct_1111111111111111111111111111113AFEFpt5"]),
+
+    ok.
+
+calldata_init_test() ->
+    encode_decode_calldata("init", ["int"], ["42"], {tuple, [typerep, word]}),
+
+    Code = parameterized_contract("foo", ["int"]),
+    encode_decode_calldata_(Code, "init", [], {tuple, [typerep, {tuple, []}]}).
+
+calldata_indent_test() ->
+    Test = fun(Extra) ->
+            Code = parameterized_contract(Extra, "foo", ["int"]),
+            encode_decode_calldata_(Code, "foo", ["42"], word)
+           end,
+    Test("  stateful entrypoint bla() = ()"),
+    Test("  type x = int"),
+    Test("  stateful entrypoint bla(x : int) =\n"
+         "    x + 1"),
+    Test("  stateful entrypoint bla(x : int) : int =\n"
+         "    x + 1"),
+    ok.
+
+parameterized_contract(FunName, Types) ->
+    parameterized_contract([], FunName, Types).
+
+parameterized_contract(ExtraCode, FunName, Types) ->
+    lists:flatten(
+        ["contract Remote =\n"
+         "  entrypoint bla : () => ()\n\n"
+         "contract Dummy =\n",
+         ExtraCode, "\n",
+         "  type an_alias('a) = (string, 'a)\n"
+         "  record r = {x : an_alias(int), y : variant}\n"
+         "  datatype variant = Red | Blue(map(string, int))\n"
+         "  entrypoint ", FunName, " : (", string:join(Types, ", "), ") => int\n" ]).
+
+oracle_test() ->
+    Contract =
+        "contract OracleTest =\n"
+        "  entrypoint question(o, q : oracle_query(list(string), option(int))) =\n"
+        "    Oracle.get_question(o, q)\n",
+    {ok, _, {[word, word], {list, string}}, [16#123, 16#456]} =
+        aeso_compiler:check_call(Contract, "question", ["ok_111111111111111111111111111111ZrdqRz9",
+                                                        "oq_1111111111111111111111111111113AFEFpt5"], []),
+
+    ok.
+
+permissive_literals_fail_test() ->
+    Contract =
+        "contract OracleTest =\n"
+        "  stateful entrypoint haxx(o : oracle(list(string), option(int))) =\n"
+        "    Chain.spend(o, 1000000)\n",
+        {error, <<"Type errors\nCannot unify", _/binary>>} =
+            aeso_compiler:check_call(Contract, "haxx", ["#123"], []),
+    ok.
+
+encode_decode_calldata(FunName, Types, Args) ->
+    encode_decode_calldata(FunName, Types, Args, word).
+
+encode_decode_calldata(FunName, Types, Args, RetType) ->
+    Code = parameterized_contract(FunName, Types),
+    encode_decode_calldata_(Code, FunName, Args, RetType).
+
+encode_decode_calldata_(Code, FunName, Args, RetVMType) ->
+    {ok, Calldata} = aeso_compiler:create_calldata(Code, FunName, Args),
+    {ok, _, {ArgTypes, RetType}, _} = aeso_compiler:check_call(Code, FunName, Args, [{backend, aevm}]),
+    ?assertEqual(RetType, RetVMType),
+    CalldataType = {tuple, [word, {tuple, ArgTypes}]},
+    {ok, {_Hash, ArgTuple}} = aeb_heap:from_binary(CalldataType, Calldata),
+    case FunName of
+        "init" ->
+            ok;
+        _ ->
+            {ok, _ArgTypes, ValueASTs} = aeso_compiler:decode_calldata(Code, FunName, Calldata),
+            Values = [ prettypr:format(aeso_pretty:expr(V)) || V <- ValueASTs ],
+            ?assertMatch({X, X}, {Args, Values})
+    end,
+    tuple_to_list(ArgTuple).
 
 encode_decode(T, D) ->
     ?assertEqual(D, decode(T, encode(D))),
     D.
 
 encode(D) ->
-    aeso_heap:to_binary(D).
+    aeb_heap:to_binary(D).
 
 decode(T,B) ->
-    {ok, D} = aeso_heap:from_binary(T, B),
+    {ok, D} = aeb_heap:from_binary(T, B),
     D.

test/aeso_aci_tests.erl

@@ -0,0 +1,122 @@
+-module(aeso_aci_tests).
+
+-include_lib("eunit/include/eunit.hrl").
+
+simple_aci_test_() ->
+    [{"Test contract " ++ integer_to_list(N),
+      fun() -> test_contract(N) end}
+     || N <- [1, 2, 3]].
+
+test_contract(N) ->
+    {Contract,MapACI,DecACI} = test_cases(N),
+    {ok,JSON} = aeso_aci:contract_interface(json, Contract),
+    ?assertEqual([MapACI], JSON),
+    ?assertEqual({ok, DecACI}, aeso_aci:render_aci_json(JSON)).
+
+test_cases(1) ->
+    Contract = <<"contract C =\n"
+		 "  entrypoint a(i : int) = i+1\n">>,
+    MapACI = #{contract =>
+		   #{name => <<"C">>,
+		     type_defs => [],
+		     functions =>
+			 [#{name => <<"a">>,
+			    arguments =>
+				[#{name => <<"i">>,
+				   type => <<"int">>}],
+			    returns => <<"int">>,
+			    stateful => false}]}},
+    DecACI = <<"contract C =\n"
+	       "  entrypoint a : (int) => int\n">>,
+    {Contract,MapACI,DecACI};
+
+test_cases(2) ->
+    Contract = <<"contract C =\n"
+		 "  type allan = int\n"
+		 "  entrypoint a(i : allan) = i+1\n">>,
+    MapACI = #{contract =>
+                       #{name => <<"C">>,
+                         type_defs =>
+                             [#{name => <<"allan">>,
+                                typedef => <<"int">>,
+                                vars => []}],
+			 functions =>
+                             [#{arguments =>
+                                    [#{name => <<"i">>,
+                                       type => <<"C.allan">>}],
+                                name => <<"a">>,
+                                returns => <<"int">>,
+                                stateful => false}]}},
+    DecACI = <<"contract C =\n"
+               "  type allan = int\n"
+               "  entrypoint a : (C.allan) => int\n">>,
+    {Contract,MapACI,DecACI};
+test_cases(3) ->
+    Contract = <<"contract C =\n"
+                 "  type state = ()\n"
+                 "  datatype event = SingleEventDefined\n"
+		 "  datatype bert('a) = Bin('a)\n"
+		 "  entrypoint a(i : bert(string)) = 1\n">>,
+    MapACI = #{contract =>
+		   #{functions =>
+			 [#{arguments =>
+				[#{name => <<"i">>,
+				   type =>
+				       #{<<"C.bert">> => [<<"string">>]}}],
+			    name => <<"a">>,returns => <<"int">>,
+			    stateful => false}],
+		     name => <<"C">>,
+                     event => #{variant => [#{<<"SingleEventDefined">> => []}]},
+                     state => #{tuple => []},
+		     type_defs =>
+			 [#{name => <<"bert">>,
+			    typedef =>
+				#{variant =>
+				      [#{<<"Bin">> => [<<"'a">>]}]},
+			    vars => [#{name => <<"'a">>}]}]}},
+    DecACI = <<"contract C =\n"
+               "  type state = ()\n"
+               "  datatype event = SingleEventDefined\n"
+	       "  datatype bert('a) = Bin('a)\n"
+	       "  entrypoint a : (C.bert(string)) => int\n">>,
+    {Contract,MapACI,DecACI}.
+
+%% Rounttrip
+aci_test_() ->
+    [{"Testing ACI generation for " ++ ContractName,
+      fun() -> aci_test_contract(ContractName) end}
+     || ContractName <- all_contracts()].
+
+all_contracts() -> aeso_compiler_tests:compilable_contracts().
+
+aci_test_contract(Name) ->
+    String = aeso_test_utils:read_contract(Name),
+    Opts   = [{include, {file_system, [aeso_test_utils:contract_path()]}}],
+    {ok, JSON} = aeso_aci:contract_interface(json, String, Opts),
+
+    io:format("JSON:\n~p\n", [JSON]),
+    {ok, ContractStub} = aeso_aci:render_aci_json(JSON),
+
+    io:format("STUB:\n~s\n", [ContractStub]),
+    check_stub(ContractStub, [{src_file, Name}]),
+
+    ok.
+
+check_stub(Stub, Options) ->
+    case aeso_parser:string(binary_to_list(Stub), Options) of
+        {ok, Ast} ->
+            try
+                %% io:format("AST: ~120p\n", [Ast]),
+                aeso_ast_infer_types:infer(Ast, [])
+            catch _:{type_errors, TE} ->
+                io:format("Type error:\n~s\n", [TE]),
+                error(TE);
+                  _:R ->
+                io:format("Error: ~p\n", [R]),
+                error(R)
+            end;
+        {error, E} ->
+            io:format("Error: ~p\n", [E]),
+            error({parse_error, E})
+    end.
+

test/aeso_blake2_tests.erl

@@ -1,73 +0,0 @@
-%%%=============================================================================
-%%% @copyright (C) 2019, Aeternity Anstalt
-%%% @doc
-%%%   Unit tests for the aeso_blake2 module
-%%%
-%%%   In addition the aeso_blake2 module was compared to the C reference
-%%%   implementation by writing a QuickCheck property.
-%%% @end
-%%%=============================================================================
--module(aeso_blake2_tests).
-
--ifdef(TEST).
-
--include_lib("eunit/include/eunit.hrl").
-
-blake2b_test_() ->
-    {"Tests for BLAKE2b hash implementation",
-     [ fun() -> blake2b(Data) end || Data <- test_data_blake2b() ]}.
-
-blake2b({Msg0, Key0, ExpectedOut0}) ->
-    Msg = mk_binary(Msg0),
-    Key = mk_binary(Key0),
-    ExpectedOut = mk_binary(ExpectedOut0),
-    Result = aeso_blake2:blake2b(byte_size(ExpectedOut), Msg, Key),
-    ?assertEqual(Result, {ok, ExpectedOut}).
-
-mk_binary(Bin) when is_binary(Bin) -> Bin;
-mk_binary(HexStr) when is_list(HexStr) ->
-    << << (erlang:list_to_integer([H], 16)):4 >> || H <- HexStr >>.
-
-test_data_blake2b() ->
-    [ %% {Message, Key, ExpectedHash}
-      %% From Wikipedia
-      %% https://en.wikipedia.org/wiki/BLAKE_(hash_function)#BLAKE2
-      {<<>>,
-       <<>>,
-       "786A02F742015903C6C6FD852552D272912F4740E15847618A86E217F71F5419D25E1031AFEE585313896444934EB04B903A685B1448B755D56F701AFE9BE2CE"}
-    , {<<"The quick brown fox jumps over the lazy dog">>,
-       <<>>,
-       "A8ADD4BDDDFD93E4877D2746E62817B116364A1FA7BC148D95090BC7333B3673F82401CF7AA2E4CB1ECD90296E3F14CB5413F8ED77BE73045B13914CDCD6A918"}
-
-      %% From reference implementation testvectors
-      %% https://github.com/BLAKE2/BLAKE2/tree/master/testvectors
-      %%
-      %% Non-keyed
-    , {"00",
-        "",
-        "2FA3F686DF876995167E7C2E5D74C4C7B6E48F8068FE0E44208344D480F7904C36963E44115FE3EB2A3AC8694C28BCB4F5A0F3276F2E79487D8219057A506E4B"}
-    , {"0001",
-       "",
-       "1C08798DC641ABA9DEE435E22519A4729A09B2BFE0FF00EF2DCD8ED6F8A07D15EAF4AEE52BBF18AB5608A6190F70B90486C8A7D4873710B1115D3DEBBB4327B5"}
-    , {"00010203040506070809",
-       "",
-       "29102511D749DB3CC9B4E335FA1F5E8FACA8421D558F6A3F3321D50D044A248BA595CFC3EFD3D2ADC97334DA732413F5CBF4751C362BA1D53862AC1E8DABEEE8"}
-
-      %% Keyed
-    , {"",
-       "000102030405060708090a0b0c0d0e0f101112131415161718191a1b1c1d1e1f202122232425262728292a2b2c2d2e2f303132333435363738393a3b3c3d3e3f",
-       "10ebb67700b1868efb4417987acf4690ae9d972fb7a590c2f02871799aaa4786b5e996e8f0f4eb981fc214b005f42d2ff4233499391653df7aefcbc13fc51568"}
-    , {"00",
-       "000102030405060708090a0b0c0d0e0f101112131415161718191a1b1c1d1e1f202122232425262728292a2b2c2d2e2f303132333435363738393a3b3c3d3e3f",
-       "961f6dd1e4dd30f63901690c512e78e4b45e4742ed197c3c5e45c549fd25f2e4187b0bc9fe30492b16b0d0bc4ef9b0f34c7003fac09a5ef1532e69430234cebd"}
-    , {"0001",
-       "000102030405060708090a0b0c0d0e0f101112131415161718191a1b1c1d1e1f202122232425262728292a2b2c2d2e2f303132333435363738393a3b3c3d3e3f",
-       "da2cfbe2d8409a0f38026113884f84b50156371ae304c4430173d08a99d9fb1b983164a3770706d537f49e0c916d9f32b95cc37a95b99d857436f0232c88a965"}
-    , {"00010203040506070809",
-       "000102030405060708090a0b0c0d0e0f101112131415161718191a1b1c1d1e1f202122232425262728292a2b2c2d2e2f303132333435363738393a3b3c3d3e3f",
-       "4fe181f54ad63a2983feaaf77d1e7235c2beb17fa328b6d9505bda327df19fc37f02c4b6f0368ce23147313a8e5738b5fa2a95b29de1c7f8264eb77b69f585cd"}
-    ].
-
-
--endif.
-

test/aeso_calldata_tests.erl

@@ -0,0 +1,102 @@
+%%% -*- erlang-indent-level:4; indent-tabs-mode: nil -*-
+%%%-------------------------------------------------------------------
+%%% @copyright (C) 2019, Aeternity Anstalt
+%%% @doc Test Sophia language compiler.
+%%%
+%%% @end
+%%%-------------------------------------------------------------------
+
+-module(aeso_calldata_tests).
+
+-compile([export_all, nowarn_export_all]).
+
+-include_lib("eunit/include/eunit.hrl").
+
+%%  Very simply test compile the given contracts. Only basic checks
+%%  are made on the output, just that it is a binary which indicates
+%%  that the compilation worked.
+calldata_test_() ->
+     [ {"Testing " ++ ContractName ++ " contract calling " ++ Fun,
+        fun() ->
+           ContractString = aeso_test_utils:read_contract(ContractName),
+           AevmExprs =
+              case not lists:member(ContractName, not_yet_compilable(aevm)) of
+                  true -> ast_exprs(ContractString, Fun, Args, [{backend, aevm}]);
+                  false -> undefined
+              end,
+           FateExprs =
+              case not lists:member(ContractName, not_yet_compilable(fate)) of
+                  true -> ast_exprs(ContractString, Fun, Args, [{backend, fate}]);
+                  false -> undefined
+              end,
+           case FateExprs == undefined orelse AevmExprs == undefined of
+               true -> ok;
+               false ->
+                   ?assertEqual(FateExprs, AevmExprs)
+           end
+        end} || {ContractName, Fun, Args} <- compilable_contracts()].
+
+
+ast_exprs(ContractString, Fun, Args, Opts) ->
+    {ok, Data} = aeso_compiler:create_calldata(ContractString, Fun, Args, Opts),
+    {ok, _Types, Exprs} = aeso_compiler:decode_calldata(ContractString, Fun, Data, Opts),
+    ?assert(is_list(Exprs)),
+    Exprs.
+
+check_errors(Expect, ErrorString) ->
+    %% This removes the final single \n as well.
+    Actual = binary:split(<<ErrorString/binary,$\n>>, <<"\n\n">>, [global,trim]),
+    case {Expect -- Actual, Actual -- Expect} of
+        {[], Extra}   -> ?assertMatch({unexpected, []}, {unexpected, Extra});
+        {Missing, []} -> ?assertMatch({missing, []}, {missing, Missing});
+        {Missing, Extra} -> ?assertEqual(Missing, Extra)
+    end.
+
+%% compilable_contracts() -> [ContractName].
+%%  The currently compilable contracts.
+
+compilable_contracts() ->
+    [
+     {"identity", "init", []},
+     {"maps", "init", []},
+     {"funargs", "menot", ["false"]},
+     {"funargs", "append", ["[\"false\", \" is\", \" not\", \" true\"]"]},
+     %% TODO {"funargs", "bitsum", ["Bits.all"]},
+     {"funargs", "read", ["{label = \"question 1\", result = 4}"]},
+     {"funargs", "sjutton", ["#0011012003100011012003100011012003"]},
+     {"funargs", "sextiosju", ["#01020304050607080910111213141516171819202122232425262728293031323334353637383940"
+                               "414243444546474849505152535455565758596061626364656667"]},
+     {"funargs", "trettiotva", ["#0102030405060708091011121314151617181920212223242526272829303132"]},
+     {"funargs", "find_oracle", ["ok_2YNyxd6TRJPNrTcEDCe9ra59SVUdp9FR9qWC5msKZWYD9bP9z5"]},
+     {"funargs", "find_query", ["oq_2oRvyowJuJnEkxy58Ckkw77XfWJrmRgmGaLzhdqb67SKEL1gPY"]},
+     {"funargs", "traffic_light", ["Green"]},
+     {"funargs", "traffic_light", ["Pantone(12)"]},
+     {"funargs", "tuples", ["()"]},
+     %% TODO {"funargs", "due", ["FixedTTL(1020)"]},
+     {"variant_types", "init", []},
+     {"basic_auth", "init", []},
+     {"address_literals", "init", []},
+     {"bytes_equality", "init", []},
+     {"address_chain", "init", []},
+     {"counter", "init",
+      ["-3334353637383940202122232425262728293031323334353637"]},
+     {"dutch_auction", "init",
+      ["ak_2gx9MEFxKvY9vMG5YnqnXWv1hCsX7rgnfvBLJS4aQurustR1rt", "200000", "1000"]},
+     {"maps", "fromlist_i",
+      ["[(1, {x = 1, y = 2}), (2, {x = 3, y = 4}), (3, {x = 4, y = 4})]"]},
+     {"maps", "get_i", ["1", "{}"]},
+     {"maps", "get_i", ["1", "{[1] = {x = 3, y = 4}}"]},
+     {"maps", "get_i", ["1", "{[1] = {x = 3, y = 4}, [2] = {x = 4, y = 5}}"]},
+     {"maps", "get_i", ["1", "{[1] = {x = 3, y = 4}, [2] = {x = 4, y = 5}, [3] = {x = 5, y = 6}}"]},
+     {"strings", "str_concat", ["\"test\"","\"me\""]},
+     {"complex_types", "filter_some", ["[Some(11), Some(12), None]"]},
+     {"complex_types", "init", ["ct_Ez6MyeTMm17YnTnDdHTSrzMEBKmy7Uz2sXu347bTDPgVH2ifJ"]},
+     {"__call" "init", []},
+     {"bitcoin_auth", "authorize", ["1", "#0102030405060708090a0b0c0d0e0f101718192021222324252627282930313233343536373839401a1b1c1d1e1f202122232425262728293031323334353637"]},
+     {"bitcoin_auth", "to_sign", ["#0102030405060708090a0b0c0d0e0f1017181920212223242526272829303132", "2"]}
+    ].
+
+not_yet_compilable(fate) ->
+    ["address_chain"];
+not_yet_compilable(aevm) ->
+    ["__call"].

test/aeso_compiler_tests.erl

@@ -8,44 +8,78 @@
 
 -module(aeso_compiler_tests).
 
+-compile([export_all, nowarn_export_all]).
+
 -include_lib("eunit/include/eunit.hrl").
 
-%% simple_compile_test_() -> ok.
 %%  Very simply test compile the given contracts. Only basic checks
 %%  are made on the output, just that it is a binary which indicates
 %%  that the compilation worked.
-
 simple_compile_test_() ->
-    {setup,
-     fun () -> ok end,                          %Setup
-     fun (_) -> ok end,                         %Cleanup
-     [ {"Testing the " ++ ContractName ++ " contract",
+     [ {"Testing the " ++ ContractName ++ " contract with the " ++ atom_to_list(Backend) ++ " backend",
         fun() ->
-            #{byte_code := ByteCode,
-              contract_source := _,
-              type_info := _} = compile(ContractName),
-            ?assertMatch(Code when is_binary(Code), ByteCode)
-        end} || ContractName <- compilable_contracts() ] ++
+            case compile(Backend, ContractName) of
+                #{byte_code := ByteCode,
+                  contract_source := _,
+                  type_info := _} when Backend == aevm ->
+                    ?assertMatch(Code when is_binary(Code), ByteCode);
+                #{fate_code := Code} when Backend == fate ->
+                    Code1 = aeb_fate_code:deserialize(aeb_fate_code:serialize(Code)),
+                    ?assertMatch({X, X}, {Code1, Code});
+                ErrBin ->
+                    io:format("\n~s", [ErrBin]),
+                    error(ErrBin)
+            end
+        end} || ContractName <- compilable_contracts(), Backend <- [aevm, fate],
+                not lists:member(ContractName, not_yet_compilable(Backend))] ++
      [ {"Testing error messages of " ++ ContractName,
         fun() ->
-            {type_errors, Errors} = compile(ContractName),
-            check_errors(lists:sort(ExpectedErrors), lists:sort(Errors))
+            case compile(aevm, ContractName) of
+                <<"Type errors\n", ErrorString/binary>> ->
+                    check_errors(lists:sort(ExpectedErrors), ErrorString);
+                <<"Parse errors\n", ErrorString/binary>> ->
+                    check_errors(lists:sort(ExpectedErrors), ErrorString)
+            end
         end} ||
-            {ContractName, ExpectedErrors} <- failing_contracts() ]
-    }.
+            {ContractName, ExpectedErrors} <- failing_contracts() ] ++
+     [ {"Testing include with explicit files",
+        fun() ->
+            FileSystem = maps:from_list(
+                [ begin
+                    {ok, Bin} = file:read_file(filename:join([aeso_test_utils:contract_path(), File])),
+                    {File, Bin}
+                  end || File <- ["included.aes", "../contracts/included2.aes"] ]),
+            #{byte_code := Code1} = compile(aevm, "include", [{include, {explicit_files, FileSystem}}]),
+            #{byte_code := Code2} = compile(aevm, "include"),
+            ?assertMatch(true, Code1 == Code2)
+        end} ] ++
+     [ {"Testing deadcode elimination",
+        fun() ->
+            #{ byte_code := NoDeadCode } = compile(aevm, "nodeadcode"),
+            #{ byte_code := DeadCode   } = compile(aevm, "deadcode"),
+            SizeNoDeadCode = byte_size(NoDeadCode),
+            SizeDeadCode   = byte_size(DeadCode),
+            ?assertMatch({_, _, true}, {SizeDeadCode, SizeNoDeadCode, SizeDeadCode + 40 < SizeNoDeadCode}),
+            ok
+        end} ].
 
-check_errors(Expect, Actual) ->
+check_errors(Expect, ErrorString) ->
+    %% This removes the final single \n as well.
+    Actual = binary:split(<<ErrorString/binary,$\n>>, <<"\n\n">>, [global,trim]),
     case {Expect -- Actual, Actual -- Expect} of
         {[], Extra}   -> ?assertMatch({unexpected, []}, {unexpected, Extra});
         {Missing, []} -> ?assertMatch({missing, []}, {missing, Missing});
         {Missing, Extra} -> ?assertEqual(Missing, Extra)
     end.
 
-compile(Name) ->
-    try
-        aeso_compiler:from_string(aeso_test_utils:read_contract(Name), [])
-    catch _:{type_errors, _} = E ->
-        E
+compile(Backend, Name) ->
+    compile(Backend, Name, [{include, {file_system, [aeso_test_utils:contract_path()]}}]).
+
+compile(Backend, Name, Options) ->
+    String = aeso_test_utils:read_contract(Name),
+    case aeso_compiler:from_string(String, [{src_file, Name}, {backend, Backend} | Options]) of
+        {ok, Map}            -> Map;
+        {error, ErrorString} -> ErrorString
     end.
 
 %% compilable_contracts() -> [ContractName].
@@ -57,6 +91,7 @@ compilable_contracts() ->
      "dutch_auction",
      "environment",
      "factorial",
+     "functions",
      "fundme",
      "identity",
      "maps",
@@ -68,89 +103,254 @@ compilable_contracts() ->
      "stack",
      "test",
      "builtin_bug",
-     "builtin_map_get_bug"
+     "builtin_map_get_bug",
+     "nodeadcode",
+     "deadcode",
+     "variant_types",
+     "state_handling",
+     "events",
+     "include",
+     "basic_auth",
+     "bitcoin_auth",
+     "address_literals",
+     "bytes_equality",
+     "address_chain",
+     "namespace_bug",
+     "bytes_to_x",
+     "aens"
     ].
 
+not_yet_compilable(fate) -> [];
+not_yet_compilable(aevm) -> [].
+
 %% Contracts that should produce type errors
 
 failing_contracts() ->
     [ {"name_clash",
-        ["Duplicate definitions of abort at\n  - (builtin location)\n  - line 14, column 3\n",
-         "Duplicate definitions of double_def at\n  - line 10, column 3\n  - line 11, column 3\n",
-         "Duplicate definitions of double_proto at\n  - line 4, column 3\n  - line 5, column 3\n",
-         "Duplicate definitions of proto_and_def at\n  - line 7, column 3\n  - line 8, column 3\n",
-         "Duplicate definitions of put at\n  - (builtin location)\n  - line 15, column 3\n",
-         "Duplicate definitions of state at\n  - (builtin location)\n  - line 16, column 3\n"]}
+       [<<"Duplicate definitions of abort at\n"
+          "  - (builtin location)\n"
+          "  - line 14, column 3">>,
+        <<"Duplicate definitions of require at\n"
+          "  - (builtin location)\n"
+          "  - line 15, column 3">>,
+        <<"Duplicate definitions of double_def at\n"
+          "  - line 10, column 3\n"
+          "  - line 11, column 3">>,
+        <<"Duplicate definitions of double_proto at\n"
+          "  - line 4, column 3\n"
+          "  - line 5, column 3">>,
+        <<"Duplicate definitions of proto_and_def at\n"
+          "  - line 7, column 3\n"
+          "  - line 8, column 3">>,
+        <<"Duplicate definitions of put at\n"
+          "  - (builtin location)\n"
+          "  - line 16, column 3">>,
+        <<"Duplicate definitions of state at\n"
+          "  - (builtin location)\n"
+          "  - line 17, column 3">>]}
     , {"type_errors",
-        ["Unbound variable zz at line 17, column 21\n",
-         "Cannot unify int\n"
-         "         and list(int)\n"
-         "when checking the application at line 26, column 9 of\n"
-         "  (::) : (int, list(int)) => list(int)\n"
-         "to arguments\n"
-         "  x : int\n"
-         "  x : int\n",
-         "Cannot unify string\n"
-         "         and int\n"
-         "when checking the assignment of the field\n"
-         "  x : map(string, string) (at line 9, column 46)\n"
-         "to the old value __x and the new value\n"
-         "  __x {[\"foo\"] @ x = x + 1} : map(string, int)\n",
-         "Cannot unify int\n"
-         "         and string\n"
-         "when checking the type of the expression at line 34, column 45\n"
-         "  1 : int\n"
-         "against the expected type\n"
-         "  string\n",
-         "Cannot unify string\n"
-         "         and int\n"
-         "when checking the type of the expression at line 34, column 50\n"
-         "  \"bla\" : string\n"
-         "against the expected type\n"
-         "  int\n",
-         "Cannot unify string\n"
-         "         and int\n"
-         "when checking the type of the expression at line 32, column 18\n"
-         "  \"x\" : string\n"
-         "against the expected type\n"
-         "  int\n",
-         "Cannot unify string\n"
-         "         and int\n"
-         "when checking the type of the expression at line 11, column 56\n"
-         "  \"foo\" : string\n"
-         "against the expected type\n"
-         "  int\n",
-         "Cannot unify int\n"
-         "         and string\n"
-         "when comparing the types of the if-branches\n"
-         "  - w : int (at line 38, column 13)\n"
-         "  - z : string (at line 39, column 10)\n",
-         "Not a record type: string\n"
-         "arising from the projection of the field y (at line 22, column 38)\n",
-         "Not a record type: string\n"
-         "arising from an assignment of the field y (at line 21, column 42)\n",
-         "Not a record type: string\n"
-         "arising from an assignment of the field y (at line 20, column 38)\n",
-         "Not a record type: string\n"
-         "arising from an assignment of the field y (at line 19, column 35)\n",
-         "Ambiguous record type with field y (at line 13, column 25) could be one of\n"
-         "  - r (at line 4, column 10)\n"
-         "  - r' (at line 5, column 10)\n",
-         "Record type r2 does not have field y (at line 15, column 22)\n",
-         "The field z is missing when constructing an element of type r2 (at line 15, column 24)\n",
-         "Repeated name x in pattern\n"
-         "  x :: x (at line 26, column 7)\n",
-         "No record type with fields y, z (at line 14, column 22)\n"]}
+       [<<"Unbound variable zz at line 17, column 23">>,
+        <<"Cannot unify int\n"
+          "         and list(int)\n"
+          "when checking the application at line 26, column 9 of\n"
+          "  (::) : (int, list(int)) => list(int)\n"
+          "to arguments\n"
+          "  x : int\n"
+          "  x : int">>,
+        <<"Cannot unify string\n"
+          "         and int\n"
+          "when checking the assignment of the field\n"
+          "  x : map(string, string) (at line 9, column 48)\n"
+          "to the old value __x and the new value\n"
+          "  __x {[\"foo\"] @ x = x + 1} : map(string, int)">>,
+        <<"Cannot unify int\n"
+          "         and string\n"
+          "when checking the type of the expression at line 34, column 47\n"
+          "  1 : int\n"
+          "against the expected type\n"
+          "  string">>,
+        <<"Cannot unify string\n"
+          "         and int\n"
+          "when checking the type of the expression at line 34, column 52\n"
+          "  \"bla\" : string\n"
+          "against the expected type\n"
+          "  int">>,
+        <<"Cannot unify string\n"
+          "         and int\n"
+          "when checking the type of the expression at line 32, column 18\n"
+          "  \"x\" : string\n"
+          "against the expected type\n"
+          "  int">>,
+        <<"Cannot unify string\n"
+          "         and int\n"
+          "when checking the type of the expression at line 11, column 58\n"
+          "  \"foo\" : string\n"
+          "against the expected type\n"
+          "  int">>,
+        <<"Cannot unify int\n"
+          "         and string\n"
+          "when comparing the types of the if-branches\n"
+          "  - w : int (at line 38, column 13)\n"
+          "  - z : string (at line 39, column 10)">>,
+        <<"Not a record type: string\n"
+          "arising from the projection of the field y (at line 22, column 40)">>,
+        <<"Not a record type: string\n"
+          "arising from an assignment of the field y (at line 21, column 44)">>,
+        <<"Not a record type: string\n"
+          "arising from an assignment of the field y (at line 20, column 40)">>,
+        <<"Not a record type: string\n"
+          "arising from an assignment of the field y (at line 19, column 37)">>,
+        <<"Ambiguous record type with field y (at line 13, column 27) could be one of\n"
+          "  - r (at line 4, column 10)\n"
+          "  - r' (at line 5, column 10)">>,
+        <<"Repeated name x in pattern\n"
+          "  x :: x (at line 26, column 7)">>,
+        <<"Repeated argument x to function repeated_arg (at line 44, column 14).">>,
+        <<"Repeated argument y to function repeated_arg (at line 44, column 14).">>,
+        <<"No record type with fields y, z (at line 14, column 24)">>,
+        <<"The field z is missing when constructing an element of type r2 (at line 15, column 26)">>,
+        <<"Record type r2 does not have field y (at line 15, column 24)">>,
+        <<"Let binding at line 47, column 5 must be followed by an expression">>,
+        <<"Let binding at line 50, column 5 must be followed by an expression">>,
+        <<"Let binding at line 54, column 5 must be followed by an expression">>,
+        <<"Let binding at line 58, column 5 must be followed by an expression">>]}
     , {"init_type_error",
-        ["Cannot unify string\n"
-         "         and map(int, int)\n"
-         "when checking that 'init' returns a value of type 'state' at line 7, column 3\n"]}
+       [<<"Cannot unify string\n"
+          "         and map(int, int)\n"
+          "when checking that 'init' returns a value of type 'state' at line 7, column 3">>]}
     , {"missing_state_type",
-        ["Cannot unify string\n"
-         "         and ()\n"
-         "when checking that 'init' returns a value of type 'state' at line 5, column 3\n"]}
+       [<<"Cannot unify string\n"
+          "         and ()\n"
+          "when checking that 'init' returns a value of type 'state' at line 5, column 3">>]}
     , {"missing_fields_in_record_expression",
-        ["The field x is missing when constructing an element of type r('a) (at line 7, column 40)\n",
-         "The field y is missing when constructing an element of type r(int) (at line 8, column 40)\n",
-         "The fields y, z are missing when constructing an element of type r('1) (at line 6, column 40)\n"]}
+       [<<"The field x is missing when constructing an element of type r('a) (at line 7, column 42)">>,
+        <<"The field y is missing when constructing an element of type r(int) (at line 8, column 42)">>,
+        <<"The fields y, z are missing when constructing an element of type r('a) (at line 6, column 42)">>]}
+    , {"namespace_clash",
+       [<<"The contract Call (at line 4, column 10) has the same name as a namespace at (builtin location)">>]}
+    , {"bad_events",
+        [<<"The indexed type string (at line 9, column 25) is not a word type">>,
+         <<"The indexed type alias_string (at line 10, column 25) equals string which is not a word type">>]}
+    , {"bad_events2",
+        [<<"The event constructor BadEvent1 (at line 9, column 7) has too many non-indexed values (max 1)">>,
+         <<"The event constructor BadEvent2 (at line 10, column 7) has too many indexed values (max 3)">>]}
+    , {"type_clash",
+        [<<"Cannot unify int\n"
+           "         and string\n"
+           "when checking the record projection at line 12, column 42\n"
+           "  r.foo : (gas : int, value : int) => Remote.themap\n"
+           "against the expected type\n"
+           "  (gas : int, value : int) => map(string, int)">>]}
+    , {"bad_include_and_ns",
+        [<<"Include of 'included.aes' at line 2, column 11\nnot allowed, include only allowed at top level.">>,
+         <<"Nested namespace not allowed\nNamespace 'Foo' at line 3, column 13 not defined at top level.">>]}
+    , {"bad_address_literals",
+        [<<"The type bytes(32) is not a contract type\n"
+           "when checking that the contract literal at line 32, column 5\n"
+           "  ct_Ez6MyeTMm17YnTnDdHTSrzMEBKmy7Uz2sXu347bTDPgVH2ifJ\n"
+           "has the type\n"
+           "  bytes(32)">>,
+         <<"The type oracle(int, bool) is not a contract type\n"
+           "when checking that the contract literal at line 30, column 5\n"
+           "  ct_Ez6MyeTMm17YnTnDdHTSrzMEBKmy7Uz2sXu347bTDPgVH2ifJ\n"
+           "has the type\n"
+           "  oracle(int, bool)">>,
+         <<"The type address is not a contract type\n"
+           "when checking that the contract literal at line 28, column 5\n"
+           "  ct_Ez6MyeTMm17YnTnDdHTSrzMEBKmy7Uz2sXu347bTDPgVH2ifJ\n"
+           "has the type\n"
+           "  address">>,
+         <<"Cannot unify oracle_query('a, 'b)\n"
+           "         and Remote\n"
+           "when checking the type of the expression at line 25, column 5\n"
+           "  oq_2oRvyowJuJnEkxy58Ckkw77XfWJrmRgmGaLzhdqb67SKEL1gPY :\n"
+           "    oracle_query('a, 'b)\n"
+           "against the expected type\n"
+           "  Remote">>,
+         <<"Cannot unify oracle_query('c, 'd)\n"
+           "         and bytes(32)\n"
+           "when checking the type of the expression at line 23, column 5\n"
+           "  oq_2oRvyowJuJnEkxy58Ckkw77XfWJrmRgmGaLzhdqb67SKEL1gPY :\n"
+           "    oracle_query('c, 'd)\n"
+           "against the expected type\n"
+           "  bytes(32)">>,
+         <<"Cannot unify oracle_query('e, 'f)\n"
+           "         and oracle(int, bool)\n"
+           "when checking the type of the expression at line 21, column 5\n"
+           "  oq_2oRvyowJuJnEkxy58Ckkw77XfWJrmRgmGaLzhdqb67SKEL1gPY :\n"
+           "    oracle_query('e, 'f)\n"
+           "against the expected type\n"
+           "  oracle(int, bool)">>,
+         <<"Cannot unify oracle('g, 'h)\n"
+           "         and Remote\n"
+           "when checking the type of the expression at line 18, column 5\n"
+           "  ok_2YNyxd6TRJPNrTcEDCe9ra59SVUdp9FR9qWC5msKZWYD9bP9z5 :\n"
+           "    oracle('g, 'h)\n"
+           "against the expected type\n"
+           "  Remote">>,
+         <<"Cannot unify oracle('i, 'j)\n"
+           "         and bytes(32)\n"
+           "when checking the type of the expression at line 16, column 5\n"
+           "  ok_2YNyxd6TRJPNrTcEDCe9ra59SVUdp9FR9qWC5msKZWYD9bP9z5 :\n"
+           "    oracle('i, 'j)\n"
+           "against the expected type\n"
+           "  bytes(32)">>,
+         <<"Cannot unify oracle('k, 'l)\n"
+           "         and oracle_query(int, bool)\n"
+           "when checking the type of the expression at line 14, column 5\n"
+           "  ok_2YNyxd6TRJPNrTcEDCe9ra59SVUdp9FR9qWC5msKZWYD9bP9z5 :\n"
+           "    oracle('k, 'l)\n"
+           "against the expected type\n"
+           "  oracle_query(int, bool)">>,
+         <<"Cannot unify address\n"
+           "         and oracle(int, bool)\n"
+           "when checking the type of the expression at line 11, column 5\n"
+           "  ak_2gx9MEFxKvY9vMG5YnqnXWv1hCsX7rgnfvBLJS4aQurustR1rt : address\n"
+           "against the expected type\n"
+           "  oracle(int, bool)">>,
+         <<"Cannot unify address\n"
+           "         and Remote\n"
+           "when checking the type of the expression at line 9, column 5\n"
+           "  ak_2gx9MEFxKvY9vMG5YnqnXWv1hCsX7rgnfvBLJS4aQurustR1rt : address\n"
+           "against the expected type\n"
+           "  Remote">>,
+         <<"Cannot unify address\n"
+           "         and bytes(32)\n"
+           "when checking the type of the expression at line 7, column 5\n"
+           "  ak_2gx9MEFxKvY9vMG5YnqnXWv1hCsX7rgnfvBLJS4aQurustR1rt : address\n"
+           "against the expected type\n"
+           "  bytes(32)">>]}
+    , {"stateful",
+       [<<"Cannot reference stateful function Chain.spend (at line 13, column 35)\nin the definition of non-stateful function fail1.">>,
+        <<"Cannot reference stateful function local_spend (at line 14, column 35)\nin the definition of non-stateful function fail2.">>,
+        <<"Cannot reference stateful function Chain.spend (at line 16, column 15)\nin the definition of non-stateful function fail3.">>,
+        <<"Cannot reference stateful function Chain.spend (at line 20, column 31)\nin the definition of non-stateful function fail4.">>,
+        <<"Cannot reference stateful function Chain.spend (at line 35, column 45)\nin the definition of non-stateful function fail5.">>,
+        <<"Cannot pass non-zero value argument 1000 (at line 48, column 57)\nin the definition of non-stateful function fail6.">>,
+        <<"Cannot pass non-zero value argument 1000 (at line 49, column 56)\nin the definition of non-stateful function fail7.">>,
+        <<"Cannot pass non-zero value argument 1000 (at line 52, column 17)\nin the definition of non-stateful function fail8.">>]}
+    , {"bad_init_state_access",
+       [<<"The init function should return the initial state as its result and cannot write the state,\n"
+          "but it calls\n"
+          "  - set_state (at line 11, column 5), which calls\n"
+          "  - roundabout (at line 8, column 38), which calls\n"
+          "  - put (at line 7, column 39)">>,
+        <<"The init function should return the initial state as its result and cannot read the state,\n"
+          "but it calls\n"
+          "  - new_state (at line 12, column 5), which calls\n"
+          "  - state (at line 5, column 29)">>,
+        <<"The init function should return the initial state as its result and cannot read the state,\n"
+          "but it calls\n"
+          "  - state (at line 13, column 13)">>]}
+    , {"field_parse_error",
+       [<<"line 6, column 1: In field_parse_error at 5:26:\n"
+          "Cannot use nested fields or keys in record construction: p.x\n">>]}
+    , {"modifier_checks",
+       [<<"The function all_the_things (at line 11, column 3) cannot be both public and private.">>,
+        <<"Namespaces cannot contain entrypoints (at line 3, column 3). Use 'function' instead.">>,
+        <<"The contract Remote (at line 5, column 10) has no entrypoints. Since Sophia version 3.2, public\ncontract functions must be declared with the 'entrypoint' keyword instead of\n'function'.">>,
+        <<"The entrypoint wha (at line 12, column 3) cannot be private. Use 'function' instead.">>,
+        <<"Use 'entrypoint' for declaration of foo (at line 6, column 3):\n  entrypoint foo : () => ()">>,
+        <<"Use 'entrypoint' instead of 'function' for public function foo (at line 10, column 3):\n  entrypoint foo() = ()">>,
+        <<"Use 'entrypoint' instead of 'function' for public function foo (at line 6, column 3):\n  entrypoint foo : () => ()">>]}
     ].

test/aeso_eunit_SUITE.erl

@@ -12,9 +12,11 @@ groups() ->
                  , aeso_parser_tests
                  , aeso_compiler_tests
                  , aeso_abi_tests
+		 , aeso_aci_tests
                  ]}].
 
 aeso_scan_tests(_Config)   -> ok = eunit:test(aeso_scan_tests).
 aeso_parser_tests(_Config) -> ok = eunit:test(aeso_parser_tests).
 aeso_compiler_tests(_Config) -> ok = eunit:test(aeso_compiler_tests).
 aeso_abi_tests(_Config) -> ok = eunit:test(aeso_abi_tests).
+aeso_aci_tests(_Config) -> ok = eunit:test(aeso_aci_tests).

test/aeso_parser_tests.erl

@@ -62,7 +62,7 @@ simple_contracts_test_() ->
      %% Parse tests of example contracts
      [ {lists:concat(["Parse the ", Contract, " contract."]),
         fun() -> roundtrip_contract(Contract) end}
-        || Contract <- [counter, voting, all_syntax, '05_greeter', aeproof, multi_sig, simple_storage, withdrawal, fundme, dutch_auction] ]
+        || Contract <- [counter, voting, all_syntax, '05_greeter', aeproof, multi_sig, simple_storage, fundme, dutch_auction] ]
     }.
 
 parse_contract(Name) ->

test/aeso_scan_tests.erl

@@ -41,14 +41,14 @@ all_tokens() ->
     %% Operators
     lists:map(Lit, ['=', '==', '!=', '>', '<', '>=', '=<', '-', '+', '++', '*', '/', mod, ':', '::', '->', '=>', '||', '&&', '!']) ++
     %% Keywords
-    lists:map(Lit, [contract, type, 'let', switch, rec, 'and']) ++
+    lists:map(Lit, [contract, type, 'let', switch]) ++
     %% Comment token (not an actual token), just for tests
     [{comment, 0, "// *Comment!\"\n"},
      {comment, 0, "/* bla /* bla bla */*/"}] ++
     %% Literals
     [ Lit(true), Lit(false)
     , Tok(id, "foo"), Tok(id, "_"), Tok(con, "Foo")
-    , Tok(hash, Hash)
+    , Tok(bytes, Hash)
     , Tok(int, 1234567890), Tok(hex, 9876543210)
     , Tok(string, <<"bla\"\\\b\e\f\n\r\t\vbla">>)
     ].
@@ -78,7 +78,7 @@ show_token({param, _, P}) -> "@" ++ P;
 show_token({string, _, S}) -> fmt(binary_to_list(S));
 show_token({int, _, N}) -> fmt(N);
 show_token({hex, _, N}) -> fmt("0x~.16b", N);
-show_token({hash, _, <<N:256>>}) -> fmt("#~.16b", N);
+show_token({bytes, _, <<N:256>>}) -> fmt("#~64.16.0b", N);
 show_token({comment, _, S}) -> S;
 show_token({_, _, _}) -> "TODO".
 

test/contract_tests.erl

@@ -1,28 +0,0 @@
--module(contract_tests).
-
--include_lib("eunit/include/eunit.hrl").
-
-make_cmd() -> "make -C " ++ aeso_test_utils:contract_path().
-
-contracts_test_() ->
-    {setup,
-     fun()  -> os:cmd(make_cmd()) end,
-     fun(_) -> os:cmd(make_cmd() ++ " clean") end,
-     [ {"Testing the " ++ Contract ++ " contract",
-        fun() ->
-          ?assertCmdOutput(Expected, filename:join(aeso_test_utils:contract_path(), Contract ++ "_test"))
-        end} || {Contract, Expected} <- contracts() ]}.
-
-contracts() ->
-    [].
-  %% [{"voting",
-  %%   "Delegate before vote\n"
-  %%   "Cake: 1\n"
-  %%   "Beer: 2\n"
-  %%   "Winner: Beer\n"
-  %%   "Delegate after vote\n"
-  %%   "Cake: 1\n"
-  %%   "Beer: 2\n"
-  %%   "Winner: Beer\n"
-  %% }].
-

test/contracts/__call.aes

@@ -0,0 +1,5 @@
+
+contract Identity =
+  function main (x:int) = x
+
+  function __call() = 12

test/contracts/address_chain.aes

@@ -0,0 +1,33 @@
+contract Remote =
+  entrypoint main : (int) => ()
+
+contract AddrChain =
+  type o_type = oracle(string, map(string, int))
+  type oq_type = oracle_query(string, map(string, int))
+
+  entrypoint is_o(a : address) =
+    Address.is_oracle(a)
+
+  entrypoint is_c(a : address) =
+    Address.is_contract(a)
+
+//   entrypoint get_o(a : address) : option(o_type) =
+//     Address.get_oracle(a)
+
+//   entrypoint get_c(a : address) : option(Remote) =
+//     Address.get_contract(a)
+
+  entrypoint check_o(o : o_type) =
+    Oracle.check(o)
+
+  entrypoint check_oq(o : o_type, oq : oq_type) =
+    Oracle.check_query(o, oq)
+
+//   entrypoint h_to_i(h : hash) : int =
+//     Hash.to_int(h)
+
+//   entrypoint a_to_i(a : address) : int =
+//     Address.to_int(a) mod 10 ^ 16
+
+  entrypoint c_creator() : address =
+    Contract.creator

test/contracts/address_literals.aes

@@ -0,0 +1,14 @@
+
+contract Remote =
+  entrypoint foo : () => ()
+
+contract AddressLiterals =
+  entrypoint addr() : address =
+    ak_2gx9MEFxKvY9vMG5YnqnXWv1hCsX7rgnfvBLJS4aQurustR1rt
+  entrypoint oracle() : oracle(int, bool) =
+    ok_2YNyxd6TRJPNrTcEDCe9ra59SVUdp9FR9qWC5msKZWYD9bP9z5
+  entrypoint query() : oracle_query(int, bool) =
+    oq_2oRvyowJuJnEkxy58Ckkw77XfWJrmRgmGaLzhdqb67SKEL1gPY
+  entrypoint contr() : Remote =
+    ct_Ez6MyeTMm17YnTnDdHTSrzMEBKmy7Uz2sXu347bTDPgVH2ifJ
+

test/contracts/aens.aes

@@ -3,53 +3,53 @@ contract AENSTest =
 
   // Name resolution
 
-  function resolve_word(name : string, key : string) : option(address) =
+  stateful entrypoint resolve_word(name : string, key : string) : option(address) =
     AENS.resolve(name, key)
 
-  function resolve_string(name : string, key : string) : option(string) =
+  stateful entrypoint resolve_string(name : string, key : string) : option(string) =
     AENS.resolve(name, key)
 
   // Transactions
 
-  function preclaim(addr  : address,          // Claim on behalf of this account (can be Contract.address)
-                    chash : hash) : () =      // Commitment hash
+  stateful entrypoint preclaim(addr  : address,     // Claim on behalf of this account (can be Contract.address)
+                             chash : hash) : () = // Commitment hash
     AENS.preclaim(addr, chash)
 
-  function signedPreclaim(addr  : address,          // Claim on behalf of this account (can be Contract.address)
-                          chash : hash,             // Commitment hash
-                          sign  : signature) : () = // Signed by addr (if not Contract.address)
+  stateful entrypoint signedPreclaim(addr  : address, // Claim on behalf of this account (can be Contract.address)
+                                   chash : hash,             // Commitment hash
+                                   sign  : signature) : () = // Signed by addr (if not Contract.address)
     AENS.preclaim(addr, chash, signature = sign)
 
-  function claim(addr : address,
-                 name : string,
-                 salt : int) : () =
+  stateful entrypoint claim(addr : address,
+                          name : string,
+                          salt : int) : () =
     AENS.claim(addr, name, salt)
 
-  function signedClaim(addr : address,
-                       name : string,
-                       salt : int,
-                       sign : signature) : () =
+  stateful entrypoint signedClaim(addr : address,
+                                name : string,
+                                salt : int,
+                                sign : signature) : () =
     AENS.claim(addr, name, salt, signature = sign)
 
   // TODO: update() -- how to handle pointers?
 
-  function transfer(owner     : address,
-                    new_owner : address,
-                    name_hash : hash) : () =
+  stateful entrypoint transfer(owner     : address,
+                             new_owner : address,
+                             name_hash : hash) : () =
     AENS.transfer(owner, new_owner, name_hash)
 
-  function signedTransfer(owner     : address,
-                          new_owner : address,
-                          name_hash : hash,
-                          sign      : signature) : () =
+  stateful entrypoint signedTransfer(owner     : address,
+                                   new_owner : address,
+                                   name_hash : hash,
+                                   sign      : signature) : () =
     AENS.transfer(owner, new_owner, name_hash, signature = sign)
 
-  function revoke(owner     : address,
-                  name_hash : hash) : () =
+  stateful entrypoint revoke(owner     : address,
+                           name_hash : hash) : () =
     AENS.revoke(owner, name_hash)
 
-  function signedRevoke(owner     : address,
-                        name_hash : hash,
-                        sign      : signature) : () =
+  stateful entrypoint signedRevoke(owner     : address,
+                                 name_hash : hash,
+                                 sign      : signature) : () =
     AENS.revoke(owner, name_hash, signature = sign)
 

test/contracts/aeproof.aes

@@ -104,10 +104,10 @@ contract AEProof =
                      proofsByOwner : map(address, array(uint)) }
 
     function notarize(document:string, comment:string, ipfsHash:hash) =
-        let _ = require(aetoken.balanceOf(caller()) > 0)
+        let _ = require(aetoken.balanceOf(caller()) > 0, "false")
         let proofHash: uint = calculateHash(document)
         let proof : proof = Map.get_(proofHash, state().proofs)
-        let _ = require(proof.owner == #0)
+        let _ = require(proof.owner == #0, "false")
         let proof' : proof = proof { owner = caller()
                                    , timestamp = block().timestamp
                                    , proofBlock = block().height
@@ -124,12 +124,12 @@ contract AEProof =
     function getProof(document) : proof =
         let calcHash = calculateHash(document)
         let proof = Map.get_(calcHash, state().proofs)
-        let _ = require(proof.owner != #0)
+        let _ = require(proof.owner != #0, "false")
         proof
 
     function getProofByHash(hash: uint) : proof =
         let proof = Map.get_(hash, state().proofs)
-        let _ = require(proof.owner != #0)
+        let _ = require(proof.owner != #0, "false")
         proof
 
 
@@ -141,5 +141,3 @@ contract AEProof =
     function getProofsByOwner(owner: address): array(uint) =
         Map.get(owner, state())
 
-    function require(x : bool) : unit = if(x) () else abort("false")
-

test/contracts/all_syntax.aes

@@ -36,13 +36,6 @@ contract AllSyntax =
       (x, [y, z]) => bar({x = z, y = -y + - -z * (-1)})
       (x, y :: _) => ()
 
-  function bitOperations(x, y) = bnot (0xff00 band x bsl 4 bxor 0xa5a5a5 bsr 4 bor y)
-
-  function mutual() =
-    let rec recFun(x : int) = mutFun(x)
-        and mutFun(x) = if(x =< 0) 1 else x * recFun(x - 1)
-    recFun(0)
-
   let hash : address = #01ab0fff11
   let b = false
   let qcon = Mod.Con

test/contracts/bad_address_literals.aes

@@ -0,0 +1,33 @@
+
+contract Remote =
+  entrypoint foo : () => ()
+
+contract AddressLiterals =
+  entrypoint addr1() : bytes(32) =
+    ak_2gx9MEFxKvY9vMG5YnqnXWv1hCsX7rgnfvBLJS4aQurustR1rt
+  entrypoint addr2() : Remote =
+    ak_2gx9MEFxKvY9vMG5YnqnXWv1hCsX7rgnfvBLJS4aQurustR1rt
+  entrypoint addr3() : oracle(int, bool) =
+    ak_2gx9MEFxKvY9vMG5YnqnXWv1hCsX7rgnfvBLJS4aQurustR1rt
+
+  entrypoint oracle1() : oracle_query(int, bool) =
+    ok_2YNyxd6TRJPNrTcEDCe9ra59SVUdp9FR9qWC5msKZWYD9bP9z5
+  entrypoint oracle2() : bytes(32) =
+    ok_2YNyxd6TRJPNrTcEDCe9ra59SVUdp9FR9qWC5msKZWYD9bP9z5
+  entrypoint oracle3() : Remote =
+    ok_2YNyxd6TRJPNrTcEDCe9ra59SVUdp9FR9qWC5msKZWYD9bP9z5
+
+  entrypoint query1() : oracle(int, bool) =
+    oq_2oRvyowJuJnEkxy58Ckkw77XfWJrmRgmGaLzhdqb67SKEL1gPY
+  entrypoint query2() : bytes(32) =
+    oq_2oRvyowJuJnEkxy58Ckkw77XfWJrmRgmGaLzhdqb67SKEL1gPY
+  entrypoint query3() : Remote =
+    oq_2oRvyowJuJnEkxy58Ckkw77XfWJrmRgmGaLzhdqb67SKEL1gPY
+
+  entrypoint contr1() : address =
+    ct_Ez6MyeTMm17YnTnDdHTSrzMEBKmy7Uz2sXu347bTDPgVH2ifJ
+  entrypoint contr2() : oracle(int, bool) =
+    ct_Ez6MyeTMm17YnTnDdHTSrzMEBKmy7Uz2sXu347bTDPgVH2ifJ
+  entrypoint contr3() : bytes(32) =
+    ct_Ez6MyeTMm17YnTnDdHTSrzMEBKmy7Uz2sXu347bTDPgVH2ifJ
+

test/contracts/bad_events.aes

@@ -0,0 +1,23 @@
+contract Events =
+  type alias_int = int
+  type alias_address = address
+  type alias_string = string
+
+  datatype event =
+      Event1(indexed alias_int, indexed int, string)
+    | Event2(alias_string, indexed alias_address)
+    | BadEvent1(indexed string)
+    | BadEvent2(indexed alias_string)
+
+  entrypoint f1(x : int, y : string) =
+    Chain.event(Event1(x, x+1, y))
+
+  entrypoint f2(s : string) =
+    Chain.event(Event2(s, Call.caller))
+
+  entrypoint f3(x : int) =
+    Chain.event(Event1(x, x + 2, Int.to_str(x + 7)))
+
+  entrypoint i2s(i : int) = Int.to_str(i)
+  entrypoint a2s(a : address) = Address.to_str(a)
+

test/contracts/bad_events2.aes

@@ -0,0 +1,23 @@
+contract Events =
+  type alias_int = int
+  type alias_address = address
+  type alias_string = string
+
+  datatype event =
+      Event1(indexed alias_int, indexed int, string)
+    | Event2(alias_string, indexed alias_address)
+    | BadEvent1(string, string)
+    | BadEvent2(indexed int, indexed int, indexed int, indexed address)
+
+  entrypoint f1(x : int, y : string) =
+    Chain.event(Event1(x, x+1, y))
+
+  entrypoint f2(s : string) =
+    Chain.event(Event2(s, Call.caller))
+
+  entrypoint f3(x : int) =
+    Chain.event(Event1(x, x + 2, Int.to_str(x + 7)))
+
+  entrypoint i2s(i : int) = Int.to_str(i)
+  entrypoint a2s(a : address) = Address.to_str(a)
+

test/contracts/bad_include_and_ns.aes

@@ -0,0 +1,6 @@
+contract Bad =
+  include "included.aes"
+  namespace Foo =
+    function foo() = 42
+
+  entrypoint foo() = 43

test/contracts/bad_init_state_access.aes

@@ -0,0 +1,13 @@
+contract BadInit =
+
+  type state = int
+
+  entrypoint new_state(n) = state + n
+
+  stateful entrypoint roundabout(n) = put(n)
+  stateful entrypoint set_state(n) = roundabout(n)
+
+  stateful entrypoint init() =
+    set_state(4)
+    new_state(0)
+    state + state

test/contracts/basic_auth.aes

@@ -0,0 +1,17 @@
+// Contract replicating "normal" Aeternity authentication
+contract BasicAuth =
+  record state = { nonce : int, owner : address }
+
+  entrypoint init() = { nonce = 1, owner = Call.caller }
+
+  stateful entrypoint authorize(n : int, s : signature) : bool =
+    require(n >= state.nonce, "Nonce too low")
+    require(n =< state.nonce, "Nonce too high")
+    put(state{ nonce = n + 1 })
+    switch(Auth.tx_hash)
+      None          => abort("Not in Auth context")
+      Some(tx_hash) => Crypto.ecverify(to_sign(tx_hash, n), state.owner, s)
+
+  entrypoint to_sign(h : hash, n : int) =
+    Crypto.blake2b((h, n))
+

test/contracts/bitcoin_auth.aes

@@ -0,0 +1,16 @@
+contract BitcoinAuth =
+  record state = { nonce : int, owner : bytes(64) }
+
+  entrypoint init(owner' : bytes(64)) = { nonce = 1, owner = owner' }
+
+  stateful entrypoint authorize(n : int, s : signature) : bool =
+    require(n >= state.nonce, "Nonce too low")
+    require(n =< state.nonce, "Nonce too high")
+    put(state{ nonce = n + 1 })
+    switch(Auth.tx_hash)
+      None          => abort("Not in Auth context")
+      Some(tx_hash) => Crypto.ecverify_secp256k1(to_sign(tx_hash, n), state.owner, s)
+
+  entrypoint to_sign(h : hash, n : int) : hash =
+    Crypto.blake2b((h, n))
+

test/contracts/builtin_bug.aes

@@ -5,8 +5,8 @@ contract BuiltinBug =
 
   record state = {proofs : map(address, list(string))}
 
-  public function init() = {proofs = {}}
+  entrypoint init() = {proofs = {}}
 
-  public stateful function createProof(hash : string) =
+  stateful entrypoint createProof(hash : string) =
     put( state{ proofs[Call.caller] = hash :: state.proofs[Call.caller] } )
 

test/contracts/builtin_map_get_bug.aes

@@ -1,12 +1,8 @@
 contract TestContract =
-  record state = { 
-    _allowed          : map(address, map(address, int))}
+  record state = {_allowed : map(address, map(address, int))}
 
-  public stateful function init() = {
-    _allowed = {}}
-
-  public stateful function approve(spender: address, value: int) : bool = 
+  entrypoint init() = {_allowed = {}}
 
+  stateful entrypoint approve(spender: address, value: int) : bool =
     put(state{_allowed[Call.caller][spender] = value})
-
     true

test/contracts/bytes_equality.aes

@@ -0,0 +1,18 @@
+
+contract BytesEquality =
+
+  entrypoint eq16(a : bytes(16), b) = a == b
+  entrypoint ne16(a : bytes(16), b) = a != b
+
+  entrypoint eq32(a : bytes(32), b) = a == b
+  entrypoint ne32(a : bytes(32), b) = a != b
+
+  entrypoint eq47(a : bytes(47), b) = a == b
+  entrypoint ne47(a : bytes(47), b) = a != b
+
+  entrypoint eq64(a : bytes(64), b) = a == b
+  entrypoint ne64(a : bytes(64), b) = a != b
+
+  entrypoint eq65(a : bytes(65), b) = a == b
+  entrypoint ne65(a : bytes(65), b) = a != b
+

test/contracts/bytes_to_x.aes

@@ -0,0 +1,8 @@
+
+contract BytesToX =
+
+  entrypoint to_int(b : bytes(42)) : int = Bytes.to_int(b)
+  entrypoint to_str(b : bytes(12)) : string =
+    String.concat(Bytes.to_str(b), Bytes.to_str(#ffff))
+  entrypoint to_str_big(b : bytes(65)) : string =
+    Bytes.to_str(b)

test/contracts/chain.aes

@@ -1,6 +1,6 @@
 // Test more advanced chain interactions
 
-contract Chain =
+contract ChainTest =
 
   record state = { last_bf : address }
 
@@ -10,4 +10,4 @@ contract Chain =
   function miner() = Chain.coinbase
 
   function save_coinbase() =
-    put(state{last_bf = Chain.coinbase})
+    put(state{last_bf = Chain.coinbase})

test/contracts/complex_types.aes

@@ -1,78 +1,78 @@
 
 contract Remote =
-  function up_to       : (int)               => list(int)
-  function sum         : (list(int))         => int
-  function some_string : ()                  => string
-  function pair        : (int, string)       => (int, string)
-  function squares     : (int)               => list((int, int))
-  function filter_some : (list(option(int))) => list(int)
-  function all_some    : (list(option(int))) => option(list(int))
+  entrypoint up_to       : (int)               => list(int)
+  entrypoint sum         : (list(int))         => int
+  entrypoint some_string : ()                  => string
+  entrypoint pair        : (int, string)       => (int, string)
+  entrypoint squares     : (int)               => list((int, int))
+  entrypoint filter_some : (list(option(int))) => list(int)
+  entrypoint all_some    : (list(option(int))) => option(list(int))
 
 contract ComplexTypes =
 
   record state = { worker : Remote }
 
-  function init(worker) = {worker = worker}
+  entrypoint init(worker) = {worker = worker}
 
-  function sum_acc(xs, n) =
+  entrypoint sum_acc(xs, n) =
     switch(xs)
       []      => n
       x :: xs => sum_acc(xs, x + n)
 
   // Sum a list of integers
-  function sum(xs : list(int)) =
+  entrypoint sum(xs : list(int)) =
     sum_acc(xs, 0)
 
-  function up_to_acc(n, xs) =
+  entrypoint up_to_acc(n, xs) =
     switch(n)
       0 => xs
       _ => up_to_acc(n - 1, n :: xs)
 
-  function up_to(n) = up_to_acc(n, [])
+  entrypoint up_to(n) = up_to_acc(n, [])
 
   record answer('a) = {label : string, result : 'a}
 
-  function remote_triangle(worker, n) : answer(int) =
+  entrypoint remote_triangle(worker, n) : answer(int) =
     let xs = worker.up_to(gas = 100000, n)
     let t  = worker.sum(xs)
     { label = "answer:", result = t }
 
-  function remote_list(n) : list(int) =
+  entrypoint remote_list(n) : list(int) =
     state.worker.up_to(n)
 
-  function some_string() = "string"
+  entrypoint some_string() = "string"
 
-  function remote_string() : string =
+  entrypoint remote_string() : string =
     state.worker.some_string()
 
-  function pair(x : int, y : string) = (x, y)
+  entrypoint pair(x : int, y : string) = (x, y)
 
-  function remote_pair(n : int, s : string) : (int, string) =
+  entrypoint remote_pair(n : int, s : string) : (int, string) =
     state.worker.pair(gas = 10000, n, s)
 
-  function map(f, xs) =
+  entrypoint map(f, xs) =
     switch(xs)
       []      => []
       x :: xs => f(x) :: map(f, xs)
 
-  function squares(n) =
+  entrypoint squares(n) =
     map((i) => (i, i * i), up_to(n))
 
-  function remote_squares(n) : list((int, int)) =
+  entrypoint remote_squares(n) : list((int, int)) =
     state.worker.squares(n)
 
   // option types
 
-  function filter_some(xs : list(option(int))) : list(int) =
+  entrypoint filter_some(xs : list(option(int))) : list(int) =
     switch(xs)
       []            => []
       None    :: ys => filter_some(ys)
       Some(x) :: ys => x :: filter_some(ys)
 
-  function remote_filter_some(xs : list(option(int))) : list(int) =
+  entrypoint remote_filter_some(xs : list(option(int))) : list(int) =
     state.worker.filter_some(xs)
 
-  function all_some(xs : list(option(int))) : option(list(int)) =
+  entrypoint all_some(xs : list(option(int))) : option(list(int)) =
     switch(xs)
       []         => Some([])
       None :: ys => None
@@ -81,6 +81,6 @@ contract ComplexTypes =
           Some(xs) => Some(x :: xs)
           None     => None
 
-  function remote_all_some(xs : list(option(int))) : option(list(int)) =
+  entrypoint remote_all_some(xs : list(option(int))) : option(list(int)) =
     state.worker.all_some(gas = 10000, xs)
 

test/contracts/counter.aes

@@ -3,7 +3,7 @@ contract Counter =
 
   record state = { value : int }
 
-  function init(val) = { value = val }
-  function get()     = state.value
-  function tick()    = put(state{ value = state.value + 1 })
+  entrypoint init(val) = { value = val }
+  entrypoint get()     = state.value
+  stateful entrypoint tick()    = put(state{ value = state.value + 1 })
 

test/contracts/deadcode.aes

@@ -0,0 +1,21 @@
+
+namespace List =
+
+  function map1(f : 'a => 'b, xs : list('a)) =
+    switch(xs)
+      [] => []
+      x :: xs => f(x) :: map1(f, xs)
+
+  function map2(f : 'a => 'b, xs : list('a)) =
+    switch(xs)
+      [] => []
+      x :: xs => f(x) :: map2(f, xs)
+
+contract Deadcode =
+
+  entrypoint inc1(xs : list(int)) : list(int) =
+    List.map1((x) => x + 1, xs)
+
+  entrypoint inc2(xs : list(int)) : list(int) =
+    List.map1((x) => x + 1, xs)
+

test/contracts/dutch_auction.aes

@@ -10,16 +10,13 @@ contract DutchAuction =
                    sold         : bool }
 
   // Add to work around current lack of predefined functions
-  private function spend(to, amount) =
+  stateful function spend(to, amount) =
     let total = Contract.balance
     Chain.spend(to, amount)
     total - amount
 
-  private function require(b : bool, err : string) =
-    if(!b) abort(err)
-
   // TTL set by user on posting contract, typically (start - end ) div dec
-  public function init(beneficiary, start, decrease) : state =
+  entrypoint init(beneficiary, start, decrease) : state =
     require(start > 0 && decrease > 0, "bad args")
     { start_amount = start,
       start_height = Chain.block_height,
@@ -30,7 +27,7 @@ contract DutchAuction =
   // -- API
 
   // We are the buyer... interesting case to buy for someone else and keep 10%
-  public stateful function bid() =
+  stateful entrypoint bid() =
     require( !(state.sold), "sold")
     let cost =
       state.start_amount - (Chain.block_height - state.start_height) * state.dec

test/contracts/environment.aes

@@ -1,69 +1,69 @@
 
 // Testing primitives for accessing the block chain environment
 contract Interface =
-  function contract_address : () => address
-  function call_origin      : () => address
-  function call_caller      : () => address
-  function call_value       : () => int
+  entrypoint contract_address : () => address
+  entrypoint call_origin      : () => address
+  entrypoint call_caller      : () => address
+  entrypoint call_value       : () => int
 
 contract Environment =
 
   record state = {remote : Interface}
 
-  function init(remote) = {remote = remote}
+  entrypoint init(remote) = {remote = remote}
 
-  function set_remote(remote) = put({remote = remote})
+  stateful entrypoint set_remote(remote) = put({remote = remote})
 
   // -- Information about the this contract ---
 
   // Address
-  function contract_address() : address = Contract.address
-  function nested_address(who) : address =
+  entrypoint contract_address() : address = Contract.address
+  entrypoint nested_address(who) : address =
     who.contract_address(gas = 1000)
 
   // Balance
-  function contract_balance() : int = Contract.balance
+  entrypoint contract_balance() : int = Contract.balance
 
   // -- Information about the current call ---
 
   // Origin
-  function call_origin()   : address = Call.origin
-  function nested_origin() : address =
+  entrypoint call_origin()   : address = Call.origin
+  entrypoint nested_origin() : address =
     state.remote.call_origin()
 
   // Caller
-  function call_caller() : address = Call.caller
-  function nested_caller() : address =
+  entrypoint call_caller() : address = Call.caller
+  entrypoint nested_caller() : address =
     state.remote.call_caller()
 
   // Value
-  function call_value() : int = Call.value
-  function nested_value(value : int) : int =
+  entrypoint call_value() : int = Call.value
+  stateful entrypoint nested_value(value : int) : int =
     state.remote.call_value(value = value / 2)
 
   // Gas price
-  function call_gas_price() : int = Call.gas_price
+  entrypoint call_gas_price() : int = Call.gas_price
 
   // -- Information about the chain ---
 
   // Account balances
-  function get_balance(acct : address) : int = Chain.balance(acct)
+  entrypoint get_balance(acct : address) : int = Chain.balance(acct)
 
   // Block hash
-  function block_hash(height : int) : int = Chain.block_hash(height)
+  entrypoint block_hash(height : int) : option(hash) = Chain.block_hash(height)
 
   // Coinbase
-  function coinbase() : address = Chain.coinbase
+  entrypoint coinbase() : address = Chain.coinbase
 
   // Block timestamp
-  function timestamp() : int = Chain.timestamp
+  entrypoint timestamp() : int = Chain.timestamp
 
   // Block height
-  function block_height() : int = Chain.block_height
+  entrypoint block_height() : int = Chain.block_height
 
   // Difficulty
-  function difficulty() : int = Chain.difficulty
+  entrypoint difficulty() : int = Chain.difficulty
 
   // Gas limit
-  function gas_limit() : int = Chain.gas_limit
+  entrypoint gas_limit() : int = Chain.gas_limit
 

test/contracts/erc20_token.aes

@@ -77,9 +77,6 @@ contract ERC20Token =
     put( state{approval_log = e :: state.approval_log })
     e
 
-  private function require(b : bool, err : string) =
-    if(!b) abort(err)
-
   private function sub(_a : int, _b : int) : int =
     require(_b =< _a, "Error")
     _a - _b

test/contracts/events.aes

@@ -1,22 +1,40 @@
+contract Remote =
+  entrypoint dummy : () => ()
+
 contract Events =
-  type alias_int = int
-  type alias_address = address
-  type alias_string = string
 
-  datatype event =
-      Event1(indexed alias_int, indexed int, string)
-    | Event2(alias_string, indexed alias_address)
-    // | BadEvent1(indexed string, string)
-    // | BadEvent2(indexed int, int)
+  // Valid index types
+  type ix1 = int
+  type ix2 = bool
+  type ix3 = bits
+  type ix4 = bytes(12)
+  type ix5 = hash // bytes(32)
+  type ix6 = address
+  type ix7 = Remote
+  type ix8 = oracle(int, int)
+  type ix9 = oracle_query(int, int)
 
-  function f1(x : int, y : string) =
-    Chain.event(Event1(x, x+1, y))
+  // Valid payload types
+  type data1 = string
+  type data2 = signature  // bytes(64)
+  type data3 = bytes(65)
 
-  function f2(s : string) =
-    Chain.event(Event2(s, Call.caller))
+  datatype event
+    = Nodata0
+    | Nodata1(ix1)
+    | Nodata2(ix2, ix3)
+    | Nodata3(ix4, ix5, ix6)
+    | Data0(data1)
+    | Data1(data2, ix7)
+    | Data2(ix8, data3, ix9)
+    | Data3(ix1, ix2, ix5, data1)
 
-  function f3(x : int) =
-    Chain.event(Event1(x, x + 2, Int.to_str(x + 7)))
+  entrypoint nodata0()                   = Chain.event(Nodata0)
+  entrypoint nodata1(ix1)                = Chain.event(Nodata1(ix1))
+  entrypoint nodata2(ix2, ix3)           = Chain.event(Nodata2(ix2, ix3))
+  entrypoint nodata3(ix4, ix5, ix6)      = Chain.event(Nodata3(ix4, ix5, ix6))
+  entrypoint data0(data1)                = Chain.event(Data0(data1))
+  entrypoint data1(data2, ix7)           = Chain.event(Data1(data2, ix7))
+  entrypoint data2(ix8, data3, ix9)      = Chain.event(Data2(ix8, data3, ix9))
+  entrypoint data3(ix1, ix2, ix5, data1) = Chain.event(Data3(ix1, ix2, ix5, data1))
 
-  function i2s(i : int) = Int.to_str(i)
-  function a2s(a : address) = Address.to_str(a)

test/contracts/factorial.aes

@@ -1,17 +1,17 @@
 // An implementation of the factorial function where each recursive
 // call is to another contract. Not the cheapest way to compute factorial.
 contract FactorialServer =
-  function fac : (int) => int
+  entrypoint fac : (int) => int
 
 contract Factorial =
 
   record state = {worker : FactorialServer}
 
-  function init(worker) = {worker = worker}
+  entrypoint init(worker) = {worker = worker}
 
-  function set_worker(worker) = put(state{worker = worker})
+  stateful entrypoint set_worker(worker) = put(state{worker = worker})
 
-  function fac(x : int) : int =
+  entrypoint fac(x : int) : int =
     if(x == 0) 1
     else x * state.worker.fac(x - 1)
 

test/contracts/field_parse_error.aes

@@ -0,0 +1,5 @@
+
+contract Fail =
+  record pt = {x : int, y : int}
+  record r  = {p : pt}
+  function fail() = {p.x = 0, p.y = 0}

test/contracts/funargs.aes

@@ -0,0 +1,47 @@
+
+contract FunctionArguments =
+
+  entrypoint sum(n : int, m: int) =
+    n + m
+
+  entrypoint append(xs : list(string)) =
+     switch(xs)
+      []      => ""
+      y :: ys => String.concat(y, append(ys))
+
+  entrypoint menot(b) =
+    !b
+
+  entrypoint bitsum(b : bits) =
+    Bits.sum(b)
+
+  record answer('a) = {label : string, result : 'a}
+
+  entrypoint read(a : answer(int)) =
+     a.result
+
+  entrypoint sjutton(b : bytes(17)) =
+     b
+
+  entrypoint sextiosju(b : bytes(67)) =
+     b
+
+  entrypoint trettiotva(b : bytes(32)) =
+     b
+
+  entrypoint find_oracle(o : oracle(int, bool)) =
+     true
+
+  entrypoint find_query(q : oracle_query(int, bool)) =
+     true
+
+  datatype colour() = Green | Yellow | Red | Pantone(int)
+
+  entrypoint traffic_light(c : colour) =
+     Red
+
+  entrypoint tuples(t : ()) =
+     t
+
+  entrypoint due(t : Chain.ttl) =
+     true

test/contracts/functions.aes

@@ -0,0 +1,15 @@
+contract Functions =
+  function curry(f : ('a, 'b) => 'c) =
+    (x) => (y) => f(x, y)
+  function map(f : 'a => 'b, xs : list('a)) =
+    switch(xs)
+      [] => []
+      x :: xs => f(x) :: map(f, xs)
+  function map'() = map
+  function plus(x, y) = x + y
+  entrypoint test1(xs : list(int)) = map(curry(plus)(5), xs)
+  entrypoint test2(xs : list(int)) = map'()(((x) => (y) => ((x, y) => x + y)(x, y))(100), xs)
+  entrypoint test3(xs : list(int)) =
+    let m(f, xs) = map(f, xs)
+    m((x) => x + 1, xs)
+

test/contracts/fundme.aes

@@ -12,23 +12,20 @@ contract FundMe =
                    deadline      : int,
                    goal          : int }
 
-  private function require(b : bool, err : string) =
-    if(!b) abort(err)
-
-  private function spend(args : spend_args) =
+  stateful function spend(args : spend_args) =
     Chain.spend(args.recipient, args.amount)
 
-  public function init(beneficiary, deadline, goal) : state =
+  entrypoint init(beneficiary, deadline, goal) : state =
     { contributions = {},
       beneficiary   = beneficiary,
       deadline      = deadline,
       total         = 0,
       goal          = goal }
 
-  private function is_contributor(addr) =
+  function is_contributor(addr) =
     Map.member(addr, state.contributions)
 
-  public stateful function contribute() =
+  stateful entrypoint contribute() =
     if(Chain.block_height >= state.deadline)
       spend({ recipient = Call.caller, amount = Call.value }) // Refund money
       false
@@ -39,7 +36,7 @@ contract FundMe =
                  total @ tot = tot + Call.value })
       true
 
-  public stateful function withdraw() =
+  stateful entrypoint withdraw() =
     if(Chain.block_height < state.deadline)
       abort("Cannot withdraw before deadline")
     if(Call.caller == state.beneficiary)
@@ -49,13 +46,13 @@ contract FundMe =
     else
       abort("Not a contributor or beneficiary")
 
-  private stateful function withdraw_beneficiary() =
+  stateful function withdraw_beneficiary() =
     require(state.total >= state.goal, "Project was not funded")
     spend({recipient = state.beneficiary,
            amount    = Contract.balance })
-    put(state{ beneficiary = #0 })
+    put(state{ beneficiary = ak_11111111111111111111111111111111273Yts })
 
-  private stateful function withdraw_contributor() =
+  stateful function withdraw_contributor() =
     if(state.total >= state.goal)
       abort("Project was funded")
     let to = Call.caller

test/contracts/identity.aes

@@ -1,3 +1,3 @@
 
 contract Identity =
-  function main (x:int) = x
+  entrypoint main (x:int) = x

test/contracts/include.aes

@@ -0,0 +1,9 @@
+include "included.aes"
+include "../contracts/included2.aes"
+
+contract Include =
+  entrypoint foo() =
+    Included.foo() < Included2a.bar()
+
+  entrypoint bar() =
+    Included2b.foo() > Included.foo()

test/contracts/included.aes

@@ -0,0 +1,2 @@
+namespace Included =
+  function foo() = 42

test/contracts/included2.aes

@@ -0,0 +1,5 @@
+namespace Included2a =
+  function bar() = 43
+
+namespace Included2b =
+  function foo() = 44

test/contracts/init_type_error.aes

@@ -3,6 +3,6 @@ contract InitTypeError =
 
   type state = map(int, int)
 
-  // Check that the compiler catches ill-typed init function
-  function init() = "not the right type!"
+  // Check that the compiler catches ill-typed init entrypoint
+  entrypoint init() = "not the right type!"
 

test/contracts/maps.aes

@@ -4,97 +4,97 @@ contract Maps =
   record state = { map_i : map(int, pt),
                    map_s : map(string, pt) }
 
-  function init() = { map_i = {}, map_s = {} }
+  entrypoint init() = { map_i = {}, map_s = {} }
 
-  function get_state() = state
+  entrypoint get_state() = state
 
   // {[k] = v}
-  function map_i() =
+  entrypoint map_i() =
     { [1] = {x = 1, y = 2},
       [2] = {x = 3, y = 4},
       [3] = {x = 5, y = 6} }
-  function map_s() =
+  entrypoint map_s() =
     { ["one"]   = {x = 1, y = 2},
       ["two"]   = {x = 3, y = 4},
       ["three"] = {x = 5, y = 6} }
-  function map_state_i() = put(state{ map_i = map_i() })
-  function map_state_s() = put(state{ map_s = map_s() })
+  stateful entrypoint map_state_i() = put(state{ map_i = map_i() })
+  stateful entrypoint map_state_s() = put(state{ map_s = map_s() })
 
   // m[k]
-  function get_i(k, m : map(int,    pt)) = m[k]
-  function get_s(k, m : map(string, pt)) = m[k]
-  function get_state_i(k) = get_i(k, state.map_i)
-  function get_state_s(k) = get_s(k, state.map_s)
+  entrypoint get_i(k, m : map(int,    pt)) = m[k]
+  entrypoint get_s(k, m : map(string, pt)) = m[k]
+  entrypoint get_state_i(k) = get_i(k, state.map_i)
+  entrypoint get_state_s(k) = get_s(k, state.map_s)
 
   // m[k = v]
-  function get_def_i(k, v, m : map(int,    pt)) = m[k = v]
-  function get_def_s(k, v, m : map(string, pt)) = m[k = v]
-  function get_def_state_i(k, v) = get_def_i(k, v, state.map_i)
-  function get_def_state_s(k, v) = get_def_s(k, v, state.map_s)
+  entrypoint get_def_i(k, v, m : map(int,    pt)) = m[k = v]
+  entrypoint get_def_s(k, v, m : map(string, pt)) = m[k = v]
+  entrypoint get_def_state_i(k, v) = get_def_i(k, v, state.map_i)
+  entrypoint get_def_state_s(k, v) = get_def_s(k, v, state.map_s)
 
   // m{[k] = v}
-  function set_i(k, p, m : map(int,    pt)) = m{ [k] = p }
-  function set_s(k, p, m : map(string, pt)) = m{ [k] = p }
-  function set_state_i(k, p) = put(state{ map_i = set_i(k, p, state.map_i) })
-  function set_state_s(k, p) = put(state{ map_s = set_s(k, p, state.map_s) })
+  entrypoint set_i(k, p, m : map(int,    pt)) = m{ [k] = p }
+  entrypoint set_s(k, p, m : map(string, pt)) = m{ [k] = p }
+  stateful entrypoint set_state_i(k, p) = put(state{ map_i = set_i(k, p, state.map_i) })
+  stateful entrypoint set_state_s(k, p) = put(state{ map_s = set_s(k, p, state.map_s) })
 
   // m{f[k].x = v}
-  function setx_i(k, x, m : map(int,    pt)) = m{ [k].x = x }
-  function setx_s(k, x, m : map(string, pt)) = m{ [k].x = x }
-  function setx_state_i(k, x) = put(state{ map_i[k].x = x })
-  function setx_state_s(k, x) = put(state{ map_s[k].x = x })
+  entrypoint setx_i(k, x, m : map(int,    pt)) = m{ [k].x = x }
+  entrypoint setx_s(k, x, m : map(string, pt)) = m{ [k].x = x }
+  stateful entrypoint setx_state_i(k, x) = put(state{ map_i[k].x = x })
+  stateful entrypoint setx_state_s(k, x) = put(state{ map_s[k].x = x })
 
   // m{[k] @ x = v }
-  function addx_i(k, d, m : map(int,    pt)) = m{ [k].x @ x = x + d }
-  function addx_s(k, d, m : map(string, pt)) = m{ [k].x @ x = x + d }
-  function addx_state_i(k, d) = put(state{ map_i[k].x @ x = x + d })
-  function addx_state_s(k, d) = put(state{ map_s[k].x @ x = x + d })
+  entrypoint addx_i(k, d, m : map(int,    pt)) = m{ [k].x @ x = x + d }
+  entrypoint addx_s(k, d, m : map(string, pt)) = m{ [k].x @ x = x + d }
+  stateful entrypoint addx_state_i(k, d) = put(state{ map_i[k].x @ x = x + d })
+  stateful entrypoint addx_state_s(k, d) = put(state{ map_s[k].x @ x = x + d })
 
   // m{[k = def] @ x = v }
-  function addx_def_i(k, v, d, m : map(int,    pt)) = m{ [k = v].x @ x = x + d }
-  function addx_def_s(k, v, d, m : map(string, pt)) = m{ [k = v].x @ x = x + d }
+  entrypoint addx_def_i(k, v, d, m : map(int,    pt)) = m{ [k = v].x @ x = x + d }
+  entrypoint addx_def_s(k, v, d, m : map(string, pt)) = m{ [k = v].x @ x = x + d }
 
   // Map.member
-  function member_i(k, m : map(int,    pt)) = Map.member(k, m)
-  function member_s(k, m : map(string, pt)) = Map.member(k, m)
-  function member_state_i(k) = member_i(k, state.map_i)
-  function member_state_s(k) = member_s(k, state.map_s)
+  entrypoint member_i(k, m : map(int,    pt)) = Map.member(k, m)
+  entrypoint member_s(k, m : map(string, pt)) = Map.member(k, m)
+  entrypoint member_state_i(k) = member_i(k, state.map_i)
+  entrypoint member_state_s(k) = member_s(k, state.map_s)
 
   // Map.lookup
-  function lookup_i(k, m : map(int,    pt)) = Map.lookup(k, m)
-  function lookup_s(k, m : map(string, pt)) = Map.lookup(k, m)
-  function lookup_state_i(k) = lookup_i(k, state.map_i)
-  function lookup_state_s(k) = lookup_s(k, state.map_s)
+  entrypoint lookup_i(k, m : map(int,    pt)) = Map.lookup(k, m)
+  entrypoint lookup_s(k, m : map(string, pt)) = Map.lookup(k, m)
+  entrypoint lookup_state_i(k) = lookup_i(k, state.map_i)
+  entrypoint lookup_state_s(k) = lookup_s(k, state.map_s)
 
   // Map.lookup_default
-  function lookup_def_i(k, m : map(int,    pt), def : pt) =
+  entrypoint lookup_def_i(k, m : map(int,    pt), def : pt) =
     Map.lookup_default(k, m, def)
-  function lookup_def_s(k, m : map(string, pt), def : pt) =
+  entrypoint lookup_def_s(k, m : map(string, pt), def : pt) =
     Map.lookup_default(k, m, def)
-  function lookup_def_state_i(k, def) = lookup_def_i(k, state.map_i, def)
-  function lookup_def_state_s(k, def) = lookup_def_s(k, state.map_s, def)
+  entrypoint lookup_def_state_i(k, def) = lookup_def_i(k, state.map_i, def)
+  entrypoint lookup_def_state_s(k, def) = lookup_def_s(k, state.map_s, def)
 
   // Map.delete
-  function delete_i(k, m : map(int,    pt)) = Map.delete(k, m)
-  function delete_s(k, m : map(string, pt)) = Map.delete(k, m)
-  function delete_state_i(k) = put(state{ map_i = delete_i(k, state.map_i) })
-  function delete_state_s(k) = put(state{ map_s = delete_s(k, state.map_s) })
+  entrypoint delete_i(k, m : map(int,    pt)) = Map.delete(k, m)
+  entrypoint delete_s(k, m : map(string, pt)) = Map.delete(k, m)
+  stateful entrypoint delete_state_i(k) = put(state{ map_i = delete_i(k, state.map_i) })
+  stateful entrypoint delete_state_s(k) = put(state{ map_s = delete_s(k, state.map_s) })
 
   // Map.size
-  function size_i(m : map(int,    pt)) = Map.size(m)
-  function size_s(m : map(string, pt)) = Map.size(m)
-  function size_state_i() = size_i(state.map_i)
-  function size_state_s() = size_s(state.map_s)
+  entrypoint size_i(m : map(int,    pt)) = Map.size(m)
+  entrypoint size_s(m : map(string, pt)) = Map.size(m)
+  entrypoint size_state_i() = size_i(state.map_i)
+  entrypoint size_state_s() = size_s(state.map_s)
 
   // Map.to_list
-  function tolist_i(m : map(int,    pt)) = Map.to_list(m)
-  function tolist_s(m : map(string, pt)) = Map.to_list(m)
-  function tolist_state_i() = tolist_i(state.map_i)
-  function tolist_state_s() = tolist_s(state.map_s)
+  entrypoint tolist_i(m : map(int,    pt)) = Map.to_list(m)
+  entrypoint tolist_s(m : map(string, pt)) = Map.to_list(m)
+  entrypoint tolist_state_i() = tolist_i(state.map_i)
+  entrypoint tolist_state_s() = tolist_s(state.map_s)
 
   // Map.from_list
-  function fromlist_i(xs : list((int,    pt))) = Map.from_list(xs)
-  function fromlist_s(xs : list((string, pt))) = Map.from_list(xs)
-  function fromlist_state_i(xs) = put(state{ map_i = fromlist_i(xs) })
-  function fromlist_state_s(xs) = put(state{ map_s = fromlist_s(xs) })
+  entrypoint fromlist_i(xs : list((int,    pt))) = Map.from_list(xs)
+  entrypoint fromlist_s(xs : list((string, pt))) = Map.from_list(xs)
+  stateful entrypoint fromlist_state_i(xs) = put(state{ map_i = fromlist_i(xs) })
+  stateful entrypoint fromlist_state_s(xs) = put(state{ map_s = fromlist_s(xs) })
 

test/contracts/missing_fields_in_record_expression.aes

@@ -3,6 +3,6 @@ contract MissingFieldsInRecordExpr =
   record r('a) = {x : int, y : string, z : 'a}
   type alias('a) = r('a)
 
-  function fail1()               = { x = 0 }
-  function fail2(z : 'a) : r('a) = { y = "string", z = z }
-  function fail3() : alias(int)  = { x = 0, z = 1 }
+  entrypoint fail1()               = { x = 0 }
+  entrypoint fail2(z : 'a) : r('a) = { y = "string", z = z }
+  entrypoint fail3() : alias(int)  = { x = 0, z = 1 }

test/contracts/missing_state_type.aes

@@ -2,5 +2,5 @@
 contract MissingStateType =
 
   // Check that we get a type error also for implicit state
-  function init() = "should be ()"
+  entrypoint init() = "should be ()"
 

test/contracts/modifier_checks.aes

@@ -0,0 +1,12 @@
+
+namespace Lib =
+  entrypoint foo() = ()
+
+contract Remote =
+  public function foo : () => ()
+  function bla() = ()
+
+contract Contract =
+  public function foo() = ()
+  public private stateful function all_the_things() = ()
+  private entrypoint wha() = ()

test/contracts/multi_sig.aes

@@ -5,7 +5,7 @@
 
 contract MultiSig =
 
-    record pending_state = { yetNeeded : uint, ownersDone : uint, index : uint }
+    record pending_state = { yetNeeded : int, ownersDone : bits, index : int }
 
     datatype event =
         Confirmation (address, hash)    // of { .owner : Address, .operation : Hash }
@@ -13,18 +13,18 @@ contract MultiSig =
       | OwnerChanged (address, address) // of { .oldOwner : Address, .newOwner : Address }
       | OwnerAdded   (address)          // of { .newOwner : Address }
       | OwnerRemoved (address)          // of { .removedOwner : Address }
-      | ReqChanged   (uint)             // of { .newReq : uint }
+      | ReqChanged   (int)             // of { .newReq : int }
 
-    let maxOwners : uint = 250
+    let maxOwners : int = 250
 
-    record state = { nRequired    : uint
-                 , nOwners      : uint
-                 , owners       : map(uint, address)
-                 , ownerIndex   : map(address, uint)
+    record state = { nRequired    : int
+                 , nOwners      : int
+                 , owners       : map(int, address)
+                 , ownerIndex   : map(address, int)
                  , pending      : map(hash, pending_state)
                  , pendingIndex : list(address) }
 
-    function init (owners : list(address), nRequired : uint) : state =
+    function init (owners : list(address), nRequired : int) : state =
       let n = length(owners) + 1
       { nRequired  = nRequired,
         nOwners    = n,
@@ -39,10 +39,9 @@ contract MultiSig =
     function revoke(operation : hash) =
       let ownerIx = lookup(state.ownerIndex, caller())
       let pending = lookup(state.pendingIndex, operation)
-      let ownerIxBit = 1 bsl (ownerIx - 1)
-      let _ = require(pending.ownersDone band ownerIxBit > 0)
+      let _ = require(Bits.test(pending.ownersDone, ownerIx))
       let pending' = pending { yetNeeded  = pending.yetNeeded + 1
-                             , ownersDone = pending.ownersDone - ownerIxBit }
+                             , ownersDone = Bits.clear(pending.ownersDone, ownerIx - 1) }
       put(state{ pendingIndex.operator = pending' })
       event(Revoke(caller, operation))
 
@@ -91,7 +90,7 @@ contract MultiSig =
                              , pendingIx = [] },
               event = [OwnerRemoved(oldOwner)] }
 
-    function changeRequirement(newReq : uint) =
+    function changeRequirement(newReq : int) =
       let _ = require(newReq =< state.nOwners)
       switch(check_pending(callhash()))
         CheckFail(state') => { state = state' }
@@ -102,7 +101,7 @@ contract MultiSig =
             event = [ReqChanged(newReq)] }
 
 
-    function getOwner(ownerIx0 : uint) =
+    function getOwner(ownerIx0 : int) =
       lookup(state.owners, ownerIx0 + 1)
 
     function isOwner(owner : address) =
@@ -116,8 +115,7 @@ contract MultiSig =
         Some(pending) =>
           let _ = require(isOwner(owner))
           let ownerIx = lookup(state.ownerIndex, owner)
-          let ownerIxBit = 1 bsl (ownerIx - 1)
-          (pending.ownersDone band ownerIxBit) != 0
+          Bits.test(pending.ownersDone, ownerIx - 1)
 
     /* Leave the rest for now... */
 

test/contracts/name_clash.aes

@@ -1,16 +1,17 @@
 
 contract NameClash =
 
-  function double_proto : () => int
-  function double_proto : () => int
+  entrypoint double_proto : () => int
+  entrypoint double_proto : () => int
 
-  function proto_and_def : int => int
-  function proto_and_def(n) = n + 1
+  entrypoint proto_and_def : int => int
+  entrypoint proto_and_def(n) = n + 1
 
-  function double_def(x) = x
-  function double_def(y) = 0
+  entrypoint double_def(x) = x
+  entrypoint double_def(y) = 0
 
-  // abort, put and state are builtin
-  function abort() : int = 0
-  function put(x) = x
-  function state(x, y) = x + y
+  // abort, require, put and state are builtin
+  entrypoint abort() : int = 0
+  entrypoint require(b, err) = if(b) abort(err)
+  entrypoint put(x) = x
+  entrypoint state(x, y) = x + y

test/contracts/namespace_bug.aes

@@ -0,0 +1,18 @@
+
+namespace Foo =
+
+  record bla = {x : int, y : bool}
+
+  function bar() : Foo.bla = {x = 17, y = true}
+
+contract Bug =
+
+  // Crashed the type checker
+  entrypoint foo() = Foo.bar()
+
+  // Also crashed the type checker
+  type t = Foo.bla
+
+  entrypoint test() =
+    let x : t = Foo.bar()
+    x

test/contracts/namespace_clash.aes

@@ -0,0 +1,5 @@
+
+// You can't shadow existing contracts or namespaces.
+
+contract Call =
+  entrypoint whatever() = ()

test/contracts/namespaces.aes

@@ -0,0 +1,21 @@
+
+namespace Lib =
+
+  private function rev(xs, ys) =
+    switch(xs)
+      []      => ys
+      x :: xs => rev(xs, x :: ys)
+
+  function reverse(xs : list('a)) : list('a) = rev(xs, [])
+
+  function eqlist(xs : list(int), ys : list(int)) =
+    switch((xs, ys))
+      ([], [])           => true
+      (x :: xs, y :: ys) => x == y && eqlist(xs, ys)
+      _                  => false
+
+contract TestNamespaces =
+
+  function palindrome(xs : list(int)) : bool =
+    Lib.eqlist(xs, Lib.reverse(xs))
+

test/contracts/nodeadcode.aes

@@ -0,0 +1,21 @@
+
+namespace List =
+
+  function map1(f : 'a => 'b, xs : list('a)) =
+    switch(xs)
+      [] => []
+      x :: xs => f(x) :: map1(f, xs)
+
+  function map2(f : 'a => 'b, xs : list('a)) =
+    switch(xs)
+      [] => []
+      x :: xs => f(x) :: map2(f, xs)
+
+contract Deadcode =
+
+  entrypoint inc1(xs : list(int)) : list(int) =
+    List.map1((x) => x + 1, xs)
+
+  entrypoint inc2(xs : list(int)) : list(int) =
+    List.map2((x) => x + 1, xs)
+

test/contracts/operators.aes

@@ -1,5 +1,4 @@
 // - + * / mod 	arithmetic operators
-// bnot band bor bxor bsl bsr 	bitwise operators
 // ! && || 	logical operators
 // == != < > =< >= 	comparison operators
 // :: ++ 	list operators
@@ -13,12 +12,6 @@ contract Operators =
       "/"    => a / b
       "mod"  => a mod b
       "^"    => a ^ b
-      "bnot" => bnot a
-      "band" => a band b
-      "bor"  => a bor b
-      "bxor" => a bxor b
-      "bsl"  => a bsl b
-      "bsr"  => a bsr b
 
   function bool_op(a : bool, b : bool, op : string) =
     switch(op)

test/contracts/oracles.aes

@@ -9,31 +9,31 @@ contract Oracles =
   type oracle_id = oracle(query_t, answer_t)
   type query_id  = oracle_query(query_t, answer_t)
 
-  function registerOracle(acct : address,
+  stateful entrypoint registerOracle(acct : address,
                           qfee : fee,
                           ttl  : ttl) : oracle_id =
      Oracle.register(acct, qfee, ttl)
 
-  function registerIntIntOracle(acct : address,
+  stateful entrypoint registerIntIntOracle(acct : address,
                                 qfee : fee,
                                 ttl  : ttl) : oracle(int, int) =
      Oracle.register(acct, qfee, ttl)
 
-  function registerStringStringOracle(acct : address,
+  stateful entrypoint registerStringStringOracle(acct : address,
                                       qfee : fee,
                                       ttl  : ttl) : oracle(string, string) =
      Oracle.register(acct, qfee, ttl)
 
-  function signedRegisterOracle(acct : address,
+  stateful entrypoint signedRegisterOracle(acct : address,
                                 sign : signature,
                                 qfee : fee,
                                 ttl  : ttl) : oracle_id =
      Oracle.register(acct, qfee, ttl, signature = sign)
 
-  function queryFee(o : oracle_id) : fee =
+  entrypoint queryFee(o : oracle_id) : fee =
     Oracle.query_fee(o)
 
-  function createQuery(o    : oracle_id,
+  stateful entrypoint createQuery(o    : oracle_id,
                        q    : query_t,
                        qfee : fee,
                        qttl : ttl,
@@ -42,7 +42,7 @@ contract Oracles =
     Oracle.query(o, q, qfee, qttl, rttl)
 
   // Do not use in production!
-  function unsafeCreateQuery(o    : oracle_id,
+  stateful entrypoint unsafeCreateQuery(o    : oracle_id,
                        q    : query_t,
                        qfee : fee,
                        qttl : ttl,
@@ -50,7 +50,7 @@ contract Oracles =
     Oracle.query(o, q, qfee, qttl, rttl)
 
   // Do not use in production!
-  function unsafeCreateQueryThenErr(o    : oracle_id,
+  stateful entrypoint unsafeCreateQueryThenErr(o    : oracle_id,
                        q    : query_t,
                        qfee : fee,
                        qttl : ttl,
@@ -59,54 +59,52 @@ contract Oracles =
     require(qfee >= 100000000000000000, "causing a late error")
     res
 
-  function extendOracle(o    : oracle_id,
+  stateful entrypoint extendOracle(o    : oracle_id,
                         ttl  : ttl) : () =
     Oracle.extend(o, ttl)
 
-  function signedExtendOracle(o    : oracle_id,
+  stateful entrypoint signedExtendOracle(o    : oracle_id,
                               sign : signature,   // Signed oracle address
                               ttl  : ttl) : () =
     Oracle.extend(o, signature = sign, ttl)
 
-  function respond(o    : oracle_id,
+  stateful entrypoint respond(o    : oracle_id,
                    q    : query_id,
                    r    : answer_t) : () =
     Oracle.respond(o, q, r)
 
-  function signedRespond(o    : oracle_id,
+  stateful entrypoint signedRespond(o    : oracle_id,
                          q    : query_id,
                          sign : signature,
                          r    : answer_t) : () =
     Oracle.respond(o, q, signature = sign, r)
 
-  function getQuestion(o : oracle_id,
+  entrypoint getQuestion(o : oracle_id,
                        q : query_id) : query_t =
     Oracle.get_question(o, q)
 
-  function hasAnswer(o : oracle_id,
+  entrypoint hasAnswer(o : oracle_id,
                      q : query_id) =
     switch(Oracle.get_answer(o, q))
       None    => false
       Some(_) => true
 
-  function getAnswer(o : oracle_id,
+  entrypoint getAnswer(o : oracle_id,
                      q : query_id) : option(answer_t) =
     Oracle.get_answer(o, q)
 
   datatype complexQuestion = Why(int) | How(string)
   datatype complexAnswer   = NoAnswer | Answer(complexQuestion, string, int)
 
-  function complexOracle(question) =
+  stateful entrypoint complexOracle(question) =
     let o = Oracle.register(Contract.address, 0, FixedTTL(1000)) : oracle(complexQuestion, complexAnswer)
     let q = Oracle.query(o, question, 0, RelativeTTL(100), RelativeTTL(100))
     Oracle.respond(o, q, Answer(question, "magic", 1337))
     Oracle.get_answer(o, q)
 
-  function signedComplexOracle(question, sig) =
+  stateful entrypoint signedComplexOracle(question, sig) =
     let o = Oracle.register(signature = sig, Contract.address, 0, FixedTTL(1000)) : oracle(complexQuestion, complexAnswer)
     let q = Oracle.query(o, question, 0, RelativeTTL(100), RelativeTTL(100))
     Oracle.respond(o, q, Answer(question, "magic", 1337), signature = sig)
     Oracle.get_answer(o, q)
 
-  private function require(b : bool, err : string) =
-    if(!b) abort(err)

test/contracts/oracles_gas.aes

@@ -20,5 +20,3 @@ contract OraclesGas =
     Oracle.respond(o, q, answer)
     ()
 
-  private function require(b : bool, err : string) =
-    if(!b) abort(err)

test/contracts/oracles_no_vm.aes

@@ -33,5 +33,3 @@ contract Oracles =
                      q : query_id) : option(answer_t) =
     Oracle.get_answer(o, q)
 
-  private function require(b : bool, err : string) =
-    if(!b) abort(err)

test/contracts/remote_call.aes

@@ -1,27 +1,27 @@
 
 contract Remote1 =
-  function main : (int) => int
+  entrypoint main : (int) => int
 
 contract Remote2 =
-  function call : (Remote1, int) => int
+  entrypoint call : (Remote1, int) => int
 
 contract Remote3 =
-  function get : () => int
-  function tick : () => ()
+  entrypoint get : () => int
+  entrypoint tick : () => ()
 
 contract RemoteCall =
 
-    function call(r : Remote1, x : int) : int =
+    stateful entrypoint call(r : Remote1, x : int) : int =
         r.main(gas = 10000, value = 10, x)
 
-    function staged_call(r1 : Remote1, r2 : Remote2, x : int) =
+    entrypoint staged_call(r1 : Remote1, r2 : Remote2, x : int) =
         r2.call(r1, x)
 
-    function increment(r3 : Remote3) =
+    entrypoint increment(r3 : Remote3) =
         r3.tick()
 
-    function get(r3 : Remote3) =
+    entrypoint get(r3 : Remote3) =
         r3.get()
 
-    function plus(x, y) = x + y
+    entrypoint plus(x, y) = x + y
 

test/contracts/remote_oracles.aes

@@ -1,99 +0,0 @@
-contract Oracles =
-
-  function registerOracle :
-    (address,
-     int,
-     Chain.ttl) => oracle(string, int)
-
-  function createQuery :
-    (oracle(string, int),
-     string,
-     int,
-     Chain.ttl,
-     Chain.ttl) => oracle_query(string, int)
-
-  function unsafeCreateQuery :
-    (oracle(string, int),
-     string,
-     int,
-     Chain.ttl,
-     Chain.ttl) => oracle_query(string, int)
-
-  function respond :
-    (oracle(string, int),
-     oracle_query(string, int),
-     int) => ()
-
-contract OraclesErr =
-
-  function unsafeCreateQueryThenErr :
-    (oracle(string, int),
-     string,
-     int,
-     Chain.ttl,
-     Chain.ttl) => oracle_query(string, int)
-
-contract RemoteOracles =
-
-  public function callRegisterOracle(
-      r    : Oracles,
-      acct : address,
-      qfee : int,
-      ttl  : Chain.ttl) : oracle(string, int) =
-    r.registerOracle(acct, qfee, ttl)
-
-  public function callCreateQuery(
-    r     : Oracles,
-    value : int,
-    o     : oracle(string, int),
-    q     : string,
-    qfee  : int,
-    qttl  : Chain.ttl,
-    rttl  : Chain.ttl) : oracle_query(string, int) =
-    require(value =< Call.value, "insufficient value")
-    r.createQuery(value = value, o, q, qfee, qttl, rttl)
-
-  // Do not use in production!
-  public function callUnsafeCreateQuery(
-    r     : Oracles,
-    value : int,
-    o     : oracle(string, int),
-    q     : string,
-    qfee  : int,
-    qttl  : Chain.ttl,
-    rttl  : Chain.ttl) : oracle_query(string, int) =
-    r.unsafeCreateQuery(value = value, o, q, qfee, qttl, rttl)
-
-  // Do not use in production!
-  public function callUnsafeCreateQueryThenErr(
-    r     : OraclesErr,
-    value : int,
-    o     : oracle(string, int),
-    q     : string,
-    qfee  : int,
-    qttl  : Chain.ttl,
-    rttl  : Chain.ttl) : oracle_query(string, int) =
-    r.unsafeCreateQueryThenErr(value = value, o, q, qfee, qttl, rttl)
-
-  // Do not use in production!
-  public function callUnsafeCreateQueryAndThenErr(
-    r     : Oracles,
-    value : int,
-    o     : oracle(string, int),
-    q     : string,
-    qfee  : int,
-    qttl  : Chain.ttl,
-    rttl  : Chain.ttl) : oracle_query(string, int) =
-    let x = r.unsafeCreateQuery(value = value, o, q, qfee, qttl, rttl)
-    switch(0) 1 => ()
-    x // Never reached.
-
-  public function callRespond(
-    r    : Oracles,
-    o    : oracle(string, int),
-    q    : oracle_query(string, int),
-    qr   : int) =
-    r.respond(o, q, qr)
-
-  private function require(b : bool, err : string) =
-    if(!b) abort(err)

test/contracts/simple.aes

@@ -1,3 +1,4 @@
 
 contract Simple =
   type t = int => int
+  entrypoint dummy() = ()

test/contracts/simple_storage.aes

@@ -6,11 +6,11 @@
    contract SimpleStorage {
        uint storedData
 
-       function set(uint x) {
+       entrypoint set(uint x) {
            storedData = x
        }
 
-       function get() constant returns (uint) {
+       entrypoint get() constant returns (uint) {
            return storedData
        }
    }
@@ -18,12 +18,11 @@
 
 contract SimpleStorage =
 
-  type event = int
   record state = { data : int }
 
-  function init(value : int) : state = { data = value }
+  entrypoint init(value : int) : state = { data = value }
 
-  function get() : int = state.data
+  entrypoint get() : int = state.data
 
-  function set(value : int) =
+  stateful entrypoint set(value : int) =
       put(state{data = value})

test/contracts/spend_test.aes

@@ -1,26 +1,26 @@
 
 contract SpendContract =
-  function withdraw : (int) => int
+  entrypoint withdraw : (int) => int
 
 contract SpendTest =
 
-  function spend(to, amount) =
+  stateful entrypoint spend(to, amount) =
     let total = Contract.balance
     Chain.spend(to, amount)
     total - amount
 
-  function withdraw(amount) : int =
+  stateful entrypoint withdraw(amount) : int =
     spend(Call.caller, amount)
 
-  function withdraw_from(account, amount) =
+  stateful entrypoint withdraw_from(account, amount) =
     account.withdraw(amount)
     withdraw(amount)
 
-  function spend_from(from, to, amount) =
+  stateful entrypoint spend_from(from, to, amount) =
     from.withdraw(amount)
     Chain.spend(to, amount)
     Chain.balance(to)
 
-  function get_balance() = Contract.balance
-  function get_balance_of(a) = Chain.balance(a)
+  entrypoint get_balance() = Contract.balance
+  entrypoint get_balance_of(a) = Chain.balance(a)
 

test/contracts/stack.aes

@@ -6,24 +6,24 @@ contract Stack =
   record state = { stack : stack(string),
                    size  : int }
 
-  function init(ss : list(string)) = { stack = ss, size = length(ss) }
+  entrypoint init(ss : list(string)) = { stack = ss, size = length(ss) }
 
-  private function length(xs) =
+  function length(xs) =
     switch(xs)
       [] => 0
       _ :: xs => length(xs) + 1
 
-  stateful function pop() : string =
+  stateful entrypoint pop() : string =
     switch(state.stack)
       s :: ss =>
         put(state{ stack = ss, size = state.size - 1 })
         s
 
-  stateful function push(s) =
+  stateful entrypoint push(s) =
     put(state{ stack = s :: state.stack, size = state.size + 1 })
     state.size
 
-  function all() = state.stack
+  entrypoint all() = state.stack
 
-  function size() = state.size
+  entrypoint size() = state.size
 

test/contracts/state_handling.aes

@@ -1,67 +1,70 @@
 contract Remote =
-  function look_at : (state) => ()
-  function return_s : (bool) => string
-  function return_m : (bool) => map(int, int)
-  function get : (state) => state
-  function get_i : (state) => int
-  function get_s : (state) => string
-  function get_m : (state) => map(int, int)
+  record rstate = { i : int, s : string, m : map(int, int) }
 
-  function fun_update_i  : (state, int)           => state
-  function fun_update_s  : (state, string)        => state
-  function fun_update_m  : (state, map(int, int)) => state
-  function fun_update_mk : (state, int, int)      => state
+  entrypoint look_at : (rstate) => ()
+  entrypoint return_s : (bool) => string
+  entrypoint return_m : (bool) => map(int, int)
+  entrypoint get : (rstate) => rstate
+  entrypoint get_i : (rstate) => int
+  entrypoint get_s : (rstate) => string
+  entrypoint get_m : (rstate) => map(int, int)
+
+  entrypoint fun_update_i  : (rstate, int)           => rstate
+  entrypoint fun_update_s  : (rstate, string)        => rstate
+  entrypoint fun_update_m  : (rstate, map(int, int)) => rstate
+  entrypoint fun_update_mk : (rstate, int, int)      => rstate
 
 contract StateHandling =
-  record state = { i : int, s : string, m : map(int, int) }
 
-  function init(r : Remote, i : int) =
+  type state = Remote.rstate
+
+  entrypoint init(r : Remote, i : int) =
     let state0 = { i = 0, s = "undefined", m = {} }
     r.fun_update_i(state0, i)
 
-  function read() = state
-  function read_i() = state.i
-  function read_s() = state.s
-  function read_m() = state.m
+  entrypoint read() = state
+  entrypoint read_i() = state.i
+  entrypoint read_s() = state.s
+  entrypoint read_m() = state.m
 
-  function update(new_state : state) = put(new_state)
-  function update_i(new_i) = put(state{ i = new_i })
-  function update_s(new_s) = put(state{ s = new_s })
-  function update_m(new_m) = put(state{ m = new_m })
+  stateful entrypoint update(new_state : state) = put(new_state)
+  stateful entrypoint update_i(new_i) = put(state{ i = new_i })
+  stateful entrypoint update_s(new_s) = put(state{ s = new_s })
+  stateful entrypoint update_m(new_m) = put(state{ m = new_m })
 
-  function pass_it(r : Remote) = r.look_at(state)
-  function nop(r : Remote) = put(state{ i = state.i })
-  function return_it_s(r : Remote, big : bool) =
+  entrypoint pass_it(r : Remote) = r.look_at(state)
+  stateful entrypoint nop(r : Remote) = put(state{ i = state.i })
+  entrypoint return_it_s(r : Remote, big : bool) =
     let x = r.return_s(big)
     String.length(x)
-  function return_it_m(r : Remote, big : bool) =
+  entrypoint return_it_m(r : Remote, big : bool) =
     let x = r.return_m(big)
     Map.size(x)
 
-  function pass(r : Remote) = r.get(state)
-  function pass_i(r : Remote) = r.get_i(state)
-  function pass_s(r : Remote) = r.get_s(state)
-  function pass_m(r : Remote) = r.get_m(state)
+  entrypoint pass(r : Remote) = r.get(state)
+  entrypoint pass_i(r : Remote) = r.get_i(state)
+  entrypoint pass_s(r : Remote) = r.get_s(state)
+  entrypoint pass_m(r : Remote) = r.get_m(state)
 
-  function pass_update_i(r : Remote, i) = r.fun_update_i(state, i)
-  function pass_update_s(r : Remote, s) = r.fun_update_s(state, s)
-  function pass_update_m(r : Remote, m) = r.fun_update_m(state, m)
+  entrypoint pass_update_i(r : Remote, i) = r.fun_update_i(state, i)
+  entrypoint pass_update_s(r : Remote, s) = r.fun_update_s(state, s)
+  entrypoint pass_update_m(r : Remote, m) = r.fun_update_m(state, m)
 
-  function remote_update_i (r : Remote, i)    = put(r.fun_update_i(state, i))
-  function remote_update_s (r : Remote, s)    = put(r.fun_update_s(state, s))
-  function remote_update_m (r : Remote, m)    = put(r.fun_update_m(state, m))
-  function remote_update_mk(r : Remote, k, v) = put(r.fun_update_mk(state, k, v))
+  stateful entrypoint remote_update_i (r : Remote, i)    = put(r.fun_update_i(state, i))
+  stateful entrypoint remote_update_s (r : Remote, s)    = put(r.fun_update_s(state, s))
+  stateful entrypoint remote_update_m (r : Remote, m)    = put(r.fun_update_m(state, m))
+  stateful entrypoint remote_update_mk(r : Remote, k, v) = put(r.fun_update_mk(state, k, v))
 
   // remote called
-  function look_at(s : state) = ()
+  entrypoint look_at(s : state) = ()
 
-  function get(s : state) = s
-  function get_i(s : state) = s.i
-  function get_s(s : state) = s.s
-  function get_m(s : state) = s.m
+  entrypoint get(s : state) = s
+  entrypoint get_i(s : state) = s.i
+  entrypoint get_s(s : state) = s.s
+  entrypoint get_m(s : state) = s.m
 
-  function fun_update_i(st, ni) = st{ i = ni }
-  function fun_update_s(st, ns) = st{ s = ns }
-  function fun_update_m(st, nm) = st{ m = nm }
-  function fun_update_mk(st, k, v) = st{ m = st.m{[k] = v} }
+  entrypoint fun_update_i(st, ni) = st{ i = ni }
+  entrypoint fun_update_s(st, ns) = st{ s = ns }
+  entrypoint fun_update_m(st, nm) = st{ m = nm }
+  entrypoint fun_update_mk(st, k, v) = st{ m = st.m{[k] = v} }