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merge into: QPQ-AG/sophia:aens-at-full-node-ver
Branches Tags
QPQ-AG/sophia:master QPQ-AG/sophia:prh-docs-fix QPQ-AG/sophia:uw-mldsa-crypto QPQ-AG/sophia:uw-rename-fix-deps QPQ-AG/sophia:bump_gmserialization QPQ-AG/sophia:zomp QPQ-AG/sophia:ceres QPQ-AG/sophia:gh-pages QPQ-AG/sophia:gh-485 QPQ-AG/sophia:dependabot/pip/dot-github/workflows/pygments-2.15.0 QPQ-AG/sophia:old_ceres QPQ-AG/sophia:ghallak/split-typechecker QPQ-AG/sophia:gh-400 QPQ-AG/sophia:new_ceres QPQ-AG/sophia:loop-op QPQ-AG/sophia:type-env QPQ-AG/sophia:ghallak/229 QPQ-AG/sophia:option-force-msg QPQ-AG/sophia:6.0.2 QPQ-AG/sophia:lima QPQ-AG/sophia:call-fee QPQ-AG/sophia:fix-ets QPQ-AG/sophia:mergesort QPQ-AG/sophia:lima-master-merge QPQ-AG/sophia:optionally_generate_aci QPQ-AG/sophia:changelog-update QPQ-AG/sophia:make-return-reserved-word QPQ-AG/sophia:radrow-patch-2 QPQ-AG/sophia:aens-subdomains QPQ-AG/sophia:aens-at-full-node-ver QPQ-AG/sophia:pt-166866806-claim-with-name-fee QPQ-AG/sophia:extend-aci-interface QPQ-AG/sophia:generalized_accounts_no_abi_move QPQ-AG/sophia:roma QPQ-AG/sophia:quickcheck-ci
QPQ-AG/sophia:v7.5.0 QPQ-AG/sophia:v7.4.0 QPQ-AG/sophia:v7.3.0 QPQ-AG/sophia:v7.2.1 QPQ-AG/sophia:v7.2.0 QPQ-AG/sophia:v7.1.0 QPQ-AG/sophia:v7.0.1 QPQ-AG/sophia:v7.0.0 QPQ-AG/sophia:v6.1.0 QPQ-AG/sophia:v6.0.2 QPQ-AG/sophia:v6.0.1 QPQ-AG/sophia:v6.0.0 QPQ-AG/sophia:v5.0.0 QPQ-AG/sophia:v4.3.0 QPQ-AG/sophia:v4.2.0 QPQ-AG/sophia:v4.1.0 QPQ-AG/sophia:v4.1.0-rc1 QPQ-AG/sophia:v4.0.0 QPQ-AG/sophia:v4.0.0-rc5 QPQ-AG/sophia:v4.0.0-rc4 QPQ-AG/sophia:v4.0.0-rc3 QPQ-AG/sophia:v4.0.0-rc1 QPQ-AG/sophia:v3.2.0 QPQ-AG/sophia:v3.1.0 QPQ-AG/sophia:v3.0.0 QPQ-AG/sophia:v2.1.0 QPQ-AG/sophia:v2.0.0 QPQ-AG/sophia:roma-v1 QPQ-AG/sophia:v2
..
pull from: QPQ-AG/sophia:extend-aci-interface
Branches Tags
QPQ-AG/sophia:prh-docs-fix QPQ-AG/sophia:uw-mldsa-crypto QPQ-AG/sophia:master QPQ-AG/sophia:uw-rename-fix-deps QPQ-AG/sophia:bump_gmserialization QPQ-AG/sophia:zomp QPQ-AG/sophia:ceres QPQ-AG/sophia:gh-pages QPQ-AG/sophia:gh-485 QPQ-AG/sophia:dependabot/pip/dot-github/workflows/pygments-2.15.0 QPQ-AG/sophia:old_ceres QPQ-AG/sophia:ghallak/split-typechecker QPQ-AG/sophia:gh-400 QPQ-AG/sophia:new_ceres QPQ-AG/sophia:loop-op QPQ-AG/sophia:type-env QPQ-AG/sophia:ghallak/229 QPQ-AG/sophia:option-force-msg QPQ-AG/sophia:6.0.2 QPQ-AG/sophia:lima QPQ-AG/sophia:call-fee QPQ-AG/sophia:fix-ets QPQ-AG/sophia:mergesort QPQ-AG/sophia:lima-master-merge QPQ-AG/sophia:optionally_generate_aci QPQ-AG/sophia:changelog-update QPQ-AG/sophia:make-return-reserved-word QPQ-AG/sophia:radrow-patch-2 QPQ-AG/sophia:aens-subdomains QPQ-AG/sophia:aens-at-full-node-ver QPQ-AG/sophia:pt-166866806-claim-with-name-fee QPQ-AG/sophia:extend-aci-interface QPQ-AG/sophia:generalized_accounts_no_abi_move QPQ-AG/sophia:roma QPQ-AG/sophia:quickcheck-ci
QPQ-AG/sophia:v7.5.0 QPQ-AG/sophia:v7.4.0 QPQ-AG/sophia:v7.3.0 QPQ-AG/sophia:v7.2.1 QPQ-AG/sophia:v7.2.0 QPQ-AG/sophia:v7.1.0 QPQ-AG/sophia:v7.0.1 QPQ-AG/sophia:v7.0.0 QPQ-AG/sophia:v6.1.0 QPQ-AG/sophia:v6.0.2 QPQ-AG/sophia:v6.0.1 QPQ-AG/sophia:v6.0.0 QPQ-AG/sophia:v5.0.0 QPQ-AG/sophia:v4.3.0 QPQ-AG/sophia:v4.2.0 QPQ-AG/sophia:v4.1.0 QPQ-AG/sophia:v4.1.0-rc1 QPQ-AG/sophia:v4.0.0 QPQ-AG/sophia:v4.0.0-rc5 QPQ-AG/sophia:v4.0.0-rc4 QPQ-AG/sophia:v4.0.0-rc3 QPQ-AG/sophia:v4.0.0-rc1 QPQ-AG/sophia:v3.2.0 QPQ-AG/sophia:v3.1.0 QPQ-AG/sophia:v3.0.0 QPQ-AG/sophia:v2.1.0 QPQ-AG/sophia:v2.0.0 QPQ-AG/sophia:roma-v1 QPQ-AG/sophia:v2

9 Commits
aens-at-full-node-ver .. extend-aci-interface

Author SHA1 Message Date
Robert Virding d16fb82e25 Break out state and event from typedefs and update docs 2019-05-08 16:06:58 +02:00
Robert Virding d2cd97def7 Add handling of creating/updating maps and records, definitely WIP 2019-04-29 00:56:31 +02:00
Robert Virding 5455d0fcd7 Fixed a type error and test, definitely WIP 2019-04-25 12:19:49 +02:00
Robert Virding 2d3e6ab6e0 Refactor internal code and more add statements, definitely WIP 2019-04-25 11:56:21 +02:00
Robert Virding 70a0f77793 Replace hash with bytes, definitely WIP 2019-04-23 11:56:54 +02:00
Robert Virding 04b3227317 Update documentation, definitely WIP 2019-04-23 11:56:08 +02:00
Robert Virding d9be8b2fca Saving even more stuff, definitely WIP 2019-04-23 11:56:08 +02:00
Robert Virding a38afe7693 Saving more stuff, definitely WIP 2019-04-23 11:56:08 +02:00
Robert Virding 5719730d8c Saving stuff, definitely WIP 2019-04-23 11:56:08 +02:00
91 changed files with 2095 additions and 5383 deletions
Expand all files Collapse all files
.gitignore
+1 -3
View File
@@ -1,5 +1,5 @@
.rebar3
_[^_]*
_*
.eunit
*.o
*.beam
@@ -19,5 +19,3 @@ rebar3.crashdump
*.erl~
*.aes~
aesophia
.qcci
current_counterexample.eqc
CHANGELOG.md
+1 -72
View File
@@ -9,74 +9,6 @@ and this project adheres to [Semantic Versioning](https://semver.org/spec/v2.0.0
### 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
@@ -103,9 +35,6 @@ and this project adheres to [Semantic Versioning](https://semver.org/spec/v2.0.0
- 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
[Unreleased]: https://github.com/aeternity/aesophia/compare/v2.1.0...HEAD
[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
docs/aeso_aci.md
+139 -74
View File
@@ -30,14 +30,53 @@ generates the following JSON structure representing the contract interface:
``` json
{
"contract": {
"name": "Answers",
"state": {
"record": [
{
"name": "a",
"type": {
"map": {
"key": "string",
"value": "int"
}
}
}
]
},
"type_defs": [
{
"name": "answers",
"vars": [],
"typedef": {
"map": {
"key": "string",
"value": "int"
}
}
}
],
"functions": [
{
"arguments": [],
"name": "init",
"returns": "Answers.state",
"arguments": [],
"returns": {
"record": [
{
"name": "a",
"type": {
"map": {
"key": "string",
"value": "int"
}
}
}
]
},
"stateful": true
},
{
"name": "new_answer",
"arguments": [
{
"name": "q",
@@ -48,36 +87,14 @@ generates the following JSON structure representing the contract interface:
"type": "int"
}
],
"name": "new_answer",
"returns": {
"map": [
"string",
"int"
]
"map": {
"key": "string",
"value": "int"
}
},
"stateful": false
}
],
"name": "Answers",
"state": {
"record": [
{
"name": "a",
"type": "Answers.answers"
}
]
},
"type_defs": [
{
"name": "answers",
"typedef": {
"map": [
"string",
"int"
]
},
"vars": []
}
]
}
}
@@ -87,70 +104,118 @@ 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().
``` erlang
contract_string() = string() | binary()
json_string() = binary()
```
### Exports
#### contract\_interface(aci\_type(), string()) -> {ok, json() | string()} | {error, term()}
#### encode_contract(ContractString) -> {ok,JSONstring} | {error,ErrorString}
Generate the JSON encoding of the interface to a contract. The type definitions
and non-private functions are included in the JSON string.
Types
#### render\_aci\_json(json() | json\_text()) -> string().
``` erlang
ConstractString = contract_string()
JSONstring = json_string()
```
Take a JSON encoding of a contract interface and generate a contract interface
that can be included in another contract.
This is equivalent to `aeso_aci:encode_contract(ConstractString, [])`.
#### encode_contract(ContractString, Options) -> {ok,JSONstring} | {error,ErrorString}
Types
``` erlang
ConstractString = contract_string()
Options = [option()]
JSONstring = json_string()
```
Generate the JSON encoding of the interface to a contract. The type definitions and non-private functions are included in the JSON string.
#### decode_contract(JSONstring) -> ConstractString.
Types
``` erlang
ConstractString = contract_string()
JSONstring = json_string()
```
Take a JSON encoding of a contract interface and generate and generate a contract definition which can be included in another contract.
#### encode_type(TypeAST) -> JSONstring.
Types
``` erlang
JSONstring = json_string()
```
Generate the JSON encoding of a type from the AST of the type.
#### encode_arg(ArgAST) -> JSONstring.
Types
``` erlang
JSONstring = json_string()
```
Generate the JSON encoding of a function argument from the AST of the argument.
#### encode_stmt(StmtAST) -> JSONstring.
Types
``` erlang
JSONstring = json_string()
```
Generate the JSON encoding of a statement from the AST of the statement.
#### encode_expr(ExprAST) -> JSONstring.
Types
``` erlang
JSONstring = json_string()
```
Generate the JSON encoding of an expression from the AST of the expression.
### Notes
The deprecated functions `aseo_aci:encode/2` and `aeso_aci:decode/1` are still available but should not be used.
### 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.
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,<<"contract Answers =\n\n record state = { a : answers }\n type answers() = map(string, int)\n\n stateful functio"...>>}
2> {ok,Encoding} = aeso_aci:encode_contract(Contract).
{ok,<<"{\"contract\":{\"name\":\"Answers\",\"state\":{\"record\":[{\"name\":\"a\",\"type\":{\"map\":{\"key\":\"string\",\"value\":\"int\"}}}]"...>>}
3> file:write_file("aci_test.aci", Encoding).
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).
4> Decoded = aeso_aci:decode_contract(Encoding).
<<"contract Answers =\n function new_answer : (string, int) => map(string, int)\n">>
5> file:write_file("aci_test.include", Decoded).
ok
6> jsx:prettify(jsx:encode(JsonACI)).
<<"[\n {\n \"contract\": {\n \"functions\": [\n {\n \"arguments\": [],\n \"name\": \"init\",\n "...>>
6> jsx:prettify(Encoding).
<<"{\n \"contract\": {\n \"name\": \"Answers\",\n \"state\": {\n \"record\": [\n {\n \"name\": \"a\",\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.
The final call to `jsx:prettify(Encoding)` returns the encoding in a
more easily readable form. This is what is shown in the description
above.
### Notes
The ACI generator currently cannot properly handle types defined using `datatype`.
rebar.config
+18 -3
View File
@@ -2,20 +2,35 @@
{erl_opts, [debug_info]}.
{deps, [ {aebytecode, {git, "https://github.com/aeternity/aebytecode.git", {ref,"adf3664"}}}
{deps, [ {aebytecode, {git, "https://github.com/aeternity/aebytecode.git",
{ref, "e8253b0"}}}
, {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, "%%! \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"},
{relx, [{release, {aesophia, "2.1.0"},
[aesophia, aebytecode, getopt]},
{dev_mode, true},
rebar.lock
+3 -3
View File
@@ -1,17 +1,17 @@
{"1.1.0",
[{<<"aebytecode">>,
{git,"https://github.com/aeternity/aebytecode.git",
{ref,"adf3664dd03626c115756f79fa0e602fda24318d"}},
{ref,"e8253b09709f1595d8bd6a1756a0ce93185c6518"}},
0},
{<<"aeserialization">>,
{git,"https://github.com/aeternity/aeserialization.git",
{ref,"816bf994ffb5cee218c3f22dc5fea296c9e0882e"}},
{ref,"6dce265753af4e651f77746e77ea125145c85dd3"}},
1},
{<<"base58">>,
{git,"https://github.com/aeternity/erl-base58.git",
{ref,"60a335668a60328a29f9731b67c4a0e9e3d50ab6"}},
2},
{<<"eblake2">>,{pkg,<<"eblake2">>,<<"1.0.0">>},0},
{<<"eblake2">>,{pkg,<<"eblake2">>,<<"1.0.0">>},1},
{<<"getopt">>,{pkg,<<"getopt">>,<<"1.0.1">>},0},
{<<"jsx">>,
{git,"https://github.com/talentdeficit/jsx.git",
rebar3
BIN
View File
Binary file not shown.
src/aeso_aci.erl
+467 -255
View File
@@ -9,70 +9,100 @@
-module(aeso_aci).
-export([ file/2
, file/3
, contract_interface/2
, contract_interface/3
%% Old deprecated interface.
-export([encode/1,encode/2,decode/1]).
, render_aci_json/1
-export([encode_contract/1,encode_contract/2,decode_contract/1]).
-export([encode_func/1,encode_type/1,encode_arg/1,
encode_stmt/1,encode_expr/1]).
, json_encode_expr/1
, json_encode_type/1]).
%% Define records for the various typed syntactic forms. These make
%% the code easier but don't seem to exist elsewhere. Unfortunately
%% sometimes the same typename is used with different fields.
-type aci_type() :: json | string.
-type json() :: jsx:json_term().
-type json_text() :: binary().
%% Top-level
-record(contract, {ann,con,decls}).
%% -record(namespace, {ann,con,decls}).
-record(letfun, {ann,id,args,type,body}).
-record(type_def, {ann,id,vars,typedef}).
%% External API
-spec file(aci_type(), string()) -> {ok, json() | string()} | {error, term()}.
file(Type, File) ->
file(Type, File, []).
%% Types
-record(app_t, {ann,id,fields}).
-record(tuple_t, {ann,args}).
-record(bytes_t, {ann,len}).
-record(record_t, {fields}).
-record(field_t, {ann,id,type}).
-record(alias_t, {type}).
-record(variant_t, {cons}).
-record(constr_t, {ann,con,args}).
-record(fun_t, {ann,named,args,type}).
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.
%% Tokens
-record(arg, {ann,id,type}).
-record(id, {ann,name}).
-record(con, {ann,name}).
-record(qid, {ann,names}).
-record(qcon, {ann,names}).
-record(tvar, {ann,name}).
-spec contract_interface(aci_type(), string()) ->
{ok, json() | string()} | {error, term()}.
contract_interface(Type, ContractString) ->
contract_interface(Type, ContractString, []).
%% Statements
-record(block, {ann,body}).
-record('if', {ann,test,then,else}). %Both statement and expression
-record(letval, {ann,pat,type,exp}).
-record(switch, {ann,arg,cases}).
-record('case', {ann,pat,body}).
-spec contract_interface(aci_type(), string(), [term()]) ->
{ok, json() | string()} | {error, term()}.
contract_interface(Type, ContractString, CompilerOpts) ->
do_contract_interface(Type, ContractString, CompilerOpts).
%% Expressions
-record(bool, {ann,bool}).
-record(int, {ann,value}).
-record(string, {ann,bin}).
-record(bytes, {ann,bin}).
-record(tuple, {ann,args}).
-record(list, {ann,args}).
-record(record, {ann,fields}). %Create a record
-record(field, {ann,name,value}). %A record field
-record(proj, {ann,value}). %?
-record(map, {ann,fields}). %Create a map
-record(map_get, {ann,field}).
-record(lam, {ann,args,body}).
-record(app, {ann,func,args}).
-record(typed, {ann,expr,type}).
-spec render_aci_json(json() | json_text()) -> {ok, binary()}.
render_aci_json(Json) ->
do_render_aci_json(Json).
%% The old deprecated interface.
-spec json_encode_expr(aeso_syntax:expr()) -> json().
json_encode_expr(Expr) ->
encode_expr(Expr).
encode(C) -> encode_contract(C).
encode(C, Os) -> encode_contract(C, Os).
decode(J) -> decode_contract(J).
-spec json_encode_type(aeso_syntax:type()) -> json().
json_encode_type(Type) ->
encode_type(Type).
%% encode_contract(ContractString) -> {ok,JSON} | {error,String}.
%% encode_contract(ContractString, Options) -> {ok,JSON} | {error,String}.
%% Build a JSON structure with lists and tuples, not maps, as this
%% allows us to order the fields in the contructed JSON string.
%% 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) ->
encode_contract(ContractString) ->
encode_contract(ContractString, []).
encode_contract(ContractString, Options) when is_binary(ContractString) ->
encode_contract(binary_to_list(ContractString), Options);
encode_contract(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
Ast = parse(ContractString, Options),
%% io:format("Ast\n~p\n", [Ast]),
%% aeso_ast:pp(Ast),
TypedAst = aeso_ast_infer_types:infer(Ast, Options),
%% io:format("Typed ast\n~p\n", [TypedAst]),
%% aeso_ast:pp_typed(TypedAst),
%% We find and look at the last contract.
Contract = lists:last(TypedAst),
Cname = contract_name(Contract),
Tdefs = do_encode_contract_typedefs(sort_decls(contract_types(Contract))),
Fdefs = [ do_encode_func(F) || F <- sort_decls(contract_funcs(Contract)),
not is_private_func(F) ],
Jmap = [{<<"contract">>,
[{<<"name">>, do_encode_name(Cname)}] ++
Tdefs ++
[{<<"functions">>, Fdefs}]}],
%% io:format("~p\n", [Jmap]),
{ok,jsx:encode(Jmap)}
catch
%% The compiler errors.
error:{parse_errors, Errors} ->
@@ -89,259 +119,394 @@ 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)},
%% do_encode_contract_typedefs(TypeDefs) -> [JSON].
%% Return a list of typedefs and state and event if they occur.
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),
do_encode_contract_typedefs(Tdefs) ->
Fun = fun(T, {Ts,Ss,Es}) ->
%% Only one state and event.
case typedef_name(T) of
"state" -> {Ts,[do_encode_state_typedef(T)],Es};
"event" -> {Ts,Ss,[do_encode_event_typedef(T)]};
_Name -> {Ts ++ [do_encode_typedef(T)],Ss,Es}
end
end,
{Ts,Ss,Es} = lists:foldl(Fun, {[],[],[]}, Tdefs),
Ss ++ [{<<"type_defs">>, Ts}] ++ Es.
C1 = C0#{type_defs => Tdefs},
%% do_encode_state_typedef(StateTdef) -> JSON.
%% do_encode_event_typedef(EventTdef) -> JSON.
C2 = case Es of
[] -> C1;
[#{typedef := ET}] -> C1#{event => ET}
end,
do_encode_state_typedef(State) ->
Def = typedef_def(State),
{<<"state">>,do_encode_alias(Def)}.
C3 = case Ss of
[] -> C2;
[#{typedef := ST}] -> C2#{state => ST}
end,
do_encode_event_typedef(State) ->
Def = typedef_def(State),
{<<"event">>,do_encode_alias(Def)}.
Fdefs = [ encode_function(F)
|| F <- sort_decls(contract_funcs(Contract)),
is_entrypoint(F) ],
%% encode_func(TypedAST) -> JSON.
%% Encode a function AST into a JSON structure.
#{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_func(AST) ->
jsx:encode(do_encode_func(AST)).
%% do_encode_func(Function) -> JSONmap
%% 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) ].
do_encode_func(Fdef) ->
Name = function_name(Fdef),
Args = function_args(Fdef),
Type = function_type(Fdef),
[{<<"name">>, do_encode_name(Name)},
{<<"arguments">>, do_encode_args(Args)},
{<<"returns">>, do_encode_type(Type)},
{<<"stateful">>, is_stateful_func(Fdef)}].
encode_args(Args) -> [ encode_arg(A) || A <- Args ].
%% encode_arg(TypedAST) -> JSON.
%% Encode an argument AST into a JSON structure.
encode_arg({arg, _, Id, T}) ->
#{name => encode_type(Id),
type => encode_type(T)}.
encode_arg(AST) ->
jsx:encode(do_encode_arg(AST)).
encode_typedef(Type) ->
%% do_encode_args(ArgASTs) -> [JSONmap].
%% do_encode_arg(ArgAST) -> JSONmap.
do_encode_args(Args) ->
[ do_encode_arg(A) || A <- Args ].
do_encode_arg(#arg{id=Id,type=T}) ->
[{<<"name">>,do_encode_type(Id)},
{<<"type">>,do_encode_type(T)}].
%% encode_type(TypedAST) -> JSON.
%% Encode a type AST into a JSON structure.
encode_type(AST) ->
jsx:encode(do_encode_type(AST)).
%% do_encode_types([TypeAST]) -> [JSONmap].
%% do_encode_type(TypeAST) -> JsonMap.
do_encode_types(Types) ->
[ do_encode_type(T) || T <- Types ].
do_encode_type(#tvar{name=N}) -> do_encode_name(N);
do_encode_type(#id{name=N}) -> do_encode_name(N);
do_encode_type(#con{name=N}) -> do_encode_name(N);
do_encode_type(#qid{names=Ns}) ->
do_encode_name(lists:join(".", Ns));
do_encode_type(#qcon{names=Ns}) ->
do_encode_name(lists:join(".", Ns)); %?
do_encode_type(#tuple_t{args=As}) ->
Eas = do_encode_types(As),
[{<<"tuple">>,Eas}];
do_encode_type(#bytes_t{len=Len}) ->
{<<"bytes">>,Len};
do_encode_type(#record_t{fields=Fs}) ->
Efs = do_encode_type_rec_fields(Fs),
[{<<"record">>,Efs}];
%% Special case lists and maps as they are built-in types.
do_encode_type(#app_t{id=#id{name="list"},fields=[F]}) ->
Ef = do_encode_type(F),
[{<<"list">>,Ef}];
do_encode_type(#app_t{id=#id{name="map"},fields=Fs}) ->
Ef = do_encode_type_mapo_field(Fs),
[{<<"map">>,Ef}];
%% Other applications.
do_encode_type(#app_t{id=Id,fields=Fs}) ->
Name = do_encode_type(Id),
Efs = do_encode_types(Fs),
[{Name,Efs}];
do_encode_type(#variant_t{cons=Cs}) ->
Ecs = do_encode_types(Cs),
[{<<"variant">>,Ecs}];
do_encode_type(#constr_t{con=C,args=As}) ->
Ec = do_encode_type(C),
Eas = do_encode_types(As),
[{Ec,Eas}];
do_encode_type(#fun_t{args=As,type=T}) ->
Eas = do_encode_types(As),
Et = do_encode_type(T),
[{<<"function">>,[{<<"arguments">>,Eas},{<<"returns">>,Et}]}].
do_encode_name(Name) ->
list_to_binary(Name).
%% do_encode_type_rec_fields(Fields) -> [JSONmap].
%% do_encode_type_rec_field(Field) -> JSONmap.
%% Encode a record field type.
do_encode_type_rec_fields(Fs) ->
[ do_encode_type_rec_field(F) || F <- Fs ].
do_encode_type_rec_field(#field_t{id=Id,type=T}) ->
[{<<"name">>,do_encode_type(Id)},
{<<"type">>,do_encode_type(T)}].
%% do_encode_type_mapo_field(Field) -> JSONmap.
%% Two fields for one map type.
do_encode_type_mapo_field([K,V]) ->
[{<<"key">>,do_encode_type(K)},
{<<"value">>,do_encode_type(V)}].
%% do_encode_typedef(TypeDefAST) -> JSON.
do_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)}.
Def = typedef_def(Type),
[{<<"name">>, do_encode_name(Name)},
{<<"vars">>, do_encode_tvars(Vars)},
{<<"typedef">>, do_encode_alias(Def)}].
encode_tvars(Vars) ->
[ #{name => encode_type(V)} || V <- Vars ].
do_encode_tvars(Vars) ->
[ do_encode_tvar(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)}}.
do_encode_tvar(#tvar{name=N}) ->
[{<<"name">>, do_encode_name(N)}].
encode_types(Ts) -> [ encode_type(T) || T <- Ts ].
do_encode_alias(#alias_t{type=T}) ->
do_encode_type(T);
do_encode_alias(A) -> do_encode_type(A).
encode_type_fields(Fs) -> [ encode_type_field(F) || F <- Fs ].
%% encode_stmt(StmtAST) -> JSON.
%% Encode a statement AST into a JSON structure.
encode_type_field({field_t, _, Id, T}) ->
#{name => encode_type(Id),
type => encode_type(T)}.
encode_stmt(AST) ->
jsx:encode(do_encode_stmt(AST)).
encode_name(Name) when is_list(Name) ->
list_to_binary(Name);
encode_name(Name) when is_binary(Name) ->
Name.
%% do_encode_stmt(StmtAST) -> JSONmap.
%% Encode Expr
encode_exprs(Es) -> [ encode_expr(E) || E <- Es ].
do_encode_stmt(#typed{expr=E}) -> %Ignore the type
do_encode_stmt(E);
do_encode_stmt(#block{body=Body}) ->
Eblock = [ do_encode_stmt(B) || B <- Body ],
[{<<"block">>,Eblock}];
do_encode_stmt(#'if'{test=Test,then=Then,else=Else}) ->
%% This is both a statement and en expression.
Etest = do_encode_expr(Test),
Ethen = do_encode_stmt(Then),
Eelse = do_encode_stmt(Else),
[{<<"if">>,[{<<"test">>,Etest},{<<"then">>,Ethen},{<<"else">>,Eelse}]}];
do_encode_stmt(#letval{pat=Pat,exp=Exp}) ->
Epat = do_encode_expr(Pat),
Eexp = do_encode_expr(Exp),
[{<<"let">>,[{<<"pattern">>,Epat},{<<"expression">>,Eexp}]}];
do_encode_stmt(#switch{arg=Arg,cases=Cases}) ->
Earg = do_encode_expr(Arg),
Ecases = [ do_encode_stmt_case(Case) || Case <- Cases ],
[{<<"switch">>,[{<<"arg">>,Earg},{<<"cases">>,Ecases}]}];
do_encode_stmt(E) ->
do_encode_expr(E).
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}).
do_encode_stmt_case(#'case'{pat=Pat,body=Body}) ->
Epat = do_encode_expr(Pat), %Patterns are expessions
Ebody = do_encode_stmt(Body),
[{<<"pattern">>,Epat},{<<"body">>,Ebody}].
encode_fields(Flds) -> [ encode_field(F) || F <- Flds ].
%% encode_expr(ExprAST) -> JSON.
%% Encode an expression AST into a JSON structure.
encode_field({field, _, [{proj, _, {id, _, Fld}}], Val}) ->
{encode_name(Fld), encode_expr(Val)}.
encode_expr(AST) ->
jsx:encode(do_encode_expr(AST)).
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"))}.
%% do_encode_exprs(ExprASTs) -> [JSONmap].
%% do_encode_expr(ExprAST) -> JSONmap.
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(_) -> [].
do_encode_exprs(Es) ->
[ do_encode_expr(E) || E <- Es ].
decode_funcs(Fs) -> [ decode_func(F) || F <- Fs ].
do_encode_expr(#typed{expr=E}) -> %Ignore the type
do_encode_expr(E);
do_encode_expr(#id{name=N}) -> do_encode_name(N);
do_encode_expr(#con{name=N}) -> do_encode_name(N);
do_encode_expr(#qid{names=Ns}) ->
do_encode_name(lists:join(".", Ns));
do_encode_expr(#qcon{names=Ns}) ->
do_encode_name(lists:join(".", Ns)); %?
do_encode_expr(#bool{bool=B}) -> B;
do_encode_expr(#int{value=V}) -> V;
do_encode_expr(#string{bin=B}) ->
[{<<"string">>,B}];
do_encode_expr(#bytes{bin=B}) -> B;
do_encode_expr(#tuple{args=As}) ->
Eas = do_encode_exprs(As),
[{<<"tuple">>,Eas}];
do_encode_expr(#list{args=As}) ->
Eas = do_encode_exprs(As),
[{<<"list">>,Eas}];
do_encode_expr(#record{fields=Fs}) -> %Create a record
Efs = do_encode_expr_rec_fields(Fs),
[{<<"create_record">>,Efs}];
do_encode_expr({record,_Ann,Rec,Fs}) -> %Update a record
Erec = do_encode_expr(Rec),
Efs = do_encode_expr_rec_fields(Fs),
[{<<"update_record">>,[Erec,Efs]}];
do_encode_expr(#lam{args=As,body=B}) ->
Eas = do_encode_args(As),
Eb = do_encode_stmt(B),
[{<<"function">>,[{<<"arguments">>,Eas},{<<"body">>,Eb}]}];
do_encode_expr(#map{fields=Fs}) -> %Create a map
Efs = do_encode_expr_map_fields(Fs),
[{<<"create_map">>,Efs}];
do_encode_expr({map,_Ann,Map,Fs}) -> %Update a map
Emap = do_encode_expr(Map),
Efs = do_encode_expr_map_fields(Fs),
[{<<"update_map">>,[Emap,Efs]}];
do_encode_expr(#map_get{field=F}) ->
do_encode_expr(F);
do_encode_expr(#proj{value=V}) ->
do_encode_expr(V);
do_encode_expr(#app{func=F,args=As}) ->
Ef = do_encode_expr(F),
Eas = do_encode_exprs(As),
[{<<"apply">>,[{<<"function">>,Ef},
{<<"arguments">>,Eas}]}];
do_encode_expr(#'if'{test=Test,then=Then,else=Else}) ->
%% This is both a statement and en expression.
Etest = do_encode_expr(Test),
Ethen = do_encode_expr(Then),
Eelse = do_encode_expr(Else),
[{<<"if">>,[{<<"test">>,Etest},{<<"then">>,Ethen},{<<"else">>,Eelse}]}];
do_encode_expr({Op,_Ann}) ->
list_to_binary(atom_to_list(Op)).
%% decode_func(#{name := init}) -> [];
decode_func(#{name := Name, arguments := As, returns := T}) ->
[" entrypoint", " ", io_lib:format("~s", [Name]), " : ",
decode_args(As), " => ", decode_type(T), $\n].
%% do_encode_expr_rec_fields(Fields) -> [JSON].
%% do_encode_expr_rec_field(Field) -> JSON.
%% Encode a record field expression.
decode_args(As) ->
Das = [ decode_arg(A) || A <- As ],
do_encode_expr_rec_fields(Fs) ->
[ do_encode_expr_rec_field(F) || F <- Fs ].
do_encode_expr_rec_field(#field{name=[N],value=V}) ->
[{<<"name">>,do_encode_expr(N)},
{<<"value">>,do_encode_expr(V)}].
%% do_encode_expr_map_fields(Fields) -> [JSON].
%% do_encode_expr_map_field(Field) -> JSON.
%% Encode a map field expression.
do_encode_expr_map_fields(Fs) ->
[ do_encode_expr_map_field(F) || F <- Fs ].
do_encode_expr_map_field({K,V}) ->
[{<<"key">>,do_encode_expr(K)},
{<<"value">>,do_encode_expr(V)}];
do_encode_expr_map_field(#field{name=[K],value=V}) ->
[{<<"key">>,do_encode_expr(K)},
{<<"value">>,do_encode_expr(V)}].
%% decode_contract(JSON) -> ContractString.
%% Decode a JSON string and generate a suitable contract string which
%% can be included in a contract definition. We decode into a map
%% here as this is easier to work with and order is not important.
decode_contract(Json) ->
Map = jsx:decode(Json, [return_maps]),
%% io:format("~p\n", [Map]),
#{<<"contract">> := C} = Map,
#{<<"name">> := Name, <<"type_defs">> := Ts, <<"functions">> := Fs} = C,
CS = ["contract"," ",io_lib:format("~s", [Name])," =\n",
do_decode_tdefs(Ts),
do_decode_funcs(Fs)],
list_to_binary(CS).
do_decode_funcs(Fs) -> [ do_decode_func(F) || F <- Fs ].
do_decode_func(#{<<"name">> := <<"init">>}) -> [];
do_decode_func(#{<<"name">> := Name,<<"arguments">> := As,<<"returns">> := T}) ->
[" function"," ",io_lib:format("~s", [Name])," : ",
do_decode_args(As)," => ",do_decode_type(T),$\n].
do_decode_args(As) ->
Das = [ do_decode_arg(A) || A <- As ],
[$(,lists:join(", ", Das),$)].
decode_arg(#{type := T}) -> decode_type(T).
do_decode_arg(#{<<"type">> := T}) -> do_decode_type(T).
decode_types(Ets) ->
[ decode_type(Et) || Et <- Ets ].
do_decode_types(Ets) ->
[ do_decode_type(Et) || Et <- Ets ].
decode_type(#{tuple := Ets}) ->
Ts = decode_types(Ets),
case Ts of
[] -> ["unit"];
_ -> [$(,lists:join(" * ", Ts),$)]
end;
decode_type(#{record := Efs}) ->
Fs = decode_fields(Efs),
[${,lists:join(",", Fs),$}];
decode_type(#{list := [Et]}) ->
T = decode_type(Et),
do_decode_type(#{<<"tuple">> := Ets}) ->
Ts = do_decode_types(Ets),
[$(,lists:join(", ", Ts),$)];
do_decode_type(#{<<"record">> := Efs}) ->
Fs = do_decode_type_rec_fields(Efs),
[${,lists:join(", ", Fs),$}];
do_decode_type(#{<<"list">> := Et}) ->
T = do_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),
do_decode_type(#{<<"map">> := Et}) ->
T = do_decode_type_map(Et),
["map",$(,T,$)];
do_decode_type(#{<<"variant">> := Ets}) ->
Ts = do_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
do_decode_type(Econs) when is_map(Econs) -> %General constructor
%% io:format("~p\n", [Econs]),
[{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).
C = do_decode_name(Ec),
Ts = do_decode_types(Ets),
[C,$(,lists:join(", ", Ts),$)];
do_decode_type(T) -> %Just raw names.
do_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).
do_decode_name(En) ->
binary_to_list(En).
decode_fields(Efs) ->
[ decode_field(Ef) || Ef <- Efs ].
do_decode_type_rec_fields(Efs) ->
[ do_decode_type_rec_field(Ef) || Ef <- Efs ].
decode_field(#{name := En, type := Et}) ->
Name = decode_name(En),
Type = decode_type(Et),
do_decode_type_rec_field(#{<<"name">> := En,<<"type">> := Et}) ->
Name = do_decode_name(En),
Type = do_decode_type(Et),
[Name," : ",Type].
%% decode_tdefs(Json) -> [TypeString].
do_decode_type_map(#{<<"key">> := Ek,<<"value">> := Ev}) ->
Key = do_decode_type(Ek),
Value = do_decode_type(Ev),
[Key,", ",Value].
%% do_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 ].
do_decode_tdefs(Ts) -> [ do_decode_tdef(T) ||
#{<<"typedef">> := #{<<"variant">> := _}} = 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, $\n].
do_decode_tdef(#{<<"name">> := Name,<<"vars">> := Vs,<<"typedef">> := T}) ->
[" datatype"," ",do_decode_name(Name),do_decode_tvars(Vs),
" = ",do_decode_type(T),$\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 ],
do_decode_tvars([]) -> []; %No tvars, no parentheses
do_decode_tvars(Vs) ->
Dvs = [ do_decode_tvar(V) || V <- Vs ],
[$(,lists:join(", ", Dvs),$)].
decode_tvar(#{name := N}) -> io_lib:format("~s", [N]).
do_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_name(#contract{con=#con{name=N}}) -> N.
contract_types({C, _, _, Decls}) when C == contract; C == namespace ->
[ D || D <- Decls, is_type(D) ].
contract_funcs(#contract{decls=Decls}) ->
[ D || D <- Decls, is_record(D, letfun) ].
is_fun({letfun, _, _, _, _, _}) -> true;
is_fun({fun_decl, _, _, _}) -> true;
is_fun(_) -> false.
contract_types(#contract{decls=Decls}) ->
[ D || D <- Decls, is_record(D, type_def) ].
is_type({type_def, _, _, _, _}) -> true;
is_type(_) -> false.
%% To keep dialyzer happy and quiet.
%% namespace_name(#namespace{con=#con{name=N}}) -> N.
%%
%% namespace_funcs(#namespace{decls=Decls}) ->
%% [ D || D <- Decls, is_record(D, letfun) ].
%%
%% namespace_types(#namespace{decls=Decls}) ->
%% [ D || D <- Decls, is_record(D, type_def) ].
sort_decls(Ds) ->
Sort = fun (D1, D2) ->
@@ -350,11 +515,58 @@ sort_decls(Ds) ->
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).
%% #letfun{Ann, Id, [Arg], Type, Typedef}.
typedef_name({type_def, _, {id, _, Name}, _, _}) -> Name.
function_name(#letfun{id=#id{name=N}}) -> N.
typedef_vars({type_def, _, _, Vars, _}) -> Vars.
function_args(#letfun{args=Args}) -> Args.
typedef_def({type_def, _, _, _, Def}) -> Def.
function_type(#letfun{type=Type}) -> Type.
is_private_func(#letfun{ann=A}) -> aeso_syntax:get_ann(private, A, false).
is_stateful_func(#letfun{ann=A}) -> aeso_syntax:get_ann(stateful, A, false).
%% #type_def{Ann, Id, [Var], Typedef}.
typedef_name(#type_def{id=#id{name=N}}) -> N.
typedef_vars(#type_def{vars=Vars}) -> Vars.
typedef_def(#type_def{typedef=Def}) -> Def.
%% parse(ContractString, Options) -> {ok,AST}.
%% Signal errors, the sophia compiler way. Sigh!
parse(Text, Options) ->
%% Try and return something sensible here!
case aeso_parser:string(Text, Options) of
%% Yay, it worked!
{ok, Contract} -> Contract;
%% Scan errors.
{error, {Pos, scan_error}} ->
parse_error(Pos, "scan error");
{error, {Pos, scan_error_no_state}} ->
parse_error(Pos, "scan error");
%% Parse errors.
{error, {Pos, parse_error, Error}} ->
parse_error(Pos, Error);
{error, {Pos, ambiguous_parse, As}} ->
ErrorString = io_lib:format("Ambiguous ~p", [As]),
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(Pos, ErrorString) ->
%% io:format("Error ~p ~p\n", [Pos,ErrorString]),
Error = io_lib:format("~s: ~s", [pos_error(Pos), ErrorString]),
error({parse_errors, [Error]}).
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_ast_infer_types.erl
+90 -341
View File
@@ -98,14 +98,11 @@
-type scope() :: #scope{}.
-record(env,
{ scopes = #{ [] => #scope{}} :: #{ qname() => scope() }
, vars = [] :: [{name(), var_info()}]
, typevars = unrestricted :: unrestricted | [name()]
, fields = #{} :: #{ name() => [field_info()] } %% fields are global
, namespace = [] :: qname()
, in_pattern = false :: boolean()
, stateful = false :: boolean()
, current_function = none :: none | aeso_syntax:id()
{ scopes = #{ [] => #scope{}} :: #{ qname() => scope() }
, vars = [] :: [{name(), var_info()}]
, typevars = unrestricted :: unrestricted | [name()]
, fields = #{} :: #{ name() => [field_info()] } %% fields are global
, namespace = [] :: qname()
}).
-type env() :: #env{}.
@@ -135,10 +132,6 @@ on_current_scope(Env = #env{ namespace = NS, scopes = Scopes }, Fun) ->
Scope = maps:get(NS, Scopes),
Env#env{ scopes = Scopes#{ NS => Fun(Scope) } }.
-spec on_scopes(env(), fun((scope()) -> scope())) -> env().
on_scopes(Env = #env{ scopes = Scopes }, Fun) ->
Env#env{ scopes = maps:map(fun(_, Scope) -> Fun(Scope) end, Scopes) }.
-spec bind_var(aeso_syntax:id(), type(), env()) -> env().
bind_var({id, Ann, X}, T, Env) ->
Env#env{ vars = [{X, {Ann, T}} | Env#env.vars] }.
@@ -156,7 +149,7 @@ bind_tvars(Xs, Env) ->
check_tvar(#env{ typevars = TVars}, T = {tvar, _, X}) ->
case TVars == unrestricted orelse lists:member(X, TVars) of
true -> ok;
false -> type_error({unbound_type, T})
false -> type_error({unbound_type_variable, T})
end,
T.
@@ -203,7 +196,7 @@ bind_state(Env) ->
false -> {id, Ann, "event"} %% will cause type error if used(?)
end,
Env1 = bind_funs([{"state", State},
{"put", {type_sig, [stateful | Ann], [], [State], Unit}}], Env),
{"put", {fun_t, Ann, [], [State], Unit}}], Env),
%% We bind Chain.event in a local 'Chain' namespace.
pop_scope(
@@ -363,12 +356,11 @@ global_env() ->
Pair = fun(A, B) -> {tuple_t, Ann, [A, B]} end,
Fun = fun(Ts, T) -> {type_sig, Ann, [], Ts, T} end,
Fun1 = fun(S, T) -> Fun([S], T) end,
StateFun = fun(Ts, T) -> {type_sig, [stateful|Ann], [], Ts, T} end,
TVar = fun(X) -> {tvar, Ann, "'" ++ X} end,
TVar = fun(X) -> {tvar, Ann, "'" ++ X} end,
SignId = {id, Ann, "signature"},
SignDef = {bytes, Ann, <<0:64/unit:8>>},
SignDef = {tuple, Ann, [{int, Ann, 0}, {int, Ann, 0}]},
Signature = {named_arg_t, Ann, SignId, SignId, {typed, Ann, SignDef, SignId}},
SignFun = fun(Ts, T) -> {type_sig, [stateful|Ann], [Signature], Ts, T} end,
SignFun = fun(Ts, T) -> {type_sig, Ann, [Signature], Ts, T} end,
TTL = {qid, Ann, ["Chain", "ttl"]},
Fee = Int,
[A, Q, R, K, V] = lists:map(TVar, ["a", "q", "r", "k", "v"]),
@@ -384,11 +376,9 @@ global_env() ->
{"RelativeTTL", Fun1(Int, TTL)},
{"FixedTTL", Fun1(Int, TTL)},
%% Abort
{"abort", Fun1(String, A)},
{"require", Fun([Bool, String], Unit)}])
{"abort", Fun1(String, A)}])
, types = MkDefs(
[{"int", 0}, {"bool", 0}, {"char", 0}, {"string", 0}, {"address", 0},
{"unit", {[], {alias_t, Unit}}},
[{"int", 0}, {"bool", 0}, {"string", 0}, {"address", 0},
{"hash", {[], {alias_t, Bytes(32)}}},
{"signature", {[], {alias_t, Bytes(64)}}},
{"bits", 0},
@@ -399,10 +389,10 @@ global_env() ->
ChainScope = #scope
{ funs = MkDefs(
%% Spend transaction.
[{"spend", StateFun([Address, Int], Unit)},
[{"spend", Fun([Address, Int], Unit)},
%% Chain environment
{"balance", Fun1(Address, Int)},
{"block_hash", Fun1(Int, Option(Hash))},
{"block_hash", Fun1(Int, Int)},
{"coinbase", Address},
{"timestamp", Int},
{"block_height", Int},
@@ -413,7 +403,7 @@ global_env() ->
ContractScope = #scope
{ funs = MkDefs(
[{"address", Address},
{"creator", Address},
%% {"owner", Int}, %% Not in EVM
{"balance", Int}]) },
CallScope = #scope
@@ -429,21 +419,19 @@ global_env() ->
{ funs = MkDefs(
[{"register", SignFun([Address, Fee, TTL], Oracle(Q, R))},
{"query_fee", Fun([Oracle(Q, R)], Fee)},
{"query", StateFun([Oracle(Q, R), Q, Fee, TTL, TTL], Query(Q, R))},
{"query", Fun([Oracle(Q, R), Q, Fee, TTL, TTL], Query(Q, R))},
{"get_question", Fun([Oracle(Q, R), Query(Q, R)], Q)},
{"respond", SignFun([Oracle(Q, R), Query(Q, R), R], Unit)},
{"extend", SignFun([Oracle(Q, R), TTL], Unit)},
{"get_answer", Fun([Oracle(Q, R), Query(Q, R)], option_t(Ann, R))},
{"check", Fun([Oracle(Q, R)], Bool)},
{"check_query", Fun([Oracle(Q,R), Query(Q, R)], Bool)}]) },
{"get_answer", Fun([Oracle(Q, R), Query(Q, R)], option_t(Ann, R))}]) },
AENSScope = #scope
{ funs = MkDefs(
[{"resolve", Fun([String, String], option_t(Ann, A))},
{"preclaim", SignFun([Address, Hash], Unit)},
{"claim", SignFun([Address, String, Int, Int], Unit)},
{"transfer", SignFun([Address, Address, String], Unit)},
{"revoke", SignFun([Address, String], Unit)}]) },
{"claim", SignFun([Address, String, Int], Unit)},
{"transfer", SignFun([Address, Address, Hash], Unit)},
{"revoke", SignFun([Address, Hash], Unit)}]) },
MapScope = #scope
{ funs = MkDefs(
@@ -491,17 +479,9 @@ global_env() ->
{"none", Bits},
{"all", Bits}]) },
%% Bytes
BytesScope = #scope
{ funs = MkDefs(
[{"to_int", Fun1(Bytes(any), Int)},
{"to_str", Fun1(Bytes(any), String)}]) },
%% Conversion
IntScope = #scope{ funs = MkDefs([{"to_str", Fun1(Int, String)}]) },
AddressScope = #scope{ funs = MkDefs([{"to_str", Fun1(Address, String)},
{"is_oracle", Fun1(Address, Bool)},
{"is_contract", Fun1(Address, Bool)}]) },
AddressScope = #scope{ funs = MkDefs([{"to_str", Fun1(Address, String)}]) },
#env{ scopes =
#{ [] => TopScope
@@ -515,7 +495,6 @@ global_env() ->
, ["Crypto"] => CryptoScope
, ["String"] => StringScope
, ["Bits"] => BitsScope
, ["Bytes"] => BytesScope
, ["Int"] => IntScope
, ["Address"] => AddressScope
} }.
@@ -527,7 +506,7 @@ map_t(As, K, V) -> {app_t, As, {id, As, "map"}, [K, V]}.
infer(Contracts) ->
infer(Contracts, []).
-type option() :: return_env | dont_unfold.
-type option() :: return_env.
-spec init_env(list(option())) -> env().
init_env(_Options) -> global_env().
@@ -539,38 +518,30 @@ infer(Contracts, Options) ->
Env = init_env(Options),
create_options(Options),
ets_new(type_vars, [set]),
check_modifiers(Env, Contracts),
{Env1, Decls} = infer1(Env, Contracts, [], Options),
{Env2, Decls2} =
case proplists:get_value(dont_unfold, Options, false) of
true -> {Env1, Decls};
false -> E = on_scopes(Env1, fun(Scope) -> unfold_record_types(Env1, Scope) end),
{E, unfold_record_types(E, Decls)}
end,
{Env1, Decls} = infer1(Env, Contracts, []),
case proplists:get_value(return_env, Options, false) of
false -> Decls2;
true -> {Env2, Decls2}
false -> Decls;
true -> {Env1, Decls}
end
after
clean_up_ets()
end.
-spec infer1(env(), [aeso_syntax:decl()], [aeso_syntax:decl()], list(option())) ->
{env(), [aeso_syntax:decl()]}.
infer1(Env, [], Acc, _Options) -> {Env, lists:reverse(Acc)};
infer1(Env, [{contract, Ann, ConName, Code} | Rest], Acc, Options) ->
-spec infer1(env(), [aeso_syntax:decl()], [aeso_syntax:decl()]) -> {env(), [aeso_syntax:decl()]}.
infer1(Env, [], Acc) -> {Env, lists:reverse(Acc)};
infer1(Env, [{contract, Ann, ConName, Code} | Rest], Acc) ->
%% do type inference on each contract independently.
check_scope_name_clash(Env, contract, ConName),
{Env1, Code1} = infer_contract_top(push_scope(contract, ConName, Env), contract, Code, Options),
{Env1, Code1} = infer_contract_top(push_scope(contract, ConName, Env), contract, Code),
Contract1 = {contract, Ann, ConName, Code1},
Env2 = pop_scope(Env1),
Env3 = bind_contract(Contract1, Env2),
infer1(Env3, Rest, [Contract1 | Acc], Options);
infer1(Env, [{namespace, Ann, Name, Code} | Rest], Acc, Options) ->
infer1(Env3, Rest, [Contract1 | Acc]);
infer1(Env, [{namespace, Ann, Name, Code} | Rest], Acc) ->
check_scope_name_clash(Env, namespace, Name),
{Env1, Code1} = infer_contract_top(push_scope(namespace, Name, Env), namespace, Code, Options),
{Env1, Code1} = infer_contract_top(push_scope(namespace, Name, Env), namespace, Code),
Namespace1 = {namespace, Ann, Name, Code1},
infer1(pop_scope(Env1), Rest, [Namespace1 | Acc], Options).
infer1(pop_scope(Env1), Rest, [Namespace1 | Acc]).
check_scope_name_clash(Env, Kind, Name) ->
case get_scope(Env, qname(Name)) of
@@ -581,11 +552,13 @@ check_scope_name_clash(Env, Kind, Name) ->
destroy_and_report_type_errors(Env)
end.
-spec infer_contract_top(env(), contract | namespace, [aeso_syntax:decl()], list(option())) ->
{env(), [aeso_syntax:decl()]}.
infer_contract_top(Env, Kind, Defs0, _Options) ->
-spec infer_contract_top(env(), contract | namespace, [aeso_syntax:decl()]) -> {env(), [aeso_syntax:decl()]}.
infer_contract_top(Env, Kind, Defs0) ->
Defs = desugar(Defs0),
infer_contract(Env, Kind, Defs).
{Env1, Defs1} = infer_contract(Env, Kind, Defs),
Env2 = on_current_scope(Env1, fun(Scope) -> unfold_record_types(Env1, Scope) end),
Defs2 = unfold_record_types(Env2, Defs1),
{Env2, Defs2}.
%% TODO: revisit
infer_constant({letval, Attrs,_Pattern, Type, E}) ->
@@ -624,17 +597,15 @@ infer_contract(Env, What, Defs) ->
SCCs = aeso_utils:scc(DepGraph),
%% io:format("Dependency sorted functions:\n ~p\n", [SCCs]),
{Env4, Defs1} = check_sccs(Env3, FunMap, SCCs, []),
%% Check that `init` doesn't read or write the state
check_state_dependencies(Env4, Defs1),
destroy_and_report_type_errors(Env4),
{Env4, TypeDefs ++ Decls ++ Defs1}.
-spec check_typedefs(env(), [aeso_syntax:decl()]) -> {env(), [aeso_syntax:decl()]}.
check_typedefs(Env = #env{ namespace = Ns }, Defs) ->
check_typedefs(Env, Defs) ->
create_type_errors(),
GetName = fun({type_def, _, {id, _, Name}, _, _}) -> Name end,
TypeMap = maps:from_list([ {GetName(Def), Def} || Def <- Defs ]),
DepGraph = maps:map(fun(_, Def) -> aeso_syntax_utils:used_types(Ns, Def) end, TypeMap),
DepGraph = maps:map(fun(_, Def) -> aeso_syntax_utils:used_types(Def) end, TypeMap),
SCCs = aeso_utils:scc(DepGraph),
{Env1, Defs1} = check_typedef_sccs(Env, TypeMap, SCCs, []),
destroy_and_report_type_errors(Env),
@@ -687,40 +658,6 @@ check_typedef(Env, {variant_t, Cons}) ->
check_unexpected(Xs) ->
[ type_error(X) || X <- Xs ].
check_modifiers(Env, Contracts) ->
create_type_errors(),
[ case C of
{contract, _, Con, Decls} ->
check_modifiers1(contract, Decls),
case {lists:keymember(letfun, 1, Decls),
[ D || D <- Decls, aeso_syntax:get_ann(entrypoint, D, false) ]} of
{true, []} -> type_error({contract_has_no_entrypoints, Con});
_ -> ok
end;
{namespace, _, _, Decls} -> check_modifiers1(namespace, Decls)
end || C <- Contracts ],
destroy_and_report_type_errors(Env).
-spec check_modifiers1(contract | namespace, [aeso_syntax:decl()] | aeso_syntax:decl()) -> ok.
check_modifiers1(What, Decls) when is_list(Decls) ->
_ = [ check_modifiers1(What, Decl) || Decl <- Decls ],
ok;
check_modifiers1(What, Decl) when element(1, Decl) == letfun; element(1, Decl) == fun_decl ->
Public = aeso_syntax:get_ann(public, Decl, false),
Private = aeso_syntax:get_ann(private, Decl, false),
Entrypoint = aeso_syntax:get_ann(entrypoint, Decl, false),
FunDecl = element(1, Decl) == fun_decl,
{id, _, Name} = element(3, Decl),
_ = [ type_error({proto_must_be_entrypoint, Decl}) || FunDecl, Private orelse not Entrypoint, What == contract ],
_ = [ type_error({proto_in_namespace, Decl}) || FunDecl, What == namespace ],
_ = [ type_error({init_must_be_an_entrypoint, Decl}) || not Entrypoint, Name == "init", What == contract ],
_ = [ type_error({public_modifier_in_contract, Decl}) || Public, not Private, not Entrypoint, What == contract ],
_ = [ type_error({entrypoint_in_namespace, Decl}) || Entrypoint, What == namespace ],
_ = [ type_error({private_entrypoint, Decl}) || Private, Entrypoint ],
_ = [ type_error({private_and_public, Decl}) || Private, Public ],
ok;
check_modifiers1(_, _) -> ok.
-spec check_type(env(), aeso_syntax:type()) -> aeso_syntax:type().
check_type(Env, T) ->
check_type(Env, T, 0).
@@ -791,35 +728,35 @@ check_event(Env, "event", Ann, Def) ->
check_event(_Env, _Name, _Ann, Def) -> Def.
check_event_con(Env, {constr_t, Ann, Con, Args}) ->
IsIndexed = fun(T) ->
T1 = unfold_types_in_type(Env, T),
%% `indexed` is optional but if used it has to be correctly used
case {is_word_type(T1), is_string_type(T1), aeso_syntax:get_ann(indexed, T, false)} of
{true, _, _} -> indexed;
{false, true, true} -> type_error({indexed_type_must_be_word, T, T1});
{false, true, _} -> notindexed;
{false, false, _} -> type_error({event_arg_type_word_or_string, T, T1}), error
end
end,
IsIndexed = fun(T) -> case aeso_syntax:get_ann(indexed, T, false) of
true -> indexed;
false -> notindexed
end end,
Indices = lists:map(IsIndexed, Args),
Indexed = [ T || T <- Args, IsIndexed(T) == indexed ],
NonIndexed = Args -- Indexed,
[ check_event_arg_type(Env, Ix, Type) || {Ix, Type} <- lists:zip(Indices, Args) ],
[ type_error({event_0_to_3_indexed_values, Con}) || length(Indexed) > 3 ],
[ type_error({event_0_to_1_string_values, Con}) || length(NonIndexed) > 1 ],
{constr_t, [{indices, Indices} | Ann], Con, Args}.
check_event_arg_type(Env, Ix, Type0) ->
Type = unfold_types_in_type(Env, Type0),
case Ix of
indexed -> [ type_error({indexed_type_must_be_word, Type0, Type}) || not is_word_type(Type) ];
notindexed -> [ type_error({payload_type_must_be_string, Type0, Type}) || not is_string_type(Type) ]
end.
%% Not so nice.
is_word_type({id, _, Name}) ->
lists:member(Name, ["int", "address", "hash", "bits", "bool"]);
is_word_type({app_t, _, {id, _, Name}, [_, _]}) ->
lists:member(Name, ["oracle", "oracle_query"]);
is_word_type({bytes_t, _, N}) -> N =< 32;
is_word_type({con, _, _}) -> true;
is_word_type({qcon, _, _}) -> true;
is_word_type(_) -> false.
is_string_type({id, _, "string"}) -> true;
is_string_type({bytes_t, _, N}) -> N > 32;
is_string_type(_) -> false.
-spec check_constructor_overlap(env(), aeso_syntax:con(), type()) -> ok | no_return().
@@ -856,7 +793,7 @@ check_sccs(Env = #env{}, Funs, [{acyclic, X} | SCCs], Acc) ->
end;
check_sccs(Env = #env{}, Funs, [{cyclic, Xs} | SCCs], Acc) ->
Defs = [ maps:get(X, Funs) || X <- Xs ],
{TypeSigs, Defs1} = infer_letrec(Env, Defs),
{TypeSigs, {letrec, _, Defs1}} = infer_letrec(Env, {letrec, [], Defs}),
Env1 = bind_funs(TypeSigs, Env),
check_sccs(Env1, Funs, SCCs, Defs1 ++ Acc).
@@ -898,7 +835,7 @@ check_special_funs(_, _) -> ok.
typesig_to_fun_t({type_sig, Ann, Named, Args, Res}) -> {fun_t, Ann, Named, Args, Res}.
infer_letrec(Env, Defs) ->
infer_letrec(Env, {letrec, Attrs, Defs}) ->
create_constraints(),
Funs = [{Name, fresh_uvar(A)}
|| {letfun, _, {id, A, Name}, _, _, _} <- Defs],
@@ -918,12 +855,9 @@ infer_letrec(Env, Defs) ->
TypeSigs = instantiate([Sig || {Sig, _} <- Inferred]),
NewDefs = instantiate([D || {_, D} <- Inferred]),
[print_typesig(S) || S <- TypeSigs],
{TypeSigs, NewDefs}.
{TypeSigs, {letrec, Attrs, NewDefs}}.
infer_letfun(Env0, {letfun, Attrib, Fun = {id, NameAttrib, Name}, Args, What, Body}) ->
Env = Env0#env{ stateful = aeso_syntax:get_ann(stateful, Attrib, false),
current_function = Fun },
check_unique_arg_names(Fun, Args),
infer_letfun(Env, {letfun, Attrib, {id, NameAttrib, Name}, Args, What, Body}) ->
ArgTypes = [{ArgName, check_type(Env, arg_type(T))} || {arg, _, ArgName, T} <- Args],
ExpectedType = check_type(Env, arg_type(What)),
NewBody={typed, _, _, ResultType} = check_expr(bind_vars(ArgTypes, Env), Body, ExpectedType),
@@ -934,13 +868,6 @@ infer_letfun(Env0, {letfun, Attrib, Fun = {id, NameAttrib, Name}, Args, What, Bo
{{Name, TypeSig},
{letfun, Attrib, {id, NameAttrib, Name}, NewArgs, ResultType, NewBody}}.
check_unique_arg_names(Fun, Args) ->
Name = fun({arg, _, {id, _, X}, _}) -> X end,
Names = lists:map(Name, Args),
Dups = lists:usort(Names -- lists:usort(Names)),
[ type_error({repeated_arg, Fun, Arg}) || Arg <- Dups ],
ok.
print_typesig({Name, TypeSig}) ->
?PRINT_TYPES("Inferred ~s : ~s\n", [Name, pp(TypeSig)]).
@@ -964,70 +891,14 @@ lookup_name(Env, As, Id, Options) ->
{Id, fresh_uvar(As)};
{QId, {_, Ty}} ->
Freshen = proplists:get_value(freshen, Options, false),
check_stateful(Env, Id, Ty),
Ty1 = case Ty of
{type_sig, _, _, _, _} -> freshen_type(As, typesig_to_fun_t(Ty));
_ when Freshen -> freshen_type(As, Ty);
{type_sig, _, _, _, _} -> freshen_type(typesig_to_fun_t(Ty));
_ when Freshen -> freshen_type(Ty);
_ -> Ty
end,
{set_qname(QId, Id), Ty1}
end.
check_stateful(#env{ stateful = false, current_function = Fun }, Id, Type = {type_sig, _, _, _, _}) ->
case aeso_syntax:get_ann(stateful, Type, false) of
false -> ok;
true ->
type_error({stateful_not_allowed, Id, Fun})
end;
check_stateful(_Env, _Id, _Type) -> ok.
%% Hack: don't allow passing the 'value' named arg if not stateful. This only
%% works since the user can't create functions with named arguments.
check_stateful_named_arg(#env{ stateful = false, current_function = Fun }, {id, _, "value"}, Default) ->
case Default of
{int, _, 0} -> ok;
_ -> type_error({value_arg_not_allowed, Default, Fun})
end;
check_stateful_named_arg(_, _, _) -> ok.
%% Check that `init` doesn't read or write the state
check_state_dependencies(Env, Defs) ->
Top = Env#env.namespace,
GetState = Top ++ ["state"],
SetState = Top ++ ["put"],
Init = Top ++ ["init"],
UsedNames = fun(X) -> [{Xs, Ann} || {{term, Xs}, Ann} <- aeso_syntax_utils:used(X)] end,
Funs = [ {Top ++ [Name], Fun} || Fun = {letfun, _, {id, _, Name}, _Args, _Type, _Body} <- Defs ],
Deps = maps:from_list([{Name, UsedNames(Def)} || {Name, Def} <- Funs]),
case maps:get(Init, Deps, false) of
false -> ok; %% No init, so nothing to check
_ ->
[ type_error({init_depends_on_state, state, Chain})
|| Chain <- get_call_chains(Deps, Init, GetState) ],
[ type_error({init_depends_on_state, put, Chain})
|| Chain <- get_call_chains(Deps, Init, SetState) ],
ok
end.
%% Compute all paths (not sharing intermediate nodes) from Start to Stop in Graph.
get_call_chains(Graph, Start, Stop) ->
get_call_chains(Graph, #{}, queue:from_list([{Start, [], []}]), Stop, []).
get_call_chains(Graph, Visited, Queue, Stop, Acc) ->
case queue:out(Queue) of
{empty, _} -> lists:reverse(Acc);
{{value, {Stop, Ann, Path}}, Queue1} ->
get_call_chains(Graph, Visited, Queue1, Stop, [lists:reverse([{Stop, Ann} | Path]) | Acc]);
{{value, {Node, Ann, Path}}, Queue1} ->
case maps:is_key(Node, Visited) of
true -> get_call_chains(Graph, Visited, Queue1, Stop, Acc);
false ->
Calls = maps:get(Node, Graph, []),
NewQ = queue:from_list([{New, Ann1, [{Node, Ann} | Path]} || {New, Ann1} <- Calls]),
get_call_chains(Graph, Visited#{Node => true}, queue:join(Queue1, NewQ), Stop, Acc)
end
end.
check_expr(Env, Expr, Type) ->
E = {typed, _, _, Type1} = infer_expr(Env, Expr),
unify(Env, Type1, Type, {check_expr, Expr, Type1, Type}),
@@ -1037,8 +908,6 @@ infer_expr(_Env, Body={bool, As, _}) ->
{typed, As, Body, {id, As, "bool"}};
infer_expr(_Env, Body={int, As, _}) ->
{typed, As, Body, {id, As, "int"}};
infer_expr(_Env, Body={char, As, _}) ->
{typed, As, Body, {id, As, "char"}};
infer_expr(_Env, Body={string, As, _}) ->
{typed, As, Body, {id, As, "string"}};
infer_expr(_Env, Body={bytes, As, Bin}) ->
@@ -1066,6 +935,8 @@ infer_expr(Env, Id = {Tag, As, _}) when Tag == id; Tag == qid ->
infer_expr(Env, Id = {Tag, As, _}) when Tag == con; Tag == qcon ->
{QName, Type} = lookup_name(Env, As, Id, [freshen]),
{typed, As, QName, Type};
infer_expr(Env, {unit, As}) ->
infer_expr(Env, {tuple, As, []});
infer_expr(Env, {tuple, As, Cpts}) ->
NewCpts = [infer_expr(Env, C) || C <- Cpts],
CptTypes = [T || {typed, _, _, T} <- NewCpts],
@@ -1119,7 +990,7 @@ infer_expr(Env, {record, Attrs, Fields}) ->
constrain([ #record_create_constraint{
record_t = RecordType1,
fields = [ FieldName || {field, _, [{proj, _, FieldName}], _} <- Fields ],
context = Attrs } || not Env#env.in_pattern ] ++
context = Attrs } ] ++
[begin
[{proj, _, FieldName}] = LV,
#field_constraint{
@@ -1184,17 +1055,10 @@ infer_expr(Env, {lam, Attrs, Args, Body}) ->
{'case', _, {typed, _, {tuple, _, NewArgPatterns}, _}, NewBody} =
infer_case(Env, Attrs, {tuple, Attrs, ArgPatterns}, {tuple_t, Attrs, ArgTypes}, Body, ResultType),
NewArgs = [{arg, As, NewPat, NewT} || {typed, As, NewPat, NewT} <- NewArgPatterns],
{typed, Attrs, {lam, Attrs, NewArgs, NewBody}, {fun_t, Attrs, [], ArgTypes, ResultType}};
infer_expr(Env, Let = {letval, Attrs, _, _, _}) ->
type_error({missing_body_for_let, Attrs}),
infer_expr(Env, {block, Attrs, [Let, abort_expr(Attrs, "missing body")]});
infer_expr(Env, Let = {letfun, Attrs, _, _, _, _}) ->
type_error({missing_body_for_let, Attrs}),
infer_expr(Env, {block, Attrs, [Let, abort_expr(Attrs, "missing body")]}).
{typed, Attrs, {lam, Attrs, NewArgs, NewBody}, {fun_t, Attrs, [], ArgTypes, ResultType}}.
infer_named_arg(Env, NamedArgs, {named_arg, Ann, Id, E}) ->
CheckedExpr = {typed, _, _, ArgType} = infer_expr(Env, E),
check_stateful_named_arg(Env, Id, E),
add_named_argument_constraint(
#named_argument_constraint{
args = NamedArgs,
@@ -1255,7 +1119,7 @@ infer_case(Env, Attrs, Pattern, ExprType, Branch, SwitchType) ->
[] -> ok;
Nonlinear -> type_error({non_linear_pattern, Pattern, lists:usort(Nonlinear)})
end,
NewEnv = bind_vars([{Var, fresh_uvar(Ann)} || Var = {id, Ann, _} <- Vars], Env#env{ in_pattern = true }),
NewEnv = bind_vars([{Var, fresh_uvar(Ann)} || Var = {id, Ann, _} <- Vars], Env),
NewPattern = {typed, _, _, PatType} = infer_expr(NewEnv, Pattern),
NewBranch = check_expr(NewEnv, Branch, SwitchType),
unify(Env, PatType, ExprType, {case_pat, Pattern, PatType, ExprType}),
@@ -1264,18 +1128,19 @@ infer_case(Env, Attrs, Pattern, ExprType, Branch, SwitchType) ->
%% NewStmts = infer_block(Env, Attrs, Stmts, BlockType)
infer_block(_Env, Attrs, [], BlockType) ->
error({impossible, empty_block, Attrs, BlockType});
infer_block(Env, _, [E], BlockType) ->
[check_expr(Env, E, BlockType)];
infer_block(Env, Attrs, [Def={letfun, Ann, _, _, _, _}|Rest], BlockType) ->
{{Name, TypeSig}, LetFun} = infer_letfun(Env, Def),
FunT = freshen_type(Ann, typesig_to_fun_t(TypeSig)),
NewE = bind_var({id, Ann, Name}, FunT, Env),
[LetFun|infer_block(NewE, Attrs, Rest, BlockType)];
infer_block(Env, Attrs, [Def={letfun, _, _, _, _, _}|Rest], BlockType) ->
NewDef = infer_letfun(Env, Def),
[NewDef|infer_block(Env, Attrs, Rest, BlockType)];
infer_block(Env, Attrs, [Def={letrec, _, _}|Rest], BlockType) ->
NewDef = infer_letrec(Env, Def),
[NewDef|infer_block(Env, Attrs, Rest, BlockType)];
infer_block(Env, _, [{letval, Attrs, Pattern, Type, E}|Rest], BlockType) ->
NewE = {typed, _, _, PatType} = infer_expr(Env, {typed, Attrs, E, arg_type(Type)}),
{'case', _, NewPattern, {typed, _, {block, _, NewRest}, _}} =
infer_case(Env, Attrs, Pattern, PatType, {block, Attrs, Rest}, BlockType),
[{letval, Attrs, NewPattern, Type, NewE}|NewRest];
infer_block(Env, _, [E], BlockType) ->
[check_expr(Env, E, BlockType)];
infer_block(Env, Attrs, [E|Rest], BlockType) ->
[infer_expr(Env, E)|infer_block(Env, Attrs, Rest, BlockType)].
@@ -1311,13 +1176,8 @@ infer_prefix({IntOp,As}) when IntOp =:= '-' ->
Int = {id, As, "int"},
{fun_t, As, [], [Int], Int}.
abort_expr(Ann, Str) ->
{app, Ann, {id, Ann, "abort"}, [{string, Ann, Str}]}.
free_vars({int, _, _}) ->
[];
free_vars({char, _, _}) ->
[];
free_vars({string, _, _}) ->
[];
free_vars({bool, _, _}) ->
@@ -1408,17 +1268,14 @@ when_option(Opt, Do) ->
create_constraints() ->
create_named_argument_constraints(),
create_bytes_constraints(),
create_field_constraints().
solve_constraints(Env) ->
solve_named_argument_constraints(Env),
solve_bytes_constraints(Env),
solve_field_constraints(Env).
destroy_and_report_unsolved_constraints(Env) ->
destroy_and_report_unsolved_field_constraints(Env),
destroy_and_report_unsolved_bytes_constraints(Env),
destroy_and_report_unsolved_named_argument_constraints(Env).
%% -- Named argument constraints --
@@ -1467,37 +1324,6 @@ destroy_and_report_unsolved_named_argument_constraints(Env) ->
destroy_named_argument_constraints(),
ok.
%% -- Bytes constraints --
-type byte_constraint() :: {is_bytes, utype()}.
create_bytes_constraints() ->
ets_new(bytes_constraints, [bag]).
get_bytes_constraints() ->
ets_tab2list(bytes_constraints).
-spec add_bytes_constraint(byte_constraint()) -> true.
add_bytes_constraint(Constraint) ->
ets_insert(bytes_constraints, Constraint).
solve_bytes_constraints(_Env) ->
ok.
destroy_bytes_constraints() ->
ets_delete(bytes_constraints).
destroy_and_report_unsolved_bytes_constraints(Env) ->
[ check_bytes_constraint(Env, C) || C <- get_bytes_constraints() ],
destroy_bytes_constraints().
check_bytes_constraint(Env, {is_bytes, Type}) ->
Type1 = unfold_types_in_type(Env, instantiate(Type)),
case Type1 of
{bytes_t, _, _} -> ok;
_ -> type_error({cannot_unify, Type1, {bytes_t, [], any}, {at, Type}})
end.
%% -- Field constraints --
create_field_constraints() ->
@@ -1907,10 +1733,6 @@ occurs_check1(R, {tuple_t, _, Ts}) ->
occurs_check(R, Ts);
occurs_check1(R, {named_arg_t, _, _, T, _}) ->
occurs_check(R, T);
occurs_check1(R, {record_t, Fields}) ->
occurs_check(R, Fields);
occurs_check1(R, {field_t, _, _, T}) ->
occurs_check(R, T);
occurs_check1(R, [H | T]) ->
occurs_check(R, H) orelse occurs_check(R, T);
occurs_check1(_, []) -> false.
@@ -1924,31 +1746,26 @@ create_freshen_tvars() ->
destroy_freshen_tvars() ->
ets_delete(freshen_tvars).
freshen_type(Ann, Type) ->
freshen_type(Type) ->
create_freshen_tvars(),
Type1 = freshen(Ann, Type),
Type1 = freshen(Type),
destroy_freshen_tvars(),
Type1.
freshen(Type) ->
freshen(aeso_syntax:get_ann(Type), Type).
freshen(Ann, {tvar, _, Name}) ->
freshen({tvar, As, Name}) ->
NewT = case ets_lookup(freshen_tvars, Name) of
[] -> fresh_uvar(Ann);
[{Name, T}] -> T
[] ->
fresh_uvar(As);
[{Name, T}] ->
T
end,
ets_insert(freshen_tvars, {Name, NewT}),
NewT;
freshen(Ann, {bytes_t, _, any}) ->
X = fresh_uvar(Ann),
add_bytes_constraint({is_bytes, X}),
X;
freshen(Ann, T) when is_tuple(T) ->
list_to_tuple(freshen(Ann, tuple_to_list(T)));
freshen(Ann, [A | B]) ->
[freshen(Ann, A) | freshen(Ann, B)];
freshen(_, X) ->
freshen(T) when is_tuple(T) ->
list_to_tuple(freshen(tuple_to_list(T)));
freshen([A|B]) ->
[freshen(A)|freshen(B)];
freshen(X) ->
X.
%% Dereferences all uvars and replaces the uninstantiated ones with a
@@ -1957,8 +1774,8 @@ instantiate(E) ->
instantiate1(dereference(E)).
instantiate1({uvar, Attr, R}) ->
Next = proplists:get_value(next, ets_lookup(type_vars, next), 0),
TVar = {tvar, Attr, "'" ++ integer_to_tvar(Next)},
Next = proplists:get_value(next, ets_lookup(type_vars, next), 1),
TVar = {tvar, Attr, "'" ++ integer_to_list(Next)},
ets_insert(type_vars, [{next, Next + 1}, {R, TVar}]),
TVar;
instantiate1({fun_t, Ann, Named, Args, Ret}) ->
@@ -1978,12 +1795,6 @@ instantiate1([A|B]) ->
instantiate1(X) ->
X.
integer_to_tvar(X) when X < 26 ->
[$a + X];
integer_to_tvar(X) ->
[integer_to_tvar(X div 26)] ++ [$a + (X rem 26)].
%% Save unification failures for error messages.
cannot_unify(A, B, When) ->
@@ -1996,7 +1807,7 @@ create_type_errors() ->
ets_new(type_errors, [bag]).
destroy_and_report_type_errors(Env) ->
Errors = lists:reverse(ets_tab2list(type_errors)),
Errors = ets_tab2list(type_errors),
%% io:format("Type errors now: ~p\n", [Errors]),
PPErrors = [ pp_error(unqualify(Env, Err)) || Err <- Errors ],
ets_delete(type_errors),
@@ -2106,73 +1917,16 @@ pp_error({duplicate_definition, Name, Locs}) ->
pp_error({duplicate_scope, Kind, Name, OtherKind, L}) ->
io_lib:format("The ~p ~s (at ~s) has the same name as a ~p at ~s\n",
[Kind, pp(Name), pp_loc(Name), OtherKind, pp_loc(L)]);
pp_error({include, _, {string, Pos, Name}}) ->
pp_error({include, {string, Pos, Name}}) ->
io_lib:format("Include of '~s' at ~s\nnot allowed, include only allowed at top level.\n",
[binary_to_list(Name), pp_loc(Pos)]);
pp_error({namespace, _Pos, {con, Pos, Name}, _Def}) ->
io_lib:format("Nested namespace not allowed\nNamespace '~s' at ~s not defined at top level.\n",
[Name, pp_loc(Pos)]);
pp_error({repeated_arg, Fun, Arg}) ->
io_lib:format("Repeated argument ~s to function ~s (at ~s).\n",
[Arg, pp(Fun), pp_loc(Fun)]);
pp_error({stateful_not_allowed, Id, Fun}) ->
io_lib:format("Cannot reference stateful function ~s (at ~s)\nin the definition of non-stateful function ~s.\n",
[pp(Id), pp_loc(Id), pp(Fun)]);
pp_error({value_arg_not_allowed, Value, Fun}) ->
io_lib:format("Cannot pass non-zero value argument ~s (at ~s)\nin the definition of non-stateful function ~s.\n",
[pp_expr("", Value), pp_loc(Value), pp(Fun)]);
pp_error({init_depends_on_state, Which, [_Init | Chain]}) ->
WhichCalls = fun("put") -> ""; ("state") -> ""; (_) -> ", which calls" end,
io_lib:format("The init function should return the initial state as its result and cannot ~s the state,\nbut it calls\n~s",
[if Which == put -> "write"; true -> "read" end,
[ io_lib:format(" - ~s (at ~s)~s\n", [Fun, pp_loc(Ann), WhichCalls(Fun)])
|| {[_, Fun], Ann} <- Chain]]);
pp_error({missing_body_for_let, Ann}) ->
io_lib:format("Let binding at ~s must be followed by an expression\n", [pp_loc(Ann)]);
pp_error({public_modifier_in_contract, Decl}) ->
Decl1 = mk_entrypoint(Decl),
io_lib:format("Use 'entrypoint' instead of 'function' for public function ~s (at ~s):\n~s\n",
[pp_expr("", element(3, Decl)), pp_loc(Decl),
prettypr:format(prettypr:nest(2, aeso_pretty:decl(Decl1)))]);
pp_error({init_must_be_an_entrypoint, Decl}) ->
Decl1 = mk_entrypoint(Decl),
io_lib:format("The init function (at ~s) must be an entrypoint:\n~s\n",
[pp_loc(Decl),
prettypr:format(prettypr:nest(2, aeso_pretty:decl(Decl1)))]);
pp_error({proto_must_be_entrypoint, Decl}) ->
Decl1 = mk_entrypoint(Decl),
io_lib:format("Use 'entrypoint' for declaration of ~s (at ~s):\n~s\n",
[pp_expr("", element(3, Decl)), pp_loc(Decl),
prettypr:format(prettypr:nest(2, aeso_pretty:decl(Decl1)))]);
pp_error({proto_in_namespace, Decl}) ->
io_lib:format("Namespaces cannot contain function prototypes (at ~s).\n",
[pp_loc(Decl)]);
pp_error({entrypoint_in_namespace, Decl}) ->
io_lib:format("Namespaces cannot contain entrypoints (at ~s). Use 'function' instead.\n",
[pp_loc(Decl)]);
pp_error({private_entrypoint, Decl}) ->
io_lib:format("The entrypoint ~s (at ~s) cannot be private. Use 'function' instead.\n",
[pp_expr("", element(3, Decl)), pp_loc(Decl)]);
pp_error({private_and_public, Decl}) ->
io_lib:format("The function ~s (at ~s) cannot be both public and private.\n",
[pp_expr("", element(3, Decl)), pp_loc(Decl)]);
pp_error({contract_has_no_entrypoints, Con}) ->
io_lib:format("The contract ~s (at ~s) has no entrypoints. Since Sophia version 3.2, public\n"
"contract functions must be declared with the 'entrypoint' keyword instead of\n"
"'function'.\n", [pp_expr("", Con), pp_loc(Con)]);
pp_error({unbound_type, Type}) ->
io_lib:format("Unbound type ~s (at ~s).\n", [pp_type("", Type), pp_loc(Type)]);
pp_error(Err) ->
io_lib:format("Unknown error: ~p\n", [Err]).
mk_entrypoint(Decl) ->
Ann = [entrypoint | lists:keydelete(public, 1,
lists:keydelete(private, 1,
aeso_syntax:get_ann(Decl))) -- [public, private]],
aeso_syntax:set_ann(Ann, Decl).
pp_when({todo, What}) -> io_lib:format("[TODO] ~p\n", [What]);
pp_when({at, Ann}) -> io_lib:format("at ~s\n", [pp_loc(Ann)]);
pp_when({check_typesig, Name, Inferred, Given}) ->
io_lib:format("when checking the definition of ~s\n"
" inferred type: ~s\n"
@@ -2323,11 +2077,8 @@ pp({uvar, _, Ref}) ->
["?u" | integer_to_list(erlang:phash2(Ref, 16384)) ];
pp({tvar, _, Name}) ->
Name;
pp({tuple_t, _, []}) ->
"unit";
pp({tuple_t, _, Cpts}) ->
["(", string:join(lists:map(fun pp/1, Cpts), " * "), ")"];
pp({bytes_t, _, any}) -> "bytes(_)";
["(", pp(Cpts), ")"];
pp({bytes_t, _, Len}) ->
["bytes(", integer_to_list(Len), ")"];
pp({app_t, _, T, []}) ->
@@ -2339,9 +2090,7 @@ pp({named_arg_t, _, Name, Type, Default}) ->
pp({fun_t, _, Named = {uvar, _, _}, As, B}) ->
["(", pp(Named), " | ", pp(As), ") => ", pp(B)];
pp({fun_t, _, Named, As, B}) when is_list(Named) ->
["(", pp(Named ++ As), ") => ", pp(B)];
pp(Other) ->
io_lib:format("~p", [Other]).
["(", pp(Named ++ As), ") => ", pp(B)].
%% -- Pre-type checking desugaring -------------------------------------------
src/aeso_ast_to_fcode.erl
-1450
View File
File diff suppressed because it is too large Load Diff
src/aeso_ast_to_icode.erl
+48 -78
View File
@@ -21,19 +21,18 @@ convert_typed(TypedTree, Options) ->
{contract, _, {con, _, Con}, _} -> Con;
_ -> gen_error(last_declaration_must_be_contract)
end,
NewIcode = aeso_icode:set_name(Name, aeso_icode:new(Options)),
Icode = code(TypedTree, NewIcode, Options),
Icode = code(TypedTree, aeso_icode:set_name(Name, aeso_icode:new(Options))),
deadcode_elimination(Icode).
code([{contract, _Attribs, Con, Code}|Rest], Icode, Options) ->
code([{contract, _Attribs, Con, Code}|Rest], Icode) ->
NewIcode = contract_to_icode(Code, aeso_icode:set_namespace(Con, Icode)),
code(Rest, NewIcode, Options);
code([{namespace, _Ann, Name, Code}|Rest], Icode, Options) ->
%% TODO: nested namespaces
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, Options);
code([], Icode, Options) ->
add_default_init_function(add_builtins(Icode), Options).
code(Rest, NewIcode);
code([], Icode) ->
add_default_init_function(add_builtins(Icode)).
%% Generate error on correct format.
@@ -41,12 +40,10 @@ gen_error(Error) ->
error({code_errors, [Error]}).
%% Create default init function (only if state is unit).
add_default_init_function(Icode = #{functions := Funs, state_type := State}, Options) ->
NoCode = proplists:get_value(no_code, Options, false),
add_default_init_function(Icode = #{functions := Funs, state_type := State}) ->
{_, _, QInit} = aeso_icode:qualify({id, [], "init"}, Icode),
case lists:keymember(QInit, 1, Funs) of
true -> Icode;
false when NoCode -> Icode;
false when State /= {tuple, []} ->
gen_error(missing_init_function);
false ->
@@ -105,6 +102,13 @@ contract_to_icode([{letfun, Attrib, Name, Args, _What, Body={typed,_,_,T}}|Rest]
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([{fun_decl, _, _, _} | Code], Icode) ->
contract_to_icode(Code, Icode);
@@ -144,11 +148,10 @@ ast_body(?qid_app([Con, "Chain", "event"], [Event], _, _), Icode = #{ contract_n
ast_body(?qid_app(["Chain", "balance"], [Address], _, _), Icode) ->
#prim_balance{ address = ast_body(Address, Icode) };
ast_body(?qid_app(["Chain", "block_hash"], [Height], _, _), Icode) ->
builtin_call(block_hash, [ast_body(Height, Icode)]);
#prim_block_hash{ height = 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;
@@ -176,9 +179,8 @@ ast_body({qid, _, [Con, "put"]}, #{ contract_name := Con }) ->
%% Abort
ast_body(?id_app("abort", [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)]);
#funcall{ function = #var_ref{ name = {builtin, abort} },
args = [ast_body(String, Icode)] };
%% Authentication
ast_body({qid, _, ["Auth", "tx_hash"]}, _Icode) ->
@@ -222,17 +224,6 @@ 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'});
@@ -263,21 +254,21 @@ ast_body(?qid_app(["AENS", "preclaim"], Args, _, _), Icode) ->
[word, word, sign_t()], {tuple, []});
ast_body(?qid_app(["AENS", "claim"], Args, _, _), Icode) ->
{Sign, [Addr, Name, Salt, NameFee]} = get_signature_arg(Args),
{Sign, [Addr, Name, Salt]} = get_signature_arg(Args),
prim_call(?PRIM_CALL_AENS_CLAIM, #integer{value = 0},
[ast_body(Addr, Icode), ast_body(Name, Icode), ast_body(Salt, Icode), ast_body(Sign, Icode), ast_body(NameFee, Icode)],
[word, string, word, sign_t(), word], {tuple, []});
[ast_body(Addr, Icode), ast_body(Name, Icode), ast_body(Salt, Icode), ast_body(Sign, Icode)],
[word, string, word, sign_t()], {tuple, []});
ast_body(?qid_app(["AENS", "transfer"], Args, _, _), Icode) ->
{Sign, [FromAddr, ToAddr, Name]} = get_signature_arg(Args),
{Sign, [FromAddr, ToAddr, NameHash]} = get_signature_arg(Args),
prim_call(?PRIM_CALL_AENS_TRANSFER, #integer{value = 0},
[ast_body(FromAddr, Icode), ast_body(ToAddr, Icode), ast_body(Name, Icode), ast_body(Sign, Icode)],
[ast_body(FromAddr, Icode), ast_body(ToAddr, Icode), ast_body(NameHash, Icode), ast_body(Sign, Icode)],
[word, word, word, sign_t()], {tuple, []});
ast_body(?qid_app(["AENS", "revoke"], Args, _, _), Icode) ->
{Sign, [Addr, Name]} = get_signature_arg(Args),
{Sign, [Addr, NameHash]} = get_signature_arg(Args),
prim_call(?PRIM_CALL_AENS_REVOKE, #integer{value = 0},
[ast_body(Addr, Icode), ast_body(Name, Icode), ast_body(Sign, Icode)],
[ast_body(Addr, Icode), ast_body(NameHash, Icode), ast_body(Sign, Icode)],
[word, word, sign_t()], {tuple, []});
ast_body({qid, _, ["AENS", "resolve"]}, _Icode) -> gen_error({underapplied_primitive, 'AENS.resolve'});
@@ -374,11 +365,13 @@ ast_body(?qid_app(["String", "blake2b"], [String], _, _), Icode) ->
%% Strings
%% -- String length
ast_body(?qid_app(["String", "length"], [String], _, _), Icode) ->
builtin_call(string_length, [ast_body(String, Icode)]);
#funcall{ function = #var_ref{ name = {builtin, string_length} },
args = [ast_body(String, Icode)] };
%% -- String concat
ast_body(?qid_app(["String", "concat"], [String1, String2], _, _), Icode) ->
builtin_call(string_concat, [ast_body(String1, Icode), ast_body(String2, Icode)]);
#funcall{ function = #var_ref{ name = {builtin, string_concat} },
args = [ast_body(String1, Icode), ast_body(String2, Icode)] };
%% -- String hash (sha3)
ast_body(?qid_app(["String", "sha3"], [String], _, _), Icode) ->
@@ -417,19 +410,6 @@ ast_body(?qid_app(["Int", "to_str"], [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) ->
@@ -477,7 +457,7 @@ 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>> = aeb_aevm_abi:function_type_hash(list_to_binary(FunName), ArgType, OutType),
<<TypeHash:256>> = aeb_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{
@@ -532,8 +512,6 @@ 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) ->
@@ -601,30 +579,19 @@ 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)};
OtherType ->
string ->
Neg = case Op of
'==' -> fun(X) -> X end;
'!=' -> fun(X) -> #unop{ op = '!', rand = X } end;
_ -> gen_error({cant_compare, Ann, Op, Type})
end,
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)
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})
end;
ast_binop('++', _, A, B, Icode) ->
builtin_call(list_concat, [ast_body(A, Icode), ast_body(B, Icode)]);
#funcall{ function = #var_ref{ name = {builtin, list_concat} },
args = [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)}.
@@ -691,7 +658,7 @@ prim_call(Prim, Amount, Args, ArgTypes, OutType) ->
true ->
PrimBin = binary:encode_unsigned(Prim),
ArgType = {tuple, ArgTypes},
<<TH:256>> = aeb_aevm_abi:function_type_hash(PrimBin, ArgType, OutType),
<<TH:256>> = aeb_abi:function_type_hash(PrimBin, ArgType, OutType),
TH;
false ->
0
@@ -730,8 +697,8 @@ ast_typerep({qid, _, Name}, Icode) ->
ast_typerep({con, _, _}, _) ->
word; %% Contract type
ast_typerep({bytes_t, _, Len}, _) ->
bytes_t(Len);
ast_typerep({app_t, _, {I, _, Name}, Args}, Icode) when I =:= id; I =:= qid ->
{bytes, Len};
ast_typerep({app_t, _, {id, _, Name}, Args}, Icode) ->
ArgReps = [ ast_typerep(Arg, Icode) || Arg <- Args ],
lookup_type_id(Name, ArgReps, Icode);
ast_typerep({tvar,_,A}, #{ type_vars := TypeVars }) ->
@@ -759,8 +726,7 @@ ttl_t(Icode) ->
ast_typerep({qid, [], ["Chain", "ttl"]}, Icode).
sign_t() -> bytes_t(64).
bytes_t(Len) when Len =< 32 -> word;
bytes_t(Len) -> {tuple, lists:duplicate((31 + Len) div 32, word)}.
bytes_t(Len) -> {bytes, Len}.
get_signature_arg(Args0) ->
NamedArgs = [Arg || Arg = {named_arg, _, _, _} <- Args0],
@@ -794,6 +760,8 @@ type_value({list, A}) ->
type_value({tuple, As}) ->
#tuple{ cpts = [#integer{ value = ?TYPEREP_TUPLE_TAG },
#list{ elems = [ type_value(A) || A <- As ] }] };
type_value({bytes, Len}) ->
#tuple{ cpts = [#integer{ value = ?TYPEREP_BYTES_TAG }, #integer{ value = Len }] };
type_value({variant, Cs}) ->
#tuple{ cpts = [#integer{ value = ?TYPEREP_VARIANT_TAG },
#list{ elems = [ #list{ elems = [ type_value(A) || A <- As ] } || As <- Cs ] }] };
@@ -820,11 +788,13 @@ 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).
%% A function is private if marked 'private' or 'internal', 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
proplists:get_value(private, Ann, false) orelse
proplists:get_value(internal, Ann, false) orelse
MainContract /= CurrentNamespace.
%% -------------------------------------------------------------------
src/aeso_builtins.erl
+18 -95
View File
@@ -44,9 +44,7 @@ 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) ->
@@ -62,14 +60,12 @@ 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, operand(Ptr), [{{tuple, [v(Var)]}, Body}]}).
-define(DEREF(Var, Ptr, Body), {switch, v(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)).
@@ -95,6 +91,12 @@ 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) | aeb_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} ->
@@ -115,12 +117,11 @@ check_event_type(EvtName, Ix, Type, Icode) ->
catch _:_ ->
error({EvtName, could_not_resolve_type, Type})
end,
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})
case {Ix, VMType} of
{indexed, word} -> ok;
{notindexed, string} -> 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}) ->
@@ -130,8 +131,6 @@ 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());
@@ -159,9 +158,6 @@ 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.
@@ -175,23 +171,16 @@ builtin_event(EventT) ->
VIx = fun(Ix) -> v(lists:concat(["v", Ix])) end,
ArgPats = fun(Ts) -> [ VIx(Ix) || Ix <- lists:seq(0, length(Ts) - 1) ] end,
Payload = %% Should put data ptr, length on stack.
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)}]}
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
end,
Ix =
fun({bytes_t, _, N}, V) when N < 32 -> ?BSR(V, 32 - N);
(_, V) -> V end,
Clause =
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)}
Indexed = [ Var || {Var, {indexed, _Type}} <- lists:zip(ArgPats(Types), IxTypes) ],
EvtIndex = {unop, 'sha3', str_to_icode(Con)},
{event, lists:reverse(Indexed) ++ [EvtIndex], Payload(ArgPats(Types) -- Indexed)}
end,
Pat = fun(Tag, Types) -> {tuple, [{integer, Tag} | ArgPats(Types)]} end,
@@ -212,17 +201,6 @@ 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),
@@ -459,10 +437,6 @@ 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),
@@ -497,57 +471,6 @@ 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
+165 -253
View File
@@ -12,16 +12,12 @@
, file/2
, from_string/2
, check_call/4
, create_calldata/3 %% deprecated
, create_calldata/4
, create_calldata/3
, version/0
, sophia_type_to_typerep/1
, to_sophia_value/4 %% deprecated, need a backend
, to_sophia_value/4
, to_sophia_value/5
, decode_calldata/3 %% deprecated
, decode_calldata/4
, parse/2
, add_include_path/2
, decode_calldata/3
]).
-include_lib("aebytecode/include/aeb_opcodes.hrl").
@@ -35,8 +31,6 @@
| pp_icode
| pp_assembler
| pp_bytecode
| no_code
| {backend, aevm | fate}
| {include, {file_system, [string()]} |
{explicit_files, #{string() => binary()}}}
| {src_file, string()}.
@@ -67,11 +61,12 @@ version() ->
-spec file(string()) -> {ok, map()} | {error, binary()}.
file(Filename) ->
file(Filename, []).
Dir = filename:dirname(Filename),
{ok, Cwd} = file:get_cwd(),
file(Filename, [{include, {file_system, [Cwd, Dir]}}]).
-spec file(string(), options()) -> {ok, map()} | {error, binary()}.
file(File, Options0) ->
Options = add_include_path(File, Options0),
file(File, Options) ->
case read_contract(File) of
{ok, Bin} -> from_string(Bin, [{src_file, File} | Options]);
{error, Error} ->
@@ -79,24 +74,24 @@ file(File, Options0) ->
{error, join_errors("File errors", [ErrorString], fun(E) -> E end)}
end.
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) ->
from_string(ContractBin, Options) when is_binary(ContractBin) ->
from_string(binary_to_list(ContractBin), Options);
from_string(ContractString, Options) ->
try
from_string1(Backend, ContractString, Options)
#{icode := Icode} = string_to_icode(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 >>,
pp_bytecode(ByteCode, Options),
{ok, Version} = version(),
{ok, #{byte_code => ByteCode,
compiler_version => Version,
contract_source => ContractString,
type_info => TypeInfo
}}
catch
%% The compiler errors.
error:{parse_errors, Errors} ->
@@ -109,54 +104,18 @@ from_string(Backend, ContractString, Options) ->
%% 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 >>,
pp_bytecode(ByteCode, Options),
{ok, Version} = version(),
{ok, #{byte_code => ByteCode,
compiler_version => Version,
contract_source => ContractString,
type_info => TypeInfo,
abi_version => aeb_aevm_abi:abi_version()
}};
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,
abi_version => aeb_fate_abi:abi_version()
}}.
-spec string_to_code(string(), options()) -> map().
string_to_code(ContractString, Options) ->
-spec string_to_icode(string(), [option()]) -> map().
string_to_icode(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.
Icode = ast_to_icode(TypedAst, Options),
pp_icode(Icode, Options),
#{ typed_ast => TypedAst,
type_env => TypeEnv,
icode => Icode }.
join_errors(Prefix, Errors, Pfun) ->
Ess = [ Pfun(E) || E <- Errors ],
@@ -171,15 +130,14 @@ join_errors(Prefix, Errors, Pfun) ->
%% terms for the arguments.
%% 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()}
-spec check_call(string(), string(), [string()], options()) -> {ok, string(), {[Type], Type}, [term()]} | {error, term()}
when Type :: term().
check_call(Source, "init" = FunName, Args, Options) ->
case check_call1(Source, FunName, Args, Options) of
PatchFun = fun(T) -> {tuple, [typerep, T]} end,
case check_call(Source, FunName, Args, Options, PatchFun) of
Err = {error, _} when Args == [] ->
%% Try with default init-function
case check_call1(insert_init_function(Source, Options), FunName, Args, Options) of
case check_call(insert_init_function(Source, Options), FunName, Args, Options, PatchFun) of
{error, _} -> Err; %% The first error is most likely better...
Res -> Res
end;
@@ -187,46 +145,27 @@ check_call(Source, "init" = FunName, Args, Options) ->
Res
end;
check_call(Source, FunName, Args, Options) ->
check_call1(Source, FunName, Args, Options).
PatchFun = fun(T) -> T end,
check_call(Source, FunName, Args, Options, PatchFun).
check_call1(ContractString0, FunName, Args, Options) ->
check_call(ContractString0, FunName, Args, Options, PatchFun) ->
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
%% First check the contract without the __call function
#{} = string_to_icode(ContractString0, Options),
ContractString = insert_call_function(ContractString0, FunName, Args, Options),
#{typed_ast := TypedAst,
icode := Icode} = string_to_icode(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) ],
{ok, FunName, {ArgVMTypes, PatchFun(RetVMType)}, ArgTerms}
catch
error:{parse_errors, Errors} ->
{error, join_errors("Parse errors", Errors, fun (E) -> E end)};
@@ -240,32 +179,16 @@ check_call1(ContractString0, FunName, Args, Options) ->
fun (E) -> io_lib:format("~p", [E]) end)}
end.
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) ->
-spec insert_call_function(string(), string(), [string()], options()) -> string().
insert_call_function(Code, 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"
"function __call() = ", FunName, "(", string:join(Args, ","), ")\n"
]).
-spec insert_init_function(string(), options()) -> string().
@@ -275,7 +198,7 @@ insert_init_function(Code, Options) ->
lists:flatten(
[ Code,
"\n\n",
lists:duplicate(Ind, " "), "entrypoint init() = ()\n"
lists:duplicate(Ind, " "), "function init() = ()\n"
]).
last_contract_indent(Decls) ->
@@ -287,60 +210,38 @@ last_contract_indent(Decls) ->
-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}]).
to_sophia_value(ContractString, Fun, ResType, Data, []).
-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 proplists:get_value(backend, Options, aevm) of
aevm ->
case aeb_heap:from_binary(string, Data) of
{ok, Err} -> {ok, {app, [], {id, [], "abort"}, [{string, [], Err}]}};
{error, _} = Err -> Err
end;
fate ->
Err = aeb_fate_encoding:deserialize(Data),
{ok, {app, [], {id, [], "abort"}, [{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;
to_sophia_value(ContractString, FunName, ok, Data, Options0) ->
Options = [no_code | Options0],
to_sophia_value(ContractString, FunName, ok, Data, Options) ->
try
Code = string_to_code(ContractString, Options),
#{ typed_ast := TypedAst, type_env := TypeEnv} = Code,
#{ typed_ast := TypedAst,
type_env := TypeEnv,
icode := Icode } = string_to_icode(ContractString, Options),
{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)}
VmType = aeso_ast_to_icode:ast_typerep(Type, Icode),
case aeb_heap:from_binary(VmType, Data) of
{ok, VmValue} ->
try
{ok, translate_vm_value(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;
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
{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
catch
error:{parse_errors, Errors} ->
@@ -355,91 +256,101 @@ to_sophia_value(ContractString, FunName, ok, Data, Options0) ->
fun (E) -> io_lib:format("~p", [E]) end)}
end.
address_literal(Type, N) -> {Type, [], <<N:256>>}.
%% TODO: somewhere else
-spec translate_vm_value(aeb_aevm_data:type(), aeso_syntax:type(), aeb_aevm_data:data()) -> aeso_syntax:expr().
translate_vm_value(word, {id, _, "address"}, N) -> address_literal(account_pubkey, N);
translate_vm_value(word, {app_t, _, {id, _, "oracle"}, _}, N) -> address_literal(oracle_pubkey, N);
translate_vm_value(word, {app_t, _, {id, _, "oracle_query"}, _}, N) -> address_literal(oracle_query_id, N);
translate_vm_value(word, {con, _, _Name}, N) -> address_literal(contract_pubkey, N);
translate_vm_value(word, {id, _, "int"}, N) -> {int, [], N};
translate_vm_value(word, {id, _, "bits"}, N) -> error({todo, bits, N});
translate_vm_value(word, {id, _, "bool"}, N) -> {bool, [], N /= 0};
translate_vm_value({bytes, Len}, {bytes_t, _, Len}, Val) when Len =< 32 ->
{bytes, [], <<Val:Len/unit:8>>};
translate_vm_value({bytes, Len}, {bytes_t, _, Len}, Val) ->
{bytes, [], binary:part(<< <<W:32/unit:8>> || W <- tuple_to_list(Val) >>, 0, Len)};
translate_vm_value(string, {id, _, "string"}, S) -> {string, [], S};
translate_vm_value({list, VmType}, {app_t, _, {id, _, "list"}, [Type]}, List) ->
{list, [], [translate_vm_value(VmType, Type, X) || X <- List]};
translate_vm_value({option, VmType}, {app_t, _, {id, _, "option"}, [Type]}, Val) ->
case Val of
none -> {con, [], "None"};
{some, X} -> {app, [], {con, [], "Some"}, [translate_vm_value(VmType, Type, X)]}
end;
translate_vm_value({variant, [[], [VmType]]}, {app_t, _, {id, _, "option"}, [Type]}, Val) ->
case Val of
{variant, 0, []} -> {con, [], "None"};
{variant, 1, [X]} -> {app, [], {con, [], "Some"}, [translate_vm_value(VmType, Type, X)]}
end;
translate_vm_value({tuple, VmTypes}, {tuple_t, _, Types}, Val)
when length(VmTypes) == length(Types),
length(VmTypes) == tuple_size(Val) ->
{tuple, [], [translate_vm_value(VmType, Type, X)
|| {VmType, Type, X} <- lists:zip3(VmTypes, Types, tuple_to_list(Val))]};
translate_vm_value({tuple, VmTypes}, {record_t, Fields}, Val)
when length(VmTypes) == length(Fields),
length(VmTypes) == tuple_size(Val) ->
{record, [], [ {field, [], [{proj, [], FName}], translate_vm_value(VmType, FType, X)}
|| {VmType, {field_t, _, FName, FType}, X} <- lists:zip3(VmTypes, Fields, tuple_to_list(Val)) ]};
translate_vm_value({map, VmKeyType, VmValType}, {app_t, _, {id, _, "map"}, [KeyType, ValType]}, Map)
when is_map(Map) ->
{map, [], [ {translate_vm_value(VmKeyType, KeyType, Key),
translate_vm_value(VmValType, ValType, Val)}
|| {Key, Val} <- maps:to_list(Map) ]};
translate_vm_value({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),
translate_vm_value(VmTypes, ConType, Args);
translate_vm_value(VmTypes, {constr_t, _, Con, Types}, Args)
when length(VmTypes) == length(Types),
length(VmTypes) == length(Args) ->
{app, [], Con, [ translate_vm_value(VmType, Type, Arg)
|| {VmType, Type, Arg} <- lists:zip3(VmTypes, Types, Args) ]};
translate_vm_value(_VmType, _Type, _Data) ->
throw(cannot_translate_to_sophia).
-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, Options0) ->
Options = [no_code | Options0],
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
case check_call(Code, Fun, Args, []) of
{ok, FunName, {ArgTypes, RetType}, VMArgs} ->
aeb_abi:create_calldata(FunName, VMArgs, ArgTypes, RetType);
{error, _} = Err -> Err
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, Options0) ->
Options = [no_code | Options0],
try
Code = string_to_code(ContractString, Options),
#{ typed_ast := TypedAst, type_env := TypeEnv} = Code,
#{ typed_ast := TypedAst,
type_env := TypeEnv,
icode := Icode } = string_to_icode(ContractString, []),
{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)}
Type = aeso_ast_infer_types:unfold_types_in_type(TypeEnv, Type0, [unfold_record_types, unfold_variant_types]),
VmType = aeso_ast_to_icode:ast_typerep(Type, Icode),
case aeb_heap:from_binary({tuple, [word, VmType]}, Calldata) of
{ok, {_, VmValue}} ->
try
{tuple, [], Values} = translate_vm_value(VmType, Type, VmValue),
{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;
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
{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
catch
error:{parse_errors, Errors} ->
@@ -454,6 +365,7 @@ decode_calldata(ContractString, FunName, Calldata, Options0) ->
fun (E) -> io_lib:format("~p", [E]) end)}
end.
get_arg_icode(Funs) ->
case [ Args || {[_, ?CALL_NAME], _, _, {funcall, _, Args}, _} <- Funs ] of
[Args] -> Args;
@@ -479,11 +391,7 @@ get_decode_type(FunName, [{contract, _, _, Defs}]) ->
(_) -> [] end,
case lists:flatmap(GetType, Defs) of
[{Args, Ret}] -> {ok, Args, Ret};
[] ->
case FunName of
"init" -> {ok, [], {tuple_t, [], []}};
_ -> {error, missing_function}
end
[] -> {error, missing_function}
end;
get_decode_type(FunName, [_ | Contracts]) ->
%% The __decode should be in the final contract
@@ -492,10 +400,13 @@ get_decode_type(FunName, [_ | Contracts]) ->
%% Translate an icode value (error if not value) to an Erlang term that can be
%% 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;
icode_to_term({bytes, Len}, {integer, Value}) when Len =< 32 ->
Value;
icode_to_term({bytes, Len}, {tuple, Words}) when Len > 32->
list_to_tuple([W || {integer, W} <- Words]);
icode_to_term({list, T}, {list, Vs}) ->
[ icode_to_term(T, V) || V <- Vs ];
icode_to_term({tuple, Ts}, {tuple, Vs}) ->
@@ -539,7 +450,7 @@ to_bytecode([], _) -> [].
extract_type_info(#{functions := Functions} =_Icode) ->
ArgTypesOnly = fun(As) -> [ T || {_, T} <- As ] end,
TypeInfo = [aeb_aevm_abi:function_type_info(list_to_binary(lists:last(Name)),
TypeInfo = [aeb_abi:function_type_info(list_to_binary(lists:last(Name)),
ArgTypesOnly(Args), TypeRep)
|| {Name, Attrs, Args,_Body, TypeRep} <- Functions,
not is_tuple(Name),
@@ -609,3 +520,4 @@ 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_fcode_to_fate.erl
-1503
View File
File diff suppressed because it is too large Load Diff
src/aeso_icode_to_asm.erl
+1 -3
View File
@@ -105,7 +105,7 @@ make_args(Args) ->
fun_hash({FName, _, Args, _, TypeRep}) ->
ArgType = {tuple, [T || {_, T} <- Args]},
<<Hash:256>> = aeb_aevm_abi:function_type_hash(list_to_binary(lists:last(FName)), ArgType, TypeRep),
<<Hash:256>> = aeb_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
@@ -343,8 +343,6 @@ 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) ->
src/aeso_icode_to_fate.erl
+299
View File
@@ -0,0 +1,299 @@
%%%-------------------------------------------------------------------
%%% @author Ulf Norell
%%% @copyright (C) 2019, Aeternity Anstalt
%%% @doc
%%% Fate backend for Sophia compiler
%%% @end
%%% Created : 11 Jan 2019
%%%
%%%-------------------------------------------------------------------
-module(aeso_icode_to_fate).
-include("aeso_icode.hrl").
-export([compile/2]).
%% -- Preamble ---------------------------------------------------------------
-define(TODO(What), error({todo, ?FILE, ?LINE, ?FUNCTION_NAME, What})).
-define(i(__X__), {immediate, __X__}).
-define(a, {stack, 0}).
-record(env, { args = [], stack = [], tailpos = true }).
%% -- Debugging --------------------------------------------------------------
%% debug(Options, Fmt) -> debug(Options, Fmt, []).
debug(Options, Fmt, Args) ->
case proplists:get_value(debug, Options, true) of
true -> io:format(Fmt, Args);
false -> ok
end.
%% -- Main -------------------------------------------------------------------
%% @doc Main entry point.
compile(ICode, Options) ->
#{ contract_name := _ContractName,
state_type := _StateType,
functions := Functions } = ICode,
SFuns = functions_to_scode(Functions, Options),
SFuns1 = optimize_scode(SFuns, Options),
to_basic_blocks(SFuns1, Options).
functions_to_scode(Functions, Options) ->
maps:from_list(
[ {list_to_binary(Name), function_to_scode(Name, Args, Body, Type, Options)}
|| {Name, _Ann, Args, Body, Type} <- Functions, Name /= "init" ]). %% TODO: skip init for now
function_to_scode(Name, Args, Body, Type, Options) ->
debug(Options, "Compiling ~p ~p : ~p ->\n ~p\n", [Name, Args, Type, Body]),
ArgTypes = [ icode_type_to_fate(T) || {_, T} <- Args ],
ResType = icode_type_to_fate(Type),
SCode = to_scode(init_env(Args), Body),
debug(Options, " scode: ~p\n", [SCode]),
{{ArgTypes, ResType}, SCode}.
%% -- Types ------------------------------------------------------------------
%% TODO: the Fate types don't seem to be specified anywhere...
icode_type_to_fate(word) -> integer;
icode_type_to_fate(string) -> string;
icode_type_to_fate({tuple, Types}) ->
{tuple, lists:map(fun icode_type_to_fate/1, Types)};
icode_type_to_fate({list, Type}) ->
{list, icode_type_to_fate(Type)};
icode_type_to_fate(typerep) -> typerep;
icode_type_to_fate(Type) -> ?TODO(Type).
%% -- Phase I ----------------------------------------------------------------
%% Icode to structured assembly
%% -- Environment functions --
init_env(Args) ->
#env{ args = Args, stack = [], tailpos = true }.
push_env(Type, Env) ->
Env#env{ stack = [{"_", Type} | Env#env.stack] }.
notail(Env) -> Env#env{ tailpos = false }.
lookup_var(#env{ args = Args, stack = S }, X) ->
case {keyfind_index(X, 1, S), keyfind_index(X, 1, Args)} of
{false, false} -> false;
{false, Arg} -> {arg, Arg};
{Local, _} -> {stack, Local}
end.
%% -- The compiler --
to_scode(_Env, #integer{ value = N }) ->
[aeb_fate_code:push(?i(N))]; %% Doesn't exist (yet), translated by desugaring
to_scode(Env, #var_ref{name = X}) ->
case lookup_var(Env, X) of
false -> error({unbound_variable, X, Env});
{stack, N} -> [aeb_fate_code:dup(?i(N))];
{arg, N} -> [aeb_fate_code:push({arg, N})]
end;
to_scode(Env, #binop{ op = Op, left = A, right = B }) ->
[ to_scode(notail(Env), B)
, to_scode(push_env(binop_type_r(Op), Env), A)
, binop_to_scode(Op) ];
to_scode(Env, #ifte{decision = Dec, then = Then, else = Else}) ->
[ to_scode(notail(Env), Dec)
, {ifte, to_scode(Env, Then), to_scode(Env, Else)} ];
to_scode(_Env, Icode) -> ?TODO(Icode).
%% -- Operators --
binop_types('+') -> {word, word};
binop_types('-') -> {word, word};
binop_types('==') -> {word, word};
binop_types(Op) -> ?TODO(Op).
%% binop_type_l(Op) -> element(1, binop_types(Op)).
binop_type_r(Op) -> element(2, binop_types(Op)).
binop_to_scode('+') -> add_a_a_a(); %% Optimization introduces other variants
binop_to_scode('-') -> sub_a_a_a();
binop_to_scode('==') -> eq_a_a_a().
% binop_to_scode(Op) -> ?TODO(Op).
add_a_a_a() -> aeb_fate_code:add(?a, ?a, ?a).
sub_a_a_a() -> aeb_fate_code:sub(?a, ?a, ?a).
eq_a_a_a() -> aeb_fate_code:eq(?a, ?a, ?a).
%% -- Phase II ---------------------------------------------------------------
%% Optimize
optimize_scode(Funs, Options) ->
maps:map(fun(Name, Def) -> optimize_fun(Funs, Name, Def, Options) end,
Funs).
flatten(Code) -> lists:map(fun flatten_s/1, lists:flatten(Code)).
flatten_s({ifte, Then, Else}) -> {ifte, flatten(Then), flatten(Else)};
flatten_s(I) -> I.
optimize_fun(_Funs, Name, {{Args, Res}, Code}, Options) ->
Code0 = flatten(Code),
debug(Options, "Optimizing ~s\n", [Name]),
debug(Options, " original : ~p\n", [Code0]),
Code1 = simplify(Code0),
debug(Options, " simplified: ~p\n", [Code1]),
Code2 = desugar(Code1),
debug(Options, " desugared : ~p\n", [Code2]),
{{Args, Res}, Code2}.
simplify([]) -> [];
simplify([I | Code]) ->
simpl_top(simpl_s(I), simplify(Code)).
simpl_s({ifte, Then, Else}) ->
{ifte, simplify(Then), simplify(Else)};
simpl_s(I) -> I.
%% add_i 0 --> nop
simpl_top({'ADD', _, ?i(0), _}, Code) -> Code;
%% push n, add_a --> add_i n
simpl_top({'PUSH', ?a, ?i(N)},
[{'ADD', ?a, ?a, ?a} | Code]) ->
simpl_top( aeb_fate_code:add(?a, ?i(N), ?a), Code);
%% push n, add_i m --> add_i (n + m)
simpl_top({'PUSH', ?a, ?i(N)}, [{'ADD', ?a, ?i(M), ?a} | Code]) ->
simpl_top(aeb_fate_code:push(?i(N + M)), Code);
%% add_i n, add_i m --> add_i (n + m)
simpl_top({'ADD', ?a, ?i(N), ?a}, [{'ADD', ?a, ?i(M), ?a} | Code]) ->
simpl_top({'ADD', ?a, ?i(N + M), ?a}, Code);
simpl_top(I, Code) -> [I | Code].
%% Desugar and specialize
desugar({'ADD', ?a, ?i(1), ?a}) -> [aeb_fate_code:inc()];
desugar({ifte, Then, Else}) -> [{ifte, desugar(Then), desugar(Else)}];
desugar(Code) when is_list(Code) ->
lists:flatmap(fun desugar/1, Code);
desugar(I) -> [I].
%% -- Phase III --------------------------------------------------------------
%% Constructing basic blocks
to_basic_blocks(Funs, Options) ->
maps:from_list([ {Name, {{Args, Res},
bb(Name, Code ++ [aeb_fate_code:return()], Options)}}
|| {Name, {{Args, Res}, Code}} <- maps:to_list(Funs) ]).
bb(Name, Code, Options) ->
Blocks0 = blocks(Code),
Blocks = optimize_blocks(Blocks0),
Labels = maps:from_list([ {Ref, I} || {I, {Ref, _}} <- with_ixs(Blocks) ]),
BBs = [ set_labels(Labels, B) || B <- Blocks ],
debug(Options, "Final code for ~s:\n ~p\n", [Name, BBs]),
maps:from_list(BBs).
%% -- Break up scode into basic blocks --
blocks(Code) ->
Top = make_ref(),
blocks([{Top, Code}], []).
blocks([], Acc) ->
lists:reverse(Acc);
blocks([{Ref, Code} | Blocks], Acc) ->
block(Ref, Code, [], Blocks, Acc).
block(Ref, [], CodeAcc, Blocks, BlockAcc) ->
blocks(Blocks, [{Ref, lists:reverse(CodeAcc)} | BlockAcc]);
block(Ref, [{ifte, Then, Else} | Code], Acc, Blocks, BlockAcc) ->
ThenLbl = make_ref(),
RestLbl = make_ref(),
block(Ref, Else ++ [{jump, RestLbl}],
[{jumpif, ThenLbl} | Acc],
[{ThenLbl, Then ++ [{jump, RestLbl}]},
{RestLbl, Code} | Blocks],
BlockAcc);
block(Ref, [I | Code], Acc, Blocks, BlockAcc) ->
block(Ref, Code, [I | Acc], Blocks, BlockAcc).
%% -- Reorder, inline, and remove dead blocks --
optimize_blocks(Blocks) ->
%% We need to look at the last instruction a lot, so reverse all blocks.
Rev = fun(Bs) -> [ {Ref, lists:reverse(Code)} || {Ref, Code} <- Bs ] end,
RBlocks = Rev(Blocks),
RBlockMap = maps:from_list(RBlocks),
RBlocks1 = reorder_blocks(RBlocks, []),
RBlocks2 = [ {Ref, inline_block(RBlockMap, Ref, Code)} || {Ref, Code} <- RBlocks1 ],
RBlocks3 = remove_dead_blocks(RBlocks2),
Rev(RBlocks3).
%% Choose the next block based on the final jump.
reorder_blocks([], Acc) ->
lists:reverse(Acc);
reorder_blocks([{Ref, Code} | Blocks], Acc) ->
reorder_blocks(Ref, Code, Blocks, Acc).
reorder_blocks(Ref, Code, Blocks, Acc) ->
Acc1 = [{Ref, Code} | Acc],
case Code of
['RETURN'|_] -> reorder_blocks(Blocks, Acc1);
[{'RETURNR', _}|_] -> reorder_blocks(Blocks, Acc1);
[{jump, L}|_] ->
NotL = fun({L1, _}) -> L1 /= L end,
case lists:splitwith(NotL, Blocks) of
{Blocks1, [{L, Code1} | Blocks2]} ->
reorder_blocks(L, Code1, Blocks1 ++ Blocks2, Acc1);
{_, []} -> reorder_blocks(Blocks, Acc1)
end
end.
%% Inline short blocks ( 2 instructions)
inline_block(BlockMap, Ref, [{jump, L} | Code] = Code0) when L /= Ref ->
case maps:get(L, BlockMap, nocode) of
Dest when length(Dest) < 3 ->
%% Remove Ref to avoid infinite loops
inline_block(maps:remove(Ref, BlockMap), L, Dest) ++ Code;
_ -> Code0
end;
inline_block(_, _, Code) -> Code.
%% Remove unused blocks
remove_dead_blocks(Blocks = [{Top, _} | _]) ->
BlockMap = maps:from_list(Blocks),
LiveBlocks = chase_labels([Top], BlockMap, #{}),
[ B || B = {L, _} <- Blocks, maps:is_key(L, LiveBlocks) ].
chase_labels([], _, Live) -> Live;
chase_labels([L | Ls], Map, Live) ->
Code = maps:get(L, Map),
Jump = fun({jump, A}) -> [A || not maps:is_key(A, Live)];
({jumpif, A}) -> [A || not maps:is_key(A, Live)];
(_) -> [] end,
New = lists:flatmap(Jump, Code),
chase_labels(New ++ Ls, Map, Live#{ L => true }).
%% -- Translate label refs to indices --
set_labels(Labels, {Ref, Code}) when is_reference(Ref) ->
{maps:get(Ref, Labels), [ set_labels(Labels, I) || I <- Code ]};
set_labels(Labels, {jump, Ref}) -> aeb_fate_code:jump(maps:get(Ref, Labels));
set_labels(Labels, {jumpif, Ref}) -> aeb_fate_code:jumpif(?a, maps:get(Ref, Labels));
set_labels(_, I) -> I.
%% -- Helpers ----------------------------------------------------------------
with_ixs(Xs) ->
lists:zip(lists:seq(0, length(Xs) - 1), Xs).
keyfind_index(X, J, Xs) ->
case [ I || {I, E} <- with_ixs(Xs), X == element(J, E) ] of
[I | _] -> I;
[] -> false
end.
src/aeso_parser.erl
+29 -44
View File
@@ -47,7 +47,7 @@ decl() ->
%% Contract declaration
[ ?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})
, ?RULE(keyword(include), str(), {include, _2})
%% Type declarations TODO: format annotation for "type bla" vs "type bla()"
, ?RULE(keyword(type), id(), {type_decl, _1, _2, []})
@@ -60,22 +60,13 @@ decl() ->
, ?RULE(keyword(datatype), id(), type_vars(), tok('='), typedef(variant), {type_def, _1, _2, _3, _5})
%% Function declarations
, ?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))
, ?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))
])).
fun_or_entry() ->
choice([?RULE(keyword(function), {function, _1}),
?RULE(keyword(entrypoint), {entrypoint, _1})]).
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).
many(choice([token(stateful), token(public), token(private), token(internal)])).
add_modifiers([], Node) -> Node;
add_modifiers(Mods = [Tok | _], Node) ->
@@ -96,7 +87,7 @@ 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()).
@@ -108,7 +99,9 @@ con_arg() -> choice(type(), ?RULE(keyword(indexed), type(), set_ann(indexed,
%% -- Let declarations -------------------------------------------------------
letdecl() ->
?RULE(keyword('let'), letdef(), set_pos(get_pos(_1), _2)).
choice(
?RULE(keyword('let'), letdef(), set_pos(get_pos(_1), _2)),
?RULE(keyword('let'), tok(rec), sep1(letdef(), tok('and')), {letrec, _1, _3})).
letdef() -> choice(valdef(), fundef()).
@@ -140,8 +133,7 @@ type100() -> type200().
type200() ->
?RULE(many({fun_domain(), keyword('=>')}), type300(), fun_t(_1, _2)).
type300() ->
?RULE(sep1(type400(), tok('*')), tuple_t(get_ann(lists:nth(1, _1)), _1)).
type300() -> type400().
type400() ->
choice(
@@ -156,18 +148,11 @@ type400() ->
typeAtom() ->
?LAZY_P(choice(
[ parens(type())
, id(), token(con), token(qcon), token(qid), tvar()
[ id(), token(con), token(qcon), token(qid), tvar()
, ?RULE(keyword('('), comma_sep(type()), tok(')'), tuple_t(_1, _2))
])).
fun_domain() -> ?LAZY_P(choice(
[ ?RULE(tok('('), tok(')'), [])
%% Note avoidance of ambiguity: `(int)` can be treated as:
%% - literally `int`
%% - list of arguments with just one element int. This approach is dropped.
, ?RULE(tok('('), type(), tok(','), sep1(type(), tok(',')), tok(')'), [_2|_4])
, ?RULE(type300(), [_1])
])).
fun_domain() -> ?RULE(?LAZY_P(type300()), fun_domain(_1)).
%% -- Statements -------------------------------------------------------------
@@ -228,7 +213,7 @@ exprAtom() ->
, ?RULE(token(hex), set_ann(format, hex, setelement(1, _1, int)))
, {bool, keyword(true), true}
, {bool, keyword(false), false}
, ?LET_P(Fs, brace_list(?LAZY_P(field_assignment())), record(Fs))
, ?RULE(brace_list(?LAZY_P(field_assignment())), record(_1))
, {list, [], bracket_list(Expr)}
, ?RULE(tok('['), Expr, binop('..'), Expr, tok(']'), _3(_2, _4))
, ?RULE(keyword('('), comma_sep(Expr), tok(')'), tuple_e(_1, _2))
@@ -271,20 +256,14 @@ record_update(Ann, E, Flds) ->
record([]) -> {map, [], []};
record(Fs) ->
case record_or_map(Fs) of
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)};
record -> {record, get_ann(hd(Fs)), Fs};
map ->
Ann = get_ann(hd(Fs ++ [{empty, []}])), %% TODO: source location for empty maps
KV = fun({field, _, [{map_get, _, Key}], Val}) -> {Key, Val};
({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,
({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,
{map, Ann, lists:map(KV, Fs)}
end.
@@ -462,7 +441,7 @@ 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, {tuple, [{origin, system}], []}}.
{'if', Ann, Cond, Then, {unit, [{origin, system}]}}.
else_branches([Elif = {elif, _, _, _} | Stmts], Acc) ->
else_branches(Stmts, [Elif | Acc]);
@@ -478,9 +457,14 @@ 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}.
%% TODO: not nice
fun_domain({tuple_t, _, Args}) -> Args;
fun_domain(T) -> [T].
-spec parse_pattern(aeso_syntax:expr()) -> aeso_parse_lib:parser(aeso_syntax:pat()).
parse_pattern({app, Ann, Con = {'::', _}, Es}) ->
{app, Ann, Con, lists:map(fun parse_pattern/1, Es)};
@@ -494,6 +478,7 @@ 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 = {bytes, _, _}) -> E;
@@ -510,11 +495,11 @@ return_error({no_file, 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()) -> aeso_parse_lib:parser(none()).
-spec ret_doc_err(ann(), prettypr:document()) -> no_return().
ret_doc_err(Ann, Doc) ->
return_error(ann_pos(Ann), prettypr:format(Doc)).
-spec bad_expr_err(string(), aeso_syntax:expr()) -> aeso_parse_lib:parser(none()).
-spec bad_expr_err(string(), aeso_syntax:expr()) -> no_return().
bad_expr_err(Reason, E) ->
ret_doc_err(get_ann(E),
prettypr:sep([prettypr:text(Reason ++ ":"),
@@ -526,7 +511,7 @@ expand_includes(AST, Opts) ->
expand_includes([], Acc, _Opts) ->
{ok, lists:reverse(Acc)};
expand_includes([{include, _, S = {string, _, File}} | AST], Acc, Opts) ->
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}),
src/aeso_pretty.erl
+16 -32
View File
@@ -153,22 +153,15 @@ 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, 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({fun_decl, _, F, T}) ->
hsep(text("function"), typed(name(F), T));
decl(D = {letfun, Attrs, _, _, _, _}) ->
Mod = fun({Mod, true}) when Mod == private; Mod == stateful ->
Mod = fun({Mod, true}) when Mod == private; Mod == internal; Mod == public; Mod == stateful ->
text(atom_to_list(Mod));
(_) -> empty() end,
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).
hsep(lists:map(Mod, Attrs) ++ [letdecl("function", D)]);
decl(D = {letval, _, _, _, _}) -> letdecl("let", D);
decl(D = {letrec, _, _}) -> letdecl("let", D).
-spec expr(aeso_syntax:expr(), options()) -> doc().
expr(E, Options) ->
@@ -191,7 +184,9 @@ 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).
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 ] ])).
-spec args([aeso_syntax:arg()]) -> doc().
args(Args) ->
@@ -222,7 +217,7 @@ typedef({variant_t, Constructors}) ->
-spec constructor_t(aeso_syntax:constructor_t()) -> doc().
constructor_t({constr_t, _, C, []}) -> name(C);
constructor_t({constr_t, _, C, Args}) -> beside(name(C), args_type(Args)).
constructor_t({constr_t, _, C, Args}) -> beside(name(C), tuple_type(Args)).
-spec field_t(aeso_syntax:field_t()) -> doc().
field_t({field_t, _, Name, Type}) ->
@@ -234,14 +229,13 @@ type(Type, Options) ->
-spec type(aeso_syntax:type()) -> doc().
type({fun_t, _, Named, Args, Ret}) ->
follow(hsep(args_type(Named ++ Args), text("=>")), type(Ret));
follow(hsep(tuple_type(Named ++ Args), text("=>")), type(Ret));
type({app_t, _, Type, []}) ->
type(Type);
type({app_t, _, Type, Args}) ->
beside(type(Type), args_type(Args));
beside(type(Type), tuple_type(Args));
type({tuple_t, _, Args}) ->
tuple_type(Args);
type({bytes_t, _, any}) -> text("bytes(_)");
type({bytes_t, _, Len}) ->
text(lists:concat(["bytes(", Len, ")"]));
type({named_arg_t, _, Name, Type, _Default}) ->
@@ -256,19 +250,9 @@ type(T = {con, _, _}) -> name(T);
type(T = {qcon, _, _}) -> name(T);
type(T = {tvar, _, _}) -> name(T).
-spec args_type([aeso_syntax:type()]) -> doc().
args_type(Args) ->
tuple(lists:map(fun type/1, Args)).
-spec tuple_type([aeso_syntax:type()]) -> doc().
tuple_type([]) ->
text("unit");
tuple_type(Factors) ->
beside(
[ text("(")
, par(punctuate(text(" *"), lists:map(fun type/1, Factors)), 0)
, text(")")
]).
tuple_type(Args) ->
tuple(lists:map(fun type/1, Args)).
-spec arg_expr(aeso_syntax:arg_expr()) -> doc().
arg_expr({named_arg, _, Name, E}) ->
@@ -348,7 +332,7 @@ expr_p(_, {Type, _, Bin})
Type == oracle_pubkey;
Type == oracle_query_id ->
text(binary_to_list(aeser_api_encoder:encode(Type, Bin)));
expr_p(_, {string, _, <<>>}) -> text("\"\"");
expr_p(_, {unit, _}) -> text("()");
expr_p(_, {string, _, S}) -> term(binary_to_list(S));
expr_p(_, {char, _, C}) ->
case C of
@@ -381,7 +365,6 @@ 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};
@@ -453,6 +436,7 @@ 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
+2 -2
View File
@@ -36,8 +36,8 @@ lexer() ->
, {"\\*/", pop(skip())}
, {"[^/*]+|[/*]", skip()} ],
Keywords = ["contract", "include", "let", "switch", "type", "record", "datatype", "if", "elif", "else", "function",
"stateful", "true", "false", "mod", "public", "entrypoint", "private", "indexed", "namespace"],
Keywords = ["contract", "include", "let", "rec", "switch", "type", "record", "datatype", "if", "elif", "else", "function",
"stateful", "true", "false", "and", "mod", "public", "private", "indexed", "internal", "namespace"],
KW = string:join(Keywords, "|"),
Rules =
src/aeso_syntax.erl
+11 -8
View File
@@ -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()} | stateful | private].
-type ann() :: [{line, ann_line()} | {col, ann_col()} | {format, ann_format()} | {origin, ann_origin()}].
-type name() :: string().
-type id() :: {id, ann(), name()}.
@@ -43,7 +43,8 @@
-type letbind()
:: {letval, ann(), id(), type(), expr()}
| {letfun, ann(), id(), [arg()], type(), expr()}.
| {letfun, ann(), id(), [arg()], type(), expr()}
| {letrec, ann(), [letbind()]}.
-type arg() :: {arg, ann(), id(), type()}.
@@ -59,7 +60,7 @@
-type type() :: {fun_t, ann(), [named_arg_t()], [type()], type()}
| {app_t, ann(), type(), [type()]}
| {tuple_t, ann(), [type()]}
| {bytes_t, ann(), integer() | any}
| {bytes_t, ann(), integer()}
| id() | qid()
| con() | qcon() %% contracts
| tvar().
@@ -69,11 +70,12 @@
-type constant()
:: {int, ann(), integer()}
| {bool, ann(), true | false}
| {bytes, ann(), binary()}
| {account_pubkey, ann(), binary()}
| {contract_pubkey, ann(), binary()}
| {oracle_pubkey, ann(), binary()}
| {oracle_query_id, ann(), binary()}
| {hash, ann(), binary()}
| {account_pubkey, binary()}
| {contract_pubkey, binary()}
| {oracle_pubkey, binary()}
| {oracle_query_id, binary()}
| {unit, ann()}
| {string, ann(), binary()}
| {char, ann(), integer()}.
@@ -148,3 +150,4 @@ get_ann(Key, 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
+24 -24
View File
@@ -6,7 +6,7 @@
%%%-------------------------------------------------------------------
-module(aeso_syntax_utils).
-export([used_ids/1, used_types/2, used/1]).
-export([used_ids/1, used_types/1, used/1]).
-record(alg, {zero, plus, scoped}).
@@ -39,6 +39,11 @@ fold(Alg = #alg{zero = Zero, plus = Plus, scoped = Scoped}, Fun, K, X) ->
BindExpr = fun(P) -> fold(Alg, Fun, bind_expr, P) end,
BindType = fun(T) -> fold(Alg, Fun, bind_type, T) end,
Top = Fun(K, X),
Bound = fun LB ({letval, _, Y, _, _}) -> BindExpr(Y);
LB ({letfun, _, F, _, _, _}) -> BindExpr(F);
LB ({letrec, _, Ds}) -> Sum(lists:map(LB, Ds));
LB (_) -> Zero
end,
Rec = case X of
%% lists (bound things in head scope over tail)
[A | As] -> Scoped(Same(A), Same(As));
@@ -50,6 +55,7 @@ fold(Alg = #alg{zero = Zero, plus = Plus, scoped = Scoped}, Fun, K, X) ->
{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))]);
{letrec, _, Ds} -> Plus(Bound(Ds), Decl(Ds));
%% typedef()
{alias_t, T} -> Type(T);
{record_t, Fs} -> Type(Fs);
@@ -98,35 +104,29 @@ fold(Alg = #alg{zero = Zero, plus = Plus, scoped = Scoped}, Fun, K, X) ->
%% Name dependencies
used_ids(E) ->
[ X || {{term, [X]}, _} <- used(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)).
used_types(T) ->
[ X || {type, [X]} <- used(T) ].
-type entity() :: {term, [string()]}
| {type, [string()]}
| {namespace, [string()]}.
-spec entity_alg() -> alg(#{entity() => aeso_syntax:ann()}).
-spec entity_alg() -> alg([entity()]).
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),
{Bound, Others} = lists:partition(IsBound, Ys),
Bound1 = [ {Unbind(Tag), X} || {Tag, X} <- Bound ],
maps:merge(Remove(Bound1, Xs), Others)
lists:umerge(Xs -- Bound1, Others)
end,
#alg{ zero = #{}
, plus = fun maps:merge/2
#alg{ zero = []
, plus = fun lists:umerge/2
, scoped = Scoped }.
-spec used(_) -> [{entity(), aeso_syntax:ann()}].
-spec used(_) -> [entity()].
used(D) ->
Kind = fun(expr) -> term;
(bind_expr) -> bound_term;
@@ -134,14 +134,14 @@ used(D) ->
(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,
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)),
fold(entity_alg(),
fun(K, {id, _, X}) -> [{Kind(K), [X]}];
(K, {qid, _, Xs}) -> [{Kind(K), Xs}, NS(Xs)];
(K, {con, _, X}) -> [{Kind(K), [X]}];
(K, {qcon, _, Xs}) -> [{Kind(K), Xs}, NS(Xs)];
(_, _) -> []
end, decl, D),
lists:filter(NotBound, Xs).
src/aeso_vm_decode.erl
-113
View File
@@ -1,113 +0,0 @@
%%%-------------------------------------------------------------------
%%% @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
+2 -3
View File
@@ -1,6 +1,6 @@
{application, aesophia,
[{description, "Contract Language for aeternity"},
{vsn, "3.2.0"},
{vsn, "2.1.0"},
{registered, []},
{applications,
[kernel,
@@ -8,8 +8,7 @@
jsx,
syntax_tools,
getopt,
aebytecode,
eblake2
aebytecode
]},
{env,[]},
{modules, []},
src/aesophia.erl
+78
View File
@@ -0,0 +1,78 @@
-module(aesophia).
-export([main/1]).
-define(OPT_SPEC,
[ {src_file, undefined, undefined, string, "Sophia source code file"}
, {version, $V, "version", undefined, "Print compiler version"}
, {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 Opts of
[version] ->
print_vsn();
[help] ->
usage();
_ ->
compile(Opts)
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]).
print_vsn() ->
{ok, Vsn} = aeso_compiler:version(),
io:format("Compiler version: ~s\n", [Vsn]).
test/aeso_abi_tests.erl
+18 -19
View File
@@ -1,7 +1,7 @@
-module(aeso_abi_tests).
-include_lib("eunit/include/eunit.hrl").
-compile([export_all, nowarn_export_all]).
-compile(export_all).
-define(SANDBOX(Code), sandbox(fun() -> Code end)).
-define(DUMMY_HASH_WORD, 16#123).
@@ -62,11 +62,10 @@ encode_decode_sophia_test() ->
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)",
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}"),
@@ -76,10 +75,10 @@ encode_decode_sophia_string(SophiaType, String) ->
io:format("String ~p~n", [String]),
Code = [ "contract MakeCall =\n"
, " type arg_type = ", SophiaType, "\n"
, " type an_alias('a) = string * 'a\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" ],
, " function 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]),
@@ -120,14 +119,16 @@ calldata_init_test() ->
calldata_indent_test() ->
Test = fun(Extra) ->
Code = parameterized_contract(Extra, "foo", ["int"]),
encode_decode_calldata_(Code, "foo", ["42"], word)
encode_decode_calldata_(
parameterized_contract(Extra, "foo", ["int"]),
"foo", ["42"], word)
end,
Test(" stateful entrypoint bla() = ()"),
Test(" stateful function bla() = ()"),
Test(" type x = int"),
Test(" stateful entrypoint bla(x : int) =\n"
Test(" private function bla : int => int"),
Test(" public stateful function bla(x : int) =\n"
" x + 1"),
Test(" stateful entrypoint bla(x : int) : int =\n"
Test(" stateful private function bla(x : int) : int =\n"
" x + 1"),
ok.
@@ -137,18 +138,18 @@ parameterized_contract(FunName, Types) ->
parameterized_contract(ExtraCode, FunName, Types) ->
lists:flatten(
["contract Remote =\n"
" entrypoint bla : () => unit\n\n"
" function bla : () => ()\n\n"
"contract Dummy =\n",
ExtraCode, "\n",
" type an_alias('a) = string * 'a\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" ]).
" function ", FunName, " : (", string:join(Types, ", "), ") => int\n" ]).
oracle_test() ->
Contract =
"contract OracleTest =\n"
" entrypoint question(o, q : oracle_query(list(string), option(int))) =\n"
" function 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",
@@ -159,7 +160,7 @@ oracle_test() ->
permissive_literals_fail_test() ->
Contract =
"contract OracleTest =\n"
" stateful entrypoint haxx(o : oracle(list(string), option(int))) =\n"
" function 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"], []),
@@ -173,10 +174,8 @@ encode_decode_calldata(FunName, Types, Args, RetType) ->
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, Calldata, CalldataType, RetVMType1} = aeso_compiler:create_calldata(Code, FunName, Args),
?assertEqual(RetVMType1, RetVMType),
{ok, {_Hash, ArgTuple}} = aeb_heap:from_binary(CalldataType, Calldata),
case FunName of
"init" ->
test/aeso_aci_tests.erl
+50 -96
View File
@@ -2,121 +2,75 @@
-include_lib("eunit/include/eunit.hrl").
simple_aci_test_() ->
[{"Test contract " ++ integer_to_list(N),
fun() -> test_contract(N) end}
|| N <- [1, 2, 3]].
do_test() ->
test_contract(1),
test_contract(2),
test_contract(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)).
{ok,JSON} = aeso_aci:encode(Contract),
?assertEqual(MapACI, jsx:decode(JSON, [return_maps])),
?assertEqual(DecACI, aeso_aci:decode(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}]}},
" function 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">>,
" function 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}]}},
" function a(i : allan) = i+1\n">>,
MapACI = #{<<"contract">> =>
#{<<"name">> => <<"C">>,
<<"type_defs">> =>
[#{<<"name">> => <<"allan">>,
<<"typedef">> => <<"int">>,
<<"vars">> => []}],
<<"functions">> =>
[#{<<"arguments">> =>
[#{<<"name">> => <<"i">>,
<<"type">> => <<"int">>}],
<<"name">> => <<"a">>,
<<"returns">> => <<"int">>,
<<"stateful">> => false}]}},
DecACI = <<"contract C =\n"
" type allan = int\n"
" entrypoint a : (C.allan) => int\n">>,
" function a : (int) => int\n">>,
{Contract,MapACI,DecACI};
test_cases(3) ->
Contract = <<"contract C =\n"
" type state = unit\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 =>
" function 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 => <<"unit">>,
type_defs =>
[#{name => <<"bert">>,
typedef =>
#{variant =>
<<"name">> => <<"a">>,<<"returns">> => <<"int">>,
<<"stateful">> => false}],
<<"name">> => <<"C">>,
<<"type_defs">> =>
[#{<<"name">> => <<"bert">>,
<<"typedef">> =>
#{<<"variant">> =>
[#{<<"Bin">> => [<<"'a">>]}]},
vars => [#{name => <<"'a">>}]}]}},
<<"vars">> => [#{<<"name">> => <<"'a">>}]}]}},
DecACI = <<"contract C =\n"
" type state = unit\n"
" datatype event = SingleEventDefined\n"
" datatype bert('a) = Bin('a)\n"
" entrypoint a : (C.bert(string)) => int\n">>,
" function 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_calldata_tests.erl
-128
View File
@@ -1,128 +0,0 @@
%%% -*- 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()].
calldata_aci_test_() ->
[ {"Testing " ++ ContractName ++ " contract calling " ++ Fun,
fun() ->
ContractString = aeso_test_utils:read_contract(ContractName),
{ok, ContractACIBin} = aeso_aci:contract_interface(string, ContractString),
ContractACI = binary_to_list(ContractACIBin),
io:format("ACI:\n~s\n", [ContractACIBin]),
AevmExprs =
case not lists:member(ContractName, not_yet_compilable(aevm)) of
true -> ast_exprs(ContractACI, Fun, Args, [{backend, aevm}]);
false -> undefined
end,
FateExprs =
case not lists:member(ContractName, not_yet_compilable(fate)) of
true -> ast_exprs(ContractACI, 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} = (catch aeso_compiler:create_calldata(ContractString, Fun, Args, Opts)),
{ok, _Types, Exprs} = (catch 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"]},
{"stub", "foo", ["42"]},
{"stub", "foo", ["-42"]}
].
not_yet_compilable(fate) ->
[];
not_yet_compilable(aevm) ->
[].
test/aeso_compiler_tests.erl
+54 -106
View File
@@ -16,25 +16,20 @@
%% are made on the output, just that it is a binary which indicates
%% that the compilation worked.
simple_compile_test_() ->
[ {"Testing the " ++ ContractName ++ " contract with the " ++ atom_to_list(Backend) ++ " backend",
[ {"Testing the " ++ ContractName ++ " contract",
fun() ->
case compile(Backend, ContractName) of
case compile(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});
type_info := _} -> ?assertMatch(Code when is_binary(Code), ByteCode);
ErrBin ->
io:format("\n~s", [ErrBin]),
error(ErrBin)
end
end} || ContractName <- compilable_contracts(), Backend <- [aevm, fate],
not lists:member(ContractName, not_yet_compilable(Backend))] ++
end} || ContractName <- compilable_contracts() ] ++
[ {"Testing error messages of " ++ ContractName,
fun() ->
case compile(aevm, ContractName) of
case compile(ContractName) of
<<"Type errors\n", ErrorString/binary>> ->
check_errors(lists:sort(ExpectedErrors), ErrorString);
<<"Parse errors\n", ErrorString/binary>> ->
@@ -49,14 +44,14 @@ simple_compile_test_() ->
{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"),
#{byte_code := Code1} = compile("include", [{include, {explicit_files, FileSystem}}]),
#{byte_code := Code2} = compile("include"),
?assertMatch(true, Code1 == Code2)
end} ] ++
[ {"Testing deadcode elimination",
fun() ->
#{ byte_code := NoDeadCode } = compile(aevm, "nodeadcode"),
#{ byte_code := DeadCode } = compile(aevm, "deadcode"),
#{ byte_code := NoDeadCode } = compile("nodeadcode"),
#{ byte_code := DeadCode } = compile("deadcode"),
SizeNoDeadCode = byte_size(NoDeadCode),
SizeDeadCode = byte_size(DeadCode),
?assertMatch({_, _, true}, {SizeDeadCode, SizeNoDeadCode, SizeDeadCode + 40 < SizeNoDeadCode}),
@@ -72,12 +67,12 @@ check_errors(Expect, ErrorString) ->
{Missing, Extra} -> ?assertEqual(Missing, Extra)
end.
compile(Backend, Name) ->
compile(Backend, Name, [{include, {file_system, [aeso_test_utils:contract_path()]}}]).
compile(Name) ->
compile(Name, [{include, {file_system, [aeso_test_utils:contract_path()]}}]).
compile(Backend, Name, Options) ->
compile(Name, Options) ->
String = aeso_test_utils:read_contract(Name),
case aeso_compiler:from_string(String, [{src_file, Name}, {backend, Backend} | Options]) of
case aeso_compiler:from_string(String, [{src_file, Name} | Options]) of
{ok, Map} -> Map;
{error, ErrorString} -> ErrorString
end.
@@ -91,7 +86,6 @@ compilable_contracts() ->
"dutch_auction",
"environment",
"factorial",
"functions",
"fundme",
"identity",
"maps",
@@ -112,18 +106,9 @@ compilable_contracts() ->
"include",
"basic_auth",
"bitcoin_auth",
"address_literals",
"bytes_equality",
"address_chain",
"namespace_bug",
"bytes_to_x",
"aens",
"tuple_match"
"address_literals"
].
not_yet_compilable(fate) -> [];
not_yet_compilable(aevm) -> [].
%% Contracts that should produce type errors
failing_contracts() ->
@@ -131,9 +116,6 @@ failing_contracts() ->
[<<"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">>,
@@ -145,12 +127,12 @@ failing_contracts() ->
" - line 8, column 3">>,
<<"Duplicate definitions of put at\n"
" - (builtin location)\n"
" - line 16, column 3">>,
" - line 15, column 3">>,
<<"Duplicate definitions of state at\n"
" - (builtin location)\n"
" - line 17, column 3">>]}
" - line 16, column 3">>]}
, {"type_errors",
[<<"Unbound variable zz at line 17, column 23">>,
[<<"Unbound variable zz at line 17, column 21">>,
<<"Cannot unify int\n"
" and list(int)\n"
"when checking the application at line 26, column 9 of\n"
@@ -161,18 +143,18 @@ failing_contracts() ->
<<"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"
" 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)">>,
<<"Cannot unify int\n"
" and string\n"
"when checking the type of the expression at line 34, column 47\n"
"when checking the type of the expression at line 34, column 45\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"
"when checking the type of the expression at line 34, column 50\n"
" \"bla\" : string\n"
"against the expected type\n"
" int">>,
@@ -184,7 +166,7 @@ failing_contracts() ->
" int">>,
<<"Cannot unify string\n"
" and int\n"
"when checking the type of the expression at line 11, column 58\n"
"when checking the type of the expression at line 11, column 56\n"
" \"foo\" : string\n"
"against the expected type\n"
" int">>,
@@ -194,51 +176,50 @@ failing_contracts() ->
" - 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)">>,
"arising from the projection of the field y (at line 22, column 38)">>,
<<"Not a record type: string\n"
"arising from an assignment of the field y (at line 21, column 44)">>,
"arising from an assignment of the field y (at line 21, column 42)">>,
<<"Not a record type: string\n"
"arising from an assignment of the field y (at line 20, column 40)">>,
"arising from an assignment of the field y (at line 20, column 38)">>,
<<"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"
"arising from an assignment of the field y (at line 19, column 35)">>,
<<"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)">>,
<<"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">>]}
<<"No record type with fields y, z (at line 14, column 22)">>,
<<"The field z is missing when constructing an element of type r2 (at line 15, column 24)">>,
<<"Record type r2 does not have field y (at line 15, column 22)">>]}
, {"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">>]}
, {"missing_state_type",
[<<"Cannot unify string\n"
" and unit\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 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)">>]}
[<<"The field x is missing when constructing an element of type r('a) (at line 7, column 40)">>,
<<"The field y is missing when constructing an element of type r(int) (at line 8, column 40)">>,
<<"The fields y, z are missing when constructing an element of type r('1) (at line 6, column 40)">>]}
, {"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">>]}
[<<"The payload type int (at line 10, column 30) should be string">>,
<<"The payload type alias_address (at line 12, column 30) equals address but it should be string">>,
<<"The indexed type string (at line 9, column 25) is not a word type">>,
<<"The indexed type alias_string (at line 11, 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)">>]}
<<"The event constructor BadEvent2 (at line 10, column 7) has too many indexed values (max 3)">>,
<<"The event constructor BadEvent3 (at line 11, column 7) has too many non-indexed values (max 1)">>,
<<"The payload type address (at line 11, column 17) should be string">>,
<<"The payload type int (at line 11, column 26) should be string">>]}
, {"type_clash",
[<<"Cannot unify int\n"
" and string\n"
"when checking the record projection at line 12, column 42\n"
"when checking the record projection at line 12, column 40\n"
" r.foo : (gas : int, value : int) => Remote.themap\n"
"against the expected type\n"
" (gas : int, value : int) => map(string, int)">>]}
@@ -261,46 +242,46 @@ failing_contracts() ->
" ct_Ez6MyeTMm17YnTnDdHTSrzMEBKmy7Uz2sXu347bTDPgVH2ifJ\n"
"has the type\n"
" address">>,
<<"Cannot unify oracle_query('a, 'b)\n"
<<"Cannot unify oracle_query('1, '2)\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"
" oracle_query('1, '2)\n"
"against the expected type\n"
" Remote">>,
<<"Cannot unify oracle_query('c, 'd)\n"
<<"Cannot unify oracle_query('3, '4)\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"
" oracle_query('3, '4)\n"
"against the expected type\n"
" bytes(32)">>,
<<"Cannot unify oracle_query('e, 'f)\n"
<<"Cannot unify oracle_query('5, '6)\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"
" oracle_query('5, '6)\n"
"against the expected type\n"
" oracle(int, bool)">>,
<<"Cannot unify oracle('g, 'h)\n"
<<"Cannot unify oracle('7, '8)\n"
" and Remote\n"
"when checking the type of the expression at line 18, column 5\n"
" ok_2YNyxd6TRJPNrTcEDCe9ra59SVUdp9FR9qWC5msKZWYD9bP9z5 :\n"
" oracle('g, 'h)\n"
" oracle('7, '8)\n"
"against the expected type\n"
" Remote">>,
<<"Cannot unify oracle('i, 'j)\n"
<<"Cannot unify oracle('9, '10)\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"
" oracle('9, '10)\n"
"against the expected type\n"
" bytes(32)">>,
<<"Cannot unify oracle('k, 'l)\n"
<<"Cannot unify oracle('11, '12)\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"
" oracle('11, '12)\n"
"against the expected type\n"
" oracle_query(int, bool)">>,
<<"Cannot unify address\n"
@@ -321,37 +302,4 @@ failing_contracts() ->
" 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 47)\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 : () => unit">>,
<<"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 : () => unit">>]}
].
test/aeso_parser_tests.erl
+1 -1
View File
@@ -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, fundme, dutch_auction] ]
|| Contract <- [counter, voting, all_syntax, '05_greeter', aeproof, multi_sig, simple_storage, withdrawal, fundme, dutch_auction] ]
}.
parse_contract(Name) ->
test/aeso_scan_tests.erl
+1 -1
View File
@@ -41,7 +41,7 @@ all_tokens() ->
%% Operators
lists:map(Lit, ['=', '==', '!=', '>', '<', '>=', '=<', '-', '+', '++', '*', '/', mod, ':', '::', '->', '=>', '||', '&&', '!']) ++
%% Keywords
lists:map(Lit, [contract, type, 'let', switch]) ++
lists:map(Lit, [contract, type, 'let', switch, rec, 'and']) ++
%% Comment token (not an actual token), just for tests
[{comment, 0, "// *Comment!\"\n"},
{comment, 0, "/* bla /* bla bla */*/"}] ++
test/contracts/__call.aes
-5
View File
@@ -1,5 +0,0 @@
contract Identity =
function main (x:int) = x
function __call() = 12
test/contracts/abort_test.aes
+1 -1
View File
@@ -8,7 +8,7 @@ contract AbortTest =
{ value = v }
// Aborting
public function do_abort(v : int, s : string) : unit =
public function do_abort(v : int, s : string) : () =
put_value(v)
revert_abort(s)
test/contracts/abort_test_int.aes
+3 -3
View File
@@ -1,9 +1,9 @@
contract Interface =
function do_abort : (int, string) => unit
function do_abort : (int, string) => ()
function get_value : () => int
function put_value : (int) => unit
function put_value : (int) => ()
function get_values : () => list(int)
function put_values : (int) => unit
function put_values : (int) => ()
contract AbortTestInt =
test/contracts/address_chain.aes
-33
View File
@@ -1,33 +0,0 @@
contract Remote =
entrypoint main : (int) => unit
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
+5 -5
View File
@@ -1,14 +1,14 @@
contract Remote =
entrypoint foo : () => unit
function foo : () => ()
contract AddressLiterals =
entrypoint addr() : address =
function addr() : address =
ak_2gx9MEFxKvY9vMG5YnqnXWv1hCsX7rgnfvBLJS4aQurustR1rt
entrypoint oracle() : oracle(int, bool) =
function oracle() : oracle(int, bool) =
ok_2YNyxd6TRJPNrTcEDCe9ra59SVUdp9FR9qWC5msKZWYD9bP9z5
entrypoint query() : oracle_query(int, bool) =
function query() : oracle_query(int, bool) =
oq_2oRvyowJuJnEkxy58Ckkw77XfWJrmRgmGaLzhdqb67SKEL1gPY
entrypoint contr() : Remote =
function contr() : Remote =
ct_Ez6MyeTMm17YnTnDdHTSrzMEBKmy7Uz2sXu347bTDPgVH2ifJ
test/contracts/aens.aes
+33 -34
View File
@@ -3,54 +3,53 @@ contract AENSTest =
// Name resolution
stateful entrypoint resolve_word(name : string, key : string) : option(address) =
function resolve_word(name : string, key : string) : option(address) =
AENS.resolve(name, key)
stateful entrypoint resolve_string(name : string, key : string) : option(string) =
function resolve_string(name : string, key : string) : option(string) =
AENS.resolve(name, key)
// Transactions
stateful entrypoint preclaim(addr : address, // Claim on behalf of this account (can be Contract.address)
chash : hash) : unit = // Commitment hash
function preclaim(addr : address, // Claim on behalf of this account (can be Contract.address)
chash : hash) : () = // Commitment hash
AENS.preclaim(addr, chash)
stateful entrypoint signedPreclaim(addr : address, // Claim on behalf of this account (can be Contract.address)
chash : hash, // Commitment hash
sign : signature) : unit = // Signed by addr (if not Contract.address)
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)
AENS.preclaim(addr, chash, signature = sign)
stateful entrypoint claim(addr : address,
name : string,
salt : int,
name_fee : int) : unit =
AENS.claim(addr, name, salt, name_fee)
function claim(addr : address,
name : string,
salt : int) : () =
AENS.claim(addr, name, salt)
stateful entrypoint signedClaim(addr : address,
name : string,
salt : int,
name_fee : int,
sign : signature) : unit =
AENS.claim(addr, name, salt, name_fee, signature = sign)
function signedClaim(addr : address,
name : string,
salt : int,
sign : signature) : () =
AENS.claim(addr, name, salt, signature = sign)
// TODO: update() -- how to handle pointers?
stateful entrypoint transfer(owner : address,
new_owner : address,
name : string) : unit =
AENS.transfer(owner, new_owner, name)
function transfer(owner : address,
new_owner : address,
name_hash : hash) : () =
AENS.transfer(owner, new_owner, name_hash)
stateful entrypoint signedTransfer(owner : address,
new_owner : address,
name : string,
sign : signature) : unit =
AENS.transfer(owner, new_owner, name, signature = sign)
function signedTransfer(owner : address,
new_owner : address,
name_hash : hash,
sign : signature) : () =
AENS.transfer(owner, new_owner, name_hash, signature = sign)
stateful entrypoint revoke(owner : address,
name : string) : unit =
AENS.revoke(owner, name)
function revoke(owner : address,
name_hash : hash) : () =
AENS.revoke(owner, name_hash)
function signedRevoke(owner : address,
name_hash : hash,
sign : signature) : () =
AENS.revoke(owner, name_hash, signature = sign)
stateful entrypoint signedRevoke(owner : address,
name : string,
sign : signature) : unit =
AENS.revoke(owner, name, signature = sign)
test/contracts/aeproof.aes
+6 -4
View File
@@ -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, "false")
let _ = require(aetoken.balanceOf(caller()) > 0)
let proofHash: uint = calculateHash(document)
let proof : proof = Map.get_(proofHash, state().proofs)
let _ = require(proof.owner == #0, "false")
let _ = require(proof.owner == #0)
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, "false")
let _ = require(proof.owner != #0)
proof
function getProofByHash(hash: uint) : proof =
let proof = Map.get_(hash, state().proofs)
let _ = require(proof.owner != #0, "false")
let _ = require(proof.owner != #0)
proof
@@ -141,3 +141,5 @@ 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
+6 -1
View File
@@ -24,7 +24,7 @@ contract AllSyntax =
if(valWithType(Map.empty) == None)
print(42 mod 10 * 5 / 3)
function funWithType(x : int, y) : int * list(int) = (x, 0 :: [y] ++ [])
function funWithType(x : int, y) : (int, list(int)) = (x, 0 :: [y] ++ [])
function funNoType() =
let foo = (x, y : bool) =>
if (! (y && x =< 0x0b || true)) [x]
@@ -36,6 +36,11 @@ contract AllSyntax =
(x, [y, z]) => bar({x = z, y = -y + - -z * (-1)})
(x, 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
+13 -13
View File
@@ -1,33 +1,33 @@
contract Remote =
entrypoint foo : () => unit
function foo : () => ()
contract AddressLiterals =
entrypoint addr1() : bytes(32) =
function addr1() : bytes(32) =
ak_2gx9MEFxKvY9vMG5YnqnXWv1hCsX7rgnfvBLJS4aQurustR1rt
entrypoint addr2() : Remote =
function addr2() : Remote =
ak_2gx9MEFxKvY9vMG5YnqnXWv1hCsX7rgnfvBLJS4aQurustR1rt
entrypoint addr3() : oracle(int, bool) =
function addr3() : oracle(int, bool) =
ak_2gx9MEFxKvY9vMG5YnqnXWv1hCsX7rgnfvBLJS4aQurustR1rt
entrypoint oracle1() : oracle_query(int, bool) =
function oracle1() : oracle_query(int, bool) =
ok_2YNyxd6TRJPNrTcEDCe9ra59SVUdp9FR9qWC5msKZWYD9bP9z5
entrypoint oracle2() : bytes(32) =
function oracle2() : bytes(32) =
ok_2YNyxd6TRJPNrTcEDCe9ra59SVUdp9FR9qWC5msKZWYD9bP9z5
entrypoint oracle3() : Remote =
function oracle3() : Remote =
ok_2YNyxd6TRJPNrTcEDCe9ra59SVUdp9FR9qWC5msKZWYD9bP9z5
entrypoint query1() : oracle(int, bool) =
function query1() : oracle(int, bool) =
oq_2oRvyowJuJnEkxy58Ckkw77XfWJrmRgmGaLzhdqb67SKEL1gPY
entrypoint query2() : bytes(32) =
function query2() : bytes(32) =
oq_2oRvyowJuJnEkxy58Ckkw77XfWJrmRgmGaLzhdqb67SKEL1gPY
entrypoint query3() : Remote =
function query3() : Remote =
oq_2oRvyowJuJnEkxy58Ckkw77XfWJrmRgmGaLzhdqb67SKEL1gPY
entrypoint contr1() : address =
function contr1() : address =
ct_Ez6MyeTMm17YnTnDdHTSrzMEBKmy7Uz2sXu347bTDPgVH2ifJ
entrypoint contr2() : oracle(int, bool) =
function contr2() : oracle(int, bool) =
ct_Ez6MyeTMm17YnTnDdHTSrzMEBKmy7Uz2sXu347bTDPgVH2ifJ
entrypoint contr3() : bytes(32) =
function contr3() : bytes(32) =
ct_Ez6MyeTMm17YnTnDdHTSrzMEBKmy7Uz2sXu347bTDPgVH2ifJ
test/contracts/bad_events.aes
+9 -7
View File
@@ -6,18 +6,20 @@ contract Events =
datatype event =
Event1(indexed alias_int, indexed int, string)
| Event2(alias_string, indexed alias_address)
| BadEvent1(indexed string)
| BadEvent2(indexed alias_string)
| BadEvent1(indexed string, string)
| BadEvent2(indexed int, int)
| BadEvent3(indexed alias_string, string)
| BadEvent4(indexed int, alias_address)
entrypoint f1(x : int, y : string) =
function f1(x : int, y : string) =
Chain.event(Event1(x, x+1, y))
entrypoint f2(s : string) =
function f2(s : string) =
Chain.event(Event2(s, Call.caller))
entrypoint f3(x : int) =
function 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)
function i2s(i : int) = Int.to_str(i)
function a2s(a : address) = Address.to_str(a)
test/contracts/bad_events2.aes
+6 -5
View File
@@ -8,16 +8,17 @@ contract Events =
| Event2(alias_string, indexed alias_address)
| BadEvent1(string, string)
| BadEvent2(indexed int, indexed int, indexed int, indexed address)
| BadEvent3(address, int)
entrypoint f1(x : int, y : string) =
function f1(x : int, y : string) =
Chain.event(Event1(x, x+1, y))
entrypoint f2(s : string) =
function f2(s : string) =
Chain.event(Event2(s, Call.caller))
entrypoint f3(x : int) =
function 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)
function i2s(i : int) = Int.to_str(i)
function a2s(a : address) = Address.to_str(a)
test/contracts/bad_include_and_ns.aes
+1 -1
View File
@@ -3,4 +3,4 @@ contract Bad =
namespace Foo =
function foo() = 42
entrypoint foo() = 43
function foo() = 43
test/contracts/bad_init_state_access.aes
-13
View File
@@ -1,13 +0,0 @@
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
+5 -3
View File
@@ -2,9 +2,9 @@
contract BasicAuth =
record state = { nonce : int, owner : address }
entrypoint init() = { nonce = 1, owner = Call.caller }
function init() = { nonce = 1, owner = Call.caller }
stateful entrypoint authorize(n : int, s : signature) : bool =
function 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 })
@@ -12,6 +12,8 @@ contract BasicAuth =
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) =
function to_sign(h : hash, n : int) =
Crypto.blake2b((h, n))
private function require(b : bool, err : string) =
if(!b) abort(err)
test/contracts/bitcoin_auth.aes
+5 -3
View File
@@ -1,9 +1,9 @@
contract BitcoinAuth =
record state = { nonce : int, owner : bytes(64) }
entrypoint init(owner' : bytes(64)) = { nonce = 1, owner = owner' }
function init(owner' : bytes(64)) = { nonce = 1, owner = owner' }
stateful entrypoint authorize(n : int, s : signature) : bool =
function 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 })
@@ -11,6 +11,8 @@ contract BitcoinAuth =
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 =
function to_sign(h : hash, n : int) : hash =
Crypto.blake2b((h, n))
private function require(b : bool, err : string) =
if(!b) abort(err)
test/contracts/builtin_bug.aes
+2 -2
View File
@@ -5,8 +5,8 @@ contract BuiltinBug =
record state = {proofs : map(address, list(string))}
entrypoint init() = {proofs = {}}
public function init() = {proofs = {}}
stateful entrypoint createProof(hash : string) =
public stateful function createProof(hash : string) =
put( state{ proofs[Call.caller] = hash :: state.proofs[Call.caller] } )
test/contracts/builtin_map_get_bug.aes
+7 -3
View File
@@ -1,8 +1,12 @@
contract TestContract =
record state = {_allowed : map(address, map(address, int))}
record state = {
_allowed : map(address, map(address, int))}
entrypoint init() = {_allowed = {}}
public stateful function init() = {
_allowed = {}}
public stateful function approve(spender: address, value: int) : bool =
stateful entrypoint approve(spender: address, value: int) : bool =
put(state{_allowed[Call.caller][spender] = value})
true
test/contracts/bytes_equality.aes
-18
View File
@@ -1,18 +0,0 @@
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
-8
View File
@@ -1,8 +0,0 @@
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/complex_types.aes
+25 -25
View File
@@ -1,78 +1,78 @@
contract Remote =
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))
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))
contract ComplexTypes =
record state = { worker : Remote }
entrypoint init(worker) = {worker = worker}
function init(worker) = {worker = worker}
entrypoint sum_acc(xs, n) =
function sum_acc(xs, n) =
switch(xs)
[] => n
x :: xs => sum_acc(xs, x + n)
// Sum a list of integers
entrypoint sum(xs : list(int)) =
function sum(xs : list(int)) =
sum_acc(xs, 0)
entrypoint up_to_acc(n, xs) =
function up_to_acc(n, xs) =
switch(n)
0 => xs
_ => up_to_acc(n - 1, n :: xs)
entrypoint up_to(n) = up_to_acc(n, [])
function up_to(n) = up_to_acc(n, [])
record answer('a) = {label : string, result : 'a}
entrypoint remote_triangle(worker, n) : answer(int) =
function remote_triangle(worker, n) : answer(int) =
let xs = worker.up_to(gas = 100000, n)
let t = worker.sum(xs)
{ label = "answer:", result = t }
entrypoint remote_list(n) : list(int) =
function remote_list(n) : list(int) =
state.worker.up_to(n)
entrypoint some_string() = "string"
function some_string() = "string"
entrypoint remote_string() : string =
function remote_string() : string =
state.worker.some_string()
entrypoint pair(x : int, y : string) = (x, y)
function pair(x : int, y : string) = (x, y)
entrypoint remote_pair(n : int, s : string) : int * string =
function remote_pair(n : int, s : string) : (int, string) =
state.worker.pair(gas = 10000, n, s)
entrypoint map(f, xs) =
function map(f, xs) =
switch(xs)
[] => []
x :: xs => f(x) :: map(f, xs)
entrypoint squares(n) =
function squares(n) =
map((i) => (i, i * i), up_to(n))
entrypoint remote_squares(n) : list(int * int) =
function remote_squares(n) : list((int, int)) =
state.worker.squares(n)
// option types
entrypoint filter_some(xs : list(option(int))) : list(int) =
function filter_some(xs : list(option(int))) : list(int) =
switch(xs)
[] => []
None :: ys => filter_some(ys)
Some(x) :: ys => x :: filter_some(ys)
entrypoint remote_filter_some(xs : list(option(int))) : list(int) =
function remote_filter_some(xs : list(option(int))) : list(int) =
state.worker.filter_some(xs)
entrypoint all_some(xs : list(option(int))) : option(list(int)) =
function 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
entrypoint remote_all_some(xs : list(option(int))) : option(list(int)) =
function remote_all_some(xs : list(option(int))) : option(list(int)) =
state.worker.all_some(gas = 10000, xs)
test/contracts/counter.aes
+3 -3
View File
@@ -3,7 +3,7 @@ contract Counter =
record state = { value : int }
entrypoint init(val) = { value = val }
entrypoint get() = state.value
stateful entrypoint tick() = put(state{ value = state.value + 1 })
function init(val) = { value = val }
function get() = state.value
function tick() = put(state{ value = state.value + 1 })
test/contracts/deadcode.aes
+2 -2
View File
@@ -13,9 +13,9 @@ namespace List =
contract Deadcode =
entrypoint inc1(xs : list(int)) : list(int) =
function inc1(xs : list(int)) : list(int) =
List.map1((x) => x + 1, xs)
entrypoint inc2(xs : list(int)) : list(int) =
function inc2(xs : list(int)) : list(int) =
List.map1((x) => x + 1, xs)
test/contracts/dutch_auction.aes
+6 -3
View File
@@ -10,13 +10,16 @@ contract DutchAuction =
sold : bool }
// Add to work around current lack of predefined functions
stateful function spend(to, amount) =
private 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
entrypoint init(beneficiary, start, decrease) : state =
public function init(beneficiary, start, decrease) : state =
require(start > 0 && decrease > 0, "bad args")
{ start_amount = start,
start_height = Chain.block_height,
@@ -27,7 +30,7 @@ contract DutchAuction =
// -- API
// We are the buyer... interesting case to buy for someone else and keep 10%
stateful entrypoint bid() =
public stateful function bid() =
require( !(state.sold), "sold")
let cost =
state.start_amount - (Chain.block_height - state.start_height) * state.dec
test/contracts/environment.aes
+23 -23
View File
@@ -1,69 +1,69 @@
// Testing primitives for accessing the block chain environment
contract Interface =
entrypoint contract_address : () => address
entrypoint call_origin : () => address
entrypoint call_caller : () => address
entrypoint call_value : () => int
function contract_address : () => address
function call_origin : () => address
function call_caller : () => address
function call_value : () => int
contract Environment =
record state = {remote : Interface}
entrypoint init(remote) = {remote = remote}
function init(remote) = {remote = remote}
stateful entrypoint set_remote(remote) = put({remote = remote})
function set_remote(remote) = put({remote = remote})
// -- Information about the this contract ---
// Address
entrypoint contract_address() : address = Contract.address
entrypoint nested_address(who) : address =
function contract_address() : address = Contract.address
function nested_address(who) : address =
who.contract_address(gas = 1000)
// Balance
entrypoint contract_balance() : int = Contract.balance
function contract_balance() : int = Contract.balance
// -- Information about the current call ---
// Origin
entrypoint call_origin() : address = Call.origin
entrypoint nested_origin() : address =
function call_origin() : address = Call.origin
function nested_origin() : address =
state.remote.call_origin()
// Caller
entrypoint call_caller() : address = Call.caller
entrypoint nested_caller() : address =
function call_caller() : address = Call.caller
function nested_caller() : address =
state.remote.call_caller()
// Value
entrypoint call_value() : int = Call.value
stateful entrypoint nested_value(value : int) : int =
function call_value() : int = Call.value
function nested_value(value : int) : int =
state.remote.call_value(value = value / 2)
// Gas price
entrypoint call_gas_price() : int = Call.gas_price
function call_gas_price() : int = Call.gas_price
// -- Information about the chain ---
// Account balances
entrypoint get_balance(acct : address) : int = Chain.balance(acct)
function get_balance(acct : address) : int = Chain.balance(acct)
// Block hash
entrypoint block_hash(height : int) : option(hash) = Chain.block_hash(height)
function block_hash(height : int) : int = Chain.block_hash(height)
// Coinbase
entrypoint coinbase() : address = Chain.coinbase
function coinbase() : address = Chain.coinbase
// Block timestamp
entrypoint timestamp() : int = Chain.timestamp
function timestamp() : int = Chain.timestamp
// Block height
entrypoint block_height() : int = Chain.block_height
function block_height() : int = Chain.block_height
// Difficulty
entrypoint difficulty() : int = Chain.difficulty
function difficulty() : int = Chain.difficulty
// Gas limit
entrypoint gas_limit() : int = Chain.gas_limit
function gas_limit() : int = Chain.gas_limit
test/contracts/erc20_token.aes
+3
View File
@@ -77,6 +77,9 @@ 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
+16 -34
View File
@@ -1,40 +1,22 @@
contract Remote =
entrypoint dummy : () => unit
contract Events =
type alias_int = int
type alias_address = address
type alias_string = string
// 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)
datatype event =
Event1(indexed alias_int, indexed int, string)
| Event2(alias_string, indexed alias_address)
// | BadEvent1(indexed string, string)
// | BadEvent2(indexed int, int)
// Valid payload types
type data1 = string
type data2 = signature // bytes(64)
type data3 = bytes(65)
function f1(x : int, y : string) =
Chain.event(Event1(x, x+1, y))
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 f2(s : string) =
Chain.event(Event2(s, Call.caller))
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 f3(x : int) =
Chain.event(Event1(x, x + 2, Int.to_str(x + 7)))
function i2s(i : int) = Int.to_str(i)
function a2s(a : address) = Address.to_str(a)
test/contracts/factorial.aes
+4 -4
View File
@@ -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 =
entrypoint fac : (int) => int
function fac : (int) => int
contract Factorial =
record state = {worker : FactorialServer}
entrypoint init(worker) = {worker = worker}
function init(worker) = {worker = worker}
stateful entrypoint set_worker(worker) = put(state{worker = worker})
function set_worker(worker) = put(state{worker = worker})
entrypoint fac(x : int) : int =
function fac(x : int) : int =
if(x == 0) 1
else x * state.worker.fac(x - 1)
test/contracts/field_parse_error.aes
-5
View File
@@ -1,5 +0,0 @@
contract Fail =
record pt = {x : int, y : int}
record r = {p : pt}
function fail() = {p.x = 0, p.y = 0}
test/contracts/funargs.aes
-47
View File
@@ -1,47 +0,0 @@
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 : unit) =
t
entrypoint due(t : Chain.ttl) =
true
test/contracts/functions.aes
-15
View File
@@ -1,15 +0,0 @@
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
+10 -7
View File
@@ -12,20 +12,23 @@ contract FundMe =
deadline : int,
goal : int }
stateful function spend(args : spend_args) =
private function require(b : bool, err : string) =
if(!b) abort(err)
private function spend(args : spend_args) =
Chain.spend(args.recipient, args.amount)
entrypoint init(beneficiary, deadline, goal) : state =
public function init(beneficiary, deadline, goal) : state =
{ contributions = {},
beneficiary = beneficiary,
deadline = deadline,
total = 0,
goal = goal }
function is_contributor(addr) =
private function is_contributor(addr) =
Map.member(addr, state.contributions)
stateful entrypoint contribute() =
public stateful function contribute() =
if(Chain.block_height >= state.deadline)
spend({ recipient = Call.caller, amount = Call.value }) // Refund money
false
@@ -36,7 +39,7 @@ contract FundMe =
total @ tot = tot + Call.value })
true
stateful entrypoint withdraw() =
public stateful function withdraw() =
if(Chain.block_height < state.deadline)
abort("Cannot withdraw before deadline")
if(Call.caller == state.beneficiary)
@@ -46,13 +49,13 @@ contract FundMe =
else
abort("Not a contributor or beneficiary")
stateful function withdraw_beneficiary() =
private stateful function withdraw_beneficiary() =
require(state.total >= state.goal, "Project was not funded")
spend({recipient = state.beneficiary,
amount = Contract.balance })
put(state{ beneficiary = ak_11111111111111111111111111111111273Yts })
stateful function withdraw_contributor() =
private stateful function withdraw_contributor() =
if(state.total >= state.goal)
abort("Project was funded")
let to = Call.caller
test/contracts/identity.aes
+1 -1
View File
@@ -1,3 +1,3 @@
contract Identity =
entrypoint main (x:int) = x
function main (x:int) = x
test/contracts/include.aes
+2 -2
View File
@@ -2,8 +2,8 @@ include "included.aes"
include "../contracts/included2.aes"
contract Include =
entrypoint foo() =
function foo() =
Included.foo() < Included2a.bar()
entrypoint bar() =
function bar() =
Included2b.foo() > Included.foo()
test/contracts/init_type_error.aes
+2 -2
View File
@@ -3,6 +3,6 @@ contract InitTypeError =
type state = map(int, int)
// Check that the compiler catches ill-typed init entrypoint
entrypoint init() = "not the right type!"
// Check that the compiler catches ill-typed init function
function init() = "not the right type!"
test/contracts/maps.aes
+56 -56
View File
@@ -4,97 +4,97 @@ contract Maps =
record state = { map_i : map(int, pt),
map_s : map(string, pt) }
entrypoint init() = { map_i = {}, map_s = {} }
function init() = { map_i = {}, map_s = {} }
entrypoint get_state() = state
function get_state() = state
// {[k] = v}
entrypoint map_i() =
function map_i() =
{ [1] = {x = 1, y = 2},
[2] = {x = 3, y = 4},
[3] = {x = 5, y = 6} }
entrypoint map_s() =
function map_s() =
{ ["one"] = {x = 1, y = 2},
["two"] = {x = 3, y = 4},
["three"] = {x = 5, y = 6} }
stateful entrypoint map_state_i() = put(state{ map_i = map_i() })
stateful entrypoint map_state_s() = put(state{ map_s = map_s() })
function map_state_i() = put(state{ map_i = map_i() })
function map_state_s() = put(state{ map_s = map_s() })
// m[k]
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)
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)
// m[k = v]
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)
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)
// m{[k] = v}
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) })
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) })
// m{f[k].x = v}
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 })
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 })
// m{[k] @ x = v }
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 })
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 })
// m{[k = def] @ x = v }
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 }
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 }
// Map.member
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)
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)
// Map.lookup
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)
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)
// Map.lookup_default
entrypoint lookup_def_i(k, m : map(int, pt), def : pt) =
function lookup_def_i(k, m : map(int, pt), def : pt) =
Map.lookup_default(k, m, def)
entrypoint lookup_def_s(k, m : map(string, pt), def : pt) =
function lookup_def_s(k, m : map(string, pt), def : pt) =
Map.lookup_default(k, m, 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)
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)
// Map.delete
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) })
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) })
// Map.size
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)
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)
// Map.to_list
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)
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)
// Map.from_list
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) })
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) })
test/contracts/missing_fields_in_record_expression.aes
+3 -3
View File
@@ -3,6 +3,6 @@ contract MissingFieldsInRecordExpr =
record r('a) = {x : int, y : string, z : 'a}
type alias('a) = r('a)
entrypoint fail1() = { x = 0 }
entrypoint fail2(z : 'a) : r('a) = { y = "string", z = z }
entrypoint fail3() : alias(int) = { x = 0, z = 1 }
function fail1() = { x = 0 }
function fail2(z : 'a) : r('a) = { y = "string", z = z }
function fail3() : alias(int) = { x = 0, z = 1 }
test/contracts/missing_state_type.aes
+1 -1
View File
@@ -2,5 +2,5 @@
contract MissingStateType =
// Check that we get a type error also for implicit state
entrypoint init() = "should be ()"
function init() = "should be ()"
test/contracts/modifier_checks.aes
-12
View File
@@ -1,12 +0,0 @@
namespace Lib =
entrypoint foo() = ()
contract Remote =
public function foo : () => unit
function bla() = ()
contract Contract =
public function foo() = ()
public private stateful function all_the_things() = ()
private entrypoint wha() = ()
test/contracts/name_clash.aes
+10 -11
View File
@@ -1,17 +1,16 @@
contract NameClash =
entrypoint double_proto : () => int
entrypoint double_proto : () => int
function double_proto : () => int
function double_proto : () => int
entrypoint proto_and_def : int => int
entrypoint proto_and_def(n) = n + 1
function proto_and_def : int => int
function proto_and_def(n) = n + 1
entrypoint double_def(x) = x
entrypoint double_def(y) = 0
function double_def(x) = x
function double_def(y) = 0
// 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
// abort, put and state are builtin
function abort() : int = 0
function put(x) = x
function state(x, y) = x + y
test/contracts/namespace_bug.aes
-18
View File
@@ -1,18 +0,0 @@
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
+1 -1
View File
@@ -2,4 +2,4 @@
// You can't shadow existing contracts or namespaces.
contract Call =
entrypoint whatever() = ()
function whatever() = ()
test/contracts/nodeadcode.aes
+2 -2
View File
@@ -13,9 +13,9 @@ namespace List =
contract Deadcode =
entrypoint inc1(xs : list(int)) : list(int) =
function inc1(xs : list(int)) : list(int) =
List.map1((x) => x + 1, xs)
entrypoint inc2(xs : list(int)) : list(int) =
function inc2(xs : list(int)) : list(int) =
List.map2((x) => x + 1, xs)
test/contracts/oracles.aes
+23 -21
View File
@@ -9,31 +9,31 @@ contract Oracles =
type oracle_id = oracle(query_t, answer_t)
type query_id = oracle_query(query_t, answer_t)
stateful entrypoint registerOracle(acct : address,
function registerOracle(acct : address,
qfee : fee,
ttl : ttl) : oracle_id =
Oracle.register(acct, qfee, ttl)
stateful entrypoint registerIntIntOracle(acct : address,
function registerIntIntOracle(acct : address,
qfee : fee,
ttl : ttl) : oracle(int, int) =
Oracle.register(acct, qfee, ttl)
stateful entrypoint registerStringStringOracle(acct : address,
function registerStringStringOracle(acct : address,
qfee : fee,
ttl : ttl) : oracle(string, string) =
Oracle.register(acct, qfee, ttl)
stateful entrypoint signedRegisterOracle(acct : address,
function signedRegisterOracle(acct : address,
sign : signature,
qfee : fee,
ttl : ttl) : oracle_id =
Oracle.register(acct, qfee, ttl, signature = sign)
entrypoint queryFee(o : oracle_id) : fee =
function queryFee(o : oracle_id) : fee =
Oracle.query_fee(o)
stateful entrypoint createQuery(o : oracle_id,
function 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!
stateful entrypoint unsafeCreateQuery(o : oracle_id,
function 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!
stateful entrypoint unsafeCreateQueryThenErr(o : oracle_id,
function unsafeCreateQueryThenErr(o : oracle_id,
q : query_t,
qfee : fee,
qttl : ttl,
@@ -59,52 +59,54 @@ contract Oracles =
require(qfee >= 100000000000000000, "causing a late error")
res
stateful entrypoint extendOracle(o : oracle_id,
ttl : ttl) : unit =
function extendOracle(o : oracle_id,
ttl : ttl) : () =
Oracle.extend(o, ttl)
stateful entrypoint signedExtendOracle(o : oracle_id,
function signedExtendOracle(o : oracle_id,
sign : signature, // Signed oracle address
ttl : ttl) : unit =
ttl : ttl) : () =
Oracle.extend(o, signature = sign, ttl)
stateful entrypoint respond(o : oracle_id,
function respond(o : oracle_id,
q : query_id,
r : answer_t) : unit =
r : answer_t) : () =
Oracle.respond(o, q, r)
stateful entrypoint signedRespond(o : oracle_id,
function signedRespond(o : oracle_id,
q : query_id,
sign : signature,
r : answer_t) : unit =
r : answer_t) : () =
Oracle.respond(o, q, signature = sign, r)
entrypoint getQuestion(o : oracle_id,
function getQuestion(o : oracle_id,
q : query_id) : query_t =
Oracle.get_question(o, q)
entrypoint hasAnswer(o : oracle_id,
function hasAnswer(o : oracle_id,
q : query_id) =
switch(Oracle.get_answer(o, q))
None => false
Some(_) => true
entrypoint getAnswer(o : oracle_id,
function 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)
stateful entrypoint complexOracle(question) =
function 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)
stateful entrypoint signedComplexOracle(question, sig) =
function 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
+2
View File
@@ -20,3 +20,5 @@ contract OraclesGas =
Oracle.respond(o, q, answer)
()
private function require(b : bool, err : string) =
if(!b) abort(err)
test/contracts/oracles_no_vm.aes
+3 -1
View File
@@ -21,7 +21,7 @@ contract Oracles =
function respond(o : oracle_id,
q : query_id,
sign : signature,
r : answer_t) : unit =
r : answer_t) : () =
Oracle.respond(o, q, signature = sign, r)
@@ -33,3 +33,5 @@ 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
+9 -9
View File
@@ -1,27 +1,27 @@
contract Remote1 =
entrypoint main : (int) => int
function main : (int) => int
contract Remote2 =
entrypoint call : (Remote1, int) => int
function call : (Remote1, int) => int
contract Remote3 =
entrypoint get : () => int
entrypoint tick : () => unit
function get : () => int
function tick : () => ()
contract RemoteCall =
stateful entrypoint call(r : Remote1, x : int) : int =
function call(r : Remote1, x : int) : int =
r.main(gas = 10000, value = 10, x)
entrypoint staged_call(r1 : Remote1, r2 : Remote2, x : int) =
function staged_call(r1 : Remote1, r2 : Remote2, x : int) =
r2.call(r1, x)
entrypoint increment(r3 : Remote3) =
function increment(r3 : Remote3) =
r3.tick()
entrypoint get(r3 : Remote3) =
function get(r3 : Remote3) =
r3.get()
entrypoint plus(x, y) = x + y
function plus(x, y) = x + y
test/contracts/remote_oracles.aes
+99
View File
@@ -0,0 +1,99 @@
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
View File
@@ -1,4 +1,3 @@
contract Simple =
type t = int => int
entrypoint dummy() = ()
test/contracts/simple_storage.aes
+5 -5
View File
@@ -6,11 +6,11 @@
contract SimpleStorage {
uint storedData
entrypoint set(uint x) {
function set(uint x) {
storedData = x
}
entrypoint get() constant returns (uint) {
function get() constant returns (uint) {
return storedData
}
}
@@ -20,9 +20,9 @@ contract SimpleStorage =
record state = { data : int }
entrypoint init(value : int) : state = { data = value }
function init(value : int) : state = { data = value }
entrypoint get() : int = state.data
function get() : int = state.data
stateful entrypoint set(value : int) =
function set(value : int) =
put(state{data = value})
test/contracts/spend_test.aes
+7 -7
View File
@@ -1,26 +1,26 @@
contract SpendContract =
entrypoint withdraw : (int) => int
function withdraw : (int) => int
contract SpendTest =
stateful entrypoint spend(to, amount) =
function spend(to, amount) =
let total = Contract.balance
Chain.spend(to, amount)
total - amount
stateful entrypoint withdraw(amount) : int =
function withdraw(amount) : int =
spend(Call.caller, amount)
stateful entrypoint withdraw_from(account, amount) =
function withdraw_from(account, amount) =
account.withdraw(amount)
withdraw(amount)
stateful entrypoint spend_from(from, to, amount) =
function spend_from(from, to, amount) =
from.withdraw(amount)
Chain.spend(to, amount)
Chain.balance(to)
entrypoint get_balance() = Contract.balance
entrypoint get_balance_of(a) = Chain.balance(a)
function get_balance() = Contract.balance
function get_balance_of(a) = Chain.balance(a)
test/contracts/stack.aes
+6 -6
View File
@@ -6,24 +6,24 @@ contract Stack =
record state = { stack : stack(string),
size : int }
entrypoint init(ss : list(string)) = { stack = ss, size = length(ss) }
function init(ss : list(string)) = { stack = ss, size = length(ss) }
function length(xs) =
private function length(xs) =
switch(xs)
[] => 0
_ :: xs => length(xs) + 1
stateful entrypoint pop() : string =
stateful function pop() : string =
switch(state.stack)
s :: ss =>
put(state{ stack = ss, size = state.size - 1 })
s
stateful entrypoint push(s) =
stateful function push(s) =
put(state{ stack = s :: state.stack, size = state.size + 1 })
state.size
entrypoint all() = state.stack
function all() = state.stack
entrypoint size() = state.size
function size() = state.size
test/contracts/state_handling.aes
+44 -44
View File
@@ -1,70 +1,70 @@
contract Remote =
record rstate = { i : int, s : string, m : map(int, int) }
entrypoint look_at : (rstate) => unit
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)
function look_at : (rstate) => ()
function return_s : (bool) => string
function return_m : (bool) => map(int, int)
function get : (rstate) => rstate
function get_i : (rstate) => int
function get_s : (rstate) => string
function 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
function fun_update_i : (rstate, int) => rstate
function fun_update_s : (rstate, string) => rstate
function fun_update_m : (rstate, map(int, int)) => rstate
function fun_update_mk : (rstate, int, int) => rstate
contract StateHandling =
type state = Remote.rstate
entrypoint init(r : Remote, i : int) =
function init(r : Remote, i : int) =
let state0 = { i = 0, s = "undefined", m = {} }
r.fun_update_i(state0, i)
entrypoint read() = state
entrypoint read_i() = state.i
entrypoint read_s() = state.s
entrypoint read_m() = state.m
function read() = state
function read_i() = state.i
function read_s() = state.s
function read_m() = state.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 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 })
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) =
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) =
let x = r.return_s(big)
String.length(x)
entrypoint return_it_m(r : Remote, big : bool) =
function return_it_m(r : Remote, big : bool) =
let x = r.return_m(big)
Map.size(x)
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(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_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 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)
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))
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))
// remote called
entrypoint look_at(s : state) = ()
function look_at(s : state) = ()
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 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 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} }
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} }
test/contracts/stateful.aes
-54
View File
@@ -1,54 +0,0 @@
contract Remote =
stateful entrypoint remote_spend : (address, int) => unit
entrypoint remote_pure : int => int
contract Stateful =
function pure(x) = x + 1
stateful function local_spend(a) =
Chain.spend(a, 1000)
// Non-stateful functions cannot mention stateful functions
entrypoint fail1(a : address) = Chain.spend(a, 1000)
entrypoint fail2(a : address) = local_spend(a)
entrypoint fail3(a : address) =
let foo = Chain.spend
foo(a, 1000)
// Private functions must also be annotated
private function fail4(a) = Chain.spend(a, 1000)
// If annotated, stateful functions are allowed
stateful entrypoint ok1(a : address) = Chain.spend(a, 1000)
// And pure functions are always allowed
stateful entrypoint ok2(a : address) = pure(5)
stateful entrypoint ok3(a : address) =
let foo = pure
foo(5)
// No error here (fail4 is annotated as not stateful)
entrypoint ok4(a : address) = fail4(a)
// Lamdbas are checked at the construction site
function fail5() : address => unit = (a) => Chain.spend(a, 1000)
// .. so you can pass a stateful lambda to a non-stateful higher-order
// function:
function apply(f : 'a => 'b, x) = f(x)
stateful entrypoint ok5(a : address) =
apply((val) => Chain.spend(a, val), 1000)
// It doesn't matter if remote calls are stateful or not
entrypoint ok6(r : Remote) = r.remote_spend(Contract.address, 1000)
entrypoint ok7(r : Remote) = r.remote_pure(5)
// But you can't send any tokens if not stateful
entrypoint fail6(r : Remote) = r.remote_spend(value = 1000, Contract.address, 1000)
entrypoint fail7(r : Remote) = r.remote_pure(value = 1000, 5)
entrypoint fail8(r : Remote) =
let foo = r.remote_pure
foo(value = 1000, 5)
entrypoint ok8(r : Remote) = r.remote_spend(Contract.address, 1000, value = 0)
test/contracts/strings.aes
+2 -2
View File
@@ -1,4 +1,4 @@
contract Strings =
entrypoint str_len(s) = String.length(s)
entrypoint str_concat(s1, s2) = String.concat(s1, s2)
function str_len(s) = String.length(s)
function str_concat(s1, s2) = String.concat(s1, s2)
test/contracts/stub.aes
-2
View File
@@ -1,2 +0,0 @@
contract Stub =
entrypoint foo : (int) => int
test/contracts/test.aes
+4 -4
View File
@@ -91,10 +91,10 @@ contract Identity =
// }
// let id(x) = x
// let main(xs) = map(double,xs)
entrypoint z(f,x) = x
function s(n) = (f,x)=>f(n(f,x))
function add(m,n) = (f,x)=>m(f,n(f,x))
entrypoint main(_) =
function z(f,x) = x
private function s(n) = (f,x)=>f(n(f,x))
private function add(m,n) = (f,x)=>m(f,n(f,x))
function main(_) =
let three=s(s(s(z)))
add(three,three)
(((i)=>i+1),0)
test/contracts/tuple_match.aes
-36
View File
@@ -1,36 +0,0 @@
contract TuplesMatch =
entrypoint tuplify3() = (t) => switch(t)
(x, y, z) => 3
entrypoint fst(p : int * string) =
switch(p)
(x, y) => x
entrypoint fst'(p : int * string) =
switch(p)
(x, _) => x
entrypoint snd(p : int * string) =
switch(p)
(x, y) => y
entrypoint snd'(p : int * string) =
switch(p)
(_, y) => y
entrypoint sum(p) =
switch(p)
(x, y) => x + y
entrypoint swap(p : int * string) =
switch(p)
(x, y) => (y, x)
entrypoint id(p : int * int * string) =
switch(p)
(x, y, z) => (x, y, z)
entrypoint nest(p : (int * int) * string) =
switch(p)
(xy, z) => switch(xy) (x, y) => (x, y, z)
entrypoint deep(p : (int * int) * (int * int)) =
switch(p)
((x, y), (z, w)) => (x, y, z, w)
entrypoint deep_sum(p : (int * int) * (int * int)) =
switch(p)
((x, y), (z, w)) => x + y + z + w
test/contracts/type_clash.aes
+2 -2
View File
@@ -2,12 +2,12 @@
contract Remote =
type themap = map(int, string)
entrypoint foo : () => themap
function foo : () => themap
contract Main =
type themap = map(string, int)
// Should fail
entrypoint foo(r : Remote) : themap = r.foo()
function foo(r : Remote) : themap = r.foo()
test/contracts/type_errors.aes
+15 -32
View File
@@ -6,54 +6,37 @@ contract Test =
record r2 = { z : int, w : int }
record r3 = { x : int, z : int }
entrypoint set_x(r : r, z) = r{ x["foo"] @ x = x + 1 }
function set_x(r : r, z) = r{ x["foo"] @ x = x + 1 }
entrypoint bla(m : map(string, int)) = { [0] = "bla", ["foo"] = "" }
function bla(m : map(string, int)) = { [0] = "bla", ["foo"] = "" }
entrypoint foo(r) = r { y = 0 }
entrypoint bar() = { y = "foo", z = 0 }
entrypoint baz() = { y = "foo", w = 0 }
function foo(r) = r { y = 0 }
function bar() = { y = "foo", z = 0 }
function baz() = { y = "foo", w = 0 }
entrypoint foo1() = zz
function foo1() = zz
entrypoint test1() : string = { y = 0 }
entrypoint test2(x : string) = x { y = 0 }
entrypoint test3(x : string) = x { y @ y = y + 1 }
entrypoint test4(x : string) : int = x.y
function test1() : string = { y = 0 }
function test2(x : string) = x { y = 0 }
function test3(x : string) = x { y @ y = y + 1 }
function test4(x : string) : int = x.y
entrypoint test5(xs) =
function test5(xs) =
switch(xs)
x :: x => x
[] => 0
entrypoint case_pat(xs) =
function case_pat(xs) =
switch(xs)
[] => 0
x :: xs => "x"
entrypoint foo2(m : map(string, int)) = m{ [1] = "bla" }
function foo2(m : map(string, int)) = m{ [1] = "bla" }
entrypoint bad_if(x, y : int, w : int, z : string) =
function bad_if(x, y : int, w : int, z : string) =
if(x) y
elif(x) w
else z
entrypoint type_error(r, x) =
function type_error(r, x) =
set_x(set_x(x, r), x)
entrypoint repeated_arg(x : int, y, x : string, y : bool) : string = x
entrypoint missing1() =
let x = 0
entrypoint missing_fun1() =
let f(x) = x
entrypoint missing2() =
let x = 0
let y = 0
entrypoint missing_fun2() =
let f() = 0
let g() = f()
test/contracts/variant_types.aes
+9 -7
View File
@@ -7,21 +7,23 @@ contract VariantTypes =
datatype color = Red | Green | Blue | Grey(int)
entrypoint init() = Stopped
function init() = Stopped
stateful entrypoint start(bal : int) =
function require(b) = if(!b) abort("required")
function start(bal : int) =
switch(state)
Stopped => put(Started({owner = Call.caller, balance = bal, color = Grey(0)}))
stateful entrypoint stop() =
function stop() =
switch(state)
Started(st) =>
require(Call.caller == st.owner, "required")
require(Call.caller == st.owner)
put(Stopped)
st.balance
entrypoint get_color() = switch(state) Started(st) => st.color
stateful entrypoint set_color(c) = switch(state) Started(st) => put(Started(st{color = c}))
function get_color() = switch(state) Started(st) => st.color
function set_color(c) = switch(state) Started(st) => put(Started(st{color = c}))
entrypoint get_state() = state
function get_state() = state
test/contracts/voting.aes
+1 -1
View File
@@ -8,7 +8,7 @@ contract VotingType =
function delegate : address => unit
function vote : int => unit
function winnerName : unit => string
function currentTally : unit => list(string * int)
function currentTally : unit => list((string, int))
/* Contract implementation */
contract Voting =
test/contracts/withdrawal.aes
+56
View File
@@ -0,0 +1,56 @@
/* Example from Solidity by Example
http://solidity.readthedocs.io/en/develop/common-patterns.html
contract WithdrawalContract {
address public richest
uint public mostSent
mapping (address => uint) pendingWithdrawals
function WithdrawalContract() payable {
richest = msg.sender
mostSent = msg.value
}
function becomeRichest() payable returns (bool) {
if (msg.value > mostSent) {
pendingWithdrawals[richest] += msg.value
richest = msg.sender
mostSent = msg.value
return true
} else {
return false
}
}
function withdraw() {
uint amount = pendingWithdrawals[msg.sender]
// Remember to zero the pending refund before
// sending to prevent re-entrancy attacks
pendingWithdrawals[msg.sender] = 0
msg.sender.transfer(amount)
}
}
*/
contract WithdrawalContract =
record state = { richest : address,
mostSent : uint,
pendingWithdrawals : map(address, uint) }
function becomeRichest() : result(bool) =
if (call().value > state.mostSent)
let totalAmount : uint = Map.get_(state.richest, pendingWithdrawals) + call().value
{state = state{ pendingWithdrawals = Map.insert(state.richest, call().value, state.pendingWithdrawals),
richest = call().sender,
mostSent = call().value },
result = true}
else
{result = false}
function withdraw() =
let amount : uint = Map.get_(call().sender, state.pendingWithdrawals)
{ state.pendingWithdrawals = Map.insert(call().sender, 0, state.pendingWithdrawals),
transactions = spend_tx(amount, call().sender) }