Removes the special casing for foldl

Had to implement both functions as arguments and type place holders (variables) for type constructors. Had to implement functions as a type as well. Still have to figure out how to pass functions around.
2025-04-27 12:54:34 +02:00 · 2025-04-27 12:54:34 +02:00 · 0e8540c611
commit 0e8540c611
parent 46b06dbcf1
16 changed files with 663 additions and 270 deletions
--- a/TODO.md
+++ b/TODO.md
@ -31,3 +31,5 @@
  - Functions don't seem to be a thing on typing level yet?
  - Related to the FIXME in phasm_type3?
  - Type constuctor should also be able to constuct placeholders - somehow.
 - Read https://bytecodealliance.org/articles/multi-value-all-the-wasm
--- a/phasm/codestyle.py
+++ b/phasm/codestyle.py
@ -105,10 +105,6 @@ def expression(inp: ourlang.Expression) -> str:
    if isinstance(inp, ourlang.AccessStructMember):
        return f'{expression(inp.varref)}.{inp.member}'
    if isinstance(inp, ourlang.Fold):
        fold_name = 'foldl' if ourlang.Fold.Direction.LEFT == inp.dir else 'foldr'
        return f'{fold_name}({inp.func.name}, {expression(inp.base)}, {expression(inp.iter)})'
    raise NotImplementedError(expression, inp)
 def statement(inp: ourlang.Statement) -> Statements:
--- a/phasm/compiler.py
+++ b/phasm/compiler.py
@ -4,12 +4,12 @@ This module contains the code to convert parsed Ourlang into WebAssembly code
 import struct
 from typing import List
-from . import codestyle, ourlang, prelude, wasm
+from . import ourlang, prelude, wasm
 from .runtime import calculate_alloc_size, calculate_member_offset
 from .stdlib import alloc as stdlib_alloc
 from .stdlib import types as stdlib_types
 from .stdlib.types import TYPE_INFO_CONSTRUCTED, TYPE_INFO_MAP
-from .type3.functions import TypeVariable
+from .type3.functions import FunctionArgument, TypeVariable
 from .type3.routers import NoRouteForTypeException, TypeApplicationRouter
 from .type3.typeclasses import Type3ClassMethod
 from .type3.types import (
@ -273,6 +273,10 @@ def expression(wgn: WasmGenerator, mod: ourlang.Module, inp: ourlang.Expression)
                type_var_map[type_var] = arg_expr.type3
                continue
            if isinstance(type_var, FunctionArgument):
                # Fixed type, not part of the lookup requirements
                continue
            raise NotImplementedError(type_var, arg_expr.type3)
        router = prelude.PRELUDE_TYPE_CLASS_INSTANCE_METHODS[inp.operator]
@ -298,6 +302,10 @@ def expression(wgn: WasmGenerator, mod: ourlang.Module, inp: ourlang.Expression)
                    type_var_map[type_var] = arg_expr.type3
                    continue
                if isinstance(type_var, FunctionArgument):
                    # Fixed type, not part of the lookup requirements
                    continue
                raise NotImplementedError(type_var, arg_expr.type3)
            router = prelude.PRELUDE_TYPE_CLASS_INSTANCE_METHODS[inp.function]
@ -359,90 +367,8 @@ def expression(wgn: WasmGenerator, mod: ourlang.Module, inp: ourlang.Expression)
        )))
        return
    if isinstance(inp, ourlang.Fold):
        expression_fold(wgn, mod, inp)
        return
    raise NotImplementedError(expression, inp)
 def expression_fold(wgn: WasmGenerator, mod: ourlang.Module, inp: ourlang.Fold) -> None:
    """
    Compile: Fold expression
    """
    assert inp.type3 is not None, TYPE3_ASSERTION_ERROR
    if inp.iter.type3 is not prelude.bytes_:
        raise NotImplementedError(expression_fold, inp, inp.iter.type3)
    wgn.add_statement('nop', comment='acu :: u8')
    acu_var = wgn.temp_var_u8(f'fold_{codestyle.type3(inp.type3)}_acu')
    wgn.add_statement('nop', comment='adr :: bytes*')
    adr_var = wgn.temp_var_i32('fold_i32_adr')
    wgn.add_statement('nop', comment='len :: i32')
    len_var = wgn.temp_var_i32('fold_i32_len')
    wgn.add_statement('nop', comment='acu = base')
    expression(wgn, mod, inp.base)
    wgn.local.set(acu_var)
    wgn.add_statement('nop', comment='adr = adr(iter)')
    expression(wgn, mod, inp.iter)
    wgn.local.set(adr_var)
    wgn.add_statement('nop', comment='len = len(iter)')
    wgn.local.get(adr_var)
    wgn.i32.load()
    wgn.local.set(len_var)
    wgn.add_statement('nop', comment='i = 0')
    idx_var = wgn.temp_var_i32(f'fold_{codestyle.type3(inp.type3)}_idx')
    wgn.i32.const(0)
    wgn.local.set(idx_var)
    wgn.add_statement('nop', comment='if i < len')
    wgn.local.get(idx_var)
    wgn.local.get(len_var)
    wgn.i32.lt_u()
    with wgn.if_():
        # From here on, adr_var is the address of byte we're referencing
        # This is akin to calling stdlib_types.__subscript_bytes__
        # But since we already know we are inside of bounds,
        # can just bypass it and load the memory directly.
        wgn.local.get(adr_var)
        wgn.i32.const(3) # Bytes header -1, since we do a +1 every loop
        wgn.i32.add()
        wgn.local.set(adr_var)
        wgn.add_statement('nop', comment='while True')
        with wgn.loop():
            wgn.add_statement('nop', comment='acu = func(acu, iter[i])')
            wgn.local.get(acu_var)
            # Get the next byte, write back the address
            wgn.local.get(adr_var)
            wgn.i32.const(1)
            wgn.i32.add()
            wgn.local.tee(adr_var)
            wgn.i32.load8_u()
            wgn.add_statement('call', f'${inp.func.name}')
            wgn.local.set(acu_var)
            wgn.add_statement('nop', comment='i = i + 1')
            wgn.local.get(idx_var)
            wgn.i32.const(1)
            wgn.i32.add()
            wgn.local.set(idx_var)
            wgn.add_statement('nop', comment='if i >= len: break')
            wgn.local.get(idx_var)
            wgn.local.get(len_var)
            wgn.i32.lt_u()
            wgn.br_if(0)
    # return acu
    wgn.local.get(acu_var)
 def statement_return(wgn: WasmGenerator, mod: ourlang.Module, inp: ourlang.StatementReturn) -> None:
    """
    Compile: Return statement
--- a/phasm/ourlang.py
+++ b/phasm/ourlang.py
@ -1,7 +1,6 @@
 """
 Contains the syntax tree for ourlang
 """
 import enum
 from typing import Dict, Iterable, List, Optional, Union
 from . import prelude
@ -219,36 +218,6 @@ class AccessStructMember(Expression):
        self.struct_type3 = struct_type3
        self.member = member
 class Fold(Expression):
    """
    A (left or right) fold
    """
    class Direction(enum.Enum):
        """
        Which direction to fold in
        """
        LEFT = 0
        RIGHT = 1
    dir: Direction
    func: 'Function'
    base: Expression
    iter: Expression
    def __init__(
            self,
            dir_: Direction,
            func: 'Function',
            base: Expression,
            iter_: Expression,
        ) -> None:
        super().__init__()
        self.dir = dir_
        self.func = func
        self.base = base
        self.iter = iter_
 class Statement:
    """
    A statement within a function
--- a/phasm/parser.py
+++ b/phasm/parser.py
@ -14,7 +14,6 @@ from .ourlang import (
    ConstantStruct,
    ConstantTuple,
    Expression,
    Fold,
    Function,
    FunctionCall,
    FunctionParam,
@ -467,7 +466,7 @@ class OurVisitor:
        raise NotImplementedError(f'{node} as expr in FunctionDef')
-    def visit_Module_FunctionDef_Call(self, module: Module, function: Function, our_locals: OurLocals, node: ast.Call) -> Union[Fold, FunctionCall]:
+    def visit_Module_FunctionDef_Call(self, module: Module, function: Function, our_locals: OurLocals, node: ast.Call) -> Union[FunctionCall]:
        if node.keywords:
            _raise_static_error(node, 'Keyword calling not supported') # Yet?
@ -480,28 +479,6 @@ class OurVisitor:
        if node.func.id in PRELUDE_METHODS:
            func = PRELUDE_METHODS[node.func.id]
        elif node.func.id == 'foldl':
            if 3 != len(node.args):
                _raise_static_error(node, f'Function {node.func.id} requires 3 arguments but {len(node.args)} are given')
            # TODO: This is not generic, you cannot return a function
            subnode = node.args[0]
            if not isinstance(subnode, ast.Name):
                raise NotImplementedError(f'Calling methods that are not a name {subnode}')
            if not isinstance(subnode.ctx, ast.Load):
                _raise_static_error(subnode, 'Must be load context')
            if subnode.id not in module.functions:
                _raise_static_error(subnode, 'Reference to undefined function')
            func = module.functions[subnode.id]
            if 2 != len(func.posonlyargs):
                _raise_static_error(node, f'Function {node.func.id} requires a function with 2 arguments but a function with {len(func.posonlyargs)} args is given')
            return Fold(
                Fold.Direction.LEFT,
                func,
                self.visit_Module_FunctionDef_expr(module, function, our_locals, node.args[1]),
                self.visit_Module_FunctionDef_expr(module, function, our_locals, node.args[2]),
            )
        elif node.func.id in our_locals:
            func = our_locals[node.func.id]
        else:
--- a/phasm/prelude/init.py
+++ b/phasm/prelude/init.py
@ -553,12 +553,21 @@ instance_type_class(Promotable, f32, f64, methods={
 Foldable = Type3Class('Foldable', (t, ), methods={
    'sum': [t(a), a],
    'foldl': [[b, a, b], b, t(a), b],
    'foldr': [[a, b, b], b, t(a), b],
 }, operators={}, additional_context={
    'sum': [Constraint_TypeClassInstanceExists(NatNum, (a, ))],
 })
 instance_type_class(Foldable, dynamic_array, methods={
    'sum': stdtypes.dynamic_array_sum,
    'foldl': stdtypes.dynamic_array_foldl,
    'foldr': stdtypes.dynamic_array_foldr,
 })
 instance_type_class(Foldable, static_array, methods={
    'sum': stdtypes.static_array_sum,
    'foldl': stdtypes.static_array_foldl,
    'foldr': stdtypes.static_array_foldr,
 })
 bytes_ = dynamic_array(u8)
--- a/phasm/stdlib/types.py
+++ b/phasm/stdlib/types.py
@ -14,7 +14,9 @@ from phasm.wasm import (
    WasmTypeInt64,
    WasmTypeNone,
 )
-from phasm.wasmgenerator import Generator, func_wrapper
+from phasm.wasmgenerator import Generator, VarType_Base, func_wrapper
 from phasm.wasmgenerator import VarType_f32 as f32
 from phasm.wasmgenerator import VarType_f64 as f64
 from phasm.wasmgenerator import VarType_i32 as i32
 from phasm.wasmgenerator import VarType_i64 as i64
@ -1059,12 +1061,16 @@ def dynamic_array_sized_len(g: Generator, tv_map: TypeVariableLookup) -> None:
    # The length is stored in the first 4 bytes
    g.i32.load()
-def static_array_sized_len(g: Generator, tv_map: TypeVariableLookup) -> None:
+def static_array_sized_len(g: Generator, tvl: TypeVariableLookup) -> None:
-    assert len(tv_map) == 1
+    tv_map, tc_map = tvl
    sa_type, sa_len = next(iter(tv_map.values()))
    assert isinstance(sa_type, Type3)
    assert isinstance(sa_len, IntType3)
    tvn_map = {
        x.name: y
        for x, y in tv_map.items()
    }
    sa_len = tvn_map['a*']
    assert isinstance(sa_len, IntType3)
    g.i32.const(sa_len.value)
 ## ###
@ -1137,9 +1143,23 @@ def f32_f64_demote(g: Generator, tv_map: TypeVariableLookup) -> None:
    del tv_map
    g.f32.demote_f64()
-def static_array_sum(g: Generator, tv_map: TypeVariableLookup) -> None:
+## ###
-    assert len(tv_map) == 1
+## Foldable
-    sa_type, sa_len = next(iter(tv_map.values()))
+
 def dynamic_array_sum(g: Generator, tvl: TypeVariableLookup) -> None:
    raise NotImplementedError
 def static_array_sum(g: Generator, tvl: TypeVariableLookup) -> None:
    tv_map, tc_map = tvl
    tvn_map = {
        x.name: y
        for x, y in tv_map.items()
    }
    sa_type = tvn_map['a']
    sa_len = tvn_map['a*']
    assert isinstance(sa_type, Type3)
    assert isinstance(sa_len, IntType3)
@ -1200,7 +1220,7 @@ def static_array_sum(g: Generator, tv_map: TypeVariableLookup) -> None:
            g.nop(comment='Add array value')
            g.local.get(sum_adr)
            g.add_statement(sa_type_info.wasm_load_func)
-            sa_type_add_gen(g, {})
+            sa_type_add_gen(g, ({}, {}, ))
            # adr = adr + sa_type_alloc_size
            # Stack: [sum] -> [sum]
@ -1219,3 +1239,396 @@ def static_array_sum(g: Generator, tv_map: TypeVariableLookup) -> None:
    g.nop(comment=f'Completed sum for {sa_type.name}[{sa_len.value}]')
    # End result: [sum]
 def dynamic_array_foldl(g: Generator, tvl: TypeVariableLookup) -> None:
    tv_map, tc_map = tvl
    tvn_map = {
        x.name: y
        for x, y in tv_map.items()
    }
    sa_type = tvn_map['a']
    res_type = tvn_map['b']
    assert isinstance(sa_type, Type3)
    assert isinstance(res_type, Type3)
    # FIXME: We should probably use LOAD_STORE_TYPE_MAP for this?
    load_map = {
        'u8': 'i32.load8_u',
        'u32': 'i32.load',
        'u64': 'i64.load',
        'i8': 'i32.load8_s',
        'i32': 'i32.load',
        'i64': 'i64.load',
        'f32': 'f32.load',
        'f64': 'f64.load',
    }
    mtyp_map = {
        'u32': 'i32',
        'u64': 'i64',
        'i32': 'i32',
        'i64': 'i64',
        'f32': 'f32',
        'f64': 'f64',
    }
    mtyp_f_map: dict[str, type[VarType_Base]] = {
        'i32': i32,
        'i64': i64,
        'f32': f32,
        'f64': f64,
    }
    # FIXME: We should probably use calc_alloc_size for this?
    type_var_size_map = {
        'u8': 1,
        'u32': 4,
        'u64': 8,
        'i8': 1,
        'i32': 4,
        'i64': 8,
        'f32': 4,
        'f64': 8,
    }
    # By default, constructed types are passed as pointers
    # FIXME: We don't know what add function to call
    sa_type_load = load_map.get(sa_type.name, 'i32')
    sa_type_mtyp = mtyp_map.get(sa_type.name, 'i32')
    sa_type_alloc_size = type_var_size_map.get(sa_type.name, 4)
    res_type_mtyp = mtyp_map.get(res_type.name, 'i32')
    res_type_mtyp_f = mtyp_f_map[res_type_mtyp]
    # Definitions
    fold_adr = g.temp_var(i32('fold_adr'))
    fold_stop = g.temp_var(i32('fold_stop'))
    fold_init = g.temp_var(res_type_mtyp_f('fold_init'))
    fold_func = g.temp_var(i32('fold_func'))
    fold_len = g.temp_var(i32('fold_len'))
    with g.block(params=['i32', res_type_mtyp, 'i32'], result=res_type_mtyp, comment=f'foldl a={sa_type.name} b={res_type.name}'):
        # Stack: [fn*, b, sa*] -> [fn*, b]
        g.local.tee(fold_adr)  # Store address, but also keep it for loading the length
        g.i32.load()  # Load the length
        g.local.set(fold_len)  # Store the length
        # Stack: [fn*, b] -> [fn*]
        g.local.set(fold_init)
        # Stack: [fn*] -> []
        g.local.set(fold_func)
        # Stack: [] -> [b]
        g.nop(comment='No applications if array is empty')
        g.local.get(fold_init)
        g.local.get(fold_len)
        g.i32.eqz() # If the array is empty
        g.br_if(0)  # Then the base value is the result
        # Stack: [b] -> [b]  ; fold_adr=fold_adr + 4
        g.nop(comment='Skip the header')
        g.local.get(fold_adr)
        g.i32.const(4)
        g.i32.add()
        g.local.set(fold_adr)
        # Stack: [b] -> [b]
        g.nop(comment='Apply the first function call')
        g.local.get(fold_adr)
        g.add_statement(sa_type_load)
        g.local.get(fold_func)
        g.add_statement(f'call_indirect (param {res_type_mtyp} {sa_type_mtyp}) (result {res_type_mtyp})')
        # Stack: [b] -> [b]
        g.nop(comment='No loop if there is only one item')
        g.local.get(fold_len)
        g.i32.const(1)
        g.i32.eq()
        g.br_if(0)  # just one value, don't need to loop
        # Stack: [b] -> [b]  ; fold_stop=fold_adr + (sa_len.value * sa_type_alloc_size)
        g.nop(comment='Calculate address at which to stop looping')
        g.local.get(fold_adr)
        g.local.get(fold_len)
        g.i32.const(sa_type_alloc_size)
        g.i32.mul()
        g.i32.add()
        g.local.set(fold_stop)
        # Stack: [b] -> [b]  ; fold_adr = fold_adr + sa_type_alloc_size
        g.nop(comment='Calculate address of the next value')
        g.local.get(fold_adr)
        g.i32.const(sa_type_alloc_size)
        g.i32.add()
        g.local.set(fold_adr)
        with g.loop(params=[res_type_mtyp], result=res_type_mtyp):
            # Stack: [b] -> [b]
            g.nop(comment='Apply function call')
            g.local.get(fold_adr)
            g.add_statement(sa_type_load)
            g.local.get(fold_func)
            g.add_statement(f'call_indirect (param {res_type_mtyp} {sa_type_mtyp}) (result {res_type_mtyp})')
            # Stack: [b] -> [b]  ; fold_adr = fold_adr + sa_type_alloc_size
            g.nop(comment='Calculate address of the next value')
            g.local.get(fold_adr)
            g.i32.const(sa_type_alloc_size)
            g.i32.add()
            g.local.tee(fold_adr)
            # loop if adr > stop
            # Stack: [b] -> [b]
            g.nop(comment='Check if address exceeds array bounds')
            g.local.get(fold_stop)
            g.i32.lt_u()
            g.br_if(0)
    # Stack: [b]
 def static_array_foldl(g: Generator, tvl: TypeVariableLookup) -> None:
    tv_map, tc_map = tvl
    tvn_map = {
        x.name: y
        for x, y in tv_map.items()
    }
    sa_type = tvn_map['a']
    sa_len = tvn_map['a*']
    res_type = tvn_map['b']
    assert isinstance(sa_type, Type3)
    assert isinstance(sa_len, IntType3)
    assert isinstance(res_type, Type3)
    # FIXME: We should probably use LOAD_STORE_TYPE_MAP for this?
    mtyp_map = {
        'u32': 'i32',
        'u64': 'i64',
        'i32': 'i32',
        'i64': 'i64',
        'f32': 'f32',
        'f64': 'f64',
    }
    mtyp_f_map: dict[str, type[VarType_Base]] = {
        'i32': i32,
        'i64': i64,
        'f32': f32,
        'f64': f64,
    }
    # FIXME: We should probably use calc_alloc_size for this?
    type_var_size_map = {
        'u32': 4,
        'u64': 8,
        'i32': 4,
        'i64': 8,
        'f32': 4,
        'f64': 8,
    }
    # By default, constructed types are passed as pointers
    # FIXME: We don't know what add function to call
    sa_type_mtyp = mtyp_map.get(sa_type.name, 'i32')
    sa_type_alloc_size = type_var_size_map.get(sa_type.name, 4)
    res_type_mtyp = mtyp_map.get(res_type.name, 'i32')
    res_type_mtyp_f = mtyp_f_map[res_type_mtyp]
    # Definitions
    fold_adr = g.temp_var(i32('fold_adr'))
    fold_stop = g.temp_var(i32('fold_stop'))
    fold_init = g.temp_var(res_type_mtyp_f('fold_init'))
    fold_func = g.temp_var(i32('fold_func'))
    with g.block(params=['i32', res_type_mtyp, 'i32'], result=res_type_mtyp, comment=f'foldl a={sa_type.name} a*={sa_len.value} b={res_type.name}'):
        # Stack: [fn*, b, sa*] -> [fn*, b]
        g.local.set(fold_adr)
        # Stack: [fn*, b] -> [fn*]
        g.local.set(fold_init)
        # Stack: [fn*] -> []
        g.local.set(fold_func)
        if sa_len.value < 1:
            g.local.get(fold_init)
            return
        # Stack: [] -> [b]
        g.nop(comment='Apply the first function call')
        g.local.get(fold_init)
        g.local.get(fold_adr)
        g.add_statement(f'{sa_type_mtyp}.load')
        g.local.get(fold_func)
        g.add_statement(f'call_indirect (param {res_type_mtyp} {sa_type_mtyp}) (result {res_type_mtyp})')
        if sa_len.value > 1:
            # Stack: [b] -> [b]  ; fold_stop=fold_adr + (sa_len.value * sa_type_alloc_size)
            g.nop(comment='Calculate address at which to stop looping')
            g.local.get(fold_adr)
            g.i32.const(sa_len.value * sa_type_alloc_size)
            g.i32.add()
            g.local.set(fold_stop)
            # Stack: [b] -> [b]  ; fold_adr = fold_adr + sa_type_alloc_size
            g.nop(comment='Calculate address of the next value')
            g.local.get(fold_adr)
            g.i32.const(sa_type_alloc_size)
            g.i32.add()
            g.local.set(fold_adr)
            with g.loop(params=[res_type_mtyp], result=res_type_mtyp):
                # Stack: [b] -> [b]
                g.nop(comment='Apply function call')
                g.local.get(fold_adr)
                g.add_statement(f'{sa_type_mtyp}.load')
                g.local.get(fold_func)
                g.add_statement(f'call_indirect (param {res_type_mtyp} {sa_type_mtyp}) (result {res_type_mtyp})')
                # Stack: [b] -> [b]  ; fold_adr = fold_adr + sa_type_alloc_size
                g.nop(comment='Calculate address of the next value')
                g.local.get(fold_adr)
                g.i32.const(sa_type_alloc_size)
                g.i32.add()
                g.local.tee(fold_adr)
                # loop if adr > stop
                # Stack: [b] -> [b]
                g.nop(comment='Check if address exceeds array bounds')
                g.local.get(fold_stop)
                g.i32.lt_u()
                g.br_if(0)
        # else: just one value, don't need to loop
    # Stack: [b]
 def dynamic_array_foldr(g: Generator, tvl: TypeVariableLookup) -> None:
    raise NotImplementedError
 def static_array_foldr(g: Generator, tvl: TypeVariableLookup) -> None:
    tv_map, tc_map = tvl
    tvn_map = {
        x.name: y
        for x, y in tv_map.items()
    }
    sa_type = tvn_map['a']
    sa_len = tvn_map['a*']
    res_type = tvn_map['b']
    assert isinstance(sa_type, Type3)
    assert isinstance(sa_len, IntType3)
    assert isinstance(res_type, Type3)
    # FIXME: We should probably use LOAD_STORE_TYPE_MAP for this?
    mtyp_map = {
        'u32': 'i32',
        'u64': 'i64',
        'i32': 'i32',
        'i64': 'i64',
        'f32': 'f32',
        'f64': 'f64',
    }
    mtyp_f_map: dict[str, type[VarType_Base]] = {
        'i32': i32,
        'i64': i64,
        'f32': f32,
        'f64': f64,
    }
    # FIXME: We should probably use calc_alloc_size for this?
    type_var_size_map = {
        'u32': 4,
        'u64': 8,
        'i32': 4,
        'i64': 8,
        'f32': 4,
        'f64': 8,
    }
    # By default, constructed types are passed as pointers
    sa_type_mtyp = mtyp_map.get(sa_type.name, 'i32')
    sa_type_alloc_size = type_var_size_map.get(sa_type.name, 4)
    res_type_mtyp = mtyp_map.get(res_type.name, 'i32')
    res_type_mtyp_f = mtyp_f_map[res_type_mtyp]
    # Definitions
    fold_adr = g.temp_var(i32('fold_adr'))
    fold_stop = g.temp_var(i32('fold_stop'))
    fold_tmp = g.temp_var(res_type_mtyp_f('fold_tmp'))
    fold_func = g.temp_var(i32('fold_func'))
    with g.block(params=['i32', res_type_mtyp, 'i32'], result=res_type_mtyp, comment=f'foldr a={sa_type.name} a*={sa_len.value} b={res_type.name}'):
        # Stack: [fn*, b, sa*] -> [fn*, b]  ; fold_adr=fn*, fold_tmp=b, fold_func=fn*
        g.local.set(fold_adr)
        # Stack: [fn*, b] -> [fn*]
        g.local.set(fold_tmp)
        # Stack: [fn*] -> []
        g.local.set(fold_func)
        if sa_len.value < 1:
            g.local.get(fold_tmp)
            return
        # Stack: [] -> []  ; fold_stop=fold_adr
        g.nop(comment='Calculate address at which to stop looping')
        g.local.get(fold_adr)
        g.local.set(fold_stop)
        # Stack: [] -> []  ; fold_adr=fold_adr + (sa_len.value - 1) * sa_type_alloc_size
        g.nop(comment='Calculate address at which to stop looping')
        g.local.get(fold_adr)
        g.i32.const((sa_len.value - 1) * sa_type_alloc_size)
        g.i32.add()
        g.local.set(fold_adr)
        # Stack: [] -> [b]
        g.nop(comment='Get the init value and first array value as starting point')
        g.local.get(fold_adr)
        g.add_statement(f'{sa_type_mtyp}.load')
        g.local.get(fold_tmp)
        g.local.get(fold_func)
        g.add_statement(f'call_indirect (param {sa_type_mtyp} {res_type_mtyp}) (result {res_type_mtyp})')
        if sa_len.value > 1:
            # Stack: [b] -> [b]  ; fold_adr = fold_adr - sa_type_alloc_size
            g.nop(comment='Calculate address of the next value')
            g.local.get(fold_adr)
            g.i32.const(sa_type_alloc_size)
            g.i32.sub()
            g.local.set(fold_adr)
            with g.loop(params=[res_type_mtyp], result=res_type_mtyp):
                g.nop(comment='Apply function call')
                # Stack [b] since we don't have proper stack switching opcodes
                # Stack: [b] -> []
                g.local.set(fold_tmp)
                # Stack: [] -> [a]
                g.local.get(fold_adr)
                g.add_statement(f'{sa_type_mtyp}.load')
                # Stack [a] -> [a, b]
                g.local.get(fold_tmp)
                # Stack [a, b] -> [b]
                g.local.get(fold_func)
                g.add_statement(f'call_indirect (param {sa_type_mtyp} {res_type_mtyp}) (result {res_type_mtyp})')
                # Stack: [b] -> [b]  ; fold_adr = fold_adr - sa_type_alloc_size
                g.nop(comment='Calculate address of the next value')
                g.local.get(fold_adr)
                g.i32.const(sa_type_alloc_size)
                g.i32.sub()
                g.local.tee(fold_adr)
                # loop if adr >= stop
                # Stack: [b] -> [b]
                g.nop(comment='Check if address exceeds array bounds')
                g.local.get(fold_stop)
                g.i32.ge_u()
                g.br_if(0)
        # else: just one value, don't need to loop
    # Stack: [b]
--- a/phasm/type3/constraints.py
+++ b/phasm/type3/constraints.py
@ -183,7 +183,7 @@ class SameTypeArgumentConstraint(ConstraintBase):
        self.arg_var = arg_var
    def check(self) -> CheckResult:
-        if self.tc_var.resolve_as is None or self.arg_var.resolve_as is None:
+        if self.tc_var.resolve_as is None:
            return RequireTypeSubstitutes()
        tc_typ = self.tc_var.resolve_as
@ -200,12 +200,16 @@ class SameTypeArgumentConstraint(ConstraintBase):
            # So we can let the MustImplementTypeClassConstraint handle it.
            return None
        if isinstance(tc_typ.application, TypeApplication_Type):
            return [SameTypeConstraint(
                tc_typ.application.arguments[0],
                self.arg_var,
                comment=self.comment,
            )]
        # FIXME: This feels sketchy. Shouldn't the type variable
        # have the exact same number as arguments?
        if isinstance(tc_typ.application, TypeApplication_TypeInt):
            if tc_typ.application.arguments[0] == arg_typ:
                return None
            return [SameTypeConstraint(
                tc_typ.application.arguments[0],
                self.arg_var,
@ -346,14 +350,10 @@ class MustImplementTypeClassConstraint(ConstraintBase):
    __slots__ = ('context', 'type_class3', 'types', )
    context: Context
-    type_class3: Union[str, Type3Class]
+    type_class3: Type3Class
    types: list[Type3OrPlaceholder]
-    DATA = {
+    def __init__(self, context: Context, type_class3: Type3Class, typ_list: list[Type3OrPlaceholder], comment: Optional[str] = None) -> None:
        'dynamic_array': {'Foldable'},
    }
    def __init__(self, context: Context, type_class3: Union[str, Type3Class], typ_list: list[Type3OrPlaceholder], comment: Optional[str] = None) -> None:
        super().__init__(comment=comment)
        self.context = context
@ -381,13 +381,9 @@ class MustImplementTypeClassConstraint(ConstraintBase):
        assert len(typ_list) == len(self.types)
-        if isinstance(self.type_class3, Type3Class):
+        key = (self.type_class3, tuple(typ_list), )
-            key = (self.type_class3, tuple(typ_list), )
+        if key in self.context.type_class_instances_existing:
-            if key in self.context.type_class_instances_existing:
+            return None
                return None
        else:
            if self.type_class3 in self.__class__.DATA.get(typ_list[0].name, set()):
                return None
        typ_cls_name = self.type_class3 if isinstance(self.type_class3, str) else self.type_class3.name
        typ_name_list = ' '.join(x.name for x in typ_list)
--- a/phasm/type3/constraintsgenerator.py
+++ b/phasm/type3/constraintsgenerator.py
@ -202,6 +202,10 @@ def _expression_function_call(
            yield SameTypeConstraint(sig_part, arg_placeholders[arg_expr], comment=comment)
            continue
        if isinstance(sig_part, FunctionArgument):
            yield SameTypeConstraint(func_var_map[sig_part], arg_placeholders[arg_expr], comment=comment)
            continue
        raise NotImplementedError(sig_part)
    return
@ -265,19 +269,6 @@ def expression(ctx: Context, inp: ourlang.Expression, phft: PlaceholderForType)
            comment=f'The type of a struct member reference is the same as the type of struct member {inp.struct_type3.name}.{inp.member}')
        return
    if isinstance(inp, ourlang.Fold):
        base_phft = PlaceholderForType([inp.base])
        iter_phft = PlaceholderForType([inp.iter])
        yield from expression(ctx, inp.base, base_phft)
        yield from expression(ctx, inp.iter, iter_phft)
        yield SameTypeConstraint(inp.func.posonlyargs[0].type3, inp.func.returns_type3, base_phft, phft,
            comment='foldl :: Foldable t => (b -> a -> b) -> b -> t a -> b')
        yield MustImplementTypeClassConstraint(ctx, 'Foldable', [iter_phft])
        return
    raise NotImplementedError(expression, inp)
 def statement_return(ctx: Context, fun: ourlang.Function, inp: ourlang.StatementReturn) -> ConstraintGenerator:
--- a/phasm/type3/routers.py
+++ b/phasm/type3/routers.py
@ -3,6 +3,7 @@ from typing import Any, Callable
 from .functions import (
    TypeConstructorVariable,
    TypeVariable,
    TypeVariableApplication_Nullary,
    TypeVariableApplication_Unary,
 )
 from .typeclasses import Type3ClassArgs
@ -60,7 +61,10 @@ class TypeApplicationRouter[S, R]:
        raise NoRouteForTypeException(arg0, typ)
-TypeVariableLookup = dict[TypeVariable, tuple[KindArgument, ...]]
+TypeVariableLookup = tuple[
    dict[TypeVariable, KindArgument],
    dict[TypeConstructorVariable, TypeConstructor_Base[Any]],
 ]
 class TypeClassArgsRouter[S, R]:
    """
@ -95,11 +99,12 @@ class TypeClassArgsRouter[S, R]:
    def __call__(self, arg0: S, tv_map: dict[TypeVariable, Type3]) -> R:
        key: list[Type3 | TypeConstructor_Base[Any]] = []
-        arguments: TypeVariableLookup = {}
+        arguments: TypeVariableLookup = (dict(tv_map), {}, )
        for tc_arg in self.args:
            if isinstance(tc_arg, TypeVariable):
                key.append(tv_map[tc_arg])
                arguments[0][tc_arg] = tv_map[tc_arg]
                continue
            for tvar, typ in tv_map.items():
@ -108,16 +113,24 @@ class TypeClassArgsRouter[S, R]:
                    continue
                key.append(typ.application.constructor)
                arguments[1][tc_arg] = typ.application.constructor
                if isinstance(tvar.application, TypeVariableApplication_Unary):
                    if isinstance(typ.application, TypeApplication_Type):
-                        arguments[tvar.application.arguments] = typ.application.arguments
+                        da_type, = typ.application.arguments
                        sa_type_tv = tvar.application.arguments
                        arguments[0][sa_type_tv] = da_type
                        continue
                    # FIXME: This feels sketchy. Shouldn't the type variable
                    # have the exact same number as arguments?
                    if isinstance(typ.application, TypeApplication_TypeInt):
-                        arguments[tvar.application.arguments] = typ.application.arguments
+                        sa_type, sa_len = typ.application.arguments
                        sa_type_tv = tvar.application.arguments
                        sa_len_tv = TypeVariable(sa_type_tv.name + '*', TypeVariableApplication_Nullary(None, None))
                        arguments[0][sa_type_tv] = sa_type
                        arguments[0][sa_len_tv] = sa_len
                        continue
                raise NotImplementedError(tvar.application, typ.application)
--- a/phasm/type3/typeclasses.py
+++ b/phasm/type3/typeclasses.py
@ -1,4 +1,4 @@
-from typing import Dict, Iterable, List, Mapping, Optional, Union
+from typing import Dict, Iterable, List, Mapping, Optional
 from .functions import (
    Constraint_TypeClassInstanceExists,
@ -42,8 +42,8 @@ class Type3Class:
            self,
            name: str,
            args: Type3ClassArgs,
-            methods: Mapping[str, Iterable[Union[Type3, TypeVariable]]],
+            methods: Mapping[str, Iterable[Type3 | TypeVariable | list[Type3 | TypeVariable]]],
-            operators: Mapping[str, Iterable[Union[Type3, TypeVariable]]],
+            operators: Mapping[str, Iterable[Type3 | TypeVariable | list[Type3 | TypeVariable]]],
            inherited_classes: Optional[List['Type3Class']] = None,
            additional_context: Optional[Mapping[str, Iterable[ConstraintBase]]] = None,
        ) -> None:
@ -71,19 +71,23 @@ class Type3Class:
        return self.name
 def _create_signature(
-        method_arg_list: Iterable[Type3 | TypeVariable],
+        method_arg_list: Iterable[Type3 | TypeVariable | list[Type3 | TypeVariable]],
        type_class3: Type3Class,
    ) -> FunctionSignature:
    context = TypeVariableContext()
    if not isinstance(type_class3.args[0], TypeConstructorVariable):
        context.constraints.append(Constraint_TypeClassInstanceExists(type_class3, type_class3.args))
-    signature_args: list[Type3 | TypeVariable] = []
+    signature_args: list[Type3 | TypeVariable | list[Type3 | TypeVariable]] = []
    for method_arg in method_arg_list:
        if isinstance(method_arg, Type3):
            signature_args.append(method_arg)
            continue
        if isinstance(method_arg, list):
            signature_args.append(method_arg)
            continue
        if isinstance(method_arg, TypeVariable):
            type_constructor = method_arg.application.constructor
            if type_constructor is None:
--- a/phasm/wasmgenerator.py
+++ b/phasm/wasmgenerator.py
@ -170,11 +170,12 @@ class Generator_Local:
        self.generator.add_statement('local.tee', variable.name_ref, comment=comment)
 class GeneratorBlock:
-    def __init__(self, generator: 'Generator', name: str, params: Iterable[str] = (), result: str | None = None) -> None:
+    def __init__(self, generator: 'Generator', name: str, params: Iterable[str] = (), result: str | None = None, comment: str | None = None) -> None:
        self.generator = generator
        self.name = name
        self.params = params
        self.result = result
        self.comment = comment
    def __enter__(self) -> None:
        stmt = self.name
@ -186,7 +187,7 @@ class GeneratorBlock:
        if self.result:
            stmt = f'{stmt} (result {self.result})'
-        self.generator.add_statement(stmt)
+        self.generator.add_statement(stmt, comment=self.comment)
    def __exit__(self, exc_type: Any, exc_value: Any, traceback: Any) -> None:
        if not exc_type:
@ -208,7 +209,7 @@ class Generator:
        # 2.4.5 Control Instructions
        self.nop = functools.partial(self.add_statement, 'nop')
        self.unreachable = functools.partial(self.add_statement, 'unreachable')
-        # block
+        self.block = functools.partial(GeneratorBlock, self, 'block')
        self.loop = functools.partial(GeneratorBlock, self, 'loop')
        self.if_ = functools.partial(GeneratorBlock, self, 'if')
        # br
--- a/tests/integration/helpers.py
+++ b/tests/integration/helpers.py
@ -1,3 +1,4 @@
 import os
 import struct
 import sys
 from typing import Any, Generator, Iterable, List, TextIO, Union
@ -36,26 +37,39 @@ class Suite:
    def __init__(self, code_py: str) -> None:
        self.code_py = code_py
-    def run_code(self, *args: Any, runtime: str = 'wasmtime', func_name: str = 'testEntry', imports: runners.Imports = None, do_format_check: bool = True) -> Any:
+    def run_code(
            self,
            *args: Any,
            runtime: str = 'wasmtime',
            func_name: str = 'testEntry',
            imports: runners.Imports = None,
            do_format_check: bool = True,
            verbose: bool | None = None,
        ) -> Any:
        """
        Compiles the given python code into wasm and
        then runs it
        Returned is an object with the results set
        """
        if verbose is None:
            verbose = bool(os.environ.get('VERBOSE'))
        class_ = RUNNER_CLASS_MAP[runtime]
        runner = class_(self.code_py)
-        write_header(sys.stderr, 'Phasm')
+        if verbose:
-        runner.dump_phasm_code(sys.stderr)
+            write_header(sys.stderr, 'Phasm')
            runner.dump_phasm_code(sys.stderr)
-        runner.parse()
+        runner.parse(verbose=verbose)
        runner.compile_ast()
        runner.compile_wat()
-        write_header(sys.stderr, 'Assembly')
+        if verbose:
-        runner.dump_wasm_wat(sys.stderr)
+            write_header(sys.stderr, 'Assembly')
            runner.dump_wasm_wat(sys.stderr)
        runner.interpreter_setup()
        runner.interpreter_load(imports)
@ -70,8 +84,9 @@ class Suite:
        wasm_args: List[Union[float, int]] = []
        if args:
-            write_header(sys.stderr, 'Memory (pre alloc)')
+            if verbose:
-            runner.interpreter_dump_memory(sys.stderr)
+                write_header(sys.stderr, 'Memory (pre alloc)')
                runner.interpreter_dump_memory(sys.stderr)
            for arg, arg_typ in zip(args, func_args, strict=True):
                if arg_typ in (prelude.u8, prelude.u32, prelude.u64, ):
@ -95,8 +110,9 @@ class Suite:
                except NoRouteForTypeException:
                    raise NotImplementedError(arg_typ, arg)
-        write_header(sys.stderr, 'Memory (pre run)')
+        if verbose:
-        runner.interpreter_dump_memory(sys.stderr)
+            write_header(sys.stderr, 'Memory (pre run)')
            runner.interpreter_dump_memory(sys.stderr)
        result = SuiteResult()
        result.returned_value = runner.call(func_name, *wasm_args)
@ -107,8 +123,9 @@ class Suite:
            result.returned_value,
        )
-        write_header(sys.stderr, 'Memory (post run)')
+        if verbose:
-        runner.interpreter_dump_memory(sys.stderr)
+            write_header(sys.stderr, 'Memory (post run)')
            runner.interpreter_dump_memory(sys.stderr)
        return result
--- a/tests/integration/runners.py
+++ b/tests/integration/runners.py
@ -32,12 +32,12 @@ class RunnerBase:
        """
        _dump_code(textio, self.phasm_code)
-    def parse(self) -> None:
+    def parse(self, verbose: bool = True) -> None:
        """
        Parses the Phasm code into an AST
        """
        self.phasm_ast = phasm_parse(self.phasm_code)
-        phasm_type3(self.phasm_ast, verbose=True)
+        phasm_type3(self.phasm_ast, verbose=verbose)
    def compile_ast(self) -> None:
        """
@ -120,6 +120,8 @@ class RunnerWasmtime(RunnerBase):
            if vartype is int:
                params.append(wasmtime.ValType.i32())
            elif vartype is float:
                params.append(wasmtime.ValType.f32())
            else:
                raise NotImplementedError
@ -128,6 +130,8 @@ class RunnerWasmtime(RunnerBase):
            pass # No return value
        elif func.__annotations__['return'] is int:
            results.append(wasmtime.ValType.i32())
        elif func.__annotations__['return'] is float:
            results.append(wasmtime.ValType.f32())
        else:
            raise NotImplementedError('Return type', func.__annotations__['return'])
--- a/tests/integration/test_lang/test_builtins.py
+++ b/tests/integration/test_lang/test_builtins.py
@ -1,61 +0,0 @@
 import pytest
 from ..helpers import Suite
@pytest.mark.integration_test
 def test_foldl_1():
    code_py = """
 def u8_or(l: u8, r: u8) -> u8:
    return l | r
@exported
 def testEntry(b: bytes) -> u8:
    return foldl(u8_or, 128, b)
 """
    suite = Suite(code_py)
    result = suite.run_code(b'')
    assert 128 == result.returned_value
    result = suite.run_code(b'\x80')
    assert 128 == result.returned_value
    result = suite.run_code(b'\x80\x40')
    assert 192 == result.returned_value
    result = suite.run_code(b'\x80\x40\x20\x10')
    assert 240 == result.returned_value
    result = suite.run_code(b'\x80\x40\x20\x10\x08\x04\x02\x01')
    assert 255 == result.returned_value
@pytest.mark.integration_test
 def test_foldl_2():
    code_py = """
 def xor(l: u8, r: u8) -> u8:
    return l ^ r
@exported
 def testEntry(a: bytes, b: bytes) -> u8:
    return foldl(xor, 0, a) ^ foldl(xor, 0, b)
 """
    suite = Suite(code_py)
    result = suite.run_code(b'\x55\x0F', b'\x33\x80')
    assert 233 == result.returned_value
@pytest.mark.integration_test
 def test_foldl_3():
    code_py = """
 def xor(l: u32, r: u8) -> u32:
    return l ^ extend(r)
@exported
 def testEntry(a: bytes) -> u32:
    return foldl(xor, 0, a)
 """
    suite = Suite(code_py)
    result = suite.run_code(b'\x55\x0F\x33\x80')
    assert 233 == result.returned_value
--- a/tests/integration/test_typeclasses/test_foldable.py
+++ b/tests/integration/test_typeclasses/test_foldable.py
@ -36,6 +36,142 @@ def testEntry(x: Foo[4]) -> Foo:
    with pytest.raises(Type3Exception, match='Missing type class instantation: NatNum Foo'):
        Suite(code_py).run_code()
@pytest.mark.integration_test
@pytest.mark.parametrize('length', [1, 5, 13])
@pytest.mark.parametrize('direction', ['foldl', 'foldr'])
 def test_foldable_foldl_foldr_size(direction, length):
    code_py = f"""
 def u64_add(l: u64, r: u64) -> u64:
    return l + r
@exported
 def testEntry(b: u64[{length}]) -> u64:
    return {direction}(u64_add, 100, b)
 """
    suite = Suite(code_py)
    in_put = tuple(range(1, length + 1))
    result = suite.run_code(in_put)
    assert (100 + sum(in_put)) == result.returned_value
@pytest.mark.integration_test
@pytest.mark.parametrize('direction', ['foldl', 'foldr'])
 def test_foldable_foldl_foldr_compounded_type(direction):
    code_py = f"""
 def combine_foldl(b: u64, a: (u32, u32, )) -> u64:
    return extend(a[0] * a[1]) + b
 def combine_foldr(a: (u32, u32, ), b: u64) -> u64:
    return extend(a[0] * a[1]) + b
@exported
 def testEntry(b: (u32, u32, )[3]) -> u64:
    return {direction}(combine_{direction}, 10000, b)
 """
    suite = Suite(code_py)
    result = suite.run_code(((2, 5), (25, 4), (125, 8)))
    assert 11110 == result.returned_value
@pytest.mark.integration_test
@pytest.mark.parametrize('in_put, direction, exp_result', [
    ([], 'foldl', 0, ),
    ([], 'foldr', 0, ),
    ([1], 'foldl', -1, ),
    ([1], 'foldr', 1, ),
    ([1,2], 'foldl', -3, ),
    ([1,2], 'foldr', -1, ),
    ([1,2,3], 'foldl', -6, ),
    ([1,2,3], 'foldr', 2, ),
    ([1,2,3,4], 'foldl', -10, ),
    ([1,2,3,4], 'foldr', -2, ),
    ([1,2,3,4,5], 'foldl', -15, ),
    ([1,2,3,4,5], 'foldr', 3, ),
    ([1,2,3,4,5,6], 'foldl', -21, ),
    ([1,2,3,4,5,6], 'foldr', -3, ),
    ([1,2,3,4,5,6,7], 'foldl', -28, ),
    ([1,2,3,4,5,6,7], 'foldr', 4, ),
    ([1,2,3,4,5,6,7,8], 'foldl', -36, ),
    ([1,2,3,4,5,6,7,8], 'foldr', -4, ),
 ])
 def test_foldable_foldl_foldr_result(direction, in_put, exp_result):
    # See https://stackoverflow.com/a/13280185
    code_py = f"""
 def i32_sub(l: i32, r: i32) -> i32:
    return l - r
@exported
 def testEntry(b: i32[{len(in_put)}]) -> i32:
    return {direction}(i32_sub, 0, b)
 """
    suite = Suite(code_py)
    result = suite.run_code(tuple(in_put))
    assert exp_result == result.returned_value
@pytest.mark.integration_test
 def test_foldable_foldl_bytes():
    code_py = """
 def u8_or(l: u8, r: u8) -> u8:
    return l | r
@exported
 def testEntry(b: bytes) -> u8:
    return foldl(u8_or, 0, b)
 """
    suite = Suite(code_py)
    result = suite.run_code(b'')
    assert 0 == result.returned_value
    result = suite.run_code(b'\x80')
    assert 128 == result.returned_value
    result = suite.run_code(b'\x80\x40')
    assert 192 == result.returned_value
    result = suite.run_code(b'\x80\x40\x20\x10')
    assert 240 == result.returned_value
    result = suite.run_code(b'\x80\x40\x20\x10\x08\x04\x02\x01')
    assert 255 == result.returned_value
@pytest.mark.integration_test
@pytest.mark.parametrize('in_typ', ['i8', 'i8[3]'])
 def test_foldable_argument_must_be_a_function(in_typ):
    code_py = f"""
@exported
 def testEntry(x: {in_typ}, y: i32, z: i64[3]) -> i32:
    return foldl(x, y, z)
 """
    r_in_typ = in_typ.replace('[', '\\[').replace(']', '\\]')
    with pytest.raises(Type3Exception, match=f'{r_in_typ} must be a function instead'):
        Suite(code_py).run_code()
@pytest.mark.integration_test
 def test_foldable_argument_must_be_right_function():
    code_py = """
 def foo(l: i32, r: i64) -> i64:
    return extend(l) + r
@exported
 def testEntry(i: i64, l: i64[3]) -> i64:
    return foldr(foo, i, l)
 """
    with pytest.raises(Type3Exception, match=r'Callable\[i64, i64, i64\] must be Callable\[i32, i64, i64\] instead'):
        Suite(code_py).run_code()
@pytest.mark.integration_test
 def test_foldable_invalid_return_type():