def generate_string_literal(c_string_literal):
return 'stringLiteral(STRING_LITERAL_LIST[{}])'.format(c_string_literal.index)
-CONSTANT_EXPRESSION_MAPPING = {
- 'true': 'TRUE',
- 'false': 'FALSE',
-}
-
-def generate_constant_expression(c_constant_expression):
- return CONSTANT_EXPRESSION_MAPPING[c_constant_expression.value]
-
-def generate_symbol_expression(c_symbol_expression):
+def generate_symbol_expression(symbol_expression):
return 'Environment_get(environment, SYMBOL_LIST[{}] /* symbol: {} */)'.format(
- c_symbol_expression.symbol_list_index,
- c_symbol_expression.symbol,
+ symbol_expression.symbol_list_index,
+ symbol_expression.symbol,
)
def generate_variable_expression(expression):
LITERAL_TYPE_MAPPING = {
transformation.CIntegerLiteral: generate_integer_literal,
transformation.CStringLiteral: generate_string_literal,
- transformation.CConstantExpression: generate_constant_expression,
transformation.CSymbolExpression: generate_symbol_expression,
}
return LITERAL_TYPE_MAPPING[type(expression)](expression)
if isinstance(expression, transformation.CFunctionCallForFurInfixOperator):
- return 'builtin${}({}, {})'.format(
+ return 'operator${}({}, {})'.format(
expression.name,
generate_expression(expression.left),
generate_expression(expression.right),
}[type(expression)](expression)
def generate_negation_expression(c_negation_expression):
- return 'builtin$negate({})'.format(
+ return 'operator$negate({})'.format(
generate_expression(c_negation_expression.value)
)
def generate_function_call(function_call):
- return '{}({}, {})'.format(
- function_call.name,
+ # This gets called twice, so we want to be sure it is efficient and without side effects
+ assert isinstance(function_call.function_expression, transformation.CVariableExpression)
+
+ # TODO Check the type of the things being called
+ function_expression = generate_variable_expression(function_call.function_expression)
+ return '{}.instance.closure.call(environmentPool, {}.instance.closure.closed, {}, {})'.format(
+ function_expression,
+ function_expression,
function_call.argument_count,
# TODO This is just a single item containing a reference to the items list--make that clearer
generate_expression(function_call.argument_items),
# TODO Do we need to garbage collect the results of arbitrary statements?
return '{};'.format(generate_expression(statement.expression))
-def generate_symbol_assignment_statement(c_assignment_statement):
+def generate_symbol_assignment_statement(statement):
return 'Environment_set(environment, SYMBOL_LIST[{}] /* symbol: {} */, {});'.format(
- c_assignment_statement.target_symbol_list_index,
- c_assignment_statement.target,
- generate_expression(c_assignment_statement.expression),
+ statement.target_symbol_list_index,
+ statement.target,
+ generate_expression(statement.expression),
)
def generate_array_variable_initialization_statement(statement):
def generate_if_else_statement(statement):
# TODO Check that the argument is boolean
- return 'if({}.instance.boolean)\n{{\n{}\n}}\nelse\n{{\n{}\n}}'.format(
+ condition_expression = '{}.instance.boolean'.format(
generate_expression(statement.condition_expression),
- indent('\n'.join(generate_statement(s) for s in statement.if_statements)),
- indent('\n'.join(generate_statement(s) for s in statement.else_statements)),
)
+ if len(statement.if_statements) == 0:
+ condition_expression = '!({})'.format(condition_expression)
+ if_statements = statement.else_statements
+ else_statements = ()
+ else:
+ if_statements = statement.if_statements
+ else_statements = statement.else_statements
+
+ generated_if_clause = 'if({})'.format(condition_expression)
+
+ if len(if_statements) == 0:
+ generated_if_statements = ';'
+ else:
+ generated_if_statements = indent('\n{{\n{}\n}}'.format(
+ indent('\n'.join(generate_statement(s) for s in if_statements)),
+ ))
+
+ if len(else_statements) == 0:
+ generated_else_statements = ''
+ else:
+ generated_else_statements = indent('\nelse\n{{\n{}\n}}'.format(
+ indent('\n'.join(generate_statement(s) for s in else_statements)),
+ ))
+
+ return generated_if_clause + generated_if_statements + generated_else_statements
+
+def generate_function_declaration(statement):
+ return 'Environment_set(environment, "{}", (Object){{ CLOSURE, (Instance)(Closure){{ environment, user${}$implementation }} }});'.format(statement.name, statement.name)
+
def generate_statement(statement):
return {
transformation.CExpressionStatement: generate_expression_statement,
+ transformation.CFunctionDeclaration: generate_function_declaration,
transformation.CIfElseStatement: generate_if_else_statement,
transformation.CSymbolAssignmentStatement: generate_symbol_assignment_statement,
transformation.CArrayVariableInitializationStatement: generate_array_variable_initialization_statement,
transformation.CVariableReassignmentStatement: generate_variable_reassignment_statement,
}[type(statement)](statement)
+def generate_function_definition(definition):
+ template = ENV.get_template('function_definition.c')
+ return template.render(
+ name=definition.name,
+ argument_name_list=definition.argument_name_list,
+ statement_list=list(generate_statement(s) for s in definition.statement_list),
+ )
+ return definition
+
def generate(program):
template = ENV.get_template('program.c')
return template.render(
- builtins=list(sorted(program.builtin_set)),
- statements=[generate_statement(statement) for statement in program.statements],
+ builtins=tuple(sorted(program.builtin_set)),
+ function_definition_list=list(generate_function_definition(fd) for fd in program.function_definition_list),
+ infix_declarations=program.operator_declarations,
+ statements=list(generate_statement(s) for s in program.statements),
standard_libraries=list(sorted(program.standard_libraries)),
string_literal_list=program.string_literal_list,
symbol_list=program.symbol_list,