roto/codegen/src/generator.rs

use crate::google::protobuf::descriptor::{
    DescriptorProto, EnumDescriptorProto, FieldDescriptorProto, FileDescriptorProto,
    FileDescriptorSet, MessageOptions, MethodDescriptorProto, OneofDescriptorProto, ServiceDescriptorProto,
};
use roto_runtime::ProtoAccessor;
use std::collections::{HashMap, HashSet};
use std::str;

pub fn to_pascal_case(s: &str) -> String {
    s.split('_')
        .map(|word| {
            let mut chars = word.chars();
            match chars.next() {
                None => String::new(),
                Some(f) => f.to_uppercase().collect::<String>() + chars.as_str(),
            }
        })
        .collect()
}

pub fn to_snake_case(s: &str) -> String {
    let mut result = String::new();
    for (i, c) in s.chars().enumerate() {
        if c.is_uppercase() {
            if i > 0 {
                result.push('_');
            }
            result.push(c.to_ascii_lowercase());
        } else {
            result.push(c);
        }
    }
    result
}

fn map_type_to_rust_accessor(field_type: i32, label: i32, is_map: bool) -> (String, String, String) {
    if label == 3 {
        // LABEL_REPEATED
        let iterator_type = if is_map {
            "roto_runtime::MapFieldIterator<'a>"
        } else {
            "roto_runtime::RepeatedFieldIterator<'a>"
        };
        return (
            iterator_type.to_string(),
            "".to_string(), // Not used for repeated fields in the same way
            "".to_string(), // Not used for repeated fields
        );
    }

    match field_type {
        9 => (
            "&'a str".to_string(),
            "str::from_utf8(bytes).map_err(|_| roto_runtime::RotoError::WireFormatViolation)".to_string(),
            "\"\"".to_string(),
        ), // TYPE_STRING
        1 => (
            "f64".to_string(),
            "Ok(f64::from_le_bytes(bytes.try_into().map_err(|_| roto_runtime::RotoError::WireFormatViolation)?))".to_string(),
            "0.0".to_string(),
        ), // TYPE_DOUBLE
        2 => (
            "f32".to_string(),
            "Ok(f32::from_le_bytes(bytes.try_into().map_err(|_| roto_runtime::RotoError::WireFormatViolation)?))".to_string(),
            "0.0".to_string(),
        ), // TYPE_FLOAT
        3 | 5 | 15 | 17 => (
            "i32".to_string(),
            "roto_runtime::read_varint(bytes).map(|(v, _)| v as i32).map_err(|_| roto_runtime::RotoError::WireFormatViolation)".to_string(),
            "0".to_string(),
        ), // INT/SINT/SFIXED 32
        4 | 6 | 13 => (
            "u32".to_string(),
            "roto_runtime::read_varint(bytes).map(|(v, _)| v as u32).map_err(|_| roto_runtime::RotoError::WireFormatViolation)".to_string(),
            "0".to_string(),
        ), // UINT/FIXED 32
        16 | 18 => (
            "i64".to_string(),
            "roto_runtime::read_varint(bytes).map(|(v, _)| v as i64).map_err(|_| roto_runtime::RotoError::WireFormatViolation)".to_string(),
            "0".to_string(),
        ), // SINT/SFIXED 64
        7 | 14 => (
            "u64".to_string(),
            "roto_runtime::read_varint(bytes).map(|(v, _)| v as u64).map_err(|_| roto_runtime::RotoError::WireFormatViolation)".to_string(),
            "0".to_string(),
        ), // UINT/FIXED 64
        8 => (
            "bool".to_string(),
            "roto_runtime::read_varint(bytes).map(|(v, _)| v != 0).map_err(|_| roto_runtime::RotoError::WireFormatViolation)".to_string(),
            "false".to_string(),
        ), // TYPE_BOOL
        11 | 12 => (
            "&'a [u8]".to_string(),
            "Ok(bytes)".to_string(),
            "&[]".to_string(),
        ), // MESSAGE/BYTES
        _ => (
            "&'a [u8]".to_string(),
            "Ok(bytes)".to_string(),
            "&[]".to_string(),
        ),
    }
}

fn write_enum(enum_proto: &EnumDescriptorProto, output: &mut String) {
    let enum_name = to_pascal_case(enum_proto.name().unwrap());

    output.push_str(&format!(
        "#[derive(Debug, Clone, Copy, PartialEq, Eq)]\n#[repr(i32)]\npub enum {} {{\n",
        enum_name
    ));

    let mut values = enum_proto.value();
    let mut zero_variant_name = None;
    while let Some(val_res) = values.next() {
        let (val_data, _) = val_res.expect("Failed to iterate enum");
        let accessor =
            ProtoAccessor::new(val_data).expect("Failed to parse EnumValueDescriptorProto");
        let (name_bytes, _) = accessor.get_value(1).expect("Enum value name missing");
        let name = str::from_utf8(name_bytes).expect("Enum value name invalid utf8");
        let (num_bytes, _) = accessor.get_value(2).expect("Enum value number missing");
        let (num, _) =
            roto_runtime::read_varint(num_bytes).expect("Enum value number invalid varint");

        let pascal_name = to_pascal_case(name);
        if num == 0 {
            zero_variant_name = Some(pascal_name.clone());
        }
        output.push_str(&format!("    {} = {},\n", pascal_name, num));
    }

    if zero_variant_name.is_none() {
        output.push_str("    Unknown = 0,\n");
        zero_variant_name = Some("Unknown".to_string());
    }

    output.push_str("}\n\n");

    output.push_str(&format!(
        "impl {} {{\n    pub fn from_i32(value: i32) -> Self {{\n        match value {{\n",
        enum_name
    ));

    let mut values = enum_proto.value();
    while let Some(val_res) = values.next() {
        let (val_data, _) = val_res.expect("Failed to read enum value");
        let accessor =
            ProtoAccessor::new(val_data).expect("Failed to parse EnumValueDescriptorProto");
        let (name_bytes, _) = accessor.get_value(1).expect("Enum value name missing");
        let name = str::from_utf8(name_bytes).expect("Enum value name invalid utf8");
        let (num_bytes, _) = accessor.get_value(2).expect("Enum value number missing");
        let (num, _) =
            roto_runtime::read_varint(num_bytes).expect("Enum value number invalid varint");

        output.push_str(&format!(
            "            {} => {}::{},\n",
            num,
            enum_name,
            to_pascal_case(name)
        ));
    }

    output.push_str(&format!(
        "            _ => {}::{},\n",
        enum_name,
        zero_variant_name.as_ref().unwrap()
    ));
    output.push_str("        }\n    }\n}\n\n");
}

fn write_message(msg_proto: &DescriptorProto, output: &mut String) {
    let msg_name = to_pascal_case(msg_proto.name().unwrap());

    let mut fields_info = Vec::new();
    for field_res in msg_proto.field() {
        let (field_data, _) = field_res.expect("Failed to iterate field");
        let field_proto =
            FieldDescriptorProto::new(field_data).expect("Failed to parse FieldDescriptorProto");
        let field_name = field_proto.name().unwrap();

        let tag = field_proto.number().unwrap();
        let f_type = field_proto.r#type().unwrap() as i32;
        let f_label = field_proto.label().unwrap() as i32;
        let oneof_index = field_proto.oneof_index().ok();
        let is_map = field_proto
            .options()
            .map(|opt| {
                MessageOptions::new(opt)
                    .unwrap()
                    .map_entry()
                    .unwrap_or(false)
            })
            .unwrap_or(false);

        fields_info.push((
            field_name.to_string(),
            tag,
            f_type,
            f_label,
            oneof_index,
            is_map,
        ));
    }

    let mut oneofs = Vec::new();
    for o_res in msg_proto.oneof_decl() {
        let (o, _) = o_res.expect("Failed to iterate oneof");
        oneofs.push(o);
    }

    output.push_str(&format!("pub struct {}<'a> {{\n", msg_name));
    output.push_str("    accessor: roto_runtime::ProtoAccessor<'a>,\n");

    for (field_name, _tag, _f_type, f_label, _oneof_index, _is_map) in &fields_info {
        if *f_label == 3 {
            output.push_str(&format!("    {}_start: Option<usize>,\n", field_name));
            output.push_str(&format!("    {}_end: Option<usize>,\n", field_name));
        } else {
            output.push_str(&format!("    {}_offset: Option<usize>,\n", field_name));
        }
    }
    output.push_str("}\n\n");

    output.push_str(&format!("impl<'a> {}<'a> {{\n", msg_name));
    output.push_str("    pub fn new(data: &'a [u8]) -> roto_runtime::Result<Self> {\n");
    output.push_str("        let accessor = roto_runtime::ProtoAccessor::new(data)?;\n");
    for (name, _, _, label, _oneof_index, _is_map) in &fields_info {
        if *label == 3 {
            output.push_str(&format!("        let mut {}_start = None;\n", name));
            output.push_str(&format!("        let mut {}_end = None;\n", name));
        } else {
            output.push_str(&format!("        let mut {}_offset = None;\n", name));
        }
    }

    output.push_str("        for item in accessor.fields() {\n");
    output.push_str("            let (offset, tag, _) = item?;\n");
    for (name, tag, _, label, _oneof_index, _is_map) in &fields_info {
        if *label == 3 {
            output.push_str(&format!("            if tag.field_number == {} {{\n", tag));
            output.push_str(&format!(
                "                if {}_start.is_none() {{ {}_start = Some(offset); }}\n",
                name, name
            ));
            output.push_str(&format!("                {}_end = Some(offset);\n", name));
            output.push_str("            }\n");
        } else {
            output.push_str(&format!(
                "            if tag.field_number == {} {{ {}_offset = Some(offset); }}\n",
                tag, name
            ));
        }
    }
    output.push_str("        }\n\n");

    output.push_str("        Ok(Self {\n");
    output.push_str("            accessor,\n");
    for (name, _, _, label, _oneof_index, _is_map) in &fields_info {
        if *label == 3 {
            output.push_str(&format!("{}_start, {}_end,\n", name, name));
        } else {
            output.push_str(&format!("{}_offset,\n", name));
        }
    }
    output.push_str("        })\n    }\n\n");

    for (field_name, tag, f_type, f_label, _oneof_index, is_map) in &fields_info {
        let (rust_type, logic, default_val) = map_type_to_rust_accessor(*f_type, *f_label, *is_map);
        let safe_name = if field_name == "type" {
            format!("r#{}", field_name)
        } else {
            field_name.clone()
        };

        if *f_label == 3 {
            output.push_str(&format!(
                "    pub fn {}(&self) -> {} {{\n",
                safe_name, rust_type
            ));
            output.push_str(&format!(
                "        match (self.{}_start, self.{}_end) {{\n",
                field_name, field_name
            ));
            if *is_map {
                output.push_str(&format!("            (Some(start), Some(end)) => roto_runtime::MapFieldIterator::new(self.accessor.iter_repeated_range({}, start, end)),\n", tag));
                output.push_str(&format!(
                    "            _ => roto_runtime::MapFieldIterator::new(self.accessor.iter_repeated({})),\n",
                    tag
                ));
            } else {
                output.push_str(&format!("            (Some(start), Some(end)) => self.accessor.iter_repeated_range({}, start, end),\n", tag));
                output.push_str(&format!(
                    "            _ => self.accessor.iter_repeated({}),\n",
                    tag
                ));
            }
            output.push_str("        }\n    }\n\n");
        } else {
            output.push_str(&format!(
                "    pub fn {}(&self) -> roto_runtime::Result<{}> {{\n",
                safe_name, rust_type
            ));
            output.push_str(&format!(
                "        let offset = self.{}_offset.ok_or(roto_runtime::RotoError::FieldNotFound)?;\n",
                field_name
            ));
            output.push_str("        let (bytes, _) = self.accessor.get_value_at(offset)?;\n");
            output.push_str(&format!("        {}\n", logic));
            output.push_str("    }\n\n");

            output.push_str(&format!(
                "    pub fn {}_or_default(&self) -> roto_runtime::Result<{}> {{\n",
                 safe_name, rust_type
            ));
            output.push_str(&format!(
                "        self.{}().or(Ok({}))\n",
                safe_name, default_val
            ));
            output.push_str("    }\n\n");

            output.push_str(&format!(
                "    pub fn has_{}(&self) -> bool {{ self.{}_offset.is_some() }}\n\n",
                field_name, field_name
            ));
        }
    }

    for (oneof_index, oneof_proto) in oneofs.iter().enumerate() {
        let oneof_desc =
            OneofDescriptorProto::new(*oneof_proto).expect("Failed to parse OneofDescriptorProto");
        let oneof_name = oneof_desc.name().unwrap();
        let pascal_oneof_name = to_pascal_case(oneof_name);
        let snake_oneof_name = to_snake_case(oneof_name);

        output.push_str(&format!(
            "    pub fn which_{}(&self) -> roto_runtime::Result<Option<{}::{}<'a>>> {{\n",
            snake_oneof_name, msg_name, pascal_oneof_name
        ));
        for (field_name, _tag, _f_type, _f_label, f_oneof_index, _is_map) in &fields_info {
            if *f_oneof_index == Some(oneof_index as i32) {
                let safe_field_name = if field_name == "type" {
                    format!("r#{}", field_name)
                } else {
                    field_name.clone()
                };
                output.push_str(&format!(
                    "        if self.{}_offset.is_some() {{\n",
                    field_name
                ));
                output.push_str(&format!(
                    "            return Ok(Some({}::{} (self.{}()?)));\n",
                    pascal_oneof_name, safe_field_name, safe_field_name
                ));
                output.push_str("        }\n");
            }
        }
        output.push_str("        Ok(None)\n    }\n\n");
    }

    // raw_fields() convenience on the message struct (before closing the impl)
    output.push_str("    pub fn raw_fields(&self) -> roto_runtime::RawFieldIterator<'a> {\n");
    output.push_str("        self.accessor.raw_fields()\n");
    output.push_str("    }\n\n");
    output.push_str("}\n\n");

    // Collect builder field info so we can use it multiple times below.
    // Tuple: (field_name, safe_name, tag, rust_type, write_method)
    let mut builder_fields: Vec<(String, String, u32, String, String)> = Vec::new();
    for field_res in msg_proto.field() {
        let (field_data, _) = field_res.expect("Failed to iterate field");
        let field_proto =
            FieldDescriptorProto::new(field_data).expect("Failed to parse FieldDescriptorProto");
        let field_name = field_proto.name().unwrap().to_string();
        let safe_name = if field_name == "type" {
            format!("r#{}", field_name)
        } else {
            field_name.clone()
        };
        let tag = field_proto.number().unwrap();
        let f_type = field_proto.r#type().unwrap() as i32;
        let (rust_type, method) = map_type_to_rust_builder(f_type);
        builder_fields.push((field_name, safe_name, tag as u32, rust_type, method));
    }

    // Builder struct — one `_written: bool` flag per field
    output.push_str(&format!("pub struct {}Builder<'b> {{\n", msg_name));
    output.push_str("    builder: roto_runtime::ProtoBuilder<'b>,\n");
    for (field_name, _, _, _, _) in &builder_fields {
        output.push_str(&format!("    {}_written: bool,\n", field_name));
    }
    output.push_str(&format!("}}\n\nimpl<'b> {}Builder<'b> {{\n", msg_name));

    // Constructor — initialise every flag to false
    output.push_str(&format!(
        "    pub fn builder(buf: &mut [u8]) -> {}Builder<'_> {{\n        {}Builder {{\n",
        msg_name, msg_name
    ));
    output.push_str("            builder: roto_runtime::ProtoBuilder::new(buf),\n");
    for (field_name, _, _, _, _) in &builder_fields {
        output.push_str(&format!("            {}_written: false,\n", field_name));
    }
    output.push_str("        }\n    }\n\n");

    // Per-field setters — mark field as written
    for (field_name, safe_name, tag, rust_type, method) in &builder_fields {
        output.push_str(&format!(
            "    pub fn {}(mut self, value: {}) -> roto_runtime::Result<Self> {{\n        self.builder.{}({}, value)?;\n        self.{}_written = true;\n        Ok(self)\n    }}\n\n",
            safe_name, rust_type, method, tag, field_name
        ));
    }

    // with() — copies unseen fields from an existing message
    output.push_str(&format!(
        "    pub fn with(mut self, msg: &{}<'_>) -> roto_runtime::Result<Self> {{\n",
        msg_name
    ));
    output.push_str("        for item in msg.raw_fields() {\n");
    output.push_str("            let (field_number, raw_bytes) = item?;\n");
    output.push_str("            let is_written = match field_number {\n");
    for (field_name, _, tag, _, _) in &builder_fields {
        output.push_str(&format!(
            "                {} => self.{}_written,\n",
            tag, field_name
        ));
    }
    output.push_str("                _ => false,\n");
    output.push_str("            };\n");
    output.push_str("            if !is_written {\n");
    output.push_str("                self.builder.write_raw(raw_bytes)?;\n");
    output.push_str("            }\n");
    output.push_str("        }\n");
    output.push_str("        Ok(self)\n");
    output.push_str("    }\n\n");

    output.push_str(&format!("    pub fn finish(self) -> roto_runtime::Result<&'b mut [u8]> {{\n        self.builder.finish()\n    }}\n}}\n\n"));

    output.push_str(&format!("pub struct Owned{} {{\n", msg_name));
    output.push_str("    pub data: bytes::Bytes,\n");
    output.push_str("}\n\n");

    output.push_str(&format!("impl roto_runtime::RotoOwned for Owned{} {{\n", msg_name));
    output.push_str(&format!("    type Reader<'a> = {}<'a>;\n", msg_name));
    output.push_str(&format!("    fn reader(&self) -> {}<'_> {{\n", msg_name));
    output.push_str(&format!("        {}::new(&self.data).expect(\"failed to create reader\")\n", msg_name));
    output.push_str("    }\n");
    output.push_str("}\n\n");

    output.push_str(&format!("impl roto_runtime::RotoMessage for Owned{} {{\n", msg_name));
    output.push_str("    fn decode(buf: bytes::Bytes) -> roto_runtime::Result<Self> {\n");
    output.push_str(&format!("        Ok(Owned{} {{ data: buf }})\n", msg_name));
    output.push_str("    }\n\n");
    output.push_str("    fn bytes(&self) -> bytes::Bytes {\n");
    output.push_str("        self.data.clone()\n");
    output.push_str("    }\n");
    output.push_str("}\n\n");

    let mut nested_enums = Vec::new();
    for e_res in msg_proto.enum_type() {
        if let Ok((e, _)) = e_res {
            nested_enums.push(e);
        }
    }
    let mut nested_msgs = Vec::new();
    for m_res in msg_proto.nested_type() {
        if let Ok((m, _)) = m_res {
            nested_msgs.push(m);
        }
    }

    if !nested_enums.is_empty() || !nested_msgs.is_empty() || !oneofs.is_empty() {
        let mod_name = to_snake_case(msg_proto.name().unwrap());
        output.push_str(&format!("pub mod {} {{\n", mod_name));
        for e_data in &nested_enums {
            write_enum(
                &EnumDescriptorProto::new(e_data)
                    .expect("Failed to parse nested EnumDescriptorProto"),
                output,
            );
        }
        for m_data in &nested_msgs {
            write_message(
                &DescriptorProto::new(m_data).expect("Failed to parse nested DescriptorProto"),
                output,
            );
        }

        for (oneof_index, oneof_proto) in oneofs.iter().enumerate() {
            let oneof_desc = OneofDescriptorProto::new(*oneof_proto)
                .expect("Failed to parse OneofDescriptorProto");
            let oneof_name = oneof_desc.name().unwrap();
            let pascal_oneof_name = to_pascal_case(oneof_name);
            output.push_str(&format!("pub enum {}<'a> {{\n", pascal_oneof_name));
            for (field_name, _tag, f_type, f_label, f_oneof_index, _is_map) in &fields_info {
                if *f_oneof_index == Some(oneof_index as i32) {
                    let (rust_type, _, _) = map_type_to_rust_accessor(*f_type, *f_label, *_is_map);
                    let safe_field_name = if field_name == "type" {
                        format!("r#{}", field_name)
                    } else {
                        field_name.clone()
                    };
                    output.push_str(&format!("    {}({}),\n", safe_field_name, rust_type));
                }
            }
            output.push_str("}\n\n");
        }
    }
    if !nested_enums.is_empty() || !nested_msgs.is_empty() || !oneofs.is_empty() {
        output.push_str("}\n\n");
    }
}

fn map_type_to_rust_builder(field_type: i32) -> (String, String) {
    match field_type {
        9 => ("&str".to_string(), "write_string".to_string()),
        5 | 17 => ("i32".to_string(), "write_int32".to_string()),
        3 | 4 | 8 | 13 | 14 | 18 => ("u64".to_string(), "write_varint".to_string()),
        7 | 15 => ("u32".to_string(), "write_fixed32".to_string()),
        6 | 16 => ("u64".to_string(), "write_fixed64".to_string()),
        11 | 12 => ("&[u8]".to_string(), "write_bytes".to_string()),
        _ => ("&[u8]".to_string(), "write_bytes".to_string()),
    }
}

pub fn generate_rust_code(
    set: &FileDescriptorSet,
    files_to_generate: Option<&[String]>,
    generate_mod_files: bool,
) -> Vec<(String, String)> {
    let mut generated_files = Vec::new();

    for file_res in set.file() {
        let (file_data, _) = file_res.expect("Failed to iterate file");
        let file_proto =
            FileDescriptorProto::new(file_data).expect("Failed to parse FileDescriptorProto");
        let proto_name = file_proto.name().expect("File proto name missing");

        if let Some(filter) = files_to_generate {
            if !filter.contains(&proto_name.to_string()) {
                continue;
            }
        }

        let rust_file_name = format!("{}.rs", proto_name.replace(".proto", ""));

        let mut output = String::new();
        output.push_str("// @generated by protoc-gen-roto — do not edit\n");
        output.push_str("#[allow(unused_imports)]\n\n");
        output.push_str("use roto_runtime::{ProtoAccessor, ProtoBuilder, Result, RotoError, read_varint, RepeatedFieldIterator};\n");
        output.push_str("use std::str;\n");
        output.push_str("use bytes::Bytes;\n");
        output.push_str("use tonic::{Request, Response, Status};\n");
        output.push_str("use tokio_stream::Stream;\n");
        output.push_str("use std::pin::Pin;\n\n");

        for dep_res in file_proto.dependency() {
            let (dep_data, _) = dep_res.expect("Failed to iterate dependency");
            let dep_name = str::from_utf8(dep_data).expect("Dependency name invalid utf8");
            let dep_mod_path = dep_name.replace(".proto", "").replace('/', "::");
            output.push_str(&format!("use crate::{};\n", dep_mod_path));
        }
        output.push_str("\n");

        // Enums
        for enum_res in file_proto.enum_type() {
            let (enum_data, _) = enum_res.expect("Failed to iterate enum");
            write_enum(
                &EnumDescriptorProto::new(enum_data).expect("Failed to parse EnumDescriptorProto"),
                &mut output,
            );
        }

        // Messages
        for msg_res in file_proto.message_type() {
            let (msg_data, _) = msg_res.expect("Failed to iterate message");
            write_message(
                &DescriptorProto::new(msg_data).expect("Failed to parse DescriptorProto"),
                &mut output,
            );
        }

        // Services
        for svc_res in file_proto.service() {
            let (svc_data, _) = svc_res.expect("Failed to iterate service");
            write_service(
                &ServiceDescriptorProto::new(svc_data).expect("Failed to parse ServiceDescriptorProto"),
                &mut output,
            );
        }
        generated_files.push((rust_file_name, output));
    }

    if !generate_mod_files {
        return generated_files;
    }

    let mut all_paths: Vec<String> = generated_files.iter().map(|(p, _)| p.clone()).collect();
    all_paths.sort();

    let mut mod_files: HashMap<String, HashSet<String>> = HashMap::new();
    for path in &all_paths {
        let parts: Vec<&str> = path.split('/').collect();
        let mut current_dir = String::new();
        for i in 0..parts.len() - 1 {
            if !current_dir.is_empty() {
                current_dir.push('/');
            }
            current_dir.push_str(parts[i]);
            let mod_path = format!("{}/mod.rs", current_dir);
            let sub_mod = parts[i + 1].replace(".rs", "");
            mod_files.entry(mod_path).or_default().insert(sub_mod);
        }
    }

    let mut root_mods = HashSet::new();
    for path in &all_paths {
        let parts: Vec<&str> = path.split('/').collect();
        root_mods.insert(parts[0].replace(".rs", ""));
    }

    let mut root_mod_content = String::new();
    root_mod_content.push_str("// @generated by protoc-gen-roto — do not edit\n");
    root_mod_content.push_str("#![allow(unused_imports)]\n\n");
    let mut sorted_root_mods: Vec<_> = root_mods.into_iter().collect();
    sorted_root_mods.sort();
    for m in sorted_root_mods {
        root_mod_content.push_str(&format!("pub mod {};\n", m));
    }
    generated_files.push(("mod.rs".to_string(), root_mod_content));

    for (mod_path, sub_mods) in mod_files {
        let mut content = String::new();
        content.push_str("// @generated by protoc-gen-roto — do not edit\n");
        content.push_str("#![allow(unused_imports)]\n\n");
        let mut sorted_subs: Vec<_> = sub_mods.into_iter().collect();
        sorted_subs.sort();
        for sub in sorted_subs {
            content.push_str(&format!("pub mod {};\n", sub));
        }
        generated_files.push((mod_path, content));
    }

    generated_files
}

fn write_service(svc_proto: &ServiceDescriptorProto, output: &mut String) {
    let svc_name = to_pascal_case(svc_proto.name().unwrap());
    output.push_str(&format!("#[tonic::async_trait]\npub trait {}: Send + Sync + 'static {{\n", svc_name));

    for method_res in svc_proto.method() {
        let (method_data, _) = method_res.expect("Failed to iterate method");
        let method_proto = MethodDescriptorProto::new(method_data).expect("Failed to parse MethodDescriptorProto");
        let method_name = to_snake_case(method_proto.name().unwrap());

        let input_full_name = method_proto.input_type().unwrap();
        let output_full_name = method_proto.output_type().unwrap();

        let input_type = input_full_name.split('.').last().unwrap();
        let output_type = output_full_name.split('.').last().unwrap();

        let input_owned = format!("Owned{}", input_type);
        let output_owned = format!("Owned{}", output_type);

        let client_streaming = method_proto.client_streaming().unwrap_or(false);
        let server_streaming = method_proto.server_streaming().unwrap_or(false);

        let req_type = if client_streaming {
            format!("Request<tonic::Streaming<{}>>", input_owned)
        } else {
            format!("Request<{}>", input_owned)
        };

        let resp_type = if server_streaming {
            format!("Response<Pin<Box<dyn Stream<Item = Result<{}, Status>> + Send>>>", output_owned)
        } else {
            format!("Response<{}>", output_owned)
        };

        output.push_str(&format!(
            "    async fn {}(&self, request: {}) -> std::result::Result<{}, Status>;\n",
            method_name, req_type, resp_type
        ));
    }
    output.push_str("}\n\n");
}