#![recursion_limit = "256"] // extern crate serde; // #[macro_use] // extern crate serde_derive; #[macro_use] extern crate nom; extern crate heck; extern crate proc_macro2; #[macro_use] extern crate quote; extern crate syn; pub extern crate vk_parse; pub extern crate vkxml; use heck::{CamelCase, ShoutySnakeCase, SnakeCase}; use proc_macro2::{Term, TokenTree}; use quote::Tokens; use std::collections::HashMap; use syn::Ident; #[derive(Copy, Clone, Debug)] pub enum CType { USize, U32, U64, Float, } impl CType { fn to_tokens(&self) -> Tokens { let term = match self { CType::USize => Term::intern("usize"), CType::U32 => Term::intern("u32"), CType::U64 => Term::intern("u64"), CType::Float => Term::intern("f32"), }; quote!{#term} } } named!(ctype<&str, CType>, alt!( tag!("ULL") => { |_| CType::U64 } | tag!("U") => { |_| CType::U32 } ) ); named!(cexpr<&str, (CType, String)>, alt!( map!(cfloat, |f| (CType::Float, format!("{:.2}", f))) | inverse_number ) ); named!(inverse_number<&str, (CType, String)>, do_parse!( tag!("(")>> tag!("~") >> s: take_while1!(|c: char| c.is_digit(10)) >> ctype: ctype >> minus_num: opt!( do_parse!( tag!("-") >> n: take_while1!(|c: char| c.is_digit(10)) >> (n) ) ) >> tag!(")") >> ( { let expr = if let Some(minus) = minus_num { format!("!{}-{}", s, minus) } else{ format!("!{}", s) }; (ctype, expr) } ) ) ); named!(cfloat<&str, f32>, terminated!(nom::float_s, char!('f')) ); pub fn define_handle_macro() -> Tokens { quote! { macro_rules! define_handle{ ($name: ident) => { #[derive(Clone, Copy, Debug)] #[repr(C)] pub struct $name{ ptr: *mut u8 } unsafe impl Send for $name {} unsafe impl Sync for $name {} impl $name{ pub unsafe fn null() -> Self{ $name{ ptr: ::std::ptr::null_mut() } } } } } } } pub fn handle_nondispatchable_macro() -> Tokens { quote!{ macro_rules! handle_nondispatchable { ($name: ident) => { #[repr(C)] #[derive(Eq, PartialEq, Ord, PartialOrd, Clone, Copy, Hash)] pub struct $name (uint64_t); impl $name{ pub fn null() -> $name{ $name(0) } } impl ::std::fmt::Pointer for $name { fn fmt(&self, f: &mut ::std::fmt::Formatter) -> ::std::result::Result<(), ::std::fmt::Error> { write!(f, "0x{:x}", self.0) } } impl ::std::fmt::Debug for $name { fn fmt(&self, f: &mut ::std::fmt::Formatter) -> ::std::result::Result<(), ::std::fmt::Error> { write!(f, "0x{:x}", self.0) } } } } } } pub fn vk_bitflags_wrapped_macro() -> Tokens { quote!{ macro_rules! vk_bitflags_wrapped { ($name: ident, $all: expr, $flag_type: ty) => { #[repr(C)] #[derive(Clone, Copy, PartialEq, Eq, PartialOrd, Ord, Hash)] pub struct $name {flags: $flag_type} impl Default for $name{ fn default() -> $name { $name {flags: 0} } } impl ::std::fmt::Debug for $name { fn fmt(&self, f: &mut ::std::fmt::Formatter) -> ::std::result::Result<(), ::std::fmt::Error> { write!(f, "{}({:b})", stringify!($name), self.flags) } } impl $name { #[inline] pub fn empty() -> $name { $name {flags: 0} } #[inline] pub fn all() -> $name { $name {flags: $all} } #[inline] pub fn flags(self) -> $flag_type { self.flags } #[inline] pub fn from_flags(flags: $flag_type) -> Option<$name> { if flags & !$all == 0 { Some($name {flags: flags}) } else { None } } #[inline] pub fn from_flags_truncate(flags: $flag_type) -> $name { $name {flags: flags & $all} } #[inline] pub fn is_empty(self) -> bool { self == $name::empty() } #[inline] pub fn is_all(self) -> bool { self & $name::all() == $name::all() } #[inline] pub fn intersects(self, other: $name) -> bool { self & other != $name::empty() } /// Returns true of `other` is a subset of `self` #[inline] pub fn subset(self, other: $name) -> bool { self & other == other } } impl ::std::ops::BitOr for $name { type Output = $name; #[inline] fn bitor(self, rhs: $name) -> $name { $name {flags: self.flags | rhs.flags } } } impl ::std::ops::BitOrAssign for $name { #[inline] fn bitor_assign(&mut self, rhs: $name) { *self = *self | rhs } } impl ::std::ops::BitAnd for $name { type Output = $name; #[inline] fn bitand(self, rhs: $name) -> $name { $name {flags: self.flags & rhs.flags} } } impl ::std::ops::BitAndAssign for $name { #[inline] fn bitand_assign(&mut self, rhs: $name) { *self = *self & rhs } } impl ::std::ops::BitXor for $name { type Output = $name; #[inline] fn bitxor(self, rhs: $name) -> $name { $name {flags: self.flags ^ rhs.flags} } } impl ::std::ops::BitXorAssign for $name { #[inline] fn bitxor_assign(&mut self, rhs: $name) { *self = *self ^ rhs } } impl ::std::ops::Sub for $name { type Output = $name; #[inline] fn sub(self, rhs: $name) -> $name { self & !rhs } } impl ::std::ops::SubAssign for $name { #[inline] fn sub_assign(&mut self, rhs: $name) { *self = *self - rhs } } impl ::std::ops::Not for $name { type Output = $name; #[inline] fn not(self) -> $name { self ^ $name::all() } } } } } } pub fn platform_specific_types() -> Tokens { quote! { pub type RROutput = c_ulong; pub type VisualID = c_uint; pub type Display = *const c_void; pub type Window = c_ulong; #[allow(non_camel_case_types)] pub type xcb_connection_t = *const c_void; #[allow(non_camel_case_types)] pub type xcb_window_t = u32; #[allow(non_camel_case_types)] pub type xcb_visualid_t = *const c_void; pub type MirConnection = *const c_void; pub type MirSurface = *const c_void; pub type HINSTANCE = *const c_void; pub type HWND = *const c_void; #[allow(non_camel_case_types)] pub type wl_display = *const c_void; #[allow(non_camel_case_types)] pub type wl_surface = *const c_void; pub type HANDLE = *mut c_void; pub type DWORD = c_ulong; pub type WCHAR = wchar_t; pub type LPCWSTR = *const WCHAR; // FIXME: Platform specific types that should come from a library // typedefs are only here so that the code compiles for now #[allow(non_camel_case_types)] pub type SECURITY_ATTRIBUTES = (); // Opage types pub type ANativeWindow = c_void; pub type AHardwareBuffer = c_void; } } #[derive(Debug, Copy, Clone)] pub enum ConstVal { U32(u32), U64(u64), Float(f32), } impl ConstVal { pub fn bits(&self) -> u64 { match self { ConstVal::U64(n) => *n, _ => panic!("Constval not supported"), } } } pub enum Constant { Number(i32), Hex(String), BitPos(u32), CExpr(vkxml::CExpression), Text(String), } impl quote::ToTokens for ConstVal { fn to_tokens(&self, tokens: &mut Tokens) { match self { ConstVal::U32(n) => n.to_tokens(tokens), ConstVal::U64(n) => n.to_tokens(tokens), ConstVal::Float(f) => f.to_tokens(tokens), } } } impl Constant { // pub fn type(&self) -> Type { // } pub fn value(&self) -> Option { match *self { Constant::Number(n) => Some(ConstVal::U64(n as u64)), Constant::Hex(ref hex) => u64::from_str_radix(&hex, 16).ok().map(ConstVal::U64), Constant::BitPos(pos) => Some(ConstVal::U64((1 << pos) as u64)), _ => None, } } pub fn ty(&self) -> CType { match self { Constant::Number(_) | Constant::Hex(_) => CType::USize, Constant::CExpr(expr) => { let (_, (ty, _)) = cexpr(expr).expect("Unable to parse cexpr"); ty } _ => unimplemented!(), } } pub fn to_tokens(&self) -> Tokens { match *self { Constant::Number(n) => { let term = Term::intern(&n.to_string()); quote!{#term} } Constant::Hex(ref s) => { let term = Term::intern(&format!("0x{}", s)); quote!{#term} } Constant::Text(ref text) => { quote!{#text} } Constant::CExpr(ref expr) => { let (_, (_, rexpr)) = cexpr(expr).expect("Unable to parse cexpr"); let term = Term::intern(rexpr.as_str()); quote!{#term} } Constant::BitPos(pos) => { let value = 1 << pos; let term = Term::intern(&format!("0b{:b}", value)); quote!{#term} } } } pub fn from_constant(constant: &vkxml::Constant) -> Self { let number = constant.number.map(|n| Constant::Number(n)); let hex = constant.hex.as_ref().map(|hex| Constant::Hex(hex.clone())); let bitpos = constant.bitpos.map(|bit| Constant::BitPos(bit)); let expr = constant .c_expression .as_ref() .map(|e| Constant::CExpr(e.clone())); number.or(hex).or(bitpos).or(expr).expect("") } pub fn from_extension(extension: &vkxml::ExtensionConstant) -> Self { let number = extension.number.map(|n| Constant::Number(n)); let hex = extension.hex.as_ref().map(|hex| Constant::Hex(hex.clone())); let bitpos = extension.bitpos.map(|bit| Constant::BitPos(bit)); let expr = extension .c_expression .as_ref() .map(|e| Constant::CExpr(e.clone())); let text = extension.text.as_ref().map(|e| Constant::Text(e.clone())); number.or(hex).or(bitpos).or(expr).or(text).expect("") } } pub trait ConstantExt {} impl ConstantExt for vkxml::Constant {} pub trait FeatureExt { fn version_string(&self) -> String; } impl FeatureExt for vkxml::Feature { fn version_string(&self) -> String { let mut version = format!("{}", self.version); if version.len() == 1 { version = format!("{}_0", version) } version.replace(".", "_") } } #[derive(Debug, Copy, Clone)] pub enum FunctionType { Static, Entry, Instance, Device, } pub trait CommandExt { /// Returns the ident in snake_case and without the 'vk' prefix. fn function_type(&self) -> FunctionType; /// /// Returns true if the command is a device level command. This is indicated by /// the type of the first parameter. fn command_ident(&self) -> Ident; } impl CommandExt for vkxml::Command { fn command_ident(&self) -> Ident { Ident::from(self.name[2..].to_snake_case().as_str()) } fn function_type(&self) -> FunctionType { let is_first_param_device = self .param .iter() .nth(0) .map(|field| match field.basetype.as_str() { "VkDevice" | "VkCommandBuffer" | "VkQueue" => true, _ => false, }) .unwrap_or(false); match self.name.as_str() { "vkGetInstanceProcAddr" => FunctionType::Static, "vkCreateInstance" | "vkEnumerateInstanceLayerProperties" | "vkEnumerateInstanceExtensionProperties" => FunctionType::Entry, // This is actually not a device level function "vkGetDeviceProcAddr" => FunctionType::Instance, _ => { if is_first_param_device { FunctionType::Device } else { FunctionType::Instance } } } } } pub trait FieldExt { /// Returns the name of the paramter that doesn't clash with Rusts resevered /// keywords fn param_ident(&self) -> Ident; /// Returns the basetype ident and removes the 'Vk' prefix fn type_tokens(&self) -> Tokens; fn is_clone(&self) -> bool; } pub trait ToTokens { fn to_tokens(&self) -> Tokens; } impl ToTokens for vkxml::ReferenceType { fn to_tokens(&self) -> Tokens { let ptr_name = match self { vkxml::ReferenceType::Pointer => "*const", vkxml::ReferenceType::PointerToPointer => "*mut *mut", vkxml::ReferenceType::PointerToConstPointer => "*const", }; let ident = Term::intern(ptr_name); quote!{ #ident } } } fn name_to_tokens(type_name: &str) -> Tokens { let new_name = match type_name { "int" => "c_int", "void" => "c_void", "char" => "c_char", "float" => "c_float", "long" => "c_ulong", _ => { if type_name.starts_with("Vk") { &type_name[2..] } else { type_name } } }; let new_name = new_name.replace("FlagBits", "Flags"); let name = Term::intern(new_name.as_str()); quote! { #name } } fn to_type_tokens(type_name: &str, reference: Option<&vkxml::ReferenceType>) -> Tokens { let new_name = name_to_tokens(type_name); let ptr_name = reference.map(|r| r.to_tokens()).unwrap_or(quote!{}); quote!{#ptr_name #new_name} } impl FieldExt for vkxml::Field { fn is_clone(&self) -> bool { true } fn param_ident(&self) -> Ident { let name = self.name.as_ref().map(|s| s.as_str()).unwrap_or("field"); let name_corrected = match name { "type" => "ty", _ => name, }; Ident::from(name_corrected.to_snake_case().as_str()) } fn type_tokens(&self) -> Tokens { let ty = name_to_tokens(&self.basetype); let pointer = self .reference .as_ref() .map(|r| r.to_tokens()) .unwrap_or(quote!{}); let pointer_ty = quote!{ #pointer #ty }; let array = self.array.as_ref().and_then(|arraytype| match arraytype { vkxml::ArrayType::Static => { let size = self .size .as_ref() .or(self.size_enumref.as_ref()) .expect("Should have size"); let size = Term::intern(size); Some(quote!{ [#ty; #size] }) } _ => None, }); array.unwrap_or(pointer_ty) } } pub type CommandMap<'a> = HashMap; fn generate_function_pointers(ident: Ident, commands: &[&vkxml::Command]) -> quote::Tokens { let names: Vec<_> = commands.iter().map(|cmd| cmd.command_ident()).collect(); let names_ref = &names; let raw_names: Vec<_> = commands .iter() .map(|cmd| Ident::from(cmd.name.as_str())) .collect(); let raw_names_ref = &raw_names; let names_left = &names; let names_right = &names; let params: Vec> = commands .iter() .map(|cmd| { let fn_name_raw = cmd.name.as_str(); let fn_name_snake = cmd.command_ident(); let params: Vec<_> = cmd .param .iter() .map(|field| { let name = field.param_ident(); let ty = field.type_tokens(); (name, ty) }) .collect(); params }) .collect(); let params_names: Vec> = params .iter() .map(|inner_params| { inner_params .iter() .map(|&(param_name, _)| param_name) .collect() }) .collect(); let param_names_ref = ¶ms_names; let expanded_params: Vec<_> = params .iter() .map(|inner_params| { let inner_params_iter = inner_params.iter().map(|&(ref param_name, ref param_ty)| { quote!{#param_name: #param_ty} }); quote!{ #(#inner_params_iter,)* } }) .collect(); let expanded_params_ref = &expanded_params; let params_ref = ¶ms; let return_types: Vec<_> = commands .iter() .map(|cmd| cmd.return_type.type_tokens()) .collect(); let return_types_ref = &return_types; quote!{ pub struct #ident { #( #names_ref: extern "system" fn(#expanded_params_ref) -> #return_types_ref, )* } unsafe impl Send for #ident {} unsafe impl Sync for #ident {} impl ::std::clone::Clone for #ident { fn clone(&self) -> Self { #ident{ #(#names_left: self.#names_right,)* } } } impl #ident { pub fn load(mut _f: F) -> ::std::result::Result> where F: FnMut(&::std::ffi::CStr) -> *const c_void { let mut _err_str = Vec::new(); let s = #ident { #( #names_ref: unsafe { let raw_name = stringify!(#raw_names_ref); let cname = ::std::ffi::CString::new(raw_name).unwrap(); let val = _f(&cname); if val.is_null(){ _err_str.push(raw_name); } ::std::mem::transmute(val) }, )* }; if _err_str.is_empty() { Ok(s) } else{ Err(_err_str) } } #( pub unsafe fn #names_ref(&self, #expanded_params_ref) -> #return_types_ref { (self.#names_left)(#(#param_names_ref,)*) } )* } } } pub fn generate_extension(extension: &vkxml::Extension, commands: &CommandMap) -> quote::Tokens { let extension_commands: Vec<&vkxml::Command> = extension .elements .iter() .flat_map(|extension| { if let &vkxml::ExtensionElement::Require(ref spec) = extension { spec.elements .iter() .filter_map(|extension_spec| { if let &vkxml::ExtensionSpecificationElement::CommandReference( ref cmd_ref, ) = extension_spec { Some(cmd_ref) } else { None } }) .collect() } else { vec![] } }) .filter_map(|cmd_ref| commands.get(&cmd_ref.name)) .map(|&cmd| cmd) .collect(); if extension_commands.is_empty() { return quote!{}; } let name = format!("{}Fn", extension.name.to_camel_case()); let ident = Ident::from(&name[2..]); generate_function_pointers(ident, &extension_commands) } pub fn generate_typedef(typedef: &vkxml::Typedef) -> Tokens { let typedef_name = to_type_tokens(&typedef.name, None); let typedef_ty = to_type_tokens(&typedef.basetype, None); quote!{ pub type #typedef_name = #typedef_ty; } } pub fn generate_bitmask(bitmask: &vkxml::Bitmask) -> Option { // Workaround for empty bitmask if bitmask.name.len() == 0 { return None; } // If this enum has constants, then it will generated later in generate_enums. if bitmask.enumref.is_some() { return None; } let name = &bitmask.name[2..]; let ident = Ident::from(name); Some(quote!{ vk_bitflags_wrapped!(#ident, 0b0, Flags); }) } pub fn to_variant_ident(enum_name: &str, variant_name: &str) -> Ident { let tag = ["AMD", "NN", "KHR", "NV", "EXT", "NVX", "KHX"] .iter() .filter_map(|tag| { if enum_name.ends_with(tag) { Some(tag) } else { None } }) .nth(0); let name_without_tag = tag .map(|t| enum_name.replace(t, "")) .unwrap_or(enum_name.into()); let variant_without_tag = tag .map(|t| variant_name.replace(t, "")) .unwrap_or(variant_name.into()); let camel_case_name_enum = &name_without_tag.to_camel_case(); let name = variant_without_tag.to_camel_case()[2..].replace(camel_case_name_enum, ""); let is_digit = name.chars().nth(0).map(|c| c.is_digit(10)).unwrap_or(false); if is_digit { Ident::from(format!("Type{}", name).as_str()) } else { Ident::from(name) } } pub enum EnumType { Bitflags(Tokens), Enum(Tokens), } pub fn generate_enum(_enum: &vkxml::Enumeration) -> EnumType { let name = &_enum.name[2..]; let _name = name.replace("FlagBits", "Flags"); if name.contains("Bit") { let ident = Ident::from(_name.as_str()); let all_bits = _enum .elements .iter() .filter_map(|elem| match elem { vkxml::EnumerationElement::Enum(ref constant) => { let c = Constant::from_constant(constant); c.value() } _ => None, }) .fold(0, |acc, next| acc | next.bits()); let all_bits_term = Term::intern(&format!("0b{:b}", all_bits)); let variants = _enum.elements.iter().filter_map(|elem| { let (variant_name, value) = match *elem { vkxml::EnumerationElement::Enum(ref constant) => { let variant_name = &constant.name[3..]; let c = Constant::from_constant(constant); if c.value().map(|v| v.bits() == 0).unwrap_or(false) { return None; } (variant_name, c.to_tokens()) } _ => { return None; } }; let variant_ident = Ident::from(variant_name); Some(quote!{ pub const #variant_ident: #ident = #ident { flags: #value }; }) }); let q = quote!{ #(#variants)* vk_bitflags_wrapped!(#ident, #all_bits_term, Flags); }; EnumType::Bitflags(q) } else { let q = match _name.as_str() { "Result" => generate_result(&_name, _enum), _ => { let ident = Ident::from(_name.as_str()); let variants = _enum.elements.iter().filter_map(|elem| { let (variant_name, value) = match *elem { vkxml::EnumerationElement::Enum(ref constant) => { let c = Constant::from_constant(constant); //println!("value {:?}", c.value()); (constant.name.as_str(), c.to_tokens()) } _ => { return None; } }; let variant_ident = to_variant_ident(&_name, variant_name); Some(quote!{ #variant_ident = #value }) }); quote!{ #[derive(Debug, Clone, Copy, PartialEq, Eq, PartialOrd, Ord, Hash)] #[repr(C)] pub enum #ident { #(#variants,)* } } } }; EnumType::Enum(q) } } pub fn generate_result(name: &str, _enum: &vkxml::Enumeration) -> Tokens { let ident = Ident::from(name); let variants = _enum.elements.iter().filter_map(|elem| { let (variant_name, value) = match *elem { vkxml::EnumerationElement::Enum(ref constant) => { let c = Constant::from_constant(constant); //println!("value {:?}", c.value()); (constant.name.as_str(), c.to_tokens()) } _ => { return None; } }; let variant_ident = to_variant_ident(&name, variant_name); Some(quote!{ #variant_ident = #value }) }); let notation = _enum.elements.iter().filter_map(|elem| { let (variant_name, notation) = match *elem { vkxml::EnumerationElement::Enum(ref constant) => ( constant.name.as_str(), constant.notation.as_ref().map(|s| s.as_str()).unwrap_or(""), ), _ => { return None; } }; let variant_ident = to_variant_ident(&name, variant_name); Some(quote!{ #ident::#variant_ident => write!(fmt, #notation) }) }); quote!{ #[derive(Debug, Clone, Copy, PartialEq, Eq, PartialOrd, Ord, Hash)] #[repr(C)] pub enum #ident { #(#variants,)* } impl ::std::error::Error for #ident { fn description(&self) -> &str { "vk::Result" } } impl ::std::fmt::Display for #ident { fn fmt(&self, fmt: &mut ::std::fmt::Formatter) -> ::std::fmt::Result { writeln!(fmt, "vk::Result::{:?}", self)?; match self { #(#notation),* } } } } } pub trait StructExt {} pub fn generate_struct(_struct: &vkxml::Struct) -> Tokens { let name = to_type_tokens(&_struct.name, None); let members = _struct.elements.iter().filter_map(|elem| match *elem { vkxml::StructElement::Member(ref field) => Some(field), _ => None, }); let params = members.clone().map(|field| { let param_ident = field.param_ident(); let param_ty_tokens = field.type_tokens(); quote!{pub #param_ident: #param_ty_tokens} }); let contains_pfn = members.clone().any(|field| { field .name .as_ref() .map(|n| n.contains("pfn")) .unwrap_or(false) }); let derive = if contains_pfn { quote!{ #[derive(Copy, Clone)] } } else { // FIXME: Properly derive Debug quote!{ #[derive(Copy, Clone)] } }; quote!{ #[repr(C)] #derive pub struct #name { #(#params,)* } } } pub fn generate_handle(handle: &vkxml::Handle) -> Option { if handle.name == "" { return None; } let tokens = match handle.ty { vkxml::HandleType::Dispatch => { let name = &handle.name[2..]; let name = Ident::from(name); quote! { define_handle!(#name); } } vkxml::HandleType::NoDispatch => { let name = &handle.name[2..]; let name = Ident::from(name); quote! { handle_nondispatchable!(#name); } } }; Some(tokens) } fn generate_funcptr(fnptr: &vkxml::FunctionPointer) -> Tokens { let name = Ident::from(fnptr.name.as_str()); let ret_ty_tokens = fnptr.return_type.type_tokens(); quote!{ #[allow(non_camel_case_types)] pub type #name = unsafe extern "system" fn() -> #ret_ty_tokens; } } fn generate_union(union: &vkxml::Union) -> Tokens { let name = to_type_tokens(&union.name, None); let fields = union.elements.iter().map(|field| { let name = field.param_ident(); let ty = field.type_tokens(); quote!{ pub #name: #ty } }); quote!{ #[repr(C)] #[derive(Copy, Clone)] pub union #name { #(#fields),* } } } pub fn generate_definition(definition: &vkxml::DefinitionsElement) -> Option { match *definition { vkxml::DefinitionsElement::Typedef(ref typedef) => Some(generate_typedef(typedef)), vkxml::DefinitionsElement::Struct(ref _struct) => Some(generate_struct(_struct)), vkxml::DefinitionsElement::Bitmask(ref mask) => generate_bitmask(mask), vkxml::DefinitionsElement::Handle(ref handle) => generate_handle(handle), vkxml::DefinitionsElement::FuncPtr(ref fp) => Some(generate_funcptr(fp)), vkxml::DefinitionsElement::Union(ref union) => Some(generate_union(union)), _ => None, } } pub fn generate_feature(feature: &vkxml::Feature, commands: &CommandMap) -> quote::Tokens { let (static_commands, entry_commands, device_commands, instance_commands) = feature .elements .iter() .flat_map(|feature| { if let &vkxml::FeatureElement::Require(ref spec) = feature { spec.elements .iter() .filter_map(|feature_spec| { if let &vkxml::FeatureReference::CommandReference(ref cmd_ref) = feature_spec { Some(cmd_ref) } else { None } }) .collect() } else { vec![] } }) .filter_map(|cmd_ref| commands.get(&cmd_ref.name)) .fold( (Vec::new(), Vec::new(), Vec::new(), Vec::new()), |mut acc, &cmd_ref| { match cmd_ref.function_type() { FunctionType::Static => { acc.0.push(cmd_ref); } FunctionType::Entry => { acc.1.push(cmd_ref); } FunctionType::Device => { acc.2.push(cmd_ref); } FunctionType::Instance => { acc.3.push(cmd_ref); } } acc }, ); let version = feature.version_string(); let static_fn = if feature.version == 1.0 { generate_function_pointers(Ident::from("StaticFn"), &static_commands) } else { quote!{} }; let entry = generate_function_pointers( Ident::from(format!("EntryFnV{}", version).as_str()), &entry_commands, ); let instance = generate_function_pointers( Ident::from(format!("InstanceFnV{}", version).as_str()), &instance_commands, ); let device = generate_function_pointers( Ident::from(format!("DeviceFnV{}", version).as_str()), &device_commands, ); quote! { #static_fn #entry #instance #device } } pub fn generate_constant(constant: &vkxml::Constant) -> Tokens { let c = Constant::from_constant(constant); let ident = Ident::from(constant.name.as_str()); let value = c.to_tokens(); let ty = c.ty().to_tokens(); quote!{ pub const #ident: #ty = #value; } } pub fn write_source_code(spec: &vkxml::Registry) { use std::fs::File; use std::io::Write; println!("{:#?}", spec); let commands: HashMap = spec .elements .iter() .filter_map(|elem| match elem { &vkxml::RegistryElement::Commands(ref cmds) => Some(cmds), _ => None, }) .flat_map(|cmds| cmds.elements.iter().map(|cmd| (cmd.name.clone(), cmd))) .collect(); let features: Vec<&vkxml::Feature> = spec .elements .iter() .filter_map(|elem| match elem { &vkxml::RegistryElement::Features(ref features) => Some(features), _ => None, }) .flat_map(|features| features.elements.iter().map(|feature| feature)) .collect(); let extensions: Vec<&vkxml::Extension> = spec .elements .iter() .filter_map(|elem| match elem { &vkxml::RegistryElement::Extensions(ref extensions) => Some(extensions), _ => None, }) .flat_map(|extensions| extensions.elements.iter().map(|extension| extension)) .collect(); let definitions: Vec<&vkxml::DefinitionsElement> = spec .elements .iter() .filter_map(|elem| match elem { &vkxml::RegistryElement::Definitions(ref definitions) => Some(definitions), _ => None, }) .flat_map(|definitions| definitions.elements.iter().map(|definition| definition)) .collect(); let enums: Vec<&vkxml::Enumeration> = spec .elements .iter() .filter_map(|elem| match elem { &vkxml::RegistryElement::Enums(ref enums) => Some(enums), _ => None, }) .flat_map(|enums| { enums.elements.iter().filter_map(|_enum| match *_enum { vkxml::EnumsElement::Enumeration(ref e) => Some(e), _ => None, }) }) .collect(); let constants: Vec<&vkxml::Constant> = spec .elements .iter() .filter_map(|elem| match elem { &vkxml::RegistryElement::Constants(ref constants) => Some(constants), _ => None, }) .flat_map(|constants| constants.elements.iter()) .collect(); let (enum_code, bitflags_code) = enums.into_iter().map(generate_enum).fold( (Vec::new(), Vec::new()), |mut acc, elem| { match elem { EnumType::Enum(token) => acc.0.push(token), EnumType::Bitflags(token) => acc.1.push(token), }; acc }, ); let definition_code: Vec<_> = definitions .into_iter() .filter_map(generate_definition) .collect(); let feature_code: Vec<_> = features .iter() .map(|feature| generate_feature(feature, &commands)) .collect(); let extension_code: Vec<_> = extensions .iter() .map(|ext| generate_extension(ext, &commands)) .collect(); let constants_code: Vec<_> = constants .iter() .map(|constant| generate_constant(constant)) .collect(); let mut file = File::create("../ash/src/vk_test.rs").expect("vk"); let bitflags_macro = vk_bitflags_wrapped_macro(); let handle_nondispatchable_macro = handle_nondispatchable_macro(); let define_handle_macro = define_handle_macro(); let platform_specific_types = platform_specific_types(); let source_code = quote!{ pub use libc::*; #platform_specific_types #bitflags_macro #handle_nondispatchable_macro #define_handle_macro #(#feature_code)* #(#definition_code)* #(#enum_code)* #(#bitflags_code)* #(#constants_code)* #(#extension_code)* }; write!(&mut file, "{}", source_code); }