use rustc_ast as ast; use rustc_ast::ptr::P; use rustc_ast::token::{self, Delimiter}; use rustc_ast::tokenstream::TokenStream; use rustc_data_structures::fx::{FxHashMap, FxIndexMap}; use rustc_errors::PResult; use rustc_expand::base::{self, *}; use rustc_index::bit_set::GrowableBitSet; use rustc_parse::parser::Parser; use rustc_parse_format as parse; use rustc_session::lint; use rustc_session::parse::ParseSess; use rustc_span::symbol::Ident; use rustc_span::symbol::{kw, sym, Symbol}; use rustc_span::{InnerSpan, Span}; use rustc_target::asm::InlineAsmArch; use smallvec::smallvec; use crate::errors; pub struct AsmArgs { pub templates: Vec>, pub operands: Vec<(ast::InlineAsmOperand, Span)>, named_args: FxIndexMap, reg_args: GrowableBitSet, pub clobber_abis: Vec<(Symbol, Span)>, options: ast::InlineAsmOptions, pub options_spans: Vec, } fn parse_args<'a>( ecx: &mut ExtCtxt<'a>, sp: Span, tts: TokenStream, is_global_asm: bool, ) -> PResult<'a, AsmArgs> { let mut p = ecx.new_parser_from_tts(tts); let sess = &ecx.sess.parse_sess; parse_asm_args(&mut p, sess, sp, is_global_asm) } // Primarily public for rustfmt consumption. // Internal consumers should continue to leverage `expand_asm`/`expand__global_asm` pub fn parse_asm_args<'a>( p: &mut Parser<'a>, sess: &'a ParseSess, sp: Span, is_global_asm: bool, ) -> PResult<'a, AsmArgs> { let diag = &sess.span_diagnostic; if p.token == token::Eof { return Err(diag.create_err(errors::AsmRequiresTemplate { span: sp })); } let first_template = p.parse_expr()?; let mut args = AsmArgs { templates: vec![first_template], operands: vec![], named_args: Default::default(), reg_args: Default::default(), clobber_abis: Vec::new(), options: ast::InlineAsmOptions::empty(), options_spans: vec![], }; let mut allow_templates = true; while p.token != token::Eof { if !p.eat(&token::Comma) { if allow_templates { // After a template string, we always expect *only* a comma... return Err(diag.create_err(errors::AsmExpectedComma { span: p.token.span })); } else { // ...after that delegate to `expect` to also include the other expected tokens. return Err(p.expect(&token::Comma).err().unwrap()); } } if p.token == token::Eof { break; } // accept trailing commas // Parse clobber_abi if p.eat_keyword(sym::clobber_abi) { parse_clobber_abi(p, &mut args)?; allow_templates = false; continue; } // Parse options if p.eat_keyword(sym::options) { parse_options(p, &mut args, is_global_asm)?; allow_templates = false; continue; } let span_start = p.token.span; // Parse operand names let name = if p.token.is_ident() && p.look_ahead(1, |t| *t == token::Eq) { let (ident, _) = p.token.ident().unwrap(); p.bump(); p.expect(&token::Eq)?; allow_templates = false; Some(ident.name) } else { None }; let mut explicit_reg = false; let op = if !is_global_asm && p.eat_keyword(kw::In) { let reg = parse_reg(p, &mut explicit_reg)?; if p.eat_keyword(kw::Underscore) { let err = diag.create_err(errors::AsmUnderscoreInput { span: p.token.span }); return Err(err); } let expr = p.parse_expr()?; ast::InlineAsmOperand::In { reg, expr } } else if !is_global_asm && p.eat_keyword(sym::out) { let reg = parse_reg(p, &mut explicit_reg)?; let expr = if p.eat_keyword(kw::Underscore) { None } else { Some(p.parse_expr()?) }; ast::InlineAsmOperand::Out { reg, expr, late: false } } else if !is_global_asm && p.eat_keyword(sym::lateout) { let reg = parse_reg(p, &mut explicit_reg)?; let expr = if p.eat_keyword(kw::Underscore) { None } else { Some(p.parse_expr()?) }; ast::InlineAsmOperand::Out { reg, expr, late: true } } else if !is_global_asm && p.eat_keyword(sym::inout) { let reg = parse_reg(p, &mut explicit_reg)?; if p.eat_keyword(kw::Underscore) { let err = diag.create_err(errors::AsmUnderscoreInput { span: p.token.span }); return Err(err); } let expr = p.parse_expr()?; if p.eat(&token::FatArrow) { let out_expr = if p.eat_keyword(kw::Underscore) { None } else { Some(p.parse_expr()?) }; ast::InlineAsmOperand::SplitInOut { reg, in_expr: expr, out_expr, late: false } } else { ast::InlineAsmOperand::InOut { reg, expr, late: false } } } else if !is_global_asm && p.eat_keyword(sym::inlateout) { let reg = parse_reg(p, &mut explicit_reg)?; if p.eat_keyword(kw::Underscore) { let err = diag.create_err(errors::AsmUnderscoreInput { span: p.token.span }); return Err(err); } let expr = p.parse_expr()?; if p.eat(&token::FatArrow) { let out_expr = if p.eat_keyword(kw::Underscore) { None } else { Some(p.parse_expr()?) }; ast::InlineAsmOperand::SplitInOut { reg, in_expr: expr, out_expr, late: true } } else { ast::InlineAsmOperand::InOut { reg, expr, late: true } } } else if p.eat_keyword(kw::Const) { let anon_const = p.parse_expr_anon_const()?; ast::InlineAsmOperand::Const { anon_const } } else if p.eat_keyword(sym::sym) { let expr = p.parse_expr()?; let ast::ExprKind::Path(qself, path) = &expr.kind else { let err = diag .create_err(errors::AsmSymNoPath { span: expr.span }); return Err(err); }; let sym = ast::InlineAsmSym { id: ast::DUMMY_NODE_ID, qself: qself.clone(), path: path.clone(), }; ast::InlineAsmOperand::Sym { sym } } else if allow_templates { let template = p.parse_expr()?; // If it can't possibly expand to a string, provide diagnostics here to include other // things it could have been. match template.kind { ast::ExprKind::Lit(token_lit) if matches!( token_lit.kind, token::LitKind::Str | token::LitKind::StrRaw(_) ) => {} ast::ExprKind::MacCall(..) => {} _ => { let err = diag.create_err(errors::AsmExpectedOther { span: template.span, is_global_asm, }); return Err(err); } } args.templates.push(template); continue; } else { return p.unexpected(); }; allow_templates = false; let span = span_start.to(p.prev_token.span); let slot = args.operands.len(); args.operands.push((op, span)); // Validate the order of named, positional & explicit register operands and // clobber_abi/options. We do this at the end once we have the full span // of the argument available. if explicit_reg { if name.is_some() { diag.emit_err(errors::AsmExplicitRegisterName { span }); } args.reg_args.insert(slot); } else if let Some(name) = name { if let Some(&prev) = args.named_args.get(&name) { diag.emit_err(errors::AsmDuplicateArg { span, name, prev: args.operands[prev].1 }); continue; } args.named_args.insert(name, slot); } else { if !args.named_args.is_empty() || !args.reg_args.is_empty() { let named = args.named_args.values().map(|p| args.operands[*p].1).collect(); let explicit = args.reg_args.iter().map(|p| args.operands[p].1).collect(); diag.emit_err(errors::AsmPositionalAfter { span, named, explicit }); } } } if args.options.contains(ast::InlineAsmOptions::NOMEM) && args.options.contains(ast::InlineAsmOptions::READONLY) { let spans = args.options_spans.clone(); diag.emit_err(errors::AsmMutuallyExclusive { spans, opt1: "nomem", opt2: "readonly" }); } if args.options.contains(ast::InlineAsmOptions::PURE) && args.options.contains(ast::InlineAsmOptions::NORETURN) { let spans = args.options_spans.clone(); diag.emit_err(errors::AsmMutuallyExclusive { spans, opt1: "pure", opt2: "noreturn" }); } if args.options.contains(ast::InlineAsmOptions::PURE) && !args.options.intersects(ast::InlineAsmOptions::NOMEM | ast::InlineAsmOptions::READONLY) { let spans = args.options_spans.clone(); diag.emit_err(errors::AsmPureCombine { spans }); } let mut have_real_output = false; let mut outputs_sp = vec![]; let mut regclass_outputs = vec![]; for (op, op_sp) in &args.operands { match op { ast::InlineAsmOperand::Out { reg, expr, .. } | ast::InlineAsmOperand::SplitInOut { reg, out_expr: expr, .. } => { outputs_sp.push(*op_sp); have_real_output |= expr.is_some(); if let ast::InlineAsmRegOrRegClass::RegClass(_) = reg { regclass_outputs.push(*op_sp); } } ast::InlineAsmOperand::InOut { reg, .. } => { outputs_sp.push(*op_sp); have_real_output = true; if let ast::InlineAsmRegOrRegClass::RegClass(_) = reg { regclass_outputs.push(*op_sp); } } _ => {} } } if args.options.contains(ast::InlineAsmOptions::PURE) && !have_real_output { diag.emit_err(errors::AsmPureNoOutput { spans: args.options_spans.clone() }); } if args.options.contains(ast::InlineAsmOptions::NORETURN) && !outputs_sp.is_empty() { let err = diag.create_err(errors::AsmNoReturn { outputs_sp }); // Bail out now since this is likely to confuse MIR return Err(err); } if args.clobber_abis.len() > 0 { if is_global_asm { let err = diag.create_err(errors::GlobalAsmClobberAbi { spans: args.clobber_abis.iter().map(|(_, span)| *span).collect(), }); // Bail out now since this is likely to confuse later stages return Err(err); } if !regclass_outputs.is_empty() { diag.emit_err(errors::AsmClobberNoReg { spans: regclass_outputs, clobbers: args.clobber_abis.iter().map(|(_, span)| *span).collect(), }); } } Ok(args) } /// Report a duplicate option error. /// /// This function must be called immediately after the option token is parsed. /// Otherwise, the suggestion will be incorrect. fn err_duplicate_option(p: &mut Parser<'_>, symbol: Symbol, span: Span) { // Tool-only output let full_span = if p.token.kind == token::Comma { span.to(p.token.span) } else { span }; p.sess.span_diagnostic.emit_err(errors::AsmOptAlreadyprovided { span, symbol, full_span }); } /// Try to set the provided option in the provided `AsmArgs`. /// If it is already set, report a duplicate option error. /// /// This function must be called immediately after the option token is parsed. /// Otherwise, the error will not point to the correct spot. fn try_set_option<'a>( p: &mut Parser<'a>, args: &mut AsmArgs, symbol: Symbol, option: ast::InlineAsmOptions, ) { if !args.options.contains(option) { args.options |= option; } else { err_duplicate_option(p, symbol, p.prev_token.span); } } fn parse_options<'a>( p: &mut Parser<'a>, args: &mut AsmArgs, is_global_asm: bool, ) -> PResult<'a, ()> { let span_start = p.prev_token.span; p.expect(&token::OpenDelim(Delimiter::Parenthesis))?; while !p.eat(&token::CloseDelim(Delimiter::Parenthesis)) { if !is_global_asm && p.eat_keyword(sym::pure) { try_set_option(p, args, sym::pure, ast::InlineAsmOptions::PURE); } else if !is_global_asm && p.eat_keyword(sym::nomem) { try_set_option(p, args, sym::nomem, ast::InlineAsmOptions::NOMEM); } else if !is_global_asm && p.eat_keyword(sym::readonly) { try_set_option(p, args, sym::readonly, ast::InlineAsmOptions::READONLY); } else if !is_global_asm && p.eat_keyword(sym::preserves_flags) { try_set_option(p, args, sym::preserves_flags, ast::InlineAsmOptions::PRESERVES_FLAGS); } else if !is_global_asm && p.eat_keyword(sym::noreturn) { try_set_option(p, args, sym::noreturn, ast::InlineAsmOptions::NORETURN); } else if !is_global_asm && p.eat_keyword(sym::nostack) { try_set_option(p, args, sym::nostack, ast::InlineAsmOptions::NOSTACK); } else if !is_global_asm && p.eat_keyword(sym::may_unwind) { try_set_option(p, args, kw::Raw, ast::InlineAsmOptions::MAY_UNWIND); } else if p.eat_keyword(sym::att_syntax) { try_set_option(p, args, sym::att_syntax, ast::InlineAsmOptions::ATT_SYNTAX); } else if p.eat_keyword(kw::Raw) { try_set_option(p, args, kw::Raw, ast::InlineAsmOptions::RAW); } else { return p.unexpected(); } // Allow trailing commas if p.eat(&token::CloseDelim(Delimiter::Parenthesis)) { break; } p.expect(&token::Comma)?; } let new_span = span_start.to(p.prev_token.span); args.options_spans.push(new_span); Ok(()) } fn parse_clobber_abi<'a>(p: &mut Parser<'a>, args: &mut AsmArgs) -> PResult<'a, ()> { let span_start = p.prev_token.span; p.expect(&token::OpenDelim(Delimiter::Parenthesis))?; if p.eat(&token::CloseDelim(Delimiter::Parenthesis)) { return Err(p.sess.span_diagnostic.create_err(errors::NonABI { span: p.token.span })); } let mut new_abis = Vec::new(); while !p.eat(&token::CloseDelim(Delimiter::Parenthesis)) { match p.parse_str_lit() { Ok(str_lit) => { new_abis.push((str_lit.symbol_unescaped, str_lit.span)); } Err(opt_lit) => { let span = opt_lit.map_or(p.token.span, |lit| lit.span); let mut err = p.sess.span_diagnostic.struct_span_err(span, "expected string literal"); err.span_label(span, "not a string literal"); return Err(err); } }; // Allow trailing commas if p.eat(&token::CloseDelim(Delimiter::Parenthesis)) { break; } p.expect(&token::Comma)?; } let full_span = span_start.to(p.prev_token.span); match &new_abis[..] { // should have errored above during parsing [] => unreachable!(), [(abi, _span)] => args.clobber_abis.push((*abi, full_span)), [abis @ ..] => { for (abi, span) in abis { args.clobber_abis.push((*abi, *span)); } } } Ok(()) } fn parse_reg<'a>( p: &mut Parser<'a>, explicit_reg: &mut bool, ) -> PResult<'a, ast::InlineAsmRegOrRegClass> { p.expect(&token::OpenDelim(Delimiter::Parenthesis))?; let result = match p.token.uninterpolate().kind { token::Ident(name, false) => ast::InlineAsmRegOrRegClass::RegClass(name), token::Literal(token::Lit { kind: token::LitKind::Str, symbol, suffix: _ }) => { *explicit_reg = true; ast::InlineAsmRegOrRegClass::Reg(symbol) } _ => { return Err(p.sess.create_err(errors::ExpectedRegisterClassOrExplicitRegister { span: p.token.span, })); } }; p.bump(); p.expect(&token::CloseDelim(Delimiter::Parenthesis))?; Ok(result) } fn expand_preparsed_asm(ecx: &mut ExtCtxt<'_>, args: AsmArgs) -> Option { let mut template = vec![]; // Register operands are implicitly used since they are not allowed to be // referenced in the template string. let mut used = vec![false; args.operands.len()]; for pos in args.reg_args.iter() { used[pos] = true; } let named_pos: FxHashMap = args.named_args.iter().map(|(&sym, &idx)| (idx, sym)).collect(); let mut line_spans = Vec::with_capacity(args.templates.len()); let mut curarg = 0; let mut template_strs = Vec::with_capacity(args.templates.len()); for (i, template_expr) in args.templates.into_iter().enumerate() { if i != 0 { template.push(ast::InlineAsmTemplatePiece::String("\n".to_string())); } let msg = "asm template must be a string literal"; let template_sp = template_expr.span; let (template_str, template_style, template_span) = match expr_to_spanned_string(ecx, template_expr, msg) { Ok(template_part) => template_part, Err(err) => { if let Some((mut err, _)) = err { err.emit(); } return None; } }; let str_style = match template_style { ast::StrStyle::Cooked => None, ast::StrStyle::Raw(raw) => Some(raw as usize), }; let template_snippet = ecx.source_map().span_to_snippet(template_sp).ok(); template_strs.push(( template_str, template_snippet.as_deref().map(Symbol::intern), template_sp, )); let template_str = template_str.as_str(); if let Some(InlineAsmArch::X86 | InlineAsmArch::X86_64) = ecx.sess.asm_arch { let find_span = |needle: &str| -> Span { if let Some(snippet) = &template_snippet { if let Some(pos) = snippet.find(needle) { let end = pos + snippet[pos..] .find(|c| matches!(c, '\n' | ';' | '\\' | '"')) .unwrap_or(snippet[pos..].len() - 1); let inner = InnerSpan::new(pos, end); return template_sp.from_inner(inner); } } template_sp }; if template_str.contains(".intel_syntax") { ecx.parse_sess().buffer_lint( lint::builtin::BAD_ASM_STYLE, find_span(".intel_syntax"), ecx.current_expansion.lint_node_id, "avoid using `.intel_syntax`, Intel syntax is the default", ); } if template_str.contains(".att_syntax") { ecx.parse_sess().buffer_lint( lint::builtin::BAD_ASM_STYLE, find_span(".att_syntax"), ecx.current_expansion.lint_node_id, "avoid using `.att_syntax`, prefer using `options(att_syntax)` instead", ); } } // Don't treat raw asm as a format string. if args.options.contains(ast::InlineAsmOptions::RAW) { template.push(ast::InlineAsmTemplatePiece::String(template_str.to_string())); let template_num_lines = 1 + template_str.matches('\n').count(); line_spans.extend(std::iter::repeat(template_sp).take(template_num_lines)); continue; } let mut parser = parse::Parser::new( template_str, str_style, template_snippet, false, parse::ParseMode::InlineAsm, ); parser.curarg = curarg; let mut unverified_pieces = Vec::new(); while let Some(piece) = parser.next() { if !parser.errors.is_empty() { break; } else { unverified_pieces.push(piece); } } if !parser.errors.is_empty() { let err = parser.errors.remove(0); let err_sp = template_span.from_inner(InnerSpan::new(err.span.start, err.span.end)); let msg = format!("invalid asm template string: {}", err.description); let mut e = ecx.struct_span_err(err_sp, msg); e.span_label(err_sp, err.label + " in asm template string"); if let Some(note) = err.note { e.note(note); } if let Some((label, span)) = err.secondary_label { let err_sp = template_span.from_inner(InnerSpan::new(span.start, span.end)); e.span_label(err_sp, label); } e.emit(); return None; } curarg = parser.curarg; let mut arg_spans = parser .arg_places .iter() .map(|span| template_span.from_inner(InnerSpan::new(span.start, span.end))); for piece in unverified_pieces { match piece { parse::Piece::String(s) => { template.push(ast::InlineAsmTemplatePiece::String(s.to_string())) } parse::Piece::NextArgument(arg) => { let span = arg_spans.next().unwrap_or(template_sp); let operand_idx = match arg.position { parse::ArgumentIs(idx) | parse::ArgumentImplicitlyIs(idx) => { if idx >= args.operands.len() || named_pos.contains_key(&idx) || args.reg_args.contains(idx) { let msg = format!("invalid reference to argument at index {}", idx); let mut err = ecx.struct_span_err(span, msg); err.span_label(span, "from here"); let positional_args = args.operands.len() - args.named_args.len() - args.reg_args.len(); let positional = if positional_args != args.operands.len() { "positional " } else { "" }; let msg = match positional_args { 0 => format!("no {}arguments were given", positional), 1 => format!("there is 1 {}argument", positional), x => format!("there are {} {}arguments", x, positional), }; err.note(msg); if named_pos.contains_key(&idx) { err.span_label(args.operands[idx].1, "named argument"); err.span_note( args.operands[idx].1, "named arguments cannot be referenced by position", ); } else if args.reg_args.contains(idx) { err.span_label( args.operands[idx].1, "explicit register argument", ); err.span_note( args.operands[idx].1, "explicit register arguments cannot be used in the asm template", ); err.span_help( args.operands[idx].1, "use the register name directly in the assembly code", ); } err.emit(); None } else { Some(idx) } } parse::ArgumentNamed(name) => { match args.named_args.get(&Symbol::intern(name)) { Some(&idx) => Some(idx), None => { let msg = format!("there is no argument named `{}`", name); let span = arg.position_span; ecx.struct_span_err( template_span .from_inner(InnerSpan::new(span.start, span.end)), msg, ) .emit(); None } } } }; let mut chars = arg.format.ty.chars(); let mut modifier = chars.next(); if chars.next().is_some() { let span = arg .format .ty_span .map(|sp| template_sp.from_inner(InnerSpan::new(sp.start, sp.end))) .unwrap_or(template_sp); ecx.emit_err(errors::AsmModifierInvalid { span }); modifier = None; } if let Some(operand_idx) = operand_idx { used[operand_idx] = true; template.push(ast::InlineAsmTemplatePiece::Placeholder { operand_idx, modifier, span, }); } } } } if parser.line_spans.is_empty() { let template_num_lines = 1 + template_str.matches('\n').count(); line_spans.extend(std::iter::repeat(template_sp).take(template_num_lines)); } else { line_spans.extend( parser .line_spans .iter() .map(|span| template_span.from_inner(InnerSpan::new(span.start, span.end))), ); }; } let mut unused_operands = vec![]; let mut help_str = String::new(); for (idx, used) in used.into_iter().enumerate() { if !used { let msg = if let Some(sym) = named_pos.get(&idx) { help_str.push_str(&format!(" {{{}}}", sym)); "named argument never used" } else { help_str.push_str(&format!(" {{{}}}", idx)); "argument never used" }; unused_operands.push((args.operands[idx].1, msg)); } } match unused_operands.len() { 0 => {} 1 => { let (sp, msg) = unused_operands.into_iter().next().unwrap(); let mut err = ecx.struct_span_err(sp, msg); err.span_label(sp, msg); err.help(format!( "if this argument is intentionally unused, \ consider using it in an asm comment: `\"/*{} */\"`", help_str )); err.emit(); } _ => { let mut err = ecx.struct_span_err( unused_operands.iter().map(|&(sp, _)| sp).collect::>(), "multiple unused asm arguments", ); for (sp, msg) in unused_operands { err.span_label(sp, msg); } err.help(format!( "if these arguments are intentionally unused, \ consider using them in an asm comment: `\"/*{} */\"`", help_str )); err.emit(); } } Some(ast::InlineAsm { template, template_strs: template_strs.into_boxed_slice(), operands: args.operands, clobber_abis: args.clobber_abis, options: args.options, line_spans, }) } pub(super) fn expand_asm<'cx>( ecx: &'cx mut ExtCtxt<'_>, sp: Span, tts: TokenStream, ) -> Box { match parse_args(ecx, sp, tts, false) { Ok(args) => { let expr = if let Some(inline_asm) = expand_preparsed_asm(ecx, args) { P(ast::Expr { id: ast::DUMMY_NODE_ID, kind: ast::ExprKind::InlineAsm(P(inline_asm)), span: sp, attrs: ast::AttrVec::new(), tokens: None, }) } else { DummyResult::raw_expr(sp, true) }; MacEager::expr(expr) } Err(mut err) => { err.emit(); DummyResult::any(sp) } } } pub(super) fn expand_global_asm<'cx>( ecx: &'cx mut ExtCtxt<'_>, sp: Span, tts: TokenStream, ) -> Box { match parse_args(ecx, sp, tts, true) { Ok(args) => { if let Some(inline_asm) = expand_preparsed_asm(ecx, args) { MacEager::items(smallvec![P(ast::Item { ident: Ident::empty(), attrs: ast::AttrVec::new(), id: ast::DUMMY_NODE_ID, kind: ast::ItemKind::GlobalAsm(Box::new(inline_asm)), vis: ast::Visibility { span: sp.shrink_to_lo(), kind: ast::VisibilityKind::Inherited, tokens: None, }, span: ecx.with_def_site_ctxt(sp), tokens: None, })]) } else { DummyResult::any(sp) } } Err(mut err) => { err.emit(); DummyResult::any(sp) } } }