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-rw-r--r--src/display/display_sink.rs1232
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diff --git a/src/display/display_sink.rs b/src/display/display_sink.rs
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@@ -0,0 +1,1232 @@
+use core::fmt;
+
+use crate::display::u8_to_hex;
+
+use crate::safer_unchecked::unreachable_kinda_unchecked;
+
+/// `DisplaySink` allows client code to collect output and minimal markup. this is currently used
+/// in formatting instructions for two reasons:
+/// * `DisplaySink` implementations have the opportunity to collect starts and ends of tokens at
+/// the same time as collecting output itself.
+/// * `DisplaySink` implementations provide specialized functions for writing strings in
+/// circumstances where a simple "use `core::fmt`" might incur unwanted overhead.
+///
+/// ## spans
+///
+/// spans are out-of-band indicators for the meaning of data written to this sink. when a
+/// `span_start_<foo>` function is called, data written until a matching `span_end_<foo>` can be
+/// considered the text corresponding to `<foo>`.
+///
+/// spans are entered and exited in a FILO manner. implementations of `DisplaySink` are explicitly
+/// allowed to depend on this fact. functions writing to a `DisplaySink` must exit spans in reverse
+/// order to when they are entered. a function that has a call sequence like
+/// ```text
+/// sink.span_start_operand();
+/// sink.span_start_immediate();
+/// sink.span_end_operand();
+/// ```
+/// is in error.
+///
+/// spans are reported through the `span_start_*` and `span_end_*` families of functions to avoid
+/// constraining implementations into tracking current output offset (which may not be knowable) or
+/// span size (which may be knowable, but incur additional overhead to compute or track). if the
+/// task for a span is to simply emit VT100 color codes, for example, implementations avoid the
+/// overhead of tracking offsets.
+///
+/// default implementations of the `span_start_*` and `span_end_*` functions are to do nothing. a
+/// no-op `span_start_*` or `span_end_*` allows rustc to elimiate such calls at compile time for
+/// `DisplaySink` that are uninterested in the corresponding span type.
+///
+/// # write helpers (`write_*`)
+///
+/// the `write_*` helpers on `DisplaySink` may be able to take advantage of contraints described in
+/// documentation here to better support writing some kinds of inputs than a fully-general solution
+/// (such as `core::fmt`) might be able to yield.
+///
+/// currently there are two motivating factors for `write_*` helpers:
+///
+/// instruction formatting often involves writing small but variable-size strings, such as register
+/// names, which is something of a pathological case for string appending as Rust currently exists:
+/// this often becomes `memcpy` and specifically a call to the platform's `memcpy` (rather than an
+/// inlined `rep movsb`) just to move 3-5 bytes. one relevant Rust issue for reference:
+/// <https://github.com/rust-lang/rust/issues/92993#issuecomment-2028915232>
+///
+/// there are similar papercuts around formatting integers as base-16 numbers, such as
+/// <https://github.com/rust-lang/rust/pull/122770>. in isolation and in most applications these are
+/// not a significant source of overhead. but for programs bounded on decoding and printing
+/// instructions, these can add up to significant overhead - on the order of 10-20% of total
+/// runtime.
+///
+/// ## example
+///
+/// a simple call sequence to `DisplaySink` might look something like:
+/// ```compile_fail
+/// sink.span_start_operand()
+/// sink.write_char('[')
+/// sink.span_start_register()
+/// sink.write_fixed_size("rbp")
+/// sink.span_end_register()
+/// sink.write_char(']')
+/// sink.span_end_operand()
+/// ```
+/// which writes the text `[rbp]`, telling sinks that the operand begins at `[`, ends after `]`,
+/// and `rbp` is a register in that operand.
+///
+/// ## extensibility
+///
+/// additional `span_{start,end}_*` helpers may be added over time - in the above example, one
+/// future addition might be to add a new `effective_address` span that is started before
+/// `register` and ended after `register. for an operand like `\[rbp\]` the effective address span
+/// would exactly match a corresponding register span, but in more complicated scenarios like
+/// `[rsp + rdi * 4 + 0x50]` the effective address would be all of `rsp + rdi * 4 + 0x50`.
+///
+/// additional spans are expected to be added as needed. it is not immediately clear how to add
+/// support for more architecture-specific concepts (such as itanium predicate registers) would be
+/// supported yet, and so architecture-specific concepts may be expressed on `DisplaySink` if the
+/// need arises.
+///
+/// new `span_{start,end}_*` helpers will be defaulted as no-op. additions to this trait will be
+/// minor version bumps, so users should take care to not add custom functions starting with
+/// `span_start_` or `span_end_` to structs implementing `DisplaySink`.
+pub trait DisplaySink: fmt::Write {
+ #[inline(always)]
+ fn write_fixed_size(&mut self, s: &str) -> Result<(), core::fmt::Error> {
+ self.write_str(s)
+ }
+
+ /// write a string to this sink that is less than 32 bytes. this is provided for optimization
+ /// opportunities when writing a variable-length string with known max size.
+ ///
+ /// SAFETY: the provided `s` must be less than 32 bytes. if the provided string is longer than
+ /// 31 bytes, implementations may only copy part of a multi-byte codepoint while writing to a
+ /// utf-8 string. this may corrupt Rust strings.
+ unsafe fn write_lt_32(&mut self, s: &str) -> Result<(), core::fmt::Error> {
+ self.write_str(s)
+ }
+ /// write a string to this sink that is less than 16 bytes. this is provided for optimization
+ /// opportunities when writing a variable-length string with known max size.
+ ///
+ /// SAFETY: the provided `s` must be less than 16 bytes. if the provided string is longer than
+ /// 15 bytes, implementations may only copy part of a multi-byte codepoint while writing to a
+ /// utf-8 string. this may corrupt Rust strings.
+ unsafe fn write_lt_16(&mut self, s: &str) -> Result<(), core::fmt::Error> {
+ self.write_str(s)
+ }
+ /// write a string to this sink that is less than 8 bytes. this is provided for optimization
+ /// opportunities when writing a variable-length string with known max size.
+ ///
+ /// SAFETY: the provided `s` must be less than 8 bytes. if the provided string is longer than
+ /// 7 bytes, implementations may only copy part of a multi-byte codepoint while writing to a
+ /// utf-8 string. this may corrupt Rust strings.
+ unsafe fn write_lt_8(&mut self, s: &str) -> Result<(), core::fmt::Error> {
+ self.write_str(s)
+ }
+
+ /// write a u8 to the output as a base-16 integer.
+ ///
+ /// this corresponds to the Rust format specifier `{:x}` - see [`std::fmt::LowerHex`] for more.
+ ///
+ /// this is provided for optimization opportunities when the formatted integer can be written
+ /// directly to the sink (rather than formatted to an intermediate buffer and output as a
+ /// followup step)
+ fn write_u8(&mut self, v: u8) -> Result<(), core::fmt::Error> {
+ write!(self, "{:x}", v)
+ }
+ /// write a u8 to the output as a base-16 integer with leading `0x`.
+ ///
+ /// this corresponds to the Rust format specifier `{#:x}` - see [`std::fmt::LowerHex`] for more.
+ ///
+ /// this is provided for optimization opportunities when the formatted integer can be written
+ /// directly to the sink (rather than formatted to an intermediate buffer and output as a
+ /// followup step)
+ fn write_prefixed_u8(&mut self, v: u8) -> Result<(), core::fmt::Error> {
+ self.write_fixed_size("0x")?;
+ self.write_u8(v)
+ }
+ /// write an i8 to the output as a base-16 integer with leading `0x`, and leading `-` if the
+ /// value is negative.
+ ///
+ /// there is no matching `std` formatter, so some examples here:
+ /// ```text
+ /// sink.write_prefixed_i8(-0x60); // writes `-0x60` to the sink
+ /// sink.write_prefixed_i8(127); // writes `0x7f` to the sink
+ /// sink.write_prefixed_i8(-128); // writes `-0x80` to the sink
+ /// ```
+ ///
+ /// this is provided for optimization opportunities when the formatted integer can be written
+ /// directly to the sink (rather than formatted to an intermediate buffer and output as a
+ /// followup step)
+ fn write_prefixed_i8(&mut self, v: i8) -> Result<(), core::fmt::Error> {
+ let v = if v < 0 {
+ self.write_char('-')?;
+ v.unsigned_abs()
+ } else {
+ v as u8
+ };
+ self.write_prefixed_u8(v)
+ }
+ /// write a u16 to the output as a base-16 integer.
+ ///
+ /// this is provided for optimization opportunities when the formatted integer can be written
+ /// directly to the sink (rather than formatted to an intermediate buffer and output as a
+ /// followup step)
+ fn write_u16(&mut self, v: u16) -> Result<(), core::fmt::Error> {
+ write!(self, "{:x}", v)
+ }
+ /// write a u16 to the output as a base-16 integer with leading `0x`.
+ ///
+ /// this corresponds to the Rust format specifier `{#:x}` - see [`std::fmt::LowerHex`] for more.
+ ///
+ /// this is provided for optimization opportunities when the formatted integer can be written
+ /// directly to the sink (rather than formatted to an intermediate buffer and output as a
+ /// followup step)
+ fn write_prefixed_u16(&mut self, v: u16) -> Result<(), core::fmt::Error> {
+ self.write_fixed_size("0x")?;
+ self.write_u16(v)
+ }
+ /// write an i16 to the output as a base-16 integer with leading `0x`, and leading `-` if the
+ /// value is negative.
+ ///
+ /// there is no matching `std` formatter, so some examples here:
+ /// ```text
+ /// sink.write_prefixed_i16(-0x60); // writes `-0x60` to the sink
+ /// sink.write_prefixed_i16(127); // writes `0x7f` to the sink
+ /// sink.write_prefixed_i16(-128); // writes `-0x80` to the sink
+ /// ```
+ ///
+ /// this is provided for optimization opportunities when the formatted integer can be written
+ /// directly to the sink (rather than formatted to an intermediate buffer and output as a
+ /// followup step)
+ fn write_prefixed_i16(&mut self, v: i16) -> Result<(), core::fmt::Error> {
+ let v = if v < 0 {
+ self.write_char('-')?;
+ v.unsigned_abs()
+ } else {
+ v as u16
+ };
+ self.write_prefixed_u16(v)
+ }
+ /// write a u32 to the output as a base-16 integer.
+ ///
+ /// this is provided for optimization opportunities when the formatted integer can be written
+ /// directly to the sink (rather than formatted to an intermediate buffer and output as a
+ /// followup step)
+ fn write_u32(&mut self, v: u32) -> Result<(), core::fmt::Error> {
+ write!(self, "{:x}", v)
+ }
+ /// write a u32 to the output as a base-16 integer with leading `0x`.
+ ///
+ /// this corresponds to the Rust format specifier `{#:x}` - see [`std::fmt::LowerHex`] for more.
+ ///
+ /// this is provided for optimization opportunities when the formatted integer can be written
+ /// directly to the sink (rather than formatted to an intermediate buffer and output as a
+ /// followup step)
+ fn write_prefixed_u32(&mut self, v: u32) -> Result<(), core::fmt::Error> {
+ self.write_fixed_size("0x")?;
+ self.write_u32(v)
+ }
+ /// write an i32 to the output as a base-32 integer with leading `0x`, and leading `-` if the
+ /// value is negative.
+ ///
+ /// there is no matching `std` formatter, so some examples here:
+ /// ```text
+ /// sink.write_prefixed_i32(-0x60); // writes `-0x60` to the sink
+ /// sink.write_prefixed_i32(127); // writes `0x7f` to the sink
+ /// sink.write_prefixed_i32(-128); // writes `-0x80` to the sink
+ /// ```
+ ///
+ /// this is provided for optimization opportunities when the formatted integer can be written
+ /// directly to the sink (rather than formatted to an intermediate buffer and output as a
+ /// followup step)
+ fn write_prefixed_i32(&mut self, v: i32) -> Result<(), core::fmt::Error> {
+ let v = if v < 0 {
+ self.write_char('-')?;
+ v.unsigned_abs()
+ } else {
+ v as u32
+ };
+ self.write_prefixed_u32(v)
+ }
+ /// write a u64 to the output as a base-16 integer.
+ ///
+ /// this is provided for optimization opportunities when the formatted integer can be written
+ /// directly to the sink (rather than formatted to an intermediate buffer and output as a
+ /// followup step)
+ fn write_u64(&mut self, v: u64) -> Result<(), core::fmt::Error> {
+ write!(self, "{:x}", v)
+ }
+ /// write a u64 to the output as a base-16 integer with leading `0x`.
+ ///
+ /// this corresponds to the Rust format specifier `{#:x}` - see [`std::fmt::LowerHex`] for more.
+ ///
+ /// this is provided for optimization opportunities when the formatted integer can be written
+ /// directly to the sink (rather than formatted to an intermediate buffer and output as a
+ /// followup step)
+ fn write_prefixed_u64(&mut self, v: u64) -> Result<(), core::fmt::Error> {
+ self.write_fixed_size("0x")?;
+ self.write_u64(v)
+ }
+ /// write an i64 to the output as a base-64 integer with leading `0x`, and leading `-` if the
+ /// value is negative.
+ ///
+ /// there is no matching `std` formatter, so some examples here:
+ /// ```text
+ /// sink.write_prefixed_i64(-0x60); // writes `-0x60` to the sink
+ /// sink.write_prefixed_i64(127); // writes `0x7f` to the sink
+ /// sink.write_prefixed_i64(-128); // writes `-0x80` to the sink
+ /// ```
+ ///
+ /// this is provided for optimization opportunities when the formatted integer can be written
+ /// directly to the sink (rather than formatted to an intermediate buffer and output as a
+ /// followup step)
+ fn write_prefixed_i64(&mut self, v: i64) -> Result<(), core::fmt::Error> {
+ let v = if v < 0 {
+ self.write_char('-')?;
+ v.unsigned_abs()
+ } else {
+ v as u64
+ };
+ self.write_prefixed_u64(v)
+ }
+
+ /// enter a region inside which output corresponds to an immediate.
+ fn span_start_immediate(&mut self) { }
+ /// end a region where an immediate was written. see docs on [`DisplaySink`] for more.
+ fn span_end_immediate(&mut self) { }
+
+ /// enter a region inside which output corresponds to a register.
+ fn span_start_register(&mut self) { }
+ /// end a region where a register was written. see docs on [`DisplaySink`] for more.
+ fn span_end_register(&mut self) { }
+
+ /// enter a region inside which output corresponds to an opcode.
+ fn span_start_opcode(&mut self) { }
+ /// end a region where an opcode was written. see docs on [`DisplaySink`] for more.
+ fn span_end_opcode(&mut self) { }
+
+ /// enter a region inside which output corresponds to the program counter.
+ fn span_start_program_counter(&mut self) { }
+ /// end a region where the program counter was written. see docs on [`DisplaySink`] for more.
+ fn span_end_program_counter(&mut self) { }
+
+ /// enter a region inside which output corresponds to a number, such as a memory offset or
+ /// immediate.
+ fn span_start_number(&mut self) { }
+ /// end a region where a number was written. see docs on [`DisplaySink`] for more.
+ fn span_end_number(&mut self) { }
+
+ /// enter a region inside which output corresponds to an address. this is a best guess;
+ /// instructions like x86's `lea` may involve an "address" that is not, and arithmetic
+ /// instructions may operate on addresses held in registers.
+ ///
+ /// where possible, the presence of this span will be informed by ISA semantics - if an
+ /// instruction has a memory operand, the effective address calculation of that operand should
+ /// be in an address span.
+ fn span_start_address(&mut self) { }
+ /// end a region where an address was written. the specifics of an "address" are ambiguous and
+ /// best-effort; see [`DisplaySink::span_start_address`] for more about this. otherwise, see
+ /// docs on [`DisplaySink`] for more about spans.
+ fn span_end_address(&mut self) { }
+
+ /// enter a region inside which output corresponds to a function address, or expression
+ /// evaluating to a function address. this is a best guess; instructions like `call` may call
+ /// to a non-function address, `jmp` may jump to a function (as with tail calls), function
+ /// addresses may be computed via table lookup without semantic hints.
+ ///
+ /// where possible, the presence of this span will be informed by ISA semantics - if an
+ /// instruction is like a "call", an address operand should be a `function` span. if other
+ /// instructions can be expected to handle subroutine starting addresses purely from ISA
+ /// semantics, address operand(s) should be in a `function` span.
+ fn span_start_function_expr(&mut self) { }
+ /// end a region where function address expression was written. the specifics of a "function
+ /// address" are ambiguous and best-effort; see [`DisplaySink::span_start_function_expr`] for more
+ /// about this. otherwise, see docs on [`DisplaySink`] for more about spans.
+ fn span_end_function_expr(&mut self) { }
+}
+
+/// `FmtSink` can be used to adapt any `fmt::Write`-implementing type into a `DisplaySink` to
+/// format an instruction while discarding all span information at zero cost.
+pub struct FmtSink<'a, T: fmt::Write> {
+ out: &'a mut T,
+}
+
+impl<'a, T: fmt::Write> FmtSink<'a, T> {
+ pub fn new(f: &'a mut T) -> Self {
+ Self { out: f }
+ }
+}
+
+/// blanket impl that discards all span information, forwards writes to the underlying `fmt::Write`
+/// type.
+impl<'a, T: fmt::Write> DisplaySink for FmtSink<'a, T> { }
+
+impl<'a, T: fmt::Write> fmt::Write for FmtSink<'a, T> {
+ fn write_str(&mut self, s: &str) -> Result<(), core::fmt::Error> {
+ self.out.write_str(s)
+ }
+ fn write_char(&mut self, c: char) -> Result<(), core::fmt::Error> {
+ self.out.write_char(c)
+ }
+ fn write_fmt(&mut self, f: fmt::Arguments) -> Result<(), core::fmt::Error> {
+ self.out.write_fmt(f)
+ }
+}
+
+/// this is an implementation detail of yaxpeax-arch and related crates. if you are a user of the
+/// disassemblers, do not use this struct. do not depend on this struct existing. this struct is
+/// not stable. this struct is not safe for general use. if you use this struct you and your
+/// program will be eaten by gremlins.
+///
+/// if you are implementing an instruction formatter for the yaxpeax family of crates: this struct
+/// is guaranteed to contain a string that is long enough to hold a fully-formatted instruction.
+/// because the buffer is guaranteed to be long enough, writes through `InstructionTextSink` are
+/// not bounds-checked, and the buffer is never grown.
+///
+/// this is wildly dangerous in general use. the public constructor of `InstructionTextSink` is
+/// unsafe as a result. as used in `InstructionFormatter`, the buffer is guaranteed to be
+/// `clear()`ed before use, `InstructionFormatter` ensures the buffer is large enough, *and*
+/// `InstructionFormatter` never allows `InstructionTextSink` to exist in a context where it would
+/// be written to without being rewound first.
+///
+/// because this opens a very large hole through which `fmt::Write` can become unsafe, incorrect
+/// uses of this struct will be hard to debug in general. `InstructionFormatter` is probably at the
+/// limit of easily-reasoned-about lifecycle of the buffer, which "only" leaves the problem of
+/// ensuring that instruction formatting impls this buffer is passed to are appropriately sized.
+///
+/// this is intended to be hidden in docs. if you see this in docs, it's a bug.
+#[doc(hidden)]
+pub struct InstructionTextSink<'buf> {
+ buf: &'buf mut alloc::string::String
+}
+
+impl<'buf> InstructionTextSink<'buf> {
+ // TODO: safety
+ pub unsafe fn new(buf: &'buf mut alloc::string::String) -> Self {
+ Self { buf }
+ }
+}
+
+impl<'buf> fmt::Write for InstructionTextSink<'buf> {
+ fn write_str(&mut self, s: &str) -> Result<(), core::fmt::Error> {
+ self.buf.write_str(s)
+ }
+ fn write_char(&mut self, c: char) -> Result<(), core::fmt::Error> {
+ if cfg!(debug_assertions) {
+ if self.buf.capacity() < self.buf.len() + 1 {
+ panic!("InstructionTextSink::write_char would overflow output");
+ }
+ }
+ // SAFETY: `buf` is assumed to be long enough to hold all input, `buf` at `underlying.len()`
+ // is valid for writing, but may be uninitialized.
+ //
+ // this function is essentially equivalent to `Vec::push` specialized for the case that
+ // `len < buf.capacity()`:
+ // https://github.com/rust-lang/rust/blob/be9e27e/library/alloc/src/vec/mod.rs#L1993-L2006
+ unsafe {
+ let underlying = self.buf.as_mut_vec();
+ // `InstructionTextSink::write_char` is only used by yaxpeax-x86, and is only used to
+ // write single ASCII characters. this is wrong in the general case, but `write_char`
+ // here is not going to be used in the general case.
+ if cfg!(debug_asertions) {
+ panic!("InstructionTextSink::write_char would truncate output");
+ }
+ let to_push = c as u8;
+ // `ptr::write` here because `underlying.add(underlying.len())` may not point to an
+ // initialized value, which would mean that turning that pointer into a `&mut u8` to
+ // store through would be UB. `ptr::write` avoids taking the mut ref.
+ underlying.as_mut_ptr().offset(underlying.len() as isize).write(to_push);
+ // we have initialized all (one) bytes that `set_len` is increasing the length to
+ // include.
+ underlying.set_len(underlying.len() + 1);
+ }
+ Ok(())
+ }
+}
+
+/// this [`DisplaySink`] impl exists to support somewhat more performant buffering of the kinds of
+/// strings `yaxpeax-x86` uses in formatting instructions.
+///
+/// span information is discarded at zero cost.
+impl DisplaySink for alloc::string::String {
+ #[inline(always)]
+ fn write_fixed_size(&mut self, s: &str) -> Result<(), core::fmt::Error> {
+ self.reserve(s.len());
+ let buf = unsafe { self.as_mut_vec() };
+ let new_bytes = s.as_bytes();
+
+ if new_bytes.len() == 0 {
+ unsafe { unreachable_kinda_unchecked() }
+ }
+
+ if new_bytes.len() >= 16 {
+ unsafe { unreachable_kinda_unchecked() }
+ }
+
+ unsafe {
+ let dest = buf.as_mut_ptr().offset(buf.len() as isize);
+
+ // this used to be enough to bamboozle llvm away from
+ // https://github.com/rust-lang/rust/issues/92993#issuecomment-2028915232
+ // if `s` is not fixed size. somewhere between Rust 1.68 and Rust 1.74 this stopped
+ // being sufficient, so `write_fixed_size` truly should only be used for fixed size `s`
+ // (otherwise this is a libc memcpy call in disguise). for fixed-size strings this
+ // unrolls into some kind of appropriate series of `mov`.
+ dest.offset(0 as isize).write(new_bytes[0]);
+ for i in 1..new_bytes.len() {
+ dest.offset(i as isize).write(new_bytes[i]);
+ }
+
+ buf.set_len(buf.len() + new_bytes.len());
+ }
+
+ Ok(())
+ }
+ unsafe fn write_lt_32(&mut self, s: &str) -> Result<(), fmt::Error> {
+ self.reserve(s.len());
+
+ // SAFETY: todo
+ let buf = unsafe { self.as_mut_vec() };
+ let new_bytes = s.as_bytes();
+
+ // should get DCE
+ if new_bytes.len() >= 32 {
+ unsafe { core::hint::unreachable_unchecked() }
+ }
+
+ unsafe {
+ let dest = buf.as_mut_ptr().offset(buf.len() as isize);
+ let src = new_bytes.as_ptr();
+
+ let rem = new_bytes.len() as isize;
+
+ // set_len early because there is no way to avoid the following asm!() writing that
+ // same number of bytes into buf
+ buf.set_len(buf.len() + new_bytes.len());
+
+ core::arch::asm!(
+ "6:",
+ "cmp {rem:e}, 16",
+ "jb 7f",
+ "mov {buf:r}, qword ptr [{src} + {rem} - 16]",
+ "mov qword ptr [{dest} + {rem} - 16], {buf:r}",
+ "mov {buf:r}, qword ptr [{src} + {rem} - 8]",
+ "mov qword ptr [{dest} + {rem} - 8], {buf:r}",
+ "sub {rem:e}, 16",
+ "jz 11f",
+ "7:",
+ "cmp {rem:e}, 8",
+ "jb 8f",
+ "mov {buf:r}, qword ptr [{src} + {rem} - 8]",
+ "mov qword ptr [{dest} + {rem} - 8], {buf:r}",
+ "sub {rem:e}, 8",
+ "jz 11f",
+ "8:",
+ "cmp {rem:e}, 4",
+ "jb 9f",
+ "mov {buf:e}, dword ptr [{src} + {rem} - 4]",
+ "mov dword ptr [{dest} + {rem} - 4], {buf:e}",
+ "sub {rem:e}, 4",
+ "jz 11f",
+ "9:",
+ "cmp {rem:e}, 2",
+ "jb 10f",
+ "mov {buf:x}, word ptr [{src} + {rem} - 2]",
+ "mov word ptr [{dest} + {rem} - 2], {buf:x}",
+ "sub {rem:e}, 2",
+ "jz 11f",
+ "10:",
+ "cmp {rem:e}, 1",
+ "jb 11f",
+ "mov {buf:l}, byte ptr [{src} + {rem} - 1]",
+ "mov byte ptr [{dest} + {rem} - 1], {buf:l}",
+ "11:",
+ src = in(reg) src,
+ dest = in(reg) dest,
+ rem = inout(reg) rem => _,
+ buf = out(reg) _,
+ options(nostack),
+ );
+ }
+
+ Ok(())
+ }
+ unsafe fn write_lt_16(&mut self, s: &str) -> Result<(), fmt::Error> {
+ self.reserve(s.len());
+
+ // SAFETY: todo
+ let buf = unsafe { self.as_mut_vec() };
+ let new_bytes = s.as_bytes();
+
+ // should get DCE
+ if new_bytes.len() >= 16 {
+ unsafe { core::hint::unreachable_unchecked() }
+ }
+
+ unsafe {
+ let dest = buf.as_mut_ptr().offset(buf.len() as isize);
+ let src = new_bytes.as_ptr();
+
+ let rem = new_bytes.len() as isize;
+
+ // set_len early because there is no way to avoid the following asm!() writing that
+ // same number of bytes into buf
+ buf.set_len(buf.len() + new_bytes.len());
+
+ core::arch::asm!(
+ "7:",
+ "cmp {rem:e}, 8",
+ "jb 8f",
+ "mov {buf:r}, qword ptr [{src} + {rem} - 8]",
+ "mov qword ptr [{dest} + {rem} - 8], {buf:r}",
+ "sub {rem:e}, 8",
+ "jz 11f",
+ "8:",
+ "cmp {rem:e}, 4",
+ "jb 9f",
+ "mov {buf:e}, dword ptr [{src} + {rem} - 4]",
+ "mov dword ptr [{dest} + {rem} - 4], {buf:e}",
+ "sub {rem:e}, 4",
+ "jz 11f",
+ "9:",
+ "cmp {rem:e}, 2",
+ "jb 10f",
+ "mov {buf:x}, word ptr [{src} + {rem} - 2]",
+ "mov word ptr [{dest} + {rem} - 2], {buf:x}",
+ "sub {rem:e}, 2",
+ "jz 11f",
+ "10:",
+ "cmp {rem:e}, 1",
+ "jb 11f",
+ "mov {buf:l}, byte ptr [{src} + {rem} - 1]",
+ "mov byte ptr [{dest} + {rem} - 1], {buf:l}",
+ "11:",
+ src = in(reg) src,
+ dest = in(reg) dest,
+ rem = inout(reg) rem => _,
+ buf = out(reg) _,
+ options(nostack),
+ );
+ }
+
+ Ok(())
+ }
+ unsafe fn write_lt_8(&mut self, s: &str) -> Result<(), fmt::Error> {
+ self.reserve(s.len());
+
+ // SAFETY: todo
+ let buf = unsafe { self.as_mut_vec() };
+ let new_bytes = s.as_bytes();
+
+ // should get DCE
+ if new_bytes.len() >= 8 {
+ unsafe { core::hint::unreachable_unchecked() }
+ }
+
+ unsafe {
+ let dest = buf.as_mut_ptr().offset(buf.len() as isize);
+ let src = new_bytes.as_ptr();
+
+ let rem = new_bytes.len() as isize;
+
+ // set_len early because there is no way to avoid the following asm!() writing that
+ // same number of bytes into buf
+ buf.set_len(buf.len() + new_bytes.len());
+
+ core::arch::asm!(
+ "8:",
+ "cmp {rem:e}, 4",
+ "jb 9f",
+ "mov {buf:e}, dword ptr [{src} + {rem} - 4]",
+ "mov dword ptr [{dest} + {rem} - 4], {buf:e}",
+ "sub {rem:e}, 4",
+ "jz 11f",
+ "9:",
+ "cmp {rem:e}, 2",
+ "jb 10f",
+ "mov {buf:x}, word ptr [{src} + {rem} - 2]",
+ "mov word ptr [{dest} + {rem} - 2], {buf:x}",
+ "sub {rem:e}, 2",
+ "jz 11f",
+ "10:",
+ "cmp {rem:e}, 1",
+ "jb 11f",
+ "mov {buf:l}, byte ptr [{src} + {rem} - 1]",
+ "mov byte ptr [{dest} + {rem} - 1], {buf:l}",
+ "11:",
+ src = in(reg) src,
+ dest = in(reg) dest,
+ rem = inout(reg) rem => _,
+ buf = out(reg) _,
+ options(nostack),
+ );
+ }
+
+ Ok(())
+ }
+ /// write a u8 to the output as a base-16 integer.
+ ///
+ /// this is provided for optimization opportunities when the formatted integer can be written
+ /// directly to the sink (rather than formatted to an intermediate buffer and output as a
+ /// followup step)
+ #[inline(always)]
+ fn write_u8(&mut self, mut v: u8) -> Result<(), core::fmt::Error> {
+ if v == 0 {
+ return self.write_fixed_size("0");
+ }
+ // we can fairly easily predict the size of a formatted string here with lzcnt, which also
+ // means we can write directly into the correct offsets of the output string.
+ let printed_size = ((8 - v.leading_zeros() + 3) >> 2) as usize;
+
+ self.reserve(printed_size);
+
+ let buf = unsafe { self.as_mut_vec() };
+ let new_len = buf.len() + printed_size;
+
+ unsafe {
+ buf.set_len(new_len);
+ }
+ let mut p = unsafe { buf.as_mut_ptr().offset(new_len as isize) };
+
+ loop {
+ let digit = v % 16;
+ let c = u8_to_hex(digit as u8);
+ unsafe {
+ p = p.offset(-1);
+ p.write(c);
+ }
+ v = v / 16;
+ if v == 0 {
+ break;
+ }
+ }
+
+ Ok(())
+ }
+ /// write a u16 to the output as a base-16 integer.
+ ///
+ /// this is provided for optimization opportunities when the formatted integer can be written
+ /// directly to the sink (rather than formatted to an intermediate buffer and output as a
+ /// followup step)
+ #[inline(always)]
+ fn write_u16(&mut self, mut v: u16) -> Result<(), core::fmt::Error> {
+ if v == 0 {
+ return self.write_fixed_size("0");
+ }
+ // we can fairly easily predict the size of a formatted string here with lzcnt, which also
+ // means we can write directly into the correct offsets of the output string.
+ let printed_size = ((16 - v.leading_zeros() + 3) >> 2) as usize;
+
+ self.reserve(printed_size);
+
+ let buf = unsafe { self.as_mut_vec() };
+ let new_len = buf.len() + printed_size;
+
+ unsafe {
+ buf.set_len(new_len);
+ }
+ let mut p = unsafe { buf.as_mut_ptr().offset(new_len as isize) };
+
+ loop {
+ let digit = v % 16;
+ let c = u8_to_hex(digit as u8);
+ unsafe {
+ p = p.offset(-1);
+ p.write(c);
+ }
+ v = v / 16;
+ if v == 0 {
+ break;
+ }
+ }
+
+ Ok(())
+ }
+ /// write a u32 to the output as a base-16 integer.
+ ///
+ /// this is provided for optimization opportunities when the formatted integer can be written
+ /// directly to the sink (rather than formatted to an intermediate buffer and output as a
+ /// followup step)
+ #[inline(always)]
+ fn write_u32(&mut self, mut v: u32) -> Result<(), core::fmt::Error> {
+ if v == 0 {
+ return self.write_fixed_size("0");
+ }
+ // we can fairly easily predict the size of a formatted string here with lzcnt, which also
+ // means we can write directly into the correct offsets of the output string.
+ let printed_size = ((32 - v.leading_zeros() + 3) >> 2) as usize;
+
+ self.reserve(printed_size);
+
+ let buf = unsafe { self.as_mut_vec() };
+ let new_len = buf.len() + printed_size;
+
+ unsafe {
+ buf.set_len(new_len);
+ }
+ let mut p = unsafe { buf.as_mut_ptr().offset(new_len as isize) };
+
+ loop {
+ let digit = v % 16;
+ let c = u8_to_hex(digit as u8);
+ unsafe {
+ p = p.offset(-1);
+ p.write(c);
+ }
+ v = v / 16;
+ if v == 0 {
+ break;
+ }
+ }
+
+ Ok(())
+ }
+ /// write a u64 to the output as a base-16 integer.
+ ///
+ /// this is provided for optimization opportunities when the formatted integer can be written
+ /// directly to the sink (rather than formatted to an intermediate buffer and output as a
+ /// followup step)
+ #[inline(always)]
+ fn write_u64(&mut self, mut v: u64) -> Result<(), core::fmt::Error> {
+ if v == 0 {
+ return self.write_fixed_size("0");
+ }
+ // we can fairly easily predict the size of a formatted string here with lzcnt, which also
+ // means we can write directly into the correct offsets of the output string.
+ let printed_size = ((64 - v.leading_zeros() + 3) >> 2) as usize;
+
+ self.reserve(printed_size);
+
+ let buf = unsafe { self.as_mut_vec() };
+ let new_len = buf.len() + printed_size;
+
+ unsafe {
+ buf.set_len(new_len);
+ }
+ let mut p = unsafe { buf.as_mut_ptr().offset(new_len as isize) };
+
+ loop {
+ let digit = v % 16;
+ let c = u8_to_hex(digit as u8);
+ unsafe {
+ p = p.offset(-1);
+ p.write(c);
+ }
+ v = v / 16;
+ if v == 0 {
+ break;
+ }
+ }
+
+ Ok(())
+ }
+}
+
+impl<'buf> DisplaySink for InstructionTextSink<'buf> {
+ #[inline(always)]
+ fn write_fixed_size(&mut self, s: &str) -> Result<(), core::fmt::Error> {
+ if cfg!(debug_assertions) {
+ if self.buf.capacity() < self.buf.len() + s.len() {
+ panic!("InstructionTextSink::write_fixed_size would overflow output");
+ }
+ }
+
+ let buf = unsafe { self.buf.as_mut_vec() };
+ let new_bytes = s.as_bytes();
+
+ if new_bytes.len() == 0 {
+ return Ok(());
+ }
+
+ if new_bytes.len() >= 16 {
+ unsafe { unreachable_kinda_unchecked() }
+ }
+
+ unsafe {
+ let dest = buf.as_mut_ptr().offset(buf.len() as isize);
+
+ // this used to be enough to bamboozle llvm away from
+ // https://github.com/rust-lang/rust/issues/92993#issuecomment-2028915232https://github.com/rust-lang/rust/issues/92993#issuecomment-2028915232
+ // if `s` is not fixed size. somewhere between Rust 1.68 and Rust 1.74 this stopped
+ // being sufficient, so `write_fixed_size` truly should only be used for fixed size `s`
+ // (otherwise this is a libc memcpy call in disguise). for fixed-size strings this
+ // unrolls into some kind of appropriate series of `mov`.
+ dest.offset(0 as isize).write(new_bytes[0]);
+ for i in 1..new_bytes.len() {
+ dest.offset(i as isize).write(new_bytes[i]);
+ }
+
+ buf.set_len(buf.len() + new_bytes.len());
+ }
+
+ Ok(())
+ }
+ unsafe fn write_lt_32(&mut self, s: &str) -> Result<(), fmt::Error> {
+ if cfg!(debug_assertions) {
+ if self.buf.capacity() < self.buf.len() + s.len() {
+ panic!("InstructionTextSink::write_lt_32 would overflow output");
+ }
+ }
+
+ // SAFETY: todo
+ let buf = unsafe { self.buf.as_mut_vec() };
+ let new_bytes = s.as_bytes();
+
+ // should get DCE
+ if new_bytes.len() >= 32 {
+ unsafe { core::hint::unreachable_unchecked() }
+ }
+
+ unsafe {
+ let dest = buf.as_mut_ptr().offset(buf.len() as isize);
+ let src = new_bytes.as_ptr();
+
+ let rem = new_bytes.len() as isize;
+
+ // set_len early because there is no way to avoid the following asm!() writing that
+ // same number of bytes into buf
+ buf.set_len(buf.len() + new_bytes.len());
+
+ core::arch::asm!(
+ "6:",
+ "cmp {rem:e}, 16",
+ "jb 7f",
+ "mov {buf:r}, qword ptr [{src} + {rem} - 16]",
+ "mov qword ptr [{dest} + {rem} - 16], {buf:r}",
+ "mov {buf:r}, qword ptr [{src} + {rem} - 8]",
+ "mov qword ptr [{dest} + {rem} - 8], {buf:r}",
+ "sub {rem:e}, 16",
+ "jz 11f",
+ "7:",
+ "cmp {rem:e}, 8",
+ "jb 8f",
+ "mov {buf:r}, qword ptr [{src} + {rem} - 8]",
+ "mov qword ptr [{dest} + {rem} - 8], {buf:r}",
+ "sub {rem:e}, 8",
+ "jz 11f",
+ "8:",
+ "cmp {rem:e}, 4",
+ "jb 9f",
+ "mov {buf:e}, dword ptr [{src} + {rem} - 4]",
+ "mov dword ptr [{dest} + {rem} - 4], {buf:e}",
+ "sub {rem:e}, 4",
+ "jz 11f",
+ "9:",
+ "cmp {rem:e}, 2",
+ "jb 10f",
+ "mov {buf:x}, word ptr [{src} + {rem} - 2]",
+ "mov word ptr [{dest} + {rem} - 2], {buf:x}",
+ "sub {rem:e}, 2",
+ "jz 11f",
+ "10:",
+ "cmp {rem:e}, 1",
+ "jb 11f",
+ "mov {buf:l}, byte ptr [{src} + {rem} - 1]",
+ "mov byte ptr [{dest} + {rem} - 1], {buf:l}",
+ "11:",
+ src = in(reg) src,
+ dest = in(reg) dest,
+ rem = inout(reg) rem => _,
+ buf = out(reg) _,
+ options(nostack),
+ );
+ }
+
+ Ok(())
+ }
+ unsafe fn write_lt_16(&mut self, s: &str) -> Result<(), fmt::Error> {
+ if cfg!(debug_assertions) {
+ if self.buf.capacity() < self.buf.len() + s.len() {
+ panic!("InstructionTextSink::write_lt_16 would overflow output");
+ }
+ }
+
+ // SAFETY: todo
+ let buf = unsafe { self.buf.as_mut_vec() };
+ let new_bytes = s.as_bytes();
+
+ // should get DCE
+ if new_bytes.len() >= 16 {
+ unsafe { core::hint::unreachable_unchecked() }
+ }
+
+ unsafe {
+ let dest = buf.as_mut_ptr().offset(buf.len() as isize);
+ let src = new_bytes.as_ptr();
+
+ let rem = new_bytes.len() as isize;
+
+ // set_len early because there is no way to avoid the following asm!() writing that
+ // same number of bytes into buf
+ buf.set_len(buf.len() + new_bytes.len());
+
+ core::arch::asm!(
+ "7:",
+ "cmp {rem:e}, 8",
+ "jb 8f",
+ "mov {buf:r}, qword ptr [{src} + {rem} - 8]",
+ "mov qword ptr [{dest} + {rem} - 8], {buf:r}",
+ "sub {rem:e}, 8",
+ "jz 11f",
+ "8:",
+ "cmp {rem:e}, 4",
+ "jb 9f",
+ "mov {buf:e}, dword ptr [{src} + {rem} - 4]",
+ "mov dword ptr [{dest} + {rem} - 4], {buf:e}",
+ "sub {rem:e}, 4",
+ "jz 11f",
+ "9:",
+ "cmp {rem:e}, 2",
+ "jb 10f",
+ "mov {buf:x}, word ptr [{src} + {rem} - 2]",
+ "mov word ptr [{dest} + {rem} - 2], {buf:x}",
+ "sub {rem:e}, 2",
+ "jz 11f",
+ "10:",
+ "cmp {rem:e}, 1",
+ "jb 11f",
+ "mov {buf:l}, byte ptr [{src} + {rem} - 1]",
+ "mov byte ptr [{dest} + {rem} - 1], {buf:l}",
+ "11:",
+ src = in(reg) src,
+ dest = in(reg) dest,
+ rem = inout(reg) rem => _,
+ buf = out(reg) _,
+ options(nostack),
+ );
+ }
+
+ Ok(())
+ }
+ unsafe fn write_lt_8(&mut self, s: &str) -> Result<(), fmt::Error> {
+ if cfg!(debug_assertions) {
+ if self.buf.capacity() < self.buf.len() + s.len() {
+ panic!("InstructionTextSink::write_lt_8 would overflow output");
+ }
+ }
+
+ // SAFETY: todo
+ let buf = unsafe { self.buf.as_mut_vec() };
+ let new_bytes = s.as_bytes();
+
+ // should get DCE
+ if new_bytes.len() >= 8 {
+ unsafe { core::hint::unreachable_unchecked() }
+ }
+
+ unsafe {
+ let dest = buf.as_mut_ptr().offset(buf.len() as isize);
+ let src = new_bytes.as_ptr();
+
+ let rem = new_bytes.len() as isize;
+
+ // set_len early because there is no way to avoid the following asm!() writing that
+ // same number of bytes into buf
+ buf.set_len(buf.len() + new_bytes.len());
+
+ core::arch::asm!(
+ "8:",
+ "cmp {rem:e}, 4",
+ "jb 9f",
+ "mov {buf:e}, dword ptr [{src} + {rem} - 4]",
+ "mov dword ptr [{dest} + {rem} - 4], {buf:e}",
+ "sub {rem:e}, 4",
+ "jz 11f",
+ "9:",
+ "cmp {rem:e}, 2",
+ "jb 10f",
+ "mov {buf:x}, word ptr [{src} + {rem} - 2]",
+ "mov word ptr [{dest} + {rem} - 2], {buf:x}",
+ "sub {rem:e}, 2",
+ "jz 11f",
+ "10:",
+ "cmp {rem:e}, 1",
+ "jb 11f",
+ "mov {buf:l}, byte ptr [{src} + {rem} - 1]",
+ "mov byte ptr [{dest} + {rem} - 1], {buf:l}",
+ "11:",
+ src = in(reg) src,
+ dest = in(reg) dest,
+ rem = inout(reg) rem => _,
+ buf = out(reg) _,
+ options(nostack),
+ );
+ }
+
+ Ok(())
+ }
+ /// write a u8 to the output as a base-16 integer.
+ ///
+ /// this is provided for optimization opportunities when the formatted integer can be written
+ /// directly to the sink (rather than formatted to an intermediate buffer and output as a
+ /// followup step)
+ #[inline(always)]
+ fn write_u8(&mut self, mut v: u8) -> Result<(), core::fmt::Error> {
+ if v == 0 {
+ return self.write_fixed_size("0");
+ }
+ // we can fairly easily predict the size of a formatted string here with lzcnt, which also
+ // means we can write directly into the correct offsets of the output string.
+ let printed_size = ((8 - v.leading_zeros() + 3) >> 2) as usize;
+
+ if cfg!(debug_assertions) {
+ if self.buf.capacity() < self.buf.len() + printed_size {
+ panic!("InstructionTextSink::write_u8 would overflow output");
+ }
+ }
+
+ let buf = unsafe { self.buf.as_mut_vec() };
+ let new_len = buf.len() + printed_size;
+
+ unsafe {
+ buf.set_len(new_len);
+ }
+ let mut p = unsafe { buf.as_mut_ptr().offset(new_len as isize) };
+
+ loop {
+ let digit = v % 16;
+ let c = u8_to_hex(digit as u8);
+ unsafe {
+ p = p.offset(-1);
+ p.write(c);
+ }
+ v = v / 16;
+ if v == 0 {
+ break;
+ }
+ }
+
+ Ok(())
+ }
+ /// write a u16 to the output as a base-16 integer.
+ ///
+ /// this is provided for optimization opportunities when the formatted integer can be written
+ /// directly to the sink (rather than formatted to an intermediate buffer and output as a
+ /// followup step)
+ #[inline(always)]
+ fn write_u16(&mut self, mut v: u16) -> Result<(), core::fmt::Error> {
+ if v == 0 {
+ return self.write_fixed_size("0");
+ }
+
+ // we can fairly easily predict the size of a formatted string here with lzcnt, which also
+ // means we can write directly into the correct offsets of the output string.
+ let printed_size = ((16 - v.leading_zeros() + 3) >> 2) as usize;
+
+ if cfg!(debug_assertions) {
+ if self.buf.capacity() < self.buf.len() + printed_size {
+ panic!("InstructionTextSink::write_u16 would overflow output");
+ }
+ }
+
+ let buf = unsafe { self.buf.as_mut_vec() };
+ let new_len = buf.len() + printed_size;
+
+ unsafe {
+ buf.set_len(new_len);
+ }
+ let mut p = unsafe { buf.as_mut_ptr().offset(new_len as isize) };
+
+ loop {
+ let digit = v % 16;
+ let c = u8_to_hex(digit as u8);
+ unsafe {
+ p = p.offset(-1);
+ p.write(c);
+ }
+ v = v / 16;
+ if v == 0 {
+ break;
+ }
+ }
+
+ Ok(())
+ }
+ /// write a u32 to the output as a base-16 integer.
+ ///
+ /// this is provided for optimization opportunities when the formatted integer can be written
+ /// directly to the sink (rather than formatted to an intermediate buffer and output as a
+ /// followup step)
+ #[inline(always)]
+ fn write_u32(&mut self, mut v: u32) -> Result<(), core::fmt::Error> {
+ if v == 0 {
+ return self.write_fixed_size("0");
+ }
+
+ // we can fairly easily predict the size of a formatted string here with lzcnt, which also
+ // means we can write directly into the correct offsets of the output string.
+ let printed_size = ((32 - v.leading_zeros() + 3) >> 2) as usize;
+
+ if cfg!(debug_assertions) {
+ if self.buf.capacity() < self.buf.len() + printed_size {
+ panic!("InstructionTextSink::write_u32 would overflow output");
+ }
+ }
+
+ let buf = unsafe { self.buf.as_mut_vec() };
+ let new_len = buf.len() + printed_size;
+
+ unsafe {
+ buf.set_len(new_len);
+ }
+ let mut p = unsafe { buf.as_mut_ptr().offset(new_len as isize) };
+
+ loop {
+ let digit = v % 16;
+ let c = u8_to_hex(digit as u8);
+ unsafe {
+ p = p.offset(-1);
+ p.write(c);
+ }
+ v = v / 16;
+ if v == 0 {
+ break;
+ }
+ }
+
+ Ok(())
+ }
+ /// write a u64 to the output as a base-16 integer.
+ ///
+ /// this is provided for optimization opportunities when the formatted integer can be written
+ /// directly to the sink (rather than formatted to an intermediate buffer and output as a
+ /// followup step)
+ #[inline(always)]
+ fn write_u64(&mut self, mut v: u64) -> Result<(), core::fmt::Error> {
+ if v == 0 {
+ return self.write_fixed_size("0");
+ }
+
+ // we can fairly easily predict the size of a formatted string here with lzcnt, which also
+ // means we can write directly into the correct offsets of the output string.
+ let printed_size = ((64 - v.leading_zeros() + 3) >> 2) as usize;
+
+ if cfg!(debug_assertions) {
+ if self.buf.capacity() < self.buf.len() + printed_size {
+ panic!("InstructionTextSink::write_u64 would overflow output");
+ }
+ }
+
+ let buf = unsafe { self.buf.as_mut_vec() };
+ let new_len = buf.len() + printed_size;
+
+ unsafe {
+ buf.set_len(new_len);
+ }
+ let mut p = unsafe { buf.as_mut_ptr().offset(new_len as isize) };
+
+ loop {
+ let digit = v % 16;
+ let c = u8_to_hex(digit as u8);
+ unsafe {
+ p = p.offset(-1);
+ p.write(c);
+ }
+ v = v / 16;
+ if v == 0 {
+ break;
+ }
+ }
+
+ Ok(())
+ }
+}