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add riscv32

master
occheung 2021-08-20 17:42:16 +08:00
parent 099bc28867
commit 9748bb8af8
3 changed files with 221 additions and 1 deletions
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1
src/arch/mod.rs
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@ -13,6 +13,7 @@ pub use self::imp::*;
#[cfg_attr(target_arch = "x86_64", path = "x86_64.rs")]
#[cfg_attr(target_arch = "aarch64", path = "aarch64.rs")]
#[cfg_attr(target_arch = "or1k", path = "or1k.rs")]
#[cfg_attr(target_arch = "riscv32", path = "riscv32.rs")]
mod imp;
#[cfg(test)]

219
src/arch/riscv32.rs Normal file
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@ -0,0 +1,219 @@
// This file is part of libfringe, a low-level green threading library.
// Copyright (c) edef <edef@edef.eu>,
// whitequark <whitequark@whitequark.org>
// Amanieu d'Antras <amanieu@gmail.com>
// Licensed under the Apache License, Version 2.0, <LICENSE-APACHE or
// http://apache.org/licenses/LICENSE-2.0> or the MIT license <LICENSE-MIT or
// http://opensource.org/licenses/MIT>, at your option. This file may not be
// copied, modified, or distributed except according to those terms.
// To understand the machine code in this file, keep in mind these facts:
// * RISCV does not have a red zone.
// * RISCV requires (loosely) that the stack pointer (sp) should be 16 bytes
// aligned.
// * RISCV passes the first argument in a0. We also use a0 to pass a value
// while swapping context; this is an arbitrary choice
// (we clobber all registers and could use any of them) but this allows us
// to reuse the swap function to perform the initial call. We do the same
// thing with a1 to pass the stack pointer to the new context.
//
// To understand the DWARF CFI code in this file, keep in mind these facts:
// * CFI is "call frame information"; a set of instructions to a debugger or
// an unwinder that allow it to simulate returning from functions. This implies
// restoring every register to its pre-call state, as well as the stack pointer.
// * CFA is "call frame address"; the value of stack pointer right before the call
// instruction in the caller. Everything strictly below CFA (and inclusive until
// the next CFA) is the call frame of the callee. This implies that the return
// address is the part of callee's call frame.
// * Logically, DWARF CFI is a table where rows are instruction pointer values and
// columns describe where registers are spilled (mostly using expressions that
// compute a memory location as CFA+n). A .cfi_offset pseudoinstruction changes
// the state of a column for all IP numerically larger than the one it's placed
// after. A .cfi_def_* pseudoinstruction changes the CFA value similarly.
// * Simulating return is as easy as restoring register values from the CFI table
// and then setting stack pointer to CFA.
//
// A high-level overview of the function of the trampolines when unwinding is:
// * The 2nd init trampoline puts a controlled value (written in swap to `new_cfa`)
// into fp. This is then used as the CFA for the 1st trampoline.
// * This controlled value points to the bottom of the stack of the parent context,
// which holds the saved fp and ra from the call to swap().
// * The 1st init trampoline tells the unwinder to restore fp and ra
// from the stack frame at fp (in the parent stack), thus continuing
// unwinding at the swap call site instead of falling off the end of context stack.
use core::mem;
use stack::Stack;
pub const STACK_ALIGNMENT: usize = 16;
#[derive(Debug, Clone, Copy)]
#[repr(transparent)]
pub struct StackPointer(*mut usize);
pub unsafe fn init(stack: &Stack, f: unsafe extern "C" fn(usize, StackPointer) -> !) -> StackPointer {
#[naked]
unsafe extern "C" fn trampoline_1() {
llvm_asm!(
r#"
# gdb has a hardcoded check that rejects backtraces where frame addresses
# do not monotonically decrease. It is turned off if the function is called
# "__morestack" and that is hardcoded. So, to make gdb backtraces match
# the actual unwinder behavior, we call ourselves "__morestack" and mark
# the symbol as local; it shouldn't interfere with anything.
__morestack:
.local __morestack
# Set up the first part of our DWARF CFI linking stacks together. When
# we reach this function from unwinding, fp will be pointing at the bottom
# of the parent linked stack. This link is set each time swap() is called.
# When unwinding the frame corresponding to this function, a DWARF unwinder
# will use fp+8 as the next call frame address, restore fp from CFA-4 and
# restore return address (ra) from CFA-8. This mirrors what the second half
# of `swap_trampoline` does.
.cfi_def_cfa fp, 16
.cfi_offset fp, -12
.cfi_offset ra, -16
# This nop is here so that the initial swap doesn't return to the start
# of the trampoline, which confuses the unwinder since it will look for
# frame information in the previous symbol rather than this one. It is
# never actually executed.
nop
.Lend:
.size __morestack, .Lend-__morestack
"#
: : : : "volatile")
}
#[naked]
unsafe extern "C" fn trampoline_2() {
llvm_asm!(
r#"
# Set up the second part of our DWARF CFI.
# When unwinding the frame corresponding to this function, a DWARF unwinder
# will restore fp (and thus CFA of the first trampoline) from the stack slot.
# This stack slot is updated every time swap() is called to point to the bottom
# of the stack of the context switch just switched from.
.cfi_def_cfa fp, 16
.cfi_offset fp, -12
.cfi_offset ra, -16
# This nop is here so that the return address of the swap trampoline
# doesn't point to the start of the symbol. This confuses gdb's backtraces,
# causing them to think the parent function is trampoline_1 instead of
# trampoline_2.
nop
# Call the provided function.
# The function address is at offset 8 because sp will increment by 16 at the end
# of the swap, before calling trampoline_2.
lw a2, 8(sp)
jalr a2
"#
: : : : "volatile")
}
unsafe fn push(sp: &mut StackPointer, val: usize) {
sp.0 = sp.0.offset(-1);
*sp.0 = val
}
// We set up the stack in a somewhat special way so that to the unwinder it
// looks like trampoline_1 has called trampoline_2, which has in turn called
// swap::trampoline.
//
// There are 2 call frames in this setup, each containing the return address
// followed by the fp value for that frame. This setup supports unwinding
// using DWARF CFI as well as the frame pointer-based unwinding used by tools
// such as perf or dtrace.
let mut sp = StackPointer(stack.base() as *mut usize);
push(&mut sp, 0); // Make sure that the stack pointer is 16 bytes aligned
push(&mut sp, f as usize); // Function that trampoline_2 should call
// Call frame for trampoline_2. The CFA slot is updated by swap::trampoline
// each time a context switch is performed.
push(&mut sp, 0xdead0cfa); // CFA slot
push(&mut sp, trampoline_1 as usize + 4); // Return after the nop
let frame = sp;
push(&mut sp, 0); // Alignment
push(&mut sp, 0); // Alignment
// Call frame for swap::trampoline. We set up the fp value to point to the
// parent call frame.
push(&mut sp, frame.0 as usize); // Pointer to parent call frame
push(&mut sp, trampoline_2 as usize + 4); // Entry point, skip initial nop
sp
}
#[inline(always)]
pub unsafe fn swap(arg: usize, new_sp: StackPointer,
new_stack: Option<&Stack>) -> (usize, StackPointer) {
// Address of the topmost CFA stack slot.
let mut dummy: usize = mem::uninitialized();
let new_cfa = if let Some(new_stack) = new_stack {
(new_stack.base() as *mut usize).offset(-3)
} else {
// Just pass a dummy pointer if we aren't linking the stack
&mut dummy
};
#[naked]
unsafe extern "C" fn trampoline() {
llvm_asm!(
r#"
# Save the frame pointer and link register by allocating 16 bytes
# from the stack; unwinder uses them to find the CFA of the caller,
# and so they have to have the correct value immediately after the
# call instruction that invoked the trampoline.
sw fp, -12(sp)
sw ra, -16(sp)
addi sp, sp, -16
.cfi_offset fp, 4
.cfi_offset ra, 0
# Link the call stacks together by writing the current stack bottom
# address to the CFA slot in the new stack.
sw sp, 0(a3)
# Pass the stack pointer of the old context to the new one.
or a1, zero, sp
# Load stack pointer of the new context.
or sp, zero, a2
# Deallocate the 16 bytes
addi sp, sp, 16
# Restore frame pointer and link register of the new context.
# Load frame and instruction pointers of the new context.
lw fp, -12(sp)
lw ra, -16(sp)
# Return into the new context.
jr ra
"#
: : : : "volatile")
}
let ret: usize;
let ret_sp: *mut usize;
llvm_asm!(
r#"
# Call the trampoline to switch to the new context.
jal ${2}
"#
: "={a0}" (ret)
"={a1}" (ret_sp)
: "s" (trampoline as usize)
"{a0}" (arg)
"{a2}" (new_sp.0)
"{a3}" (new_cfa)
:/*"zero",*/"ra",/*"sp","gp","tp",*/"t0","t1","t2",
/*"fp",*/"s1",/*"a0", "a1"*/"a2", "a3", "a4", "a5",
"a6", "a7", "s2", "s3", "s4", "s5", "s6", "s7",
"s8", "s9", "s10", "s11", "t3", "t4", "t5", "t6",
"memory"
: "volatile");
(ret, StackPointer(ret_sp))
}

2
src/lib.rs
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@ -4,7 +4,7 @@
// http://apache.org/licenses/LICENSE-2.0> or the MIT license <LICENSE-MIT or
// http://opensource.org/licenses/MIT>, at your option. This file may not be
// copied, modified, or distributed except according to those terms.
#![feature(asm, naked_functions, untagged_unions)]
#![feature(llvm_asm, naked_functions, untagged_unions)]
#![cfg_attr(feature = "alloc", feature(alloc, allocator_api))]
#![cfg_attr(test, feature(test))]
#![no_std]