kc3-lang/libffi/src/loongarch64/sysv.S

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  Commit

• Author : Xi Ruoyao
  Date : 2022-07-22 05:56:30
  Hash : 5a4774cd
  Message : static trampoline for LoongArch (#723) For the benefit and technical details of static trampoline, see https://github.com/libffi/libffi/pull/624. As a new architecture, let's be "safer" from the start. The change survived libffi testsuite on loongarch64-linux-gnu.

• src/loongarch64/sysv.S

• /* -----------------------------------------------------------------------
    sysv.S  - Copyright (c) 2022 Xu Chenghua <xuchenghua@loongson.cn>
                            2022 Cheng Lulu <chenglulu@loongson.cn>
  
     LoongArch Foreign Function Interface
  
     Permission is hereby granted, free of charge, to any person obtaining
     a copy of this software and associated documentation files (the
     ``Software''), to deal in the Software without restriction, including
     without limitation the rights to use, copy, modify, merge, publish,
     distribute, sublicense, and/or sell copies of the Software, and to
     permit persons to whom the Software is furnished to do so, subject to
     the following conditions:
  
     The above copyright notice and this permission notice shall be included
     in all copies or substantial portions of the Software.
  
     THE SOFTWARE IS PROVIDED ``AS IS'', WITHOUT WARRANTY OF ANY KIND,
     EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
     MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
     NONINFRINGEMENT.  IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT
     HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY,
     WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
     OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER
     DEALINGS IN THE SOFTWARE.
     ----------------------------------------------------------------------- */
  
  #define LIBFFI_ASM
  #include <fficonfig.h>
  #include <ffi.h>
  
  /* Define aliases so that we can handle all ABIs uniformly.  */
  
  #if __SIZEOF_POINTER__ == 8
  # define PTRS 8
  # define LARG ld.d
  # define SARG st.d
  #else
  # define PTRS 4
  # define LARG ld.w
  # define SARG st.w
  #endif
  
  #if defined(__loongarch_single_float)
  # define FLTS 4
  # define FLD fld.w
  # define FST fst.w
  #elif defined(__loongarch_double_float)
  # define FLTS 8
  # define FLARG fld.d
  # define FSARG fst.d
  #elif defined(__loongarch_soft_float)
  # define FLTS 0
  #else
  #error unsupported LoongArch floating-point ABI
  #endif
  
      .text
      .globl  ffi_call_asm
      .type   ffi_call_asm, @function
      .hidden ffi_call_asm
  /* struct call_context
     {
       ABI_FLOAT fa[8];
       size_t a[10];
     }
  
     - 8 floating point parameter/result registers (fa[0] - fa[7])
     - 8 integer parameter/result registers (a[0] - a[7])
     - 2 registers used by the assembly code to in-place construct its own stack
       frame.
      - frame pointer (a[8])
      - return address (a[9])
  
     void ffi_call_asm (size_t *stackargs, struct call_context *regargs,
  		      void (*fn)(void), void *closure); */
  
  #define FRAME_LEN (8 * FLTS + 10 * PTRS)
  
  ffi_call_asm:
  	.cfi_startproc
  
  	/* We are NOT going to set up an ordinary stack frame.  In order to pass
  	   the stacked args to the called function, we adjust our stack pointer
  	   to a0, which is in the _caller's_ alloca area.  We establish our own
  	   stack frame at the end of the call_context.
  
  	   Anything below the arguments will be freed at this point, although
  	   we preserve the call_context so that it can be read back in the
  	   caller.  */
  
  	.cfi_def_cfa	5, FRAME_LEN # Interim CFA based on a1.
  	SARG	$fp, $a1, FRAME_LEN - 2*PTRS
  	.cfi_offset	22, -2*PTRS
  	SARG	$ra, $a1, FRAME_LEN - 1*PTRS
  	.cfi_offset	1, -1*PTRS
  
  	addi.d	$fp, $a1, FRAME_LEN
  	move	$sp, $a0
  	.cfi_def_cfa	22, 0 # Our frame is fully set up.
  
  	# Load arguments.
  	move	$t1, $a2
  	move	$t2, $a3
  
  #if FLTS
  	FLARG	$fa0, $fp, -FRAME_LEN+0*FLTS
  	FLARG	$fa1, $fp, -FRAME_LEN+1*FLTS
  	FLARG	$fa2, $fp, -FRAME_LEN+2*FLTS
  	FLARG	$fa3, $fp, -FRAME_LEN+3*FLTS
  	FLARG	$fa4, $fp, -FRAME_LEN+4*FLTS
  	FLARG	$fa5, $fp, -FRAME_LEN+5*FLTS
  	FLARG	$fa6, $fp, -FRAME_LEN+6*FLTS
  	FLARG	$fa7, $fp, -FRAME_LEN+7*FLTS
  #endif
  
  	LARG	$a0, $fp, -FRAME_LEN+8*FLTS+0*PTRS
  	LARG	$a1, $fp, -FRAME_LEN+8*FLTS+1*PTRS
  	LARG	$a2, $fp, -FRAME_LEN+8*FLTS+2*PTRS
  	LARG	$a3, $fp, -FRAME_LEN+8*FLTS+3*PTRS
  	LARG	$a4, $fp, -FRAME_LEN+8*FLTS+4*PTRS
  	LARG	$a5, $fp, -FRAME_LEN+8*FLTS+5*PTRS
  	LARG	$a6, $fp, -FRAME_LEN+8*FLTS+6*PTRS
  	LARG	$a7, $fp, -FRAME_LEN+8*FLTS+7*PTRS
  
  	/* Call */
  	jirl	$ra, $t1, 0
  
  #if FLTS
  	/* Save return values - only a0/a1 (fa0/fa1) are used.  */
  	FSARG	$fa0, $fp, -FRAME_LEN+0*FLTS
  	FSARG	$fa1, $fp, -FRAME_LEN+1*FLTS
  #endif
  
  	SARG	$a0, $fp, -FRAME_LEN+8*FLTS+0*PTRS
  	SARG	$a1, $fp, -FRAME_LEN+8*FLTS+1*PTRS
  
  	/* Restore and return.  */
  	addi.d	$sp, $fp, -FRAME_LEN
  	.cfi_def_cfa	3, FRAME_LEN
  	LARG	$ra, $fp, -1*PTRS
  	.cfi_restore	1
  	LARG	$fp, $fp, -2*PTRS
  	.cfi_restore	22
  	jr	$ra
  	.cfi_endproc
  	.size	ffi_call_asm, .-ffi_call_asm
  
  
  /* ffi_closure_asm. Expects address of the passed-in ffi_closure in t0.
     void ffi_closure_inner (ffi_cif *cif,
  			   void (*fun)(ffi_cif *, void *, void **, void *),
  			   void *user_data,
  			   size_t *stackargs, struct call_context *regargs) */
  
  	.globl	ffi_closure_asm
  	.hidden	ffi_closure_asm
  	.type	ffi_closure_asm, @function
  
  ffi_closure_asm:
  	.cfi_startproc
  	addi.d	$sp, $sp, -FRAME_LEN
  	.cfi_def_cfa_offset FRAME_LEN
  
  	/* Make a frame.  */
  	SARG	$fp, $sp, FRAME_LEN - 2*PTRS
  	.cfi_offset	22, -2*PTRS
  	SARG	$ra, $sp, FRAME_LEN - 1*PTRS
  	.cfi_offset	1, -1*PTRS
  	addi.d	$fp, $sp, FRAME_LEN
  
  	/* Save arguments.  */
  #if FLTS
  	FSARG	$fa0, $sp, 0*FLTS
  	FSARG	$fa1, $sp, 1*FLTS
  	FSARG	$fa2, $sp, 2*FLTS
  	FSARG	$fa3, $sp, 3*FLTS
  	FSARG	$fa4, $sp, 4*FLTS
  	FSARG	$fa5, $sp, 5*FLTS
  	FSARG	$fa6, $sp, 6*FLTS
  	FSARG	$fa7, $sp, 7*FLTS
  #endif
  
  	SARG	$a0, $sp, 8*FLTS+0*PTRS
  	SARG	$a1, $sp, 8*FLTS+1*PTRS
  	SARG	$a2, $sp, 8*FLTS+2*PTRS
  	SARG	$a3, $sp, 8*FLTS+3*PTRS
  	SARG	$a4, $sp, 8*FLTS+4*PTRS
  	SARG	$a5, $sp, 8*FLTS+5*PTRS
  	SARG	$a6, $sp, 8*FLTS+6*PTRS
  	SARG	$a7, $sp, 8*FLTS+7*PTRS
  
  	/* Enter C */
  	LARG	$a0, $t0, FFI_TRAMPOLINE_SIZE+0*PTRS
  	LARG	$a1, $t0, FFI_TRAMPOLINE_SIZE+1*PTRS
  	LARG	$a2, $t0, FFI_TRAMPOLINE_SIZE+2*PTRS
  	addi.d	$a3, $sp, FRAME_LEN
  	move	$a4, $sp
  
  	bl	ffi_closure_inner
  
  	/* Return values.  */
  #if FLTS
  	FLARG	$fa0, $sp, 0*FLTS
  	FLARG	$fa1, $sp, 1*FLTS
  #endif
  
  	LARG	$a0, $sp, 8*FLTS+0*PTRS
  	LARG	$a1, $sp, 8*FLTS+1*PTRS
  
  	/* Restore and return.  */
  	LARG	$ra, $sp, FRAME_LEN-1*PTRS
  	.cfi_restore	1
  	LARG	$fp, $sp, FRAME_LEN-2*PTRS
  	.cfi_restore	22
  	addi.d	$sp, $sp, FRAME_LEN
  	.cfi_def_cfa_offset 0
  	jr	$ra
  	.cfi_endproc
  	.size	ffi_closure_asm, .-ffi_closure_asm
  
  /* Static trampoline code table, in which each element is a trampoline.
  
     The trampoline clobbers t0 and t1, but we don't save them on the stack
     because our psABI explicitly says they are scratch registers, at least for
     ELF.  Our dynamic trampoline is already clobbering them anyway.
  
     The trampoline has two parameters - target code to jump to and data for
     the target code. The trampoline extracts the parameters from its parameter
     block (see tramp_table_map()).  The trampoline saves the data address in
     t0 and jumps to the target code.  As ffi_closure_asm() already expects the
     data address to be in t0, we don't need a "ffi_closure_asm_alt".  */
  
  #if defined(FFI_EXEC_STATIC_TRAMP)
  	.align	16
  	.globl	trampoline_code_table
  	.hidden	trampoline_code_table
  	.type	trampoline_code_table, @function
  
  trampoline_code_table:
  
  	.rept	65536 / 16
  	pcaddu12i	$t1, 16 # 65536 >> 12
  	ld.d	$t0, $t1, 0
  	ld.d	$t1, $t1, 8
  	jirl	$zero, $t1, 0
  	.endr
  	.size	trampoline_code_table, .-trampoline_code_table
  
  	.align	2
  #endif
  
  /* ffi_go_closure_asm.  Expects address of the passed-in ffi_go_closure in t2.
     void ffi_closure_inner (ffi_cif *cif,
  			   void (*fun)(ffi_cif *, void *, void **, void *),
  			   void *user_data,
  			   size_t *stackargs, struct call_context *regargs) */
  
  	.globl	ffi_go_closure_asm
  	.hidden	ffi_go_closure_asm
  	.type	ffi_go_closure_asm, @function
  
  ffi_go_closure_asm:
  	.cfi_startproc
  	addi.d	$sp, $sp, -FRAME_LEN
  	.cfi_def_cfa_offset FRAME_LEN
  
  	/* Make a frame.  */
  	SARG	$fp, $sp, FRAME_LEN - 2*PTRS
  	.cfi_offset	22, -2*PTRS
  	SARG	$ra, $sp, FRAME_LEN - 1*PTRS
  	.cfi_offset	1, -1*PTRS
  	addi.d	$fp, $sp, FRAME_LEN
  
  	/* Save arguments.  */
  #if FLTS
  	FSARG	$fa0, $sp, 0*FLTS
  	FSARG	$fa1, $sp, 1*FLTS
  	FSARG	$fa2, $sp, 2*FLTS
  	FSARG	$fa3, $sp, 3*FLTS
  	FSARG	$fa4, $sp, 4*FLTS
  	FSARG	$fa5, $sp, 5*FLTS
  	FSARG	$fa6, $sp, 6*FLTS
  	FSARG	$fa7, $sp, 7*FLTS
  #endif
  
  	SARG	$a0, $sp, 8*FLTS+0*PTRS
  	SARG	$a1, $sp, 8*FLTS+1*PTRS
  	SARG	$a2, $sp, 8*FLTS+2*PTRS
  	SARG	$a3, $sp, 8*FLTS+3*PTRS
  	SARG	$a4, $sp, 8*FLTS+4*PTRS
  	SARG	$a5, $sp, 8*FLTS+5*PTRS
  	SARG	$a6, $sp, 8*FLTS+6*PTRS
  	SARG	$a7, $sp, 8*FLTS+7*PTRS
  
  	/* Enter C */
  	LARG	$a0, $t2, 1*PTRS
  	LARG	$a1, $t2, 2*PTRS
  	move	$a2, $t2
  	addi.d	$a3, $sp, FRAME_LEN
  	move	$a4, $sp
  
  	bl	ffi_closure_inner
  
  	/* Return values.  */
  #if FLTS
  	FLARG	$fa0, $sp, 0*FLTS
  	FLARG	$fa1, $sp, 1*FLTS
  #endif
  
  	LARG	$a0, $sp, 8*FLTS+0*PTRS
  	LARG	$a1, $sp, 8*FLTS+1*PTRS
  
  	/* Restore and return.  */
  	LARG	$ra, $sp, FRAME_LEN-1*PTRS
  	.cfi_restore	1
  	LARG	$fp, $sp, FRAME_LEN-2*PTRS
  	.cfi_restore	22
  	addi.d	$sp, $sp, FRAME_LEN
  	.cfi_def_cfa_offset 0
  	jr	$ra
  	.cfi_endproc
  	.size	ffi_go_closure_asm, .-ffi_go_closure_asm
  
  #if defined __ELF__ && defined __linux__
  	.section .note.GNU-stack,"",%progbits
  #endif