/* ----------------------------------------------------------------------- osf.S - Copyright (c) 1998, 2001 Red Hat Alpha/OSF Foreign Function Interface $Id: osf.S,v 1.1.1.1 1998/11/29 16:48:16 green Exp $ 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 CYGNUS SOLUTIONS 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 #include .arch ev6 .text /* ffi_call_osf (void *args, unsigned long bytes, unsigned flags, void *raddr, void (*fnaddr)()); Bit o trickiness here -- ARGS+BYTES is the base of the stack frame for this function. This has been allocated by ffi_call. We also deallocate some of the stack that has been alloca'd. */ .align 3 .globl ffi_call_osf .ent ffi_call_osf ffi_call_osf: .frame $15, 32, $26, 0 .mask 0x4008000, -32 $LFB1: addq $16,$17,$1 mov $16, $30 stq $26, 0($1) $LCFI0: stq $15, 8($1) $LCFI1: stq $18, 16($1) mov $1, $15 $LCFI2: .prologue 0 stq $19, 24($1) mov $20, $27 # Load up all of the (potential) argument registers. ldq $16, 0($30) ldt $f16, 0($30) ldt $f17, 8($30) ldq $17, 8($30) ldt $f18, 16($30) ldq $18, 16($30) ldt $f19, 24($30) ldq $19, 24($30) ldt $f20, 32($30) ldq $20, 32($30) ldt $f21, 40($30) ldq $21, 40($30) # Deallocate the register argument area. lda $30, 48($30) jsr $26, ($27), 0 ldgp $29, 0($26) # If the return value pointer is NULL, assume no return value. ldq $19, 24($15) ldq $18, 16($15) ldq $26, 0($15) beq $19, $noretval # Store the return value out in the proper type. cmpeq $18, FFI_TYPE_INT, $1 bne $1, $retint cmpeq $18, FFI_TYPE_FLOAT, $2 bne $2, $retfloat cmpeq $18, FFI_TYPE_DOUBLE, $3 bne $3, $retdouble $noretval: ldq $15, 8($15) ret $retint: stq $0, 0($19) nop ldq $15, 8($15) ret $retfloat: sts $f0, 0($19) nop ldq $15, 8($15) ret $retdouble: stt $f0, 0($19) nop ldq $15, 8($15) ret $LFE1: .end ffi_call_osf /* ffi_closure_osf(...) Receives the closure argument in $1. */ .align 3 .globl ffi_closure_osf .ent ffi_closure_osf ffi_closure_osf: .frame $30, 16*8, $26, 0 .mask 0x4000000, -16*8 $LFB2: ldgp $29, 0($27) subq $30, 16*8, $30 $LCFI5: stq $26, 0($30) $LCFI6: .prologue 1 # Store all of the potential argument registers in va_list format. stt $f16, 4*8($30) stt $f17, 5*8($30) stt $f18, 6*8($30) stt $f19, 7*8($30) stt $f20, 8*8($30) stt $f21, 9*8($30) stq $16, 10*8($30) stq $17, 11*8($30) stq $18, 12*8($30) stq $19, 13*8($30) stq $20, 14*8($30) stq $21, 15*8($30) # Call ffi_closure_osf_inner to do the bulk of the work. mov $1, $16 lda $17, 2*8($30) lda $18, 10*8($30) jsr $26, ffi_closure_osf_inner ldgp $29, 0($26) ldq $26, 0($30) # Load up the return value in the proper type. lda $1, $load_table s4addq $0, $1, $1 ldl $1, 0($1) addq $1, $29, $1 jmp $31, ($1), $load_32 .align 4 $load_none: addq $30, 16*8, $30 ret .align 4 $load_float: lds $f0, 16($30) nop addq $30, 16*8, $30 ret .align 4 $load_double: ldt $f0, 16($30) nop addq $30, 16*8, $30 ret .align 4 $load_u8: #ifdef __alpha_bwx__ ldbu $0, 16($30) nop #else ldq $0, 16($30) and $0, 255, $0 #endif addq $30, 16*8, $30 ret .align 4 $load_s8: #ifdef __alpha_bwx__ ldbu $0, 16($30) sextb $0, $0 #else ldq $0, 16($30) sll $0, 56, $0 sra $0, 56, $0 #endif addq $30, 16*8, $30 ret .align 4 $load_u16: #ifdef __alpha_bwx__ ldwu $0, 16($30) nop #else ldq $0, 16($30) zapnot $0, 3, $0 #endif addq $30, 16*8, $30 ret .align 4 $load_s16: #ifdef __alpha_bwx__ ldwu $0, 16($30) sextw $0, $0 #else ldq $0, 16($30) sll $0, 48, $0 sra $0, 48, $0 #endif addq $30, 16*8, $30 ret .align 4 $load_32: ldl $0, 16($30) nop addq $30, 16*8, $30 ret .align 4 $load_64: ldq $0, 16($30) nop addq $30, 16*8, $30 ret $LFE2: .end ffi_closure_osf #ifdef __ELF__ .section .rodata #else .rdata #endif $load_table: .gprel32 $load_none # FFI_TYPE_VOID .gprel32 $load_32 # FFI_TYPE_INT .gprel32 $load_float # FFI_TYPE_FLOAT .gprel32 $load_double # FFI_TYPE_DOUBLE .gprel32 $load_double # FFI_TYPE_LONGDOUBLE .gprel32 $load_u8 # FFI_TYPE_UINT8 .gprel32 $load_s8 # FFI_TYPE_SINT8 .gprel32 $load_u16 # FFI_TYPE_UINT16 .gprel32 $load_s16 # FFI_TYPE_SINT16 .gprel32 $load_32 # FFI_TYPE_UINT32 .gprel32 $load_32 # FFI_TYPE_SINT32 .gprel32 $load_64 # FFI_TYPE_UINT64 .gprel32 $load_64 # FFI_TYPE_SINT64 .gprel32 $load_none # FFI_TYPE_STRUCT .gprel32 $load_64 # FFI_TYPE_POINTER /* Assert that the table above is in sync with ffi.h. */ #if FFI_TYPE_FLOAT != 2 \ || FFI_TYPE_DOUBLE != 3 \ || FFI_TYPE_UINT8 != 5 \ || FFI_TYPE_SINT8 != 6 \ || FFI_TYPE_UINT16 != 7 \ || FFI_TYPE_SINT16 != 8 \ || FFI_TYPE_UINT32 != 9 \ || FFI_TYPE_SINT32 != 10 \ || FFI_TYPE_UINT64 != 11 \ || FFI_TYPE_SINT64 != 12 \ || FFI_TYPE_STRUCT != 13 \ || FFI_TYPE_POINTER != 14 \ || FFI_TYPE_LAST != 14 #error "osf.S out of sync with ffi.h" #endif #ifdef __ELF__ .section .eh_frame,EH_FRAME_FLAGS,@progbits __FRAME_BEGIN__: .4byte $LECIE1-$LSCIE1 # Length of Common Information Entry $LSCIE1: .4byte 0x0 # CIE Identifier Tag .byte 0x1 # CIE Version .ascii "zR\0" # CIE Augmentation .byte 0x1 # uleb128 0x1; CIE Code Alignment Factor .byte 0x78 # sleb128 -8; CIE Data Alignment Factor .byte 0x1a # CIE RA Column .byte 0x1 # uleb128 0x1; Augmentation size .byte 0x1b # FDE Encoding (pcrel sdata4) .byte 0xc # DW_CFA_def_cfa .byte 0x1e # uleb128 0x1e .byte 0x0 # uleb128 0x0 .align 3 $LECIE1: $LSFDE1: .4byte $LEFDE1-$LASFDE1 # FDE Length $LASFDE1: .4byte $LASFDE1-__FRAME_BEGIN__ # FDE CIE offset .4byte $LFB1-. # FDE initial location .4byte $LFE1-$LFB1 # FDE address range .byte 0x0 # uleb128 0x0; Augmentation size .byte 0x4 # DW_CFA_advance_loc4 .4byte $LCFI0-$LFB1 .byte 0xe # DW_CFA_def_cfa_offset .byte 0x30 # uleb128 0x30 .byte 0x4 # DW_CFA_advance_loc4 .4byte $LCFI1-$LCFI0 .byte 0x9a # DW_CFA_offset, column 0x1a .byte 0x6 # uleb128 0x6 .byte 0x8f # DW_CFA_offset, column 0xf .byte 0x5 # uleb128 0x5 .byte 0x4 # DW_CFA_advance_loc4 .4byte $LCFI2-$LCFI1 .byte 0xc # DW_CFA_def_cfa .byte 0xf # uleb128 0xf .byte 0x30 # uleb128 0x30 .align 3 $LEFDE1: $LSFDE3: .4byte $LEFDE3-$LASFDE3 # FDE Length $LASFDE3: .4byte $LASFDE3-__FRAME_BEGIN__ # FDE CIE offset .4byte $LFB2-. # FDE initial location .4byte $LFE2-$LFB2 # FDE address range .byte 0x0 # uleb128 0x0; Augmentation size .byte 0x4 # DW_CFA_advance_loc4 .4byte $LCFI5-$LFB2 .byte 0xe # DW_CFA_def_cfa_offset .byte 0x90,0x1 # uleb128 0x90 .byte 0x4 # DW_CFA_advance_loc4 .4byte $LCFI6-$LCFI5 .byte 0x9a # DW_CFA_offset, column 0x1a .byte 0x12 # uleb128 0x12 .align 3 $LEFDE3: #endif