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/* Subroutines for insn-output.c for Renesas H8/300. Copyright (C) 1992, 1993, 1994, 1995, 1996, 1997, 1998, 1999, 2000, 2001, 2002, 2003, 2004, 2005, 2006, 2007, 2008, 2009, 2010, 2011 Free Software Foundation, Inc. Contributed by Steve Chamberlain (sac@cygnus.com), Jim Wilson (wilson@cygnus.com), and Doug Evans (dje@cygnus.com). This file is part of GCC. GCC is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3, or (at your option) any later version. GCC is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with GCC; see the file COPYING3. If not see <http://www.gnu.org/licenses/>. */ #include "config.h" #include "system.h" #include "coretypes.h" #include "tm.h" #include "rtl.h" #include "tree.h" #include "regs.h" #include "hard-reg-set.h" #include "insn-config.h" #include "conditions.h" #include "output.h" #include "insn-attr.h" #include "flags.h" #include "recog.h" #include "expr.h" #include "function.h" #include "optabs.h" #include "diagnostic-core.h" #include "c-family/c-pragma.h" /* ??? */ #include "tm_p.h" #include "tm-constrs.h" #include "ggc.h" #include "target.h" #include "target-def.h" #include "df.h" /* Classifies a h8300_src_operand or h8300_dst_operand. H8OP_IMMEDIATE A constant operand of some sort. H8OP_REGISTER An ordinary register. H8OP_MEM_ABSOLUTE A memory reference with a constant address. H8OP_MEM_BASE A memory reference with a register as its address. H8OP_MEM_COMPLEX Some other kind of memory reference. */ enum h8300_operand_class { H8OP_IMMEDIATE, H8OP_REGISTER, H8OP_MEM_ABSOLUTE, H8OP_MEM_BASE, H8OP_MEM_COMPLEX, NUM_H8OPS }; /* For a general two-operand instruction, element [X][Y] gives the length of the opcode fields when the first operand has class (X + 1) and the second has class Y. */ typedef unsigned char h8300_length_table[NUM_H8OPS - 1][NUM_H8OPS]; /* Forward declarations. */ static const char *byte_reg (rtx, int); static int h8300_interrupt_function_p (tree); static int h8300_saveall_function_p (tree); static int h8300_monitor_function_p (tree); static int h8300_os_task_function_p (tree); static void h8300_emit_stack_adjustment (int, HOST_WIDE_INT, bool); static HOST_WIDE_INT round_frame_size (HOST_WIDE_INT); static unsigned int compute_saved_regs (void); static const char *cond_string (enum rtx_code); static unsigned int h8300_asm_insn_count (const char *); static tree h8300_handle_fndecl_attribute (tree *, tree, tree, int, bool *); static tree h8300_handle_eightbit_data_attribute (tree *, tree, tree, int, bool *); static tree h8300_handle_tiny_data_attribute (tree *, tree, tree, int, bool *); static void h8300_print_operand_address (FILE *, rtx); static void h8300_print_operand (FILE *, rtx, int); static bool h8300_print_operand_punct_valid_p (unsigned char code); #ifndef OBJECT_FORMAT_ELF static void h8300_asm_named_section (const char *, unsigned int, tree); #endif static int h8300_register_move_cost (enum machine_mode, reg_class_t, reg_class_t); static int h8300_and_costs (rtx); static int h8300_shift_costs (rtx); static void h8300_push_pop (int, int, bool, bool); static int h8300_stack_offset_p (rtx, int); static int h8300_ldm_stm_regno (rtx, int, int, int); static void h8300_reorg (void); static unsigned int h8300_constant_length (rtx); static unsigned int h8300_displacement_length (rtx, int); static unsigned int h8300_classify_operand (rtx, int, enum h8300_operand_class *); static unsigned int h8300_length_from_table (rtx, rtx, const h8300_length_table *); static unsigned int h8300_unary_length (rtx); static unsigned int h8300_short_immediate_length (rtx); static unsigned int h8300_bitfield_length (rtx, rtx); static unsigned int h8300_binary_length (rtx, const h8300_length_table *); static bool h8300_short_move_mem_p (rtx, enum rtx_code); static unsigned int h8300_move_length (rtx *, const h8300_length_table *); static bool h8300_hard_regno_scratch_ok (unsigned int); static rtx h8300_get_index (rtx, enum machine_mode mode, int *); /* CPU_TYPE, says what cpu we're compiling for. */ int cpu_type; /* True if a #pragma interrupt has been seen for the current function. */ static int pragma_interrupt; /* True if a #pragma saveall has been seen for the current function. */ static int pragma_saveall; static const char *const names_big[] = { "r0", "r1", "r2", "r3", "r4", "r5", "r6", "r7" }; static const char *const names_extended[] = { "er0", "er1", "er2", "er3", "er4", "er5", "er6", "er7" }; static const char *const names_upper_extended[] = { "e0", "e1", "e2", "e3", "e4", "e5", "e6", "e7" }; /* Points to one of the above. */ /* ??? The above could be put in an array indexed by CPU_TYPE. */ const char * const *h8_reg_names; /* Various operations needed by the following, indexed by CPU_TYPE. */ const char *h8_push_op, *h8_pop_op, *h8_mov_op; /* Value of MOVE_RATIO. */ int h8300_move_ratio; /* See below where shifts are handled for explanation of this enum. */ enum shift_alg { SHIFT_INLINE, SHIFT_ROT_AND, SHIFT_SPECIAL, SHIFT_LOOP }; /* Symbols of the various shifts which can be used as indices. */ enum shift_type { SHIFT_ASHIFT, SHIFT_LSHIFTRT, SHIFT_ASHIFTRT }; /* Macros to keep the shift algorithm tables small. */ #define INL SHIFT_INLINE #define ROT SHIFT_ROT_AND #define LOP SHIFT_LOOP #define SPC SHIFT_SPECIAL /* The shift algorithms for each machine, mode, shift type, and shift count are defined below. The three tables below correspond to QImode, HImode, and SImode, respectively. Each table is organized by, in the order of indices, machine, shift type, and shift count. */ static enum shift_alg shift_alg_qi[3][3][8] = { { /* TARGET_H8300 */ /* 0 1 2 3 4 5 6 7 */ { INL, INL, INL, INL, INL, ROT, ROT, ROT }, /* SHIFT_ASHIFT */ { INL, INL, INL, INL, INL, ROT, ROT, ROT }, /* SHIFT_LSHIFTRT */ { INL, INL, INL, INL, INL, LOP, LOP, SPC } /* SHIFT_ASHIFTRT */ }, { /* TARGET_H8300H */ /* 0 1 2 3 4 5 6 7 */ { INL, INL, INL, INL, INL, ROT, ROT, ROT }, /* SHIFT_ASHIFT */ { INL, INL, INL, INL, INL, ROT, ROT, ROT }, /* SHIFT_LSHIFTRT */ { INL, INL, INL, INL, INL, LOP, LOP, SPC } /* SHIFT_ASHIFTRT */ }, { /* TARGET_H8300S */ /* 0 1 2 3 4 5 6 7 */ { INL, INL, INL, INL, INL, INL, ROT, ROT }, /* SHIFT_ASHIFT */ { INL, INL, INL, INL, INL, INL, ROT, ROT }, /* SHIFT_LSHIFTRT */ { INL, INL, INL, INL, INL, INL, INL, SPC } /* SHIFT_ASHIFTRT */ } }; static enum shift_alg shift_alg_hi[3][3][16] = { { /* TARGET_H8300 */ /* 0 1 2 3 4 5 6 7 */ /* 8 9 10 11 12 13 14 15 */ { INL, INL, INL, INL, INL, INL, INL, SPC, SPC, SPC, SPC, SPC, SPC, SPC, SPC, SPC }, /* SHIFT_ASHIFT */ { INL, INL, INL, INL, INL, LOP, LOP, SPC, SPC, SPC, SPC, SPC, SPC, SPC, SPC, SPC }, /* SHIFT_LSHIFTRT */ { INL, INL, INL, INL, INL, LOP, LOP, SPC, SPC, SPC, SPC, SPC, SPC, SPC, SPC, SPC }, /* SHIFT_ASHIFTRT */ }, { /* TARGET_H8300H */ /* 0 1 2 3 4 5 6 7 */ /* 8 9 10 11 12 13 14 15 */ { INL, INL, INL, INL, INL, INL, INL, SPC, SPC, SPC, SPC, SPC, SPC, ROT, ROT, ROT }, /* SHIFT_ASHIFT */ { INL, INL, INL, INL, INL, INL, INL, SPC, SPC, SPC, SPC, SPC, SPC, ROT, ROT, ROT }, /* SHIFT_LSHIFTRT */ { INL, INL, INL, INL, INL, INL, INL, SPC, SPC, SPC, SPC, SPC, SPC, SPC, SPC, SPC }, /* SHIFT_ASHIFTRT */ }, { /* TARGET_H8300S */ /* 0 1 2 3 4 5 6 7 */ /* 8 9 10 11 12 13 14 15 */ { INL, INL, INL, INL, INL, INL, INL, INL, SPC, SPC, SPC, SPC, SPC, ROT, ROT, ROT }, /* SHIFT_ASHIFT */ { INL, INL, INL, INL, INL, INL, INL, INL, SPC, SPC, SPC, SPC, SPC, ROT, ROT, ROT }, /* SHIFT_LSHIFTRT */ { INL, INL, INL, INL, INL, INL, INL, INL, SPC, SPC, SPC, SPC, SPC, SPC, SPC, SPC }, /* SHIFT_ASHIFTRT */ } }; static enum shift_alg shift_alg_si[3][3][32] = { { /* TARGET_H8300 */ /* 0 1 2 3 4 5 6 7 */ /* 8 9 10 11 12 13 14 15 */ /* 16 17 18 19 20 21 22 23 */ /* 24 25 26 27 28 29 30 31 */ { INL, INL, INL, LOP, LOP, LOP, LOP, LOP, SPC, LOP, LOP, LOP, LOP, LOP, LOP, LOP, SPC, SPC, SPC, SPC, SPC, LOP, LOP, LOP, SPC, SPC, SPC, SPC, LOP, LOP, LOP, SPC }, /* SHIFT_ASHIFT */ { INL, INL, INL, LOP, LOP, LOP, LOP, LOP, SPC, SPC, LOP, LOP, LOP, LOP, LOP, SPC, SPC, SPC, SPC, LOP, LOP, LOP, LOP, LOP, SPC, SPC, SPC, SPC, SPC, LOP, LOP, SPC }, /* SHIFT_LSHIFTRT */ { INL, INL, INL, LOP, LOP, LOP, LOP, LOP, SPC, LOP, LOP, LOP, LOP, LOP, LOP, SPC, SPC, SPC, LOP, LOP, LOP, LOP, LOP, LOP, SPC, SPC, SPC, LOP, LOP, LOP, LOP, SPC }, /* SHIFT_ASHIFTRT */ }, { /* TARGET_H8300H */ /* 0 1 2 3 4 5 6 7 */ /* 8 9 10 11 12 13 14 15 */ /* 16 17 18 19 20 21 22 23 */ /* 24 25 26 27 28 29 30 31 */ { INL, INL, INL, INL, INL, LOP, LOP, LOP, SPC, LOP, LOP, LOP, LOP, LOP, LOP, SPC, SPC, SPC, SPC, SPC, LOP, LOP, LOP, LOP, SPC, LOP, LOP, LOP, SPC, SPC, SPC, SPC }, /* SHIFT_ASHIFT */ { INL, INL, INL, INL, INL, LOP, LOP, LOP, SPC, LOP, LOP, LOP, LOP, LOP, LOP, SPC, SPC, SPC, SPC, SPC, LOP, LOP, LOP, LOP, SPC, LOP, LOP, LOP, SPC, SPC, SPC, SPC }, /* SHIFT_LSHIFTRT */ { INL, INL, INL, INL, INL, LOP, LOP, LOP, SPC, LOP, LOP, LOP, LOP, LOP, LOP, LOP, SPC, SPC, SPC, SPC, LOP, LOP, LOP, LOP, SPC, LOP, LOP, LOP, LOP, LOP, LOP, SPC }, /* SHIFT_ASHIFTRT */ }, { /* TARGET_H8300S */ /* 0 1 2 3 4 5 6 7 */ /* 8 9 10 11 12 13 14 15 */ /* 16 17 18 19 20 21 22 23 */ /* 24 25 26 27 28 29 30 31 */ { INL, INL, INL, INL, INL, INL, INL, INL, INL, INL, INL, LOP, LOP, LOP, LOP, SPC, SPC, SPC, SPC, SPC, SPC, SPC, LOP, LOP, SPC, SPC, LOP, LOP, SPC, SPC, SPC, SPC }, /* SHIFT_ASHIFT */ { INL, INL, INL, INL, INL, INL, INL, INL, INL, INL, INL, LOP, LOP, LOP, LOP, SPC, SPC, SPC, SPC, SPC, SPC, SPC, LOP, LOP, SPC, SPC, LOP, LOP, SPC, SPC, SPC, SPC }, /* SHIFT_LSHIFTRT */ { INL, INL, INL, INL, INL, INL, INL, INL, INL, INL, INL, LOP, LOP, LOP, LOP, LOP, SPC, SPC, SPC, SPC, SPC, SPC, LOP, LOP, SPC, SPC, LOP, LOP, LOP, LOP, LOP, SPC }, /* SHIFT_ASHIFTRT */ } }; #undef INL #undef ROT #undef LOP #undef SPC enum h8_cpu { H8_300, H8_300H, H8_S }; /* Initialize various cpu specific globals at start up. */ static void h8300_option_override (void) { static const char *const h8_push_ops[2] = { "push" , "push.l" }; static const char *const h8_pop_ops[2] = { "pop" , "pop.l" }; static const char *const h8_mov_ops[2] = { "mov.w", "mov.l" }; if (TARGET_H8300) { cpu_type = (int) CPU_H8300; h8_reg_names = names_big; } else { /* For this we treat the H8/300H and H8S the same. */ cpu_type = (int) CPU_H8300H; h8_reg_names = names_extended; } h8_push_op = h8_push_ops[cpu_type]; h8_pop_op = h8_pop_ops[cpu_type]; h8_mov_op = h8_mov_ops[cpu_type]; if (!TARGET_H8300S && TARGET_MAC) { error ("-ms2600 is used without -ms"); target_flags |= MASK_H8300S_1; } if (TARGET_H8300 && TARGET_NORMAL_MODE) { error ("-mn is used without -mh or -ms"); target_flags ^= MASK_NORMAL_MODE; } /* Some of the shifts are optimized for speed by default. See http://gcc.gnu.org/ml/gcc-patches/2002-07/msg01858.html If optimizing for size, change shift_alg for those shift to SHIFT_LOOP. */ if (optimize_size) { /* H8/300 */ shift_alg_hi[H8_300][SHIFT_ASHIFT][5] = SHIFT_LOOP; shift_alg_hi[H8_300][SHIFT_ASHIFT][6] = SHIFT_LOOP; shift_alg_hi[H8_300][SHIFT_ASHIFT][13] = SHIFT_LOOP; shift_alg_hi[H8_300][SHIFT_ASHIFT][14] = SHIFT_LOOP; shift_alg_hi[H8_300][SHIFT_LSHIFTRT][13] = SHIFT_LOOP; shift_alg_hi[H8_300][SHIFT_LSHIFTRT][14] = SHIFT_LOOP; shift_alg_hi[H8_300][SHIFT_ASHIFTRT][13] = SHIFT_LOOP; shift_alg_hi[H8_300][SHIFT_ASHIFTRT][14] = SHIFT_LOOP; /* H8/300H */ shift_alg_hi[H8_300H][SHIFT_ASHIFT][5] = SHIFT_LOOP; shift_alg_hi[H8_300H][SHIFT_ASHIFT][6] = SHIFT_LOOP; shift_alg_hi[H8_300H][SHIFT_LSHIFTRT][5] = SHIFT_LOOP; shift_alg_hi[H8_300H][SHIFT_LSHIFTRT][6] = SHIFT_LOOP; shift_alg_hi[H8_300H][SHIFT_ASHIFTRT][5] = SHIFT_LOOP; shift_alg_hi[H8_300H][SHIFT_ASHIFTRT][6] = SHIFT_LOOP; shift_alg_hi[H8_300H][SHIFT_ASHIFTRT][13] = SHIFT_LOOP; shift_alg_hi[H8_300H][SHIFT_ASHIFTRT][14] = SHIFT_LOOP; /* H8S */ shift_alg_hi[H8_S][SHIFT_ASHIFTRT][14] = SHIFT_LOOP; } /* Work out a value for MOVE_RATIO. */ if (!TARGET_H8300SX) { /* Memory-memory moves are quite expensive without the h8sx instructions. */ h8300_move_ratio = 3; } else if (flag_omit_frame_pointer) { /* movmd sequences are fairly cheap when er6 isn't fixed. They can sometimes be as short as two individual memory-to-memory moves, but since they use all the call-saved registers, it seems better to allow up to three moves here. */ h8300_move_ratio = 4; } else if (optimize_size) { /* In this case we don't use movmd sequences since they tend to be longer than calls to memcpy(). Memory-to-memory moves are cheaper than for !TARGET_H8300SX, so it makes sense to have a slightly higher threshold. */ h8300_move_ratio = 4; } else { /* We use movmd sequences for some moves since it can be quicker than calling memcpy(). The sequences will need to save and restore er6 though, so bump up the cost. */ h8300_move_ratio = 6; } /* This target defaults to strict volatile bitfields. */ if (flag_strict_volatile_bitfields < 0 && abi_version_at_least(2)) flag_strict_volatile_bitfields = 1; } /* Return the byte register name for a register rtx X. B should be 0 if you want a lower byte register. B should be 1 if you want an upper byte register. */ static const char * byte_reg (rtx x, int b) { static const char *const names_small[] = { "r0l", "r0h", "r1l", "r1h", "r2l", "r2h", "r3l", "r3h", "r4l", "r4h", "r5l", "r5h", "r6l", "r6h", "r7l", "r7h" }; gcc_assert (REG_P (x)); return names_small[REGNO (x) * 2 + b]; } /* REGNO must be saved/restored across calls if this macro is true. */ #define WORD_REG_USED(regno) \ (regno < SP_REG \ /* No need to save registers if this function will not return. */ \ && ! TREE_THIS_VOLATILE (current_function_decl) \ && (h8300_saveall_function_p (current_function_decl) \ /* Save any call saved register that was used. */ \ || (df_regs_ever_live_p (regno) && !call_used_regs[regno]) \ /* Save the frame pointer if it was used. */ \ || (regno == HARD_FRAME_POINTER_REGNUM && df_regs_ever_live_p (regno)) \ /* Save any register used in an interrupt handler. */ \ || (h8300_current_function_interrupt_function_p () \ && df_regs_ever_live_p (regno)) \ /* Save call clobbered registers in non-leaf interrupt \ handlers. */ \ || (h8300_current_function_interrupt_function_p () \ && call_used_regs[regno] \ && !current_function_is_leaf))) /* We use this to wrap all emitted insns in the prologue. */ static rtx F (rtx x, bool set_it) { if (set_it) RTX_FRAME_RELATED_P (x) = 1; return x; } /* Mark all the subexpressions of the PARALLEL rtx PAR as frame-related. Return PAR. dwarf2out.c:dwarf2out_frame_debug_expr ignores sub-expressions of a PARALLEL rtx other than the first if they do not have the FRAME_RELATED flag set on them. */ static rtx Fpa (rtx par) { int len = XVECLEN (par, 0); int i; for (i = 0; i < len; i++) F (XVECEXP (par, 0, i), true); return par; } /* Output assembly language to FILE for the operation OP with operand size SIZE to adjust the stack pointer. */ static void h8300_emit_stack_adjustment (int sign, HOST_WIDE_INT size, bool in_prologue) { /* If the frame size is 0, we don't have anything to do. */ if (size == 0) return; /* H8/300 cannot add/subtract a large constant with a single instruction. If a temporary register is available, load the constant to it and then do the addition. */ if (TARGET_H8300 && size > 4 && !h8300_current_function_interrupt_function_p () && !(cfun->static_chain_decl != NULL && sign < 0)) { rtx r3 = gen_rtx_REG (Pmode, 3); F (emit_insn (gen_movhi (r3, GEN_INT (sign * size))), in_prologue); F (emit_insn (gen_addhi3 (stack_pointer_rtx, stack_pointer_rtx, r3)), in_prologue); } else { /* The stack adjustment made here is further optimized by the splitter. In case of H8/300, the splitter always splits the addition emitted here to make the adjustment interrupt-safe. FIXME: We don't always tag those, because we don't know what the splitter will do. */ if (Pmode == HImode) { rtx x = emit_insn (gen_addhi3 (stack_pointer_rtx, stack_pointer_rtx, GEN_INT (sign * size))); if (size < 4) F (x, in_prologue); } else F (emit_insn (gen_addsi3 (stack_pointer_rtx, stack_pointer_rtx, GEN_INT (sign * size))), in_prologue); } } /* Round up frame size SIZE. */ static HOST_WIDE_INT round_frame_size (HOST_WIDE_INT size) { return ((size + STACK_BOUNDARY / BITS_PER_UNIT - 1) & -STACK_BOUNDARY / BITS_PER_UNIT); } /* Compute which registers to push/pop. Return a bit vector of registers. */ static unsigned int compute_saved_regs (void) { unsigned int saved_regs = 0; int regno; /* Construct a bit vector of registers to be pushed/popped. */ for (regno = 0; regno <= HARD_FRAME_POINTER_REGNUM; regno++) { if (WORD_REG_USED (regno)) saved_regs |= 1 << regno; } /* Don't push/pop the frame pointer as it is treated separately. */ if (frame_pointer_needed) saved_regs &= ~(1 << HARD_FRAME_POINTER_REGNUM); return saved_regs; } /* Emit an insn to push register RN. */ static rtx push (int rn) { rtx reg = gen_rtx_REG (word_mode, rn); rtx x; if (TARGET_H8300) x = gen_push_h8300 (reg); else if (!TARGET_NORMAL_MODE) x = gen_push_h8300hs_advanced (reg); else x = gen_push_h8300hs_normal (reg); x = F (emit_insn (x), true); add_reg_note (x, REG_INC, stack_pointer_rtx); return x; } /* Emit an insn to pop register RN. */ static rtx pop (int rn) { rtx reg = gen_rtx_REG (word_mode, rn); rtx x; if (TARGET_H8300) x = gen_pop_h8300 (reg); else if (!TARGET_NORMAL_MODE) x = gen_pop_h8300hs_advanced (reg); else x = gen_pop_h8300hs_normal (reg); x = emit_insn (x); add_reg_note (x, REG_INC, stack_pointer_rtx); return x; } /* Emit an instruction to push or pop NREGS consecutive registers starting at register REGNO. POP_P selects a pop rather than a push and RETURN_P is true if the instruction should return. It must be possible to do the requested operation in a single instruction. If NREGS == 1 && !RETURN_P, use a normal push or pop insn. Otherwise emit a parallel of the form: (parallel [(return) ;; if RETURN_P (save or restore REGNO) (save or restore REGNO + 1) ... (save or restore REGNO + NREGS - 1) (set sp (plus sp (const_int adjust)))] */ static void h8300_push_pop (int regno, int nregs, bool pop_p, bool return_p) { int i, j; rtvec vec; rtx sp, offset, x; /* See whether we can use a simple push or pop. */ if (!return_p && nregs == 1) { if (pop_p) pop (regno); else push (regno); return; } /* We need one element for the return insn, if present, one for each register, and one for stack adjustment. */ vec = rtvec_alloc ((return_p ? 1 : 0) + nregs + 1); sp = stack_pointer_rtx; i = 0; /* Add the return instruction. */ if (return_p) { RTVEC_ELT (vec, i) = ret_rtx; i++; } /* Add the register moves. */ for (j = 0; j < nregs; j++) { rtx lhs, rhs; if (pop_p) { /* Register REGNO + NREGS - 1 is popped first. Before the stack adjustment, its slot is at address @sp. */ lhs = gen_rtx_REG (SImode, regno + j); rhs = gen_rtx_MEM (SImode, plus_constant (sp, (nregs - j - 1) * 4)); } else { /* Register REGNO is pushed first and will be stored at @(-4,sp). */ lhs = gen_rtx_MEM (SImode, plus_constant (sp, (j + 1) * -4)); rhs = gen_rtx_REG (SImode, regno + j); } RTVEC_ELT (vec, i + j) = gen_rtx_SET (VOIDmode, lhs, rhs); } /* Add the stack adjustment. */ offset = GEN_INT ((pop_p ? nregs : -nregs) * 4); RTVEC_ELT (vec, i + j) = gen_rtx_SET (VOIDmode, sp, gen_rtx_PLUS (Pmode, sp, offset)); x = gen_rtx_PARALLEL (VOIDmode, vec); if (!pop_p) x = Fpa (x); if (return_p) emit_jump_insn (x); else emit_insn (x); } /* Return true if X has the value sp + OFFSET. */ static int h8300_stack_offset_p (rtx x, int offset) { if (offset == 0) return x == stack_pointer_rtx; return (GET_CODE (x) == PLUS && XEXP (x, 0) == stack_pointer_rtx && GET_CODE (XEXP (x, 1)) == CONST_INT && INTVAL (XEXP (x, 1)) == offset); } /* A subroutine of h8300_ldm_stm_parallel. X is one pattern in something that may be an ldm or stm instruction. If it fits the required template, return the register it loads or stores, otherwise return -1. LOAD_P is true if X should be a load, false if it should be a store. NREGS is the number of registers that the whole instruction is expected to load or store. INDEX is the index of the register that X should load or store, relative to the lowest-numbered register. */ static int h8300_ldm_stm_regno (rtx x, int load_p, int index, int nregs) { int regindex, memindex, offset; if (load_p) regindex = 0, memindex = 1, offset = (nregs - index - 1) * 4; else memindex = 0, regindex = 1, offset = (index + 1) * -4; if (GET_CODE (x) == SET && GET_CODE (XEXP (x, regindex)) == REG && GET_CODE (XEXP (x, memindex)) == MEM && h8300_stack_offset_p (XEXP (XEXP (x, memindex), 0), offset)) return REGNO (XEXP (x, regindex)); return -1; } /* Return true if the elements of VEC starting at FIRST describe an ldm or stm instruction (LOAD_P says which). */ int h8300_ldm_stm_parallel (rtvec vec, int load_p, int first) { rtx last; int nregs, i, regno, adjust; /* There must be a stack adjustment, a register move, and at least one other operation (a return or another register move). */ if (GET_NUM_ELEM (vec) < 3) return false; /* Get the range of registers to be pushed or popped. */ nregs = GET_NUM_ELEM (vec) - first - 1; regno = h8300_ldm_stm_regno (RTVEC_ELT (vec, first), load_p, 0, nregs); /* Check that the call to h8300_ldm_stm_regno succeeded and that we're only dealing with GPRs. */ if (regno < 0 || regno + nregs > 8) return false; /* 2-register h8s instructions must start with an even-numbered register. 3- and 4-register instructions must start with er0 or er4. */ if (!TARGET_H8300SX) { if ((regno & 1) != 0) return false; if (nregs > 2 && (regno & 3) != 0) return false; } /* Check the other loads or stores. */ for (i = 1; i < nregs; i++) if (h8300_ldm_stm_regno (RTVEC_ELT (vec, first + i), load_p, i, nregs) != regno + i) return false; /* Check the stack adjustment. */ last = RTVEC_ELT (vec, first + nregs); adjust = (load_p ? nregs : -nregs) * 4; return (GET_CODE (last) == SET && SET_DEST (last) == stack_pointer_rtx && h8300_stack_offset_p (SET_SRC (last), adjust)); } /* This is what the stack looks like after the prolog of a function with a frame has been set up: <args> PC FP <- fp <locals> <saved registers> <- sp This is what the stack looks like after the prolog of a function which doesn't have a frame: <args> PC <locals> <saved registers> <- sp */ /* Generate RTL code for the function prologue. */ void h8300_expand_prologue (void) { int regno; int saved_regs; int n_regs; /* If the current function has the OS_Task attribute set, then we have a naked prologue. */ if (h8300_os_task_function_p (current_function_decl)) return; if (h8300_monitor_function_p (current_function_decl)) /* My understanding of monitor functions is they act just like interrupt functions, except the prologue must mask interrupts. */ emit_insn (gen_monitor_prologue ()); if (frame_pointer_needed) { /* Push fp. */ push (HARD_FRAME_POINTER_REGNUM); F (emit_move_insn (hard_frame_pointer_rtx, stack_pointer_rtx), true); } /* Push the rest of the registers in ascending order. */ saved_regs = compute_saved_regs (); for (regno = 0; regno < FIRST_PSEUDO_REGISTER; regno += n_regs) { n_regs = 1; if (saved_regs & (1 << regno)) { if (TARGET_H8300S) { /* See how many registers we can push at the same time. */ if ((!TARGET_H8300SX || (regno & 3) == 0) && ((saved_regs >> regno) & 0x0f) == 0x0f) n_regs = 4; else if ((!TARGET_H8300SX || (regno & 3) == 0) && ((saved_regs >> regno) & 0x07) == 0x07) n_regs = 3; else if ((!TARGET_H8300SX || (regno & 1) == 0) && ((saved_regs >> regno) & 0x03) == 0x03) n_regs = 2; } h8300_push_pop (regno, n_regs, false, false); } } /* Leave room for locals. */ h8300_emit_stack_adjustment (-1, round_frame_size (get_frame_size ()), true); } /* Return nonzero if we can use "rts" for the function currently being compiled. */ int h8300_can_use_return_insn_p (void) { return (reload_completed && !frame_pointer_needed && get_frame_size () == 0 && compute_saved_regs () == 0); } /* Generate RTL code for the function epilogue. */ void h8300_expand_epilogue (void) { int regno; int saved_regs; int n_regs; HOST_WIDE_INT frame_size; bool returned_p; if (h8300_os_task_function_p (current_function_decl)) /* OS_Task epilogues are nearly naked -- they just have an rts instruction. */ return; frame_size = round_frame_size (get_frame_size ()); returned_p = false; /* Deallocate locals. */ h8300_emit_stack_adjustment (1, frame_size, false); /* Pop the saved registers in descending order. */ saved_regs = compute_saved_regs (); for (regno = FIRST_PSEUDO_REGISTER - 1; regno >= 0; regno -= n_regs) { n_regs = 1; if (saved_regs & (1 << regno)) { if (TARGET_H8300S) { /* See how many registers we can pop at the same time. */ if ((TARGET_H8300SX || (regno & 3) == 3) && ((saved_regs << 3 >> regno) & 0x0f) == 0x0f) n_regs = 4; else if ((TARGET_H8300SX || (regno & 3) == 2) && ((saved_regs << 2 >> regno) & 0x07) == 0x07) n_regs = 3; else if ((TARGET_H8300SX || (regno & 1) == 1) && ((saved_regs << 1 >> regno) & 0x03) == 0x03) n_regs = 2; } /* See if this pop would be the last insn before the return. If so, use rte/l or rts/l instead of pop or ldm.l. */ if (TARGET_H8300SX && !frame_pointer_needed && frame_size == 0 && (saved_regs & ((1 << (regno - n_regs + 1)) - 1)) == 0) returned_p = true; h8300_push_pop (regno - n_regs + 1, n_regs, true, returned_p); } } /* Pop frame pointer if we had one. */ if (frame_pointer_needed) { if (TARGET_H8300SX) returned_p = true; h8300_push_pop (HARD_FRAME_POINTER_REGNUM, 1, true, returned_p); } if (!returned_p) emit_jump_insn (ret_rtx); } /* Return nonzero if the current function is an interrupt function. */ int h8300_current_function_interrupt_function_p (void) { return (h8300_interrupt_function_p (current_function_decl) || h8300_monitor_function_p (current_function_decl)); } /* Output assembly code for the start of the file. */ static void h8300_file_start (void) { default_file_start (); if (TARGET_H8300H) fputs (TARGET_NORMAL_MODE ? "\t.h8300hn\n" : "\t.h8300h\n", asm_out_file); else if (TARGET_H8300SX) fputs (TARGET_NORMAL_MODE ? "\t.h8300sxn\n" : "\t.h8300sx\n", asm_out_file); else if (TARGET_H8300S) fputs (TARGET_NORMAL_MODE ? "\t.h8300sn\n" : "\t.h8300s\n", asm_out_file); } /* Output assembly language code for the end of file. */ static void h8300_file_end (void) { fputs ("\t.end\n", asm_out_file); } /* Split an add of a small constant into two adds/subs insns. If USE_INCDEC_P is nonzero, we generate the last insn using inc/dec instead of adds/subs. */ void split_adds_subs (enum machine_mode mode, rtx *operands) { HOST_WIDE_INT val = INTVAL (operands[1]); rtx reg = operands[0]; HOST_WIDE_INT sign = 1; HOST_WIDE_INT amount; rtx (*gen_add) (rtx, rtx, rtx); /* Force VAL to be positive so that we do not have to consider the sign. */ if (val < 0) { val = -val; sign = -1; } switch (mode) { case HImode: gen_add = gen_addhi3; break; case SImode: gen_add = gen_addsi3; break; default: gcc_unreachable (); } /* Try different amounts in descending order. */ for (amount = (TARGET_H8300H || TARGET_H8300S) ? 4 : 2; amount > 0; amount /= 2) { for (; val >= amount; val -= amount) emit_insn (gen_add (reg, reg, GEN_INT (sign * amount))); } return; } /* Handle machine specific pragmas for compatibility with existing compilers for the H8/300. pragma saveall generates prologue/epilogue code which saves and restores all the registers on function entry. pragma interrupt saves and restores all registers, and exits with an rte instruction rather than an rts. A pointer to a function with this attribute may be safely used in an interrupt vector. */ void h8300_pr_interrupt (struct cpp_reader *pfile ATTRIBUTE_UNUSED) { pragma_interrupt = 1; } void h8300_pr_saveall (struct cpp_reader *pfile ATTRIBUTE_UNUSED) { pragma_saveall = 1; } /* If the next function argument with MODE and TYPE is to be passed in a register, return a reg RTX for the hard register in which to pass the argument. CUM represents the state after the last argument. If the argument is to be pushed, NULL_RTX is returned. On the H8/300 all normal args are pushed, unless -mquickcall in which case the first 3 arguments are passed in registers. */ static rtx h8300_function_arg (cumulative_args_t cum_v, enum machine_mode mode, const_tree type, bool named) { CUMULATIVE_ARGS *cum = get_cumulative_args (cum_v); static const char *const hand_list[] = { "__main", "__cmpsi2", "__divhi3", "__modhi3", "__udivhi3", "__umodhi3", "__divsi3", "__modsi3", "__udivsi3", "__umodsi3", "__mulhi3", "__mulsi3", "__reg_memcpy", "__reg_memset", "__ucmpsi2", 0, }; rtx result = NULL_RTX; const char *fname; int regpass = 0; /* Never pass unnamed arguments in registers. */ if (!named) return NULL_RTX; /* Pass 3 regs worth of data in regs when user asked on the command line. */ if (TARGET_QUICKCALL) regpass = 3; /* If calling hand written assembler, use 4 regs of args. */ if (cum->libcall) { const char * const *p; fname = XSTR (cum->libcall, 0); /* See if this libcall is one of the hand coded ones. */ for (p = hand_list; *p && strcmp (*p, fname) != 0; p++) ; if (*p) regpass = 4; } if (regpass) { int size; if (mode == BLKmode) size = int_size_in_bytes (type); else size = GET_MODE_SIZE (mode); if (size + cum->nbytes <= regpass * UNITS_PER_WORD && cum->nbytes / UNITS_PER_WORD <= 3) result = gen_rtx_REG (mode, cum->nbytes / UNITS_PER_WORD); } return result; } /* Update the data in CUM to advance over an argument of mode MODE and data type TYPE. (TYPE is null for libcalls where that information may not be available.) */ static void h8300_function_arg_advance (cumulative_args_t cum_v, enum machine_mode mode, const_tree type, bool named ATTRIBUTE_UNUSED) { CUMULATIVE_ARGS *cum = get_cumulative_args (cum_v); cum->nbytes += (mode != BLKmode ? (GET_MODE_SIZE (mode) + UNITS_PER_WORD - 1) & -UNITS_PER_WORD : (int_size_in_bytes (type) + UNITS_PER_WORD - 1) & -UNITS_PER_WORD); } /* Implements TARGET_REGISTER_MOVE_COST. Any SI register-to-register move may need to be reloaded, so inmplement h8300_register_move_cost to return > 2 so that reload never shortcuts. */ static int h8300_register_move_cost (enum machine_mode mode ATTRIBUTE_UNUSED, reg_class_t from, reg_class_t to) { if (from == MAC_REGS || to == MAC_REG) return 6; else return 3; } /* Compute the cost of an and insn. */ static int h8300_and_costs (rtx x) { rtx operands[4]; if (GET_MODE (x) == QImode) return 1; if (GET_MODE (x) != HImode && GET_MODE (x) != SImode) return 100; operands[0] = NULL; operands[1] = XEXP (x, 0); operands[2] = XEXP (x, 1); operands[3] = x; return compute_logical_op_length (GET_MODE (x), operands) / 2; } /* Compute the cost of a shift insn. */ static int h8300_shift_costs (rtx x) { rtx operands[4]; if (GET_MODE (x) != QImode && GET_MODE (x) != HImode && GET_MODE (x) != SImode) return 100; operands[0] = NULL; operands[1] = NULL; operands[2] = XEXP (x, 1); operands[3] = x; return compute_a_shift_length (NULL, operands) / 2; } /* Worker function for TARGET_RTX_COSTS. */ static bool h8300_rtx_costs (rtx x, int code, int outer_code, int opno ATTRIBUTE_UNUSED, int *total, bool speed) { if (TARGET_H8300SX && outer_code == MEM) { /* Estimate the number of execution states needed to calculate the address. */ if (register_operand (x, VOIDmode) || GET_CODE (x) == POST_INC || GET_CODE (x) == POST_DEC || CONSTANT_P (x)) *total = 0; else *total = COSTS_N_INSNS (1); return true; } switch (code) { case CONST_INT: { HOST_WIDE_INT n = INTVAL (x); if (TARGET_H8300SX) { /* Constant operands need the same number of processor states as register operands. Although we could try to use a size-based cost for !speed, the lack of of a mode makes the results very unpredictable. */ *total = 0; return true; } if (-4 <= n || n <= 4) { switch ((int) n) { case 0: *total = 0; return true; case 1: case 2: case -1: case -2: *total = 0 + (outer_code == SET); return true; case 4: case -4: if (TARGET_H8300H || TARGET_H8300S) *total = 0 + (outer_code == SET); else *total = 1; return true; } } *total = 1; return true; } case CONST: case LABEL_REF: case SYMBOL_REF: if (TARGET_H8300SX) { /* See comment for CONST_INT. */ *total = 0; return true; } *total = 3; return true; case CONST_DOUBLE: *total = 20; return true; case COMPARE: if (XEXP (x, 1) == const0_rtx) *total = 0; return false; case AND: if (!h8300_dst_operand (XEXP (x, 0), VOIDmode) || !h8300_src_operand (XEXP (x, 1), VOIDmode)) return false; *total = COSTS_N_INSNS (h8300_and_costs (x)); return true; /* We say that MOD and DIV are so expensive because otherwise we'll generate some really horrible code for division of a power of two. */ case MOD: case DIV: case UMOD: case UDIV: if (TARGET_H8300SX) switch (GET_MODE (x)) { case QImode: case HImode: *total = COSTS_N_INSNS (!speed ? 4 : 10); return false; case SImode: *total = COSTS_N_INSNS (!speed ? 4 : 18); return false; default: break; } *total = COSTS_N_INSNS (12); return true; case MULT: if (TARGET_H8300SX) switch (GET_MODE (x)) { case QImode: case HImode: *total = COSTS_N_INSNS (2); return false; case SImode: *total = COSTS_N_INSNS (5); return false; default: break; } *total = COSTS_N_INSNS (4); return true; case ASHIFT: case ASHIFTRT: case LSHIFTRT: if (h8sx_binary_shift_operator (x, VOIDmode)) { *total = COSTS_N_INSNS (2); return false; } else if (h8sx_unary_shift_operator (x, VOIDmode)) { *total = COSTS_N_INSNS (1); return false; } *total = COSTS_N_INSNS (h8300_shift_costs (x)); return true; case ROTATE: case ROTATERT: if (GET_MODE (x) == HImode) *total = 2; else *total = 8; return true; default: *total = COSTS_N_INSNS (1); return false; } } /* Documentation for the machine specific operand escapes: 'E' like s but negative. 'F' like t but negative. 'G' constant just the negative 'R' print operand as a byte:8 address if appropriate, else fall back to 'X' handling. 'S' print operand as a long word 'T' print operand as a word 'V' find the set bit, and print its number. 'W' find the clear bit, and print its number. 'X' print operand as a byte 'Y' print either l or h depending on whether last 'Z' operand < 8 or >= 8. If this operand isn't a register, fall back to 'R' handling. 'Z' print int & 7. 'c' print the opcode corresponding to rtl 'e' first word of 32-bit value - if reg, then least reg. if mem then least. if const then most sig word 'f' second word of 32-bit value - if reg, then biggest reg. if mem then +2. if const then least sig word 'j' print operand as condition code. 'k' print operand as reverse condition code. 'm' convert an integer operand to a size suffix (.b, .w or .l) 'o' print an integer without a leading '#' 's' print as low byte of 16-bit value 't' print as high byte of 16-bit value 'w' print as low byte of 32-bit value 'x' print as 2nd byte of 32-bit value 'y' print as 3rd byte of 32-bit value 'z' print as msb of 32-bit value */ /* Return assembly language string which identifies a comparison type. */ static const char * cond_string (enum rtx_code code) { switch (code) { case NE: return "ne"; case EQ: return "eq"; case GE: return "ge"; case GT: return "gt"; case LE: return "le"; case LT: return "lt"; case GEU: return "hs"; case GTU: return "hi"; case LEU: return "ls"; case LTU: return "lo"; default: gcc_unreachable (); } } /* Print operand X using operand code CODE to assembly language output file FILE. */ static void h8300_print_operand (FILE *file, rtx x, int code) { /* This is used for communication between codes V,W,Z and Y. */ static int bitint; switch (code) { case 'E': switch (GET_CODE (x)) { case REG: fprintf (file, "%sl", names_big[REGNO (x)]); break; case CONST_INT: fprintf (file, "#%ld", (-INTVAL (x)) & 0xff); break; default: gcc_unreachable (); } break; case 'F': switch (GET_CODE (x)) { case REG: fprintf (file, "%sh", names_big[REGNO (x)]); break; case CONST_INT: fprintf (file, "#%ld", ((-INTVAL (x)) & 0xff00) >> 8); break; default: gcc_unreachable (); } break; case 'G': gcc_assert (GET_CODE (x) == CONST_INT); fprintf (file, "#%ld", 0xff & (-INTVAL (x))); break; case 'S': if (GET_CODE (x) == REG) fprintf (file, "%s", names_extended[REGNO (x)]); else goto def; break; case 'T': if (GET_CODE (x) == REG) fprintf (file, "%s", names_big[REGNO (x)]); else goto def; break; case 'V': bitint = (INTVAL (x) & 0xffff); if ((exact_log2 ((bitint >> 8) & 0xff)) == -1) bitint = exact_log2 (bitint & 0xff); else bitint = exact_log2 ((bitint >> 8) & 0xff); gcc_assert (bitint >= 0); fprintf (file, "#%d", bitint); break; case 'W': bitint = ((~INTVAL (x)) & 0xffff); if ((exact_log2 ((bitint >> 8) & 0xff)) == -1 ) bitint = exact_log2 (bitint & 0xff); else bitint = (exact_log2 ((bitint >> 8) & 0xff)); gcc_assert (bitint >= 0); fprintf (file, "#%d", bitint); break; case 'R': case 'X': if (GET_CODE (x) == REG) fprintf (file, "%s", byte_reg (x, 0)); else goto def; break; case 'Y': gcc_assert (bitint >= 0); if (GET_CODE (x) == REG) fprintf (file, "%s%c", names_big[REGNO (x)], bitint > 7 ? 'h' : 'l'); else h8300_print_operand (file, x, 'R'); bitint = -1; break; case 'Z': bitint = INTVAL (x); fprintf (file, "#%d", bitint & 7); break; case 'c': switch (GET_CODE (x)) { case IOR: fprintf (file, "or"); break; case XOR: fprintf (file, "xor"); break; case AND: fprintf (file, "and"); break; default: break; } break; case 'e': switch (GET_CODE (x)) { case REG: if (TARGET_H8300) fprintf (file, "%s", names_big[REGNO (x)]); else fprintf (file, "%s", names_upper_extended[REGNO (x)]); break; case MEM: h8300_print_operand (file, x, 0); break; case CONST_INT: fprintf (file, "#%ld", ((INTVAL (x) >> 16) & 0xffff)); break; case CONST_DOUBLE: { long val; REAL_VALUE_TYPE rv; REAL_VALUE_FROM_CONST_DOUBLE (rv, x); REAL_VALUE_TO_TARGET_SINGLE (rv, val); fprintf (file, "#%ld", ((val >> 16) & 0xffff)); break; } default: gcc_unreachable (); break; } break; case 'f': switch (GET_CODE (x)) { case REG: if (TARGET_H8300) fprintf (file, "%s", names_big[REGNO (x) + 1]); else fprintf (file, "%s", names_big[REGNO (x)]); break; case MEM: x = adjust_address (x, HImode, 2); h8300_print_operand (file, x, 0); break; case CONST_INT: fprintf (file, "#%ld", INTVAL (x) & 0xffff); break; case CONST_DOUBLE: { long val; REAL_VALUE_TYPE rv; REAL_VALUE_FROM_CONST_DOUBLE (rv, x); REAL_VALUE_TO_TARGET_SINGLE (rv, val); fprintf (file, "#%ld", (val & 0xffff)); break; } default: gcc_unreachable (); } break; case 'j': fputs (cond_string (GET_CODE (x)), file); break; case 'k': fputs (cond_string (reverse_condition (GET_CODE (x))), file); break; case 'm': gcc_assert (GET_CODE (x) == CONST_INT); switch (INTVAL (x)) { case 1: fputs (".b", file); break; case 2: fputs (".w", file); break; case 4: fputs (".l", file); break; default: gcc_unreachable (); } break; case 'o': h8300_print_operand_address (file, x); break; case 's': if (GET_CODE (x) == CONST_INT) fprintf (file, "#%ld", (INTVAL (x)) & 0xff); else fprintf (file, "%s", byte_reg (x, 0)); break; case 't': if (GET_CODE (x) == CONST_INT) fprintf (file, "#%ld", (INTVAL (x) >> 8) & 0xff); else fprintf (file, "%s", byte_reg (x, 1)); break; case 'w': if (GET_CODE (x) == CONST_INT) fprintf (file, "#%ld", INTVAL (x) & 0xff); else fprintf (file, "%s", byte_reg (x, TARGET_H8300 ? 2 : 0)); break; case 'x': if (GET_CODE (x) == CONST_INT) fprintf (file, "#%ld", (INTVAL (x) >> 8) & 0xff); else fprintf (file, "%s", byte_reg (x, TARGET_H8300 ? 3 : 1)); break; case 'y': if (GET_CODE (x) == CONST_INT) fprintf (file, "#%ld", (INTVAL (x) >> 16) & 0xff); else fprintf (file, "%s", byte_reg (x, 0)); break; case 'z': if (GET_CODE (x) == CONST_INT) fprintf (file, "#%ld", (INTVAL (x) >> 24) & 0xff); else fprintf (file, "%s", byte_reg (x, 1)); break; default: def: switch (GET_CODE (x)) { case REG: switch (GET_MODE (x)) { case QImode: #if 0 /* Is it asm ("mov.b %0,r2l", ...) */ fprintf (file, "%s", byte_reg (x, 0)); #else /* ... or is it asm ("mov.b %0l,r2l", ...) */ fprintf (file, "%s", names_big[REGNO (x)]); #endif break; case HImode: fprintf (file, "%s", names_big[REGNO (x)]); break; case SImode: case SFmode: fprintf (file, "%s", names_extended[REGNO (x)]); break; default: gcc_unreachable (); } break; case MEM: { rtx addr = XEXP (x, 0); fprintf (file, "@"); output_address (addr); /* Add a length suffix to constant addresses. Although this is often unnecessary, it helps to avoid ambiguity in the syntax of mova. If we wrote an insn like: mova/w.l @(1,@foo.b),er0 then .b would be considered part of the symbol name. Adding a length after foo will avoid this. */ if (CONSTANT_P (addr)) switch (code) { case 'R': /* Used for mov.b and bit operations. */ if (h8300_eightbit_constant_address_p (addr)) { fprintf (file, ":8"); break; } /* Fall through. We should not get here if we are processing bit operations on H8/300 or H8/300H because 'U' constraint does not allow bit operations on the tiny area on these machines. */ case 'X': case 'T': case 'S': if (h8300_constant_length (addr) == 2) fprintf (file, ":16"); else fprintf (file, ":32"); break; default: break; } } break; case CONST_INT: case SYMBOL_REF: case CONST: case LABEL_REF: fprintf (file, "#"); h8300_print_operand_address (file, x); break; case CONST_DOUBLE: { long val; REAL_VALUE_TYPE rv; REAL_VALUE_FROM_CONST_DOUBLE (rv, x); REAL_VALUE_TO_TARGET_SINGLE (rv, val); fprintf (file, "#%ld", val); break; } default: break; } } } /* Implements TARGET_PRINT_OPERAND_PUNCT_VALID_P. */ static bool h8300_print_operand_punct_valid_p (unsigned char code) { return (code == '#'); } /* Output assembly language output for the address ADDR to FILE. */ static void h8300_print_operand_address (FILE *file, rtx addr) { rtx index; int size; switch (GET_CODE (addr)) { case REG: fprintf (file, "%s", h8_reg_names[REGNO (addr)]); break; case PRE_DEC: fprintf (file, "-%s", h8_reg_names[REGNO (XEXP (addr, 0))]); break; case POST_INC: fprintf (file, "%s+", h8_reg_names[REGNO (XEXP (addr, 0))]); break; case PRE_INC: fprintf (file, "+%s", h8_reg_names[REGNO (XEXP (addr, 0))]); break; case POST_DEC: fprintf (file, "%s-", h8_reg_names[REGNO (XEXP (addr, 0))]); break; case PLUS: fprintf (file, "("); index = h8300_get_index (XEXP (addr, 0), VOIDmode, &size); if (GET_CODE (index) == REG) { /* reg,foo */ h8300_print_operand_address (file, XEXP (addr, 1)); fprintf (file, ","); switch (size) { case 0: h8300_print_operand_address (file, index); break; case 1: h8300_print_operand (file, index, 'X'); fputs (".b", file); break; case 2: h8300_print_operand (file, index, 'T'); fputs (".w", file); break; case 4: h8300_print_operand (file, index, 'S'); fputs (".l", file); break; } /* h8300_print_operand_address (file, XEXP (addr, 0)); */ } else { /* foo+k */ h8300_print_operand_address (file, XEXP (addr, 0)); fprintf (file, "+"); h8300_print_operand_address (file, XEXP (addr, 1)); } fprintf (file, ")"); break; case CONST_INT: { /* Since the H8/300 only has 16-bit pointers, negative values are also those >= 32768. This happens for example with pointer minus a constant. We don't want to turn (char *p - 2) into (char *p + 65534) because loop unrolling can build upon this (IE: char *p + 131068). */ int n = INTVAL (addr); if (TARGET_H8300) n = (int) (short) n; fprintf (file, "%d", n); break; } default: output_addr_const (file, addr); break; } } /* Output all insn addresses and their sizes into the assembly language output file. This is helpful for debugging whether the length attributes in the md file are correct. This is not meant to be a user selectable option. */ void final_prescan_insn (rtx insn, rtx *operand ATTRIBUTE_UNUSED, int num_operands ATTRIBUTE_UNUSED) { /* This holds the last insn address. */ static int last_insn_address = 0; const int uid = INSN_UID (insn); if (TARGET_ADDRESSES) { fprintf (asm_out_file, "; 0x%x %d\n", INSN_ADDRESSES (uid), INSN_ADDRESSES (uid) - last_insn_address); last_insn_address = INSN_ADDRESSES (uid); } } /* Prepare for an SI sized move. */ int h8300_expand_movsi (rtx operands[]) { rtx src = operands[1]; rtx dst = operands[0]; if (!reload_in_progress && !reload_completed) { if (!register_operand (dst, GET_MODE (dst))) { rtx tmp = gen_reg_rtx (GET_MODE (dst)); emit_move_insn (tmp, src); operands[1] = tmp; } } return 0; } /* Given FROM and TO register numbers, say whether this elimination is allowed. Frame pointer elimination is automatically handled. For the h8300, if frame pointer elimination is being done, we would like to convert ap and rp into sp, not fp. All other eliminations are valid. */ static bool h8300_can_eliminate (const int from ATTRIBUTE_UNUSED, const int to) { return (to == STACK_POINTER_REGNUM ? ! frame_pointer_needed : true); } /* Conditionally modify register usage based on target flags. */ static void h8300_conditional_register_usage (void) { if (!TARGET_MAC) fixed_regs[MAC_REG] = call_used_regs[MAC_REG] = 1; } /* Function for INITIAL_ELIMINATION_OFFSET(FROM, TO, OFFSET). Define the offset between two registers, one to be eliminated, and the other its replacement, at the start of a routine. */ int h8300_initial_elimination_offset (int from, int to) { /* The number of bytes that the return address takes on the stack. */ int pc_size = POINTER_SIZE / BITS_PER_UNIT; /* The number of bytes that the saved frame pointer takes on the stack. */ int fp_size = frame_pointer_needed * UNITS_PER_WORD; /* The number of bytes that the saved registers, excluding the frame pointer, take on the stack. */ int saved_regs_size = 0; /* The number of bytes that the locals takes on the stack. */ int frame_size = round_frame_size (get_frame_size ()); int regno; for (regno = 0; regno <= HARD_FRAME_POINTER_REGNUM; regno++) if (WORD_REG_USED (regno)) saved_regs_size += UNITS_PER_WORD; /* Adjust saved_regs_size because the above loop took the frame pointer int account. */ saved_regs_size -= fp_size; switch (to) { case HARD_FRAME_POINTER_REGNUM: switch (from) { case ARG_POINTER_REGNUM: return pc_size + fp_size; case RETURN_ADDRESS_POINTER_REGNUM: return fp_size; case FRAME_POINTER_REGNUM: return -saved_regs_size; default: gcc_unreachable (); } break; case STACK_POINTER_REGNUM: switch (from) { case ARG_POINTER_REGNUM: return pc_size + saved_regs_size + frame_size; case RETURN_ADDRESS_POINTER_REGNUM: return saved_regs_size + frame_size; case FRAME_POINTER_REGNUM: return frame_size; default: gcc_unreachable (); } break; default: gcc_unreachable (); } gcc_unreachable (); } /* Worker function for RETURN_ADDR_RTX. */ rtx h8300_return_addr_rtx (int count, rtx frame) { rtx ret; if (count == 0) ret = gen_rtx_MEM (Pmode, gen_rtx_REG (Pmode, RETURN_ADDRESS_POINTER_REGNUM)); else if (flag_omit_frame_pointer) return (rtx) 0; else ret = gen_rtx_MEM (Pmode, memory_address (Pmode, plus_constant (frame, UNITS_PER_WORD))); set_mem_alias_set (ret, get_frame_alias_set ()); return ret; } /* Update the condition code from the insn. */ void notice_update_cc (rtx body, rtx insn) { rtx set; switch (get_attr_cc (insn)) { case CC_NONE: /* Insn does not affect CC at all. */ break; case CC_NONE_0HIT: /* Insn does not change CC, but the 0'th operand has been changed. */ if (cc_status.value1 != 0 && reg_overlap_mentioned_p (recog_data.operand[0], cc_status.value1)) cc_status.value1 = 0; if (cc_status.value2 != 0 && reg_overlap_mentioned_p (recog_data.operand[0], cc_status.value2)) cc_status.value2 = 0; break; case CC_SET_ZN: /* Insn sets the Z,N flags of CC to recog_data.operand[0]. The V flag is unusable. The C flag may or may not be known but that's ok because alter_cond will change tests to use EQ/NE. */ CC_STATUS_INIT; cc_status.flags |= CC_OVERFLOW_UNUSABLE | CC_NO_CARRY; set = single_set (insn); cc_status.value1 = SET_SRC (set); if (SET_DEST (set) != cc0_rtx) cc_status.value2 = SET_DEST (set); break; case CC_SET_ZNV: /* Insn sets the Z,N,V flags of CC to recog_data.operand[0]. The C flag may or may not be known but that's ok because alter_cond will change tests to use EQ/NE. */ CC_STATUS_INIT; cc_status.flags |= CC_NO_CARRY; set = single_set (insn); cc_status.value1 = SET_SRC (set); if (SET_DEST (set) != cc0_rtx) { /* If the destination is STRICT_LOW_PART, strip off STRICT_LOW_PART. */ if (GET_CODE (SET_DEST (set)) == STRICT_LOW_PART) cc_status.value2 = XEXP (SET_DEST (set), 0); else cc_status.value2 = SET_DEST (set); } break; case CC_COMPARE: /* The insn is a compare instruction. */ CC_STATUS_INIT; cc_status.value1 = SET_SRC (body); break; case CC_CLOBBER: /* Insn doesn't leave CC in a usable state. */ CC_STATUS_INIT; break; } } /* Given that X occurs in an address of the form (plus X constant), return the part of X that is expected to be a register. There are four kinds of addressing mode to recognize: @(dd,Rn) @(dd,RnL.b) @(dd,Rn.w) @(dd,ERn.l) If SIZE is nonnull, and the address is one of the last three forms, set *SIZE to the index multiplication factor. Set it to 0 for plain @(dd,Rn) addresses. MODE is the mode of the value being accessed. It can be VOIDmode if the address is known to be valid, but its mode is unknown. */ static rtx h8300_get_index (rtx x, enum machine_mode mode, int *size) { int dummy, factor; if (size == 0) size = &dummy; factor = (mode == VOIDmode ? 0 : GET_MODE_SIZE (mode)); if (TARGET_H8300SX && factor <= 4 && (mode == VOIDmode || GET_MODE_CLASS (mode) == MODE_INT || GET_MODE_CLASS (mode) == MODE_FLOAT)) { if (factor <= 1 && GET_CODE (x) == ZERO_EXTEND) { /* When accessing byte-sized values, the index can be a zero-extended QImode or HImode register. */ *size = GET_MODE_SIZE (GET_MODE (XEXP (x, 0))); return XEXP (x, 0); } else { /* We're looking for addresses of the form: (mult X I) or (mult (zero_extend X) I) where I is the size of the operand being accessed. The canonical form of the second expression is: (and (mult (subreg X) I) J) where J == GET_MODE_MASK (GET_MODE (X)) * I. */ rtx index; if (GET_CODE (x) == AND && GET_CODE (XEXP (x, 1)) == CONST_INT && (factor == 0 || INTVAL (XEXP (x, 1)) == 0xff * factor || INTVAL (XEXP (x, 1)) == 0xffff * factor)) { index = XEXP (x, 0); *size = (INTVAL (XEXP (x, 1)) >= 0xffff ? 2 : 1); } else { index = x; *size = 4; } if (GET_CODE (index) == MULT && GET_CODE (XEXP (index, 1)) == CONST_INT && (factor == 0 || factor == INTVAL (XEXP (index, 1)))) return XEXP (index, 0); } } *size = 0; return x; } /* Worker function for TARGET_MODE_DEPENDENT_ADDRESS_P. On the H8/300, the predecrement and postincrement address depend thus (the amount of decrement or increment being the length of the operand). */ static bool h8300_mode_dependent_address_p (const_rtx addr) { if (GET_CODE (addr) == PLUS && h8300_get_index (XEXP (addr, 0), VOIDmode, 0) != XEXP (addr, 0)) return true; return false; } static const h8300_length_table addb_length_table = { /* #xx Rs @aa @Rs @xx */ { 2, 2, 4, 4, 4 }, /* add.b xx,Rd */ { 4, 4, 4, 4, 6 }, /* add.b xx,@aa */ { 4, 4, 4, 4, 6 }, /* add.b xx,@Rd */ { 6, 4, 4, 4, 6 } /* add.b xx,@xx */ }; static const h8300_length_table addw_length_table = { /* #xx Rs @aa @Rs @xx */ { 2, 2, 4, 4, 4 }, /* add.w xx,Rd */ { 4, 4, 4, 4, 6 }, /* add.w xx,@aa */ { 4, 4, 4, 4, 6 }, /* add.w xx,@Rd */ { 4, 4, 4, 4, 6 } /* add.w xx,@xx */ }; static const h8300_length_table addl_length_table = { /* #xx Rs @aa @Rs @xx */ { 2, 2, 4, 4, 4 }, /* add.l xx,Rd */ { 4, 4, 6, 6, 6 }, /* add.l xx,@aa */ { 4, 4, 6, 6, 6 }, /* add.l xx,@Rd */ { 4, 4, 6, 6, 6 } /* add.l xx,@xx */ }; #define logicb_length_table addb_length_table #define logicw_length_table addw_length_table static const h8300_length_table logicl_length_table = { /* #xx Rs @aa @Rs @xx */ { 2, 4, 4, 4, 4 }, /* and.l xx,Rd */ { 4, 4, 6, 6, 6 }, /* and.l xx,@aa */ { 4, 4, 6, 6, 6 }, /* and.l xx,@Rd */ { 4, 4, 6, 6, 6 } /* and.l xx,@xx */ }; static const h8300_length_table movb_length_table = { /* #xx Rs @aa @Rs @xx */ { 2, 2, 2, 2, 4 }, /* mov.b xx,Rd */ { 4, 2, 4, 4, 4 }, /* mov.b xx,@aa */ { 4, 2, 4, 4, 4 }, /* mov.b xx,@Rd */ { 4, 4, 4, 4, 4 } /* mov.b xx,@xx */ }; #define movw_length_table movb_length_table static const h8300_length_table movl_length_table = { /* #xx Rs @aa @Rs @xx */ { 2, 2, 4, 4, 4 }, /* mov.l xx,Rd */ { 4, 4, 4, 4, 4 }, /* mov.l xx,@aa */ { 4, 4, 4, 4, 4 }, /* mov.l xx,@Rd */ { 4, 4, 4, 4, 4 } /* mov.l xx,@xx */ }; /* Return the size of the given address or displacement constant. */ static unsigned int h8300_constant_length (rtx constant) { /* Check for (@d:16,Reg). */ if (GET_CODE (constant) == CONST_INT && IN_RANGE (INTVAL (constant), -0x8000, 0x7fff)) return 2; /* Check for (@d:16,Reg) in cases where the displacement is an absolute address. */ if (Pmode == HImode || h8300_tiny_constant_address_p (constant)) return 2; return 4; } /* Return the size of a displacement field in address ADDR, which should have the form (plus X constant). SIZE is the number of bytes being accessed. */ static unsigned int h8300_displacement_length (rtx addr, int size) { rtx offset; offset = XEXP (addr, 1); /* Check for @(d:2,Reg). */ if (register_operand (XEXP (addr, 0), VOIDmode) && GET_CODE (offset) == CONST_INT && (INTVAL (offset) == size || INTVAL (offset) == size * 2 || INTVAL (offset) == size * 3)) return 0; return h8300_constant_length (offset); } /* Store the class of operand OP in *OPCLASS and return the length of any extra operand fields. SIZE is the number of bytes in OP. OPCLASS can be null if only the length is needed. */ static unsigned int h8300_classify_operand (rtx op, int size, enum h8300_operand_class *opclass) { enum h8300_operand_class dummy; if (opclass == 0) opclass = &dummy; if (CONSTANT_P (op)) { *opclass = H8OP_IMMEDIATE; /* Byte-sized immediates are stored in the opcode fields. */ if (size == 1) return 0; /* If this is a 32-bit instruction, see whether the constant will fit into a 16-bit immediate field. */ if (TARGET_H8300SX && size == 4 && GET_CODE (op) == CONST_INT && IN_RANGE (INTVAL (op), 0, 0xffff)) return 2; return size; } else if (GET_CODE (op) == MEM) { op = XEXP (op, 0); if (CONSTANT_P (op)) { *opclass = H8OP_MEM_ABSOLUTE; return h8300_constant_length (op); } else if (GET_CODE (op) == PLUS && CONSTANT_P (XEXP (op, 1))) { *opclass = H8OP_MEM_COMPLEX; return h8300_displacement_length (op, size); } else if (GET_RTX_CLASS (GET_CODE (op)) == RTX_AUTOINC) { *opclass = H8OP_MEM_COMPLEX; return 0; } else if (register_operand (op, VOIDmode)) { *opclass = H8OP_MEM_BASE; return 0; } } gcc_assert (register_operand (op, VOIDmode)); *opclass = H8OP_REGISTER; return 0; } /* Return the length of the instruction described by TABLE given that its operands are OP1 and OP2. OP1 must be an h8300_dst_operand and OP2 must be an h8300_src_operand. */ static unsigned int h8300_length_from_table (rtx op1, rtx op2, const h8300_length_table *table) { enum h8300_operand_class op1_class, op2_class; unsigned int size, immediate_length; size = GET_MODE_SIZE (GET_MODE (op1)); immediate_length = (h8300_classify_operand (op1, size, &op1_class) + h8300_classify_operand (op2, size, &op2_class)); return immediate_length + (*table)[op1_class - 1][op2_class]; } /* Return the length of a unary instruction such as neg or not given that its operand is OP. */ unsigned int h8300_unary_length (rtx op) { enum h8300_operand_class opclass; unsigned int size, operand_length; size = GET_MODE_SIZE (GET_MODE (op)); operand_length = h8300_classify_operand (op, size, &opclass); switch (opclass) { case H8OP_REGISTER: return 2; case H8OP_MEM_BASE: return (size == 4 ? 6 : 4); case H8OP_MEM_ABSOLUTE: return operand_length + (size == 4 ? 6 : 4); case H8OP_MEM_COMPLEX: return operand_length + 6; default: gcc_unreachable (); } } /* Likewise short immediate instructions such as add.w #xx:3,OP. */ static unsigned int h8300_short_immediate_length (rtx op) { enum h8300_operand_class opclass; unsigned int size, operand_length; size = GET_MODE_SIZE (GET_MODE (op)); operand_length = h8300_classify_operand (op, size, &opclass); switch (opclass) { case H8OP_REGISTER: return 2; case H8OP_MEM_BASE: case H8OP_MEM_ABSOLUTE: case H8OP_MEM_COMPLEX: return 4 + operand_length; default: gcc_unreachable (); } } /* Likewise bitfield load and store instructions. */ static unsigned int h8300_bitfield_length (rtx op, rtx op2) { enum h8300_operand_class opclass; unsigned int size, operand_length; if (GET_CODE (op) == REG) op = op2; gcc_assert (GET_CODE (op) != REG); size = GET_MODE_SIZE (GET_MODE (op)); operand_length = h8300_classify_operand (op, size, &opclass); switch (opclass) { case H8OP_MEM_BASE: case H8OP_MEM_ABSOLUTE: case H8OP_MEM_COMPLEX: return 4 + operand_length; default: gcc_unreachable (); } } /* Calculate the length of general binary instruction INSN using TABLE. */ static unsigned int h8300_binary_length (rtx insn, const h8300_length_table *table) { rtx set; set = single_set (insn); gcc_assert (set); if (BINARY_P (SET_SRC (set))) return h8300_length_from_table (XEXP (SET_SRC (set), 0), XEXP (SET_SRC (set), 1), table); else { gcc_assert (GET_RTX_CLASS (GET_CODE (SET_SRC (set))) == RTX_TERNARY); return h8300_length_from_table (XEXP (XEXP (SET_SRC (set), 1), 0), XEXP (XEXP (SET_SRC (set), 1), 1), table); } } /* Subroutine of h8300_move_length. Return true if OP is 1- or 2-byte memory reference and either (1) it has the form @(d:16,Rn) or (2) its address has the code given by INC_CODE. */ static bool h8300_short_move_mem_p (rtx op, enum rtx_code inc_code) { rtx addr; unsigned int size; if (GET_CODE (op) != MEM) return false; addr = XEXP (op, 0); size = GET_MODE_SIZE (GET_MODE (op)); if (size != 1 && size != 2) return false; return (GET_CODE (addr) == inc_code || (GET_CODE (addr) == PLUS && GET_CODE (XEXP (addr, 0)) == REG && h8300_displacement_length (addr, size) == 2)); } /* Calculate the length of move instruction INSN using the given length table. Although the tables are correct for most cases, there is some irregularity in the length of mov.b and mov.w. The following forms: mov @ERs+, Rd mov @(d:16,ERs), Rd mov Rs, @-ERd mov Rs, @(d:16,ERd) are two bytes shorter than most other "mov Rs, @complex" or "mov @complex,Rd" combinations. */ static unsigned int h8300_move_length (rtx *operands, const h8300_length_table *table) { unsigned int size; size = h8300_length_from_table (operands[0], operands[1], table); if (REG_P (operands[0]) && h8300_short_move_mem_p (operands[1], POST_INC)) size -= 2; if (REG_P (operands[1]) && h8300_short_move_mem_p (operands[0], PRE_DEC)) size -= 2; return size; } /* Return the length of a mova instruction with the given operands. DEST is the register destination, SRC is the source address and OFFSET is the 16-bit or 32-bit displacement. */ static unsigned int h8300_mova_length (rtx dest, rtx src, rtx offset) { unsigned int size; size = (2 + h8300_constant_length (offset) + h8300_classify_operand (src, GET_MODE_SIZE (GET_MODE (src)), 0)); if (!REG_P (dest) || !REG_P (src) || REGNO (src) != REGNO (dest)) size += 2; return size; } /* Compute the length of INSN based on its length_table attribute. OPERANDS is the array of its operands. */ unsigned int h8300_insn_length_from_table (rtx insn, rtx * operands) { switch (get_attr_length_table (insn)) { case LENGTH_TABLE_NONE: gcc_unreachable (); case LENGTH_TABLE_ADDB: return h8300_binary_length (insn, &addb_length_table); case LENGTH_TABLE_ADDW: return h8300_binary_length (insn, &addw_length_table); case LENGTH_TABLE_ADDL: return h8300_binary_length (insn, &addl_length_table); case LENGTH_TABLE_LOGICB: return h8300_binary_length (insn, &logicb_length_table); case LENGTH_TABLE_MOVB: return h8300_move_length (operands, &movb_length_table); case LENGTH_TABLE_MOVW: return h8300_move_length (operands, &movw_length_table); case LENGTH_TABLE_MOVL: return h8300_move_length (operands, &movl_length_table); case LENGTH_TABLE_MOVA: return h8300_mova_length (operands[0], operands[1], operands[2]); case LENGTH_TABLE_MOVA_ZERO: return h8300_mova_length (operands[0], operands[1], const0_rtx); case LENGTH_TABLE_UNARY: return h8300_unary_length (operands[0]); case LENGTH_TABLE_MOV_IMM4: return 2 + h8300_classify_operand (operands[0], 0, 0); case LENGTH_TABLE_SHORT_IMMEDIATE: return h8300_short_immediate_length (operands[0]); case LENGTH_TABLE_BITFIELD: return h8300_bitfield_length (operands[0], operands[1]); case LENGTH_TABLE_BITBRANCH: return h8300_bitfield_length (operands[1], operands[2]) - 2; default: gcc_unreachable (); } } /* Return true if LHS and RHS are memory references that can be mapped to the same h8sx assembly operand. LHS appears as the destination of an instruction and RHS appears as a source. Three cases are allowed: - RHS is @+Rn or @-Rn, LHS is @Rn - RHS is @Rn, LHS is @Rn+ or @Rn- - RHS and LHS have the same address and neither has side effects. */ bool h8sx_mergeable_memrefs_p (rtx lhs, rtx rhs) { if (GET_CODE (rhs) == MEM && GET_CODE (lhs) == MEM) { rhs = XEXP (rhs, 0); lhs = XEXP (lhs, 0); if (GET_CODE (rhs) == PRE_INC || GET_CODE (rhs) == PRE_DEC) return rtx_equal_p (XEXP (rhs, 0), lhs); if (GET_CODE (lhs) == POST_INC || GET_CODE (lhs) == POST_DEC) return rtx_equal_p (rhs, XEXP (lhs, 0)); if (rtx_equal_p (rhs, lhs)) return true; } return false; } /* Return true if OPERANDS[1] can be mapped to the same assembly operand as OPERANDS[0]. */ bool h8300_operands_match_p (rtx *operands) { if (register_operand (operands[0], VOIDmode) && register_operand (operands[1], VOIDmode)) return true; if (h8sx_mergeable_memrefs_p (operands[0], operands[1])) return true; return false; } /* Try using movmd to move LENGTH bytes from memory region SRC to memory region DEST. The two regions do not overlap and have the common alignment given by ALIGNMENT. Return true on success. Using movmd for variable-length moves seems to involve some complex trade-offs. For instance: - Preparing for a movmd instruction is similar to preparing for a memcpy. The main difference is that the arguments are moved into er4, er5 and er6 rather than er0, er1 and er2. - Since movmd clobbers the frame pointer, we need to save and restore it somehow when frame_pointer_needed. This can sometimes make movmd sequences longer than calls to memcpy(). - The counter register is 16 bits, so the instruction is only suitable for variable-length moves when sizeof (size_t) == 2. That's only true in normal mode. - We will often lack static alignment information. Falling back on movmd.b would likely be slower than calling memcpy(), at least for big moves. This function therefore only uses movmd when the length is a known constant, and only then if -fomit-frame-pointer is in effect or if we're not optimizing for size. At the moment the function uses movmd for all in-range constants, but it might be better to fall back on memcpy() for large moves if ALIGNMENT == 1. */ bool h8sx_emit_movmd (rtx dest, rtx src, rtx length, HOST_WIDE_INT alignment) { if (!flag_omit_frame_pointer && optimize_size) return false; if (GET_CODE (length) == CONST_INT) { rtx dest_reg, src_reg, first_dest, first_src; HOST_WIDE_INT n; int factor; /* Use movmd.l if the alignment allows it, otherwise fall back on movmd.b. */ factor = (alignment >= 2 ? 4 : 1); /* Make sure the length is within range. We can handle counter values up to 65536, although HImode truncation will make the count appear negative in rtl dumps. */ n = INTVAL (length); if (n <= 0 || n / factor > 65536) return false; /* Create temporary registers for the source and destination pointers. Initialize them to the start of each region. */ dest_reg = copy_addr_to_reg (XEXP (dest, 0)); src_reg = copy_addr_to_reg (XEXP (src, 0)); /* Create references to the movmd source and destination blocks. */ first_dest = replace_equiv_address (dest, dest_reg); first_src = replace_equiv_address (src, src_reg); set_mem_size (first_dest, n & -factor); set_mem_size (first_src, n & -factor); length = copy_to_mode_reg (HImode, gen_int_mode (n / factor, HImode)); emit_insn (gen_movmd (first_dest, first_src, length, GEN_INT (factor))); if ((n & -factor) != n) { /* Move SRC and DEST past the region we just copied. This is done to update the memory attributes. */ dest = adjust_address (dest, BLKmode, n & -factor); src = adjust_address (src, BLKmode, n & -factor); /* Replace the addresses with the source and destination registers, which movmd has left with the right values. */ dest = replace_equiv_address (dest, dest_reg); src = replace_equiv_address (src, src_reg); /* Mop up the left-over bytes. */ if (n & 2) emit_move_insn (adjust_address (dest, HImode, 0), adjust_address (src, HImode, 0)); if (n & 1) emit_move_insn (adjust_address (dest, QImode, n & 2), adjust_address (src, QImode, n & 2)); } return true; } return false; } /* Move ADDR into er6 after pushing its old value onto the stack. */ void h8300_swap_into_er6 (rtx addr) { rtx insn = push (HARD_FRAME_POINTER_REGNUM); if (frame_pointer_needed) add_reg_note (insn, REG_CFA_DEF_CFA, plus_constant (gen_rtx_MEM (Pmode, stack_pointer_rtx), 2 * UNITS_PER_WORD)); else add_reg_note (insn, REG_CFA_ADJUST_CFA, gen_rtx_SET (VOIDmode, stack_pointer_rtx, plus_constant (stack_pointer_rtx, 4))); emit_move_insn (hard_frame_pointer_rtx, addr); if (REGNO (addr) == SP_REG) emit_move_insn (hard_frame_pointer_rtx, plus_constant (hard_frame_pointer_rtx, GET_MODE_SIZE (word_mode))); } /* Move the current value of er6 into ADDR and pop its old value from the stack. */ void h8300_swap_out_of_er6 (rtx addr) { rtx insn; if (REGNO (addr) != SP_REG) emit_move_insn (addr, hard_frame_pointer_rtx); insn = pop (HARD_FRAME_POINTER_REGNUM); RTX_FRAME_RELATED_P (insn) = 1; if (frame_pointer_needed) add_reg_note (insn, REG_CFA_DEF_CFA, plus_constant (hard_frame_pointer_rtx, 2 * UNITS_PER_WORD)); else add_reg_note (insn, REG_CFA_ADJUST_CFA, gen_rtx_SET (VOIDmode, stack_pointer_rtx, plus_constant (stack_pointer_rtx, -4))); } /* Return the length of mov instruction. */ unsigned int compute_mov_length (rtx *operands) { /* If the mov instruction involves a memory operand, we compute the length, assuming the largest addressing mode is used, and then adjust later in the function. Otherwise, we compute and return the exact length in one step. */ enum machine_mode mode = GET_MODE (operands[0]); rtx dest = operands[0]; rtx src = operands[1]; rtx addr; if (GET_CODE (src) == MEM) addr = XEXP (src, 0); else if (GET_CODE (dest) == MEM) addr = XEXP (dest, 0); else addr = NULL_RTX; if (TARGET_H8300) { unsigned int base_length; switch (mode) { case QImode: if (addr == NULL_RTX) return 2; /* The eightbit addressing is available only in QImode, so go ahead and take care of it. */ if (h8300_eightbit_constant_address_p (addr)) return 2; base_length = 4; break; case HImode: if (addr == NULL_RTX) { if (REG_P (src)) return 2; if (src == const0_rtx) return 2; return 4; } base_length = 4; break; case SImode: if (addr == NULL_RTX) { if (REG_P (src)) return 4; if (GET_CODE (src) == CONST_INT) { if (src == const0_rtx) return 4; if ((INTVAL (src) & 0xffff) == 0) return 6; if ((INTVAL (src) & 0xffff) == 0) return 6; if ((INTVAL (src) & 0xffff) == ((INTVAL (src) >> 16) & 0xffff)) return 6; } return 8; } base_length = 8; break; case SFmode: if (addr == NULL_RTX) { if (REG_P (src)) return 4; if (satisfies_constraint_G (src)) return 4; return 8; } base_length = 8; break; default: gcc_unreachable (); } /* Adjust the length based on the addressing mode used. Specifically, we subtract the difference between the actual length and the longest one, which is @(d:16,Rs). For SImode and SFmode, we double the adjustment because two mov.w are used to do the job. */ /* @Rs+ and @-Rd are 2 bytes shorter than the longest. */ if (GET_CODE (addr) == PRE_DEC || GET_CODE (addr) == POST_INC) { if (mode == QImode || mode == HImode) return base_length - 2; else /* In SImode and SFmode, we use two mov.w instructions, so double the adjustment. */ return base_length - 4; } /* @Rs and @Rd are 2 bytes shorter than the longest. Note that in SImode and SFmode, the second mov.w involves an address with displacement, namely @(2,Rs) or @(2,Rd), so we subtract only 2 bytes. */ if (GET_CODE (addr) == REG) return base_length - 2; return base_length; } else { unsigned int base_length; switch (mode) { case QImode: if (addr == NULL_RTX) return 2; /* The eightbit addressing is available only in QImode, so go ahead and take care of it. */ if (h8300_eightbit_constant_address_p (addr)) return 2; base_length = 8; break; case HImode: if (addr == NULL_RTX) { if (REG_P (src)) return 2; if (src == const0_rtx) return 2; return 4; } base_length = 8; break; case SImode: if (addr == NULL_RTX) { if (REG_P (src)) { if (REGNO (src) == MAC_REG || REGNO (dest) == MAC_REG) return 4; else return 2; } if (GET_CODE (src) == CONST_INT) { int val = INTVAL (src); if (val == 0) return 2; if (val == (val & 0x00ff) || val == (val & 0xff00)) return 4; switch (val & 0xffffffff) { case 0xffffffff: case 0xfffffffe: case 0xfffffffc: case 0x0000ffff: case 0x0000fffe: case 0xffff0000: case 0xfffe0000: case 0x00010000: case 0x00020000: return 4; } } return 6; } base_length = 10; break; case SFmode: if (addr == NULL_RTX) { if (REG_P (src)) return 2; if (satisfies_constraint_G (src)) return 2; return 6; } base_length = 10; break; default: gcc_unreachable (); } /* Adjust the length based on the addressing mode used. Specifically, we subtract the difference between the actual length and the longest one, which is @(d:24,ERs). */ /* @ERs+ and @-ERd are 6 bytes shorter than the longest. */ if (GET_CODE (addr) == PRE_DEC || GET_CODE (addr) == POST_INC) return base_length - 6; /* @ERs and @ERd are 6 bytes shorter than the longest. */ if (GET_CODE (addr) == REG) return base_length - 6; /* @(d:16,ERs) and @(d:16,ERd) are 4 bytes shorter than the longest. */ if (GET_CODE (addr) == PLUS && GET_CODE (XEXP (addr, 0)) == REG && GET_CODE (XEXP (addr, 1)) == CONST_INT && INTVAL (XEXP (addr, 1)) > -32768 && INTVAL (XEXP (addr, 1)) < 32767) return base_length - 4; /* @aa:16 is 4 bytes shorter than the longest. */ if (h8300_tiny_constant_address_p (addr)) return base_length - 4; /* @aa:24 is 2 bytes shorter than the longest. */ if (CONSTANT_P (addr)) return base_length - 2; return base_length; } } /* Output an addition insn. */ const char * output_plussi (rtx *operands) { enum machine_mode mode = GET_MODE (operands[0]); gcc_assert (mode == SImode); if (TARGET_H8300) { if (GET_CODE (operands[2]) == REG) return "add.w\t%f2,%f0\n\taddx\t%y2,%y0\n\taddx\t%z2,%z0"; if (GET_CODE (operands[2]) == CONST_INT) { HOST_WIDE_INT n = INTVAL (operands[2]); if ((n & 0xffffff) == 0) return "add\t%z2,%z0"; if ((n & 0xffff) == 0) return "add\t%y2,%y0\n\taddx\t%z2,%z0"; if ((n & 0xff) == 0) return "add\t%x2,%x0\n\taddx\t%y2,%y0\n\taddx\t%z2,%z0"; } return "add\t%w2,%w0\n\taddx\t%x2,%x0\n\taddx\t%y2,%y0\n\taddx\t%z2,%z0"; } else { if (GET_CODE (operands[2]) == CONST_INT && register_operand (operands[1], VOIDmode)) { HOST_WIDE_INT intval = INTVAL (operands[2]); if (TARGET_H8300SX && (intval >= 1 && intval <= 7)) return "add.l\t%S2,%S0"; if (TARGET_H8300SX && (intval >= -7 && intval <= -1)) return "sub.l\t%G2,%S0"; /* See if we can finish with 2 bytes. */ switch ((unsigned int) intval & 0xffffffff) { case 0x00000001: case 0x00000002: case 0x00000004: return "adds\t%2,%S0"; case 0xffffffff: case 0xfffffffe: case 0xfffffffc: return "subs\t%G2,%S0"; case 0x00010000: case 0x00020000: operands[2] = GEN_INT (intval >> 16); return "inc.w\t%2,%e0"; case 0xffff0000: case 0xfffe0000: operands[2] = GEN_INT (intval >> 16); return "dec.w\t%G2,%e0"; } /* See if we can finish with 4 bytes. */ if ((intval & 0xffff) == 0) { operands[2] = GEN_INT (intval >> 16); return "add.w\t%2,%e0"; } } if (GET_CODE (operands[2]) == CONST_INT && INTVAL (operands[2]) < 0) { operands[2] = GEN_INT (-INTVAL (operands[2])); return "sub.l\t%S2,%S0"; } return "add.l\t%S2,%S0"; } } /* ??? It would be much easier to add the h8sx stuff if a single function classified the addition as either inc/dec, adds/subs, add.w or add.l. */ /* Compute the length of an addition insn. */ unsigned int compute_plussi_length (rtx *operands) { enum machine_mode mode = GET_MODE (operands[0]); gcc_assert (mode == SImode); if (TARGET_H8300) { if (GET_CODE (operands[2]) == REG) return 6; if (GET_CODE (operands[2]) == CONST_INT) { HOST_WIDE_INT n = INTVAL (operands[2]); if ((n & 0xffffff) == 0) return 2; if ((n & 0xffff) == 0) return 4; if ((n & 0xff) == 0) return 6; } return 8; } else { if (GET_CODE (operands[2]) == CONST_INT && register_operand (operands[1], VOIDmode)) { HOST_WIDE_INT intval = INTVAL (operands[2]); if (TARGET_H8300SX && (intval >= 1 && intval <= 7)) return 2; if (TARGET_H8300SX && (intval >= -7 && intval <= -1)) return 2; /* See if we can finish with 2 bytes. */ switch ((unsigned int) intval & 0xffffffff) { case 0x00000001: case 0x00000002: case 0x00000004: return 2; case 0xffffffff: case 0xfffffffe: case 0xfffffffc: return 2; case 0x00010000: case 0x00020000: return 2; case 0xffff0000: case 0xfffe0000: return 2; } /* See if we can finish with 4 bytes. */ if ((intval & 0xffff) == 0) return 4; } if (GET_CODE (operands[2]) == CONST_INT && INTVAL (operands[2]) < 0) return h8300_length_from_table (operands[0], GEN_INT (-INTVAL (operands[2])), &addl_length_table); else return h8300_length_from_table (operands[0], operands[2], &addl_length_table); return 6; } } /* Compute which flag bits are valid after an addition insn. */ enum attr_cc compute_plussi_cc (rtx *operands) { enum machine_mode mode = GET_MODE (operands[0]); gcc_assert (mode == SImode); if (TARGET_H8300) { return CC_CLOBBER; } else { if (GET_CODE (operands[2]) == CONST_INT && register_operand (operands[1], VOIDmode)) { HOST_WIDE_INT intval = INTVAL (operands[2]); if (TARGET_H8300SX && (intval >= 1 && intval <= 7)) return CC_SET_ZN; if (TARGET_H8300SX && (intval >= -7 && intval <= -1)) return CC_SET_ZN; /* See if we can finish with 2 bytes. */ switch ((unsigned int) intval & 0xffffffff) { case 0x00000001: case 0x00000002: case 0x00000004: return CC_NONE_0HIT; case 0xffffffff: case 0xfffffffe: case 0xfffffffc: return CC_NONE_0HIT; case 0x00010000: case 0x00020000: return CC_CLOBBER; case 0xffff0000: case 0xfffe0000: return CC_CLOBBER; } /* See if we can finish with 4 bytes. */ if ((intval & 0xffff) == 0) return CC_CLOBBER; } return CC_SET_ZN; } } /* Output a logical insn. */ const char * output_logical_op (enum machine_mode mode, rtx *operands) { /* Figure out the logical op that we need to perform. */ enum rtx_code code = GET_CODE (operands[3]); /* Pretend that every byte is affected if both operands are registers. */ const unsigned HOST_WIDE_INT intval = (unsigned HOST_WIDE_INT) ((GET_CODE (operands[2]) == CONST_INT) /* Always use the full instruction if the first operand is in memory. It is better to use define_splits to generate the shorter sequence where valid. */ && register_operand (operands[1], VOIDmode) ? INTVAL (operands[2]) : 0x55555555); /* The determinant of the algorithm. If we perform an AND, 0 affects a bit. Otherwise, 1 affects a bit. */ const unsigned HOST_WIDE_INT det = (code != AND) ? intval : ~intval; /* Break up DET into pieces. */ const unsigned HOST_WIDE_INT b0 = (det >> 0) & 0xff; const unsigned HOST_WIDE_INT b1 = (det >> 8) & 0xff; const unsigned HOST_WIDE_INT b2 = (det >> 16) & 0xff; const unsigned HOST_WIDE_INT b3 = (det >> 24) & 0xff; const unsigned HOST_WIDE_INT w0 = (det >> 0) & 0xffff; const unsigned HOST_WIDE_INT w1 = (det >> 16) & 0xffff; int lower_half_easy_p = 0; int upper_half_easy_p = 0; /* The name of an insn. */ const char *opname; char insn_buf[100]; switch (code) { case AND: opname = "and"; break; case IOR: opname = "or"; break; case XOR: opname = "xor"; break; default: gcc_unreachable (); } switch (mode) { case HImode: /* First, see if we can finish with one insn. */ if ((TARGET_H8300H || TARGET_H8300S) && b0 != 0 && b1 != 0) { sprintf (insn_buf, "%s.w\t%%T2,%%T0", opname); output_asm_insn (insn_buf, operands); } else { /* Take care of the lower byte. */ if (b0 != 0) { sprintf (insn_buf, "%s\t%%s2,%%s0", opname); output_asm_insn (insn_buf, operands); } /* Take care of the upper byte. */ if (b1 != 0) { sprintf (insn_buf, "%s\t%%t2,%%t0", opname); output_asm_insn (insn_buf, operands); } } break; case SImode: if (TARGET_H8300H || TARGET_H8300S) { /* Determine if the lower half can be taken care of in no more than two bytes. */ lower_half_easy_p = (b0 == 0 || b1 == 0 || (code != IOR && w0 == 0xffff)); /* Determine if the upper half can be taken care of in no more than two bytes. */ upper_half_easy_p = ((code != IOR && w1 == 0xffff) || (code == AND && w1 == 0xff00)); } /* Check if doing everything with one insn is no worse than using multiple insns. */ if ((TARGET_H8300H || TARGET_H8300S) && w0 != 0 && w1 != 0 && !(lower_half_easy_p && upper_half_easy_p) && !(code == IOR && w1 == 0xffff && (w0 & 0x8000) != 0 && lower_half_easy_p)) { sprintf (insn_buf, "%s.l\t%%S2,%%S0", opname); output_asm_insn (insn_buf, operands); } else { /* Take care of the lower and upper words individually. For each word, we try different methods in the order of 1) the special insn (in case of AND or XOR), 2) the word-wise insn, and 3) The byte-wise insn. */ if (w0 == 0xffff && (TARGET_H8300 ? (code == AND) : (code != IOR))) output_asm_insn ((code == AND) ? "sub.w\t%f0,%f0" : "not.w\t%f0", operands); else if ((TARGET_H8300H || TARGET_H8300S) && (b0 != 0) && (b1 != 0)) { sprintf (insn_buf, "%s.w\t%%f2,%%f0", opname); output_asm_insn (insn_buf, operands); } else { if (b0 != 0) { sprintf (insn_buf, "%s\t%%w2,%%w0", opname); output_asm_insn (insn_buf, operands); } if (b1 != 0) { sprintf (insn_buf, "%s\t%%x2,%%x0", opname); output_asm_insn (insn_buf, operands); } } if ((w1 == 0xffff) && (TARGET_H8300 ? (code == AND) : (code != IOR))) output_asm_insn ((code == AND) ? "sub.w\t%e0,%e0" : "not.w\t%e0", operands); else if ((TARGET_H8300H || TARGET_H8300S) && code == IOR && w1 == 0xffff && (w0 & 0x8000) != 0) { output_asm_insn ("exts.l\t%S0", operands); } else if ((TARGET_H8300H || TARGET_H8300S) && code == AND && w1 == 0xff00) { output_asm_insn ("extu.w\t%e0", operands); } else if (TARGET_H8300H || TARGET_H8300S) { if (w1 != 0) { sprintf (insn_buf, "%s.w\t%%e2,%%e0", opname); output_asm_insn (insn_buf, operands); } } else { if (b2 != 0) { sprintf (insn_buf, "%s\t%%y2,%%y0", opname); output_asm_insn (insn_buf, operands); } if (b3 != 0) { sprintf (insn_buf, "%s\t%%z2,%%z0", opname); output_asm_insn (insn_buf, operands); } } } break; default: gcc_unreachable (); } return ""; } /* Compute the length of a logical insn. */ unsigned int compute_logical_op_length (enum machine_mode mode, rtx *operands) { /* Figure out the logical op that we need to perform. */ enum rtx_code code = GET_CODE (operands[3]); /* Pretend that every byte is affected if both operands are registers. */ const unsigned HOST_WIDE_INT intval = (unsigned HOST_WIDE_INT) ((GET_CODE (operands[2]) == CONST_INT) /* Always use the full instruction if the first operand is in memory. It is better to use define_splits to generate the shorter sequence where valid. */ && register_operand (operands[1], VOIDmode) ? INTVAL (operands[2]) : 0x55555555); /* The determinant of the algorithm. If we perform an AND, 0 affects a bit. Otherwise, 1 affects a bit. */ const unsigned HOST_WIDE_INT det = (code != AND) ? intval : ~intval; /* Break up DET into pieces. */ const unsigned HOST_WIDE_INT b0 = (det >> 0) & 0xff; const unsigned HOST_WIDE_INT b1 = (det >> 8) & 0xff; const unsigned HOST_WIDE_INT b2 = (det >> 16) & 0xff; const unsigned HOST_WIDE_INT b3 = (det >> 24) & 0xff; const unsigned HOST_WIDE_INT w0 = (det >> 0) & 0xffff; const unsigned HOST_WIDE_INT w1 = (det >> 16) & 0xffff; int lower_half_easy_p = 0; int upper_half_easy_p = 0; /* Insn length. */ unsigned int length = 0; switch (mode) { case HImode: /* First, see if we can finish with one insn. */ if ((TARGET_H8300H || TARGET_H8300S) && b0 != 0 && b1 != 0) { length = h8300_length_from_table (operands[1], operands[2], &logicw_length_table); } else { /* Take care of the lower byte. */ if (b0 != 0) length += 2; /* Take care of the upper byte. */ if (b1 != 0) length += 2; } break; case SImode: if (TARGET_H8300H || TARGET_H8300S) { /* Determine if the lower half can be taken care of in no more than two bytes. */ lower_half_easy_p = (b0 == 0 || b1 == 0 || (code != IOR && w0 == 0xffff)); /* Determine if the upper half can be taken care of in no more than two bytes. */ upper_half_easy_p = ((code != IOR && w1 == 0xffff) || (code == AND && w1 == 0xff00)); } /* Check if doing everything with one insn is no worse than using multiple insns. */ if ((TARGET_H8300H || TARGET_H8300S) && w0 != 0 && w1 != 0 && !(lower_half_easy_p && upper_half_easy_p) && !(code == IOR && w1 == 0xffff && (w0 & 0x8000) != 0 && lower_half_easy_p)) { length = h8300_length_from_table (operands[1], operands[2], &logicl_length_table); } else { /* Take care of the lower and upper words individually. For each word, we try different methods in the order of 1) the special insn (in case of AND or XOR), 2) the word-wise insn, and 3) The byte-wise insn. */ if (w0 == 0xffff && (TARGET_H8300 ? (code == AND) : (code != IOR))) { length += 2; } else if ((TARGET_H8300H || TARGET_H8300S) && (b0 != 0) && (b1 != 0)) { length += 4; } else { if (b0 != 0) length += 2; if (b1 != 0) length += 2; } if (w1 == 0xffff && (TARGET_H8300 ? (code == AND) : (code != IOR))) { length += 2; } else if ((TARGET_H8300H || TARGET_H8300S) && code == IOR && w1 == 0xffff && (w0 & 0x8000) != 0) { length += 2; } else if ((TARGET_H8300H || TARGET_H8300S) && code == AND && w1 == 0xff00) { length += 2; } else if (TARGET_H8300H || TARGET_H8300S) { if (w1 != 0) length += 4; } else { if (b2 != 0) length += 2; if (b3 != 0) length += 2; } } break; default: gcc_unreachable (); } return length; } /* Compute which flag bits are valid after a logical insn. */ enum attr_cc compute_logical_op_cc (enum machine_mode mode, rtx *operands) { /* Figure out the logical op that we need to perform. */ enum rtx_code code = GET_CODE (operands[3]); /* Pretend that every byte is affected if both operands are registers. */ const unsigned HOST_WIDE_INT intval = (unsigned HOST_WIDE_INT) ((GET_CODE (operands[2]) == CONST_INT) /* Always use the full instruction if the first operand is in memory. It is better to use define_splits to generate the shorter sequence where valid. */ && register_operand (operands[1], VOIDmode) ? INTVAL (operands[2]) : 0x55555555); /* The determinant of the algorithm. If we perform an AND, 0 affects a bit. Otherwise, 1 affects a bit. */ const unsigned HOST_WIDE_INT det = (code != AND) ? intval : ~intval; /* Break up DET into pieces. */ const unsigned HOST_WIDE_INT b0 = (det >> 0) & 0xff; const unsigned HOST_WIDE_INT b1 = (det >> 8) & 0xff; const unsigned HOST_WIDE_INT w0 = (det >> 0) & 0xffff; const unsigned HOST_WIDE_INT w1 = (det >> 16) & 0xffff; int lower_half_easy_p = 0; int upper_half_easy_p = 0; /* Condition code. */ enum attr_cc cc = CC_CLOBBER; switch (mode) { case HImode: /* First, see if we can finish with one insn. */ if ((TARGET_H8300H || TARGET_H8300S) && b0 != 0 && b1 != 0) { cc = CC_SET_ZNV; } break; case SImode: if (TARGET_H8300H || TARGET_H8300S) { /* Determine if the lower half can be taken care of in no more than two bytes. */ lower_half_easy_p = (b0 == 0 || b1 == 0 || (code != IOR && w0 == 0xffff)); /* Determine if the upper half can be taken care of in no more than two bytes. */ upper_half_easy_p = ((code != IOR && w1 == 0xffff) || (code == AND && w1 == 0xff00)); } /* Check if doing everything with one insn is no worse than using multiple insns. */ if ((TARGET_H8300H || TARGET_H8300S) && w0 != 0 && w1 != 0 && !(lower_half_easy_p && upper_half_easy_p) && !(code == IOR && w1 == 0xffff && (w0 & 0x8000) != 0 && lower_half_easy_p)) { cc = CC_SET_ZNV; } else { if ((TARGET_H8300H || TARGET_H8300S) && code == IOR && w1 == 0xffff && (w0 & 0x8000) != 0) { cc = CC_SET_ZNV; } } break; default: gcc_unreachable (); } return cc; } /* Expand a conditional branch. */ void h8300_expand_branch (rtx operands[]) { enum rtx_code code = GET_CODE (operands[0]); rtx op0 = operands[1]; rtx op1 = operands[2]; rtx label = operands[3]; rtx tmp; tmp = gen_rtx_COMPARE (VOIDmode, op0, op1); emit_insn (gen_rtx_SET (VOIDmode, cc0_rtx, tmp)); tmp = gen_rtx_fmt_ee (code, VOIDmode, cc0_rtx, const0_rtx); tmp = gen_rtx_IF_THEN_ELSE (VOIDmode, tmp, gen_rtx_LABEL_REF (VOIDmode, label), pc_rtx); emit_jump_insn (gen_rtx_SET (VOIDmode, pc_rtx, tmp)); } /* Expand a conditional store. */ void h8300_expand_store (rtx operands[]) { rtx dest = operands[0]; enum rtx_code code = GET_CODE (operands[1]); rtx op0 = operands[2]; rtx op1 = operands[3]; rtx tmp; tmp = gen_rtx_COMPARE (VOIDmode, op0, op1); emit_insn (gen_rtx_SET (VOIDmode, cc0_rtx, tmp)); tmp = gen_rtx_fmt_ee (code, GET_MODE (dest), cc0_rtx, const0_rtx); emit_insn (gen_rtx_SET (VOIDmode, dest, tmp)); } /* Shifts. We devote a fair bit of code to getting efficient shifts since we can only shift one bit at a time on the H8/300 and H8/300H and only one or two bits at a time on the H8S. All shift code falls into one of the following ways of implementation: o SHIFT_INLINE: Emit straight line code for the shift; this is used when a straight line shift is about the same size or smaller than a loop. o SHIFT_ROT_AND: Rotate the value the opposite direction, then mask off the bits we don't need. This is used when only a few of the bits in the original value will survive in the shifted value. o SHIFT_SPECIAL: Often it's possible to move a byte or a word to simulate a shift by 8, 16, or 24 bits. Once moved, a few inline shifts can be added if the shift count is slightly more than 8 or 16. This case also includes other oddballs that are not worth explaining here. o SHIFT_LOOP: Emit a loop using one (or two on H8S) bit shifts. For each shift count, we try to use code that has no trade-off between code size and speed whenever possible. If the trade-off is unavoidable, we try to be reasonable. Specifically, the fastest version is one instruction longer than the shortest version, we take the fastest version. We also provide the use a way to switch back to the shortest version with -Os. For the details of the shift algorithms for various shift counts, refer to shift_alg_[qhs]i. */ /* Classify a shift with the given mode and code. OP is the shift amount. */ enum h8sx_shift_type h8sx_classify_shift (enum machine_mode mode, enum rtx_code code, rtx op) { if (!TARGET_H8300SX) return H8SX_SHIFT_NONE; switch (code) { case ASHIFT: case LSHIFTRT: /* Check for variable shifts (shll Rs,Rd and shlr Rs,Rd). */ if (GET_CODE (op) != CONST_INT) return H8SX_SHIFT_BINARY; /* Reject out-of-range shift amounts. */ if (INTVAL (op) <= 0 || INTVAL (op) >= GET_MODE_BITSIZE (mode)) return H8SX_SHIFT_NONE; /* Power-of-2 shifts are effectively unary operations. */ if (exact_log2 (INTVAL (op)) >= 0) return H8SX_SHIFT_UNARY; return H8SX_SHIFT_BINARY; case ASHIFTRT: if (op == const1_rtx || op == const2_rtx) return H8SX_SHIFT_UNARY; return H8SX_SHIFT_NONE; case ROTATE: if (GET_CODE (op) == CONST_INT && (INTVAL (op) == 1 || INTVAL (op) == 2 || INTVAL (op) == GET_MODE_BITSIZE (mode) - 2 || INTVAL (op) == GET_MODE_BITSIZE (mode) - 1)) return H8SX_SHIFT_UNARY; return H8SX_SHIFT_NONE; default: return H8SX_SHIFT_NONE; } } /* Return the asm template for a single h8sx shift instruction. OPERANDS[0] and OPERANDS[1] are the destination, OPERANDS[2] is the source and OPERANDS[3] is the shift. SUFFIX is the size suffix ('b', 'w' or 'l') and OPTYPE is the h8300_print_operand prefix for the destination operand. */ const char * output_h8sx_shift (rtx *operands, int suffix, int optype) { static char buffer[16]; const char *stem; switch (GET_CODE (operands[3])) { case ASHIFT: stem = "shll"; break; case ASHIFTRT: stem = "shar"; break; case LSHIFTRT: stem = "shlr"; break; case ROTATE: stem = "rotl"; if (INTVAL (operands[2]) > 2) { /* This is really a right rotate. */ operands[2] = GEN_INT (GET_MODE_BITSIZE (GET_MODE (operands[0])) - INTVAL (operands[2])); stem = "rotr"; } break; default: gcc_unreachable (); } if (operands[2] == const1_rtx) sprintf (buffer, "%s.%c\t%%%c0", stem, suffix, optype); else sprintf (buffer, "%s.%c\t%%X2,%%%c0", stem, suffix, optype); return buffer; } /* Emit code to do shifts. */ bool expand_a_shift (enum machine_mode mode, enum rtx_code code, rtx operands[]) { switch (h8sx_classify_shift (mode, code, operands[2])) { case H8SX_SHIFT_BINARY: operands[1] = force_reg (mode, operands[1]); return false; case H8SX_SHIFT_UNARY: return false; case H8SX_SHIFT_NONE: break; } emit_move_insn (copy_rtx (operands[0]), operands[1]); /* Need a loop to get all the bits we want - we generate the code at emit time, but need to allocate a scratch reg now. */ emit_insn (gen_rtx_PARALLEL (VOIDmode, gen_rtvec (2, gen_rtx_SET (VOIDmode, copy_rtx (operands[0]), gen_rtx_fmt_ee (code, mode, copy_rtx (operands[0]), operands[2])), gen_rtx_CLOBBER (VOIDmode, gen_rtx_SCRATCH (QImode))))); return true; } /* Symbols of the various modes which can be used as indices. */ enum shift_mode { QIshift, HIshift, SIshift }; /* For single bit shift insns, record assembler and what bits of the condition code are valid afterwards (represented as various CC_FOO bits, 0 means CC isn't left in a usable state). */ struct shift_insn { const char *const assembler; const enum attr_cc cc_valid; }; /* Assembler instruction shift table. These tables are used to look up the basic shifts. They are indexed by cpu, shift_type, and mode. */ static const struct shift_insn shift_one[2][3][3] = { /* H8/300 */ { /* SHIFT_ASHIFT */ { { "shll\t%X0", CC_SET_ZNV }, { "add.w\t%T0,%T0", CC_SET_ZN }, { "add.w\t%f0,%f0\n\taddx\t%y0,%y0\n\taddx\t%z0,%z0", CC_CLOBBER } }, /* SHIFT_LSHIFTRT */ { { "shlr\t%X0", CC_SET_ZNV }, { "shlr\t%t0\n\trotxr\t%s0", CC_CLOBBER }, { "shlr\t%z0\n\trotxr\t%y0\n\trotxr\t%x0\n\trotxr\t%w0", CC_CLOBBER } }, /* SHIFT_ASHIFTRT */ { { "shar\t%X0", CC_SET_ZNV }, { "shar\t%t0\n\trotxr\t%s0", CC_CLOBBER }, { "shar\t%z0\n\trotxr\t%y0\n\trotxr\t%x0\n\trotxr\t%w0", CC_CLOBBER } } }, /* H8/300H */ { /* SHIFT_ASHIFT */ { { "shll.b\t%X0", CC_SET_ZNV }, { "shll.w\t%T0", CC_SET_ZNV }, { "shll.l\t%S0", CC_SET_ZNV } }, /* SHIFT_LSHIFTRT */ { { "shlr.b\t%X0", CC_SET_ZNV }, { "shlr.w\t%T0", CC_SET_ZNV }, { "shlr.l\t%S0", CC_SET_ZNV } }, /* SHIFT_ASHIFTRT */ { { "shar.b\t%X0", CC_SET_ZNV }, { "shar.w\t%T0", CC_SET_ZNV }, { "shar.l\t%S0", CC_SET_ZNV } } } }; static const struct shift_insn shift_two[3][3] = { /* SHIFT_ASHIFT */ { { "shll.b\t#2,%X0", CC_SET_ZNV }, { "shll.w\t#2,%T0", CC_SET_ZNV }, { "shll.l\t#2,%S0", CC_SET_ZNV } }, /* SHIFT_LSHIFTRT */ { { "shlr.b\t#2,%X0", CC_SET_ZNV }, { "shlr.w\t#2,%T0", CC_SET_ZNV }, { "shlr.l\t#2,%S0", CC_SET_ZNV } }, /* SHIFT_ASHIFTRT */ { { "shar.b\t#2,%X0", CC_SET_ZNV }, { "shar.w\t#2,%T0", CC_SET_ZNV }, { "shar.l\t#2,%S0", CC_SET_ZNV } } }; /* Rotates are organized by which shift they'll be used in implementing. There's no need to record whether the cc is valid afterwards because it is the AND insn that will decide this. */ static const char *const rotate_one[2][3][3] = { /* H8/300 */ { /* SHIFT_ASHIFT */ { "rotr\t%X0", "shlr\t%t0\n\trotxr\t%s0\n\tbst\t#7,%t0", 0 }, /* SHIFT_LSHIFTRT */ { "rotl\t%X0", "shll\t%s0\n\trotxl\t%t0\n\tbst\t#0,%s0", 0 }, /* SHIFT_ASHIFTRT */ { "rotl\t%X0", "shll\t%s0\n\trotxl\t%t0\n\tbst\t#0,%s0", 0 } }, /* H8/300H */ { /* SHIFT_ASHIFT */ { "rotr.b\t%X0", "rotr.w\t%T0", "rotr.l\t%S0" }, /* SHIFT_LSHIFTRT */ { "rotl.b\t%X0", "rotl.w\t%T0", "rotl.l\t%S0" }, /* SHIFT_ASHIFTRT */ { "rotl.b\t%X0", "rotl.w\t%T0", "rotl.l\t%S0" } } }; static const char *const rotate_two[3][3] = { /* SHIFT_ASHIFT */ { "rotr.b\t#2,%X0", "rotr.w\t#2,%T0", "rotr.l\t#2,%S0" }, /* SHIFT_LSHIFTRT */ { "rotl.b\t#2,%X0", "rotl.w\t#2,%T0", "rotl.l\t#2,%S0" }, /* SHIFT_ASHIFTRT */ { "rotl.b\t#2,%X0", "rotl.w\t#2,%T0", "rotl.l\t#2,%S0" } }; struct shift_info { /* Shift algorithm. */ enum shift_alg alg; /* The number of bits to be shifted by shift1 and shift2. Valid when ALG is SHIFT_SPECIAL. */ unsigned int remainder; /* Special insn for a shift. Valid when ALG is SHIFT_SPECIAL. */ const char *special; /* Insn for a one-bit shift. Valid when ALG is either SHIFT_INLINE or SHIFT_SPECIAL, and REMAINDER is nonzero. */ const char *shift1; /* Insn for a two-bit shift. Valid when ALG is either SHIFT_INLINE or SHIFT_SPECIAL, and REMAINDER is nonzero. */ const char *shift2; /* CC status for SHIFT_INLINE. */ enum attr_cc cc_inline; /* CC status for SHIFT_SPECIAL. */ enum attr_cc cc_special; }; static void get_shift_alg (enum shift_type, enum shift_mode, unsigned int, struct shift_info *); /* Given SHIFT_TYPE, SHIFT_MODE, and shift count COUNT, determine the best algorithm for doing the shift. The assembler code is stored in the pointers in INFO. We achieve the maximum efficiency in most cases when !TARGET_H8300. In case of TARGET_H8300, shifts in SImode in particular have a lot of room to optimize. We first determine the strategy of the shift algorithm by a table lookup. If that tells us to use a hand crafted assembly code, we go into the big switch statement to find what that is. Otherwise, we resort to a generic way, such as inlining. In either case, the result is returned through INFO. */ static void get_shift_alg (enum shift_type shift_type, enum shift_mode shift_mode, unsigned int count, struct shift_info *info) { enum h8_cpu cpu; /* Find the target CPU. */ if (TARGET_H8300) cpu = H8_300; else if (TARGET_H8300H) cpu = H8_300H; else cpu = H8_S; /* Find the shift algorithm. */ info->alg = SHIFT_LOOP; switch (shift_mode) { case QIshift: if (count < GET_MODE_BITSIZE (QImode)) info->alg = shift_alg_qi[cpu][shift_type][count]; break; case HIshift: if (count < GET_MODE_BITSIZE (HImode)) info->alg = shift_alg_hi[cpu][shift_type][count]; break; case SIshift: if (count < GET_MODE_BITSIZE (SImode)) info->alg = shift_alg_si[cpu][shift_type][count]; break; default: gcc_unreachable (); } /* Fill in INFO. Return unless we have SHIFT_SPECIAL. */ switch (info->alg) { case SHIFT_INLINE: info->remainder = count; /* Fall through. */ case SHIFT_LOOP: /* It is up to the caller to know that looping clobbers cc. */ info->shift1 = shift_one[cpu_type][shift_type][shift_mode].assembler; info->shift2 = shift_two[shift_type][shift_mode].assembler; info->cc_inline = shift_one[cpu_type][shift_type][shift_mode].cc_valid; goto end; case SHIFT_ROT_AND: info->shift1 = rotate_one[cpu_type][shift_type][shift_mode]; info->shift2 = rotate_two[shift_type][shift_mode]; info->cc_inline = CC_CLOBBER; goto end; case SHIFT_SPECIAL: /* REMAINDER is 0 for most cases, so initialize it to 0. */ info->remainder = 0; info->shift1 = shift_one[cpu_type][shift_type][shift_mode].assembler; info->shift2 = shift_two[shift_type][shift_mode].assembler; info->cc_inline = shift_one[cpu_type][shift_type][shift_mode].cc_valid; info->cc_special = CC_CLOBBER; break; } /* Here we only deal with SHIFT_SPECIAL. */ switch (shift_mode) { case QIshift: /* For ASHIFTRT by 7 bits, the sign bit is simply replicated through the entire value. */ gcc_assert (shift_type == SHIFT_ASHIFTRT && count == 7); info->special = "shll\t%X0\n\tsubx\t%X0,%X0"; goto end; case HIshift: if (count == 7) { switch (shift_type) { case SHIFT_ASHIFT: if (TARGET_H8300) info->special = "shar.b\t%t0\n\tmov.b\t%s0,%t0\n\trotxr.b\t%t0\n\trotr.b\t%s0\n\tand.b\t#0x80,%s0"; else info->special = "shar.b\t%t0\n\tmov.b\t%s0,%t0\n\trotxr.w\t%T0\n\tand.b\t#0x80,%s0"; goto end; case SHIFT_LSHIFTRT: if (TARGET_H8300) info->special = "shal.b\t%s0\n\tmov.b\t%t0,%s0\n\trotxl.b\t%s0\n\trotl.b\t%t0\n\tand.b\t#0x01,%t0"; else info->special = "shal.b\t%s0\n\tmov.b\t%t0,%s0\n\trotxl.w\t%T0\n\tand.b\t#0x01,%t0"; goto end; case SHIFT_ASHIFTRT: info->special = "shal.b\t%s0\n\tmov.b\t%t0,%s0\n\trotxl.b\t%s0\n\tsubx\t%t0,%t0"; goto end; } } else if ((8 <= count && count <= 13) || (TARGET_H8300S && count == 14)) { info->remainder = count - 8; switch (shift_type) { case SHIFT_ASHIFT: info->special = "mov.b\t%s0,%t0\n\tsub.b\t%s0,%s0"; goto end; case SHIFT_LSHIFTRT: if (TARGET_H8300) { info->special = "mov.b\t%t0,%s0\n\tsub.b\t%t0,%t0"; info->shift1 = "shlr.b\t%s0"; info->cc_inline = CC_SET_ZNV; } else { info->special = "mov.b\t%t0,%s0\n\textu.w\t%T0"; info->cc_special = CC_SET_ZNV; } goto end; case SHIFT_ASHIFTRT: if (TARGET_H8300) { info->special = "mov.b\t%t0,%s0\n\tbld\t#7,%s0\n\tsubx\t%t0,%t0"; info->shift1 = "shar.b\t%s0"; } else { info->special = "mov.b\t%t0,%s0\n\texts.w\t%T0"; info->cc_special = CC_SET_ZNV; } goto end; } } else if (count == 14) { switch (shift_type) { case SHIFT_ASHIFT: if (TARGET_H8300) info->special = "mov.b\t%s0,%t0\n\trotr.b\t%t0\n\trotr.b\t%t0\n\tand.b\t#0xC0,%t0\n\tsub.b\t%s0,%s0"; goto end; case SHIFT_LSHIFTRT: if (TARGET_H8300) info->special = "mov.b\t%t0,%s0\n\trotl.b\t%s0\n\trotl.b\t%s0\n\tand.b\t#3,%s0\n\tsub.b\t%t0,%t0"; goto end; case SHIFT_ASHIFTRT: if (TARGET_H8300) info->special = "mov.b\t%t0,%s0\n\tshll.b\t%s0\n\tsubx.b\t%t0,%t0\n\tshll.b\t%s0\n\tmov.b\t%t0,%s0\n\tbst.b\t#0,%s0"; else if (TARGET_H8300H) { info->special = "shll.b\t%t0\n\tsubx.b\t%s0,%s0\n\tshll.b\t%t0\n\trotxl.b\t%s0\n\texts.w\t%T0"; info->cc_special = CC_SET_ZNV; } else /* TARGET_H8300S */ gcc_unreachable (); goto end; } } else if (count == 15) { switch (shift_type) { case SHIFT_ASHIFT: info->special = "bld\t#0,%s0\n\txor\t%s0,%s0\n\txor\t%t0,%t0\n\tbst\t#7,%t0"; goto end; case SHIFT_LSHIFTRT: info->special = "bld\t#7,%t0\n\txor\t%s0,%s0\n\txor\t%t0,%t0\n\tbst\t#0,%s0"; goto end; case SHIFT_ASHIFTRT: info->special = "shll\t%t0\n\tsubx\t%t0,%t0\n\tmov.b\t%t0,%s0"; goto end; } } gcc_unreachable (); case SIshift: if (TARGET_H8300 && 8 <= count && count <= 9) { info->remainder = count - 8; switch (shift_type) { case SHIFT_ASHIFT: info->special = "mov.b\t%y0,%z0\n\tmov.b\t%x0,%y0\n\tmov.b\t%w0,%x0\n\tsub.b\t%w0,%w0"; goto end; case SHIFT_LSHIFTRT: info->special = "mov.b\t%x0,%w0\n\tmov.b\t%y0,%x0\n\tmov.b\t%z0,%y0\n\tsub.b\t%z0,%z0"; info->shift1 = "shlr\t%y0\n\trotxr\t%x0\n\trotxr\t%w0"; goto end; case SHIFT_ASHIFTRT: info->special = "mov.b\t%x0,%w0\n\tmov.b\t%y0,%x0\n\tmov.b\t%z0,%y0\n\tshll\t%z0\n\tsubx\t%z0,%z0"; goto end; } } else if (count == 8 && !TARGET_H8300) { switch (shift_type) { case SHIFT_ASHIFT: info->special = "mov.w\t%e0,%f4\n\tmov.b\t%s4,%t4\n\tmov.b\t%t0,%s4\n\tmov.b\t%s0,%t0\n\tsub.b\t%s0,%s0\n\tmov.w\t%f4,%e0"; goto end; case SHIFT_LSHIFTRT: info->special = "mov.w\t%e0,%f4\n\tmov.b\t%t0,%s0\n\tmov.b\t%s4,%t0\n\tmov.b\t%t4,%s4\n\textu.w\t%f4\n\tmov.w\t%f4,%e0"; goto end; case SHIFT_ASHIFTRT: info->special = "mov.w\t%e0,%f4\n\tmov.b\t%t0,%s0\n\tmov.b\t%s4,%t0\n\tmov.b\t%t4,%s4\n\texts.w\t%f4\n\tmov.w\t%f4,%e0"; goto end; } } else if (count == 15 && TARGET_H8300) { switch (shift_type) { case SHIFT_ASHIFT: gcc_unreachable (); case SHIFT_LSHIFTRT: info->special = "bld\t#7,%z0\n\tmov.w\t%e0,%f0\n\txor\t%y0,%y0\n\txor\t%z0,%z0\n\trotxl\t%w0\n\trotxl\t%x0\n\trotxl\t%y0"; goto end; case SHIFT_ASHIFTRT: info->special = "bld\t#7,%z0\n\tmov.w\t%e0,%f0\n\trotxl\t%w0\n\trotxl\t%x0\n\tsubx\t%y0,%y0\n\tsubx\t%z0,%z0"; goto end; } } else if (count == 15 && !TARGET_H8300) { switch (shift_type) { case SHIFT_ASHIFT: info->special = "shlr.w\t%e0\n\tmov.w\t%f0,%e0\n\txor.w\t%f0,%f0\n\trotxr.l\t%S0"; info->cc_special = CC_SET_ZNV; goto end; case SHIFT_LSHIFTRT: info->special = "shll.w\t%f0\n\tmov.w\t%e0,%f0\n\txor.w\t%e0,%e0\n\trotxl.l\t%S0"; info->cc_special = CC_SET_ZNV; goto end; case SHIFT_ASHIFTRT: gcc_unreachable (); } } else if ((TARGET_H8300 && 16 <= count && count <= 20) || (TARGET_H8300H && 16 <= count && count <= 19) || (TARGET_H8300S && 16 <= count && count <= 21)) { info->remainder = count - 16; switch (shift_type) { case SHIFT_ASHIFT: info->special = "mov.w\t%f0,%e0\n\tsub.w\t%f0,%f0"; if (TARGET_H8300) info->shift1 = "add.w\t%e0,%e0"; goto end; case SHIFT_LSHIFTRT: if (TARGET_H8300) { info->special = "mov.w\t%e0,%f0\n\tsub.w\t%e0,%e0"; info->shift1 = "shlr\t%x0\n\trotxr\t%w0"; } else { info->special = "mov.w\t%e0,%f0\n\textu.l\t%S0"; info->cc_special = CC_SET_ZNV; } goto end; case SHIFT_ASHIFTRT: if (TARGET_H8300) { info->special = "mov.w\t%e0,%f0\n\tshll\t%z0\n\tsubx\t%z0,%z0\n\tmov.b\t%z0,%y0"; info->shift1 = "shar\t%x0\n\trotxr\t%w0"; } else { info->special = "mov.w\t%e0,%f0\n\texts.l\t%S0"; info->cc_special = CC_SET_ZNV; } goto end; } } else if (TARGET_H8300 && 24 <= count && count <= 28) { info->remainder = count - 24; switch (shift_type) { case SHIFT_ASHIFT: info->special = "mov.b\t%w0,%z0\n\tsub.b\t%y0,%y0\n\tsub.w\t%f0,%f0"; info->shift1 = "shll.b\t%z0"; info->cc_inline = CC_SET_ZNV; goto end; case SHIFT_LSHIFTRT: info->special = "mov.b\t%z0,%w0\n\tsub.b\t%x0,%x0\n\tsub.w\t%e0,%e0"; info->shift1 = "shlr.b\t%w0"; info->cc_inline = CC_SET_ZNV; goto end; case SHIFT_ASHIFTRT: info->special = "mov.b\t%z0,%w0\n\tbld\t#7,%w0\n\tsubx\t%x0,%x0\n\tsubx\t%x0,%x0\n\tsubx\t%x0,%x0"; info->shift1 = "shar.b\t%w0"; info->cc_inline = CC_SET_ZNV; goto end; } } else if ((TARGET_H8300H && count == 24) || (TARGET_H8300S && 24 <= count && count <= 25)) { info->remainder = count - 24; switch (shift_type) { case SHIFT_ASHIFT: info->special = "mov.b\t%s0,%t0\n\tsub.b\t%s0,%s0\n\tmov.w\t%f0,%e0\n\tsub.w\t%f0,%f0"; goto end; case SHIFT_LSHIFTRT: info->special = "mov.w\t%e0,%f0\n\tmov.b\t%t0,%s0\n\textu.w\t%f0\n\textu.l\t%S0"; info->cc_special = CC_SET_ZNV; goto end; case SHIFT_ASHIFTRT: info->special = "mov.w\t%e0,%f0\n\tmov.b\t%t0,%s0\n\texts.w\t%f0\n\texts.l\t%S0"; info->cc_special = CC_SET_ZNV; goto end; } } else if (!TARGET_H8300 && count == 28) { switch (shift_type) { case SHIFT_ASHIFT: if (TARGET_H8300H) info->special = "sub.w\t%e0,%e0\n\trotr.l\t%S0\n\trotr.l\t%S0\n\trotr.l\t%S0\n\trotr.l\t%S0\n\tsub.w\t%f0,%f0"; else info->special = "sub.w\t%e0,%e0\n\trotr.l\t#2,%S0\n\trotr.l\t#2,%S0\n\tsub.w\t%f0,%f0"; goto end; case SHIFT_LSHIFTRT: if (TARGET_H8300H) { info->special = "sub.w\t%f0,%f0\n\trotl.l\t%S0\n\trotl.l\t%S0\n\trotl.l\t%S0\n\trotl.l\t%S0\n\textu.l\t%S0"; info->cc_special = CC_SET_ZNV; } else info->special = "sub.w\t%f0,%f0\n\trotl.l\t#2,%S0\n\trotl.l\t#2,%S0\n\textu.l\t%S0"; goto end; case SHIFT_ASHIFTRT: gcc_unreachable (); } } else if (!TARGET_H8300 && count == 29) { switch (shift_type) { case SHIFT_ASHIFT: if (TARGET_H8300H) info->special = "sub.w\t%e0,%e0\n\trotr.l\t%S0\n\trotr.l\t%S0\n\trotr.l\t%S0\n\tsub.w\t%f0,%f0"; else info->special = "sub.w\t%e0,%e0\n\trotr.l\t#2,%S0\n\trotr.l\t%S0\n\tsub.w\t%f0,%f0"; goto end; case SHIFT_LSHIFTRT: if (TARGET_H8300H) { info->special = "sub.w\t%f0,%f0\n\trotl.l\t%S0\n\trotl.l\t%S0\n\trotl.l\t%S0\n\textu.l\t%S0"; info->cc_special = CC_SET_ZNV; } else { info->special = "sub.w\t%f0,%f0\n\trotl.l\t#2,%S0\n\trotl.l\t%S0\n\textu.l\t%S0"; info->cc_special = CC_SET_ZNV; } goto end; case SHIFT_ASHIFTRT: gcc_unreachable (); } } else if (!TARGET_H8300 && count == 30) { switch (shift_type) { case SHIFT_ASHIFT: if (TARGET_H8300H) info->special = "sub.w\t%e0,%e0\n\trotr.l\t%S0\n\trotr.l\t%S0\n\tsub.w\t%f0,%f0"; else info->special = "sub.w\t%e0,%e0\n\trotr.l\t#2,%S0\n\tsub.w\t%f0,%f0"; goto end; case SHIFT_LSHIFTRT: if (TARGET_H8300H) info->special = "sub.w\t%f0,%f0\n\trotl.l\t%S0\n\trotl.l\t%S0\n\textu.l\t%S0"; else info->special = "sub.w\t%f0,%f0\n\trotl.l\t#2,%S0\n\textu.l\t%S0"; goto end; case SHIFT_ASHIFTRT: gcc_unreachable (); } } else if (count == 31) { if (TARGET_H8300) { switch (shift_type) { case SHIFT_ASHIFT: info->special = "sub.w\t%e0,%e0\n\tshlr\t%w0\n\tmov.w\t%e0,%f0\n\trotxr\t%z0"; goto end; case SHIFT_LSHIFTRT: info->special = "sub.w\t%f0,%f0\n\tshll\t%z0\n\tmov.w\t%f0,%e0\n\trotxl\t%w0"; goto end; case SHIFT_ASHIFTRT: info->special = "shll\t%z0\n\tsubx\t%w0,%w0\n\tmov.b\t%w0,%x0\n\tmov.w\t%f0,%e0"; goto end; } } else { switch (shift_type) { case SHIFT_ASHIFT: info->special = "shlr.l\t%S0\n\txor.l\t%S0,%S0\n\trotxr.l\t%S0"; info->cc_special = CC_SET_ZNV; goto end; case SHIFT_LSHIFTRT: info->special = "shll.l\t%S0\n\txor.l\t%S0,%S0\n\trotxl.l\t%S0"; info->cc_special = CC_SET_ZNV; goto end; case SHIFT_ASHIFTRT: info->special = "shll\t%e0\n\tsubx\t%w0,%w0\n\texts.w\t%T0\n\texts.l\t%S0"; info->cc_special = CC_SET_ZNV; goto end; } } } gcc_unreachable (); default: gcc_unreachable (); } end: if (!TARGET_H8300S) info->shift2 = NULL; } /* Given COUNT and MODE of a shift, return 1 if a scratch reg may be needed for some shift with COUNT and MODE. Return 0 otherwise. */ int h8300_shift_needs_scratch_p (int count, enum machine_mode mode) { enum h8_cpu cpu; int a, lr, ar; if (GET_MODE_BITSIZE (mode) <= count) return 1; /* Find out the target CPU. */ if (TARGET_H8300) cpu = H8_300; else if (TARGET_H8300H) cpu = H8_300H; else cpu = H8_S; /* Find the shift algorithm. */ switch (mode) { case QImode: a = shift_alg_qi[cpu][SHIFT_ASHIFT][count]; lr = shift_alg_qi[cpu][SHIFT_LSHIFTRT][count]; ar = shift_alg_qi[cpu][SHIFT_ASHIFTRT][count]; break; case HImode: a = shift_alg_hi[cpu][SHIFT_ASHIFT][count]; lr = shift_alg_hi[cpu][SHIFT_LSHIFTRT][count]; ar = shift_alg_hi[cpu][SHIFT_ASHIFTRT][count]; break; case SImode: a = shift_alg_si[cpu][SHIFT_ASHIFT][count]; lr = shift_alg_si[cpu][SHIFT_LSHIFTRT][count]; ar = shift_alg_si[cpu][SHIFT_ASHIFTRT][count]; break; default: gcc_unreachable (); } /* On H8/300H, count == 8 uses a scratch register. */ return (a == SHIFT_LOOP || lr == SHIFT_LOOP || ar == SHIFT_LOOP || (TARGET_H8300H && mode == SImode && count == 8)); } /* Output the assembler code for doing shifts. */ const char * output_a_shift (rtx *operands) { static int loopend_lab; rtx shift = operands[3]; enum machine_mode mode = GET_MODE (shift); enum rtx_code code = GET_CODE (shift); enum shift_type shift_type; enum shift_mode shift_mode; struct shift_info info; int n; loopend_lab++; switch (mode) { case QImode: shift_mode = QIshift; break; case HImode: shift_mode = HIshift; break; case SImode: shift_mode = SIshift; break; default: gcc_unreachable (); } switch (code) { case ASHIFTRT: shift_type = SHIFT_ASHIFTRT; break; case LSHIFTRT: shift_type = SHIFT_LSHIFTRT; break; case ASHIFT: shift_type = SHIFT_ASHIFT; break; default: gcc_unreachable (); } /* This case must be taken care of by one of the two splitters that convert a variable shift into a loop. */ gcc_assert (GET_CODE (operands[2]) == CONST_INT); n = INTVAL (operands[2]); /* If the count is negative, make it 0. */ if (n < 0) n = 0; /* If the count is too big, truncate it. ANSI says shifts of GET_MODE_BITSIZE are undefined - we choose to do the intuitive thing. */ else if ((unsigned int) n > GET_MODE_BITSIZE (mode)) n = GET_MODE_BITSIZE (mode); get_shift_alg (shift_type, shift_mode, n, &info); switch (info.alg) { case SHIFT_SPECIAL: output_asm_insn (info.special, operands); /* Fall through. */ case SHIFT_INLINE: n = info.remainder; /* Emit two bit shifts first. */ if (info.shift2 != NULL) { for (; n > 1; n -= 2) output_asm_insn (info.shift2, operands); } /* Now emit one bit shifts for any residual. */ for (; n > 0; n--) output_asm_insn (info.shift1, operands); return ""; case SHIFT_ROT_AND: { int m = GET_MODE_BITSIZE (mode) - n; const int mask = (shift_type == SHIFT_ASHIFT ? ((1 << m) - 1) << n : (1 << m) - 1); char insn_buf[200]; /* Not all possibilities of rotate are supported. They shouldn't be generated, but let's watch for 'em. */ gcc_assert (info.shift1); /* Emit two bit rotates first. */ if (info.shift2 != NULL) { for (; m > 1; m -= 2) output_asm_insn (info.shift2, operands); } /* Now single bit rotates for any residual. */ for (; m > 0; m--) output_asm_insn (info.shift1, operands); /* Now mask off the high bits. */ switch (mode) { case QImode: sprintf (insn_buf, "and\t#%d,%%X0", mask); break; case HImode: gcc_assert (TARGET_H8300H || TARGET_H8300S); sprintf (insn_buf, "and.w\t#%d,%%T0", mask); break; default: gcc_unreachable (); } output_asm_insn (insn_buf, operands); return ""; } case SHIFT_LOOP: /* A loop to shift by a "large" constant value. If we have shift-by-2 insns, use them. */ if (info.shift2 != NULL) { fprintf (asm_out_file, "\tmov.b #%d,%sl\n", n / 2, names_big[REGNO (operands[4])]); fprintf (asm_out_file, ".Llt%d:\n", loopend_lab); output_asm_insn (info.shift2, operands); output_asm_insn ("add #0xff,%X4", operands); fprintf (asm_out_file, "\tbne .Llt%d\n", loopend_lab); if (n % 2) output_asm_insn (info.shift1, operands); } else { fprintf (asm_out_file, "\tmov.b #%d,%sl\n", n, names_big[REGNO (operands[4])]); fprintf (asm_out_file, ".Llt%d:\n", loopend_lab); output_asm_insn (info.shift1, operands); output_asm_insn ("add #0xff,%X4", operands); fprintf (asm_out_file, "\tbne .Llt%d\n", loopend_lab); } return ""; default: gcc_unreachable (); } } /* Count the number of assembly instructions in a string TEMPL. */ static unsigned int h8300_asm_insn_count (const char *templ) { unsigned int count = 1; for (; *templ; templ++) if (*templ == '\n') count++; return count; } /* Compute the length of a shift insn. */ unsigned int compute_a_shift_length (rtx insn ATTRIBUTE_UNUSED, rtx *operands) { rtx shift = operands[3]; enum machine_mode mode = GET_MODE (shift); enum rtx_code code = GET_CODE (shift); enum shift_type shift_type; enum shift_mode shift_mode; struct shift_info info; unsigned int wlength = 0; switch (mode) { case QImode: shift_mode = QIshift; break; case HImode: shift_mode = HIshift; break; case SImode: shift_mode = SIshift; break; default: gcc_unreachable (); } switch (code) { case ASHIFTRT: shift_type = SHIFT_ASHIFTRT; break; case LSHIFTRT: shift_type = SHIFT_LSHIFTRT; break; case ASHIFT: shift_type = SHIFT_ASHIFT; break; default: gcc_unreachable (); } if (GET_CODE (operands[2]) != CONST_INT) { /* Get the assembler code to do one shift. */ get_shift_alg (shift_type, shift_mode, 1, &info); return (4 + h8300_asm_insn_count (info.shift1)) * 2; } else { int n = INTVAL (operands[2]); /* If the count is negative, make it 0. */ if (n < 0) n = 0; /* If the count is too big, truncate it. ANSI says shifts of GET_MODE_BITSIZE are undefined - we choose to do the intuitive thing. */ else if ((unsigned int) n > GET_MODE_BITSIZE (mode)) n = GET_MODE_BITSIZE (mode); get_shift_alg (shift_type, shift_mode, n, &info); switch (info.alg) { case SHIFT_SPECIAL: wlength += h8300_asm_insn_count (info.special); /* Every assembly instruction used in SHIFT_SPECIAL case takes 2 bytes except xor.l, which takes 4 bytes, so if we see xor.l, we just pretend that xor.l counts as two insns so that the insn length will be computed correctly. */ if (strstr (info.special, "xor.l") != NULL) wlength++; /* Fall through. */ case SHIFT_INLINE: n = info.remainder; if (info.shift2 != NULL) { wlength += h8300_asm_insn_count (info.shift2) * (n / 2); n = n % 2; } wlength += h8300_asm_insn_count (info.shift1) * n; return 2 * wlength; case SHIFT_ROT_AND: { int m = GET_MODE_BITSIZE (mode) - n; /* Not all possibilities of rotate are supported. They shouldn't be generated, but let's watch for 'em. */ gcc_assert (info.shift1); if (info.shift2 != NULL) { wlength += h8300_asm_insn_count (info.shift2) * (m / 2); m = m % 2; } wlength += h8300_asm_insn_count (info.shift1) * m; /* Now mask off the high bits. */ switch (mode) { case QImode: wlength += 1; break; case HImode: wlength += 2; break; case SImode: gcc_assert (!TARGET_H8300); wlength += 3; break; default: gcc_unreachable (); } return 2 * wlength; } case SHIFT_LOOP: /* A loop to shift by a "large" constant value. If we have shift-by-2 insns, use them. */ if (info.shift2 != NULL) { wlength += 3 + h8300_asm_insn_count (info.shift2); if (n % 2) wlength += h8300_asm_insn_count (info.shift1); } else { wlength += 3 + h8300_asm_insn_count (info.shift1); } return 2 * wlength; default: gcc_unreachable (); } } } /* Compute which flag bits are valid after a shift insn. */ enum attr_cc compute_a_shift_cc (rtx insn ATTRIBUTE_UNUSED, rtx *operands) { rtx shift = operands[3]; enum machine_mode mode = GET_MODE (shift); enum rtx_code code = GET_CODE (shift); enum shift_type shift_type; enum shift_mode shift_mode; struct shift_info info; int n; switch (mode) { case QImode: shift_mode = QIshift; break; case HImode: shift_mode = HIshift; break; case SImode: shift_mode = SIshift; break; default: gcc_unreachable (); } switch (code) { case ASHIFTRT: shift_type = SHIFT_ASHIFTRT; break; case LSHIFTRT: shift_type = SHIFT_LSHIFTRT; break; case ASHIFT: shift_type = SHIFT_ASHIFT; break; default: gcc_unreachable (); } /* This case must be taken care of by one of the two splitters that convert a variable shift into a loop. */ gcc_assert (GET_CODE (operands[2]) == CONST_INT); n = INTVAL (operands[2]); /* If the count is negative, make it 0. */ if (n < 0) n = 0; /* If the count is too big, truncate it. ANSI says shifts of GET_MODE_BITSIZE are undefined - we choose to do the intuitive thing. */ else if ((unsigned int) n > GET_MODE_BITSIZE (mode)) n = GET_MODE_BITSIZE (mode); get_shift_alg (shift_type, shift_mode, n, &info); switch (info.alg) { case SHIFT_SPECIAL: if (info.remainder == 0) return info.cc_special; /* Fall through. */ case SHIFT_INLINE: return info.cc_inline; case SHIFT_ROT_AND: /* This case always ends with an and instruction. */ return CC_SET_ZNV; case SHIFT_LOOP: /* A loop to shift by a "large" constant value. If we have shift-by-2 insns, use them. */ if (info.shift2 != NULL) { if (n % 2) return info.cc_inline; } return CC_CLOBBER; default: gcc_unreachable (); } } /* A rotation by a non-constant will cause a loop to be generated, in which a rotation by one bit is used. A rotation by a constant, including the one in the loop, will be taken care of by output_a_rotate () at the insn emit time. */ int expand_a_rotate (rtx operands[]) { rtx dst = operands[0]; rtx src = operands[1]; rtx rotate_amount = operands[2]; enum machine_mode mode = GET_MODE (dst); if (h8sx_classify_shift (mode, ROTATE, rotate_amount) == H8SX_SHIFT_UNARY) return false; /* We rotate in place. */ emit_move_insn (dst, src); if (GET_CODE (rotate_amount) != CONST_INT) { rtx counter = gen_reg_rtx (QImode); rtx start_label = gen_label_rtx (); rtx end_label = gen_label_rtx (); /* If the rotate amount is less than or equal to 0, we go out of the loop. */ emit_cmp_and_jump_insns (rotate_amount, const0_rtx, LE, NULL_RTX, QImode, 0, end_label); /* Initialize the loop counter. */ emit_move_insn (counter, rotate_amount); emit_label (start_label); /* Rotate by one bit. */ switch (mode) { case QImode: emit_insn (gen_rotlqi3_1 (dst, dst, const1_rtx)); break; case HImode: emit_insn (gen_rotlhi3_1 (dst, dst, const1_rtx)); break; case SImode: emit_insn (gen_rotlsi3_1 (dst, dst, const1_rtx)); break; default: gcc_unreachable (); } /* Decrement the counter by 1. */ emit_insn (gen_addqi3 (counter, counter, constm1_rtx)); /* If the loop counter is nonzero, we go back to the beginning of the loop. */ emit_cmp_and_jump_insns (counter, const0_rtx, NE, NULL_RTX, QImode, 1, start_label); emit_label (end_label); } else { /* Rotate by AMOUNT bits. */ switch (mode) { case QImode: emit_insn (gen_rotlqi3_1 (dst, dst, rotate_amount)); break; case HImode: emit_insn (gen_rotlhi3_1 (dst, dst, rotate_amount)); break; case SImode: emit_insn (gen_rotlsi3_1 (dst, dst, rotate_amount)); break; default: gcc_unreachable (); } } return 1; } /* Output a rotate insn. */ const char * output_a_rotate (enum rtx_code code, rtx *operands) { rtx dst = operands[0]; rtx rotate_amount = operands[2]; enum shift_mode rotate_mode; enum shift_type rotate_type; const char *insn_buf; int bits; int amount; enum machine_mode mode = GET_MODE (dst); gcc_assert (GET_CODE (rotate_amount) == CONST_INT); switch (mode) { case QImode: rotate_mode = QIshift; break; case HImode: rotate_mode = HIshift; break; case SImode: rotate_mode = SIshift; break; default: gcc_unreachable (); } switch (code) { case ROTATERT: rotate_type = SHIFT_ASHIFT; break; case ROTATE: rotate_type = SHIFT_LSHIFTRT; break; default: gcc_unreachable (); } amount = INTVAL (rotate_amount); /* Clean up AMOUNT. */ if (amount < 0) amount = 0; if ((unsigned int) amount > GET_MODE_BITSIZE (mode)) amount = GET_MODE_BITSIZE (mode); /* Determine the faster direction. After this phase, amount will be at most a half of GET_MODE_BITSIZE (mode). */ if ((unsigned int) amount > GET_MODE_BITSIZE (mode) / (unsigned) 2) { /* Flip the direction. */ amount = GET_MODE_BITSIZE (mode) - amount; rotate_type = (rotate_type == SHIFT_ASHIFT) ? SHIFT_LSHIFTRT : SHIFT_ASHIFT; } /* See if a byte swap (in HImode) or a word swap (in SImode) can boost up the rotation. */ if ((mode == HImode && TARGET_H8300 && amount >= 5) || (mode == HImode && TARGET_H8300H && amount >= 6) || (mode == HImode && TARGET_H8300S && amount == 8) || (mode == SImode && TARGET_H8300H && amount >= 10) || (mode == SImode && TARGET_H8300S && amount >= 13)) { switch (mode) { case HImode: /* This code works on any family. */ insn_buf = "xor.b\t%s0,%t0\n\txor.b\t%t0,%s0\n\txor.b\t%s0,%t0"; output_asm_insn (insn_buf, operands); break; case SImode: /* This code works on the H8/300H and H8S. */ insn_buf = "xor.w\t%e0,%f0\n\txor.w\t%f0,%e0\n\txor.w\t%e0,%f0"; output_asm_insn (insn_buf, operands); break; default: gcc_unreachable (); } /* Adjust AMOUNT and flip the direction. */ amount = GET_MODE_BITSIZE (mode) / 2 - amount; rotate_type = (rotate_type == SHIFT_ASHIFT) ? SHIFT_LSHIFTRT : SHIFT_ASHIFT; } /* Output rotate insns. */ for (bits = TARGET_H8300S ? 2 : 1; bits > 0; bits /= 2) { if (bits == 2) insn_buf = rotate_two[rotate_type][rotate_mode]; else insn_buf = rotate_one[cpu_type][rotate_type][rotate_mode]; for (; amount >= bits; amount -= bits) output_asm_insn (insn_buf, operands); } return ""; } /* Compute the length of a rotate insn. */ unsigned int compute_a_rotate_length (rtx *operands) { rtx src = operands[1]; rtx amount_rtx = operands[2]; enum machine_mode mode = GET_MODE (src); int amount; unsigned int length = 0; gcc_assert (GET_CODE (amount_rtx) == CONST_INT); amount = INTVAL (amount_rtx); /* Clean up AMOUNT. */ if (amount < 0) amount = 0; if ((unsigned int) amount > GET_MODE_BITSIZE (mode)) amount = GET_MODE_BITSIZE (mode); /* Determine the faster direction. After this phase, amount will be at most a half of GET_MODE_BITSIZE (mode). */ if ((unsigned int) amount > GET_MODE_BITSIZE (mode) / (unsigned) 2) /* Flip the direction. */ amount = GET_MODE_BITSIZE (mode) - amount; /* See if a byte swap (in HImode) or a word swap (in SImode) can boost up the rotation. */ if ((mode == HImode && TARGET_H8300 && amount >= 5) || (mode == HImode && TARGET_H8300H && amount >= 6) || (mode == HImode && TARGET_H8300S && amount == 8) || (mode == SImode && TARGET_H8300H && amount >= 10) || (mode == SImode && TARGET_H8300S && amount >= 13)) { /* Adjust AMOUNT and flip the direction. */ amount = GET_MODE_BITSIZE (mode) / 2 - amount; length += 6; } /* We use 2-bit rotations on the H8S. */ if (TARGET_H8300S) amount = amount / 2 + amount % 2; /* The H8/300 uses three insns to rotate one bit, taking 6 length. */ length += amount * ((TARGET_H8300 && mode == HImode) ? 6 : 2); return length; } /* Fix the operands of a gen_xxx so that it could become a bit operating insn. */ int fix_bit_operand (rtx *operands, enum rtx_code code) { /* The bit_operand predicate accepts any memory during RTL generation, but only 'U' memory afterwards, so if this is a MEM operand, we must force it to be valid for 'U' by reloading the address. */ if (code == AND ? single_zero_operand (operands[2], QImode) : single_one_operand (operands[2], QImode)) { /* OK to have a memory dest. */ if (GET_CODE (operands[0]) == MEM && !satisfies_constraint_U (operands[0])) { rtx mem = gen_rtx_MEM (GET_MODE (operands[0]), copy_to_mode_reg (Pmode, XEXP (operands[0], 0))); MEM_COPY_ATTRIBUTES (mem, operands[0]); operands[0] = mem; } if (GET_CODE (operands[1]) == MEM && !satisfies_constraint_U (operands[1])) { rtx mem = gen_rtx_MEM (GET_MODE (operands[1]), copy_to_mode_reg (Pmode, XEXP (operands[1], 0))); MEM_COPY_ATTRIBUTES (mem, operands[0]); operands[1] = mem; } return 0; } /* Dest and src op must be register. */ operands[1] = force_reg (QImode, operands[1]); { rtx res = gen_reg_rtx (QImode); switch (code) { case AND: emit_insn (gen_andqi3_1 (res, operands[1], operands[2])); break; case IOR: emit_insn (gen_iorqi3_1 (res, operands[1], operands[2])); break; case XOR: emit_insn (gen_xorqi3_1 (res, operands[1], operands[2])); break; default: gcc_unreachable (); } emit_insn (gen_movqi (operands[0], res)); } return 1; } /* Return nonzero if FUNC is an interrupt function as specified by the "interrupt" attribute. */ static int h8300_interrupt_function_p (tree func) { tree a; if (TREE_CODE (func) != FUNCTION_DECL) return 0; a = lookup_attribute ("interrupt_handler", DECL_ATTRIBUTES (func)); return a != NULL_TREE; } /* Return nonzero if FUNC is a saveall function as specified by the "saveall" attribute. */ static int h8300_saveall_function_p (tree func) { tree a; if (TREE_CODE (func) != FUNCTION_DECL) return 0; a = lookup_attribute ("saveall", DECL_ATTRIBUTES (func)); return a != NULL_TREE; } /* Return nonzero if FUNC is an OS_Task function as specified by the "OS_Task" attribute. */ static int h8300_os_task_function_p (tree func) { tree a; if (TREE_CODE (func) != FUNCTION_DECL) return 0; a = lookup_attribute ("OS_Task", DECL_ATTRIBUTES (func)); return a != NULL_TREE; } /* Return nonzero if FUNC is a monitor function as specified by the "monitor" attribute. */ static int h8300_monitor_function_p (tree func) { tree a; if (TREE_CODE (func) != FUNCTION_DECL) return 0; a = lookup_attribute ("monitor", DECL_ATTRIBUTES (func)); return a != NULL_TREE; } /* Return nonzero if FUNC is a function that should be called through the function vector. */ int h8300_funcvec_function_p (tree func) { tree a; if (TREE_CODE (func) != FUNCTION_DECL) return 0; a = lookup_attribute ("function_vector", DECL_ATTRIBUTES (func)); return a != NULL_TREE; } /* Return nonzero if DECL is a variable that's in the eight bit data area. */ int h8300_eightbit_data_p (tree decl) { tree a; if (TREE_CODE (decl) != VAR_DECL) return 0; a = lookup_attribute ("eightbit_data", DECL_ATTRIBUTES (decl)); return a != NULL_TREE; } /* Return nonzero if DECL is a variable that's in the tiny data area. */ int h8300_tiny_data_p (tree decl) { tree a; if (TREE_CODE (decl) != VAR_DECL) return 0; a = lookup_attribute ("tiny_data", DECL_ATTRIBUTES (decl)); return a != NULL_TREE; } /* Generate an 'interrupt_handler' attribute for decls. We convert all the pragmas to corresponding attributes. */ static void h8300_insert_attributes (tree node, tree *attributes) { if (TREE_CODE (node) == FUNCTION_DECL) { if (pragma_interrupt) { pragma_interrupt = 0; /* Add an 'interrupt_handler' attribute. */ *attributes = tree_cons (get_identifier ("interrupt_handler"), NULL, *attributes); } if (pragma_saveall) { pragma_saveall = 0; /* Add an 'saveall' attribute. */ *attributes = tree_cons (get_identifier ("saveall"), NULL, *attributes); } } } /* Supported attributes: interrupt_handler: output a prologue and epilogue suitable for an interrupt handler. saveall: output a prologue and epilogue that saves and restores all registers except the stack pointer. function_vector: This function should be called through the function vector. eightbit_data: This variable lives in the 8-bit data area and can be referenced with 8-bit absolute memory addresses. tiny_data: This variable lives in the tiny data area and can be referenced with 16-bit absolute memory references. */ static const struct attribute_spec h8300_attribute_table[] = { /* { name, min_len, max_len, decl_req, type_req, fn_type_req, handler, affects_type_identity } */ { "interrupt_handler", 0, 0, true, false, false, h8300_handle_fndecl_attribute, false }, { "saveall", 0, 0, true, false, false, h8300_handle_fndecl_attribute, false }, { "OS_Task", 0, 0, true, false, false, h8300_handle_fndecl_attribute, false }, { "monitor", 0, 0, true, false, false, h8300_handle_fndecl_attribute, false }, { "function_vector", 0, 0, true, false, false, h8300_handle_fndecl_attribute, false }, { "eightbit_data", 0, 0, true, false, false, h8300_handle_eightbit_data_attribute, false }, { "tiny_data", 0, 0, true, false, false, h8300_handle_tiny_data_attribute, false }, { NULL, 0, 0, false, false, false, NULL, false } }; /* Handle an attribute requiring a FUNCTION_DECL; arguments as in struct attribute_spec.handler. */ static tree h8300_handle_fndecl_attribute (tree *node, tree name, tree args ATTRIBUTE_UNUSED, int flags ATTRIBUTE_UNUSED, bool *no_add_attrs) { if (TREE_CODE (*node) != FUNCTION_DECL) { warning (OPT_Wattributes, "%qE attribute only applies to functions", name); *no_add_attrs = true; } return NULL_TREE; } /* Handle an "eightbit_data" attribute; arguments as in struct attribute_spec.handler. */ static tree h8300_handle_eightbit_data_attribute (tree *node, tree name, tree args ATTRIBUTE_UNUSED, int flags ATTRIBUTE_UNUSED, bool *no_add_attrs) { tree decl = *node; if (TREE_STATIC (decl) || DECL_EXTERNAL (decl)) { DECL_SECTION_NAME (decl) = build_string (7, ".eight"); } else { warning (OPT_Wattributes, "%qE attribute ignored", name); *no_add_attrs = true; } return NULL_TREE; } /* Handle an "tiny_data" attribute; arguments as in struct attribute_spec.handler. */ static tree h8300_handle_tiny_data_attribute (tree *node, tree name, tree args ATTRIBUTE_UNUSED, int flags ATTRIBUTE_UNUSED, bool *no_add_attrs) { tree decl = *node; if (TREE_STATIC (decl) || DECL_EXTERNAL (decl)) { DECL_SECTION_NAME (decl) = build_string (6, ".tiny"); } else { warning (OPT_Wattributes, "%qE attribute ignored", name); *no_add_attrs = true; } return NULL_TREE; } /* Mark function vectors, and various small data objects. */ static void h8300_encode_section_info (tree decl, rtx rtl, int first) { int extra_flags = 0; default_encode_section_info (decl, rtl, first); if (TREE_CODE (decl) == FUNCTION_DECL && h8300_funcvec_function_p (decl)) extra_flags = SYMBOL_FLAG_FUNCVEC_FUNCTION; else if (TREE_CODE (decl) == VAR_DECL && (TREE_STATIC (decl) || DECL_EXTERNAL (decl))) { if (h8300_eightbit_data_p (decl)) extra_flags = SYMBOL_FLAG_EIGHTBIT_DATA; else if (first && h8300_tiny_data_p (decl)) extra_flags = SYMBOL_FLAG_TINY_DATA; } if (extra_flags) SYMBOL_REF_FLAGS (XEXP (rtl, 0)) |= extra_flags; } /* Output a single-bit extraction. */ const char * output_simode_bld (int bild, rtx operands[]) { if (TARGET_H8300) { /* Clear the destination register. */ output_asm_insn ("sub.w\t%e0,%e0\n\tsub.w\t%f0,%f0", operands); /* Now output the bit load or bit inverse load, and store it in the destination. */ if (bild) output_asm_insn ("bild\t%Z2,%Y1", operands); else output_asm_insn ("bld\t%Z2,%Y1", operands); output_asm_insn ("bst\t#0,%w0", operands); } else { /* Determine if we can clear the destination first. */ int clear_first = (REG_P (operands[0]) && REG_P (operands[1]) && REGNO (operands[0]) != REGNO (operands[1])); if (clear_first) output_asm_insn ("sub.l\t%S0,%S0", operands); /* Output the bit load or bit inverse load. */ if (bild) output_asm_insn ("bild\t%Z2,%Y1", operands); else output_asm_insn ("bld\t%Z2,%Y1", operands); if (!clear_first) output_asm_insn ("xor.l\t%S0,%S0", operands); /* Perform the bit store. */ output_asm_insn ("rotxl.l\t%S0", operands); } /* All done. */ return ""; } /* Delayed-branch scheduling is more effective if we have some idea how long each instruction will be. Use a shorten_branches pass to get an initial estimate. */ static void h8300_reorg (void) { if (flag_delayed_branch) shorten_branches (get_insns ()); } #ifndef OBJECT_FORMAT_ELF static void h8300_asm_named_section (const char *name, unsigned int flags ATTRIBUTE_UNUSED, tree decl) { /* ??? Perhaps we should be using default_coff_asm_named_section. */ fprintf (asm_out_file, "\t.section %s\n", name); } #endif /* ! OBJECT_FORMAT_ELF */ /* Nonzero if X is a constant address suitable as an 8-bit absolute, which is a special case of the 'R' operand. */ int h8300_eightbit_constant_address_p (rtx x) { /* The ranges of the 8-bit area. */ const unsigned HOST_WIDE_INT n1 = trunc_int_for_mode (0xff00, HImode); const unsigned HOST_WIDE_INT n2 = trunc_int_for_mode (0xffff, HImode); const unsigned HOST_WIDE_INT h1 = trunc_int_for_mode (0x00ffff00, SImode); const unsigned HOST_WIDE_INT h2 = trunc_int_for_mode (0x00ffffff, SImode); const unsigned HOST_WIDE_INT s1 = trunc_int_for_mode (0xffffff00, SImode); const unsigned HOST_WIDE_INT s2 = trunc_int_for_mode (0xffffffff, SImode); unsigned HOST_WIDE_INT addr; /* We accept symbols declared with eightbit_data. */ if (GET_CODE (x) == SYMBOL_REF) return (SYMBOL_REF_FLAGS (x) & SYMBOL_FLAG_EIGHTBIT_DATA) != 0; if (GET_CODE (x) != CONST_INT) return 0; addr = INTVAL (x); return (0 || ((TARGET_H8300 || TARGET_NORMAL_MODE) && IN_RANGE (addr, n1, n2)) || (TARGET_H8300H && IN_RANGE (addr, h1, h2)) || (TARGET_H8300S && IN_RANGE (addr, s1, s2))); } /* Nonzero if X is a constant address suitable as an 16-bit absolute on H8/300H and H8S. */ int h8300_tiny_constant_address_p (rtx x) { /* The ranges of the 16-bit area. */ const unsigned HOST_WIDE_INT h1 = trunc_int_for_mode (0x00000000, SImode); const unsigned HOST_WIDE_INT h2 = trunc_int_for_mode (0x00007fff, SImode); const unsigned HOST_WIDE_INT h3 = trunc_int_for_mode (0x00ff8000, SImode); const unsigned HOST_WIDE_INT h4 = trunc_int_for_mode (0x00ffffff, SImode); const unsigned HOST_WIDE_INT s1 = trunc_int_for_mode (0x00000000, SImode); const unsigned HOST_WIDE_INT s2 = trunc_int_for_mode (0x00007fff, SImode); const unsigned HOST_WIDE_INT s3 = trunc_int_for_mode (0xffff8000, SImode); const unsigned HOST_WIDE_INT s4 = trunc_int_for_mode (0xffffffff, SImode); unsigned HOST_WIDE_INT addr; switch (GET_CODE (x)) { case SYMBOL_REF: /* In the normal mode, any symbol fits in the 16-bit absolute address range. We also accept symbols declared with tiny_data. */ return (TARGET_NORMAL_MODE || (SYMBOL_REF_FLAGS (x) & SYMBOL_FLAG_TINY_DATA) != 0); case CONST_INT: addr = INTVAL (x); return (TARGET_NORMAL_MODE || (TARGET_H8300H && (IN_RANGE (addr, h1, h2) || IN_RANGE (addr, h3, h4))) || (TARGET_H8300S && (IN_RANGE (addr, s1, s2) || IN_RANGE (addr, s3, s4)))); case CONST: return TARGET_NORMAL_MODE; default: return 0; } } /* Return nonzero if ADDR1 and ADDR2 point to consecutive memory locations that can be accessed as a 16-bit word. */ int byte_accesses_mergeable_p (rtx addr1, rtx addr2) { HOST_WIDE_INT offset1, offset2; rtx reg1, reg2; if (REG_P (addr1)) { reg1 = addr1; offset1 = 0; } else if (GET_CODE (addr1) == PLUS && REG_P (XEXP (addr1, 0)) && GET_CODE (XEXP (addr1, 1)) == CONST_INT) { reg1 = XEXP (addr1, 0); offset1 = INTVAL (XEXP (addr1, 1)); } else return 0; if (REG_P (addr2)) { reg2 = addr2; offset2 = 0; } else if (GET_CODE (addr2) == PLUS && REG_P (XEXP (addr2, 0)) && GET_CODE (XEXP (addr2, 1)) == CONST_INT) { reg2 = XEXP (addr2, 0); offset2 = INTVAL (XEXP (addr2, 1)); } else return 0; if (((reg1 == stack_pointer_rtx && reg2 == stack_pointer_rtx) || (reg1 == frame_pointer_rtx && reg2 == frame_pointer_rtx)) && offset1 % 2 == 0 && offset1 + 1 == offset2) return 1; return 0; } /* Return nonzero if we have the same comparison insn as I3 two insns before I3. I3 is assumed to be a comparison insn. */ int same_cmp_preceding_p (rtx i3) { rtx i1, i2; /* Make sure we have a sequence of three insns. */ i2 = prev_nonnote_insn (i3); if (i2 == NULL_RTX) return 0; i1 = prev_nonnote_insn (i2); if (i1 == NULL_RTX) return 0; return (INSN_P (i1) && rtx_equal_p (PATTERN (i1), PATTERN (i3)) && any_condjump_p (i2) && onlyjump_p (i2)); } /* Return nonzero if we have the same comparison insn as I1 two insns after I1. I1 is assumed to be a comparison insn. */ int same_cmp_following_p (rtx i1) { rtx i2, i3; /* Make sure we have a sequence of three insns. */ i2 = next_nonnote_insn (i1); if (i2 == NULL_RTX) return 0; i3 = next_nonnote_insn (i2); if (i3 == NULL_RTX) return 0; return (INSN_P (i3) && rtx_equal_p (PATTERN (i1), PATTERN (i3)) && any_condjump_p (i2) && onlyjump_p (i2)); } /* Return nonzero if OPERANDS are valid for stm (or ldm) that pushes (or pops) N registers. OPERANDS are assumed to be an array of registers. */ int h8300_regs_ok_for_stm (int n, rtx operands[]) { switch (n) { case 2: return ((REGNO (operands[0]) == 0 && REGNO (operands[1]) == 1) || (REGNO (operands[0]) == 2 && REGNO (operands[1]) == 3) || (REGNO (operands[0]) == 4 && REGNO (operands[1]) == 5)); case 3: return ((REGNO (operands[0]) == 0 && REGNO (operands[1]) == 1 && REGNO (operands[2]) == 2) || (REGNO (operands[0]) == 4 && REGNO (operands[1]) == 5 && REGNO (operands[2]) == 6)); case 4: return (REGNO (operands[0]) == 0 && REGNO (operands[1]) == 1 && REGNO (operands[2]) == 2 && REGNO (operands[3]) == 3); default: gcc_unreachable (); } } /* Return nonzero if register OLD_REG can be renamed to register NEW_REG. */ int h8300_hard_regno_rename_ok (unsigned int old_reg ATTRIBUTE_UNUSED, unsigned int new_reg) { /* Interrupt functions can only use registers that have already been saved by the prologue, even if they would normally be call-clobbered. */ if (h8300_current_function_interrupt_function_p () && !df_regs_ever_live_p (new_reg)) return 0; return 1; } /* Returns true if register REGNO is safe to be allocated as a scratch register in the current function. */ static bool h8300_hard_regno_scratch_ok (unsigned int regno) { if (h8300_current_function_interrupt_function_p () && ! WORD_REG_USED (regno)) return false; return true; } /* Return nonzero if X is a REG or SUBREG suitable as a base register. */ static int h8300_rtx_ok_for_base_p (rtx x, int strict) { /* Strip off SUBREG if any. */ if (GET_CODE (x) == SUBREG) x = SUBREG_REG (x); return (REG_P (x) && (strict ? REG_OK_FOR_BASE_STRICT_P (x) : REG_OK_FOR_BASE_NONSTRICT_P (x))); } /* Return nozero if X is a legitimate address. On the H8/300, a legitimate address has the form REG, REG+CONSTANT_ADDRESS or CONSTANT_ADDRESS. */ static bool h8300_legitimate_address_p (enum machine_mode mode, rtx x, bool strict) { /* The register indirect addresses like @er0 is always valid. */ if (h8300_rtx_ok_for_base_p (x, strict)) return 1; if (CONSTANT_ADDRESS_P (x)) return 1; if (TARGET_H8300SX && ( GET_CODE (x) == PRE_INC || GET_CODE (x) == PRE_DEC || GET_CODE (x) == POST_INC || GET_CODE (x) == POST_DEC) && h8300_rtx_ok_for_base_p (XEXP (x, 0), strict)) return 1; if (GET_CODE (x) == PLUS && CONSTANT_ADDRESS_P (XEXP (x, 1)) && h8300_rtx_ok_for_base_p (h8300_get_index (XEXP (x, 0), mode, 0), strict)) return 1; return 0; } /* Worker function for HARD_REGNO_NREGS. We pretend the MAC register is 32bits -- we don't have any data types on the H8 series to handle more than 32bits. */ int h8300_hard_regno_nregs (int regno ATTRIBUTE_UNUSED, enum machine_mode mode) { return (GET_MODE_SIZE (mode) + UNITS_PER_WORD - 1) / UNITS_PER_WORD; } /* Worker function for HARD_REGNO_MODE_OK. */ int h8300_hard_regno_mode_ok (int regno, enum machine_mode mode) { if (TARGET_H8300) /* If an even reg, then anything goes. Otherwise the mode must be QI or HI. */ return ((regno & 1) == 0) || (mode == HImode) || (mode == QImode); else /* MAC register can only be of SImode. Otherwise, anything goes. */ return regno == MAC_REG ? mode == SImode : 1; } /* Helper function for the move patterns. Make sure a move is legitimate. */ bool h8300_move_ok (rtx dest, rtx src) { rtx addr, other; /* Validate that at least one operand is a register. */ if (MEM_P (dest)) { if (MEM_P (src) || CONSTANT_P (src)) return false; addr = XEXP (dest, 0); other = src; } else if (MEM_P (src)) { addr = XEXP (src, 0); other = dest; } else return true; /* Validate that auto-inc doesn't affect OTHER. */ if (GET_RTX_CLASS (GET_CODE (addr)) != RTX_AUTOINC) return true; addr = XEXP (addr, 0); if (addr == stack_pointer_rtx) return register_no_sp_elim_operand (other, VOIDmode); else return !reg_overlap_mentioned_p(other, addr); } /* Perform target dependent optabs initialization. */ static void h8300_init_libfuncs (void) { set_optab_libfunc (smul_optab, HImode, "__mulhi3"); set_optab_libfunc (sdiv_optab, HImode, "__divhi3"); set_optab_libfunc (udiv_optab, HImode, "__udivhi3"); set_optab_libfunc (smod_optab, HImode, "__modhi3"); set_optab_libfunc (umod_optab, HImode, "__umodhi3"); } /* Worker function for TARGET_FUNCTION_VALUE. On the H8 the return value is in R0/R1. */ static rtx h8300_function_value (const_tree ret_type, const_tree fn_decl_or_type ATTRIBUTE_UNUSED, bool outgoing ATTRIBUTE_UNUSED) { return gen_rtx_REG (TYPE_MODE (ret_type), R0_REG); } /* Worker function for TARGET_LIBCALL_VALUE. On the H8 the return value is in R0/R1. */ static rtx h8300_libcall_value (enum machine_mode mode, const_rtx fun ATTRIBUTE_UNUSED) { return gen_rtx_REG (mode, R0_REG); } /* Worker function for TARGET_FUNCTION_VALUE_REGNO_P. On the H8, R0 is the only register thus used. */ static bool h8300_function_value_regno_p (const unsigned int regno) { return (regno == R0_REG); } /* Worker function for TARGET_RETURN_IN_MEMORY. */ static bool h8300_return_in_memory (const_tree type, const_tree fntype ATTRIBUTE_UNUSED) { return (TYPE_MODE (type) == BLKmode || GET_MODE_SIZE (TYPE_MODE (type)) > (TARGET_H8300 ? 4 : 8)); } /* We emit the entire trampoline here. Depending on the pointer size, we use a different trampoline. Pmode == HImode vvvv context 1 0000 7903xxxx mov.w #0x1234,r3 2 0004 5A00xxxx jmp @0x1234 ^^^^ function Pmode == SImode vvvvvvvv context 2 0000 7A03xxxxxxxx mov.l #0x12345678,er3 3 0006 5Axxxxxx jmp @0x123456 ^^^^^^ function */ static void h8300_trampoline_init (rtx m_tramp, tree fndecl, rtx cxt) { rtx fnaddr = XEXP (DECL_RTL (fndecl), 0); rtx mem; if (Pmode == HImode) { mem = adjust_address (m_tramp, HImode, 0); emit_move_insn (mem, GEN_INT (0x7903)); mem = adjust_address (m_tramp, Pmode, 2); emit_move_insn (mem, cxt); mem = adjust_address (m_tramp, HImode, 4); emit_move_insn (mem, GEN_INT (0x5a00)); mem = adjust_address (m_tramp, Pmode, 6); emit_move_insn (mem, fnaddr); } else { rtx tem; mem = adjust_address (m_tramp, HImode, 0); emit_move_insn (mem, GEN_INT (0x7a03)); mem = adjust_address (m_tramp, Pmode, 2); emit_move_insn (mem, cxt); tem = copy_to_reg (fnaddr); emit_insn (gen_andsi3 (tem, tem, GEN_INT (0x00ffffff))); emit_insn (gen_iorsi3 (tem, tem, GEN_INT (0x5a000000))); mem = adjust_address (m_tramp, SImode, 6); emit_move_insn (mem, tem); } } /* Initialize the GCC target structure. */ #undef TARGET_ATTRIBUTE_TABLE #define TARGET_ATTRIBUTE_TABLE h8300_attribute_table #undef TARGET_ASM_ALIGNED_HI_OP #define TARGET_ASM_ALIGNED_HI_OP "\t.word\t" #undef TARGET_ASM_FILE_START #define TARGET_ASM_FILE_START h8300_file_start #undef TARGET_ASM_FILE_START_FILE_DIRECTIVE #define TARGET_ASM_FILE_START_FILE_DIRECTIVE true #undef TARGET_ASM_FILE_END #define TARGET_ASM_FILE_END h8300_file_end #undef TARGET_PRINT_OPERAND #define TARGET_PRINT_OPERAND h8300_print_operand #undef TARGET_PRINT_OPERAND_ADDRESS #define TARGET_PRINT_OPERAND_ADDRESS h8300_print_operand_address #undef TARGET_PRINT_OPERAND_PUNCT_VALID_P #define TARGET_PRINT_OPERAND_PUNCT_VALID_P h8300_print_operand_punct_valid_p #undef TARGET_ENCODE_SECTION_INFO #define TARGET_ENCODE_SECTION_INFO h8300_encode_section_info #undef TARGET_INSERT_ATTRIBUTES #define TARGET_INSERT_ATTRIBUTES h8300_insert_attributes #undef TARGET_REGISTER_MOVE_COST #define TARGET_REGISTER_MOVE_COST h8300_register_move_cost #undef TARGET_RTX_COSTS #define TARGET_RTX_COSTS h8300_rtx_costs #undef TARGET_INIT_LIBFUNCS #define TARGET_INIT_LIBFUNCS h8300_init_libfuncs #undef TARGET_FUNCTION_VALUE #define TARGET_FUNCTION_VALUE h8300_function_value #undef TARGET_LIBCALL_VALUE #define TARGET_LIBCALL_VALUE h8300_libcall_value #undef TARGET_FUNCTION_VALUE_REGNO_P #define TARGET_FUNCTION_VALUE_REGNO_P h8300_function_value_regno_p #undef TARGET_RETURN_IN_MEMORY #define TARGET_RETURN_IN_MEMORY h8300_return_in_memory #undef TARGET_FUNCTION_ARG #define TARGET_FUNCTION_ARG h8300_function_arg #undef TARGET_FUNCTION_ARG_ADVANCE #define TARGET_FUNCTION_ARG_ADVANCE h8300_function_arg_advance #undef TARGET_MACHINE_DEPENDENT_REORG #define TARGET_MACHINE_DEPENDENT_REORG h8300_reorg #undef TARGET_HARD_REGNO_SCRATCH_OK #define TARGET_HARD_REGNO_SCRATCH_OK h8300_hard_regno_scratch_ok #undef TARGET_LEGITIMATE_ADDRESS_P #define TARGET_LEGITIMATE_ADDRESS_P h8300_legitimate_address_p #undef TARGET_CAN_ELIMINATE #define TARGET_CAN_ELIMINATE h8300_can_eliminate #undef TARGET_CONDITIONAL_REGISTER_USAGE #define TARGET_CONDITIONAL_REGISTER_USAGE h8300_conditional_register_usage #undef TARGET_TRAMPOLINE_INIT #define TARGET_TRAMPOLINE_INIT h8300_trampoline_init #undef TARGET_OPTION_OVERRIDE #define TARGET_OPTION_OVERRIDE h8300_option_override #undef TARGET_MODE_DEPENDENT_ADDRESS_P #define TARGET_MODE_DEPENDENT_ADDRESS_P h8300_mode_dependent_address_p struct gcc_target targetm = TARGET_INITIALIZER;
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