[libfirm] / ir / be / sparc / bearch_sparc.c

/*
 * Copyright (C) 1995-2010 University of Karlsruhe.  All right reserved.
 *
 * This file is part of libFirm.
 *
 * This file may be distributed and/or modified under the terms of the
 * GNU General Public License version 2 as published by the Free Software
 * Foundation and appearing in the file LICENSE.GPL included in the
 * packaging of this file.
 *
 * Licensees holding valid libFirm Professional Edition licenses may use
 * this file in accordance with the libFirm Commercial License.
 * Agreement provided with the Software.
 *
 * This file is provided AS IS with NO WARRANTY OF ANY KIND, INCLUDING THE
 * WARRANTY OF DESIGN, MERCHANTABILITY AND FITNESS FOR A PARTICULAR
 * PURPOSE.
 */

/**
 * @file
 * @brief    The main sparc backend driver file.
 * @version  $Id$
 */
#include "config.h"

#include "lc_opts.h"
#include "lc_opts_enum.h"

#include "irgwalk.h"
#include "irprog.h"
#include "irprintf.h"
#include "ircons.h"
#include "irgmod.h"
#include "irgopt.h"
#include "iroptimize.h"
#include "irtools.h"
#include "irdump.h"
#include "lowering.h"

#include "bitset.h"
#include "debug.h"
#include "array_t.h"
#include "error.h"
#include "util.h"

#include "../bearch.h"
#include "../benode.h"
#include "../belower.h"
#include "../besched.h"
#include "be.h"
#include "../bemachine.h"
#include "../beilpsched.h"
#include "../bemodule.h"
#include "../beirg.h"
#include "../bespillslots.h"
#include "../begnuas.h"
#include "../belistsched.h"
#include "../beflags.h"

#include "bearch_sparc_t.h"

#include "sparc_new_nodes.h"
#include "gen_sparc_regalloc_if.h"
#include "sparc_transform.h"
#include "sparc_emitter.h"

DEBUG_ONLY(static firm_dbg_module_t *dbg = NULL;)

static arch_irn_class_t sparc_classify(const ir_node *node)
{
        (void) node;
        return 0;
}

static ir_entity *sparc_get_frame_entity(const ir_node *node)
{
        if (is_sparc_FrameAddr(node)) {
                const sparc_attr_t *attr = get_sparc_attr_const(node);
                return attr->immediate_value_entity;
        }

        if (sparc_has_load_store_attr(node)) {
                const sparc_load_store_attr_t *load_store_attr
                        = get_sparc_load_store_attr_const(node);
                if (load_store_attr->is_frame_entity) {
                        return load_store_attr->base.immediate_value_entity;
                }
        }

        return NULL;
}

/**
 * This function is called by the generic backend to correct offsets for
 * nodes accessing the stack.
 */
static void sparc_set_frame_offset(ir_node *node, int offset)
{
        sparc_attr_t *attr = get_sparc_attr(node);
        attr->immediate_value += offset;

        /* must be a FrameAddr or a load/store node with frame_entity */
        assert(is_sparc_FrameAddr(node) ||
                        get_sparc_load_store_attr_const(node)->is_frame_entity);
}

static int sparc_get_sp_bias(const ir_node *node)
{
        if (is_sparc_Save(node)) {
                const sparc_save_attr_t *attr = get_sparc_save_attr_const(node);
                /* Note we do not retport the change of the SPARC_MIN_STACKSIZE
                 * size, since we have additional magic in the emitter which
                 * calculates that! */
                assert(attr->initial_stacksize >= SPARC_MIN_STACKSIZE);
                return attr->initial_stacksize - SPARC_MIN_STACKSIZE;
        }
        return 0;
}

/* fill register allocator interface */

static const arch_irn_ops_t sparc_irn_ops = {
        sparc_classify,
        sparc_get_frame_entity,
        sparc_set_frame_offset,
        sparc_get_sp_bias,
        NULL,    /* get_inverse             */
        NULL,    /* get_op_estimated_cost   */
        NULL,    /* possible_memory_operand */
        NULL,    /* perform_memory_operand  */
};

/**
 * Transforms the standard firm graph into
 * a SPARC firm graph
 */
static void sparc_prepare_graph(void *self)
{
        sparc_code_gen_t *cg = self;

        /* transform FIRM into SPARC asm nodes */
        sparc_transform_graph(cg);

        if (cg->dump)
                dump_ir_graph(cg->irg, "transformed");
}

static bool sparc_modifies_flags(const ir_node *node)
{
        return arch_irn_get_flags(node) & sparc_arch_irn_flag_modifies_flags;
}

static bool sparc_modifies_fp_flags(const ir_node *node)
{
        return arch_irn_get_flags(node) & sparc_arch_irn_flag_modifies_fp_flags;
}

static void sparc_before_ra(void *self)
{
        sparc_code_gen_t *cg = self;
        /* fixup flags register */
        be_sched_fix_flags(cg->irg, &sparc_reg_classes[CLASS_sparc_flags_class],
                           NULL, sparc_modifies_flags);
        be_sched_fix_flags(cg->irg, &sparc_reg_classes[CLASS_sparc_fpflags_class],
                           NULL, sparc_modifies_fp_flags);
}

/**
 * transform reload node => load
 */
static void transform_Reload(ir_node *node)
{
        ir_node   *block  = get_nodes_block(node);
        dbg_info  *dbgi   = get_irn_dbg_info(node);
        ir_node   *ptr    = get_irn_n(node, be_pos_Spill_frame);
        ir_node   *mem    = get_irn_n(node, be_pos_Reload_mem);
        ir_mode   *mode   = get_irn_mode(node);
        ir_entity *entity = be_get_frame_entity(node);
        const arch_register_t *reg;
        ir_node   *proj;
        ir_node   *load;

        ir_node  *sched_point = sched_prev(node);

        load = new_bd_sparc_Ld_imm(dbgi, block, ptr, mem, mode, entity, 0, true);
        sched_add_after(sched_point, load);
        sched_remove(node);

        proj = new_rd_Proj(dbgi, load, mode, pn_sparc_Ld_res);

        reg = arch_get_irn_register(node);
        arch_set_irn_register(proj, reg);

        exchange(node, proj);
}

/**
 * transform spill node => store
 */
static void transform_Spill(ir_node *node)
{
        ir_node   *block  = get_nodes_block(node);
        dbg_info  *dbgi   = get_irn_dbg_info(node);
        ir_node   *ptr    = get_irn_n(node, be_pos_Spill_frame);
        ir_node   *mem    = new_NoMem();
        ir_node   *val    = get_irn_n(node, be_pos_Spill_val);
        ir_mode   *mode   = get_irn_mode(val);
        ir_entity *entity = be_get_frame_entity(node);
        ir_node   *sched_point;
        ir_node   *store;

        sched_point = sched_prev(node);
        store = new_bd_sparc_St_imm(dbgi, block, val, ptr, mem, mode, entity, 0, true);
        sched_remove(node);
        sched_add_after(sched_point, store);

        exchange(node, store);
}

/**
 * walker to transform be_Spill and be_Reload nodes
 */
static void sparc_after_ra_walker(ir_node *block, void *data)
{
        ir_node *node, *prev;
        (void) data;

        for (node = sched_last(block); !sched_is_begin(node); node = prev) {
                prev = sched_prev(node);

                if (be_is_Reload(node)) {
                        transform_Reload(node);
                } else if (be_is_Spill(node)) {
                        transform_Spill(node);
                }
        }
}

static void sparc_collect_frame_entity_nodes(ir_node *node, void *data)
{
        be_fec_env_t  *env = data;
        const ir_mode *mode;
        int            align;
        ir_entity     *entity;
        const sparc_load_store_attr_t *attr;

        if (be_is_Reload(node) && be_get_frame_entity(node) == NULL) {
                mode  = get_irn_mode(node);
                align = get_mode_size_bytes(mode);
                be_node_needs_frame_entity(env, node, mode, align);
                return;
        }

        if (!is_sparc_Ld(node) && !is_sparc_Ldf(node))
                return;

        attr   = get_sparc_load_store_attr_const(node);
        entity = attr->base.immediate_value_entity;
        mode   = attr->load_store_mode;
        if (entity != NULL)
                return;
        if (!attr->is_frame_entity)
                return;
        if (arch_irn_get_flags(node) & sparc_arch_irn_flag_needs_64bit_spillslot)
                mode = mode_Lu;
        align  = get_mode_size_bytes(mode);
        be_node_needs_frame_entity(env, node, mode, align);
}

static void sparc_set_frame_entity(ir_node *node, ir_entity *entity)
{
        if (is_be_node(node)) {
                be_node_set_frame_entity(node, entity);
        } else {
                /* we only say be_node_needs_frame_entity on nodes with load_store
                 * attributes, so this should be fine */
                sparc_load_store_attr_t *attr = get_sparc_load_store_attr(node);
                assert(attr->is_frame_entity);
                assert(attr->base.immediate_value_entity == NULL);
                attr->base.immediate_value_entity = entity;
        }
}

static void sparc_after_ra(void *self)
{
        sparc_code_gen_t *cg      = self;
        ir_graph         *irg     = cg->irg;
        be_fec_env_t     *fec_env = be_new_frame_entity_coalescer(irg);

        irg_walk_graph(irg, NULL, sparc_collect_frame_entity_nodes, fec_env);
        be_assign_entities(fec_env, sparc_set_frame_entity);
        be_free_frame_entity_coalescer(fec_env);

        irg_block_walk_graph(cg->irg, NULL, sparc_after_ra_walker, NULL);
}

/**
 * Emits the code, closes the output file and frees
 * the code generator interface.
 */
static void sparc_emit_and_done(void *self)
{
        sparc_code_gen_t *cg  = self;
        ir_graph         *irg = cg->irg;

        sparc_emit_routine(irg);

        /* de-allocate code generator */
        free(cg);
}

static void *sparc_cg_init(ir_graph *irg);

static const arch_code_generator_if_t sparc_code_gen_if = {
        sparc_cg_init,
        NULL,                 /* get_pic_base hook */
        NULL,                 /* before abi introduce hook */
        sparc_prepare_graph,
        NULL,                 /* spill hook */
        sparc_before_ra,      /* before register allocation hook */
        sparc_after_ra,       /* after register allocation hook */
        NULL,
        sparc_emit_and_done
};

/**
 * Initializes the code generator.
 */
static void *sparc_cg_init(ir_graph *irg)
{
        sparc_isa_t      *isa = (sparc_isa_t *) be_get_irg_arch_env(irg);
        sparc_code_gen_t *cg  = XMALLOCZ(sparc_code_gen_t);

        cg->impl      = &sparc_code_gen_if;
        cg->irg       = irg;
        cg->isa       = isa;
        cg->dump      = (be_get_irg_options(irg)->dump_flags & DUMP_BE) != 0;
        cg->constants = pmap_create();

        /* enter the current code generator */
        isa->cg = cg;

        return (arch_code_generator_t*) cg;
}

const arch_isa_if_t sparc_isa_if;
static sparc_isa_t sparc_isa_template = {
        {
                &sparc_isa_if,                      /* isa interface implementation */
                &sparc_gp_regs[REG_SP],             /* stack pointer register */
                &sparc_gp_regs[REG_FRAME_POINTER],  /* base pointer register */
                &sparc_reg_classes[CLASS_sparc_gp], /* link pointer register class */
                -1,                                 /* stack direction */
                3,                                  /* power of two stack alignment
                                                       for calls */
                NULL,                               /* main environment */
                7,                                  /* costs for a spill instruction */
                5,                                  /* costs for a reload instruction */
                true,                               /* custom abi handling */
        },
        NULL                                            /* current code generator */
};

/**
 * rewrite unsigned->float conversion.
 * Sparc has no instruction for this so instead we do the following:
 *
 *   int    signed_x = unsigned_value_x;
 *   double res      = signed_x;
 *   if (signed_x < 0)
 *       res += 4294967296. ;
 *   return (float) res;
 */
static void rewrite_unsigned_float_Conv(ir_node *node)
{
        ir_graph *irg         = get_irn_irg(node);
        dbg_info *dbgi        = get_irn_dbg_info(node);
        ir_node  *lower_block = get_nodes_block(node);

        part_block(node);

        {
                ir_node  *block       = get_nodes_block(node);
                ir_node  *unsigned_x  = get_Conv_op(node);
                ir_mode  *mode_u      = get_irn_mode(unsigned_x);
                ir_mode  *mode_s      = find_signed_mode(mode_u);
                ir_mode  *mode_d      = mode_D;
                ir_node  *signed_x    = new_rd_Conv(dbgi, block, unsigned_x, mode_s);
                ir_node  *res         = new_rd_Conv(dbgi, block, signed_x, mode_d);
                ir_node  *zero        = new_r_Const(irg, get_mode_null(mode_s));
                ir_node  *cmp         = new_rd_Cmp(dbgi, block, signed_x, zero);
                ir_node  *proj_lt     = new_r_Proj(cmp, mode_b, pn_Cmp_Lt);
                ir_node  *cond        = new_rd_Cond(dbgi, block, proj_lt);
                ir_node  *proj_true   = new_r_Proj(cond, mode_X, pn_Cond_true);
                ir_node  *proj_false  = new_r_Proj(cond, mode_X, pn_Cond_false);
                ir_node  *in_true[1]  = { proj_true };
                ir_node  *in_false[1] = { proj_false };
                ir_node  *true_block  = new_r_Block(irg, ARRAY_SIZE(in_true), in_true);
                ir_node  *false_block = new_r_Block(irg, ARRAY_SIZE(in_false),in_false);
                ir_node  *true_jmp    = new_r_Jmp(true_block);
                ir_node  *false_jmp   = new_r_Jmp(false_block);
                tarval   *correction  = new_tarval_from_double(4294967296., mode_d);
                ir_node  *c_const     = new_r_Const(irg, correction);
                ir_node  *fadd        = new_rd_Add(dbgi, true_block, res, c_const,
                                                   mode_d);

                ir_node  *lower_in[2] = { true_jmp, false_jmp };
                ir_node  *phi_in[2]   = { fadd, res };
                ir_mode  *dest_mode   = get_irn_mode(node);
                ir_node  *phi;
                ir_node  *res_conv;

                set_irn_in(lower_block, ARRAY_SIZE(lower_in), lower_in);
                phi = new_r_Phi(lower_block, ARRAY_SIZE(phi_in), phi_in, mode_d);
                assert(get_Block_phis(lower_block) == NULL);
                set_Block_phis(lower_block, phi);
                set_Phi_next(phi, NULL);

                res_conv = new_rd_Conv(dbgi, lower_block, phi, dest_mode);

                exchange(node, res_conv);
        }
}

static int sparc_rewrite_Conv(ir_node *node, void *ctx)
{
        (void) ctx;
        ir_mode *to_mode   = get_irn_mode(node);
        ir_node *op        = get_Conv_op(node);
        ir_mode *from_mode = get_irn_mode(op);

        if (mode_is_float(to_mode) && mode_is_int(from_mode)
                        && get_mode_size_bits(from_mode) == 32
                        && !mode_is_signed(from_mode)) {
                rewrite_unsigned_float_Conv(node);
                return 1;
        }

        return 0;
}

static void sparc_handle_intrinsics(void)
{
        ir_type *tp, *int_tp, *uint_tp;
        i_record records[8];
        size_t n_records = 0;

        runtime_rt rt_iMod, rt_uMod;

#define ID(x) new_id_from_chars(x, sizeof(x)-1)

        int_tp  = new_type_primitive(mode_Is);
        uint_tp = new_type_primitive(mode_Iu);

        /* we need to rewrite some forms of int->float conversions */
        {
                i_instr_record *map_Conv = &records[n_records++].i_instr;

                map_Conv->kind     = INTRINSIC_INSTR;
                map_Conv->op       = op_Conv;
                map_Conv->i_mapper = sparc_rewrite_Conv;
        }
        /* SPARC has no signed mod instruction ... */
        {
                i_instr_record *map_Mod = &records[n_records++].i_instr;

                tp = new_type_method(2, 1);
                set_method_param_type(tp, 0, int_tp);
                set_method_param_type(tp, 1, int_tp);
                set_method_res_type(tp, 0, int_tp);

                rt_iMod.ent             = new_entity(get_glob_type(), ID(".rem"), tp);
                set_entity_ld_ident(rt_iMod.ent, ID(".rem"));
                rt_iMod.mode            = mode_T;
                rt_iMod.res_mode        = mode_Is;
                rt_iMod.mem_proj_nr     = pn_Mod_M;
                rt_iMod.regular_proj_nr = pn_Mod_X_regular;
                rt_iMod.exc_proj_nr     = pn_Mod_X_except;
                rt_iMod.exc_mem_proj_nr = pn_Mod_M;
                rt_iMod.res_proj_nr     = pn_Mod_res;

                set_entity_visibility(rt_iMod.ent, ir_visibility_external);

                map_Mod->kind     = INTRINSIC_INSTR;
                map_Mod->op       = op_Mod;
                map_Mod->i_mapper = (i_mapper_func)i_mapper_RuntimeCall;
                map_Mod->ctx      = &rt_iMod;
        }
        /* ... nor an unsigned mod. */
        {
                i_instr_record *map_Mod = &records[n_records++].i_instr;

                tp = new_type_method(2, 1);
                set_method_param_type(tp, 0, uint_tp);
                set_method_param_type(tp, 1, uint_tp);
                set_method_res_type(tp, 0, uint_tp);

                rt_uMod.ent             = new_entity(get_glob_type(), ID(".urem"), tp);
                set_entity_ld_ident(rt_uMod.ent, ID(".urem"));
                rt_uMod.mode            = mode_T;
                rt_uMod.res_mode        = mode_Iu;
                rt_uMod.mem_proj_nr     = pn_Mod_M;
                rt_uMod.regular_proj_nr = pn_Mod_X_regular;
                rt_uMod.exc_proj_nr     = pn_Mod_X_except;
                rt_uMod.exc_mem_proj_nr = pn_Mod_M;
                rt_uMod.res_proj_nr     = pn_Mod_res;

                set_entity_visibility(rt_uMod.ent, ir_visibility_external);

                map_Mod->kind     = INTRINSIC_INSTR;
                map_Mod->op       = op_Mod;
                map_Mod->i_mapper = (i_mapper_func)i_mapper_RuntimeCall;
                map_Mod->ctx      = &rt_uMod;
        }

        assert(n_records < ARRAY_SIZE(records));
        lower_intrinsics(records, n_records, /*part_block_used=*/ true);
}

/**
 * Initializes the backend ISA
 */
static arch_env_t *sparc_init(FILE *outfile)
{
        static int run_once = 0;
        sparc_isa_t *isa;

        if (run_once)
                return NULL;
        run_once = 1;

        isa = XMALLOC(sparc_isa_t);
        memcpy(isa, &sparc_isa_template, sizeof(*isa));

        be_emit_init(outfile);

        sparc_register_init();
        sparc_create_opcodes(&sparc_irn_ops);
        sparc_handle_intrinsics();

        return &isa->base;
}

/**
 * Closes the output file and frees the ISA structure.
 */
static void sparc_done(void *self)
{
        sparc_isa_t *isa = self;

        /* emit now all global declarations */
        be_gas_emit_decls(isa->base.main_env);

        be_emit_exit();
        free(self);
}

static unsigned sparc_get_n_reg_class(void)
{
        return N_CLASSES;
}

static const arch_register_class_t *sparc_get_reg_class(unsigned i)
{
        assert(i < N_CLASSES);
        return &sparc_reg_classes[i];
}



/**
 * Get the register class which shall be used to store a value of a given mode.
 * @param self The this pointer.
 * @param mode The mode in question.
 * @return A register class which can hold values of the given mode.
 */
static const arch_register_class_t *sparc_get_reg_class_for_mode(const ir_mode *mode)
{
        if (mode_is_float(mode))
                return &sparc_reg_classes[CLASS_sparc_fp];
        else
                return &sparc_reg_classes[CLASS_sparc_gp];
}

static int sparc_to_appear_in_schedule(void *block_env, const ir_node *irn)
{
        (void) block_env;

        if (!is_sparc_irn(irn))
                return -1;

        return 1;
}

/**
 * Initializes the code generator interface.
 */
static const arch_code_generator_if_t *sparc_get_code_generator_if(
                void *self)
{
        (void) self;
        return &sparc_code_gen_if;
}

list_sched_selector_t sparc_sched_selector;

/**
 * Returns the reg_pressure scheduler with to_appear_in_schedule() overloaded
 */
static const list_sched_selector_t *sparc_get_list_sched_selector(
                const void *self, list_sched_selector_t *selector)
{
        (void) self;
        (void) selector;

        sparc_sched_selector = trivial_selector;
        sparc_sched_selector.to_appear_in_schedule = sparc_to_appear_in_schedule;
        return &sparc_sched_selector;
}

static const ilp_sched_selector_t *sparc_get_ilp_sched_selector(
                const void *self)
{
        (void) self;
        return NULL;
}

/**
 * Returns the necessary byte alignment for storing a register of given class.
 */
static int sparc_get_reg_class_alignment(const arch_register_class_t *cls)
{
        ir_mode *mode = arch_register_class_mode(cls);
        return get_mode_size_bytes(mode);
}

static void sparc_lower_for_target(void)
{
        int i;
        int n_irgs = get_irp_n_irgs();

        /* TODO, doubleword lowering and others */

        for (i = 0; i < n_irgs; ++i) {
                ir_graph *irg = get_irp_irg(i);
                lower_switch(irg, 256, false);
        }
}

/**
 * Returns the libFirm configuration parameter for this backend.
 */
static const backend_params *sparc_get_backend_params(void)
{
        static const ir_settings_arch_dep_t arch_dep = {
                1,     /* also_use_subs */
                1,     /* maximum_shifts */
                31,    /* highest_shift_amount */
                NULL,  /* evaluate_cost_func */
                1,     /* allow mulhs */
                1,     /* allow mulhu */
                32,    /* max_bits_for_mulh */
        };
        static backend_params p = {
                0,     /* no inline assembly */
                0,     /* no support for RotL nodes */
                1,     /* big endian */
                sparc_lower_for_target, /* lowering callback */
                &arch_dep,              /* will be set later */
                NULL,  /* parameter for if conversion */
                NULL,  /* float arithmetic mode */
                0,     /* no trampoline support: size 0 */
                0,     /* no trampoline support: align 0 */
                NULL,  /* no trampoline support: no trampoline builder */
                4      /* alignment of stack parameter: typically 4 (32bit) or 8 (64bit) */
        };
        return &p;
}

static const be_execution_unit_t ***sparc_get_allowed_execution_units(
                const ir_node *irn)
{
        (void) irn;
        /* TODO */
        panic("sparc_get_allowed_execution_units not implemented yet");
}

static const be_machine_t *sparc_get_machine(const void *self)
{
        (void) self;
        /* TODO */
        panic("sparc_get_machine not implemented yet");
}

static ir_graph **sparc_get_backend_irg_list(const void *self,
                                             ir_graph ***irgs)
{
        (void) self;
        (void) irgs;
        return NULL;
}

static asm_constraint_flags_t sparc_parse_asm_constraint(const char **c)
{
        (void) c;
        return ASM_CONSTRAINT_FLAG_INVALID;
}

static int sparc_is_valid_clobber(const char *clobber)
{
        (void) clobber;
        return 0;
}

const arch_isa_if_t sparc_isa_if = {
        sparc_init,
        sparc_done,
        NULL,                /* handle intrinsics */
        sparc_get_n_reg_class,
        sparc_get_reg_class,
        sparc_get_reg_class_for_mode,
        NULL,
        sparc_get_code_generator_if,
        sparc_get_list_sched_selector,
        sparc_get_ilp_sched_selector,
        sparc_get_reg_class_alignment,
        sparc_get_backend_params,
        sparc_get_allowed_execution_units,
        sparc_get_machine,
        sparc_get_backend_irg_list,
        NULL,                    /* mark remat */
        sparc_parse_asm_constraint,
        sparc_is_valid_clobber
};

BE_REGISTER_MODULE_CONSTRUCTOR(be_init_arch_sparc);
void be_init_arch_sparc(void)
{
        be_register_isa_if("sparc", &sparc_isa_if);
        FIRM_DBG_REGISTER(dbg, "firm.be.sparc.cg");
        sparc_init_transform();
        sparc_init_emitter();
}