xref: /dports/devel/libfirm/libfirm-1.21.0/ir/be/bearch.h

/*
 * Copyright (C) 1995-2011 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       Processor architecture specification.
 * @author      Sebastian Hack
 */
#ifndef FIRM_BE_BEARCH_H
#define FIRM_BE_BEARCH_H

#include <stdbool.h>

#include "firm_types.h"
#include "bitset.h"
#include "obst.h"
#include "raw_bitset.h"
#include "irop_t.h"

#include "be_types.h"
#include "beinfo.h"
#include "be.h"
#include "beirg.h"
#include "error.h"

/**
 * this constant is returned by the get_sp_bias functions if the stack
 * is reset (usually because the frame pointer is copied to the stack
 * pointer
 */
#define SP_BIAS_RESET      INT_MIN

typedef enum arch_register_class_flags_t {
	arch_register_class_flag_none      = 0,
	/** don't do automatic register allocation for this class */
	arch_register_class_flag_manual_ra = 1U << 0,
	/** the register models an abstract state (example: fpu rounding mode) */
	arch_register_class_flag_state     = 1U << 1
} arch_register_class_flags_t;
ENUM_BITSET(arch_register_class_flags_t)

typedef enum arch_register_type_t {
	arch_register_type_none         = 0,
	/** Do not consider this register when allocating. */
	arch_register_type_ignore       = 1U << 0,
	/** The emitter can choose an arbitrary register. The register fulfills any
	 * register constraints as long as the register class matches */
	arch_register_type_joker        = 1U << 1,
	/** This is just a virtual register. Virtual registers fulfill any register
	 * constraints as long as the register class matches. It is a allowed to
	 * have multiple definitions for the same virtual register at a point */
	arch_register_type_virtual      = 1U << 2,
	/** The register represents a state that should be handled by bestate
	 * code */
	arch_register_type_state        = 1U << 3,
} arch_register_type_t;
ENUM_BITSET(arch_register_type_t)

/**
 * Different types of register allocation requirements.
 */
typedef enum arch_register_req_type_t {
	/** No register requirement. */
	arch_register_req_type_none              = 0,
	/** All registers in the class are allowed. */
	arch_register_req_type_normal            = 1U << 0,
	/** Only a real subset of the class is allowed. */
	arch_register_req_type_limited           = 1U << 1,
	/** The register should be equal to another one at the node. */
	arch_register_req_type_should_be_same    = 1U << 2,
	/** The register must be unequal from some other at the node. */
	arch_register_req_type_must_be_different = 1U << 3,
	/** The registernumber should be aligned (in case of multiregister values)*/
	arch_register_req_type_aligned           = 1U << 4,
	/** ignore while allocating registers */
	arch_register_req_type_ignore            = 1U << 5,
	/** the output produces a new value for the stack pointer
	 * (this is not really a constraint but a marker to guide the stackpointer
	 * rewiring logic) */
	arch_register_req_type_produces_sp       = 1U << 6,
} arch_register_req_type_t;
ENUM_BITSET(arch_register_req_type_t)

extern const arch_register_req_t *arch_no_register_req;

/**
 * Print information about a register requirement in human readable form
 * @param F   output stream/file
 * @param req The requirements structure to format.
 */
void arch_dump_register_req(FILE *F, const arch_register_req_t *req,
                            const ir_node *node);

void arch_dump_register_reqs(FILE *F, const ir_node *node);
void arch_dump_reqs_and_registers(FILE *F, const ir_node *node);

void arch_set_frame_offset(ir_node *irn, int bias);

ir_entity *arch_get_frame_entity(const ir_node *irn);
int        arch_get_sp_bias(ir_node *irn);

int             arch_get_op_estimated_cost(const ir_node *irn);
arch_inverse_t *arch_get_inverse(const ir_node *irn, int i,
                                 arch_inverse_t *inverse,
                                 struct obstack *obstack);
int             arch_possible_memory_operand(const ir_node *irn,
                                             unsigned int i);
void            arch_perform_memory_operand(ir_node *irn, ir_node *spill,
                                            unsigned int i);

/**
 * Get the register allocated for a value.
 */
const arch_register_t *arch_get_irn_register(const ir_node *irn);

/**
 * Assign register to a value
 */
void arch_set_irn_register(ir_node *irn, const arch_register_t *reg);

/**
 * Set the register for a certain output operand.
 */
void arch_set_irn_register_out(ir_node *irn, unsigned pos, const arch_register_t *r);

const arch_register_t *arch_get_irn_register_out(const ir_node *irn, unsigned pos);
const arch_register_t *arch_get_irn_register_in(const ir_node *irn, int pos);

/**
 * Get register constraints for an operand at position @p
 */
static inline const arch_register_req_t *arch_get_irn_register_req_in(
		const ir_node *node, int pos)
{
	const backend_info_t *info = be_get_info(node);
	if (info->in_reqs == NULL)
		return arch_no_register_req;
	return info->in_reqs[pos];
}

/**
 * Get register constraint for a produced result (the @p pos result)
 */
static inline const arch_register_req_t *arch_get_irn_register_req_out(
		const ir_node *node, unsigned pos)
{
	const backend_info_t *info = be_get_info(node);
	if (info->out_infos == NULL)
		return arch_no_register_req;
	return info->out_infos[pos].req;
}

static inline void arch_set_irn_register_req_out(ir_node *node, unsigned pos,
		const arch_register_req_t *req)
{
	backend_info_t *info = be_get_info(node);
	assert(pos < (unsigned)ARR_LEN(info->out_infos));
	info->out_infos[pos].req = req;
}

static inline void arch_set_irn_register_reqs_in(ir_node *node,
		const arch_register_req_t **reqs)
{
	backend_info_t *info = be_get_info(node);
	info->in_reqs = reqs;
}

static inline const arch_register_req_t **arch_get_irn_register_reqs_in(
		const ir_node *node)
{
	backend_info_t *info = be_get_info(node);
	return info->in_reqs;
}

const arch_register_req_t *arch_get_irn_register_req(const ir_node *node);

/**
 * Get the flags of a node.
 * @param irn The node.
 * @return The flags.
 */
arch_irn_flags_t arch_get_irn_flags(const ir_node *irn);

void arch_set_irn_flags(ir_node *node, arch_irn_flags_t flags);
void arch_add_irn_flags(ir_node *node, arch_irn_flags_t flags);

#define arch_irn_is(irn, flag) ((arch_get_irn_flags(irn) & arch_irn_flags_ ## flag) != 0)

static inline unsigned arch_get_irn_n_outs(const ir_node *node)
{
	backend_info_t *info = be_get_info(node);
	if (info->out_infos == NULL)
		return 0;

	return (unsigned)ARR_LEN(info->out_infos);
}

/**
 * Start codegeneration
 */
arch_env_t *arch_env_begin_codegeneration(const arch_isa_if_t *isa,
                                          be_main_env_t *main_env);

/**
 * Register an instruction set architecture
 */
void be_register_isa_if(const char *name, const arch_isa_if_t *isa);

/**
 * A register.
 */
struct arch_register_t {
	const char                  *name;         /**< The name of the register. */
	const arch_register_class_t *reg_class;    /**< The class of the register */
	unsigned short               index;        /**< The index of the register in
	                                                the class. */
	unsigned short               global_index; /**< The global index this
												    register in the architecture. */
	arch_register_type_t         type;         /**< The type of the register. */
	/** register constraint allowing just this register */
	const arch_register_req_t   *single_req;
	/** register number in dwarf debugging format */
	unsigned short               dwarf_number;
};

/**
 * A class of registers.
 * Like general purpose or floating point.
 */
struct arch_register_class_t {
	unsigned                     index;   /**< index of this register class */
	const char                  *name;    /**< The name of the register class.*/
	unsigned                     n_regs;  /**< Number of registers in this
	                                           class. */
	ir_mode                     *mode;    /**< The mode of the register class.*/
	const arch_register_t       *regs;    /**< The array of registers. */
	arch_register_class_flags_t  flags;   /**< register class flags. */
	const arch_register_req_t   *class_req;
};

/** return the number of registers in this register class */
#define arch_register_class_n_regs(cls) ((cls)->n_regs)

/** return the largest mode of this register class */
#define arch_register_class_mode(cls) ((cls)->mode)

/** return the name of this register class */
#define arch_register_class_name(cls) ((cls)->name)

/** return the index of this register class */
#define arch_register_class_index(cls)  ((cls)->index)

/** return the register class flags */
#define arch_register_class_flags(cls) ((cls)->flags)

static inline const arch_register_t *arch_register_for_index(
		const arch_register_class_t *cls, unsigned idx)
{
	assert(idx < cls->n_regs);
	return &cls->regs[idx];
}

/**
 * Convenience macro to check for set constraints.
 * @param req   A pointer to register requirements.
 * @param kind  The kind of constraint to check for
 *              (see arch_register_req_type_t).
 * @return      1, If the kind of constraint is present, 0 if not.
 */
#define arch_register_req_is(req, kind) \
	(((req)->type & (arch_register_req_type_ ## kind)) != 0)

/**
 * Expresses requirements to register allocation for an operand.
 */
struct arch_register_req_t {
	arch_register_req_type_t     type; /**< The type of the constraint. */
	const arch_register_class_t *cls;  /**< The register class this constraint
	                                        belongs to. */
	const unsigned *limited;           /**< allowed register bitset
	                                        (in case of wide-values this is
	                                         only about the first register) */
	unsigned other_same;               /**< Bitmask of ins which should use the
	                                        same register (should_be_same). */
	unsigned other_different;          /**< Bitmask of ins which shall use a
	                                        different register
	                                        (must_be_different) */
	unsigned char width;               /**< specifies how many sequential
	                                        registers are required */
};

static inline bool reg_reqs_equal(const arch_register_req_t *req1,
                                  const arch_register_req_t *req2)
{
	if (req1 == req2)
		return true;

	if (req1->type              != req2->type            ||
	    req1->cls               != req2->cls             ||
	    req1->other_same        != req2->other_same      ||
	    req1->other_different   != req2->other_different ||
	    (req1->limited != NULL) != (req2->limited != NULL))
		return false;

	if (req1->limited != NULL) {
		size_t const n_regs = arch_register_class_n_regs(req1->cls);
		if (!rbitsets_equal(req1->limited, req2->limited, n_regs))
			return false;
	}

	return true;
}

/**
 * An inverse operation returned by the backend
 */
struct arch_inverse_t {
	int      n;       /**< count of nodes returned in nodes array */
	int      costs;   /**< costs of this remat */

	/** nodes for this inverse operation. shall be in schedule order.
	 * last element is the target value */
	ir_node  **nodes;
};

struct arch_irn_ops_t {

	/**
	 * Get the entity on the stack frame this node depends on.
	 * @param irn  The node in question.
	 * @return The entity on the stack frame or NULL, if the node does not have
	 *         a stack frame entity.
	 */
	ir_entity *(*get_frame_entity)(const ir_node *irn);

	/**
	 * Set the offset of a node carrying an entity on the stack frame.
	 * @param irn  The node.
	 * @param offset The offset of the node's stack frame entity.
	 */
	void (*set_frame_offset)(ir_node *irn, int offset);

	/**
	 * Returns the delta of the stackpointer for nodes that increment or
	 * decrement the stackpointer with a constant value. (push, pop
	 * nodes on most architectures).
	 * A positive value stands for an expanding stack area, a negative value for
	 * a shrinking one.
	 *
	 * @param irn       The node
	 * @return          0 if the stackpointer is not modified with a constant
	 *                  value, otherwise the increment/decrement value
	 */
	int (*get_sp_bias)(const ir_node *irn);

	/**
	 * Returns an inverse operation which yields the i-th argument
	 * of the given node as result.
	 *
	 * @param irn       The original operation
	 * @param i         Index of the argument we want the inverse operation to
	 *                  yield
	 * @param inverse   struct to be filled with the resulting inverse op
	 * @param obstack   The obstack to use for allocation of the returned nodes
	 *                  array
	 * @return          The inverse operation or NULL if operation invertible
	 */
	arch_inverse_t *(*get_inverse)(const ir_node *irn, int i,
	                               arch_inverse_t *inverse,
	                               struct obstack *obstack);

	/**
	 * Get the estimated cycle count for @p irn.
	 *
	 * @param irn  The node.
	 * @return     The estimated cycle count for this operation
	 */
	int (*get_op_estimated_cost)(const ir_node *irn);

	/**
	 * Asks the backend whether operand @p i of @p irn can be loaded form memory
	 * internally
	 *
	 * @param irn  The node.
	 * @param i    Index of the argument we would like to know whether @p irn
	 *             can load it form memory internally
	 * @return     nonzero if argument can be loaded or zero otherwise
	 */
	int (*possible_memory_operand)(const ir_node *irn, unsigned int i);

	/**
	 * Ask the backend to assimilate @p reload of operand @p i into @p irn.
	 *
	 * @param irn    The node.
	 * @param spill  The spill.
	 * @param i      The position of the reload.
	 */
	void (*perform_memory_operand)(ir_node *irn, ir_node *spill,
	                               unsigned int i);
};

/**
 * Architecture interface.
 */
struct arch_isa_if_t {
	/**
	 * Initializes the isa interface. This is necessary before calling any
	 * other functions from this interface.
	 */
	void (*init)(void);

	/**
	 * Fress resources allocated by this isa interface.
	 */
	void (*finish)(void);

	/**
	 * Returns the frontend settings needed for this backend.
	 */
	const backend_params *(*get_params)(void);

	/**
	 * lowers current program for target. See the documentation for
	 * be_lower_for_target() for details.
	 */
	void (*lower_for_target)(void);

	/**
	 * parse an assembler constraint part and set flags according to its nature
	 * advances the *c pointer to point to the last parsed character (so if you
	 * parse a single character don't advance c)
	 */
	asm_constraint_flags_t (*parse_asm_constraint)(const char **c);

	/**
	 * returns true if the string is a valid clobbered (register) in this
	 * backend
	 */
	int (*is_valid_clobber)(const char *clobber);

	/**
	 * Start codegeneration
	 * @return a new isa instance
	 */
	arch_env_t *(*begin_codegeneration)(const be_main_env_t *env);

	/**
	 * Free the isa instance.
	 */
	void (*end_codegeneration)(void *self);

	/**
	 * Initialize the code generator for a graph
	 * @param irg  A graph
	 */
	void (*init_graph)(ir_graph *irg);

	/**
	 * Get the ABI restrictions for procedure calls.
	 * @param call_type   The call type of the method (procedure) in question.
	 * @param p           The array of parameter locations to be filled.
	 */
	void (*get_call_abi)(ir_type *call_type, be_abi_call_t *abi);

	/**
	 * mark node as rematerialized
	 */
	void (*mark_remat)(ir_node *node);

	/**
	 * return node used as base in pic code addresses
	 */
	ir_node* (*get_pic_base)(ir_graph *irg);

	/**
	 * Create a spill instruction. We assume that spill instructions
	 * do not need any additional registers and do not affect cpu-flags in any
	 * way.
	 * Construct a sequence of instructions after @p after (the resulting nodes
	 * are already scheduled).
	 * Returns a mode_M value which is used as input for a reload instruction.
	 */
	ir_node *(*new_spill)(ir_node *value, ir_node *after);

	/**
	 * Create a reload instruction. We assume that reload instructions do not
	 * need any additional registers and do not affect cpu-flags in any way.
	 * Constructs a sequence of instruction before @p before (the resulting
	 * nodes are already scheduled). A rewiring of users is not performed in
	 * this function.
	 * Returns a value representing the restored value.
	 */
	ir_node *(*new_reload)(ir_node *value, ir_node *spilled_value,
	                       ir_node *before);

	/**
	 * Checks if the given register is callee/caller saved.
	 * @deprecated, only necessary if backend still uses beabi functions
	 */
	int (*register_saved_by)(const arch_register_t *reg, int callee);

	/**
	 * Called directly after initialization. Backend should handle all
	 * intrinsics here.
	 */
	void (*handle_intrinsics)(void);

	/**
	 * Called before abi introduce.
	 */
	void (*before_abi)(ir_graph *irg);

	/**
	 * Called, when the graph is being normalized.
	 */
	void (*prepare_graph)(ir_graph *irg);

	/**
	 * Called before register allocation.
	 */
	void (*before_ra)(ir_graph *irg);

	/**
	 * Called directly before done is called. This should be the last place
	 * where the irg is modified.
	 */
	void (*finish_graph)(ir_graph *irg);

	/**
	 * Called after everything happened. This call should emit the final
	 * assembly code but avoid changing the irg.
	 */
	void (*emit)(ir_graph *irg);
};

#define arch_env_end_codegeneration(env)               ((env)->impl->end_codegeneration(env))
#define arch_env_handle_intrinsics(env)                \
	do { if((env)->impl->handle_intrinsics != NULL) (env)->impl->handle_intrinsics(); } while(0)
#define arch_env_get_call_abi(env,tp,abi)              ((env)->impl->get_call_abi((tp), (abi)))
#define arch_env_get_params(env)                       ((env)->impl->get_params())
#define arch_env_parse_asm_constraint(env,c)           ((env)->impl->parse_asm_constraint((c))
#define arch_env_is_valid_clobber(env,clobber)         ((env)->impl->is_valid_clobber((clobber))
#define arch_env_mark_remat(env,node) \
	do { if ((env)->impl->mark_remat != NULL) (env)->impl->mark_remat((node)); } while(0)

#define arch_env_new_spill(env,value,after)            ((env)->impl->new_spill(value, after))
#define arch_env_new_reload(env,value,spilled,before)  ((env)->impl->new_reload(value, spilled, before))

/**
 * ISA base class.
 */
struct arch_env_t {
	const arch_isa_if_t   *impl;
	unsigned               n_registers;      /**< number of registers */
	const arch_register_t *registers;        /**< register array */
	unsigned               n_register_classes; /**< number of register classes*/
	const arch_register_class_t *register_classes; /**< register classes */
	const arch_register_t *sp;               /**< The stack pointer register. */
	const arch_register_t *bp;               /**< The base pointer register. */
	const arch_register_class_t *link_class; /**< The static link pointer
	                                              register class. */
	int                    stack_alignment;  /**< power of 2 stack alignment */
	const be_main_env_t   *main_env;         /**< the be main environment */
	int                    spill_cost;       /**< cost for a be_Spill node */
	int                    reload_cost;      /**< cost for a be_Reload node */
	bool                   custom_abi : 1;   /**< backend does all abi handling
	                                              and does not need the generic
	                                              stuff from beabi.h/.c */
};

static inline bool arch_irn_is_ignore(const ir_node *irn)
{
	const arch_register_req_t *req = arch_get_irn_register_req(irn);
	return req->type & arch_register_req_type_ignore;
}

static inline bool arch_irn_consider_in_reg_alloc(
		const arch_register_class_t *cls, const ir_node *node)
{
	const arch_register_req_t *req = arch_get_irn_register_req(node);
	return
		req->cls == cls &&
		!(req->type & arch_register_req_type_ignore);
}

/**
 * Iterate over all values defined by an instruction.
 * Only looks at values in a certain register class where the requirements
 * are not marked as ignore.
 * Executes @p code for each definition.
 */
#define be_foreach_definition_(node, ccls, value, code)                    \
	do {                                                                   \
	if (get_irn_mode(node) == mode_T) {                                    \
		foreach_out_edge(node, edge_) {                                    \
			ir_node                   *const value = get_edge_src_irn(edge_); \
			arch_register_req_t const *const req_  = arch_get_irn_register_req(value); \
			if (req_->cls != ccls)                                         \
				continue;                                                  \
			code                                                           \
		}                                                                  \
	} else {                                                               \
		arch_register_req_t const *const req_  = arch_get_irn_register_req(node); \
		ir_node                   *const value = node; \
		if (req_->cls == ccls) {                                           \
			code                                                           \
		}                                                                  \
	}                                                                      \
	} while (0)

#define be_foreach_definition(node, ccls, value, code)                     \
	be_foreach_definition_(node, ccls, value,                              \
		if (req_->type & arch_register_req_type_ignore)                    \
			continue;                                                      \
		code                                                               \
	)

static inline const arch_register_class_t *arch_get_irn_reg_class(
		const ir_node *node)
{
	const arch_register_req_t *req = arch_get_irn_register_req(node);
	return req->cls;
}

bool arch_reg_is_allocatable(const arch_register_req_t *req,
                             const arch_register_t *reg);

#endif