ack/lang/m2/comp/casestat.C

/* C A S E   S T A T E M E N T   C O D E   G E N E R A T I O N */

#ifndef NORCSID
static char *RcsId = "$Header$";
#endif

#include	"debug.h"

#include	<em_label.h>
#include	<em_arith.h>
#include	<alloc.h>
#include	<assert.h>

#include	"Lpars.h"
#include	"type.h"
#include	"LLlex.h"
#include	"node.h"
#include	"desig.h"

#include	"density.h"

struct switch_hdr	{
	struct switch_hdr *next;
	label sh_break;
	label sh_default;
	int sh_nrofentries;
	struct type *sh_type;
	arith sh_lowerbd;
	arith sh_upperbd;
	struct case_entry *sh_entries;
};

/* STATICALLOCDEF "switch_hdr" */

struct case_entry	{
	struct case_entry *next;
	label ce_label;
	arith ce_value;
};

/* STATICALLOCDEF "case_entry" */

/* The constant DENSITY determines when CSA and when CSB instructions
   are generated. Reasonable values are: 2, 3, 4.
   On machines that have lots of address space and memory, higher values
   are also reasonable. On these machines the density of jump tables
   may be lower.
*/
#define	compact(nr, low, up)	(nr != 0 && (up - low) / nr <= DENSITY)

extern label text_label(), data_label();

CaseCode(nd, exitlabel)
	struct node *nd;
	label exitlabel;
{
	/*	Check the expression, stack a new case header and
		fill in the necessary fields.
	*/
	register struct switch_hdr *sh = new_switch_hdr();
	register struct node *pnode = nd;
	register struct case_entry *ce;
	register arith val;
	label tablabel;

	assert(nd->nd_class == Stat && nd->nd_symb == CASE);

	WalkExpr(nd->nd_left, NO_LABEL, NO_LABEL);
	sh->sh_type = nd->nd_left->nd_type;
	sh->sh_break = text_label();
	sh->sh_default = 0;
	sh->sh_nrofentries = 0;
	sh->sh_lowerbd = sh->sh_upperbd = (arith)0;	/* immaterial ??? */
	sh->sh_entries = (struct case_entry *) 0; /* case-entry list	*/

	/* Now, create case label list
	*/
	while (pnode && pnode->nd_right) {
		pnode = pnode->nd_right;
		if (pnode->nd_class == Link && pnode->nd_symb == '|') {
			if (pnode->nd_left) {
				pnode->nd_lab = text_label();
				if (! AddCases(sh,
					       pnode->nd_left->nd_left,
					       pnode->nd_lab)) {
					FreeSh(sh);
					return;
				}
			}
		}
		else {
			/* Else part
			*/
			pnode = 0;
			sh->sh_default = text_label();
		}
	}

	/* Now generate code for the switch itself
	*/
	tablabel = data_label();	/* the rom must have a label	*/
	C_df_dlb(tablabel);
	if (sh->sh_default) C_rom_ilb(sh->sh_default);
	else C_rom_ucon("0", pointer_size);
	if (compact(sh->sh_nrofentries, sh->sh_lowerbd, sh->sh_upperbd)) {
		/* CSA */

		C_rom_cst(sh->sh_lowerbd);
		C_rom_cst(sh->sh_upperbd - sh->sh_lowerbd);
		ce = sh->sh_entries;
		for (val = sh->sh_lowerbd; val <= sh->sh_upperbd; val++) {
			assert(ce);
			if (val == ce->ce_value)	{
				C_rom_ilb(ce->ce_label);
				ce = ce->next;
			}
			else if (sh->sh_default) C_rom_ilb(sh->sh_default);
			else C_rom_ucon("0", pointer_size);
		}
		C_lae_dlb(tablabel, (arith)0); /* perform the switch	*/
		C_csa(word_size);
	}
	else	{ /* CSB */
		C_rom_cst((arith)sh->sh_nrofentries);
		for (ce = sh->sh_entries; ce; ce = ce->next)	{
			/* generate the entries: value + prog.label	*/
			C_rom_cst(ce->ce_value);
			C_rom_ilb(ce->ce_label);
		}
		C_lae_dlb(tablabel, (arith)0); /* perform the switch	*/
		C_csb(word_size);
	}

	/* Now generate code for the cases
	*/
	pnode = nd;
	while (pnode && pnode->nd_right) {
		pnode = pnode->nd_right;
		if (pnode->nd_class == Link && pnode->nd_symb == '|') {
			if (pnode->nd_left) {
				C_df_ilb(pnode->nd_lab);
				WalkNode(pnode->nd_left->nd_right, exitlabel);
				C_bra(sh->sh_break);
			}
		}
		else {
			/* Else part
			*/
			assert(sh->sh_default != 0);

			C_df_ilb(sh->sh_default);
			WalkNode(pnode, exitlabel);
			pnode = 0;
		}
	}

	C_df_ilb(sh->sh_break);
	FreeSh(sh);
}

FreeSh(sh)
	struct switch_hdr *sh;
{
	/*	 free the allocated switch structure	
	*/
	register struct case_entry *ce;

	ce = sh->sh_entries;
	while (ce)	{
		struct case_entry *tmp = ce->next;

		free_case_entry(ce);
		ce = tmp;
	}

	free_switch_hdr(sh);
}

AddCases(sh, node, lbl)
	struct switch_hdr *sh;
	struct node *node;
	label lbl;
{
	/*	Add case labels to the case label list
	*/
	register arith v1, v2;

	if (node->nd_class == Link) {
		if (node->nd_symb == UPTO) {
			assert(node->nd_left->nd_class == Value);
			assert(node->nd_right->nd_class == Value);
			v2 = node->nd_right->nd_INT;
			node->nd_type = node->nd_left->nd_type;
			for (v1 = node->nd_left->nd_INT; v1 <= v2; v1++) {
				node->nd_INT = v1;
				if (! AddOneCase(sh, node, lbl)) return 0;
			}
			return 1;
		}

		assert(node->nd_symb == ',');
		return	AddCases(sh, node->nd_left, lbl) &&
		    	AddCases(sh, node->nd_right, lbl);
	}

	assert(node->nd_class == Value);
	return AddOneCase(sh, node, lbl);
}

AddOneCase(sh, node, lbl)
	register struct switch_hdr *sh;
	struct node *node;
	label lbl;
{
	register struct case_entry *ce = new_case_entry();
	register struct case_entry *c1 = sh->sh_entries, *c2 = 0;

	ce->ce_label = lbl;
	ce->ce_value = node->nd_INT;
	if (! TstCompat(sh->sh_type, node->nd_type)) {
		node_error(node, "Type incompatibility in case");
		free_case_entry(ce);
		return 0;
	}
	if (sh->sh_entries == 0)	{
		/* first case entry	*/
		ce->next = (struct case_entry *) 0;
		sh->sh_entries = ce;
		sh->sh_lowerbd = sh->sh_upperbd = ce->ce_value;
		sh->sh_nrofentries = 1;
	}
	else	{
		/* second etc. case entry		*/
		/* find the proper place to put ce into the list	*/
		
		if (ce->ce_value < sh->sh_lowerbd) sh->sh_lowerbd = ce->ce_value;
		else
		if (ce->ce_value > sh->sh_upperbd) sh->sh_upperbd = ce->ce_value;
		while (c1 && c1->ce_value < ce->ce_value)	{
			c2 = c1;
			c1 = c1->next;
		}
		/*	At this point three cases are possible:
			1: c1 != 0 && c2 != 0:
				insert ce somewhere in the middle
			2: c1 != 0 && c2 == 0:
				insert ce right after the head
			3: c1 == 0 && c2 != 0:
				append ce to last element
			The case c1 == 0 && c2 == 0 cannot occur, since
			the list is guaranteed not to be empty.
		*/
		if (c1)	{
			if (c1->ce_value == ce->ce_value)	{
node_error(node, "multiple case entry for value %ld", ce->ce_value);
				free_case_entry(ce);
				return 0;
			}
			if (c2)	{
				ce->next = c2->next;
				c2->next = ce;
			}
			else	{
				ce->next = sh->sh_entries;
				sh->sh_entries = ce;
			}
		}
		else	{
			assert(c2);

			ce->next = (struct case_entry *) 0;
			c2->next = ce;
		}
		(sh->sh_nrofentries)++;
	}
	return 1;
}
newer version 1986-05-01 19:06:53 +00:00			`/* C A S E S T A T E M E N T C O D E G E N E R A T I O N */`

			`#ifndef NORCSID`
			`static char *RcsId = "$Header$";`
			`#endif`

			`#include "debug.h"`

			`#include <em_label.h>`
			`#include <em_arith.h>`
			`#include <alloc.h>`
			`#include <assert.h>`

			`#include "Lpars.h"`
			`#include "type.h"`
			`#include "LLlex.h"`
			`#include "node.h"`
newer version 1986-05-21 18:32:20 +00:00			`#include "desig.h"`
newer version 1986-05-01 19:06:53 +00:00
			`#include "density.h"`

			`struct switch_hdr {`
			`struct switch_hdr *next;`
			`label sh_break;`
			`label sh_default;`
			`int sh_nrofentries;`
			`struct type *sh_type;`
			`arith sh_lowerbd;`
			`arith sh_upperbd;`
			`struct case_entry *sh_entries;`
			`};`

			`/* STATICALLOCDEF "switch_hdr" */`

			`struct case_entry {`
			`struct case_entry *next;`
			`label ce_label;`
			`arith ce_value;`
			`};`

			`/* STATICALLOCDEF "case_entry" */`

			`/* The constant DENSITY determines when CSA and when CSB instructions`
			`are generated. Reasonable values are: 2, 3, 4.`
			`On machines that have lots of address space and memory, higher values`
			`are also reasonable. On these machines the density of jump tables`
			`may be lower.`
			`*/`
			`#define compact(nr, low, up) (nr != 0 && (up - low) / nr <= DENSITY)`

			`extern label text_label(), data_label();`

			`CaseCode(nd, exitlabel)`
			`struct node *nd;`
			`label exitlabel;`
			`{`
			`/* Check the expression, stack a new case header and`
			`fill in the necessary fields.`
			`*/`
			`register struct switch_hdr *sh = new_switch_hdr();`
			`register struct node *pnode = nd;`
			`register struct case_entry *ce;`
			`register arith val;`
			`label tablabel;`

			`assert(nd->nd_class == Stat && nd->nd_symb == CASE);`

newer version 1986-05-21 18:32:20 +00:00			`WalkExpr(nd->nd_left, NO_LABEL, NO_LABEL);`
newer version 1986-05-01 19:06:53 +00:00			`sh->sh_type = nd->nd_left->nd_type;`
			`sh->sh_break = text_label();`
			`sh->sh_default = 0;`
			`sh->sh_nrofentries = 0;`
			`sh->sh_lowerbd = sh->sh_upperbd = (arith)0; /* immaterial ??? */`
			`sh->sh_entries = (struct case_entry ) 0; / case-entry list */`

			`/* Now, create case label list`
			`*/`
			`while (pnode && pnode->nd_right) {`
			`pnode = pnode->nd_right;`
			`if (pnode->nd_class == Link && pnode->nd_symb == '\|') {`
			`if (pnode->nd_left) {`
			`pnode->nd_lab = text_label();`
			`if (! AddCases(sh,`
			`pnode->nd_left->nd_left,`
			`pnode->nd_lab)) {`
			`FreeSh(sh);`
			`return;`
			`}`
			`}`
			`}`
			`else {`
			`/* Else part`
			`*/`
			`pnode = 0;`
			`sh->sh_default = text_label();`
			`}`
			`}`

			`/* Now generate code for the switch itself`
			`*/`
			`tablabel = data_label(); /* the rom must have a label */`
			`C_df_dlb(tablabel);`
			`if (sh->sh_default) C_rom_ilb(sh->sh_default);`
newer version 1986-05-14 09:03:51 +00:00			`else C_rom_ucon("0", pointer_size);`
newer version 1986-05-01 19:06:53 +00:00			`if (compact(sh->sh_nrofentries, sh->sh_lowerbd, sh->sh_upperbd)) {`
			`/* CSA */`

			`C_rom_cst(sh->sh_lowerbd);`
			`C_rom_cst(sh->sh_upperbd - sh->sh_lowerbd);`
			`ce = sh->sh_entries;`
			`for (val = sh->sh_lowerbd; val <= sh->sh_upperbd; val++) {`
			`assert(ce);`
			`if (val == ce->ce_value) {`
			`C_rom_ilb(ce->ce_label);`
			`ce = ce->next;`
			`}`
			`else if (sh->sh_default) C_rom_ilb(sh->sh_default);`
			`else C_rom_ucon("0", pointer_size);`
			`}`
			`C_lae_dlb(tablabel, (arith)0); /* perform the switch */`
			`C_csa(word_size);`
			`}`
			`else { /* CSB */`
			`C_rom_cst((arith)sh->sh_nrofentries);`
			`for (ce = sh->sh_entries; ce; ce = ce->next) {`
			`/* generate the entries: value + prog.label */`
			`C_rom_cst(ce->ce_value);`
			`C_rom_ilb(ce->ce_label);`
			`}`
			`C_lae_dlb(tablabel, (arith)0); /* perform the switch */`
			`C_csb(word_size);`
			`}`

			`/* Now generate code for the cases`
			`*/`
			`pnode = nd;`
			`while (pnode && pnode->nd_right) {`
			`pnode = pnode->nd_right;`
			`if (pnode->nd_class == Link && pnode->nd_symb == '\|') {`
			`if (pnode->nd_left) {`
			`C_df_ilb(pnode->nd_lab);`
			`WalkNode(pnode->nd_left->nd_right, exitlabel);`
			`C_bra(sh->sh_break);`
			`}`
			`}`
			`else {`
			`/* Else part`
			`*/`
			`assert(sh->sh_default != 0);`

			`C_df_ilb(sh->sh_default);`
			`WalkNode(pnode, exitlabel);`
			`pnode = 0;`
			`}`
			`}`

			`C_df_ilb(sh->sh_break);`
			`FreeSh(sh);`
			`}`

			`FreeSh(sh)`
			`struct switch_hdr *sh;`
			`{`
			`/* free the allocated switch structure`
			`*/`
			`register struct case_entry *ce;`

			`ce = sh->sh_entries;`
			`while (ce) {`
			`struct case_entry *tmp = ce->next;`

			`free_case_entry(ce);`
			`ce = tmp;`
			`}`

			`free_switch_hdr(sh);`
			`}`

			`AddCases(sh, node, lbl)`
			`struct switch_hdr *sh;`
			`struct node *node;`
			`label lbl;`
			`{`
			`/* Add case labels to the case label list`
			`*/`
			`register arith v1, v2;`

			`if (node->nd_class == Link) {`
			`if (node->nd_symb == UPTO) {`
			`assert(node->nd_left->nd_class == Value);`
			`assert(node->nd_right->nd_class == Value);`
			`v2 = node->nd_right->nd_INT;`
			`node->nd_type = node->nd_left->nd_type;`
			`for (v1 = node->nd_left->nd_INT; v1 <= v2; v1++) {`
			`node->nd_INT = v1;`
			`if (! AddOneCase(sh, node, lbl)) return 0;`
			`}`
			`return 1;`
			`}`

			`assert(node->nd_symb == ',');`
			`return AddCases(sh, node->nd_left, lbl) &&`
			`AddCases(sh, node->nd_right, lbl);`
			`}`

			`assert(node->nd_class == Value);`
			`return AddOneCase(sh, node, lbl);`
			`}`

			`AddOneCase(sh, node, lbl)`
			`register struct switch_hdr *sh;`
			`struct node *node;`
			`label lbl;`
			`{`
			`register struct case_entry *ce = new_case_entry();`
			`register struct case_entry c1 = sh->sh_entries, c2 = 0;`

			`ce->ce_label = lbl;`
			`ce->ce_value = node->nd_INT;`
			`if (! TstCompat(sh->sh_type, node->nd_type)) {`
			`node_error(node, "Type incompatibility in case");`
			`free_case_entry(ce);`
			`return 0;`
			`}`
			`if (sh->sh_entries == 0) {`
			`/* first case entry */`
			`ce->next = (struct case_entry *) 0;`
			`sh->sh_entries = ce;`
			`sh->sh_lowerbd = sh->sh_upperbd = ce->ce_value;`
			`sh->sh_nrofentries = 1;`
			`}`
			`else {`
			`/* second etc. case entry */`
			`/* find the proper place to put ce into the list */`

			`if (ce->ce_value < sh->sh_lowerbd) sh->sh_lowerbd = ce->ce_value;`
			`else`
			`if (ce->ce_value > sh->sh_upperbd) sh->sh_upperbd = ce->ce_value;`
			`while (c1 && c1->ce_value < ce->ce_value) {`
			`c2 = c1;`
			`c1 = c1->next;`
			`}`
			`/* At this point three cases are possible:`
			`1: c1 != 0 && c2 != 0:`
			`insert ce somewhere in the middle`
			`2: c1 != 0 && c2 == 0:`
			`insert ce right after the head`
			`3: c1 == 0 && c2 != 0:`
			`append ce to last element`
			`The case c1 == 0 && c2 == 0 cannot occur, since`
			`the list is guaranteed not to be empty.`
			`*/`
			`if (c1) {`
			`if (c1->ce_value == ce->ce_value) {`
newer version 1986-05-14 09:03:51 +00:00			`node_error(node, "multiple case entry for value %ld", ce->ce_value);`
newer version 1986-05-01 19:06:53 +00:00			`free_case_entry(ce);`
			`return 0;`
			`}`
			`if (c2) {`
			`ce->next = c2->next;`
			`c2->next = ce;`
			`}`
			`else {`
			`ce->next = sh->sh_entries;`
			`sh->sh_entries = ce;`
			`}`
			`}`
			`else {`
			`assert(c2);`

			`ce->next = (struct case_entry *) 0;`
			`c2->next = ce;`
			`}`
			`(sh->sh_nrofentries)++;`
			`}`
			`return 1;`
			`}`